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protobuf/ruby/ext/google/protobuf_c/upb.c

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Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
// Amalgamated source file
#include "upb.h"
/*
* upb - a minimalist implementation of protocol buffers.
*
* Copyright (c) 2008-2012 Google Inc. See LICENSE for details.
* Author: Josh Haberman <jhaberman@gmail.com>
*/
#include <stdlib.h>
#include <string.h>
typedef struct {
size_t len;
char str[1]; // Null-terminated string data follows.
} str_t;
static str_t *newstr(const char *data, size_t len) {
str_t *ret = malloc(sizeof(*ret) + len);
if (!ret) return NULL;
ret->len = len;
memcpy(ret->str, data, len);
ret->str[len] = '\0';
return ret;
}
static void freestr(str_t *s) { free(s); }
// isalpha() etc. from <ctype.h> are locale-dependent, which we don't want.
static bool upb_isbetween(char c, char low, char high) {
return c >= low && c <= high;
}
static bool upb_isletter(char c) {
return upb_isbetween(c, 'A', 'Z') || upb_isbetween(c, 'a', 'z') || c == '_';
}
static bool upb_isalphanum(char c) {
return upb_isletter(c) || upb_isbetween(c, '0', '9');
}
static bool upb_isident(const char *str, size_t len, bool full, upb_status *s) {
bool start = true;
for (size_t i = 0; i < len; i++) {
char c = str[i];
if (c == '.') {
if (start || !full) {
upb_status_seterrf(s, "invalid name: unexpected '.' (%s)", str);
return false;
}
start = true;
} else if (start) {
if (!upb_isletter(c)) {
upb_status_seterrf(
s, "invalid name: path components must start with a letter (%s)",
str);
return false;
}
start = false;
} else {
if (!upb_isalphanum(c)) {
upb_status_seterrf(s, "invalid name: non-alphanumeric character (%s)",
str);
return false;
}
}
}
return !start;
}
/* upb_def ********************************************************************/
upb_deftype_t upb_def_type(const upb_def *d) { return d->type; }
const char *upb_def_fullname(const upb_def *d) { return d->fullname; }
bool upb_def_setfullname(upb_def *def, const char *fullname, upb_status *s) {
assert(!upb_def_isfrozen(def));
if (!upb_isident(fullname, strlen(fullname), true, s)) return false;
free((void*)def->fullname);
def->fullname = upb_strdup(fullname);
return true;
}
upb_def *upb_def_dup(const upb_def *def, const void *o) {
switch (def->type) {
case UPB_DEF_MSG:
return UPB_UPCAST(upb_msgdef_dup(upb_downcast_msgdef(def), o));
case UPB_DEF_FIELD:
return UPB_UPCAST(upb_fielddef_dup(upb_downcast_fielddef(def), o));
case UPB_DEF_ENUM:
return UPB_UPCAST(upb_enumdef_dup(upb_downcast_enumdef(def), o));
default: assert(false); return NULL;
}
}
bool upb_def_isfrozen(const upb_def *def) {
return upb_refcounted_isfrozen(UPB_UPCAST(def));
}
void upb_def_ref(const upb_def *def, const void *owner) {
upb_refcounted_ref(UPB_UPCAST(def), owner);
}
void upb_def_unref(const upb_def *def, const void *owner) {
upb_refcounted_unref(UPB_UPCAST(def), owner);
}
void upb_def_donateref(const upb_def *def, const void *from, const void *to) {
upb_refcounted_donateref(UPB_UPCAST(def), from, to);
}
void upb_def_checkref(const upb_def *def, const void *owner) {
upb_refcounted_checkref(UPB_UPCAST(def), owner);
}
static bool upb_def_init(upb_def *def, upb_deftype_t type,
const struct upb_refcounted_vtbl *vtbl,
const void *owner) {
if (!upb_refcounted_init(UPB_UPCAST(def), vtbl, owner)) return false;
def->type = type;
def->fullname = NULL;
def->came_from_user = false;
return true;
}
static void upb_def_uninit(upb_def *def) {
free((void*)def->fullname);
}
static const char *msgdef_name(const upb_msgdef *m) {
const char *name = upb_def_fullname(UPB_UPCAST(m));
return name ? name : "(anonymous)";
}
static bool upb_validate_field(upb_fielddef *f, upb_status *s) {
if (upb_fielddef_name(f) == NULL || upb_fielddef_number(f) == 0) {
upb_status_seterrmsg(s, "fielddef must have name and number set");
return false;
}
if (!f->type_is_set_) {
upb_status_seterrmsg(s, "fielddef type was not initialized");
return false;
}
if (upb_fielddef_lazy(f) &&
upb_fielddef_descriptortype(f) != UPB_DESCRIPTOR_TYPE_MESSAGE) {
upb_status_seterrmsg(s,
"only length-delimited submessage fields may be lazy");
return false;
}
if (upb_fielddef_hassubdef(f)) {
if (f->subdef_is_symbolic) {
upb_status_seterrf(s, "field '%s.%s' has not been resolved",
msgdef_name(f->msg.def), upb_fielddef_name(f));
return false;
}
const upb_def *subdef = upb_fielddef_subdef(f);
if (subdef == NULL) {
upb_status_seterrf(s, "field %s.%s is missing required subdef",
msgdef_name(f->msg.def), upb_fielddef_name(f));
return false;
}
if (!upb_def_isfrozen(subdef) && !subdef->came_from_user) {
upb_status_seterrf(s,
"subdef of field %s.%s is not frozen or being frozen",
msgdef_name(f->msg.def), upb_fielddef_name(f));
return false;
}
}
if (upb_fielddef_type(f) == UPB_TYPE_ENUM) {
bool has_default_name = upb_fielddef_enumhasdefaultstr(f);
bool has_default_number = upb_fielddef_enumhasdefaultint32(f);
// Previously verified by upb_validate_enumdef().
assert(upb_enumdef_numvals(upb_fielddef_enumsubdef(f)) > 0);
// We've already validated that we have an associated enumdef and that it
// has at least one member, so at least one of these should be true.
// Because if the user didn't set anything, we'll pick up the enum's
// default, but if the user *did* set something we should at least pick up
// the one they set (int32 or string).
assert(has_default_name || has_default_number);
if (!has_default_name) {
upb_status_seterrf(s,
"enum default for field %s.%s (%d) is not in the enum",
msgdef_name(f->msg.def), upb_fielddef_name(f),
upb_fielddef_defaultint32(f));
return false;
}
if (!has_default_number) {
upb_status_seterrf(s,
"enum default for field %s.%s (%s) is not in the enum",
msgdef_name(f->msg.def), upb_fielddef_name(f),
upb_fielddef_defaultstr(f, NULL));
return false;
}
// Lift the effective numeric default into the field's default slot, in case
// we were only getting it "by reference" from the enumdef.
upb_fielddef_setdefaultint32(f, upb_fielddef_defaultint32(f));
}
return true;
}
static bool upb_validate_enumdef(const upb_enumdef *e, upb_status *s) {
if (upb_enumdef_numvals(e) == 0) {
upb_status_seterrf(s, "enum %s has no members (must have at least one)",
upb_enumdef_fullname(e));
return false;
}
return true;
}
// All submessage fields are lower than all other fields.
// Secondly, fields are increasing in order.
uint32_t field_rank(const upb_fielddef *f) {
uint32_t ret = upb_fielddef_number(f);
const uint32_t high_bit = 1 << 30;
assert(ret < high_bit);
if (!upb_fielddef_issubmsg(f))
ret |= high_bit;
return ret;
}
int cmp_fields(const void *p1, const void *p2) {
const upb_fielddef *f1 = *(upb_fielddef*const*)p1;
const upb_fielddef *f2 = *(upb_fielddef*const*)p2;
return field_rank(f1) - field_rank(f2);
}
static bool assign_msg_indices(upb_msgdef *m, upb_status *s) {
// Sort fields. upb internally relies on UPB_TYPE_MESSAGE fields having the
// lowest indexes, but we do not publicly guarantee this.
int n = upb_msgdef_numfields(m);
upb_fielddef **fields = malloc(n * sizeof(*fields));
if (!fields) return false;
Support oneofs in MRI Ruby C extension.
10 years ago
upb_msg_field_iter j;
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
int i;
m->submsg_field_count = 0;
Support oneofs in MRI Ruby C extension.
10 years ago
for(i = 0, upb_msg_field_begin(&j, m);
!upb_msg_field_done(&j);
upb_msg_field_next(&j), i++) {
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
upb_fielddef *f = upb_msg_iter_field(&j);
assert(f->msg.def == m);
if (!upb_validate_field(f, s)) {
free(fields);
return false;
}
if (upb_fielddef_issubmsg(f)) {
m->submsg_field_count++;
}
fields[i] = f;
}
qsort(fields, n, sizeof(*fields), cmp_fields);
uint32_t selector = UPB_STATIC_SELECTOR_COUNT + m->submsg_field_count;
for (i = 0; i < n; i++) {
upb_fielddef *f = fields[i];
f->index_ = i;
f->selector_base = selector + upb_handlers_selectorbaseoffset(f);
selector += upb_handlers_selectorcount(f);
}
m->selector_count = selector;
#ifndef NDEBUG
// Verify that all selectors for the message are distinct.
//
#define TRY(type) \
if (upb_handlers_getselector(f, type, &sel)) upb_inttable_insert(&t, sel, v);
upb_inttable t;
upb_inttable_init(&t, UPB_CTYPE_BOOL);
upb_value v = upb_value_bool(true);
upb_selector_t sel;
upb_inttable_insert(&t, UPB_STARTMSG_SELECTOR, v);
upb_inttable_insert(&t, UPB_ENDMSG_SELECTOR, v);
Support oneofs in MRI Ruby C extension.
10 years ago
for(upb_msg_field_begin(&j, m);
!upb_msg_field_done(&j);
upb_msg_field_next(&j)) {
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
upb_fielddef *f = upb_msg_iter_field(&j);
// These calls will assert-fail in upb_table if the value already exists.
TRY(UPB_HANDLER_INT32);
TRY(UPB_HANDLER_INT64)
TRY(UPB_HANDLER_UINT32)
TRY(UPB_HANDLER_UINT64)
TRY(UPB_HANDLER_FLOAT)
TRY(UPB_HANDLER_DOUBLE)
TRY(UPB_HANDLER_BOOL)
TRY(UPB_HANDLER_STARTSTR)
TRY(UPB_HANDLER_STRING)
TRY(UPB_HANDLER_ENDSTR)
TRY(UPB_HANDLER_STARTSUBMSG)
TRY(UPB_HANDLER_ENDSUBMSG)
TRY(UPB_HANDLER_STARTSEQ)
TRY(UPB_HANDLER_ENDSEQ)
}
upb_inttable_uninit(&t);
#undef TRY
#endif
free(fields);
return true;
}
bool upb_def_freeze(upb_def *const* defs, int n, upb_status *s) {
upb_status_clear(s);
// First perform validation, in two passes so we can check that we have a
// transitive closure without needing to search.
for (int i = 0; i < n; i++) {
upb_def *def = defs[i];
if (upb_def_isfrozen(def)) {
// Could relax this requirement if it's annoying.
upb_status_seterrmsg(s, "def is already frozen");
goto err;
} else if (def->type == UPB_DEF_FIELD) {
upb_status_seterrmsg(s, "standalone fielddefs can not be frozen");
goto err;
} else if (def->type == UPB_DEF_ENUM) {
if (!upb_validate_enumdef(upb_dyncast_enumdef(def), s)) {
goto err;
}
} else {
// Set now to detect transitive closure in the second pass.
def->came_from_user = true;
}
}
// Second pass of validation. Also assign selector bases and indexes, and
// compact tables.
for (int i = 0; i < n; i++) {
upb_msgdef *m = upb_dyncast_msgdef_mutable(defs[i]);
upb_enumdef *e = upb_dyncast_enumdef_mutable(defs[i]);
if (m) {
upb_inttable_compact(&m->itof);
if (!assign_msg_indices(m, s)) {
goto err;
}
} else if (e) {
upb_inttable_compact(&e->iton);
}
}
// Def graph contains FieldDefs between each MessageDef, so double the limit.
int maxdepth = UPB_MAX_MESSAGE_DEPTH * 2;
// Validation all passed; freeze the defs.
bool ret =
upb_refcounted_freeze((upb_refcounted * const *)defs, n, s, maxdepth);
assert(!(s && ret != upb_ok(s)));
return ret;
err:
for (int i = 0; i < n; i++) {
defs[i]->came_from_user = false;
}
assert(!(s && upb_ok(s)));
return false;
}
/* upb_enumdef ****************************************************************/
static void upb_enumdef_free(upb_refcounted *r) {
upb_enumdef *e = (upb_enumdef*)r;
upb_inttable_iter i;
upb_inttable_begin(&i, &e->iton);
for( ; !upb_inttable_done(&i); upb_inttable_next(&i)) {
// To clean up the upb_strdup() from upb_enumdef_addval().
free(upb_value_getcstr(upb_inttable_iter_value(&i)));
}
upb_strtable_uninit(&e->ntoi);
upb_inttable_uninit(&e->iton);
upb_def_uninit(UPB_UPCAST(e));
free(e);
}
upb_enumdef *upb_enumdef_new(const void *owner) {
static const struct upb_refcounted_vtbl vtbl = {NULL, &upb_enumdef_free};
upb_enumdef *e = malloc(sizeof(*e));
if (!e) return NULL;
if (!upb_def_init(UPB_UPCAST(e), UPB_DEF_ENUM, &vtbl, owner)) goto err2;
if (!upb_strtable_init(&e->ntoi, UPB_CTYPE_INT32)) goto err2;
if (!upb_inttable_init(&e->iton, UPB_CTYPE_CSTR)) goto err1;
return e;
err1:
upb_strtable_uninit(&e->ntoi);
err2:
free(e);
return NULL;
}
upb_enumdef *upb_enumdef_dup(const upb_enumdef *e, const void *owner) {
upb_enumdef *new_e = upb_enumdef_new(owner);
if (!new_e) return NULL;
upb_enum_iter i;
for(upb_enum_begin(&i, e); !upb_enum_done(&i); upb_enum_next(&i)) {
bool success = upb_enumdef_addval(
new_e, upb_enum_iter_name(&i),upb_enum_iter_number(&i), NULL);
if (!success) {
upb_enumdef_unref(new_e, owner);
return NULL;
}
}
return new_e;
}
bool upb_enumdef_isfrozen(const upb_enumdef *e) {
return upb_def_isfrozen(UPB_UPCAST(e));
}
void upb_enumdef_ref(const upb_enumdef *e, const void *owner) {
upb_def_ref(UPB_UPCAST(e), owner);
}
void upb_enumdef_unref(const upb_enumdef *e, const void *owner) {
upb_def_unref(UPB_UPCAST(e), owner);
}
void upb_enumdef_donateref(
const upb_enumdef *e, const void *from, const void *to) {
upb_def_donateref(UPB_UPCAST(e), from, to);
}
void upb_enumdef_checkref(const upb_enumdef *e, const void *owner) {
upb_def_checkref(UPB_UPCAST(e), owner);
}
bool upb_enumdef_freeze(upb_enumdef *e, upb_status *status) {
upb_def *d = UPB_UPCAST(e);
return upb_def_freeze(&d, 1, status);
}
const char *upb_enumdef_fullname(const upb_enumdef *e) {
return upb_def_fullname(UPB_UPCAST(e));
}
bool upb_enumdef_setfullname(upb_enumdef *e, const char *fullname,
upb_status *s) {
return upb_def_setfullname(UPB_UPCAST(e), fullname, s);
}
bool upb_enumdef_addval(upb_enumdef *e, const char *name, int32_t num,
upb_status *status) {
if (!upb_isident(name, strlen(name), false, status)) {
return false;
}
if (upb_enumdef_ntoiz(e, name, NULL)) {
upb_status_seterrf(status, "name '%s' is already defined", name);
return false;
}
if (!upb_strtable_insert(&e->ntoi, name, upb_value_int32(num))) {
upb_status_seterrmsg(status, "out of memory");
return false;
}
if (!upb_inttable_lookup(&e->iton, num, NULL) &&
!upb_inttable_insert(&e->iton, num, upb_value_cstr(upb_strdup(name)))) {
upb_status_seterrmsg(status, "out of memory");
upb_strtable_remove(&e->ntoi, name, NULL);
return false;
}
if (upb_enumdef_numvals(e) == 1) {
bool ok = upb_enumdef_setdefault(e, num, NULL);
UPB_ASSERT_VAR(ok, ok);
}
return true;
}
int32_t upb_enumdef_default(const upb_enumdef *e) {
assert(upb_enumdef_iton(e, e->defaultval));
return e->defaultval;
}
bool upb_enumdef_setdefault(upb_enumdef *e, int32_t val, upb_status *s) {
assert(!upb_enumdef_isfrozen(e));
if (!upb_enumdef_iton(e, val)) {
upb_status_seterrf(s, "number '%d' is not in the enum.", val);
return false;
}
e->defaultval = val;
return true;
}
int upb_enumdef_numvals(const upb_enumdef *e) {
return upb_strtable_count(&e->ntoi);
}
void upb_enum_begin(upb_enum_iter *i, const upb_enumdef *e) {
// We iterate over the ntoi table, to account for duplicate numbers.
upb_strtable_begin(i, &e->ntoi);
}
void upb_enum_next(upb_enum_iter *iter) { upb_strtable_next(iter); }
bool upb_enum_done(upb_enum_iter *iter) { return upb_strtable_done(iter); }
bool upb_enumdef_ntoi(const upb_enumdef *def, const char *name,
size_t len, int32_t *num) {
upb_value v;
if (!upb_strtable_lookup2(&def->ntoi, name, len, &v)) {
return false;
}
if (num) *num = upb_value_getint32(v);
return true;
}
const char *upb_enumdef_iton(const upb_enumdef *def, int32_t num) {
upb_value v;
return upb_inttable_lookup32(&def->iton, num, &v) ?
upb_value_getcstr(v) : NULL;
}
const char *upb_enum_iter_name(upb_enum_iter *iter) {
return upb_strtable_iter_key(iter);
}
int32_t upb_enum_iter_number(upb_enum_iter *iter) {
return upb_value_getint32(upb_strtable_iter_value(iter));
}
/* upb_fielddef ***************************************************************/
static void upb_fielddef_init_default(upb_fielddef *f);
static void upb_fielddef_uninit_default(upb_fielddef *f) {
if (f->type_is_set_ && f->default_is_string && f->defaultval.bytes)
freestr(f->defaultval.bytes);
}
static void visitfield(const upb_refcounted *r, upb_refcounted_visit *visit,
void *closure) {
const upb_fielddef *f = (const upb_fielddef*)r;
if (upb_fielddef_containingtype(f)) {
visit(r, UPB_UPCAST2(upb_fielddef_containingtype(f)), closure);
}
Support oneofs in MRI Ruby C extension.
10 years ago
if (upb_fielddef_containingoneof(f)) {
visit(r, UPB_UPCAST2(upb_fielddef_containingoneof(f)), closure);
}
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
if (upb_fielddef_subdef(f)) {
visit(r, UPB_UPCAST(upb_fielddef_subdef(f)), closure);
}
}
static void freefield(upb_refcounted *r) {
upb_fielddef *f = (upb_fielddef*)r;
upb_fielddef_uninit_default(f);
if (f->subdef_is_symbolic)
free(f->sub.name);
upb_def_uninit(UPB_UPCAST(f));
free(f);
}
static const char *enumdefaultstr(const upb_fielddef *f) {
assert(f->type_is_set_ && f->type_ == UPB_TYPE_ENUM);
const upb_enumdef *e = upb_fielddef_enumsubdef(f);
if (f->default_is_string && f->defaultval.bytes) {
// Default was explicitly set as a string.
str_t *s = f->defaultval.bytes;
return s->str;
} else if (e) {
if (!f->default_is_string) {
// Default was explicitly set as an integer; look it up in enumdef.
const char *name = upb_enumdef_iton(e, f->defaultval.sint);
if (name) {
return name;
}
} else {
// Default is completely unset; pull enumdef default.
if (upb_enumdef_numvals(e) > 0) {
const char *name = upb_enumdef_iton(e, upb_enumdef_default(e));
assert(name);
return name;
}
}
}
return NULL;
}
static bool enumdefaultint32(const upb_fielddef *f, int32_t *val) {
assert(f->type_is_set_ && f->type_ == UPB_TYPE_ENUM);
const upb_enumdef *e = upb_fielddef_enumsubdef(f);
if (!f->default_is_string) {
// Default was explicitly set as an integer.
*val = f->defaultval.sint;
return true;
} else if (e) {
if (f->defaultval.bytes) {
// Default was explicitly set as a str; try to lookup corresponding int.
str_t *s = f->defaultval.bytes;
if (upb_enumdef_ntoiz(e, s->str, val)) {
return true;
}
} else {
// Default is unset; try to pull in enumdef default.
if (upb_enumdef_numvals(e) > 0) {
*val = upb_enumdef_default(e);
return true;
}
}
}
return false;
}
upb_fielddef *upb_fielddef_new(const void *owner) {
static const struct upb_refcounted_vtbl vtbl = {visitfield, freefield};
upb_fielddef *f = malloc(sizeof(*f));
if (!f) return NULL;
if (!upb_def_init(UPB_UPCAST(f), UPB_DEF_FIELD, &vtbl, owner)) {
free(f);
return NULL;
}
f->msg.def = NULL;
f->sub.def = NULL;
Support oneofs in MRI Ruby C extension.
10 years ago
f->oneof = NULL;
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
f->subdef_is_symbolic = false;
f->msg_is_symbolic = false;
f->label_ = UPB_LABEL_OPTIONAL;
f->type_ = UPB_TYPE_INT32;
f->number_ = 0;
f->type_is_set_ = false;
f->tagdelim = false;
f->is_extension_ = false;
f->lazy_ = false;
f->packed_ = true;
// For the moment we default this to UPB_INTFMT_VARIABLE, since it will work
// with all integer types and is in some since more "default" since the most
// normal-looking proto2 types int32/int64/uint32/uint64 use variable.
//
// Other options to consider:
// - there is no default; users must set this manually (like type).
// - default signed integers to UPB_INTFMT_ZIGZAG, since it's more likely to
// be an optimal default for signed integers.
f->intfmt = UPB_INTFMT_VARIABLE;
return f;
}
upb_fielddef *upb_fielddef_dup(const upb_fielddef *f, const void *owner) {
upb_fielddef *newf = upb_fielddef_new(owner);
if (!newf) return NULL;
upb_fielddef_settype(newf, upb_fielddef_type(f));
upb_fielddef_setlabel(newf, upb_fielddef_label(f));
upb_fielddef_setnumber(newf, upb_fielddef_number(f), NULL);
upb_fielddef_setname(newf, upb_fielddef_name(f), NULL);
if (f->default_is_string && f->defaultval.bytes) {
str_t *s = f->defaultval.bytes;
upb_fielddef_setdefaultstr(newf, s->str, s->len, NULL);
} else {
newf->default_is_string = f->default_is_string;
newf->defaultval = f->defaultval;
}
const char *srcname;
if (f->subdef_is_symbolic) {
srcname = f->sub.name; // Might be NULL.
} else {
srcname = f->sub.def ? upb_def_fullname(f->sub.def) : NULL;
}
if (srcname) {
char *newname = malloc(strlen(f->sub.def->fullname) + 2);
if (!newname) {
upb_fielddef_unref(newf, owner);
return NULL;
}
strcpy(newname, ".");
strcat(newname, f->sub.def->fullname);
upb_fielddef_setsubdefname(newf, newname, NULL);
free(newname);
}
return newf;
}
bool upb_fielddef_isfrozen(const upb_fielddef *f) {
return upb_def_isfrozen(UPB_UPCAST(f));
}
void upb_fielddef_ref(const upb_fielddef *f, const void *owner) {
upb_def_ref(UPB_UPCAST(f), owner);
}
void upb_fielddef_unref(const upb_fielddef *f, const void *owner) {
upb_def_unref(UPB_UPCAST(f), owner);
}
void upb_fielddef_donateref(
const upb_fielddef *f, const void *from, const void *to) {
upb_def_donateref(UPB_UPCAST(f), from, to);
}
void upb_fielddef_checkref(const upb_fielddef *f, const void *owner) {
upb_def_checkref(UPB_UPCAST(f), owner);
}
bool upb_fielddef_typeisset(const upb_fielddef *f) {
return f->type_is_set_;
}
upb_fieldtype_t upb_fielddef_type(const upb_fielddef *f) {
assert(f->type_is_set_);
return f->type_;
}
uint32_t upb_fielddef_index(const upb_fielddef *f) {
return f->index_;
}
upb_label_t upb_fielddef_label(const upb_fielddef *f) {
return f->label_;
}
upb_intfmt_t upb_fielddef_intfmt(const upb_fielddef *f) {
return f->intfmt;
}
bool upb_fielddef_istagdelim(const upb_fielddef *f) {
return f->tagdelim;
}
uint32_t upb_fielddef_number(const upb_fielddef *f) {
return f->number_;
}
bool upb_fielddef_isextension(const upb_fielddef *f) {
return f->is_extension_;
}
bool upb_fielddef_lazy(const upb_fielddef *f) {
return f->lazy_;
}
bool upb_fielddef_packed(const upb_fielddef *f) {
return f->packed_;
}
const char *upb_fielddef_name(const upb_fielddef *f) {
return upb_def_fullname(UPB_UPCAST(f));
}
const upb_msgdef *upb_fielddef_containingtype(const upb_fielddef *f) {
return f->msg_is_symbolic ? NULL : f->msg.def;
}
Support oneofs in MRI Ruby C extension.
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const upb_oneofdef *upb_fielddef_containingoneof(const upb_fielddef *f) {
return f->oneof;
}
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
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upb_msgdef *upb_fielddef_containingtype_mutable(upb_fielddef *f) {
return (upb_msgdef*)upb_fielddef_containingtype(f);
}
const char *upb_fielddef_containingtypename(upb_fielddef *f) {
return f->msg_is_symbolic ? f->msg.name : NULL;
}
static void release_containingtype(upb_fielddef *f) {
if (f->msg_is_symbolic) free(f->msg.name);
}
bool upb_fielddef_setcontainingtypename(upb_fielddef *f, const char *name,
upb_status *s) {
assert(!upb_fielddef_isfrozen(f));
if (upb_fielddef_containingtype(f)) {
upb_status_seterrmsg(s, "field has already been added to a message.");
return false;
}
// TODO: validate name (upb_isident() doesn't quite work atm because this name
// may have a leading ".").
release_containingtype(f);
f->msg.name = upb_strdup(name);
f->msg_is_symbolic = true;
return true;
}
bool upb_fielddef_setname(upb_fielddef *f, const char *name, upb_status *s) {
Support oneofs in MRI Ruby C extension.
10 years ago
if (upb_fielddef_containingtype(f) || upb_fielddef_containingoneof(f)) {
upb_status_seterrmsg(s, "Already added to message or oneof");
return false;
}
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
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return upb_def_setfullname(UPB_UPCAST(f), name, s);
}
static void chkdefaulttype(const upb_fielddef *f, upb_fieldtype_t type) {
UPB_UNUSED(f);
UPB_UNUSED(type);
assert(f->type_is_set_ && upb_fielddef_type(f) == type);
}
int64_t upb_fielddef_defaultint64(const upb_fielddef *f) {
chkdefaulttype(f, UPB_TYPE_INT64);
return f->defaultval.sint;
}
int32_t upb_fielddef_defaultint32(const upb_fielddef *f) {
if (f->type_is_set_ && upb_fielddef_type(f) == UPB_TYPE_ENUM) {
int32_t val;
bool ok = enumdefaultint32(f, &val);
UPB_ASSERT_VAR(ok, ok);
return val;
} else {
chkdefaulttype(f, UPB_TYPE_INT32);
return f->defaultval.sint;
}
}
uint64_t upb_fielddef_defaultuint64(const upb_fielddef *f) {
chkdefaulttype(f, UPB_TYPE_UINT64);
return f->defaultval.uint;
}
uint32_t upb_fielddef_defaultuint32(const upb_fielddef *f) {
chkdefaulttype(f, UPB_TYPE_UINT32);
return f->defaultval.uint;
}
bool upb_fielddef_defaultbool(const upb_fielddef *f) {
chkdefaulttype(f, UPB_TYPE_BOOL);
return f->defaultval.uint;
}
float upb_fielddef_defaultfloat(const upb_fielddef *f) {
chkdefaulttype(f, UPB_TYPE_FLOAT);
return f->defaultval.flt;
}
double upb_fielddef_defaultdouble(const upb_fielddef *f) {
chkdefaulttype(f, UPB_TYPE_DOUBLE);
return f->defaultval.dbl;
}
const char *upb_fielddef_defaultstr(const upb_fielddef *f, size_t *len) {
assert(f->type_is_set_);
assert(upb_fielddef_type(f) == UPB_TYPE_STRING ||
upb_fielddef_type(f) == UPB_TYPE_BYTES ||
upb_fielddef_type(f) == UPB_TYPE_ENUM);
if (upb_fielddef_type(f) == UPB_TYPE_ENUM) {
const char *ret = enumdefaultstr(f);
assert(ret);
// Enum defaults can't have embedded NULLs.
if (len) *len = strlen(ret);
return ret;
}
if (f->default_is_string) {
str_t *str = f->defaultval.bytes;
if (len) *len = str->len;
return str->str;
}
return NULL;
}
static void upb_fielddef_init_default(upb_fielddef *f) {
f->default_is_string = false;
switch (upb_fielddef_type(f)) {
case UPB_TYPE_DOUBLE: f->defaultval.dbl = 0; break;
case UPB_TYPE_FLOAT: f->defaultval.flt = 0; break;
case UPB_TYPE_INT32:
case UPB_TYPE_INT64: f->defaultval.sint = 0; break;
case UPB_TYPE_UINT64:
case UPB_TYPE_UINT32:
case UPB_TYPE_BOOL: f->defaultval.uint = 0; break;
case UPB_TYPE_STRING:
case UPB_TYPE_BYTES:
f->defaultval.bytes = newstr("", 0);
f->default_is_string = true;
break;
case UPB_TYPE_MESSAGE: break;
case UPB_TYPE_ENUM:
// This is our special sentinel that indicates "not set" for an enum.
f->default_is_string = true;
f->defaultval.bytes = NULL;
break;
}
}
const upb_def *upb_fielddef_subdef(const upb_fielddef *f) {
return f->subdef_is_symbolic ? NULL : f->sub.def;
}
const upb_msgdef *upb_fielddef_msgsubdef(const upb_fielddef *f) {
const upb_def *def = upb_fielddef_subdef(f);
return def ? upb_dyncast_msgdef(def) : NULL;
}
const upb_enumdef *upb_fielddef_enumsubdef(const upb_fielddef *f) {
const upb_def *def = upb_fielddef_subdef(f);
return def ? upb_dyncast_enumdef(def) : NULL;
}
upb_def *upb_fielddef_subdef_mutable(upb_fielddef *f) {
return (upb_def*)upb_fielddef_subdef(f);
}
const char *upb_fielddef_subdefname(const upb_fielddef *f) {
if (f->subdef_is_symbolic) {
return f->sub.name;
} else if (f->sub.def) {
return upb_def_fullname(f->sub.def);
} else {
return NULL;
}
}
bool upb_fielddef_setnumber(upb_fielddef *f, uint32_t number, upb_status *s) {
if (upb_fielddef_containingtype(f)) {
upb_status_seterrmsg(
s, "cannot change field number after adding to a message");
return false;
}
if (number == 0 || number > UPB_MAX_FIELDNUMBER) {
upb_status_seterrf(s, "invalid field number (%u)", number);
return false;
}
f->number_ = number;
return true;
}
void upb_fielddef_settype(upb_fielddef *f, upb_fieldtype_t type) {
assert(!upb_fielddef_isfrozen(f));
assert(upb_fielddef_checktype(type));
upb_fielddef_uninit_default(f);
f->type_ = type;
f->type_is_set_ = true;
upb_fielddef_init_default(f);
}
void upb_fielddef_setdescriptortype(upb_fielddef *f, int type) {
assert(!upb_fielddef_isfrozen(f));
switch (type) {
case UPB_DESCRIPTOR_TYPE_DOUBLE:
upb_fielddef_settype(f, UPB_TYPE_DOUBLE);
break;
case UPB_DESCRIPTOR_TYPE_FLOAT:
upb_fielddef_settype(f, UPB_TYPE_FLOAT);
break;
case UPB_DESCRIPTOR_TYPE_INT64:
case UPB_DESCRIPTOR_TYPE_SFIXED64:
case UPB_DESCRIPTOR_TYPE_SINT64:
upb_fielddef_settype(f, UPB_TYPE_INT64);
break;
case UPB_DESCRIPTOR_TYPE_UINT64:
case UPB_DESCRIPTOR_TYPE_FIXED64:
upb_fielddef_settype(f, UPB_TYPE_UINT64);
break;
case UPB_DESCRIPTOR_TYPE_INT32:
case UPB_DESCRIPTOR_TYPE_SFIXED32:
case UPB_DESCRIPTOR_TYPE_SINT32:
upb_fielddef_settype(f, UPB_TYPE_INT32);
break;
case UPB_DESCRIPTOR_TYPE_UINT32:
case UPB_DESCRIPTOR_TYPE_FIXED32:
upb_fielddef_settype(f, UPB_TYPE_UINT32);
break;
case UPB_DESCRIPTOR_TYPE_BOOL:
upb_fielddef_settype(f, UPB_TYPE_BOOL);
break;
case UPB_DESCRIPTOR_TYPE_STRING:
upb_fielddef_settype(f, UPB_TYPE_STRING);
break;
case UPB_DESCRIPTOR_TYPE_BYTES:
upb_fielddef_settype(f, UPB_TYPE_BYTES);
break;
case UPB_DESCRIPTOR_TYPE_GROUP:
case UPB_DESCRIPTOR_TYPE_MESSAGE:
upb_fielddef_settype(f, UPB_TYPE_MESSAGE);
break;
case UPB_DESCRIPTOR_TYPE_ENUM:
upb_fielddef_settype(f, UPB_TYPE_ENUM);
break;
default: assert(false);
}
if (type == UPB_DESCRIPTOR_TYPE_FIXED64 ||
type == UPB_DESCRIPTOR_TYPE_FIXED32 ||
type == UPB_DESCRIPTOR_TYPE_SFIXED64 ||
type == UPB_DESCRIPTOR_TYPE_SFIXED32) {
upb_fielddef_setintfmt(f, UPB_INTFMT_FIXED);
} else if (type == UPB_DESCRIPTOR_TYPE_SINT64 ||
type == UPB_DESCRIPTOR_TYPE_SINT32) {
upb_fielddef_setintfmt(f, UPB_INTFMT_ZIGZAG);
} else {
upb_fielddef_setintfmt(f, UPB_INTFMT_VARIABLE);
}
upb_fielddef_settagdelim(f, type == UPB_DESCRIPTOR_TYPE_GROUP);
}
upb_descriptortype_t upb_fielddef_descriptortype(const upb_fielddef *f) {
switch (upb_fielddef_type(f)) {
case UPB_TYPE_FLOAT: return UPB_DESCRIPTOR_TYPE_FLOAT;
case UPB_TYPE_DOUBLE: return UPB_DESCRIPTOR_TYPE_DOUBLE;
case UPB_TYPE_BOOL: return UPB_DESCRIPTOR_TYPE_BOOL;
case UPB_TYPE_STRING: return UPB_DESCRIPTOR_TYPE_STRING;
case UPB_TYPE_BYTES: return UPB_DESCRIPTOR_TYPE_BYTES;
case UPB_TYPE_ENUM: return UPB_DESCRIPTOR_TYPE_ENUM;
case UPB_TYPE_INT32:
switch (upb_fielddef_intfmt(f)) {
case UPB_INTFMT_VARIABLE: return UPB_DESCRIPTOR_TYPE_INT32;
case UPB_INTFMT_FIXED: return UPB_DESCRIPTOR_TYPE_SFIXED32;
case UPB_INTFMT_ZIGZAG: return UPB_DESCRIPTOR_TYPE_SINT32;
}
case UPB_TYPE_INT64:
switch (upb_fielddef_intfmt(f)) {
case UPB_INTFMT_VARIABLE: return UPB_DESCRIPTOR_TYPE_INT64;
case UPB_INTFMT_FIXED: return UPB_DESCRIPTOR_TYPE_SFIXED64;
case UPB_INTFMT_ZIGZAG: return UPB_DESCRIPTOR_TYPE_SINT64;
}
case UPB_TYPE_UINT32:
switch (upb_fielddef_intfmt(f)) {
case UPB_INTFMT_VARIABLE: return UPB_DESCRIPTOR_TYPE_UINT32;
case UPB_INTFMT_FIXED: return UPB_DESCRIPTOR_TYPE_FIXED32;
case UPB_INTFMT_ZIGZAG: return -1;
}
case UPB_TYPE_UINT64:
switch (upb_fielddef_intfmt(f)) {
case UPB_INTFMT_VARIABLE: return UPB_DESCRIPTOR_TYPE_UINT64;
case UPB_INTFMT_FIXED: return UPB_DESCRIPTOR_TYPE_FIXED64;
case UPB_INTFMT_ZIGZAG: return -1;
}
case UPB_TYPE_MESSAGE:
return upb_fielddef_istagdelim(f) ?
UPB_DESCRIPTOR_TYPE_GROUP : UPB_DESCRIPTOR_TYPE_MESSAGE;
}
return 0;
}
void upb_fielddef_setisextension(upb_fielddef *f, bool is_extension) {
assert(!upb_fielddef_isfrozen(f));
f->is_extension_ = is_extension;
}
void upb_fielddef_setlazy(upb_fielddef *f, bool lazy) {
assert(!upb_fielddef_isfrozen(f));
f->lazy_ = lazy;
}
void upb_fielddef_setpacked(upb_fielddef *f, bool packed) {
assert(!upb_fielddef_isfrozen(f));
f->packed_ = packed;
}
void upb_fielddef_setlabel(upb_fielddef *f, upb_label_t label) {
assert(!upb_fielddef_isfrozen(f));
assert(upb_fielddef_checklabel(label));
f->label_ = label;
}
void upb_fielddef_setintfmt(upb_fielddef *f, upb_intfmt_t fmt) {
assert(!upb_fielddef_isfrozen(f));
assert(upb_fielddef_checkintfmt(fmt));
f->intfmt = fmt;
}
void upb_fielddef_settagdelim(upb_fielddef *f, bool tag_delim) {
assert(!upb_fielddef_isfrozen(f));
f->tagdelim = tag_delim;
f->tagdelim = tag_delim;
}
static bool checksetdefault(upb_fielddef *f, upb_fieldtype_t type) {
if (!f->type_is_set_ || upb_fielddef_isfrozen(f) ||
upb_fielddef_type(f) != type) {
assert(false);
return false;
}
if (f->default_is_string) {
str_t *s = f->defaultval.bytes;
assert(s || type == UPB_TYPE_ENUM);
if (s) freestr(s);
}
f->default_is_string = false;
return true;
}
void upb_fielddef_setdefaultint64(upb_fielddef *f, int64_t value) {
if (checksetdefault(f, UPB_TYPE_INT64))
f->defaultval.sint = value;
}
void upb_fielddef_setdefaultint32(upb_fielddef *f, int32_t value) {
if ((upb_fielddef_type(f) == UPB_TYPE_ENUM &&
checksetdefault(f, UPB_TYPE_ENUM)) ||
checksetdefault(f, UPB_TYPE_INT32)) {
f->defaultval.sint = value;
}
}
void upb_fielddef_setdefaultuint64(upb_fielddef *f, uint64_t value) {
if (checksetdefault(f, UPB_TYPE_UINT64))
f->defaultval.uint = value;
}
void upb_fielddef_setdefaultuint32(upb_fielddef *f, uint32_t value) {
if (checksetdefault(f, UPB_TYPE_UINT32))
f->defaultval.uint = value;
}
void upb_fielddef_setdefaultbool(upb_fielddef *f, bool value) {
if (checksetdefault(f, UPB_TYPE_BOOL))
f->defaultval.uint = value;
}
void upb_fielddef_setdefaultfloat(upb_fielddef *f, float value) {
if (checksetdefault(f, UPB_TYPE_FLOAT))
f->defaultval.flt = value;
}
void upb_fielddef_setdefaultdouble(upb_fielddef *f, double value) {
if (checksetdefault(f, UPB_TYPE_DOUBLE))
f->defaultval.dbl = value;
}
bool upb_fielddef_setdefaultstr(upb_fielddef *f, const void *str, size_t len,
upb_status *s) {
assert(upb_fielddef_isstring(f) || f->type_ == UPB_TYPE_ENUM);
if (f->type_ == UPB_TYPE_ENUM && !upb_isident(str, len, false, s))
return false;
if (f->default_is_string) {
str_t *s = f->defaultval.bytes;
assert(s || f->type_ == UPB_TYPE_ENUM);
if (s) freestr(s);
} else {
assert(f->type_ == UPB_TYPE_ENUM);
}
str_t *str2 = newstr(str, len);
f->defaultval.bytes = str2;
f->default_is_string = true;
return true;
}
void upb_fielddef_setdefaultcstr(upb_fielddef *f, const char *str,
upb_status *s) {
assert(f->type_is_set_);
upb_fielddef_setdefaultstr(f, str, str ? strlen(str) : 0, s);
}
bool upb_fielddef_enumhasdefaultint32(const upb_fielddef *f) {
assert(f->type_is_set_ && f->type_ == UPB_TYPE_ENUM);
int32_t val;
return enumdefaultint32(f, &val);
}
bool upb_fielddef_enumhasdefaultstr(const upb_fielddef *f) {
assert(f->type_is_set_ && f->type_ == UPB_TYPE_ENUM);
return enumdefaultstr(f) != NULL;
}
static bool upb_subdef_typecheck(upb_fielddef *f, const upb_def *subdef,
upb_status *s) {
if (f->type_ == UPB_TYPE_MESSAGE) {
if (upb_dyncast_msgdef(subdef)) return true;
upb_status_seterrmsg(s, "invalid subdef type for this submessage field");
return false;
} else if (f->type_ == UPB_TYPE_ENUM) {
if (upb_dyncast_enumdef(subdef)) return true;
upb_status_seterrmsg(s, "invalid subdef type for this enum field");
return false;
} else {
upb_status_seterrmsg(s, "only message and enum fields can have a subdef");
return false;
}
}
static void release_subdef(upb_fielddef *f) {
if (f->subdef_is_symbolic) {
free(f->sub.name);
} else if (f->sub.def) {
upb_unref2(f->sub.def, f);
}
}
bool upb_fielddef_setsubdef(upb_fielddef *f, const upb_def *subdef,
upb_status *s) {
assert(!upb_fielddef_isfrozen(f));
assert(upb_fielddef_hassubdef(f));
if (subdef && !upb_subdef_typecheck(f, subdef, s)) return false;
release_subdef(f);
f->sub.def = subdef;
f->subdef_is_symbolic = false;
if (f->sub.def) upb_ref2(f->sub.def, f);
return true;
}
bool upb_fielddef_setmsgsubdef(upb_fielddef *f, const upb_msgdef *subdef,
upb_status *s) {
return upb_fielddef_setsubdef(f, UPB_UPCAST(subdef), s);
}
bool upb_fielddef_setenumsubdef(upb_fielddef *f, const upb_enumdef *subdef,
upb_status *s) {
return upb_fielddef_setsubdef(f, UPB_UPCAST(subdef), s);
}
bool upb_fielddef_setsubdefname(upb_fielddef *f, const char *name,
upb_status *s) {
assert(!upb_fielddef_isfrozen(f));
if (!upb_fielddef_hassubdef(f)) {
upb_status_seterrmsg(s, "field type does not accept a subdef");
return false;
}
// TODO: validate name (upb_isident() doesn't quite work atm because this name
// may have a leading ".").
release_subdef(f);
f->sub.name = upb_strdup(name);
f->subdef_is_symbolic = true;
return true;
}
bool upb_fielddef_issubmsg(const upb_fielddef *f) {
return upb_fielddef_type(f) == UPB_TYPE_MESSAGE;
}
bool upb_fielddef_isstring(const upb_fielddef *f) {
return upb_fielddef_type(f) == UPB_TYPE_STRING ||
upb_fielddef_type(f) == UPB_TYPE_BYTES;
}
bool upb_fielddef_isseq(const upb_fielddef *f) {
return upb_fielddef_label(f) == UPB_LABEL_REPEATED;
}
bool upb_fielddef_isprimitive(const upb_fielddef *f) {
return !upb_fielddef_isstring(f) && !upb_fielddef_issubmsg(f);
}
bool upb_fielddef_hassubdef(const upb_fielddef *f) {
return upb_fielddef_issubmsg(f) || upb_fielddef_type(f) == UPB_TYPE_ENUM;
}
static bool between(int32_t x, int32_t low, int32_t high) {
return x >= low && x <= high;
}
bool upb_fielddef_checklabel(int32_t label) { return between(label, 1, 3); }
bool upb_fielddef_checktype(int32_t type) { return between(type, 1, 11); }
bool upb_fielddef_checkintfmt(int32_t fmt) { return between(fmt, 1, 3); }
bool upb_fielddef_checkdescriptortype(int32_t type) {
return between(type, 1, 18);
}
/* upb_msgdef *****************************************************************/
static void visitmsg(const upb_refcounted *r, upb_refcounted_visit *visit,
void *closure) {
const upb_msgdef *m = (const upb_msgdef*)r;
Support oneofs in MRI Ruby C extension.
10 years ago
upb_msg_field_iter i;
for(upb_msg_field_begin(&i, m);
!upb_msg_field_done(&i);
upb_msg_field_next(&i)) {
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
upb_fielddef *f = upb_msg_iter_field(&i);
visit(r, UPB_UPCAST2(f), closure);
}
Support oneofs in MRI Ruby C extension.
10 years ago
upb_msg_oneof_iter o;
for(upb_msg_oneof_begin(&o, m);
!upb_msg_oneof_done(&o);
upb_msg_oneof_next(&o)) {
upb_oneofdef *f = upb_msg_iter_oneof(&o);
visit(r, UPB_UPCAST2(f), closure);
}
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
}
static void freemsg(upb_refcounted *r) {
upb_msgdef *m = (upb_msgdef*)r;
Support oneofs in MRI Ruby C extension.
10 years ago
upb_strtable_uninit(&m->ntoo);
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
upb_strtable_uninit(&m->ntof);
upb_inttable_uninit(&m->itof);
upb_def_uninit(UPB_UPCAST(m));
free(m);
}
upb_msgdef *upb_msgdef_new(const void *owner) {
static const struct upb_refcounted_vtbl vtbl = {visitmsg, freemsg};
upb_msgdef *m = malloc(sizeof(*m));
if (!m) return NULL;
if (!upb_def_init(UPB_UPCAST(m), UPB_DEF_MSG, &vtbl, owner)) goto err2;
Support oneofs in MRI Ruby C extension.
10 years ago
if (!upb_inttable_init(&m->itof, UPB_CTYPE_PTR)) goto err3;
if (!upb_strtable_init(&m->ntof, UPB_CTYPE_PTR)) goto err2;
if (!upb_strtable_init(&m->ntoo, UPB_CTYPE_PTR)) goto err1;
Support for maps in the MRI C Ruby extension. This adds the Map container and support for parsing and serializing maps in the protobuf wire format (as defined by the C++ implementation, with MapEntry submessages in a repeated field). JSON map serialization/parsing are not yet supported as these will require some changes to upb as well.
10 years ago
m->map_entry = false;
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
return m;
err1:
Support oneofs in MRI Ruby C extension.
10 years ago
upb_strtable_uninit(&m->ntof);
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
err2:
Support oneofs in MRI Ruby C extension.
10 years ago
upb_inttable_uninit(&m->itof);
err3:
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
free(m);
return NULL;
}
upb_msgdef *upb_msgdef_dup(const upb_msgdef *m, const void *owner) {
upb_msgdef *newm = upb_msgdef_new(owner);
if (!newm) return NULL;
bool ok = upb_def_setfullname(UPB_UPCAST(newm),
upb_def_fullname(UPB_UPCAST(m)), NULL);
Support for maps in the MRI C Ruby extension. This adds the Map container and support for parsing and serializing maps in the protobuf wire format (as defined by the C++ implementation, with MapEntry submessages in a repeated field). JSON map serialization/parsing are not yet supported as these will require some changes to upb as well.
10 years ago
newm->map_entry = m->map_entry;
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
UPB_ASSERT_VAR(ok, ok);
Support oneofs in MRI Ruby C extension.
10 years ago
upb_msg_field_iter i;
for(upb_msg_field_begin(&i, m);
!upb_msg_field_done(&i);
upb_msg_field_next(&i)) {
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
upb_fielddef *f = upb_fielddef_dup(upb_msg_iter_field(&i), &f);
Support oneofs in MRI Ruby C extension.
10 years ago
// Fields in oneofs are dup'd below.
if (upb_fielddef_containingoneof(f)) continue;
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
if (!f || !upb_msgdef_addfield(newm, f, &f, NULL)) {
upb_msgdef_unref(newm, owner);
return NULL;
}
}
Support oneofs in MRI Ruby C extension.
10 years ago
upb_msg_oneof_iter o;
for(upb_msg_oneof_begin(&o, m);
!upb_msg_oneof_done(&o);
upb_msg_oneof_next(&o)) {
upb_oneofdef *f = upb_oneofdef_dup(upb_msg_iter_oneof(&o), &f);
if (!f || !upb_msgdef_addoneof(newm, f, &f, NULL)) {
upb_msgdef_unref(newm, owner);
return NULL;
}
}
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
return newm;
}
bool upb_msgdef_isfrozen(const upb_msgdef *m) {
return upb_def_isfrozen(UPB_UPCAST(m));
}
void upb_msgdef_ref(const upb_msgdef *m, const void *owner) {
upb_def_ref(UPB_UPCAST(m), owner);
}
void upb_msgdef_unref(const upb_msgdef *m, const void *owner) {
upb_def_unref(UPB_UPCAST(m), owner);
}
void upb_msgdef_donateref(
const upb_msgdef *m, const void *from, const void *to) {
upb_def_donateref(UPB_UPCAST(m), from, to);
}
void upb_msgdef_checkref(const upb_msgdef *m, const void *owner) {
upb_def_checkref(UPB_UPCAST(m), owner);
}
bool upb_msgdef_freeze(upb_msgdef *m, upb_status *status) {
upb_def *d = UPB_UPCAST(m);
return upb_def_freeze(&d, 1, status);
}
const char *upb_msgdef_fullname(const upb_msgdef *m) {
return upb_def_fullname(UPB_UPCAST(m));
}
bool upb_msgdef_setfullname(upb_msgdef *m, const char *fullname,
upb_status *s) {
return upb_def_setfullname(UPB_UPCAST(m), fullname, s);
}
Support oneofs in MRI Ruby C extension.
10 years ago
// Helper: check that the field |f| is safe to add to msgdef |m|. Set an error
// on status |s| and return false if not.
static bool check_field_add(const upb_msgdef *m, const upb_fielddef *f,
upb_status *s) {
if (upb_fielddef_containingtype(f) != NULL) {
upb_status_seterrmsg(s, "fielddef already belongs to a message");
return false;
} else if (upb_fielddef_name(f) == NULL || upb_fielddef_number(f) == 0) {
upb_status_seterrmsg(s, "field name or number were not set");
return false;
} else if (upb_msgdef_ntofz(m, upb_fielddef_name(f)) ||
upb_msgdef_itof(m, upb_fielddef_number(f))) {
upb_status_seterrmsg(s, "duplicate field name or number for field");
return false;
}
return true;
}
static void add_field(upb_msgdef *m, upb_fielddef *f, const void *ref_donor) {
release_containingtype(f);
f->msg.def = m;
f->msg_is_symbolic = false;
upb_inttable_insert(&m->itof, upb_fielddef_number(f), upb_value_ptr(f));
upb_strtable_insert(&m->ntof, upb_fielddef_name(f), upb_value_ptr(f));
upb_ref2(f, m);
upb_ref2(m, f);
if (ref_donor) upb_fielddef_unref(f, ref_donor);
}
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
bool upb_msgdef_addfield(upb_msgdef *m, upb_fielddef *f, const void *ref_donor,
upb_status *s) {
// TODO: extensions need to have a separate namespace, because proto2 allows a
// top-level extension (ie. one not in any package) to have the same name as a
// field from the message.
//
// This also implies that there needs to be a separate lookup-by-name method
// for extensions. It seems desirable for iteration to return both extensions
// and non-extensions though.
//
// We also need to validate that the field number is in an extension range iff
// it is an extension.
Support oneofs in MRI Ruby C extension.
10 years ago
// This method is idempotent. Check if |f| is already part of this msgdef and
// return immediately if so.
if (upb_fielddef_containingtype(f) == m) {
return true;
}
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
// Check constraints for all fields before performing any action.
Support oneofs in MRI Ruby C extension.
10 years ago
if (!check_field_add(m, f, s)) {
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
return false;
Support oneofs in MRI Ruby C extension.
10 years ago
} else if (upb_fielddef_containingoneof(f) != NULL) {
// Fields in a oneof can only be added by adding the oneof to the msgdef.
upb_status_seterrmsg(s, "fielddef is part of a oneof");
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
return false;
}
// Constraint checks ok, perform the action.
Support oneofs in MRI Ruby C extension.
10 years ago
add_field(m, f, ref_donor);
return true;
}
bool upb_msgdef_addoneof(upb_msgdef *m, upb_oneofdef *o, const void *ref_donor,
upb_status *s) {
// Check various conditions that would prevent this oneof from being added.
if (upb_oneofdef_containingtype(o)) {
upb_status_seterrmsg(s, "oneofdef already belongs to a message");
return false;
} else if (upb_oneofdef_name(o) == NULL) {
upb_status_seterrmsg(s, "oneofdef name was not set");
return false;
} else if (upb_msgdef_ntooz(m, upb_oneofdef_name(o))) {
upb_status_seterrmsg(s, "duplicate oneof name");
return false;
}
// Check that all of the oneof's fields do not conflict with names or numbers
// of fields already in the message.
upb_oneof_iter it;
for (upb_oneof_begin(&it, o); !upb_oneof_done(&it); upb_oneof_next(&it)) {
const upb_fielddef *f = upb_oneof_iter_field(&it);
if (!check_field_add(m, f, s)) {
return false;
}
}
// Everything checks out -- commit now.
// Add oneof itself first.
o->parent = m;
upb_strtable_insert(&m->ntoo, upb_oneofdef_name(o), upb_value_ptr(o));
upb_ref2(o, m);
upb_ref2(m, o);
// Add each field of the oneof directly to the msgdef.
for (upb_oneof_begin(&it, o); !upb_oneof_done(&it); upb_oneof_next(&it)) {
upb_fielddef *f = upb_oneof_iter_field(&it);
add_field(m, f, NULL);
}
if (ref_donor) upb_oneofdef_unref(o, ref_donor);
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
return true;
}
const upb_fielddef *upb_msgdef_itof(const upb_msgdef *m, uint32_t i) {
upb_value val;
return upb_inttable_lookup32(&m->itof, i, &val) ?
upb_value_getptr(val) : NULL;
}
const upb_fielddef *upb_msgdef_ntof(const upb_msgdef *m, const char *name,
size_t len) {
upb_value val;
return upb_strtable_lookup2(&m->ntof, name, len, &val) ?
upb_value_getptr(val) : NULL;
}
Support oneofs in MRI Ruby C extension.
10 years ago
const upb_oneofdef *upb_msgdef_ntoo(const upb_msgdef *m, const char *name,
size_t len) {
upb_value val;
return upb_strtable_lookup2(&m->ntoo, name, len, &val) ?
upb_value_getptr(val) : NULL;
}
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
int upb_msgdef_numfields(const upb_msgdef *m) {
return upb_strtable_count(&m->ntof);
}
Support oneofs in MRI Ruby C extension.
10 years ago
int upb_msgdef_numoneofs(const upb_msgdef *m) {
return upb_strtable_count(&m->ntoo);
}
Support for maps in the MRI C Ruby extension. This adds the Map container and support for parsing and serializing maps in the protobuf wire format (as defined by the C++ implementation, with MapEntry submessages in a repeated field). JSON map serialization/parsing are not yet supported as these will require some changes to upb as well.
10 years ago
void upb_msgdef_setmapentry(upb_msgdef *m, bool map_entry) {
assert(!upb_msgdef_isfrozen(m));
m->map_entry = map_entry;
}
bool upb_msgdef_mapentry(const upb_msgdef *m) {
return m->map_entry;
}
Support oneofs in MRI Ruby C extension.
10 years ago
void upb_msg_field_begin(upb_msg_field_iter *iter, const upb_msgdef *m) {
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
upb_inttable_begin(iter, &m->itof);
}
Support oneofs in MRI Ruby C extension.
10 years ago
void upb_msg_field_next(upb_msg_field_iter *iter) { upb_inttable_next(iter); }
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
Support oneofs in MRI Ruby C extension.
10 years ago
bool upb_msg_field_done(const upb_msg_field_iter *iter) {
return upb_inttable_done(iter);
}
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
Support oneofs in MRI Ruby C extension.
10 years ago
upb_fielddef *upb_msg_iter_field(const upb_msg_field_iter *iter) {
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
return (upb_fielddef*)upb_value_getptr(upb_inttable_iter_value(iter));
}
Support oneofs in MRI Ruby C extension.
10 years ago
void upb_msg_field_iter_setdone(upb_msg_field_iter *iter) {
upb_inttable_iter_setdone(iter);
}
void upb_msg_oneof_begin(upb_msg_oneof_iter *iter, const upb_msgdef *m) {
upb_strtable_begin(iter, &m->ntoo);
}
void upb_msg_oneof_next(upb_msg_oneof_iter *iter) { upb_strtable_next(iter); }
bool upb_msg_oneof_done(const upb_msg_oneof_iter *iter) {
return upb_strtable_done(iter);
}
upb_oneofdef *upb_msg_iter_oneof(const upb_msg_oneof_iter *iter) {
return (upb_oneofdef*)upb_value_getptr(upb_strtable_iter_value(iter));
}
void upb_msg_oneof_iter_setdone(upb_msg_oneof_iter *iter) {
upb_strtable_iter_setdone(iter);
}
/* upb_oneofdef ***************************************************************/
static void visitoneof(const upb_refcounted *r, upb_refcounted_visit *visit,
void *closure) {
const upb_oneofdef *o = (const upb_oneofdef*)r;
upb_oneof_iter i;
for (upb_oneof_begin(&i, o); !upb_oneof_done(&i); upb_oneof_next(&i)) {
const upb_fielddef *f = upb_oneof_iter_field(&i);
visit(r, UPB_UPCAST2(f), closure);
}
if (o->parent) {
visit(r, UPB_UPCAST2(o->parent), closure);
}
}
static void freeoneof(upb_refcounted *r) {
upb_oneofdef *o = (upb_oneofdef*)r;
upb_strtable_uninit(&o->ntof);
upb_inttable_uninit(&o->itof);
upb_def_uninit(UPB_UPCAST(o));
free(o);
}
upb_oneofdef *upb_oneofdef_new(const void *owner) {
static const struct upb_refcounted_vtbl vtbl = {visitoneof, freeoneof};
upb_oneofdef *o = malloc(sizeof(*o));
o->parent = NULL;
if (!o) return NULL;
if (!upb_def_init(UPB_UPCAST(o), UPB_DEF_ONEOF, &vtbl, owner)) goto err2;
if (!upb_inttable_init(&o->itof, UPB_CTYPE_PTR)) goto err2;
if (!upb_strtable_init(&o->ntof, UPB_CTYPE_PTR)) goto err1;
return o;
err1:
upb_inttable_uninit(&o->itof);
err2:
free(o);
return NULL;
}
upb_oneofdef *upb_oneofdef_dup(const upb_oneofdef *o, const void *owner) {
upb_oneofdef *newo = upb_oneofdef_new(owner);
if (!newo) return NULL;
bool ok = upb_def_setfullname(UPB_UPCAST(newo),
upb_def_fullname(UPB_UPCAST(o)), NULL);
UPB_ASSERT_VAR(ok, ok);
upb_oneof_iter i;
for (upb_oneof_begin(&i, o); !upb_oneof_done(&i); upb_oneof_next(&i)) {
upb_fielddef *f = upb_fielddef_dup(upb_oneof_iter_field(&i), &f);
if (!f || !upb_oneofdef_addfield(newo, f, &f, NULL)) {
upb_oneofdef_unref(newo, owner);
return NULL;
}
}
return newo;
}
bool upb_oneofdef_isfrozen(const upb_oneofdef *o) {
return upb_def_isfrozen(UPB_UPCAST(o));
}
void upb_oneofdef_ref(const upb_oneofdef *o, const void *owner) {
upb_def_ref(UPB_UPCAST(o), owner);
}
void upb_oneofdef_unref(const upb_oneofdef *o, const void *owner) {
upb_def_unref(UPB_UPCAST(o), owner);
}
void upb_oneofdef_donateref(const upb_oneofdef *o, const void *from,
const void *to) {
upb_def_donateref(UPB_UPCAST(o), from, to);
}
void upb_oneofdef_checkref(const upb_oneofdef *o, const void *owner) {
upb_def_checkref(UPB_UPCAST(o), owner);
}
const char *upb_oneofdef_name(const upb_oneofdef *o) {
return upb_def_fullname(UPB_UPCAST(o));
}
bool upb_oneofdef_setname(upb_oneofdef *o, const char *fullname,
upb_status *s) {
if (upb_oneofdef_containingtype(o)) {
upb_status_seterrmsg(s, "oneof already added to a message");
return false;
}
return upb_def_setfullname(UPB_UPCAST(o), fullname, s);
}
const upb_msgdef *upb_oneofdef_containingtype(const upb_oneofdef *o) {
return o->parent;
}
int upb_oneofdef_numfields(const upb_oneofdef *o) {
return upb_strtable_count(&o->ntof);
}
bool upb_oneofdef_addfield(upb_oneofdef *o, upb_fielddef *f,
const void *ref_donor,
upb_status *s) {
assert(!upb_oneofdef_isfrozen(o));
assert(!o->parent || !upb_msgdef_isfrozen(o->parent));
// This method is idempotent. Check if |f| is already part of this oneofdef
// and return immediately if so.
if (upb_fielddef_containingoneof(f) == o) {
return true;
}
// The field must have an OPTIONAL label.
if (upb_fielddef_label(f) != UPB_LABEL_OPTIONAL) {
upb_status_seterrmsg(s, "fields in oneof must have OPTIONAL label");
return false;
}
// Check that no field with this name or number exists already in the oneof.
// Also check that the field is not already part of a oneof.
if (upb_fielddef_name(f) == NULL || upb_fielddef_number(f) == 0) {
upb_status_seterrmsg(s, "field name or number were not set");
return false;
} else if (upb_oneofdef_itof(o, upb_fielddef_number(f)) ||
upb_oneofdef_ntofz(o, upb_fielddef_name(f))) {
upb_status_seterrmsg(s, "duplicate field name or number");
return false;
} else if (upb_fielddef_containingoneof(f) != NULL) {
upb_status_seterrmsg(s, "fielddef already belongs to a oneof");
return false;
}
// We allow adding a field to the oneof either if the field is not part of a
// msgdef, or if it is and we are also part of the same msgdef.
if (o->parent == NULL) {
// If we're not in a msgdef, the field cannot be either. Otherwise we would
// need to magically add this oneof to a msgdef to remain consistent, which
// is surprising behavior.
if (upb_fielddef_containingtype(f) != NULL) {
upb_status_seterrmsg(s, "fielddef already belongs to a message, but "
"oneof does not");
return false;
}
} else {
// If we're in a msgdef, the user can add fields that either aren't in any
// msgdef (in which case they're added to our msgdef) or already a part of
// our msgdef.
if (upb_fielddef_containingtype(f) != NULL &&
upb_fielddef_containingtype(f) != o->parent) {
upb_status_seterrmsg(s, "fielddef belongs to a different message "
"than oneof");
return false;
}
}
// Commit phase. First add the field to our parent msgdef, if any, because
// that may fail; then add the field to our own tables.
if (o->parent != NULL && upb_fielddef_containingtype(f) == NULL) {
if (!upb_msgdef_addfield((upb_msgdef*)o->parent, f, NULL, s)) {
return false;
}
}
release_containingtype(f);
f->oneof = o;
upb_inttable_insert(&o->itof, upb_fielddef_number(f), upb_value_ptr(f));
upb_strtable_insert(&o->ntof, upb_fielddef_name(f), upb_value_ptr(f));
upb_ref2(f, o);
upb_ref2(o, f);
if (ref_donor) upb_fielddef_unref(f, ref_donor);
return true;
}
const upb_fielddef *upb_oneofdef_ntof(const upb_oneofdef *o,
const char *name, size_t length) {
upb_value val;
return upb_strtable_lookup2(&o->ntof, name, length, &val) ?
upb_value_getptr(val) : NULL;
}
const upb_fielddef *upb_oneofdef_itof(const upb_oneofdef *o, uint32_t num) {
upb_value val;
return upb_inttable_lookup32(&o->itof, num, &val) ?
upb_value_getptr(val) : NULL;
}
void upb_oneof_begin(upb_oneof_iter *iter, const upb_oneofdef *o) {
upb_inttable_begin(iter, &o->itof);
}
void upb_oneof_next(upb_oneof_iter *iter) {
upb_inttable_next(iter);
}
bool upb_oneof_done(upb_oneof_iter *iter) {
return upb_inttable_done(iter);
}
upb_fielddef *upb_oneof_iter_field(const upb_oneof_iter *iter) {
return (upb_fielddef*)upb_value_getptr(upb_inttable_iter_value(iter));
}
void upb_oneof_iter_setdone(upb_oneof_iter *iter) {
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
upb_inttable_iter_setdone(iter);
}
/*
* upb - a minimalist implementation of protocol buffers.
*
* Copyright (c) 2011-2012 Google Inc. See LICENSE for details.
* Author: Josh Haberman <jhaberman@gmail.com>
*
* TODO(haberman): it's unclear whether a lot of the consistency checks should
* assert() or return false.
*/
#include <stdlib.h>
#include <string.h>
// Defined for the sole purpose of having a unique pointer value for
// UPB_NO_CLOSURE.
char _upb_noclosure;
static void freehandlers(upb_refcounted *r) {
upb_handlers *h = (upb_handlers*)r;
upb_inttable_iter i;
upb_inttable_begin(&i, &h->cleanup_);
for(; !upb_inttable_done(&i); upb_inttable_next(&i)) {
void *val = (void*)upb_inttable_iter_key(&i);
upb_value func_val = upb_inttable_iter_value(&i);
upb_handlerfree *func = upb_value_getfptr(func_val);
func(val);
}
upb_inttable_uninit(&h->cleanup_);
upb_msgdef_unref(h->msg, h);
free(h->sub);
free(h);
}
static void visithandlers(const upb_refcounted *r, upb_refcounted_visit *visit,
void *closure) {
const upb_handlers *h = (const upb_handlers*)r;
Support oneofs in MRI Ruby C extension.
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upb_msg_field_iter i;
for(upb_msg_field_begin(&i, h->msg);
!upb_msg_field_done(&i);
upb_msg_field_next(&i)) {
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
upb_fielddef *f = upb_msg_iter_field(&i);
if (!upb_fielddef_issubmsg(f)) continue;
const upb_handlers *sub = upb_handlers_getsubhandlers(h, f);
if (sub) visit(r, UPB_UPCAST(sub), closure);
}
}
static const struct upb_refcounted_vtbl vtbl = {visithandlers, freehandlers};
typedef struct {
upb_inttable tab; // maps upb_msgdef* -> upb_handlers*.
upb_handlers_callback *callback;
const void *closure;
} dfs_state;
// TODO(haberman): discard upb_handlers* objects that do not actually have any
// handlers set and cannot reach any upb_handlers* object that does. This is
// slightly tricky to do correctly.
static upb_handlers *newformsg(const upb_msgdef *m, const void *owner,
dfs_state *s) {
upb_handlers *h = upb_handlers_new(m, owner);
if (!h) return NULL;
if (!upb_inttable_insertptr(&s->tab, m, upb_value_ptr(h))) goto oom;
s->callback(s->closure, h);
// For each submessage field, get or create a handlers object and set it as
// the subhandlers.
Support oneofs in MRI Ruby C extension.
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upb_msg_field_iter i;
for(upb_msg_field_begin(&i, m);
!upb_msg_field_done(&i);
upb_msg_field_next(&i)) {
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
upb_fielddef *f = upb_msg_iter_field(&i);
if (!upb_fielddef_issubmsg(f)) continue;
const upb_msgdef *subdef = upb_downcast_msgdef(upb_fielddef_subdef(f));
upb_value subm_ent;
if (upb_inttable_lookupptr(&s->tab, subdef, &subm_ent)) {
upb_handlers_setsubhandlers(h, f, upb_value_getptr(subm_ent));
} else {
upb_handlers *sub_mh = newformsg(subdef, &sub_mh, s);
if (!sub_mh) goto oom;
upb_handlers_setsubhandlers(h, f, sub_mh);
upb_handlers_unref(sub_mh, &sub_mh);
}
}
return h;
oom:
upb_handlers_unref(h, owner);
return NULL;
}
// Given a selector for a STARTSUBMSG handler, resolves to a pointer to the
// subhandlers for this submessage field.
#define SUBH(h, selector) (h->sub[selector])
// The selector for a submessage field is the field index.
#define SUBH_F(h, f) SUBH(h, f->index_)
static int32_t trygetsel(upb_handlers *h, const upb_fielddef *f,
upb_handlertype_t type) {
upb_selector_t sel;
assert(!upb_handlers_isfrozen(h));
if (upb_handlers_msgdef(h) != upb_fielddef_containingtype(f)) {
upb_status_seterrf(
&h->status_, "type mismatch: field %s does not belong to message %s",
upb_fielddef_name(f), upb_msgdef_fullname(upb_handlers_msgdef(h)));
return -1;
}
if (!upb_handlers_getselector(f, type, &sel)) {
upb_status_seterrf(
&h->status_,
"type mismatch: cannot register handler type %d for field %s",
type, upb_fielddef_name(f));
return -1;
}
return sel;
}
static upb_selector_t handlers_getsel(upb_handlers *h, const upb_fielddef *f,
upb_handlertype_t type) {
int32_t sel = trygetsel(h, f, type);
assert(sel >= 0);
return sel;
}
static const void **returntype(upb_handlers *h, const upb_fielddef *f,
upb_handlertype_t type) {
return &h->table[handlers_getsel(h, f, type)].attr.return_closure_type_;
}
static bool doset(upb_handlers *h, int32_t sel, const upb_fielddef *f,
upb_handlertype_t type, upb_func *func,
upb_handlerattr *attr) {
assert(!upb_handlers_isfrozen(h));
if (sel < 0) {
upb_status_seterrmsg(&h->status_,
"incorrect handler type for this field.");
return false;
}
if (h->table[sel].func) {
upb_status_seterrmsg(&h->status_,
"cannot change handler once it has been set.");
return false;
}
upb_handlerattr set_attr = UPB_HANDLERATTR_INITIALIZER;
if (attr) {
set_attr = *attr;
}
// Check that the given closure type matches the closure type that has been
// established for this context (if any).
const void *closure_type = upb_handlerattr_closuretype(&set_attr);
const void **context_closure_type;
if (type == UPB_HANDLER_STRING) {
context_closure_type = returntype(h, f, UPB_HANDLER_STARTSTR);
} else if (f && upb_fielddef_isseq(f) &&
type != UPB_HANDLER_STARTSEQ &&
type != UPB_HANDLER_ENDSEQ) {
context_closure_type = returntype(h, f, UPB_HANDLER_STARTSEQ);
} else {
context_closure_type = &h->top_closure_type;
}
if (closure_type && *context_closure_type &&
closure_type != *context_closure_type) {
// TODO(haberman): better message for debugging.
upb_status_seterrmsg(&h->status_, "closure type does not match");
return false;
}
if (closure_type)
*context_closure_type = closure_type;
// If this is a STARTSEQ or STARTSTR handler, check that the returned pointer
// matches any pre-existing expectations about what type is expected.
if (type == UPB_HANDLER_STARTSEQ || type == UPB_HANDLER_STARTSTR) {
const void *return_type = upb_handlerattr_returnclosuretype(&set_attr);
const void *table_return_type =
upb_handlerattr_returnclosuretype(&h->table[sel].attr);
if (return_type && table_return_type && return_type != table_return_type) {
upb_status_seterrmsg(&h->status_, "closure return type does not match");
return false;
}
if (table_return_type && !return_type)
upb_handlerattr_setreturnclosuretype(&set_attr, table_return_type);
}
h->table[sel].func = (upb_func*)func;
h->table[sel].attr = set_attr;
return true;
}
// Returns the effective closure type for this handler (which will propagate
// from outer frames if this frame has no START* handler). Not implemented for
// UPB_HANDLER_STRING at the moment since this is not needed. Returns NULL is
// the effective closure type is unspecified (either no handler was registered
// to specify it or the handler that was registered did not specify the closure
// type).
const void *effective_closure_type(upb_handlers *h, const upb_fielddef *f,
upb_handlertype_t type) {
assert(type != UPB_HANDLER_STRING);
const void *ret = h->top_closure_type;
upb_selector_t sel;
if (upb_fielddef_isseq(f) &&
type != UPB_HANDLER_STARTSEQ &&
type != UPB_HANDLER_ENDSEQ &&
h->table[sel = handlers_getsel(h, f, UPB_HANDLER_STARTSEQ)].func) {
ret = upb_handlerattr_returnclosuretype(&h->table[sel].attr);
}
if (type == UPB_HANDLER_STRING &&
h->table[sel = handlers_getsel(h, f, UPB_HANDLER_STARTSTR)].func) {
ret = upb_handlerattr_returnclosuretype(&h->table[sel].attr);
}
// The effective type of the submessage; not used yet.
// if (type == SUBMESSAGE &&
// h->table[sel = handlers_getsel(h, f, UPB_HANDLER_STARTSUBMSG)].func) {
// ret = upb_handlerattr_returnclosuretype(&h->table[sel].attr);
// }
return ret;
}
// Checks whether the START* handler specified by f & type is missing even
// though it is required to convert the established type of an outer frame
// ("closure_type") into the established type of an inner frame (represented in
// the return closure type of this handler's attr.
bool checkstart(upb_handlers *h, const upb_fielddef *f, upb_handlertype_t type,
upb_status *status) {
upb_selector_t sel = handlers_getsel(h, f, type);
if (h->table[sel].func) return true;
const void *closure_type = effective_closure_type(h, f, type);
const upb_handlerattr *attr = &h->table[sel].attr;
const void *return_closure_type = upb_handlerattr_returnclosuretype(attr);
if (closure_type && return_closure_type &&
closure_type != return_closure_type) {
upb_status_seterrf(status,
"expected start handler to return sub type for field %f",
upb_fielddef_name(f));
return false;
}
return true;
}
/* Public interface ***********************************************************/
bool upb_handlers_isfrozen(const upb_handlers *h) {
return upb_refcounted_isfrozen(UPB_UPCAST(h));
}
void upb_handlers_ref(const upb_handlers *h, const void *owner) {
upb_refcounted_ref(UPB_UPCAST(h), owner);
}
void upb_handlers_unref(const upb_handlers *h, const void *owner) {
upb_refcounted_unref(UPB_UPCAST(h), owner);
}
void upb_handlers_donateref(
const upb_handlers *h, const void *from, const void *to) {
upb_refcounted_donateref(UPB_UPCAST(h), from, to);
}
void upb_handlers_checkref(const upb_handlers *h, const void *owner) {
upb_refcounted_checkref(UPB_UPCAST(h), owner);
}
upb_handlers *upb_handlers_new(const upb_msgdef *md, const void *owner) {
assert(upb_msgdef_isfrozen(md));
int extra = sizeof(upb_handlers_tabent) * (md->selector_count - 1);
upb_handlers *h = calloc(sizeof(*h) + extra, 1);
if (!h) return NULL;
h->msg = md;
upb_msgdef_ref(h->msg, h);
upb_status_clear(&h->status_);
h->sub = calloc(md->submsg_field_count, sizeof(*h->sub));
if (!h->sub) goto oom;
if (!upb_refcounted_init(UPB_UPCAST(h), &vtbl, owner)) goto oom;
if (!upb_inttable_init(&h->cleanup_, UPB_CTYPE_FPTR)) goto oom;
// calloc() above initialized all handlers to NULL.
return h;
oom:
freehandlers(UPB_UPCAST(h));
return NULL;
}
const upb_handlers *upb_handlers_newfrozen(const upb_msgdef *m,
const void *owner,
upb_handlers_callback *callback,
const void *closure) {
dfs_state state;
state.callback = callback;
state.closure = closure;
if (!upb_inttable_init(&state.tab, UPB_CTYPE_PTR)) return NULL;
upb_handlers *ret = newformsg(m, owner, &state);
upb_inttable_uninit(&state.tab);
if (!ret) return NULL;
upb_refcounted *r = UPB_UPCAST(ret);
bool ok = upb_refcounted_freeze(&r, 1, NULL, UPB_MAX_HANDLER_DEPTH);
UPB_ASSERT_VAR(ok, ok);
return ret;
}
const upb_status *upb_handlers_status(upb_handlers *h) {
assert(!upb_handlers_isfrozen(h));
return &h->status_;
}
void upb_handlers_clearerr(upb_handlers *h) {
assert(!upb_handlers_isfrozen(h));
upb_status_clear(&h->status_);
}
#define SETTER(name, handlerctype, handlertype) \
bool upb_handlers_set ## name(upb_handlers *h, const upb_fielddef *f, \
handlerctype func, upb_handlerattr *attr) { \
int32_t sel = trygetsel(h, f, handlertype); \
return doset(h, sel, f, handlertype, (upb_func*)func, attr); \
}
SETTER(int32, upb_int32_handlerfunc*, UPB_HANDLER_INT32);
SETTER(int64, upb_int64_handlerfunc*, UPB_HANDLER_INT64);
SETTER(uint32, upb_uint32_handlerfunc*, UPB_HANDLER_UINT32);
SETTER(uint64, upb_uint64_handlerfunc*, UPB_HANDLER_UINT64);
SETTER(float, upb_float_handlerfunc*, UPB_HANDLER_FLOAT);
SETTER(double, upb_double_handlerfunc*, UPB_HANDLER_DOUBLE);
SETTER(bool, upb_bool_handlerfunc*, UPB_HANDLER_BOOL);
SETTER(startstr, upb_startstr_handlerfunc*, UPB_HANDLER_STARTSTR);
SETTER(string, upb_string_handlerfunc*, UPB_HANDLER_STRING);
SETTER(endstr, upb_endfield_handlerfunc*, UPB_HANDLER_ENDSTR);
SETTER(startseq, upb_startfield_handlerfunc*, UPB_HANDLER_STARTSEQ);
SETTER(startsubmsg, upb_startfield_handlerfunc*, UPB_HANDLER_STARTSUBMSG);
SETTER(endsubmsg, upb_endfield_handlerfunc*, UPB_HANDLER_ENDSUBMSG);
SETTER(endseq, upb_endfield_handlerfunc*, UPB_HANDLER_ENDSEQ);
#undef SETTER
bool upb_handlers_setstartmsg(upb_handlers *h, upb_startmsg_handlerfunc *func,
upb_handlerattr *attr) {
return doset(h, UPB_STARTMSG_SELECTOR, NULL, UPB_HANDLER_INT32,
(upb_func *)func, attr);
}
bool upb_handlers_setendmsg(upb_handlers *h, upb_endmsg_handlerfunc *func,
upb_handlerattr *attr) {
assert(!upb_handlers_isfrozen(h));
return doset(h, UPB_ENDMSG_SELECTOR, NULL, UPB_HANDLER_INT32,
(upb_func *)func, attr);
}
bool upb_handlers_setsubhandlers(upb_handlers *h, const upb_fielddef *f,
const upb_handlers *sub) {
assert(sub);
assert(!upb_handlers_isfrozen(h));
assert(upb_fielddef_issubmsg(f));
if (SUBH_F(h, f)) return false; // Can't reset.
if (UPB_UPCAST(upb_handlers_msgdef(sub)) != upb_fielddef_subdef(f)) {
return false;
}
SUBH_F(h, f) = sub;
upb_ref2(sub, h);
return true;
}
const upb_handlers *upb_handlers_getsubhandlers(const upb_handlers *h,
const upb_fielddef *f) {
assert(upb_fielddef_issubmsg(f));
return SUBH_F(h, f);
}
bool upb_handlers_getattr(const upb_handlers *h, upb_selector_t sel,
upb_handlerattr *attr) {
if (!upb_handlers_gethandler(h, sel))
return false;
*attr = h->table[sel].attr;
return true;
}
const upb_handlers *upb_handlers_getsubhandlers_sel(const upb_handlers *h,
upb_selector_t sel) {
// STARTSUBMSG selector in sel is the field's selector base.
return SUBH(h, sel - UPB_STATIC_SELECTOR_COUNT);
}
const upb_msgdef *upb_handlers_msgdef(const upb_handlers *h) { return h->msg; }
bool upb_handlers_addcleanup(upb_handlers *h, void *p, upb_handlerfree *func) {
if (upb_inttable_lookupptr(&h->cleanup_, p, NULL)) {
return false;
}
bool ok = upb_inttable_insertptr(&h->cleanup_, p, upb_value_fptr(func));
UPB_ASSERT_VAR(ok, ok);
return true;
}
/* "Static" methods ***********************************************************/
bool upb_handlers_freeze(upb_handlers *const*handlers, int n, upb_status *s) {
// TODO: verify we have a transitive closure.
for (int i = 0; i < n; i++) {
upb_handlers *h = handlers[i];
if (!upb_ok(&h->status_)) {
upb_status_seterrf(s, "handlers for message %s had error status: %s",
upb_msgdef_fullname(upb_handlers_msgdef(h)),
upb_status_errmsg(&h->status_));
return false;
}
// Check that there are no closure mismatches due to missing Start* handlers
// or subhandlers with different type-level types.
Support oneofs in MRI Ruby C extension.
10 years ago
upb_msg_field_iter j;
for(upb_msg_field_begin(&j, h->msg);
!upb_msg_field_done(&j);
upb_msg_field_next(&j)) {
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
const upb_fielddef *f = upb_msg_iter_field(&j);
if (upb_fielddef_isseq(f)) {
if (!checkstart(h, f, UPB_HANDLER_STARTSEQ, s))
return false;
}
if (upb_fielddef_isstring(f)) {
if (!checkstart(h, f, UPB_HANDLER_STARTSTR, s))
return false;
}
if (upb_fielddef_issubmsg(f)) {
bool hashandler = false;
if (upb_handlers_gethandler(
h, handlers_getsel(h, f, UPB_HANDLER_STARTSUBMSG)) ||
upb_handlers_gethandler(
h, handlers_getsel(h, f, UPB_HANDLER_ENDSUBMSG))) {
hashandler = true;
}
if (upb_fielddef_isseq(f) &&
(upb_handlers_gethandler(
h, handlers_getsel(h, f, UPB_HANDLER_STARTSEQ)) ||
upb_handlers_gethandler(
h, handlers_getsel(h, f, UPB_HANDLER_ENDSEQ)))) {
hashandler = true;
}
if (hashandler && !upb_handlers_getsubhandlers(h, f)) {
// For now we add an empty subhandlers in this case. It makes the
// decoder code generator simpler, because it only has to handle two
// cases (submessage has handlers or not) as opposed to three
// (submessage has handlers in enclosing message but no subhandlers).
//
// This makes parsing less efficient in the case that we want to
// notice a submessage but skip its contents (like if we're testing
// for submessage presence or counting the number of repeated
// submessages). In this case we will end up parsing the submessage
// field by field and throwing away the results for each, instead of
// skipping the whole delimited thing at once. If this is an issue we
// can revisit it, but do remember that this only arises when you have
// handlers (startseq/startsubmsg/endsubmsg/endseq) set for the
// submessage but no subhandlers. The uses cases for this are
// limited.
upb_handlers *sub = upb_handlers_new(upb_fielddef_msgsubdef(f), &sub);
upb_handlers_setsubhandlers(h, f, sub);
upb_handlers_unref(sub, &sub);
}
// TODO(haberman): check type of submessage.
// This is slightly tricky; also consider whether we should check that
// they match at setsubhandlers time.
}
}
}
if (!upb_refcounted_freeze((upb_refcounted*const*)handlers, n, s,
UPB_MAX_HANDLER_DEPTH)) {
return false;
}
return true;
}
upb_handlertype_t upb_handlers_getprimitivehandlertype(const upb_fielddef *f) {
switch (upb_fielddef_type(f)) {
case UPB_TYPE_INT32:
case UPB_TYPE_ENUM: return UPB_HANDLER_INT32;
case UPB_TYPE_INT64: return UPB_HANDLER_INT64;
case UPB_TYPE_UINT32: return UPB_HANDLER_UINT32;
case UPB_TYPE_UINT64: return UPB_HANDLER_UINT64;
case UPB_TYPE_FLOAT: return UPB_HANDLER_FLOAT;
case UPB_TYPE_DOUBLE: return UPB_HANDLER_DOUBLE;
case UPB_TYPE_BOOL: return UPB_HANDLER_BOOL;
default: assert(false); return -1; // Invalid input.
}
}
bool upb_handlers_getselector(const upb_fielddef *f, upb_handlertype_t type,
upb_selector_t *s) {
switch (type) {
case UPB_HANDLER_INT32:
case UPB_HANDLER_INT64:
case UPB_HANDLER_UINT32:
case UPB_HANDLER_UINT64:
case UPB_HANDLER_FLOAT:
case UPB_HANDLER_DOUBLE:
case UPB_HANDLER_BOOL:
if (!upb_fielddef_isprimitive(f) ||
upb_handlers_getprimitivehandlertype(f) != type)
return false;
*s = f->selector_base;
break;
case UPB_HANDLER_STRING:
if (upb_fielddef_isstring(f)) {
*s = f->selector_base;
} else if (upb_fielddef_lazy(f)) {
*s = f->selector_base + 3;
} else {
return false;
}
break;
case UPB_HANDLER_STARTSTR:
if (upb_fielddef_isstring(f) || upb_fielddef_lazy(f)) {
*s = f->selector_base + 1;
} else {
return false;
}
break;
case UPB_HANDLER_ENDSTR:
if (upb_fielddef_isstring(f) || upb_fielddef_lazy(f)) {
*s = f->selector_base + 2;
} else {
return false;
}
break;
case UPB_HANDLER_STARTSEQ:
if (!upb_fielddef_isseq(f)) return false;
*s = f->selector_base - 2;
break;
case UPB_HANDLER_ENDSEQ:
if (!upb_fielddef_isseq(f)) return false;
*s = f->selector_base - 1;
break;
case UPB_HANDLER_STARTSUBMSG:
if (!upb_fielddef_issubmsg(f)) return false;
// Selectors for STARTSUBMSG are at the beginning of the table so that the
// selector can also be used as an index into the "sub" array of
// subhandlers. The indexes for the two into these two tables are the
// same, except that in the handler table the static selectors come first.
*s = f->index_ + UPB_STATIC_SELECTOR_COUNT;
break;
case UPB_HANDLER_ENDSUBMSG:
if (!upb_fielddef_issubmsg(f)) return false;
*s = f->selector_base;
break;
}
assert(*s < upb_fielddef_containingtype(f)->selector_count);
return true;
}
uint32_t upb_handlers_selectorbaseoffset(const upb_fielddef *f) {
return upb_fielddef_isseq(f) ? 2 : 0;
}
uint32_t upb_handlers_selectorcount(const upb_fielddef *f) {
uint32_t ret = 1;
if (upb_fielddef_isseq(f)) ret += 2; // STARTSEQ/ENDSEQ
if (upb_fielddef_isstring(f)) ret += 2; // [STRING]/STARTSTR/ENDSTR
if (upb_fielddef_issubmsg(f)) {
// ENDSUBMSG (STARTSUBMSG is at table beginning)
ret += 0;
if (upb_fielddef_lazy(f)) {
// STARTSTR/ENDSTR/STRING (for lazy)
ret += 3;
}
}
return ret;
}
/* upb_handlerattr ************************************************************/
void upb_handlerattr_init(upb_handlerattr *attr) {
upb_handlerattr from = UPB_HANDLERATTR_INITIALIZER;
memcpy(attr, &from, sizeof(*attr));
}
void upb_handlerattr_uninit(upb_handlerattr *attr) {
UPB_UNUSED(attr);
}
bool upb_handlerattr_sethandlerdata(upb_handlerattr *attr, const void *hd) {
attr->handler_data_ = hd;
return true;
}
bool upb_handlerattr_setclosuretype(upb_handlerattr *attr, const void *type) {
attr->closure_type_ = type;
return true;
}
const void *upb_handlerattr_closuretype(const upb_handlerattr *attr) {
return attr->closure_type_;
}
bool upb_handlerattr_setreturnclosuretype(upb_handlerattr *attr,
const void *type) {
attr->return_closure_type_ = type;
return true;
}
const void *upb_handlerattr_returnclosuretype(const upb_handlerattr *attr) {
return attr->return_closure_type_;
}
bool upb_handlerattr_setalwaysok(upb_handlerattr *attr, bool alwaysok) {
attr->alwaysok_ = alwaysok;
return true;
}
bool upb_handlerattr_alwaysok(const upb_handlerattr *attr) {
return attr->alwaysok_;
}
/* upb_bufhandle **************************************************************/
size_t upb_bufhandle_objofs(const upb_bufhandle *h) {
return h->objofs_;
}
/* upb_byteshandler ***********************************************************/
void upb_byteshandler_init(upb_byteshandler* h) {
memset(h, 0, sizeof(*h));
}
// For when we support handlerfree callbacks.
void upb_byteshandler_uninit(upb_byteshandler* h) {
UPB_UNUSED(h);
}
bool upb_byteshandler_setstartstr(upb_byteshandler *h,
upb_startstr_handlerfunc *func, void *d) {
h->table[UPB_STARTSTR_SELECTOR].func = (upb_func*)func;
h->table[UPB_STARTSTR_SELECTOR].attr.handler_data_ = d;
return true;
}
bool upb_byteshandler_setstring(upb_byteshandler *h,
upb_string_handlerfunc *func, void *d) {
h->table[UPB_STRING_SELECTOR].func = (upb_func*)func;
h->table[UPB_STRING_SELECTOR].attr.handler_data_ = d;
return true;
}
bool upb_byteshandler_setendstr(upb_byteshandler *h,
upb_endfield_handlerfunc *func, void *d) {
h->table[UPB_ENDSTR_SELECTOR].func = (upb_func*)func;
h->table[UPB_ENDSTR_SELECTOR].attr.handler_data_ = d;
return true;
}
/*
* upb - a minimalist implementation of protocol buffers.
*
* Copyright (c) 2012 Google Inc. See LICENSE for details.
* Author: Josh Haberman <jhaberman@gmail.com>
*
* Our key invariants are:
* 1. reference cycles never span groups
* 2. for ref2(to, from), we increment to's count iff group(from) != group(to)
*
* The previous two are how we avoid leaking cycles. Other important
* invariants are:
* 3. for mutable objects "from" and "to", if there exists a ref2(to, from)
* this implies group(from) == group(to). (In practice, what we implement
* is even stronger; "from" and "to" will share a group if there has *ever*
* been a ref2(to, from), but all that is necessary for correctness is the
* weaker one).
* 4. mutable and immutable objects are never in the same group.
*/
#include <setjmp.h>
#include <stdlib.h>
static void freeobj(upb_refcounted *o);
const char untracked_val;
const void *UPB_UNTRACKED_REF = &untracked_val;
/* arch-specific atomic primitives *******************************************/
#ifdef UPB_THREAD_UNSAFE //////////////////////////////////////////////////////
static void atomic_inc(uint32_t *a) { (*a)++; }
static bool atomic_dec(uint32_t *a) { return --(*a) == 0; }
#elif defined(__GNUC__) || defined(__clang__) //////////////////////////////////
static void atomic_inc(uint32_t *a) { __sync_fetch_and_add(a, 1); }
static bool atomic_dec(uint32_t *a) { return __sync_sub_and_fetch(a, 1) == 0; }
#elif defined(WIN32) ///////////////////////////////////////////////////////////
#include <Windows.h>
static void atomic_inc(upb_atomic_t *a) { InterlockedIncrement(&a->val); }
static bool atomic_dec(upb_atomic_t *a) {
return InterlockedDecrement(&a->val) == 0;
}
#else
#error Atomic primitives not defined for your platform/CPU. \
Implement them or compile with UPB_THREAD_UNSAFE.
#endif
// All static objects point to this refcount.
// It is special-cased in ref/unref below.
uint32_t static_refcount = -1;
// We can avoid atomic ops for statically-declared objects.
// This is a minor optimization but nice since we can avoid degrading under
// contention in this case.
static void refgroup(uint32_t *group) {
if (group != &static_refcount)
atomic_inc(group);
}
static bool unrefgroup(uint32_t *group) {
if (group == &static_refcount) {
return false;
} else {
return atomic_dec(group);
}
}
/* Reference tracking (debug only) ********************************************/
#ifdef UPB_DEBUG_REFS
#ifdef UPB_THREAD_UNSAFE
static void upb_lock() {}
static void upb_unlock() {}
#else
// User must define functions that lock/unlock a global mutex and link this
// file against them.
void upb_lock();
void upb_unlock();
#endif
// UPB_DEBUG_REFS mode counts on being able to malloc() memory in some
// code-paths that can normally never fail, like upb_refcounted_ref(). Since
// we have no way to propagage out-of-memory errors back to the user, and since
// these errors can only occur in UPB_DEBUG_REFS mode, we immediately fail.
#define CHECK_OOM(predicate) if (!(predicate)) { assert(predicate); exit(1); }
typedef struct {
int count; // How many refs there are (duplicates only allowed for ref2).
bool is_ref2;
} trackedref;
static trackedref *trackedref_new(bool is_ref2) {
trackedref *ret = malloc(sizeof(*ret));
CHECK_OOM(ret);
ret->count = 1;
ret->is_ref2 = is_ref2;
return ret;
}
static void track(const upb_refcounted *r, const void *owner, bool ref2) {
assert(owner);
if (owner == UPB_UNTRACKED_REF) return;
upb_lock();
upb_value v;
if (upb_inttable_lookupptr(r->refs, owner, &v)) {
trackedref *ref = upb_value_getptr(v);
// Since we allow multiple ref2's for the same to/from pair without
// allocating separate memory for each one, we lose the fine-grained
// tracking behavior we get with regular refs. Since ref2s only happen
// inside upb, we'll accept this limitation until/unless there is a really
// difficult upb-internal bug that can't be figured out without it.
assert(ref2);
assert(ref->is_ref2);
ref->count++;
} else {
trackedref *ref = trackedref_new(ref2);
bool ok = upb_inttable_insertptr(r->refs, owner, upb_value_ptr(ref));
CHECK_OOM(ok);
if (ref2) {
// We know this cast is safe when it is a ref2, because it's coming from
// another refcounted object.
const upb_refcounted *from = owner;
assert(!upb_inttable_lookupptr(from->ref2s, r, NULL));
ok = upb_inttable_insertptr(from->ref2s, r, upb_value_ptr(NULL));
CHECK_OOM(ok);
}
}
upb_unlock();
}
static void untrack(const upb_refcounted *r, const void *owner, bool ref2) {
assert(owner);
if (owner == UPB_UNTRACKED_REF) return;
upb_lock();
upb_value v;
bool found = upb_inttable_lookupptr(r->refs, owner, &v);
// This assert will fail if an owner attempts to release a ref it didn't have.
UPB_ASSERT_VAR(found, found);
trackedref *ref = upb_value_getptr(v);
assert(ref->is_ref2 == ref2);
if (--ref->count == 0) {
free(ref);
upb_inttable_removeptr(r->refs, owner, NULL);
if (ref2) {
// We know this cast is safe when it is a ref2, because it's coming from
// another refcounted object.
const upb_refcounted *from = owner;
bool removed = upb_inttable_removeptr(from->ref2s, r, NULL);
assert(removed);
}
}
upb_unlock();
}
static void checkref(const upb_refcounted *r, const void *owner, bool ref2) {
upb_lock();
upb_value v;
bool found = upb_inttable_lookupptr(r->refs, owner, &v);
UPB_ASSERT_VAR(found, found);
trackedref *ref = upb_value_getptr(v);
assert(ref->is_ref2 == ref2);
upb_unlock();
}
// Populates the given UPB_CTYPE_INT32 inttable with counts of ref2's that
// originate from the given owner.
static void getref2s(const upb_refcounted *owner, upb_inttable *tab) {
upb_lock();
upb_inttable_iter i;
upb_inttable_begin(&i, owner->ref2s);
for(; !upb_inttable_done(&i); upb_inttable_next(&i)) {
upb_refcounted *to = (upb_refcounted*)upb_inttable_iter_key(&i);
// To get the count we need to look in the target's table.
upb_value v;
bool found = upb_inttable_lookupptr(to->refs, owner, &v);
assert(found);
trackedref *ref = upb_value_getptr(v);
upb_value count = upb_value_int32(ref->count);
bool ok = upb_inttable_insertptr(tab, to, count);
CHECK_OOM(ok);
}
upb_unlock();
}
typedef struct {
upb_inttable ref2;
const upb_refcounted *obj;
} check_state;
static void visit_check(const upb_refcounted *obj, const upb_refcounted *subobj,
void *closure) {
check_state *s = closure;
assert(obj == s->obj);
assert(subobj);
upb_inttable *ref2 = &s->ref2;
upb_value v;
bool removed = upb_inttable_removeptr(ref2, subobj, &v);
// The following assertion will fail if the visit() function visits a subobj
// that it did not have a ref2 on, or visits the same subobj too many times.
assert(removed);
int32_t newcount = upb_value_getint32(v) - 1;
if (newcount > 0) {
upb_inttable_insert(ref2, (uintptr_t)subobj, upb_value_int32(newcount));
}
}
static void visit(const upb_refcounted *r, upb_refcounted_visit *v,
void *closure) {
// In DEBUG_REFS mode we know what existing ref2 refs there are, so we know
// exactly the set of nodes that visit() should visit. So we verify visit()'s
// correctness here.
check_state state;
state.obj = r;
bool ok = upb_inttable_init(&state.ref2, UPB_CTYPE_INT32);
CHECK_OOM(ok);
getref2s(r, &state.ref2);
// This should visit any children in the ref2 table.
if (r->vtbl->visit) r->vtbl->visit(r, visit_check, &state);
// This assertion will fail if the visit() function missed any children.
assert(upb_inttable_count(&state.ref2) == 0);
upb_inttable_uninit(&state.ref2);
if (r->vtbl->visit) r->vtbl->visit(r, v, closure);
}
static bool trackinit(upb_refcounted *r) {
r->refs = malloc(sizeof(*r->refs));
r->ref2s = malloc(sizeof(*r->ref2s));
if (!r->refs || !r->ref2s) goto err1;
if (!upb_inttable_init(r->refs, UPB_CTYPE_PTR)) goto err1;
if (!upb_inttable_init(r->ref2s, UPB_CTYPE_PTR)) goto err2;
return true;
err2:
upb_inttable_uninit(r->refs);
err1:
free(r->refs);
free(r->ref2s);
return false;
}
static void trackfree(const upb_refcounted *r) {
upb_inttable_uninit(r->refs);
upb_inttable_uninit(r->ref2s);
free(r->refs);
free(r->ref2s);
}
#else
static void track(const upb_refcounted *r, const void *owner, bool ref2) {
UPB_UNUSED(r);
UPB_UNUSED(owner);
UPB_UNUSED(ref2);
}
static void untrack(const upb_refcounted *r, const void *owner, bool ref2) {
UPB_UNUSED(r);
UPB_UNUSED(owner);
UPB_UNUSED(ref2);
}
static void checkref(const upb_refcounted *r, const void *owner, bool ref2) {
UPB_UNUSED(r);
UPB_UNUSED(owner);
UPB_UNUSED(ref2);
}
static bool trackinit(upb_refcounted *r) {
UPB_UNUSED(r);
return true;
}
static void trackfree(const upb_refcounted *r) {
UPB_UNUSED(r);
}
static void visit(const upb_refcounted *r, upb_refcounted_visit *v,
void *closure) {
if (r->vtbl->visit) r->vtbl->visit(r, v, closure);
}
#endif // UPB_DEBUG_REFS
/* freeze() *******************************************************************/
// The freeze() operation is by far the most complicated part of this scheme.
// We compute strongly-connected components and then mutate the graph such that
// we preserve the invariants documented at the top of this file. And we must
// handle out-of-memory errors gracefully (without leaving the graph
// inconsistent), which adds to the fun.
// The state used by the freeze operation (shared across many functions).
typedef struct {
int depth;
int maxdepth;
uint64_t index;
// Maps upb_refcounted* -> attributes (color, etc). attr layout varies by
// color.
upb_inttable objattr;
upb_inttable stack; // stack of upb_refcounted* for Tarjan's algorithm.
upb_inttable groups; // array of uint32_t*, malloc'd refcounts for new groups
upb_status *status;
jmp_buf err;
} tarjan;
static void release_ref2(const upb_refcounted *obj,
const upb_refcounted *subobj,
void *closure);
// Node attributes /////////////////////////////////////////////////////////////
// After our analysis phase all nodes will be either GRAY or WHITE.
typedef enum {
BLACK = 0, // Object has not been seen.
GRAY, // Object has been found via a refgroup but may not be reachable.
GREEN, // Object is reachable and is currently on the Tarjan stack.
WHITE, // Object is reachable and has been assigned a group (SCC).
} color_t;
UPB_NORETURN static void err(tarjan *t) { longjmp(t->err, 1); }
UPB_NORETURN static void oom(tarjan *t) {
upb_status_seterrmsg(t->status, "out of memory");
err(t);
}
static uint64_t trygetattr(const tarjan *t, const upb_refcounted *r) {
upb_value v;
return upb_inttable_lookupptr(&t->objattr, r, &v) ?
upb_value_getuint64(v) : 0;
}
static uint64_t getattr(const tarjan *t, const upb_refcounted *r) {
upb_value v;
bool found = upb_inttable_lookupptr(&t->objattr, r, &v);
UPB_ASSERT_VAR(found, found);
return upb_value_getuint64(v);
}
static void setattr(tarjan *t, const upb_refcounted *r, uint64_t attr) {
upb_inttable_removeptr(&t->objattr, r, NULL);
upb_inttable_insertptr(&t->objattr, r, upb_value_uint64(attr));
}
static color_t color(tarjan *t, const upb_refcounted *r) {
return trygetattr(t, r) & 0x3; // Color is always stored in the low 2 bits.
}
static void set_gray(tarjan *t, const upb_refcounted *r) {
assert(color(t, r) == BLACK);
setattr(t, r, GRAY);
}
// Pushes an obj onto the Tarjan stack and sets it to GREEN.
static void push(tarjan *t, const upb_refcounted *r) {
assert(color(t, r) == BLACK || color(t, r) == GRAY);
// This defines the attr layout for the GREEN state. "index" and "lowlink"
// get 31 bits, which is plenty (limit of 2B objects frozen at a time).
setattr(t, r, GREEN | (t->index << 2) | (t->index << 33));
if (++t->index == 0x80000000) {
upb_status_seterrmsg(t->status, "too many objects to freeze");
err(t);
}
upb_inttable_push(&t->stack, upb_value_ptr((void*)r));
}
// Pops an obj from the Tarjan stack and sets it to WHITE, with a ptr to its
// SCC group.
static upb_refcounted *pop(tarjan *t) {
upb_refcounted *r = upb_value_getptr(upb_inttable_pop(&t->stack));
assert(color(t, r) == GREEN);
// This defines the attr layout for nodes in the WHITE state.
// Top of group stack is [group, NULL]; we point at group.
setattr(t, r, WHITE | (upb_inttable_count(&t->groups) - 2) << 8);
return r;
}
static void tarjan_newgroup(tarjan *t) {
uint32_t *group = malloc(sizeof(*group));
if (!group) oom(t);
// Push group and empty group leader (we'll fill in leader later).
if (!upb_inttable_push(&t->groups, upb_value_ptr(group)) ||
!upb_inttable_push(&t->groups, upb_value_ptr(NULL))) {
free(group);
oom(t);
}
*group = 0;
}
static uint32_t idx(tarjan *t, const upb_refcounted *r) {
assert(color(t, r) == GREEN);
return (getattr(t, r) >> 2) & 0x7FFFFFFF;
}
static uint32_t lowlink(tarjan *t, const upb_refcounted *r) {
if (color(t, r) == GREEN) {
return getattr(t, r) >> 33;
} else {
return UINT32_MAX;
}
}
static void set_lowlink(tarjan *t, const upb_refcounted *r, uint32_t lowlink) {
assert(color(t, r) == GREEN);
setattr(t, r, ((uint64_t)lowlink << 33) | (getattr(t, r) & 0x1FFFFFFFF));
}
static uint32_t *group(tarjan *t, upb_refcounted *r) {
assert(color(t, r) == WHITE);
uint64_t groupnum = getattr(t, r) >> 8;
upb_value v;
bool found = upb_inttable_lookup(&t->groups, groupnum, &v);
UPB_ASSERT_VAR(found, found);
return upb_value_getptr(v);
}
// If the group leader for this object's group has not previously been set,
// the given object is assigned to be its leader.
static upb_refcounted *groupleader(tarjan *t, upb_refcounted *r) {
assert(color(t, r) == WHITE);
uint64_t leader_slot = (getattr(t, r) >> 8) + 1;
upb_value v;
bool found = upb_inttable_lookup(&t->groups, leader_slot, &v);
UPB_ASSERT_VAR(found, found);
if (upb_value_getptr(v)) {
return upb_value_getptr(v);
} else {
upb_inttable_remove(&t->groups, leader_slot, NULL);
upb_inttable_insert(&t->groups, leader_slot, upb_value_ptr(r));
return r;
}
}
// Tarjan's algorithm //////////////////////////////////////////////////////////
// See:
// http://en.wikipedia.org/wiki/Tarjan%27s_strongly_connected_components_algorithm
static void do_tarjan(const upb_refcounted *obj, tarjan *t);
static void tarjan_visit(const upb_refcounted *obj,
const upb_refcounted *subobj,
void *closure) {
tarjan *t = closure;
if (++t->depth > t->maxdepth) {
upb_status_seterrf(t->status, "graph too deep to freeze (%d)", t->maxdepth);
err(t);
} else if (subobj->is_frozen || color(t, subobj) == WHITE) {
// Do nothing: we don't want to visit or color already-frozen nodes,
// and WHITE nodes have already been assigned a SCC.
} else if (color(t, subobj) < GREEN) {
// Subdef has not yet been visited; recurse on it.
do_tarjan(subobj, t);
set_lowlink(t, obj, UPB_MIN(lowlink(t, obj), lowlink(t, subobj)));
} else if (color(t, subobj) == GREEN) {
// Subdef is in the stack and hence in the current SCC.
set_lowlink(t, obj, UPB_MIN(lowlink(t, obj), idx(t, subobj)));
}
--t->depth;
}
static void do_tarjan(const upb_refcounted *obj, tarjan *t) {
if (color(t, obj) == BLACK) {
// We haven't seen this object's group; mark the whole group GRAY.
const upb_refcounted *o = obj;
do { set_gray(t, o); } while ((o = o->next) != obj);
}
push(t, obj);
visit(obj, tarjan_visit, t);
if (lowlink(t, obj) == idx(t, obj)) {
tarjan_newgroup(t);
while (pop(t) != obj)
;
}
}
// freeze() ////////////////////////////////////////////////////////////////////
static void crossref(const upb_refcounted *r, const upb_refcounted *subobj,
void *_t) {
tarjan *t = _t;
assert(color(t, r) > BLACK);
if (color(t, subobj) > BLACK && r->group != subobj->group) {
// Previously this ref was not reflected in subobj->group because they
// were in the same group; now that they are split a ref must be taken.
refgroup(subobj->group);
}
}
static bool freeze(upb_refcounted *const*roots, int n, upb_status *s,
int maxdepth) {
volatile bool ret = false;
// We run in two passes so that we can allocate all memory before performing
// any mutation of the input -- this allows us to leave the input unchanged
// in the case of memory allocation failure.
tarjan t;
t.index = 0;
t.depth = 0;
t.maxdepth = maxdepth;
t.status = s;
if (!upb_inttable_init(&t.objattr, UPB_CTYPE_UINT64)) goto err1;
if (!upb_inttable_init(&t.stack, UPB_CTYPE_PTR)) goto err2;
if (!upb_inttable_init(&t.groups, UPB_CTYPE_PTR)) goto err3;
if (setjmp(t.err) != 0) goto err4;
for (int i = 0; i < n; i++) {
if (color(&t, roots[i]) < GREEN) {
do_tarjan(roots[i], &t);
}
}
// If we've made it this far, no further errors are possible so it's safe to
// mutate the objects without risk of leaving them in an inconsistent state.
ret = true;
// The transformation that follows requires care. The preconditions are:
// - all objects in attr map are WHITE or GRAY, and are in mutable groups
// (groups of all mutable objs)
// - no ref2(to, from) refs have incremented count(to) if both "to" and
// "from" are in our attr map (this follows from invariants (2) and (3))
// Pass 1: we remove WHITE objects from their mutable groups, and add them to
// new groups according to the SCC's we computed. These new groups will
// consist of only frozen objects. None will be immediately collectible,
// because WHITE objects are by definition reachable from one of "roots",
// which the caller must own refs on.
upb_inttable_iter i;
upb_inttable_begin(&i, &t.objattr);
for(; !upb_inttable_done(&i); upb_inttable_next(&i)) {
upb_refcounted *obj = (upb_refcounted*)upb_inttable_iter_key(&i);
// Since removal from a singly-linked list requires access to the object's
// predecessor, we consider obj->next instead of obj for moving. With the
// while() loop we guarantee that we will visit every node's predecessor.
// Proof:
// 1. every node's predecessor is in our attr map.
// 2. though the loop body may change a node's predecessor, it will only
// change it to be the node we are currently operating on, so with a
// while() loop we guarantee ourselves the chance to remove each node.
while (color(&t, obj->next) == WHITE &&
group(&t, obj->next) != obj->next->group) {
// Remove from old group.
upb_refcounted *move = obj->next;
if (obj == move) {
// Removing the last object from a group.
assert(*obj->group == obj->individual_count);
free(obj->group);
} else {
obj->next = move->next;
// This may decrease to zero; we'll collect GRAY objects (if any) that
// remain in the group in the third pass.
assert(*move->group >= move->individual_count);
*move->group -= move->individual_count;
}
// Add to new group.
upb_refcounted *leader = groupleader(&t, move);
if (move == leader) {
// First object added to new group is its leader.
move->group = group(&t, move);
move->next = move;
*move->group = move->individual_count;
} else {
// Group already has at least one object in it.
assert(leader->group == group(&t, move));
move->group = group(&t, move);
move->next = leader->next;
leader->next = move;
*move->group += move->individual_count;
}
move->is_frozen = true;
}
}
// Pass 2: GRAY and WHITE objects "obj" with ref2(to, obj) references must
// increment count(to) if group(obj) != group(to) (which could now be the
// case if "to" was just frozen).
upb_inttable_begin(&i, &t.objattr);
for(; !upb_inttable_done(&i); upb_inttable_next(&i)) {
upb_refcounted *obj = (upb_refcounted*)upb_inttable_iter_key(&i);
visit(obj, crossref, &t);
}
// Pass 3: GRAY objects are collected if their group's refcount dropped to
// zero when we removed its white nodes. This can happen if they had only
// been kept alive by virtue of sharing a group with an object that was just
// frozen.
//
// It is important that we do this last, since the GRAY object's free()
// function could call unref2() on just-frozen objects, which will decrement
// refs that were added in pass 2.
upb_inttable_begin(&i, &t.objattr);
for(; !upb_inttable_done(&i); upb_inttable_next(&i)) {
upb_refcounted *obj = (upb_refcounted*)upb_inttable_iter_key(&i);
if (obj->group == NULL || *obj->group == 0) {
if (obj->group) {
// We eagerly free() the group's count (since we can't easily determine
// the group's remaining size it's the easiest way to ensure it gets
// done).
free(obj->group);
// Visit to release ref2's (done in a separate pass since release_ref2
// depends on o->group being unmodified so it can test merged()).
upb_refcounted *o = obj;
do { visit(o, release_ref2, NULL); } while ((o = o->next) != obj);
// Mark "group" fields as NULL so we know to free the objects later in
// this loop, but also don't try to delete the group twice.
o = obj;
do { o->group = NULL; } while ((o = o->next) != obj);
}
freeobj(obj);
}
}
err4:
if (!ret) {
upb_inttable_begin(&i, &t.groups);
for(; !upb_inttable_done(&i); upb_inttable_next(&i))
free(upb_value_getptr(upb_inttable_iter_value(&i)));
}
upb_inttable_uninit(&t.groups);
err3:
upb_inttable_uninit(&t.stack);
err2:
upb_inttable_uninit(&t.objattr);
err1:
return ret;
}
/* Misc internal functions ***************************************************/
static bool merged(const upb_refcounted *r, const upb_refcounted *r2) {
return r->group == r2->group;
}
static void merge(upb_refcounted *r, upb_refcounted *from) {
if (merged(r, from)) return;
*r->group += *from->group;
free(from->group);
upb_refcounted *base = from;
// Set all refcount pointers in the "from" chain to the merged refcount.
//
// TODO(haberman): this linear algorithm can result in an overall O(n^2) bound
// if the user continuously extends a group by one object. Prevent this by
// using one of the techniques in this paper:
// ftp://www.ncedc.org/outgoing/geomorph/dino/orals/p245-tarjan.pdf
do { from->group = r->group; } while ((from = from->next) != base);
// Merge the two circularly linked lists by swapping their next pointers.
upb_refcounted *tmp = r->next;
r->next = base->next;
base->next = tmp;
}
static void unref(const upb_refcounted *r);
static void release_ref2(const upb_refcounted *obj,
const upb_refcounted *subobj,
void *closure) {
UPB_UNUSED(closure);
untrack(subobj, obj, true);
if (!merged(obj, subobj)) {
assert(subobj->is_frozen);
unref(subobj);
}
}
static void unref(const upb_refcounted *r) {
if (unrefgroup(r->group)) {
free(r->group);
// In two passes, since release_ref2 needs a guarantee that any subobjs
// are alive.
const upb_refcounted *o = r;
do { visit(o, release_ref2, NULL); } while((o = o->next) != r);
o = r;
do {
const upb_refcounted *next = o->next;
assert(o->is_frozen || o->individual_count == 0);
freeobj((upb_refcounted*)o);
o = next;
} while(o != r);
}
}
static void freeobj(upb_refcounted *o) {
trackfree(o);
o->vtbl->free((upb_refcounted*)o);
}
/* Public interface ***********************************************************/
bool upb_refcounted_init(upb_refcounted *r,
const struct upb_refcounted_vtbl *vtbl,
const void *owner) {
r->next = r;
r->vtbl = vtbl;
r->individual_count = 0;
r->is_frozen = false;
r->group = malloc(sizeof(*r->group));
if (!r->group) return false;
*r->group = 0;
if (!trackinit(r)) {
free(r->group);
return false;
}
upb_refcounted_ref(r, owner);
return true;
}
bool upb_refcounted_isfrozen(const upb_refcounted *r) {
return r->is_frozen;
}
void upb_refcounted_ref(const upb_refcounted *r, const void *owner) {
track(r, owner, false);
if (!r->is_frozen)
((upb_refcounted*)r)->individual_count++;
refgroup(r->group);
}
void upb_refcounted_unref(const upb_refcounted *r, const void *owner) {
untrack(r, owner, false);
if (!r->is_frozen)
((upb_refcounted*)r)->individual_count--;
unref(r);
}
void upb_refcounted_ref2(const upb_refcounted *r, upb_refcounted *from) {
assert(!from->is_frozen); // Non-const pointer implies this.
track(r, from, true);
if (r->is_frozen) {
refgroup(r->group);
} else {
merge((upb_refcounted*)r, from);
}
}
void upb_refcounted_unref2(const upb_refcounted *r, upb_refcounted *from) {
assert(!from->is_frozen); // Non-const pointer implies this.
untrack(r, from, true);
if (r->is_frozen) {
unref(r);
} else {
assert(merged(r, from));
}
}
void upb_refcounted_donateref(
const upb_refcounted *r, const void *from, const void *to) {
assert(from != to);
if (to != NULL)
upb_refcounted_ref(r, to);
if (from != NULL)
upb_refcounted_unref(r, from);
}
void upb_refcounted_checkref(const upb_refcounted *r, const void *owner) {
checkref(r, owner, false);
}
bool upb_refcounted_freeze(upb_refcounted *const*roots, int n, upb_status *s,
int maxdepth) {
for (int i = 0; i < n; i++) {
assert(!roots[i]->is_frozen);
}
return freeze(roots, n, s, maxdepth);
}
/*
* upb - a minimalist implementation of protocol buffers.
*
* Copyright (c) 2013 Google Inc. See LICENSE for details.
* Author: Josh Haberman <jhaberman@gmail.com>
*/
#include <stdlib.h>
// Fallback implementation if the shim is not specialized by the JIT.
#define SHIM_WRITER(type, ctype) \
bool upb_shim_set ## type (void *c, const void *hd, ctype val) { \
uint8_t *m = c; \
const upb_shim_data *d = hd; \
if (d->hasbit > 0) \
*(uint8_t*)&m[d->hasbit / 8] |= 1 << (d->hasbit % 8); \
*(ctype*)&m[d->offset] = val; \
return true; \
} \
SHIM_WRITER(double, double)
SHIM_WRITER(float, float)
SHIM_WRITER(int32, int32_t)
SHIM_WRITER(int64, int64_t)
SHIM_WRITER(uint32, uint32_t)
SHIM_WRITER(uint64, uint64_t)
SHIM_WRITER(bool, bool)
#undef SHIM_WRITER
bool upb_shim_set(upb_handlers *h, const upb_fielddef *f, size_t offset,
int32_t hasbit) {
upb_shim_data *d = malloc(sizeof(*d));
if (!d) return false;
d->offset = offset;
d->hasbit = hasbit;
upb_handlerattr attr = UPB_HANDLERATTR_INITIALIZER;
upb_handlerattr_sethandlerdata(&attr, d);
upb_handlerattr_setalwaysok(&attr, true);
upb_handlers_addcleanup(h, d, free);
#define TYPE(u, l) \
case UPB_TYPE_##u: \
ok = upb_handlers_set##l(h, f, upb_shim_set##l, &attr); break;
bool ok = false;
switch (upb_fielddef_type(f)) {
TYPE(INT64, int64);
TYPE(INT32, int32);
TYPE(ENUM, int32);
TYPE(UINT64, uint64);
TYPE(UINT32, uint32);
TYPE(DOUBLE, double);
TYPE(FLOAT, float);
TYPE(BOOL, bool);
default: assert(false); break;
}
#undef TYPE
upb_handlerattr_uninit(&attr);
return ok;
}
const upb_shim_data *upb_shim_getdata(const upb_handlers *h, upb_selector_t s,
upb_fieldtype_t *type) {
upb_func *f = upb_handlers_gethandler(h, s);
if ((upb_int64_handlerfunc*)f == upb_shim_setint64) {
*type = UPB_TYPE_INT64;
} else if ((upb_int32_handlerfunc*)f == upb_shim_setint32) {
*type = UPB_TYPE_INT32;
} else if ((upb_uint64_handlerfunc*)f == upb_shim_setuint64) {
*type = UPB_TYPE_UINT64;
} else if ((upb_uint32_handlerfunc*)f == upb_shim_setuint32) {
*type = UPB_TYPE_UINT32;
} else if ((upb_double_handlerfunc*)f == upb_shim_setdouble) {
*type = UPB_TYPE_DOUBLE;
} else if ((upb_float_handlerfunc*)f == upb_shim_setfloat) {
*type = UPB_TYPE_FLOAT;
} else if ((upb_bool_handlerfunc*)f == upb_shim_setbool) {
*type = UPB_TYPE_BOOL;
} else {
return NULL;
}
return (const upb_shim_data*)upb_handlers_gethandlerdata(h, s);
}
/*
* upb - a minimalist implementation of protocol buffers.
*
* Copyright (c) 2008-2012 Google Inc. See LICENSE for details.
* Author: Josh Haberman <jhaberman@gmail.com>
*/
#include <stdlib.h>
#include <string.h>
bool upb_symtab_isfrozen(const upb_symtab *s) {
return upb_refcounted_isfrozen(UPB_UPCAST(s));
}
void upb_symtab_ref(const upb_symtab *s, const void *owner) {
upb_refcounted_ref(UPB_UPCAST(s), owner);
}
void upb_symtab_unref(const upb_symtab *s, const void *owner) {
upb_refcounted_unref(UPB_UPCAST(s), owner);
}
void upb_symtab_donateref(
const upb_symtab *s, const void *from, const void *to) {
upb_refcounted_donateref(UPB_UPCAST(s), from, to);
}
void upb_symtab_checkref(const upb_symtab *s, const void *owner) {
upb_refcounted_checkref(UPB_UPCAST(s), owner);
}
static void upb_symtab_free(upb_refcounted *r) {
upb_symtab *s = (upb_symtab*)r;
upb_strtable_iter i;
upb_strtable_begin(&i, &s->symtab);
for (; !upb_strtable_done(&i); upb_strtable_next(&i)) {
const upb_def *def = upb_value_getptr(upb_strtable_iter_value(&i));
upb_def_unref(def, s);
}
upb_strtable_uninit(&s->symtab);
free(s);
}
upb_symtab *upb_symtab_new(const void *owner) {
static const struct upb_refcounted_vtbl vtbl = {NULL, &upb_symtab_free};
upb_symtab *s = malloc(sizeof(*s));
upb_refcounted_init(UPB_UPCAST(s), &vtbl, owner);
upb_strtable_init(&s->symtab, UPB_CTYPE_PTR);
return s;
}
void upb_symtab_freeze(upb_symtab *s) {
assert(!upb_symtab_isfrozen(s));
upb_refcounted *r = UPB_UPCAST(s);
// The symtab does not take ref2's (see refcounted.h) on the defs, because
// defs cannot refer back to the table and therefore cannot create cycles. So
// 0 will suffice for maxdepth here.
bool ok = upb_refcounted_freeze(&r, 1, NULL, 0);
UPB_ASSERT_VAR(ok, ok);
}
const upb_def *upb_symtab_lookup(const upb_symtab *s, const char *sym) {
upb_value v;
upb_def *ret = upb_strtable_lookup(&s->symtab, sym, &v) ?
upb_value_getptr(v) : NULL;
return ret;
}
const upb_msgdef *upb_symtab_lookupmsg(const upb_symtab *s, const char *sym) {
upb_value v;
upb_def *def = upb_strtable_lookup(&s->symtab, sym, &v) ?
upb_value_getptr(v) : NULL;
return def ? upb_dyncast_msgdef(def) : NULL;
}
const upb_enumdef *upb_symtab_lookupenum(const upb_symtab *s, const char *sym) {
upb_value v;
upb_def *def = upb_strtable_lookup(&s->symtab, sym, &v) ?
upb_value_getptr(v) : NULL;
return def ? upb_dyncast_enumdef(def) : NULL;
}
// Given a symbol and the base symbol inside which it is defined, find the
// symbol's definition in t.
static upb_def *upb_resolvename(const upb_strtable *t,
const char *base, const char *sym) {
if(strlen(sym) == 0) return NULL;
if(sym[0] == '.') {
// Symbols starting with '.' are absolute, so we do a single lookup.
// Slice to omit the leading '.'
upb_value v;
return upb_strtable_lookup(t, sym + 1, &v) ? upb_value_getptr(v) : NULL;
} else {
// Remove components from base until we find an entry or run out.
// TODO: This branch is totally broken, but currently not used.
(void)base;
assert(false);
return NULL;
}
}
const upb_def *upb_symtab_resolve(const upb_symtab *s, const char *base,
const char *sym) {
upb_def *ret = upb_resolvename(&s->symtab, base, sym);
return ret;
}
// Searches def and its children to find defs that have the same name as any
// def in "addtab." Returns true if any where found, and as a side-effect adds
// duplicates of these defs into addtab.
//
// We use a modified depth-first traversal that traverses each SCC (which we
// already computed) as if it were a single node. This allows us to traverse
// the possibly-cyclic graph as if it were a DAG and to dup the correct set of
// nodes with O(n) time.
static bool upb_resolve_dfs(const upb_def *def, upb_strtable *addtab,
const void *new_owner, upb_inttable *seen,
upb_status *s) {
// Memoize results of this function for efficiency (since we're traversing a
// DAG this is not needed to limit the depth of the search).
upb_value v;
if (upb_inttable_lookup(seen, (uintptr_t)def, &v))
return upb_value_getbool(v);
// Visit submessages for all messages in the SCC.
bool need_dup = false;
const upb_def *base = def;
do {
assert(upb_def_isfrozen(def));
if (def->type == UPB_DEF_FIELD) continue;
upb_value v;
if (upb_strtable_lookup(addtab, upb_def_fullname(def), &v)) {
need_dup = true;
}
// For messages, continue the recursion by visiting all subdefs.
const upb_msgdef *m = upb_dyncast_msgdef(def);
if (m) {
Support oneofs in MRI Ruby C extension.
10 years ago
upb_msg_field_iter i;
for(upb_msg_field_begin(&i, m);
!upb_msg_field_done(&i);
upb_msg_field_next(&i)) {
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
upb_fielddef *f = upb_msg_iter_field(&i);
if (!upb_fielddef_hassubdef(f)) continue;
// |= to avoid short-circuit; we need its side-effects.
need_dup |= upb_resolve_dfs(
upb_fielddef_subdef(f), addtab, new_owner, seen, s);
if (!upb_ok(s)) return false;
}
}
} while ((def = (upb_def*)def->base.next) != base);
if (need_dup) {
// Dup any defs that don't already have entries in addtab.
def = base;
do {
if (def->type == UPB_DEF_FIELD) continue;
const char *name = upb_def_fullname(def);
if (!upb_strtable_lookup(addtab, name, NULL)) {
upb_def *newdef = upb_def_dup(def, new_owner);
if (!newdef) goto oom;
newdef->came_from_user = false;
if (!upb_strtable_insert(addtab, name, upb_value_ptr(newdef)))
goto oom;
}
} while ((def = (upb_def*)def->base.next) != base);
}
upb_inttable_insert(seen, (uintptr_t)def, upb_value_bool(need_dup));
return need_dup;
oom:
upb_status_seterrmsg(s, "out of memory");
return false;
}
// TODO(haberman): we need a lot more testing of error conditions.
// The came_from_user stuff in particular is not tested.
bool upb_symtab_add(upb_symtab *s, upb_def *const*defs, int n, void *ref_donor,
upb_status *status) {
assert(!upb_symtab_isfrozen(s));
upb_def **add_defs = NULL;
upb_strtable addtab;
if (!upb_strtable_init(&addtab, UPB_CTYPE_PTR)) {
upb_status_seterrmsg(status, "out of memory");
return false;
}
// Add new defs to our "add" set.
for (int i = 0; i < n; i++) {
upb_def *def = defs[i];
if (upb_def_isfrozen(def)) {
upb_status_seterrmsg(status, "added defs must be mutable");
goto err;
}
assert(!upb_def_isfrozen(def));
const char *fullname = upb_def_fullname(def);
if (!fullname) {
upb_status_seterrmsg(
status, "Anonymous defs cannot be added to a symtab");
goto err;
}
upb_fielddef *f = upb_dyncast_fielddef_mutable(def);
if (f) {
if (!upb_fielddef_containingtypename(f)) {
upb_status_seterrmsg(status,
"Standalone fielddefs must have a containing type "
"(extendee) name set");
goto err;
}
} else {
if (upb_strtable_lookup(&addtab, fullname, NULL)) {
upb_status_seterrf(status, "Conflicting defs named '%s'", fullname);
goto err;
}
// We need this to back out properly, because if there is a failure we
// need to donate the ref back to the caller.
def->came_from_user = true;
upb_def_donateref(def, ref_donor, s);
if (!upb_strtable_insert(&addtab, fullname, upb_value_ptr(def)))
goto oom_err;
}
}
// Add standalone fielddefs (ie. extensions) to the appropriate messages.
// If the appropriate message only exists in the existing symtab, duplicate
// it so we have a mutable copy we can add the fields to.
for (int i = 0; i < n; i++) {
upb_def *def = defs[i];
upb_fielddef *f = upb_dyncast_fielddef_mutable(def);
if (!f) continue;
const char *msgname = upb_fielddef_containingtypename(f);
// We validated this earlier in this function.
assert(msgname);
// If the extendee name is absolutely qualified, move past the initial ".".
// TODO(haberman): it is not obvious what it would mean if this was not
// absolutely qualified.
if (msgname[0] == '.') {
msgname++;
}
upb_value v;
upb_msgdef *m;
if (upb_strtable_lookup(&addtab, msgname, &v)) {
// Extendee is in the set of defs the user asked us to add.
m = upb_value_getptr(v);
} else {
// Need to find and dup the extendee from the existing symtab.
const upb_msgdef *frozen_m = upb_symtab_lookupmsg(s, msgname);
if (!frozen_m) {
upb_status_seterrf(status,
"Tried to extend message %s that does not exist "
"in this SymbolTable.",
msgname);
goto err;
}
m = upb_msgdef_dup(frozen_m, s);
if (!m) goto oom_err;
if (!upb_strtable_insert(&addtab, msgname, upb_value_ptr(m))) {
upb_msgdef_unref(m, s);
goto oom_err;
}
}
if (!upb_msgdef_addfield(m, f, ref_donor, status)) {
goto err;
}
}
// Add dups of any existing def that can reach a def with the same name as
// anything in our "add" set.
upb_inttable seen;
if (!upb_inttable_init(&seen, UPB_CTYPE_BOOL)) goto oom_err;
upb_strtable_iter i;
upb_strtable_begin(&i, &s->symtab);
for (; !upb_strtable_done(&i); upb_strtable_next(&i)) {
upb_def *def = upb_value_getptr(upb_strtable_iter_value(&i));
upb_resolve_dfs(def, &addtab, s, &seen, status);
if (!upb_ok(status)) goto err;
}
upb_inttable_uninit(&seen);
// Now using the table, resolve symbolic references for subdefs.
upb_strtable_begin(&i, &addtab);
for (; !upb_strtable_done(&i); upb_strtable_next(&i)) {
upb_def *def = upb_value_getptr(upb_strtable_iter_value(&i));
upb_msgdef *m = upb_dyncast_msgdef_mutable(def);
if (!m) continue;
// Type names are resolved relative to the message in which they appear.
const char *base = upb_msgdef_fullname(m);
Support oneofs in MRI Ruby C extension.
10 years ago
upb_msg_field_iter j;
for(upb_msg_field_begin(&j, m);
!upb_msg_field_done(&j);
upb_msg_field_next(&j)) {
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
upb_fielddef *f = upb_msg_iter_field(&j);
const char *name = upb_fielddef_subdefname(f);
if (name && !upb_fielddef_subdef(f)) {
// Try the lookup in the current set of to-be-added defs first. If not
// there, try existing defs.
upb_def *subdef = upb_resolvename(&addtab, base, name);
if (subdef == NULL) {
subdef = upb_resolvename(&s->symtab, base, name);
}
if (subdef == NULL) {
upb_status_seterrf(
status, "couldn't resolve name '%s' in message '%s'", name, base);
goto err;
} else if (!upb_fielddef_setsubdef(f, subdef, status)) {
goto err;
}
}
}
}
// We need an array of the defs in addtab, for passing to upb_def_freeze.
add_defs = malloc(sizeof(void*) * upb_strtable_count(&addtab));
if (add_defs == NULL) goto oom_err;
upb_strtable_begin(&i, &addtab);
for (n = 0; !upb_strtable_done(&i); upb_strtable_next(&i)) {
add_defs[n++] = upb_value_getptr(upb_strtable_iter_value(&i));
}
if (!upb_def_freeze(add_defs, n, status)) goto err;
// This must be delayed until all errors have been detected, since error
// recovery code uses this table to cleanup defs.
upb_strtable_uninit(&addtab);
// TODO(haberman) we don't properly handle errors after this point (like
// OOM in upb_strtable_insert() below).
for (int i = 0; i < n; i++) {
upb_def *def = add_defs[i];
const char *name = upb_def_fullname(def);
upb_value v;
if (upb_strtable_remove(&s->symtab, name, &v)) {
const upb_def *def = upb_value_getptr(v);
upb_def_unref(def, s);
}
bool success = upb_strtable_insert(&s->symtab, name, upb_value_ptr(def));
UPB_ASSERT_VAR(success, success == true);
}
free(add_defs);
return true;
oom_err:
upb_status_seterrmsg(status, "out of memory");
err: {
// For defs the user passed in, we need to donate the refs back. For defs
// we dup'd, we need to just unref them.
upb_strtable_iter i;
upb_strtable_begin(&i, &addtab);
for (; !upb_strtable_done(&i); upb_strtable_next(&i)) {
upb_def *def = upb_value_getptr(upb_strtable_iter_value(&i));
bool came_from_user = def->came_from_user;
def->came_from_user = false;
if (came_from_user) {
upb_def_donateref(def, s, ref_donor);
} else {
upb_def_unref(def, s);
}
}
}
upb_strtable_uninit(&addtab);
free(add_defs);
assert(!upb_ok(status));
return false;
}
// Iteration.
static void advance_to_matching(upb_symtab_iter *iter) {
if (iter->type == UPB_DEF_ANY)
return;
while (!upb_strtable_done(&iter->iter) &&
iter->type != upb_symtab_iter_def(iter)->type) {
upb_strtable_next(&iter->iter);
}
}
void upb_symtab_begin(upb_symtab_iter *iter, const upb_symtab *s,
upb_deftype_t type) {
upb_strtable_begin(&iter->iter, &s->symtab);
iter->type = type;
advance_to_matching(iter);
}
void upb_symtab_next(upb_symtab_iter *iter) {
upb_strtable_next(&iter->iter);
advance_to_matching(iter);
}
bool upb_symtab_done(const upb_symtab_iter *iter) {
return upb_strtable_done(&iter->iter);
}
const upb_def *upb_symtab_iter_def(const upb_symtab_iter *iter) {
return upb_value_getptr(upb_strtable_iter_value(&iter->iter));
}
/*
* upb - a minimalist implementation of protocol buffers.
*
* Copyright (c) 2009 Google Inc. See LICENSE for details.
* Author: Josh Haberman <jhaberman@gmail.com>
*
* Implementation is heavily inspired by Lua's ltable.c.
*/
#include <stdlib.h>
#include <string.h>
#define UPB_MAXARRSIZE 16 // 64k.
// From Chromium.
#define ARRAY_SIZE(x) \
((sizeof(x)/sizeof(0[x])) / ((size_t)(!(sizeof(x) % sizeof(0[x])))))
static const double MAX_LOAD = 0.85;
// The minimum utilization of the array part of a mixed hash/array table. This
// is a speed/memory-usage tradeoff (though it's not straightforward because of
// cache effects). The lower this is, the more memory we'll use.
static const double MIN_DENSITY = 0.1;
bool is_pow2(uint64_t v) { return v == 0 || (v & (v - 1)) == 0; }
int log2ceil(uint64_t v) {
int ret = 0;
bool pow2 = is_pow2(v);
while (v >>= 1) ret++;
ret = pow2 ? ret : ret + 1; // Ceiling.
return UPB_MIN(UPB_MAXARRSIZE, ret);
}
char *upb_strdup(const char *s) {
Support for maps in the MRI C Ruby extension. This adds the Map container and support for parsing and serializing maps in the protobuf wire format (as defined by the C++ implementation, with MapEntry submessages in a repeated field). JSON map serialization/parsing are not yet supported as these will require some changes to upb as well.
10 years ago
return upb_strdup2(s, strlen(s));
}
char *upb_strdup2(const char *s, size_t len) {
// Always null-terminate, even if binary data; but don't rely on the input to
// have a null-terminating byte since it may be a raw binary buffer.
size_t n = len + 1;
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
char *p = malloc(n);
Support oneofs in MRI Ruby C extension.
10 years ago
if (p) memcpy(p, s, len);
p[len] = 0;
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
return p;
}
// A type to represent the lookup key of either a strtable or an inttable.
typedef struct {
upb_tabkey key;
} lookupkey_t;
static lookupkey_t strkey2(const char *str, size_t len) {
lookupkey_t k;
Support for maps in the MRI C Ruby extension. This adds the Map container and support for parsing and serializing maps in the protobuf wire format (as defined by the C++ implementation, with MapEntry submessages in a repeated field). JSON map serialization/parsing are not yet supported as these will require some changes to upb as well.
10 years ago
k.key.s.str = (char*)str;
k.key.s.length = len;
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
return k;
}
static lookupkey_t intkey(uintptr_t key) {
lookupkey_t k;
k.key = upb_intkey(key);
return k;
}
typedef uint32_t hashfunc_t(upb_tabkey key);
typedef bool eqlfunc_t(upb_tabkey k1, lookupkey_t k2);
/* Base table (shared code) ***************************************************/
// For when we need to cast away const.
static upb_tabent *mutable_entries(upb_table *t) {
return (upb_tabent*)t->entries;
}
static bool isfull(upb_table *t) {
return (double)(t->count + 1) / upb_table_size(t) > MAX_LOAD;
}
static bool init(upb_table *t, upb_ctype_t ctype, uint8_t size_lg2) {
t->count = 0;
t->ctype = ctype;
t->size_lg2 = size_lg2;
t->mask = upb_table_size(t) ? upb_table_size(t) - 1 : 0;
size_t bytes = upb_table_size(t) * sizeof(upb_tabent);
if (bytes > 0) {
t->entries = malloc(bytes);
if (!t->entries) return false;
memset(mutable_entries(t), 0, bytes);
} else {
t->entries = NULL;
}
return true;
}
static void uninit(upb_table *t) { free(mutable_entries(t)); }
static upb_tabent *emptyent(upb_table *t) {
upb_tabent *e = mutable_entries(t) + upb_table_size(t);
while (1) { if (upb_tabent_isempty(--e)) return e; assert(e > t->entries); }
}
static upb_tabent *getentry_mutable(upb_table *t, uint32_t hash) {
return (upb_tabent*)upb_getentry(t, hash);
}
static const upb_tabent *findentry(const upb_table *t, lookupkey_t key,
uint32_t hash, eqlfunc_t *eql) {
if (t->size_lg2 == 0) return NULL;
const upb_tabent *e = upb_getentry(t, hash);
if (upb_tabent_isempty(e)) return NULL;
while (1) {
if (eql(e->key, key)) return e;
if ((e = e->next) == NULL) return NULL;
}
}
static upb_tabent *findentry_mutable(upb_table *t, lookupkey_t key,
uint32_t hash, eqlfunc_t *eql) {
return (upb_tabent*)findentry(t, key, hash, eql);
}
static bool lookup(const upb_table *t, lookupkey_t key, upb_value *v,
uint32_t hash, eqlfunc_t *eql) {
const upb_tabent *e = findentry(t, key, hash, eql);
if (e) {
if (v) {
_upb_value_setval(v, e->val, t->ctype);
}
return true;
} else {
return false;
}
}
// The given key must not already exist in the table.
static void insert(upb_table *t, lookupkey_t key, upb_value val,
uint32_t hash, hashfunc_t *hashfunc, eqlfunc_t *eql) {
UPB_UNUSED(eql);
assert(findentry(t, key, hash, eql) == NULL);
assert(val.ctype == t->ctype);
t->count++;
upb_tabent *mainpos_e = getentry_mutable(t, hash);
upb_tabent *our_e = mainpos_e;
if (upb_tabent_isempty(mainpos_e)) {
// Our main position is empty; use it.
our_e->next = NULL;
} else {
// Collision.
upb_tabent *new_e = emptyent(t);
// Head of collider's chain.
upb_tabent *chain = getentry_mutable(t, hashfunc(mainpos_e->key));
if (chain == mainpos_e) {
// Existing ent is in its main posisiton (it has the same hash as us, and
// is the head of our chain). Insert to new ent and append to this chain.
new_e->next = mainpos_e->next;
mainpos_e->next = new_e;
our_e = new_e;
} else {
// Existing ent is not in its main position (it is a node in some other
// chain). This implies that no existing ent in the table has our hash.
// Evict it (updating its chain) and use its ent for head of our chain.
*new_e = *mainpos_e; // copies next.
while (chain->next != mainpos_e) {
chain = (upb_tabent*)chain->next;
assert(chain);
}
chain->next = new_e;
our_e = mainpos_e;
our_e->next = NULL;
}
}
our_e->key = key.key;
our_e->val = val.val;
assert(findentry(t, key, hash, eql) == our_e);
}
static bool rm(upb_table *t, lookupkey_t key, upb_value *val,
upb_tabkey *removed, uint32_t hash, eqlfunc_t *eql) {
upb_tabent *chain = getentry_mutable(t, hash);
if (upb_tabent_isempty(chain)) return false;
if (eql(chain->key, key)) {
// Element to remove is at the head of its chain.
t->count--;
if (val) {
_upb_value_setval(val, chain->val, t->ctype);
}
if (chain->next) {
upb_tabent *move = (upb_tabent*)chain->next;
*chain = *move;
if (removed) *removed = move->key;
move->key.num = 0; // Make the slot empty.
} else {
if (removed) *removed = chain->key;
chain->key.num = 0; // Make the slot empty.
}
return true;
} else {
// Element to remove is either in a non-head position or not in the table.
while (chain->next && !eql(chain->next->key, key))
chain = (upb_tabent*)chain->next;
if (chain->next) {
// Found element to remove.
if (val) {
_upb_value_setval(val, chain->next->val, t->ctype);
}
upb_tabent *rm = (upb_tabent*)chain->next;
if (removed) *removed = rm->key;
rm->key.num = 0;
chain->next = rm->next;
t->count--;
return true;
} else {
return false;
}
}
}
static size_t next(const upb_table *t, size_t i) {
do {
if (++i >= upb_table_size(t))
return SIZE_MAX;
} while(upb_tabent_isempty(&t->entries[i]));
return i;
}
static size_t begin(const upb_table *t) {
return next(t, -1);
}
/* upb_strtable ***************************************************************/
// A simple "subclass" of upb_table that only adds a hash function for strings.
static uint32_t strhash(upb_tabkey key) {
Support for maps in the MRI C Ruby extension. This adds the Map container and support for parsing and serializing maps in the protobuf wire format (as defined by the C++ implementation, with MapEntry submessages in a repeated field). JSON map serialization/parsing are not yet supported as these will require some changes to upb as well.
10 years ago
return MurmurHash2(key.s.str, key.s.length, 0);
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
}
static bool streql(upb_tabkey k1, lookupkey_t k2) {
Support for maps in the MRI C Ruby extension. This adds the Map container and support for parsing and serializing maps in the protobuf wire format (as defined by the C++ implementation, with MapEntry submessages in a repeated field). JSON map serialization/parsing are not yet supported as these will require some changes to upb as well.
10 years ago
return k1.s.length == k2.key.s.length &&
memcmp(k1.s.str, k2.key.s.str, k1.s.length) == 0;
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
}
bool upb_strtable_init(upb_strtable *t, upb_ctype_t ctype) {
return init(&t->t, ctype, 2);
}
void upb_strtable_uninit(upb_strtable *t) {
for (size_t i = 0; i < upb_table_size(&t->t); i++)
Support for maps in the MRI C Ruby extension. This adds the Map container and support for parsing and serializing maps in the protobuf wire format (as defined by the C++ implementation, with MapEntry submessages in a repeated field). JSON map serialization/parsing are not yet supported as these will require some changes to upb as well.
10 years ago
free((void*)t->t.entries[i].key.s.str);
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
uninit(&t->t);
}
bool upb_strtable_resize(upb_strtable *t, size_t size_lg2) {
upb_strtable new_table;
if (!init(&new_table.t, t->t.ctype, size_lg2))
return false;
upb_strtable_iter i;
upb_strtable_begin(&i, t);
for ( ; !upb_strtable_done(&i); upb_strtable_next(&i)) {
Support for maps in the MRI C Ruby extension. This adds the Map container and support for parsing and serializing maps in the protobuf wire format (as defined by the C++ implementation, with MapEntry submessages in a repeated field). JSON map serialization/parsing are not yet supported as these will require some changes to upb as well.
10 years ago
upb_strtable_insert2(
&new_table,
upb_strtable_iter_key(&i),
upb_strtable_iter_keylength(&i),
upb_strtable_iter_value(&i));
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
}
upb_strtable_uninit(t);
*t = new_table;
return true;
}
Support for maps in the MRI C Ruby extension. This adds the Map container and support for parsing and serializing maps in the protobuf wire format (as defined by the C++ implementation, with MapEntry submessages in a repeated field). JSON map serialization/parsing are not yet supported as these will require some changes to upb as well.
10 years ago
bool upb_strtable_insert2(upb_strtable *t, const char *k, size_t len,
upb_value v) {
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
if (isfull(&t->t)) {
// Need to resize. New table of double the size, add old elements to it.
if (!upb_strtable_resize(t, t->t.size_lg2 + 1)) {
return false;
}
}
Support for maps in the MRI C Ruby extension. This adds the Map container and support for parsing and serializing maps in the protobuf wire format (as defined by the C++ implementation, with MapEntry submessages in a repeated field). JSON map serialization/parsing are not yet supported as these will require some changes to upb as well.
10 years ago
if ((k = upb_strdup2(k, len)) == NULL) return false;
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
Support for maps in the MRI C Ruby extension. This adds the Map container and support for parsing and serializing maps in the protobuf wire format (as defined by the C++ implementation, with MapEntry submessages in a repeated field). JSON map serialization/parsing are not yet supported as these will require some changes to upb as well.
10 years ago
lookupkey_t key = strkey2(k, len);
uint32_t hash = MurmurHash2(key.key.s.str, key.key.s.length, 0);
insert(&t->t, key, v, hash, &strhash, &streql);
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
return true;
}
bool upb_strtable_lookup2(const upb_strtable *t, const char *key, size_t len,
upb_value *v) {
uint32_t hash = MurmurHash2(key, len, 0);
return lookup(&t->t, strkey2(key, len), v, hash, &streql);
}
Support for maps in the MRI C Ruby extension. This adds the Map container and support for parsing and serializing maps in the protobuf wire format (as defined by the C++ implementation, with MapEntry submessages in a repeated field). JSON map serialization/parsing are not yet supported as these will require some changes to upb as well.
10 years ago
bool upb_strtable_remove2(upb_strtable *t, const char *key, size_t len,
upb_value *val) {
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
uint32_t hash = MurmurHash2(key, strlen(key), 0);
upb_tabkey tabkey;
Support for maps in the MRI C Ruby extension. This adds the Map container and support for parsing and serializing maps in the protobuf wire format (as defined by the C++ implementation, with MapEntry submessages in a repeated field). JSON map serialization/parsing are not yet supported as these will require some changes to upb as well.
10 years ago
if (rm(&t->t, strkey2(key, len), val, &tabkey, hash, &streql)) {
free((void*)tabkey.s.str);
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
return true;
} else {
return false;
}
}
// Iteration
static const upb_tabent *str_tabent(const upb_strtable_iter *i) {
return &i->t->t.entries[i->index];
}
void upb_strtable_begin(upb_strtable_iter *i, const upb_strtable *t) {
i->t = t;
i->index = begin(&t->t);
}
void upb_strtable_next(upb_strtable_iter *i) {
i->index = next(&i->t->t, i->index);
}
bool upb_strtable_done(const upb_strtable_iter *i) {
return i->index >= upb_table_size(&i->t->t) ||
upb_tabent_isempty(str_tabent(i));
}
const char *upb_strtable_iter_key(upb_strtable_iter *i) {
assert(!upb_strtable_done(i));
Support for maps in the MRI C Ruby extension. This adds the Map container and support for parsing and serializing maps in the protobuf wire format (as defined by the C++ implementation, with MapEntry submessages in a repeated field). JSON map serialization/parsing are not yet supported as these will require some changes to upb as well.
10 years ago
return str_tabent(i)->key.s.str;
}
size_t upb_strtable_iter_keylength(upb_strtable_iter *i) {
assert(!upb_strtable_done(i));
return str_tabent(i)->key.s.length;
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
}
upb_value upb_strtable_iter_value(const upb_strtable_iter *i) {
assert(!upb_strtable_done(i));
return _upb_value_val(str_tabent(i)->val, i->t->t.ctype);
}
void upb_strtable_iter_setdone(upb_strtable_iter *i) {
i->index = SIZE_MAX;
}
bool upb_strtable_iter_isequal(const upb_strtable_iter *i1,
const upb_strtable_iter *i2) {
if (upb_strtable_done(i1) && upb_strtable_done(i2))
return true;
return i1->t == i2->t && i1->index == i2->index;
}
/* upb_inttable ***************************************************************/
// For inttables we use a hybrid structure where small keys are kept in an
// array and large keys are put in the hash table.
static uint32_t inthash(upb_tabkey key) { return upb_inthash(key.num); }
static bool inteql(upb_tabkey k1, lookupkey_t k2) {
return k1.num == k2.key.num;
}
static _upb_value *mutable_array(upb_inttable *t) {
return (_upb_value*)t->array;
}
static _upb_value *inttable_val(upb_inttable *t, uintptr_t key) {
if (key < t->array_size) {
return upb_arrhas(t->array[key]) ? &(mutable_array(t)[key]) : NULL;
} else {
upb_tabent *e =
findentry_mutable(&t->t, intkey(key), upb_inthash(key), &inteql);
return e ? &e->val : NULL;
}
}
static const _upb_value *inttable_val_const(const upb_inttable *t,
uintptr_t key) {
return inttable_val((upb_inttable*)t, key);
}
size_t upb_inttable_count(const upb_inttable *t) {
return t->t.count + t->array_count;
}
static void check(upb_inttable *t) {
UPB_UNUSED(t);
#if defined(UPB_DEBUG_TABLE) && !defined(NDEBUG)
// This check is very expensive (makes inserts/deletes O(N)).
size_t count = 0;
upb_inttable_iter i;
upb_inttable_begin(&i, t);
for(; !upb_inttable_done(&i); upb_inttable_next(&i), count++) {
assert(upb_inttable_lookup(t, upb_inttable_iter_key(&i), NULL));
}
assert(count == upb_inttable_count(t));
#endif
}
bool upb_inttable_sizedinit(upb_inttable *t, upb_ctype_t ctype,
size_t asize, int hsize_lg2) {
if (!init(&t->t, ctype, hsize_lg2)) return false;
// Always make the array part at least 1 long, so that we know key 0
// won't be in the hash part, which simplifies things.
t->array_size = UPB_MAX(1, asize);
t->array_count = 0;
size_t array_bytes = t->array_size * sizeof(upb_value);
t->array = malloc(array_bytes);
if (!t->array) {
uninit(&t->t);
return false;
}
memset(mutable_array(t), 0xff, array_bytes);
check(t);
return true;
}
bool upb_inttable_init(upb_inttable *t, upb_ctype_t ctype) {
return upb_inttable_sizedinit(t, ctype, 0, 4);
}
void upb_inttable_uninit(upb_inttable *t) {
uninit(&t->t);
free(mutable_array(t));
}
bool upb_inttable_insert(upb_inttable *t, uintptr_t key, upb_value val) {
assert(upb_arrhas(val.val));
if (key < t->array_size) {
assert(!upb_arrhas(t->array[key]));
t->array_count++;
mutable_array(t)[key] = val.val;
} else {
if (isfull(&t->t)) {
// Need to resize the hash part, but we re-use the array part.
upb_table new_table;
if (!init(&new_table, t->t.ctype, t->t.size_lg2 + 1))
return false;
size_t i;
for (i = begin(&t->t); i < upb_table_size(&t->t); i = next(&t->t, i)) {
const upb_tabent *e = &t->t.entries[i];
upb_value v;
_upb_value_setval(&v, e->val, t->t.ctype);
uint32_t hash = upb_inthash(e->key.num);
insert(&new_table, intkey(e->key.num), v, hash, &inthash, &inteql);
}
assert(t->t.count == new_table.count);
uninit(&t->t);
t->t = new_table;
}
insert(&t->t, intkey(key), val, upb_inthash(key), &inthash, &inteql);
}
check(t);
return true;
}
bool upb_inttable_lookup(const upb_inttable *t, uintptr_t key, upb_value *v) {
const _upb_value *table_v = inttable_val_const(t, key);
if (!table_v) return false;
if (v) _upb_value_setval(v, *table_v, t->t.ctype);
return true;
}
bool upb_inttable_replace(upb_inttable *t, uintptr_t key, upb_value val) {
_upb_value *table_v = inttable_val(t, key);
if (!table_v) return false;
*table_v = val.val;
return true;
}
bool upb_inttable_remove(upb_inttable *t, uintptr_t key, upb_value *val) {
bool success;
if (key < t->array_size) {
if (upb_arrhas(t->array[key])) {
t->array_count--;
if (val) {
_upb_value_setval(val, t->array[key], t->t.ctype);
}
_upb_value empty = UPB_ARRAY_EMPTYENT;
mutable_array(t)[key] = empty;
success = true;
} else {
success = false;
}
} else {
upb_tabkey removed;
uint32_t hash = upb_inthash(key);
success = rm(&t->t, intkey(key), val, &removed, hash, &inteql);
}
check(t);
return success;
}
bool upb_inttable_push(upb_inttable *t, upb_value val) {
return upb_inttable_insert(t, upb_inttable_count(t), val);
}
upb_value upb_inttable_pop(upb_inttable *t) {
upb_value val;
bool ok = upb_inttable_remove(t, upb_inttable_count(t) - 1, &val);
UPB_ASSERT_VAR(ok, ok);
return val;
}
bool upb_inttable_insertptr(upb_inttable *t, const void *key, upb_value val) {
return upb_inttable_insert(t, (uintptr_t)key, val);
}
bool upb_inttable_lookupptr(const upb_inttable *t, const void *key,
upb_value *v) {
return upb_inttable_lookup(t, (uintptr_t)key, v);
}
bool upb_inttable_removeptr(upb_inttable *t, const void *key, upb_value *val) {
return upb_inttable_remove(t, (uintptr_t)key, val);
}
void upb_inttable_compact(upb_inttable *t) {
// Create a power-of-two histogram of the table keys.
int counts[UPB_MAXARRSIZE + 1] = {0};
uintptr_t max_key = 0;
upb_inttable_iter i;
upb_inttable_begin(&i, t);
for (; !upb_inttable_done(&i); upb_inttable_next(&i)) {
uintptr_t key = upb_inttable_iter_key(&i);
if (key > max_key) {
max_key = key;
}
counts[log2ceil(key)]++;
}
int arr_size;
int arr_count = upb_inttable_count(t);
if (upb_inttable_count(t) >= max_key * MIN_DENSITY) {
// We can put 100% of the entries in the array part.
arr_size = max_key + 1;
} else {
// Find the largest power of two that satisfies the MIN_DENSITY definition.
for (int size_lg2 = ARRAY_SIZE(counts) - 1; size_lg2 > 1; size_lg2--) {
arr_size = 1 << size_lg2;
arr_count -= counts[size_lg2];
if (arr_count >= arr_size * MIN_DENSITY) {
break;
}
}
}
// Array part must always be at least 1 entry large to catch lookups of key
// 0. Key 0 must always be in the array part because "0" in the hash part
// denotes an empty entry.
arr_size = UPB_MAX(arr_size, 1);
// Insert all elements into new, perfectly-sized table.
int hash_count = upb_inttable_count(t) - arr_count;
int hash_size = hash_count ? (hash_count / MAX_LOAD) + 1 : 0;
int hashsize_lg2 = log2ceil(hash_size);
assert(hash_count >= 0);
upb_inttable new_t;
upb_inttable_sizedinit(&new_t, t->t.ctype, arr_size, hashsize_lg2);
upb_inttable_begin(&i, t);
for (; !upb_inttable_done(&i); upb_inttable_next(&i)) {
uintptr_t k = upb_inttable_iter_key(&i);
upb_inttable_insert(&new_t, k, upb_inttable_iter_value(&i));
}
assert(new_t.array_size == arr_size);
assert(new_t.t.size_lg2 == hashsize_lg2);
upb_inttable_uninit(t);
*t = new_t;
}
// Iteration.
static const upb_tabent *int_tabent(const upb_inttable_iter *i) {
assert(!i->array_part);
return &i->t->t.entries[i->index];
}
static _upb_value int_arrent(const upb_inttable_iter *i) {
assert(i->array_part);
return i->t->array[i->index];
}
void upb_inttable_begin(upb_inttable_iter *i, const upb_inttable *t) {
i->t = t;
i->index = -1;
i->array_part = true;
upb_inttable_next(i);
}
void upb_inttable_next(upb_inttable_iter *iter) {
const upb_inttable *t = iter->t;
if (iter->array_part) {
while (++iter->index < t->array_size) {
if (upb_arrhas(int_arrent(iter))) {
return;
}
}
iter->array_part = false;
iter->index = begin(&t->t);
} else {
iter->index = next(&t->t, iter->index);
}
}
bool upb_inttable_done(const upb_inttable_iter *i) {
if (i->array_part) {
return i->index >= i->t->array_size ||
!upb_arrhas(int_arrent(i));
} else {
return i->index >= upb_table_size(&i->t->t) ||
upb_tabent_isempty(int_tabent(i));
}
}
uintptr_t upb_inttable_iter_key(const upb_inttable_iter *i) {
assert(!upb_inttable_done(i));
return i->array_part ? i->index : int_tabent(i)->key.num;
}
upb_value upb_inttable_iter_value(const upb_inttable_iter *i) {
assert(!upb_inttable_done(i));
return _upb_value_val(
i->array_part ? i->t->array[i->index] : int_tabent(i)->val,
i->t->t.ctype);
}
void upb_inttable_iter_setdone(upb_inttable_iter *i) {
i->index = SIZE_MAX;
i->array_part = false;
}
bool upb_inttable_iter_isequal(const upb_inttable_iter *i1,
const upb_inttable_iter *i2) {
if (upb_inttable_done(i1) && upb_inttable_done(i2))
return true;
return i1->t == i2->t && i1->index == i2->index &&
i1->array_part == i2->array_part;
}
#ifdef UPB_UNALIGNED_READS_OK
//-----------------------------------------------------------------------------
// MurmurHash2, by Austin Appleby (released as public domain).
// Reformatted and C99-ified by Joshua Haberman.
// Note - This code makes a few assumptions about how your machine behaves -
// 1. We can read a 4-byte value from any address without crashing
// 2. sizeof(int) == 4 (in upb this limitation is removed by using uint32_t
// And it has a few limitations -
// 1. It will not work incrementally.
// 2. It will not produce the same results on little-endian and big-endian
// machines.
uint32_t MurmurHash2(const void *key, size_t len, uint32_t seed) {
// 'm' and 'r' are mixing constants generated offline.
// They're not really 'magic', they just happen to work well.
const uint32_t m = 0x5bd1e995;
const int32_t r = 24;
// Initialize the hash to a 'random' value
uint32_t h = seed ^ len;
// Mix 4 bytes at a time into the hash
const uint8_t * data = (const uint8_t *)key;
while(len >= 4) {
uint32_t k = *(uint32_t *)data;
k *= m;
k ^= k >> r;
k *= m;
h *= m;
h ^= k;
data += 4;
len -= 4;
}
// Handle the last few bytes of the input array
switch(len) {
case 3: h ^= data[2] << 16;
case 2: h ^= data[1] << 8;
case 1: h ^= data[0]; h *= m;
};
// Do a few final mixes of the hash to ensure the last few
// bytes are well-incorporated.
h ^= h >> 13;
h *= m;
h ^= h >> 15;
return h;
}
#else // !UPB_UNALIGNED_READS_OK
//-----------------------------------------------------------------------------
// MurmurHashAligned2, by Austin Appleby
// Same algorithm as MurmurHash2, but only does aligned reads - should be safer
// on certain platforms.
// Performance will be lower than MurmurHash2
#define MIX(h,k,m) { k *= m; k ^= k >> r; k *= m; h *= m; h ^= k; }
uint32_t MurmurHash2(const void * key, size_t len, uint32_t seed) {
const uint32_t m = 0x5bd1e995;
const int32_t r = 24;
const uint8_t * data = (const uint8_t *)key;
uint32_t h = seed ^ len;
uint8_t align = (uintptr_t)data & 3;
if(align && (len >= 4)) {
// Pre-load the temp registers
uint32_t t = 0, d = 0;
switch(align) {
case 1: t |= data[2] << 16;
case 2: t |= data[1] << 8;
case 3: t |= data[0];
}
t <<= (8 * align);
data += 4-align;
len -= 4-align;
int32_t sl = 8 * (4-align);
int32_t sr = 8 * align;
// Mix
while(len >= 4) {
d = *(uint32_t *)data;
t = (t >> sr) | (d << sl);
uint32_t k = t;
MIX(h,k,m);
t = d;
data += 4;
len -= 4;
}
// Handle leftover data in temp registers
d = 0;
if(len >= align) {
switch(align) {
case 3: d |= data[2] << 16;
case 2: d |= data[1] << 8;
case 1: d |= data[0];
}
uint32_t k = (t >> sr) | (d << sl);
MIX(h,k,m);
data += align;
len -= align;
//----------
// Handle tail bytes
switch(len) {
case 3: h ^= data[2] << 16;
case 2: h ^= data[1] << 8;
case 1: h ^= data[0]; h *= m;
};
} else {
switch(len) {
case 3: d |= data[2] << 16;
case 2: d |= data[1] << 8;
case 1: d |= data[0];
case 0: h ^= (t >> sr) | (d << sl); h *= m;
}
}
h ^= h >> 13;
h *= m;
h ^= h >> 15;
return h;
} else {
while(len >= 4) {
uint32_t k = *(uint32_t *)data;
MIX(h,k,m);
data += 4;
len -= 4;
}
//----------
// Handle tail bytes
switch(len) {
case 3: h ^= data[2] << 16;
case 2: h ^= data[1] << 8;
case 1: h ^= data[0]; h *= m;
};
h ^= h >> 13;
h *= m;
h ^= h >> 15;
return h;
}
}
#undef MIX
#endif // UPB_UNALIGNED_READS_OK
/*
* upb - a minimalist implementation of protocol buffers.
*
* Copyright (c) 2009-2012 Google Inc. See LICENSE for details.
* Author: Josh Haberman <jhaberman@gmail.com>
*/
#include <errno.h>
#include <stdarg.h>
#include <stddef.h>
#include <stdint.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
bool upb_dumptostderr(void *closure, const upb_status* status) {
UPB_UNUSED(closure);
fprintf(stderr, "%s\n", upb_status_errmsg(status));
return false;
}
// Guarantee null-termination and provide ellipsis truncation.
// It may be tempting to "optimize" this by initializing these final
// four bytes up-front and then being careful never to overwrite them,
// this is safer and simpler.
static void nullz(upb_status *status) {
const char *ellipsis = "...";
size_t len = strlen(ellipsis);
assert(sizeof(status->msg) > len);
memcpy(status->msg + sizeof(status->msg) - len, ellipsis, len);
}
void upb_status_clear(upb_status *status) {
Update upb amalgamation.
10 years ago
if (!status) return;
status->ok_ = true;
status->code_ = 0;
status->msg[0] = '\0';
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
}
bool upb_ok(const upb_status *status) { return status->ok_; }
upb_errorspace *upb_status_errspace(const upb_status *status) {
return status->error_space_;
}
int upb_status_errcode(const upb_status *status) { return status->code_; }
const char *upb_status_errmsg(const upb_status *status) { return status->msg; }
void upb_status_seterrmsg(upb_status *status, const char *msg) {
if (!status) return;
status->ok_ = false;
strncpy(status->msg, msg, sizeof(status->msg));
nullz(status);
}
void upb_status_seterrf(upb_status *status, const char *fmt, ...) {
va_list args;
va_start(args, fmt);
upb_status_vseterrf(status, fmt, args);
va_end(args);
}
void upb_status_vseterrf(upb_status *status, const char *fmt, va_list args) {
if (!status) return;
status->ok_ = false;
vsnprintf(status->msg, sizeof(status->msg), fmt, args);
nullz(status);
}
void upb_status_seterrcode(upb_status *status, upb_errorspace *space,
int code) {
if (!status) return;
status->ok_ = false;
status->error_space_ = space;
status->code_ = code;
space->set_message(status, code);
}
void upb_status_copy(upb_status *to, const upb_status *from) {
if (!to) return;
*to = *from;
}
// This file was generated by upbc (the upb compiler).
// Do not edit -- your changes will be discarded when the file is
// regenerated.
static const upb_msgdef msgs[20];
static const upb_fielddef fields[81];
static const upb_enumdef enums[4];
static const upb_tabent strentries[236];
static const upb_tabent intentries[14];
static const _upb_value arrays[232];
#ifdef UPB_DEBUG_REFS
static upb_inttable reftables[212];
#endif
static const upb_msgdef msgs[20] = {
UPB_MSGDEF_INIT("google.protobuf.DescriptorProto", 27, 6, UPB_INTTABLE_INIT(0, 0, UPB_CTYPE_PTR, 0, NULL, &arrays[0], 8, 7), UPB_STRTABLE_INIT(7, 15, UPB_CTYPE_PTR, 4, &strentries[0]),&reftables[0], &reftables[1]),
UPB_MSGDEF_INIT("google.protobuf.DescriptorProto.ExtensionRange", 4, 0, UPB_INTTABLE_INIT(0, 0, UPB_CTYPE_PTR, 0, NULL, &arrays[8], 3, 2), UPB_STRTABLE_INIT(2, 3, UPB_CTYPE_PTR, 2, &strentries[16]),&reftables[2], &reftables[3]),
UPB_MSGDEF_INIT("google.protobuf.EnumDescriptorProto", 11, 2, UPB_INTTABLE_INIT(0, 0, UPB_CTYPE_PTR, 0, NULL, &arrays[11], 4, 3), UPB_STRTABLE_INIT(3, 3, UPB_CTYPE_PTR, 2, &strentries[20]),&reftables[4], &reftables[5]),
UPB_MSGDEF_INIT("google.protobuf.EnumOptions", 7, 1, UPB_INTTABLE_INIT(1, 1, UPB_CTYPE_PTR, 1, &intentries[0], &arrays[15], 8, 1), UPB_STRTABLE_INIT(2, 3, UPB_CTYPE_PTR, 2, &strentries[24]),&reftables[6], &reftables[7]),
UPB_MSGDEF_INIT("google.protobuf.EnumValueDescriptorProto", 8, 1, UPB_INTTABLE_INIT(0, 0, UPB_CTYPE_PTR, 0, NULL, &arrays[23], 4, 3), UPB_STRTABLE_INIT(3, 3, UPB_CTYPE_PTR, 2, &strentries[28]),&reftables[8], &reftables[9]),
UPB_MSGDEF_INIT("google.protobuf.EnumValueOptions", 6, 1, UPB_INTTABLE_INIT(1, 1, UPB_CTYPE_PTR, 1, &intentries[2], &arrays[27], 4, 0), UPB_STRTABLE_INIT(1, 3, UPB_CTYPE_PTR, 2, &strentries[32]),&reftables[10], &reftables[11]),
UPB_MSGDEF_INIT("google.protobuf.FieldDescriptorProto", 19, 1, UPB_INTTABLE_INIT(0, 0, UPB_CTYPE_PTR, 0, NULL, &arrays[31], 9, 8), UPB_STRTABLE_INIT(8, 15, UPB_CTYPE_PTR, 4, &strentries[36]),&reftables[12], &reftables[13]),
UPB_MSGDEF_INIT("google.protobuf.FieldOptions", 14, 1, UPB_INTTABLE_INIT(1, 1, UPB_CTYPE_PTR, 1, &intentries[4], &arrays[40], 32, 6), UPB_STRTABLE_INIT(7, 15, UPB_CTYPE_PTR, 4, &strentries[52]),&reftables[14], &reftables[15]),
UPB_MSGDEF_INIT("google.protobuf.FileDescriptorProto", 39, 6, UPB_INTTABLE_INIT(0, 0, UPB_CTYPE_PTR, 0, NULL, &arrays[72], 12, 11), UPB_STRTABLE_INIT(11, 15, UPB_CTYPE_PTR, 4, &strentries[68]),&reftables[16], &reftables[17]),
UPB_MSGDEF_INIT("google.protobuf.FileDescriptorSet", 6, 1, UPB_INTTABLE_INIT(0, 0, UPB_CTYPE_PTR, 0, NULL, &arrays[84], 2, 1), UPB_STRTABLE_INIT(1, 3, UPB_CTYPE_PTR, 2, &strentries[84]),&reftables[18], &reftables[19]),
UPB_MSGDEF_INIT("google.protobuf.FileOptions", 21, 1, UPB_INTTABLE_INIT(1, 1, UPB_CTYPE_PTR, 1, &intentries[6], &arrays[86], 64, 9), UPB_STRTABLE_INIT(10, 15, UPB_CTYPE_PTR, 4, &strentries[88]),&reftables[20], &reftables[21]),
UPB_MSGDEF_INIT("google.protobuf.MessageOptions", 8, 1, UPB_INTTABLE_INIT(1, 1, UPB_CTYPE_PTR, 1, &intentries[8], &arrays[150], 16, 2), UPB_STRTABLE_INIT(3, 3, UPB_CTYPE_PTR, 2, &strentries[104]),&reftables[22], &reftables[23]),
UPB_MSGDEF_INIT("google.protobuf.MethodDescriptorProto", 13, 1, UPB_INTTABLE_INIT(0, 0, UPB_CTYPE_PTR, 0, NULL, &arrays[166], 5, 4), UPB_STRTABLE_INIT(4, 7, UPB_CTYPE_PTR, 3, &strentries[108]),&reftables[24], &reftables[25]),
UPB_MSGDEF_INIT("google.protobuf.MethodOptions", 6, 1, UPB_INTTABLE_INIT(1, 1, UPB_CTYPE_PTR, 1, &intentries[10], &arrays[171], 4, 0), UPB_STRTABLE_INIT(1, 3, UPB_CTYPE_PTR, 2, &strentries[116]),&reftables[26], &reftables[27]),
UPB_MSGDEF_INIT("google.protobuf.ServiceDescriptorProto", 11, 2, UPB_INTTABLE_INIT(0, 0, UPB_CTYPE_PTR, 0, NULL, &arrays[175], 4, 3), UPB_STRTABLE_INIT(3, 3, UPB_CTYPE_PTR, 2, &strentries[120]),&reftables[28], &reftables[29]),
UPB_MSGDEF_INIT("google.protobuf.ServiceOptions", 6, 1, UPB_INTTABLE_INIT(1, 1, UPB_CTYPE_PTR, 1, &intentries[12], &arrays[179], 4, 0), UPB_STRTABLE_INIT(1, 3, UPB_CTYPE_PTR, 2, &strentries[124]),&reftables[30], &reftables[31]),
UPB_MSGDEF_INIT("google.protobuf.SourceCodeInfo", 6, 1, UPB_INTTABLE_INIT(0, 0, UPB_CTYPE_PTR, 0, NULL, &arrays[183], 2, 1), UPB_STRTABLE_INIT(1, 3, UPB_CTYPE_PTR, 2, &strentries[128]),&reftables[32], &reftables[33]),
UPB_MSGDEF_INIT("google.protobuf.SourceCodeInfo.Location", 14, 0, UPB_INTTABLE_INIT(0, 0, UPB_CTYPE_PTR, 0, NULL, &arrays[185], 5, 4), UPB_STRTABLE_INIT(4, 7, UPB_CTYPE_PTR, 3, &strentries[132]),&reftables[34], &reftables[35]),
UPB_MSGDEF_INIT("google.protobuf.UninterpretedOption", 18, 1, UPB_INTTABLE_INIT(0, 0, UPB_CTYPE_PTR, 0, NULL, &arrays[190], 9, 7), UPB_STRTABLE_INIT(7, 15, UPB_CTYPE_PTR, 4, &strentries[140]),&reftables[36], &reftables[37]),
UPB_MSGDEF_INIT("google.protobuf.UninterpretedOption.NamePart", 6, 0, UPB_INTTABLE_INIT(0, 0, UPB_CTYPE_PTR, 0, NULL, &arrays[199], 3, 2), UPB_STRTABLE_INIT(2, 3, UPB_CTYPE_PTR, 2, &strentries[156]),&reftables[38], &reftables[39]),
};
static const upb_fielddef fields[81] = {
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_STRING, 0, false, false, false, false, "aggregate_value", 8, &msgs[18], NULL, 15, 6, {0},&reftables[40], &reftables[41]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_BOOL, 0, false, false, false, false, "allow_alias", 2, &msgs[3], NULL, 6, 1, {0},&reftables[42], &reftables[43]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_BOOL, 0, false, false, false, false, "cc_generic_services", 16, &msgs[10], NULL, 17, 6, {0},&reftables[44], &reftables[45]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_ENUM, 0, false, false, false, false, "ctype", 1, &msgs[7], UPB_UPCAST(&enums[2]), 6, 1, {0},&reftables[46], &reftables[47]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_STRING, 0, false, false, false, false, "default_value", 7, &msgs[6], NULL, 16, 7, {0},&reftables[48], &reftables[49]),
UPB_FIELDDEF_INIT(UPB_LABEL_REPEATED, UPB_TYPE_STRING, 0, false, false, false, false, "dependency", 3, &msgs[8], NULL, 30, 8, {0},&reftables[50], &reftables[51]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_BOOL, 0, false, false, false, false, "deprecated", 3, &msgs[7], NULL, 8, 3, {0},&reftables[52], &reftables[53]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_DOUBLE, 0, false, false, false, false, "double_value", 6, &msgs[18], NULL, 11, 4, {0},&reftables[54], &reftables[55]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_INT32, UPB_INTFMT_VARIABLE, false, false, false, false, "end", 2, &msgs[1], NULL, 3, 1, {0},&reftables[56], &reftables[57]),
UPB_FIELDDEF_INIT(UPB_LABEL_REPEATED, UPB_TYPE_MESSAGE, 0, false, false, false, false, "enum_type", 4, &msgs[0], UPB_UPCAST(&msgs[2]), 16, 2, {0},&reftables[58], &reftables[59]),
UPB_FIELDDEF_INIT(UPB_LABEL_REPEATED, UPB_TYPE_MESSAGE, 0, false, false, false, false, "enum_type", 5, &msgs[8], UPB_UPCAST(&msgs[2]), 13, 1, {0},&reftables[60], &reftables[61]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_STRING, 0, false, false, false, false, "experimental_map_key", 9, &msgs[7], NULL, 10, 5, {0},&reftables[62], &reftables[63]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_STRING, 0, false, false, false, false, "extendee", 2, &msgs[6], NULL, 7, 2, {0},&reftables[64], &reftables[65]),
UPB_FIELDDEF_INIT(UPB_LABEL_REPEATED, UPB_TYPE_MESSAGE, 0, false, false, false, false, "extension", 7, &msgs[8], UPB_UPCAST(&msgs[6]), 19, 3, {0},&reftables[66], &reftables[67]),
UPB_FIELDDEF_INIT(UPB_LABEL_REPEATED, UPB_TYPE_MESSAGE, 0, false, false, false, false, "extension", 6, &msgs[0], UPB_UPCAST(&msgs[6]), 22, 4, {0},&reftables[68], &reftables[69]),
UPB_FIELDDEF_INIT(UPB_LABEL_REPEATED, UPB_TYPE_MESSAGE, 0, false, false, false, false, "extension_range", 5, &msgs[0], UPB_UPCAST(&msgs[1]), 19, 3, {0},&reftables[70], &reftables[71]),
UPB_FIELDDEF_INIT(UPB_LABEL_REPEATED, UPB_TYPE_MESSAGE, 0, false, false, false, false, "field", 2, &msgs[0], UPB_UPCAST(&msgs[6]), 10, 0, {0},&reftables[72], &reftables[73]),
UPB_FIELDDEF_INIT(UPB_LABEL_REPEATED, UPB_TYPE_MESSAGE, 0, false, false, false, false, "file", 1, &msgs[9], UPB_UPCAST(&msgs[8]), 5, 0, {0},&reftables[74], &reftables[75]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_STRING, 0, false, false, false, false, "go_package", 11, &msgs[10], NULL, 14, 5, {0},&reftables[76], &reftables[77]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_STRING, 0, false, false, false, false, "identifier_value", 3, &msgs[18], NULL, 6, 1, {0},&reftables[78], &reftables[79]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_STRING, 0, false, false, false, false, "input_type", 2, &msgs[12], NULL, 7, 2, {0},&reftables[80], &reftables[81]),
UPB_FIELDDEF_INIT(UPB_LABEL_REQUIRED, UPB_TYPE_BOOL, 0, false, false, false, false, "is_extension", 2, &msgs[19], NULL, 5, 1, {0},&reftables[82], &reftables[83]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_BOOL, 0, false, false, false, false, "java_generate_equals_and_hash", 20, &msgs[10], NULL, 20, 9, {0},&reftables[84], &reftables[85]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_BOOL, 0, false, false, false, false, "java_generic_services", 17, &msgs[10], NULL, 18, 7, {0},&reftables[86], &reftables[87]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_BOOL, 0, false, false, false, false, "java_multiple_files", 10, &msgs[10], NULL, 13, 4, {0},&reftables[88], &reftables[89]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_STRING, 0, false, false, false, false, "java_outer_classname", 8, &msgs[10], NULL, 9, 2, {0},&reftables[90], &reftables[91]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_STRING, 0, false, false, false, false, "java_package", 1, &msgs[10], NULL, 6, 1, {0},&reftables[92], &reftables[93]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_ENUM, 0, false, false, false, false, "label", 4, &msgs[6], UPB_UPCAST(&enums[0]), 11, 4, {0},&reftables[94], &reftables[95]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_BOOL, 0, false, false, false, false, "lazy", 5, &msgs[7], NULL, 9, 4, {0},&reftables[96], &reftables[97]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_STRING, 0, false, false, false, false, "leading_comments", 3, &msgs[17], NULL, 8, 2, {0},&reftables[98], &reftables[99]),
UPB_FIELDDEF_INIT(UPB_LABEL_REPEATED, UPB_TYPE_MESSAGE, 0, false, false, false, false, "location", 1, &msgs[16], UPB_UPCAST(&msgs[17]), 5, 0, {0},&reftables[100], &reftables[101]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_BOOL, 0, false, false, false, false, "message_set_wire_format", 1, &msgs[11], NULL, 6, 1, {0},&reftables[102], &reftables[103]),
UPB_FIELDDEF_INIT(UPB_LABEL_REPEATED, UPB_TYPE_MESSAGE, 0, false, false, false, false, "message_type", 4, &msgs[8], UPB_UPCAST(&msgs[0]), 10, 0, {0},&reftables[104], &reftables[105]),
UPB_FIELDDEF_INIT(UPB_LABEL_REPEATED, UPB_TYPE_MESSAGE, 0, false, false, false, false, "method", 2, &msgs[14], UPB_UPCAST(&msgs[12]), 6, 0, {0},&reftables[106], &reftables[107]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_STRING, 0, false, false, false, false, "name", 1, &msgs[8], NULL, 22, 6, {0},&reftables[108], &reftables[109]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_STRING, 0, false, false, false, false, "name", 1, &msgs[14], NULL, 8, 2, {0},&reftables[110], &reftables[111]),
UPB_FIELDDEF_INIT(UPB_LABEL_REPEATED, UPB_TYPE_MESSAGE, 0, false, false, false, false, "name", 2, &msgs[18], UPB_UPCAST(&msgs[19]), 5, 0, {0},&reftables[112], &reftables[113]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_STRING, 0, false, false, false, false, "name", 1, &msgs[4], NULL, 4, 1, {0},&reftables[114], &reftables[115]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_STRING, 0, false, false, false, false, "name", 1, &msgs[0], NULL, 24, 6, {0},&reftables[116], &reftables[117]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_STRING, 0, false, false, false, false, "name", 1, &msgs[12], NULL, 4, 1, {0},&reftables[118], &reftables[119]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_STRING, 0, false, false, false, false, "name", 1, &msgs[2], NULL, 8, 2, {0},&reftables[120], &reftables[121]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_STRING, 0, false, false, false, false, "name", 1, &msgs[6], NULL, 4, 1, {0},&reftables[122], &reftables[123]),
UPB_FIELDDEF_INIT(UPB_LABEL_REQUIRED, UPB_TYPE_STRING, 0, false, false, false, false, "name_part", 1, &msgs[19], NULL, 2, 0, {0},&reftables[124], &reftables[125]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_INT64, UPB_INTFMT_VARIABLE, false, false, false, false, "negative_int_value", 5, &msgs[18], NULL, 10, 3, {0},&reftables[126], &reftables[127]),
UPB_FIELDDEF_INIT(UPB_LABEL_REPEATED, UPB_TYPE_MESSAGE, 0, false, false, false, false, "nested_type", 3, &msgs[0], UPB_UPCAST(&msgs[0]), 13, 1, {0},&reftables[128], &reftables[129]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_BOOL, 0, false, false, false, false, "no_standard_descriptor_accessor", 2, &msgs[11], NULL, 7, 2, {0},&reftables[130], &reftables[131]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_INT32, UPB_INTFMT_VARIABLE, false, false, false, false, "number", 3, &msgs[6], NULL, 10, 3, {0},&reftables[132], &reftables[133]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_INT32, UPB_INTFMT_VARIABLE, false, false, false, false, "number", 2, &msgs[4], NULL, 7, 2, {0},&reftables[134], &reftables[135]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_ENUM, 0, false, false, false, false, "optimize_for", 9, &msgs[10], UPB_UPCAST(&enums[3]), 12, 3, {0},&reftables[136], &reftables[137]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_MESSAGE, 0, false, false, false, false, "options", 7, &msgs[0], UPB_UPCAST(&msgs[11]), 23, 5, {0},&reftables[138], &reftables[139]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_MESSAGE, 0, false, false, false, false, "options", 3, &msgs[2], UPB_UPCAST(&msgs[3]), 7, 1, {0},&reftables[140], &reftables[141]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_MESSAGE, 0, false, false, false, false, "options", 8, &msgs[6], UPB_UPCAST(&msgs[7]), 3, 0, {0},&reftables[142], &reftables[143]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_MESSAGE, 0, false, false, false, false, "options", 3, &msgs[4], UPB_UPCAST(&msgs[5]), 3, 0, {0},&reftables[144], &reftables[145]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_MESSAGE, 0, false, false, false, false, "options", 8, &msgs[8], UPB_UPCAST(&msgs[10]), 20, 4, {0},&reftables[146], &reftables[147]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_MESSAGE, 0, false, false, false, false, "options", 3, &msgs[14], UPB_UPCAST(&msgs[15]), 7, 1, {0},&reftables[148], &reftables[149]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_MESSAGE, 0, false, false, false, false, "options", 4, &msgs[12], UPB_UPCAST(&msgs[13]), 3, 0, {0},&reftables[150], &reftables[151]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_STRING, 0, false, false, false, false, "output_type", 3, &msgs[12], NULL, 10, 3, {0},&reftables[152], &reftables[153]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_STRING, 0, false, false, false, false, "package", 2, &msgs[8], NULL, 25, 7, {0},&reftables[154], &reftables[155]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_BOOL, 0, false, false, false, false, "packed", 2, &msgs[7], NULL, 7, 2, {0},&reftables[156], &reftables[157]),
UPB_FIELDDEF_INIT(UPB_LABEL_REPEATED, UPB_TYPE_INT32, UPB_INTFMT_VARIABLE, false, false, false, true, "path", 1, &msgs[17], NULL, 4, 0, {0},&reftables[158], &reftables[159]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_UINT64, UPB_INTFMT_VARIABLE, false, false, false, false, "positive_int_value", 4, &msgs[18], NULL, 9, 2, {0},&reftables[160], &reftables[161]),
UPB_FIELDDEF_INIT(UPB_LABEL_REPEATED, UPB_TYPE_INT32, UPB_INTFMT_VARIABLE, false, false, false, false, "public_dependency", 10, &msgs[8], NULL, 35, 9, {0},&reftables[162], &reftables[163]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_BOOL, 0, false, false, false, false, "py_generic_services", 18, &msgs[10], NULL, 19, 8, {0},&reftables[164], &reftables[165]),
UPB_FIELDDEF_INIT(UPB_LABEL_REPEATED, UPB_TYPE_MESSAGE, 0, false, false, false, false, "service", 6, &msgs[8], UPB_UPCAST(&msgs[14]), 16, 2, {0},&reftables[166], &reftables[167]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_MESSAGE, 0, false, false, false, false, "source_code_info", 9, &msgs[8], UPB_UPCAST(&msgs[16]), 21, 5, {0},&reftables[168], &reftables[169]),
UPB_FIELDDEF_INIT(UPB_LABEL_REPEATED, UPB_TYPE_INT32, UPB_INTFMT_VARIABLE, false, false, false, true, "span", 2, &msgs[17], NULL, 7, 1, {0},&reftables[170], &reftables[171]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_INT32, UPB_INTFMT_VARIABLE, false, false, false, false, "start", 1, &msgs[1], NULL, 2, 0, {0},&reftables[172], &reftables[173]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_BYTES, 0, false, false, false, false, "string_value", 7, &msgs[18], NULL, 12, 5, {0},&reftables[174], &reftables[175]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_STRING, 0, false, false, false, false, "trailing_comments", 4, &msgs[17], NULL, 11, 3, {0},&reftables[176], &reftables[177]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_ENUM, 0, false, false, false, false, "type", 5, &msgs[6], UPB_UPCAST(&enums[1]), 12, 5, {0},&reftables[178], &reftables[179]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_STRING, 0, false, false, false, false, "type_name", 6, &msgs[6], NULL, 13, 6, {0},&reftables[180], &reftables[181]),
UPB_FIELDDEF_INIT(UPB_LABEL_REPEATED, UPB_TYPE_MESSAGE, 0, false, false, false, false, "uninterpreted_option", 999, &msgs[5], UPB_UPCAST(&msgs[18]), 5, 0, {0},&reftables[182], &reftables[183]),
UPB_FIELDDEF_INIT(UPB_LABEL_REPEATED, UPB_TYPE_MESSAGE, 0, false, false, false, false, "uninterpreted_option", 999, &msgs[15], UPB_UPCAST(&msgs[18]), 5, 0, {0},&reftables[184], &reftables[185]),
UPB_FIELDDEF_INIT(UPB_LABEL_REPEATED, UPB_TYPE_MESSAGE, 0, false, false, false, false, "uninterpreted_option", 999, &msgs[3], UPB_UPCAST(&msgs[18]), 5, 0, {0},&reftables[186], &reftables[187]),
UPB_FIELDDEF_INIT(UPB_LABEL_REPEATED, UPB_TYPE_MESSAGE, 0, false, false, false, false, "uninterpreted_option", 999, &msgs[13], UPB_UPCAST(&msgs[18]), 5, 0, {0},&reftables[188], &reftables[189]),
UPB_FIELDDEF_INIT(UPB_LABEL_REPEATED, UPB_TYPE_MESSAGE, 0, false, false, false, false, "uninterpreted_option", 999, &msgs[10], UPB_UPCAST(&msgs[18]), 5, 0, {0},&reftables[190], &reftables[191]),
UPB_FIELDDEF_INIT(UPB_LABEL_REPEATED, UPB_TYPE_MESSAGE, 0, false, false, false, false, "uninterpreted_option", 999, &msgs[11], UPB_UPCAST(&msgs[18]), 5, 0, {0},&reftables[192], &reftables[193]),
UPB_FIELDDEF_INIT(UPB_LABEL_REPEATED, UPB_TYPE_MESSAGE, 0, false, false, false, false, "uninterpreted_option", 999, &msgs[7], UPB_UPCAST(&msgs[18]), 5, 0, {0},&reftables[194], &reftables[195]),
UPB_FIELDDEF_INIT(UPB_LABEL_REPEATED, UPB_TYPE_MESSAGE, 0, false, false, false, false, "value", 2, &msgs[2], UPB_UPCAST(&msgs[4]), 6, 0, {0},&reftables[196], &reftables[197]),
UPB_FIELDDEF_INIT(UPB_LABEL_OPTIONAL, UPB_TYPE_BOOL, 0, false, false, false, false, "weak", 10, &msgs[7], NULL, 13, 6, {0},&reftables[198], &reftables[199]),
UPB_FIELDDEF_INIT(UPB_LABEL_REPEATED, UPB_TYPE_INT32, UPB_INTFMT_VARIABLE, false, false, false, false, "weak_dependency", 11, &msgs[8], NULL, 38, 10, {0},&reftables[200], &reftables[201]),
};
static const upb_enumdef enums[4] = {
UPB_ENUMDEF_INIT("google.protobuf.FieldDescriptorProto.Label", UPB_STRTABLE_INIT(3, 3, UPB_CTYPE_INT32, 2, &strentries[160]), UPB_INTTABLE_INIT(0, 0, UPB_CTYPE_CSTR, 0, NULL, &arrays[202], 4, 3), 0, &reftables[202], &reftables[203]),
UPB_ENUMDEF_INIT("google.protobuf.FieldDescriptorProto.Type", UPB_STRTABLE_INIT(18, 31, UPB_CTYPE_INT32, 5, &strentries[164]), UPB_INTTABLE_INIT(0, 0, UPB_CTYPE_CSTR, 0, NULL, &arrays[206], 19, 18), 0, &reftables[204], &reftables[205]),
UPB_ENUMDEF_INIT("google.protobuf.FieldOptions.CType", UPB_STRTABLE_INIT(3, 3, UPB_CTYPE_INT32, 2, &strentries[196]), UPB_INTTABLE_INIT(0, 0, UPB_CTYPE_CSTR, 0, NULL, &arrays[225], 3, 3), 0, &reftables[206], &reftables[207]),
UPB_ENUMDEF_INIT("google.protobuf.FileOptions.OptimizeMode", UPB_STRTABLE_INIT(3, 3, UPB_CTYPE_INT32, 2, &strentries[200]), UPB_INTTABLE_INIT(0, 0, UPB_CTYPE_CSTR, 0, NULL, &arrays[228], 4, 3), 0, &reftables[208], &reftables[209]),
};
static const upb_tabent strentries[236] = {
{UPB_TABKEY_STR("extension"), UPB_VALUE_INIT_CONSTPTR(&fields[14]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("name"), UPB_VALUE_INIT_CONSTPTR(&fields[38]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("field"), UPB_VALUE_INIT_CONSTPTR(&fields[16]), NULL},
{UPB_TABKEY_STR("extension_range"), UPB_VALUE_INIT_CONSTPTR(&fields[15]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("nested_type"), UPB_VALUE_INIT_CONSTPTR(&fields[44]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("options"), UPB_VALUE_INIT_CONSTPTR(&fields[49]), NULL},
{UPB_TABKEY_STR("enum_type"), UPB_VALUE_INIT_CONSTPTR(&fields[9]), &strentries[14]},
{UPB_TABKEY_STR("start"), UPB_VALUE_INIT_CONSTPTR(&fields[66]), NULL},
{UPB_TABKEY_STR("end"), UPB_VALUE_INIT_CONSTPTR(&fields[8]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("value"), UPB_VALUE_INIT_CONSTPTR(&fields[78]), NULL},
{UPB_TABKEY_STR("options"), UPB_VALUE_INIT_CONSTPTR(&fields[50]), NULL},
{UPB_TABKEY_STR("name"), UPB_VALUE_INIT_CONSTPTR(&fields[40]), &strentries[22]},
{UPB_TABKEY_STR("uninterpreted_option"), UPB_VALUE_INIT_CONSTPTR(&fields[73]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("allow_alias"), UPB_VALUE_INIT_CONSTPTR(&fields[1]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("number"), UPB_VALUE_INIT_CONSTPTR(&fields[47]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("options"), UPB_VALUE_INIT_CONSTPTR(&fields[52]), NULL},
{UPB_TABKEY_STR("name"), UPB_VALUE_INIT_CONSTPTR(&fields[37]), &strentries[30]},
{UPB_TABKEY_STR("uninterpreted_option"), UPB_VALUE_INIT_CONSTPTR(&fields[71]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("label"), UPB_VALUE_INIT_CONSTPTR(&fields[27]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("name"), UPB_VALUE_INIT_CONSTPTR(&fields[41]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("number"), UPB_VALUE_INIT_CONSTPTR(&fields[46]), &strentries[49]},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("type_name"), UPB_VALUE_INIT_CONSTPTR(&fields[70]), NULL},
{UPB_TABKEY_STR("extendee"), UPB_VALUE_INIT_CONSTPTR(&fields[12]), NULL},
{UPB_TABKEY_STR("type"), UPB_VALUE_INIT_CONSTPTR(&fields[69]), &strentries[48]},
{UPB_TABKEY_STR("default_value"), UPB_VALUE_INIT_CONSTPTR(&fields[4]), NULL},
{UPB_TABKEY_STR("options"), UPB_VALUE_INIT_CONSTPTR(&fields[51]), NULL},
{UPB_TABKEY_STR("experimental_map_key"), UPB_VALUE_INIT_CONSTPTR(&fields[11]), &strentries[67]},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("weak"), UPB_VALUE_INIT_CONSTPTR(&fields[79]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("packed"), UPB_VALUE_INIT_CONSTPTR(&fields[58]), NULL},
{UPB_TABKEY_STR("lazy"), UPB_VALUE_INIT_CONSTPTR(&fields[28]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("ctype"), UPB_VALUE_INIT_CONSTPTR(&fields[3]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("deprecated"), UPB_VALUE_INIT_CONSTPTR(&fields[6]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("uninterpreted_option"), UPB_VALUE_INIT_CONSTPTR(&fields[77]), NULL},
{UPB_TABKEY_STR("extension"), UPB_VALUE_INIT_CONSTPTR(&fields[13]), NULL},
{UPB_TABKEY_STR("weak_dependency"), UPB_VALUE_INIT_CONSTPTR(&fields[80]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("name"), UPB_VALUE_INIT_CONSTPTR(&fields[34]), NULL},
{UPB_TABKEY_STR("service"), UPB_VALUE_INIT_CONSTPTR(&fields[63]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("source_code_info"), UPB_VALUE_INIT_CONSTPTR(&fields[64]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("dependency"), UPB_VALUE_INIT_CONSTPTR(&fields[5]), NULL},
{UPB_TABKEY_STR("message_type"), UPB_VALUE_INIT_CONSTPTR(&fields[32]), NULL},
{UPB_TABKEY_STR("package"), UPB_VALUE_INIT_CONSTPTR(&fields[57]), NULL},
{UPB_TABKEY_STR("options"), UPB_VALUE_INIT_CONSTPTR(&fields[53]), &strentries[82]},
{UPB_TABKEY_STR("enum_type"), UPB_VALUE_INIT_CONSTPTR(&fields[10]), NULL},
{UPB_TABKEY_STR("public_dependency"), UPB_VALUE_INIT_CONSTPTR(&fields[61]), &strentries[81]},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("file"), UPB_VALUE_INIT_CONSTPTR(&fields[17]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("uninterpreted_option"), UPB_VALUE_INIT_CONSTPTR(&fields[75]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("cc_generic_services"), UPB_VALUE_INIT_CONSTPTR(&fields[2]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("java_multiple_files"), UPB_VALUE_INIT_CONSTPTR(&fields[24]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("java_generic_services"), UPB_VALUE_INIT_CONSTPTR(&fields[23]), &strentries[102]},
{UPB_TABKEY_STR("java_generate_equals_and_hash"), UPB_VALUE_INIT_CONSTPTR(&fields[22]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("go_package"), UPB_VALUE_INIT_CONSTPTR(&fields[18]), NULL},
{UPB_TABKEY_STR("java_package"), UPB_VALUE_INIT_CONSTPTR(&fields[26]), NULL},
{UPB_TABKEY_STR("optimize_for"), UPB_VALUE_INIT_CONSTPTR(&fields[48]), NULL},
{UPB_TABKEY_STR("py_generic_services"), UPB_VALUE_INIT_CONSTPTR(&fields[62]), NULL},
{UPB_TABKEY_STR("java_outer_classname"), UPB_VALUE_INIT_CONSTPTR(&fields[25]), NULL},
{UPB_TABKEY_STR("message_set_wire_format"), UPB_VALUE_INIT_CONSTPTR(&fields[31]), &strentries[106]},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("uninterpreted_option"), UPB_VALUE_INIT_CONSTPTR(&fields[76]), NULL},
{UPB_TABKEY_STR("no_standard_descriptor_accessor"), UPB_VALUE_INIT_CONSTPTR(&fields[45]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("name"), UPB_VALUE_INIT_CONSTPTR(&fields[39]), NULL},
{UPB_TABKEY_STR("input_type"), UPB_VALUE_INIT_CONSTPTR(&fields[20]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("output_type"), UPB_VALUE_INIT_CONSTPTR(&fields[56]), NULL},
{UPB_TABKEY_STR("options"), UPB_VALUE_INIT_CONSTPTR(&fields[55]), NULL},
{UPB_TABKEY_STR("uninterpreted_option"), UPB_VALUE_INIT_CONSTPTR(&fields[74]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("options"), UPB_VALUE_INIT_CONSTPTR(&fields[54]), &strentries[122]},
{UPB_TABKEY_STR("method"), UPB_VALUE_INIT_CONSTPTR(&fields[33]), NULL},
{UPB_TABKEY_STR("name"), UPB_VALUE_INIT_CONSTPTR(&fields[35]), &strentries[121]},
{UPB_TABKEY_STR("uninterpreted_option"), UPB_VALUE_INIT_CONSTPTR(&fields[72]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("location"), UPB_VALUE_INIT_CONSTPTR(&fields[30]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("span"), UPB_VALUE_INIT_CONSTPTR(&fields[65]), &strentries[139]},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("trailing_comments"), UPB_VALUE_INIT_CONSTPTR(&fields[68]), NULL},
{UPB_TABKEY_STR("leading_comments"), UPB_VALUE_INIT_CONSTPTR(&fields[29]), &strentries[137]},
{UPB_TABKEY_STR("path"), UPB_VALUE_INIT_CONSTPTR(&fields[59]), NULL},
{UPB_TABKEY_STR("double_value"), UPB_VALUE_INIT_CONSTPTR(&fields[7]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("name"), UPB_VALUE_INIT_CONSTPTR(&fields[36]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("negative_int_value"), UPB_VALUE_INIT_CONSTPTR(&fields[43]), NULL},
{UPB_TABKEY_STR("aggregate_value"), UPB_VALUE_INIT_CONSTPTR(&fields[0]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("positive_int_value"), UPB_VALUE_INIT_CONSTPTR(&fields[60]), NULL},
{UPB_TABKEY_STR("identifier_value"), UPB_VALUE_INIT_CONSTPTR(&fields[19]), NULL},
{UPB_TABKEY_STR("string_value"), UPB_VALUE_INIT_CONSTPTR(&fields[67]), &strentries[154]},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("is_extension"), UPB_VALUE_INIT_CONSTPTR(&fields[21]), NULL},
{UPB_TABKEY_STR("name_part"), UPB_VALUE_INIT_CONSTPTR(&fields[42]), NULL},
{UPB_TABKEY_STR("LABEL_REQUIRED"), UPB_VALUE_INIT_INT32(2), &strentries[162]},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("LABEL_REPEATED"), UPB_VALUE_INIT_INT32(3), NULL},
{UPB_TABKEY_STR("LABEL_OPTIONAL"), UPB_VALUE_INIT_INT32(1), NULL},
{UPB_TABKEY_STR("TYPE_FIXED64"), UPB_VALUE_INIT_INT32(6), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("TYPE_STRING"), UPB_VALUE_INIT_INT32(9), NULL},
{UPB_TABKEY_STR("TYPE_FLOAT"), UPB_VALUE_INIT_INT32(2), &strentries[193]},
{UPB_TABKEY_STR("TYPE_DOUBLE"), UPB_VALUE_INIT_INT32(1), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("TYPE_INT32"), UPB_VALUE_INIT_INT32(5), NULL},
{UPB_TABKEY_STR("TYPE_SFIXED32"), UPB_VALUE_INIT_INT32(15), NULL},
{UPB_TABKEY_STR("TYPE_FIXED32"), UPB_VALUE_INIT_INT32(7), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("TYPE_MESSAGE"), UPB_VALUE_INIT_INT32(11), &strentries[194]},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("TYPE_INT64"), UPB_VALUE_INIT_INT32(3), &strentries[191]},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("TYPE_ENUM"), UPB_VALUE_INIT_INT32(14), NULL},
{UPB_TABKEY_STR("TYPE_UINT32"), UPB_VALUE_INIT_INT32(13), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("TYPE_UINT64"), UPB_VALUE_INIT_INT32(4), &strentries[190]},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("TYPE_SFIXED64"), UPB_VALUE_INIT_INT32(16), NULL},
{UPB_TABKEY_STR("TYPE_BYTES"), UPB_VALUE_INIT_INT32(12), NULL},
{UPB_TABKEY_STR("TYPE_SINT64"), UPB_VALUE_INIT_INT32(18), NULL},
{UPB_TABKEY_STR("TYPE_BOOL"), UPB_VALUE_INIT_INT32(8), NULL},
{UPB_TABKEY_STR("TYPE_GROUP"), UPB_VALUE_INIT_INT32(10), NULL},
{UPB_TABKEY_STR("TYPE_SINT32"), UPB_VALUE_INIT_INT32(17), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("CORD"), UPB_VALUE_INIT_INT32(1), NULL},
{UPB_TABKEY_STR("STRING"), UPB_VALUE_INIT_INT32(0), &strentries[197]},
{UPB_TABKEY_STR("STRING_PIECE"), UPB_VALUE_INIT_INT32(2), NULL},
{UPB_TABKEY_STR("CODE_SIZE"), UPB_VALUE_INIT_INT32(2), NULL},
{UPB_TABKEY_STR("SPEED"), UPB_VALUE_INIT_INT32(1), &strentries[203]},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("LITE_RUNTIME"), UPB_VALUE_INIT_INT32(3), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("google.protobuf.SourceCodeInfo.Location"), UPB_VALUE_INIT_CONSTPTR(&msgs[17]), NULL},
{UPB_TABKEY_STR("google.protobuf.UninterpretedOption"), UPB_VALUE_INIT_CONSTPTR(&msgs[18]), NULL},
{UPB_TABKEY_STR("google.protobuf.FileDescriptorProto"), UPB_VALUE_INIT_CONSTPTR(&msgs[8]), NULL},
{UPB_TABKEY_STR("google.protobuf.MethodDescriptorProto"), UPB_VALUE_INIT_CONSTPTR(&msgs[12]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("google.protobuf.EnumValueOptions"), UPB_VALUE_INIT_CONSTPTR(&msgs[5]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("google.protobuf.DescriptorProto"), UPB_VALUE_INIT_CONSTPTR(&msgs[0]), &strentries[228]},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("google.protobuf.SourceCodeInfo"), UPB_VALUE_INIT_CONSTPTR(&msgs[16]), NULL},
{UPB_TABKEY_STR("google.protobuf.FieldDescriptorProto.Type"), UPB_VALUE_INIT_CONSTPTR(&enums[1]), NULL},
{UPB_TABKEY_STR("google.protobuf.DescriptorProto.ExtensionRange"), UPB_VALUE_INIT_CONSTPTR(&msgs[1]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_STR("google.protobuf.EnumValueDescriptorProto"), UPB_VALUE_INIT_CONSTPTR(&msgs[4]), NULL},
{UPB_TABKEY_STR("google.protobuf.FieldOptions"), UPB_VALUE_INIT_CONSTPTR(&msgs[7]), NULL},
{UPB_TABKEY_STR("google.protobuf.FileOptions"), UPB_VALUE_INIT_CONSTPTR(&msgs[10]), NULL},
{UPB_TABKEY_STR("google.protobuf.EnumDescriptorProto"), UPB_VALUE_INIT_CONSTPTR(&msgs[2]), &strentries[233]},
{UPB_TABKEY_STR("google.protobuf.FieldDescriptorProto.Label"), UPB_VALUE_INIT_CONSTPTR(&enums[0]), NULL},
{UPB_TABKEY_STR("google.protobuf.ServiceDescriptorProto"), UPB_VALUE_INIT_CONSTPTR(&msgs[14]), NULL},
{UPB_TABKEY_STR("google.protobuf.FieldOptions.CType"), UPB_VALUE_INIT_CONSTPTR(&enums[2]), &strentries[229]},
{UPB_TABKEY_STR("google.protobuf.FileDescriptorSet"), UPB_VALUE_INIT_CONSTPTR(&msgs[9]), &strentries[235]},
{UPB_TABKEY_STR("google.protobuf.EnumOptions"), UPB_VALUE_INIT_CONSTPTR(&msgs[3]), NULL},
{UPB_TABKEY_STR("google.protobuf.FieldDescriptorProto"), UPB_VALUE_INIT_CONSTPTR(&msgs[6]), NULL},
{UPB_TABKEY_STR("google.protobuf.FileOptions.OptimizeMode"), UPB_VALUE_INIT_CONSTPTR(&enums[3]), &strentries[221]},
{UPB_TABKEY_STR("google.protobuf.ServiceOptions"), UPB_VALUE_INIT_CONSTPTR(&msgs[15]), NULL},
{UPB_TABKEY_STR("google.protobuf.MessageOptions"), UPB_VALUE_INIT_CONSTPTR(&msgs[11]), NULL},
{UPB_TABKEY_STR("google.protobuf.MethodOptions"), UPB_VALUE_INIT_CONSTPTR(&msgs[13]), &strentries[226]},
{UPB_TABKEY_STR("google.protobuf.UninterpretedOption.NamePart"), UPB_VALUE_INIT_CONSTPTR(&msgs[19]), NULL},
};
static const upb_tabent intentries[14] = {
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NUM(999), UPB_VALUE_INIT_CONSTPTR(&fields[73]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NUM(999), UPB_VALUE_INIT_CONSTPTR(&fields[71]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NUM(999), UPB_VALUE_INIT_CONSTPTR(&fields[77]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NUM(999), UPB_VALUE_INIT_CONSTPTR(&fields[75]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NUM(999), UPB_VALUE_INIT_CONSTPTR(&fields[76]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NUM(999), UPB_VALUE_INIT_CONSTPTR(&fields[74]), NULL},
{UPB_TABKEY_NONE, UPB__VALUE_INIT_NONE, NULL},
{UPB_TABKEY_NUM(999), UPB_VALUE_INIT_CONSTPTR(&fields[72]), NULL},
};
static const _upb_value arrays[232] = {
UPB_ARRAY_EMPTYENT,
UPB_VALUE_INIT_CONSTPTR(&fields[38]),
UPB_VALUE_INIT_CONSTPTR(&fields[16]),
UPB_VALUE_INIT_CONSTPTR(&fields[44]),
UPB_VALUE_INIT_CONSTPTR(&fields[9]),
UPB_VALUE_INIT_CONSTPTR(&fields[15]),
UPB_VALUE_INIT_CONSTPTR(&fields[14]),
UPB_VALUE_INIT_CONSTPTR(&fields[49]),
UPB_ARRAY_EMPTYENT,
UPB_VALUE_INIT_CONSTPTR(&fields[66]),
UPB_VALUE_INIT_CONSTPTR(&fields[8]),
UPB_ARRAY_EMPTYENT,
UPB_VALUE_INIT_CONSTPTR(&fields[40]),
UPB_VALUE_INIT_CONSTPTR(&fields[78]),
UPB_VALUE_INIT_CONSTPTR(&fields[50]),
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_VALUE_INIT_CONSTPTR(&fields[1]),
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_VALUE_INIT_CONSTPTR(&fields[37]),
UPB_VALUE_INIT_CONSTPTR(&fields[47]),
UPB_VALUE_INIT_CONSTPTR(&fields[52]),
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_VALUE_INIT_CONSTPTR(&fields[41]),
UPB_VALUE_INIT_CONSTPTR(&fields[12]),
UPB_VALUE_INIT_CONSTPTR(&fields[46]),
UPB_VALUE_INIT_CONSTPTR(&fields[27]),
UPB_VALUE_INIT_CONSTPTR(&fields[69]),
UPB_VALUE_INIT_CONSTPTR(&fields[70]),
UPB_VALUE_INIT_CONSTPTR(&fields[4]),
UPB_VALUE_INIT_CONSTPTR(&fields[51]),
UPB_ARRAY_EMPTYENT,
UPB_VALUE_INIT_CONSTPTR(&fields[3]),
UPB_VALUE_INIT_CONSTPTR(&fields[58]),
UPB_VALUE_INIT_CONSTPTR(&fields[6]),
UPB_ARRAY_EMPTYENT,
UPB_VALUE_INIT_CONSTPTR(&fields[28]),
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_VALUE_INIT_CONSTPTR(&fields[11]),
UPB_VALUE_INIT_CONSTPTR(&fields[79]),
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_VALUE_INIT_CONSTPTR(&fields[34]),
UPB_VALUE_INIT_CONSTPTR(&fields[57]),
UPB_VALUE_INIT_CONSTPTR(&fields[5]),
UPB_VALUE_INIT_CONSTPTR(&fields[32]),
UPB_VALUE_INIT_CONSTPTR(&fields[10]),
UPB_VALUE_INIT_CONSTPTR(&fields[63]),
UPB_VALUE_INIT_CONSTPTR(&fields[13]),
UPB_VALUE_INIT_CONSTPTR(&fields[53]),
UPB_VALUE_INIT_CONSTPTR(&fields[64]),
UPB_VALUE_INIT_CONSTPTR(&fields[61]),
UPB_VALUE_INIT_CONSTPTR(&fields[80]),
UPB_ARRAY_EMPTYENT,
UPB_VALUE_INIT_CONSTPTR(&fields[17]),
UPB_ARRAY_EMPTYENT,
UPB_VALUE_INIT_CONSTPTR(&fields[26]),
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_VALUE_INIT_CONSTPTR(&fields[25]),
UPB_VALUE_INIT_CONSTPTR(&fields[48]),
UPB_VALUE_INIT_CONSTPTR(&fields[24]),
UPB_VALUE_INIT_CONSTPTR(&fields[18]),
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_VALUE_INIT_CONSTPTR(&fields[2]),
UPB_VALUE_INIT_CONSTPTR(&fields[23]),
UPB_VALUE_INIT_CONSTPTR(&fields[62]),
UPB_ARRAY_EMPTYENT,
UPB_VALUE_INIT_CONSTPTR(&fields[22]),
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_VALUE_INIT_CONSTPTR(&fields[31]),
UPB_VALUE_INIT_CONSTPTR(&fields[45]),
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_VALUE_INIT_CONSTPTR(&fields[39]),
UPB_VALUE_INIT_CONSTPTR(&fields[20]),
UPB_VALUE_INIT_CONSTPTR(&fields[56]),
UPB_VALUE_INIT_CONSTPTR(&fields[55]),
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_VALUE_INIT_CONSTPTR(&fields[35]),
UPB_VALUE_INIT_CONSTPTR(&fields[33]),
UPB_VALUE_INIT_CONSTPTR(&fields[54]),
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_VALUE_INIT_CONSTPTR(&fields[30]),
UPB_ARRAY_EMPTYENT,
UPB_VALUE_INIT_CONSTPTR(&fields[59]),
UPB_VALUE_INIT_CONSTPTR(&fields[65]),
UPB_VALUE_INIT_CONSTPTR(&fields[29]),
UPB_VALUE_INIT_CONSTPTR(&fields[68]),
UPB_ARRAY_EMPTYENT,
UPB_ARRAY_EMPTYENT,
UPB_VALUE_INIT_CONSTPTR(&fields[36]),
UPB_VALUE_INIT_CONSTPTR(&fields[19]),
UPB_VALUE_INIT_CONSTPTR(&fields[60]),
UPB_VALUE_INIT_CONSTPTR(&fields[43]),
UPB_VALUE_INIT_CONSTPTR(&fields[7]),
UPB_VALUE_INIT_CONSTPTR(&fields[67]),
UPB_VALUE_INIT_CONSTPTR(&fields[0]),
UPB_ARRAY_EMPTYENT,
UPB_VALUE_INIT_CONSTPTR(&fields[42]),
UPB_VALUE_INIT_CONSTPTR(&fields[21]),
UPB_ARRAY_EMPTYENT,
UPB_VALUE_INIT_CONSTPTR("LABEL_OPTIONAL"),
UPB_VALUE_INIT_CONSTPTR("LABEL_REQUIRED"),
UPB_VALUE_INIT_CONSTPTR("LABEL_REPEATED"),
UPB_ARRAY_EMPTYENT,
UPB_VALUE_INIT_CONSTPTR("TYPE_DOUBLE"),
UPB_VALUE_INIT_CONSTPTR("TYPE_FLOAT"),
UPB_VALUE_INIT_CONSTPTR("TYPE_INT64"),
UPB_VALUE_INIT_CONSTPTR("TYPE_UINT64"),
UPB_VALUE_INIT_CONSTPTR("TYPE_INT32"),
UPB_VALUE_INIT_CONSTPTR("TYPE_FIXED64"),
UPB_VALUE_INIT_CONSTPTR("TYPE_FIXED32"),
UPB_VALUE_INIT_CONSTPTR("TYPE_BOOL"),
UPB_VALUE_INIT_CONSTPTR("TYPE_STRING"),
UPB_VALUE_INIT_CONSTPTR("TYPE_GROUP"),
UPB_VALUE_INIT_CONSTPTR("TYPE_MESSAGE"),
UPB_VALUE_INIT_CONSTPTR("TYPE_BYTES"),
UPB_VALUE_INIT_CONSTPTR("TYPE_UINT32"),
UPB_VALUE_INIT_CONSTPTR("TYPE_ENUM"),
UPB_VALUE_INIT_CONSTPTR("TYPE_SFIXED32"),
UPB_VALUE_INIT_CONSTPTR("TYPE_SFIXED64"),
UPB_VALUE_INIT_CONSTPTR("TYPE_SINT32"),
UPB_VALUE_INIT_CONSTPTR("TYPE_SINT64"),
UPB_VALUE_INIT_CONSTPTR("STRING"),
UPB_VALUE_INIT_CONSTPTR("CORD"),
UPB_VALUE_INIT_CONSTPTR("STRING_PIECE"),
UPB_ARRAY_EMPTYENT,
UPB_VALUE_INIT_CONSTPTR("SPEED"),
UPB_VALUE_INIT_CONSTPTR("CODE_SIZE"),
UPB_VALUE_INIT_CONSTPTR("LITE_RUNTIME"),
};
static const upb_symtab symtab = UPB_SYMTAB_INIT(UPB_STRTABLE_INIT(24, 31, UPB_CTYPE_PTR, 5, &strentries[204]), &reftables[210], &reftables[211]);
const upb_symtab *upbdefs_google_protobuf_descriptor(const void *owner) {
upb_symtab_ref(&symtab, owner);
return &symtab;
}
#ifdef UPB_DEBUG_REFS
static upb_inttable reftables[212] = {
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
UPB_EMPTY_INTTABLE_INIT(UPB_CTYPE_PTR),
};
#endif
/*
* upb - a minimalist implementation of protocol buffers.
*
* Copyright (c) 2008-2009 Google Inc. See LICENSE for details.
* Author: Josh Haberman <jhaberman@gmail.com>
*
* XXX: The routines in this file that consume a string do not currently
* support having the string span buffers. In the future, as upb_sink and
* its buffering/sharing functionality evolve there should be an easy and
* idiomatic way of correctly handling this case. For now, we accept this
* limitation since we currently only parse descriptors from single strings.
*/
#include <errno.h>
#include <stdlib.h>
#include <string.h>
static char *upb_strndup(const char *buf, size_t n) {
char *ret = malloc(n + 1);
if (!ret) return NULL;
memcpy(ret, buf, n);
ret[n] = '\0';
return ret;
}
// Returns a newly allocated string that joins input strings together, for
// example:
// join("Foo.Bar", "Baz") -> "Foo.Bar.Baz"
// join("", "Baz") -> "Baz"
// Caller owns a ref on the returned string.
static char *upb_join(const char *base, const char *name) {
if (!base || strlen(base) == 0) {
return upb_strdup(name);
} else {
char *ret = malloc(strlen(base) + strlen(name) + 2);
ret[0] = '\0';
strcat(ret, base);
strcat(ret, ".");
strcat(ret, name);
return ret;
}
}
/* upb_deflist ****************************************************************/
void upb_deflist_init(upb_deflist *l) {
l->size = 0;
l->defs = NULL;
l->len = 0;
l->owned = true;
}
void upb_deflist_uninit(upb_deflist *l) {
if (l->owned)
for(size_t i = 0; i < l->len; i++)
upb_def_unref(l->defs[i], l);
free(l->defs);
}
bool upb_deflist_push(upb_deflist *l, upb_def *d) {
if(++l->len >= l->size) {
size_t new_size = UPB_MAX(l->size, 4);
new_size *= 2;
l->defs = realloc(l->defs, new_size * sizeof(void *));
if (!l->defs) return false;
l->size = new_size;
}
l->defs[l->len - 1] = d;
return true;
}
void upb_deflist_donaterefs(upb_deflist *l, void *owner) {
assert(l->owned);
for (size_t i = 0; i < l->len; i++)
upb_def_donateref(l->defs[i], l, owner);
l->owned = false;
}
static upb_def *upb_deflist_last(upb_deflist *l) {
return l->defs[l->len-1];
}
// Qualify the defname for all defs starting with offset "start" with "str".
static void upb_deflist_qualify(upb_deflist *l, char *str, int32_t start) {
for (uint32_t i = start; i < l->len; i++) {
upb_def *def = l->defs[i];
char *name = upb_join(str, upb_def_fullname(def));
upb_def_setfullname(def, name, NULL);
free(name);
}
}
/* upb_descreader ************************************************************/
void upb_descreader_init(upb_descreader *r, const upb_handlers *handlers,
upb_status *status) {
UPB_UNUSED(status);
upb_deflist_init(&r->defs);
upb_sink_reset(upb_descreader_input(r), handlers, r);
r->stack_len = 0;
r->name = NULL;
r->default_string = NULL;
}
void upb_descreader_uninit(upb_descreader *r) {
free(r->name);
upb_deflist_uninit(&r->defs);
free(r->default_string);
while (r->stack_len > 0) {
upb_descreader_frame *f = &r->stack[--r->stack_len];
free(f->name);
}
}
upb_def **upb_descreader_getdefs(upb_descreader *r, void *owner, int *n) {
*n = r->defs.len;
upb_deflist_donaterefs(&r->defs, owner);
return r->defs.defs;
}
upb_sink *upb_descreader_input(upb_descreader *r) {
return &r->sink;
}
static upb_msgdef *upb_descreader_top(upb_descreader *r) {
assert(r->stack_len > 1);
int index = r->stack[r->stack_len-1].start - 1;
assert(index >= 0);
return upb_downcast_msgdef_mutable(r->defs.defs[index]);
}
static upb_def *upb_descreader_last(upb_descreader *r) {
return upb_deflist_last(&r->defs);
}
// Start/end handlers for FileDescriptorProto and DescriptorProto (the two
// entities that have names and can contain sub-definitions.
void upb_descreader_startcontainer(upb_descreader *r) {
upb_descreader_frame *f = &r->stack[r->stack_len++];
f->start = r->defs.len;
f->name = NULL;
}
void upb_descreader_endcontainer(upb_descreader *r) {
upb_descreader_frame *f = &r->stack[--r->stack_len];
upb_deflist_qualify(&r->defs, f->name, f->start);
free(f->name);
f->name = NULL;
}
void upb_descreader_setscopename(upb_descreader *r, char *str) {
upb_descreader_frame *f = &r->stack[r->stack_len-1];
free(f->name);
f->name = str;
}
// Handlers for google.protobuf.FileDescriptorProto.
static bool file_startmsg(void *r, const void *hd) {
UPB_UNUSED(hd);
upb_descreader_startcontainer(r);
return true;
}
static bool file_endmsg(void *closure, const void *hd, upb_status *status) {
UPB_UNUSED(hd);
UPB_UNUSED(status);
upb_descreader *r = closure;
upb_descreader_endcontainer(r);
return true;
}
static size_t file_onpackage(void *closure, const void *hd, const char *buf,
size_t n, const upb_bufhandle *handle) {
UPB_UNUSED(hd);
UPB_UNUSED(handle);
upb_descreader *r = closure;
// XXX: see comment at the top of the file.
upb_descreader_setscopename(r, upb_strndup(buf, n));
return n;
}
// Handlers for google.protobuf.EnumValueDescriptorProto.
static bool enumval_startmsg(void *closure, const void *hd) {
UPB_UNUSED(hd);
upb_descreader *r = closure;
r->saw_number = false;
r->saw_name = false;
return true;
}
static size_t enumval_onname(void *closure, const void *hd, const char *buf,
size_t n, const upb_bufhandle *handle) {
UPB_UNUSED(hd);
UPB_UNUSED(handle);
upb_descreader *r = closure;
// XXX: see comment at the top of the file.
free(r->name);
r->name = upb_strndup(buf, n);
r->saw_name = true;
return n;
}
static bool enumval_onnumber(void *closure, const void *hd, int32_t val) {
UPB_UNUSED(hd);
upb_descreader *r = closure;
r->number = val;
r->saw_number = true;
return true;
}
static bool enumval_endmsg(void *closure, const void *hd, upb_status *status) {
UPB_UNUSED(hd);
upb_descreader *r = closure;
if(!r->saw_number || !r->saw_name) {
upb_status_seterrmsg(status, "Enum value missing name or number.");
return false;
}
upb_enumdef *e = upb_downcast_enumdef_mutable(upb_descreader_last(r));
upb_enumdef_addval(e, r->name, r->number, status);
free(r->name);
r->name = NULL;
return true;
}
// Handlers for google.protobuf.EnumDescriptorProto.
static bool enum_startmsg(void *closure, const void *hd) {
UPB_UNUSED(hd);
upb_descreader *r = closure;
upb_deflist_push(&r->defs, UPB_UPCAST(upb_enumdef_new(&r->defs)));
return true;
}
static bool enum_endmsg(void *closure, const void *hd, upb_status *status) {
UPB_UNUSED(hd);
upb_descreader *r = closure;
upb_enumdef *e = upb_downcast_enumdef_mutable(upb_descreader_last(r));
if (upb_def_fullname(upb_descreader_last(r)) == NULL) {
upb_status_seterrmsg(status, "Enum had no name.");
return false;
}
if (upb_enumdef_numvals(e) == 0) {
upb_status_seterrmsg(status, "Enum had no values.");
return false;
}
return true;
}
static size_t enum_onname(void *closure, const void *hd, const char *buf,
size_t n, const upb_bufhandle *handle) {
UPB_UNUSED(hd);
UPB_UNUSED(handle);
upb_descreader *r = closure;
// XXX: see comment at the top of the file.
char *fullname = upb_strndup(buf, n);
upb_def_setfullname(upb_descreader_last(r), fullname, NULL);
free(fullname);
return n;
}
// Handlers for google.protobuf.FieldDescriptorProto
static bool field_startmsg(void *closure, const void *hd) {
UPB_UNUSED(hd);
upb_descreader *r = closure;
r->f = upb_fielddef_new(&r->defs);
free(r->default_string);
r->default_string = NULL;
// fielddefs default to packed, but descriptors default to non-packed.
upb_fielddef_setpacked(r->f, false);
return true;
}
// Converts the default value in string "str" into "d". Passes a ref on str.
// Returns true on success.
static bool parse_default(char *str, upb_fielddef *f) {
bool success = true;
char *end;
switch (upb_fielddef_type(f)) {
case UPB_TYPE_INT32: {
long val = strtol(str, &end, 0);
if (val > INT32_MAX || val < INT32_MIN || errno == ERANGE || *end)
success = false;
else
upb_fielddef_setdefaultint32(f, val);
break;
}
case UPB_TYPE_INT64: {
long long val = strtoll(str, &end, 0);
if (val > INT64_MAX || val < INT64_MIN || errno == ERANGE || *end)
success = false;
else
upb_fielddef_setdefaultint64(f, val);
break;
}
case UPB_TYPE_UINT32: {
long val = strtoul(str, &end, 0);
if (val > UINT32_MAX || errno == ERANGE || *end)
success = false;
else
upb_fielddef_setdefaultuint32(f, val);
break;
}
case UPB_TYPE_UINT64: {
unsigned long long val = strtoull(str, &end, 0);
if (val > UINT64_MAX || errno == ERANGE || *end)
success = false;
else
upb_fielddef_setdefaultuint64(f, val);
break;
}
case UPB_TYPE_DOUBLE: {
double val = strtod(str, &end);
if (errno == ERANGE || *end)
success = false;
else
upb_fielddef_setdefaultdouble(f, val);
break;
}
case UPB_TYPE_FLOAT: {
float val = strtof(str, &end);
if (errno == ERANGE || *end)
success = false;
else
upb_fielddef_setdefaultfloat(f, val);
break;
}
case UPB_TYPE_BOOL: {
if (strcmp(str, "false") == 0)
upb_fielddef_setdefaultbool(f, false);
else if (strcmp(str, "true") == 0)
upb_fielddef_setdefaultbool(f, true);
else
success = false;
break;
}
default: abort();
}
return success;
}
static bool field_endmsg(void *closure, const void *hd, upb_status *status) {
UPB_UNUSED(hd);
upb_descreader *r = closure;
upb_fielddef *f = r->f;
// TODO: verify that all required fields were present.
assert(upb_fielddef_number(f) != 0);
assert(upb_fielddef_name(f) != NULL);
assert((upb_fielddef_subdefname(f) != NULL) == upb_fielddef_hassubdef(f));
if (r->default_string) {
if (upb_fielddef_issubmsg(f)) {
upb_status_seterrmsg(status, "Submessages cannot have defaults.");
return false;
}
if (upb_fielddef_isstring(f) || upb_fielddef_type(f) == UPB_TYPE_ENUM) {
upb_fielddef_setdefaultcstr(f, r->default_string, NULL);
} else {
if (r->default_string && !parse_default(r->default_string, f)) {
// We don't worry too much about giving a great error message since the
// compiler should have ensured this was correct.
upb_status_seterrmsg(status, "Error converting default value.");
return false;
}
}
}
return true;
}
static bool field_onlazy(void *closure, const void *hd, bool val) {
UPB_UNUSED(hd);
upb_descreader *r = closure;
upb_fielddef_setlazy(r->f, val);
return true;
}
static bool field_onpacked(void *closure, const void *hd, bool val) {
UPB_UNUSED(hd);
upb_descreader *r = closure;
upb_fielddef_setpacked(r->f, val);
return true;
}
static bool field_ontype(void *closure, const void *hd, int32_t val) {
UPB_UNUSED(hd);
upb_descreader *r = closure;
upb_fielddef_setdescriptortype(r->f, val);
return true;
}
static bool field_onlabel(void *closure, const void *hd, int32_t val) {
UPB_UNUSED(hd);
upb_descreader *r = closure;
upb_fielddef_setlabel(r->f, val);
return true;
}
static bool field_onnumber(void *closure, const void *hd, int32_t val) {
UPB_UNUSED(hd);
upb_descreader *r = closure;
bool ok = upb_fielddef_setnumber(r->f, val, NULL);
UPB_ASSERT_VAR(ok, ok);
return true;
}
static size_t field_onname(void *closure, const void *hd, const char *buf,
size_t n, const upb_bufhandle *handle) {
UPB_UNUSED(hd);
UPB_UNUSED(handle);
upb_descreader *r = closure;
// XXX: see comment at the top of the file.
char *name = upb_strndup(buf, n);
upb_fielddef_setname(r->f, name, NULL);
free(name);
return n;
}
static size_t field_ontypename(void *closure, const void *hd, const char *buf,
size_t n, const upb_bufhandle *handle) {
UPB_UNUSED(hd);
UPB_UNUSED(handle);
upb_descreader *r = closure;
// XXX: see comment at the top of the file.
char *name = upb_strndup(buf, n);
upb_fielddef_setsubdefname(r->f, name, NULL);
free(name);
return n;
}
static size_t field_onextendee(void *closure, const void *hd, const char *buf,
size_t n, const upb_bufhandle *handle) {
UPB_UNUSED(hd);
UPB_UNUSED(handle);
upb_descreader *r = closure;
// XXX: see comment at the top of the file.
char *name = upb_strndup(buf, n);
upb_fielddef_setcontainingtypename(r->f, name, NULL);
free(name);
return n;
}
static size_t field_ondefaultval(void *closure, const void *hd, const char *buf,
size_t n, const upb_bufhandle *handle) {
UPB_UNUSED(hd);
UPB_UNUSED(handle);
upb_descreader *r = closure;
// Have to convert from string to the correct type, but we might not know the
// type yet, so we save it as a string until the end of the field.
// XXX: see comment at the top of the file.
free(r->default_string);
r->default_string = upb_strndup(buf, n);
return n;
}
// Handlers for google.protobuf.DescriptorProto (representing a message).
static bool msg_startmsg(void *closure, const void *hd) {
UPB_UNUSED(hd);
upb_descreader *r = closure;
upb_deflist_push(&r->defs, UPB_UPCAST(upb_msgdef_new(&r->defs)));
upb_descreader_startcontainer(r);
return true;
}
static bool msg_endmsg(void *closure, const void *hd, upb_status *status) {
UPB_UNUSED(hd);
upb_descreader *r = closure;
upb_msgdef *m = upb_descreader_top(r);
if(!upb_def_fullname(UPB_UPCAST(m))) {
upb_status_seterrmsg(status, "Encountered message with no name.");
return false;
}
upb_descreader_endcontainer(r);
return true;
}
static size_t msg_onname(void *closure, const void *hd, const char *buf,
size_t n, const upb_bufhandle *handle) {
UPB_UNUSED(hd);
UPB_UNUSED(handle);
upb_descreader *r = closure;
upb_msgdef *m = upb_descreader_top(r);
// XXX: see comment at the top of the file.
char *name = upb_strndup(buf, n);
upb_def_setfullname(UPB_UPCAST(m), name, NULL);
upb_descreader_setscopename(r, name); // Passes ownership of name.
return n;
}
static bool msg_onendfield(void *closure, const void *hd) {
UPB_UNUSED(hd);
upb_descreader *r = closure;
upb_msgdef *m = upb_descreader_top(r);
upb_msgdef_addfield(m, r->f, &r->defs, NULL);
r->f = NULL;
return true;
}
static bool pushextension(void *closure, const void *hd) {
UPB_UNUSED(hd);
upb_descreader *r = closure;
assert(upb_fielddef_containingtypename(r->f));
upb_fielddef_setisextension(r->f, true);
upb_deflist_push(&r->defs, UPB_UPCAST(r->f));
r->f = NULL;
return true;
}
#define D(name) upbdefs_google_protobuf_ ## name(s)
static void reghandlers(const void *closure, upb_handlers *h) {
const upb_symtab *s = closure;
const upb_msgdef *m = upb_handlers_msgdef(h);
if (m == D(DescriptorProto)) {
upb_handlers_setstartmsg(h, &msg_startmsg, NULL);
upb_handlers_setendmsg(h, &msg_endmsg, NULL);
upb_handlers_setstring(h, D(DescriptorProto_name), &msg_onname, NULL);
upb_handlers_setendsubmsg(h, D(DescriptorProto_field), &msg_onendfield,
NULL);
upb_handlers_setendsubmsg(h, D(DescriptorProto_extension), &pushextension,
NULL);
} else if (m == D(FileDescriptorProto)) {
upb_handlers_setstartmsg(h, &file_startmsg, NULL);
upb_handlers_setendmsg(h, &file_endmsg, NULL);
upb_handlers_setstring(h, D(FileDescriptorProto_package), &file_onpackage,
NULL);
upb_handlers_setendsubmsg(h, D(FileDescriptorProto_extension), &pushextension,
NULL);
} else if (m == D(EnumValueDescriptorProto)) {
upb_handlers_setstartmsg(h, &enumval_startmsg, NULL);
upb_handlers_setendmsg(h, &enumval_endmsg, NULL);
upb_handlers_setstring(h, D(EnumValueDescriptorProto_name), &enumval_onname, NULL);
upb_handlers_setint32(h, D(EnumValueDescriptorProto_number), &enumval_onnumber,
NULL);
} else if (m == D(EnumDescriptorProto)) {
upb_handlers_setstartmsg(h, &enum_startmsg, NULL);
upb_handlers_setendmsg(h, &enum_endmsg, NULL);
upb_handlers_setstring(h, D(EnumDescriptorProto_name), &enum_onname, NULL);
} else if (m == D(FieldDescriptorProto)) {
upb_handlers_setstartmsg(h, &field_startmsg, NULL);
upb_handlers_setendmsg(h, &field_endmsg, NULL);
upb_handlers_setint32(h, D(FieldDescriptorProto_type), &field_ontype,
NULL);
upb_handlers_setint32(h, D(FieldDescriptorProto_label), &field_onlabel,
NULL);
upb_handlers_setint32(h, D(FieldDescriptorProto_number), &field_onnumber,
NULL);
upb_handlers_setstring(h, D(FieldDescriptorProto_name), &field_onname,
NULL);
upb_handlers_setstring(h, D(FieldDescriptorProto_type_name),
&field_ontypename, NULL);
upb_handlers_setstring(h, D(FieldDescriptorProto_extendee),
&field_onextendee, NULL);
upb_handlers_setstring(h, D(FieldDescriptorProto_default_value),
&field_ondefaultval, NULL);
} else if (m == D(FieldOptions)) {
upb_handlers_setbool(h, D(FieldOptions_lazy), &field_onlazy, NULL);
upb_handlers_setbool(h, D(FieldOptions_packed), &field_onpacked, NULL);
}
}
#undef D
const upb_handlers *upb_descreader_newhandlers(const void *owner) {
const upb_symtab *s = upbdefs_google_protobuf_descriptor(&s);
const upb_handlers *h = upb_handlers_newfrozen(
upbdefs_google_protobuf_FileDescriptorSet(s), owner, reghandlers, s);
upb_symtab_unref(s, &s);
return h;
}
/*
* upb - a minimalist implementation of protocol buffers.
*
* Copyright (c) 2013 Google Inc. See LICENSE for details.
* Author: Josh Haberman <jhaberman@gmail.com>
*
* Code to compile a upb::Handlers into bytecode for decoding a protobuf
* according to that specific schema and destination handlers.
*
* Compiling to bytecode is always the first step. If we are using the
* interpreted decoder we leave it as bytecode and interpret that. If we are
* using a JIT decoder we use a code generator to turn the bytecode into native
* code, LLVM IR, etc.
*
* Bytecode definition is in decoder.int.h.
*/
#include <stdarg.h>
#ifdef UPB_DUMP_BYTECODE
#include <stdio.h>
#endif
#define MAXLABEL 5
#define EMPTYLABEL -1
/* mgroup *********************************************************************/
static void freegroup(upb_refcounted *r) {
mgroup *g = (mgroup*)r;
upb_inttable_uninit(&g->methods);
#ifdef UPB_USE_JIT_X64
upb_pbdecoder_freejit(g);
#endif
free(g->bytecode);
free(g);
}
static void visitgroup(const upb_refcounted *r, upb_refcounted_visit *visit,
void *closure) {
const mgroup *g = (const mgroup*)r;
upb_inttable_iter i;
upb_inttable_begin(&i, &g->methods);
for(; !upb_inttable_done(&i); upb_inttable_next(&i)) {
upb_pbdecodermethod *method = upb_value_getptr(upb_inttable_iter_value(&i));
visit(r, UPB_UPCAST(method), closure);
}
}
mgroup *newgroup(const void *owner) {
mgroup *g = malloc(sizeof(*g));
static const struct upb_refcounted_vtbl vtbl = {visitgroup, freegroup};
upb_refcounted_init(UPB_UPCAST(g), &vtbl, owner);
upb_inttable_init(&g->methods, UPB_CTYPE_PTR);
g->bytecode = NULL;
g->bytecode_end = NULL;
return g;
}
/* upb_pbdecodermethod ********************************************************/
static void freemethod(upb_refcounted *r) {
upb_pbdecodermethod *method = (upb_pbdecodermethod*)r;
upb_byteshandler_uninit(&method->input_handler_);
if (method->dest_handlers_) {
upb_handlers_unref(method->dest_handlers_, method);
}
upb_inttable_uninit(&method->dispatch);
free(method);
}
static void visitmethod(const upb_refcounted *r, upb_refcounted_visit *visit,
void *closure) {
const upb_pbdecodermethod *m = (const upb_pbdecodermethod*)r;
visit(r, m->group, closure);
}
static upb_pbdecodermethod *newmethod(const upb_handlers *dest_handlers,
mgroup *group) {
static const struct upb_refcounted_vtbl vtbl = {visitmethod, freemethod};
upb_pbdecodermethod *ret = malloc(sizeof(*ret));
upb_refcounted_init(UPB_UPCAST(ret), &vtbl, &ret);
upb_byteshandler_init(&ret->input_handler_);
// The method references the group and vice-versa, in a circular reference.
upb_ref2(ret, group);
upb_ref2(group, ret);
upb_inttable_insertptr(&group->methods, dest_handlers, upb_value_ptr(ret));
upb_refcounted_unref(UPB_UPCAST(ret), &ret);
ret->group = UPB_UPCAST(group);
ret->dest_handlers_ = dest_handlers;
ret->is_native_ = false; // If we JIT, it will update this later.
upb_inttable_init(&ret->dispatch, UPB_CTYPE_UINT64);
if (ret->dest_handlers_) {
upb_handlers_ref(ret->dest_handlers_, ret);
}
return ret;
}
void upb_pbdecodermethod_ref(const upb_pbdecodermethod *m, const void *owner) {
upb_refcounted_ref(UPB_UPCAST(m), owner);
}
void upb_pbdecodermethod_unref(const upb_pbdecodermethod *m,
const void *owner) {
upb_refcounted_unref(UPB_UPCAST(m), owner);
}
void upb_pbdecodermethod_donateref(const upb_pbdecodermethod *m,
const void *from, const void *to) {
upb_refcounted_donateref(UPB_UPCAST(m), from, to);
}
void upb_pbdecodermethod_checkref(const upb_pbdecodermethod *m,
const void *owner) {
upb_refcounted_checkref(UPB_UPCAST(m), owner);
}
const upb_handlers *upb_pbdecodermethod_desthandlers(
const upb_pbdecodermethod *m) {
return m->dest_handlers_;
}
const upb_byteshandler *upb_pbdecodermethod_inputhandler(
const upb_pbdecodermethod *m) {
return &m->input_handler_;
}
bool upb_pbdecodermethod_isnative(const upb_pbdecodermethod *m) {
return m->is_native_;
}
const upb_pbdecodermethod *upb_pbdecodermethod_new(
const upb_pbdecodermethodopts *opts, const void *owner) {
upb_pbcodecache cache;
upb_pbcodecache_init(&cache);
const upb_pbdecodermethod *ret =
upb_pbcodecache_getdecodermethod(&cache, opts);
upb_pbdecodermethod_ref(ret, owner);
upb_pbcodecache_uninit(&cache);
return ret;
}
/* bytecode compiler **********************************************************/
// Data used only at compilation time.
typedef struct {
mgroup *group;
uint32_t *pc;
int fwd_labels[MAXLABEL];
int back_labels[MAXLABEL];
// For fields marked "lazy", parse them lazily or eagerly?
bool lazy;
} compiler;
static compiler *newcompiler(mgroup *group, bool lazy) {
compiler *ret = malloc(sizeof(*ret));
ret->group = group;
ret->lazy = lazy;
for (int i = 0; i < MAXLABEL; i++) {
ret->fwd_labels[i] = EMPTYLABEL;
ret->back_labels[i] = EMPTYLABEL;
}
return ret;
}
static void freecompiler(compiler *c) {
free(c);
}
const size_t ptr_words = sizeof(void*) / sizeof(uint32_t);
// How many words an instruction is.
static int instruction_len(uint32_t instr) {
switch (getop(instr)) {
case OP_SETDISPATCH: return 1 + ptr_words;
case OP_TAGN: return 3;
case OP_SETBIGGROUPNUM: return 2;
default: return 1;
}
}
bool op_has_longofs(int32_t instruction) {
switch (getop(instruction)) {
case OP_CALL:
case OP_BRANCH:
case OP_CHECKDELIM:
return true;
// The "tag" instructions only have 8 bytes available for the jump target,
// but that is ok because these opcodes only require short jumps.
case OP_TAG1:
case OP_TAG2:
case OP_TAGN:
return false;
default:
assert(false);
return false;
}
}
static int32_t getofs(uint32_t instruction) {
if (op_has_longofs(instruction)) {
return (int32_t)instruction >> 8;
} else {
return (int8_t)(instruction >> 8);
}
}
static void setofs(uint32_t *instruction, int32_t ofs) {
if (op_has_longofs(*instruction)) {
*instruction = getop(*instruction) | ofs << 8;
} else {
*instruction = (*instruction & ~0xff00) | ((ofs & 0xff) << 8);
}
assert(getofs(*instruction) == ofs); // Would fail in cases of overflow.
}
static uint32_t pcofs(compiler *c) { return c->pc - c->group->bytecode; }
// Defines a local label at the current PC location. All previous forward
// references are updated to point to this location. The location is noted
// for any future backward references.
static void label(compiler *c, unsigned int label) {
assert(label < MAXLABEL);
int val = c->fwd_labels[label];
uint32_t *codep = (val == EMPTYLABEL) ? NULL : c->group->bytecode + val;
while (codep) {
int ofs = getofs(*codep);
setofs(codep, c->pc - codep - instruction_len(*codep));
codep = ofs ? codep + ofs : NULL;
}
c->fwd_labels[label] = EMPTYLABEL;
c->back_labels[label] = pcofs(c);
}
// Creates a reference to a numbered label; either a forward reference
// (positive arg) or backward reference (negative arg). For forward references
// the value returned now is actually a "next" pointer into a linked list of all
// instructions that use this label and will be patched later when the label is
// defined with label().
//
// The returned value is the offset that should be written into the instruction.
static int32_t labelref(compiler *c, int label) {
assert(label < MAXLABEL);
if (label == LABEL_DISPATCH) {
// No resolving required.
return 0;
} else if (label < 0) {
// Backward local label. Relative to the next instruction.
uint32_t from = (c->pc + 1) - c->group->bytecode;
return c->back_labels[-label] - from;
} else {
// Forward local label: prepend to (possibly-empty) linked list.
int *lptr = &c->fwd_labels[label];
int32_t ret = (*lptr == EMPTYLABEL) ? 0 : *lptr - pcofs(c);
*lptr = pcofs(c);
return ret;
}
}
static void put32(compiler *c, uint32_t v) {
mgroup *g = c->group;
if (c->pc == g->bytecode_end) {
int ofs = pcofs(c);
size_t oldsize = g->bytecode_end - g->bytecode;
size_t newsize = UPB_MAX(oldsize * 2, 64);
// TODO(haberman): handle OOM.
g->bytecode = realloc(g->bytecode, newsize * sizeof(uint32_t));
g->bytecode_end = g->bytecode + newsize;
c->pc = g->bytecode + ofs;
}
*c->pc++ = v;
}
static void putop(compiler *c, opcode op, ...) {
va_list ap;
va_start(ap, op);
switch (op) {
case OP_SETDISPATCH: {
uintptr_t ptr = (uintptr_t)va_arg(ap, void*);
put32(c, OP_SETDISPATCH);
put32(c, ptr);
if (sizeof(uintptr_t) > sizeof(uint32_t))
put32(c, (uint64_t)ptr >> 32);
break;
}
case OP_STARTMSG:
case OP_ENDMSG:
case OP_PUSHLENDELIM:
case OP_POP:
case OP_SETDELIM:
case OP_HALT:
case OP_RET:
Update upb amalgamation.
10 years ago
case OP_DISPATCH:
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
put32(c, op);
break;
case OP_PARSE_DOUBLE:
case OP_PARSE_FLOAT:
case OP_PARSE_INT64:
case OP_PARSE_UINT64:
case OP_PARSE_INT32:
case OP_PARSE_FIXED64:
case OP_PARSE_FIXED32:
case OP_PARSE_BOOL:
case OP_PARSE_UINT32:
case OP_PARSE_SFIXED32:
case OP_PARSE_SFIXED64:
case OP_PARSE_SINT32:
case OP_PARSE_SINT64:
case OP_STARTSEQ:
case OP_ENDSEQ:
case OP_STARTSUBMSG:
case OP_ENDSUBMSG:
case OP_STARTSTR:
case OP_STRING:
case OP_ENDSTR:
case OP_PUSHTAGDELIM:
put32(c, op | va_arg(ap, upb_selector_t) << 8);
break;
case OP_SETBIGGROUPNUM:
put32(c, op);
put32(c, va_arg(ap, int));
break;
case OP_CALL: {
const upb_pbdecodermethod *method = va_arg(ap, upb_pbdecodermethod *);
put32(c, op | (method->code_base.ofs - (pcofs(c) + 1)) << 8);
break;
}
case OP_CHECKDELIM:
case OP_BRANCH: {
uint32_t instruction = op;
int label = va_arg(ap, int);
setofs(&instruction, labelref(c, label));
put32(c, instruction);
break;
}
case OP_TAG1:
case OP_TAG2: {
int label = va_arg(ap, int);
uint64_t tag = va_arg(ap, uint64_t);
uint32_t instruction = op | (tag << 16);
assert(tag <= 0xffff);
setofs(&instruction, labelref(c, label));
put32(c, instruction);
break;
}
case OP_TAGN: {
int label = va_arg(ap, int);
uint64_t tag = va_arg(ap, uint64_t);
uint32_t instruction = op | (upb_value_size(tag) << 16);
setofs(&instruction, labelref(c, label));
put32(c, instruction);
put32(c, tag);
put32(c, tag >> 32);
break;
}
}
va_end(ap);
}
#if defined(UPB_USE_JIT_X64) || defined(UPB_DUMP_BYTECODE)
const char *upb_pbdecoder_getopname(unsigned int op) {
#define OP(op) [OP_ ## op] = "OP_" #op
#define T(op) OP(PARSE_##op)
static const char *names[] = {
"<no opcode>",
T(DOUBLE), T(FLOAT), T(INT64), T(UINT64), T(INT32), T(FIXED64), T(FIXED32),
T(BOOL), T(UINT32), T(SFIXED32), T(SFIXED64), T(SINT32), T(SINT64),
OP(STARTMSG), OP(ENDMSG), OP(STARTSEQ), OP(ENDSEQ), OP(STARTSUBMSG),
OP(ENDSUBMSG), OP(STARTSTR), OP(STRING), OP(ENDSTR), OP(CALL), OP(RET),
OP(PUSHLENDELIM), OP(PUSHTAGDELIM), OP(SETDELIM), OP(CHECKDELIM),
OP(BRANCH), OP(TAG1), OP(TAG2), OP(TAGN), OP(SETDISPATCH), OP(POP),
Update upb amalgamation.
10 years ago
OP(SETBIGGROUPNUM), OP(DISPATCH), OP(HALT),
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
};
return op > OP_HALT ? names[0] : names[op];
#undef OP
#undef T
}
#endif
#ifdef UPB_DUMP_BYTECODE
static void dumpbc(uint32_t *p, uint32_t *end, FILE *f) {
uint32_t *begin = p;
while (p < end) {
fprintf(f, "%p %8tx", p, p - begin);
uint32_t instr = *p++;
uint8_t op = getop(instr);
fprintf(f, " %s", upb_pbdecoder_getopname(op));
switch ((opcode)op) {
case OP_SETDISPATCH: {
const upb_inttable *dispatch;
memcpy(&dispatch, p, sizeof(void*));
p += ptr_words;
const upb_pbdecodermethod *method =
(void *)((char *)dispatch -
offsetof(upb_pbdecodermethod, dispatch));
fprintf(f, " %s", upb_msgdef_fullname(
upb_handlers_msgdef(method->dest_handlers_)));
break;
}
Update upb amalgamation.
10 years ago
case OP_DISPATCH:
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
case OP_STARTMSG:
case OP_ENDMSG:
case OP_PUSHLENDELIM:
case OP_POP:
case OP_SETDELIM:
case OP_HALT:
case OP_RET:
break;
case OP_PARSE_DOUBLE:
case OP_PARSE_FLOAT:
case OP_PARSE_INT64:
case OP_PARSE_UINT64:
case OP_PARSE_INT32:
case OP_PARSE_FIXED64:
case OP_PARSE_FIXED32:
case OP_PARSE_BOOL:
case OP_PARSE_UINT32:
case OP_PARSE_SFIXED32:
case OP_PARSE_SFIXED64:
case OP_PARSE_SINT32:
case OP_PARSE_SINT64:
case OP_STARTSEQ:
case OP_ENDSEQ:
case OP_STARTSUBMSG:
case OP_ENDSUBMSG:
case OP_STARTSTR:
case OP_STRING:
case OP_ENDSTR:
case OP_PUSHTAGDELIM:
fprintf(f, " %d", instr >> 8);
break;
case OP_SETBIGGROUPNUM:
fprintf(f, " %d", *p++);
break;
case OP_CHECKDELIM:
case OP_CALL:
case OP_BRANCH:
fprintf(f, " =>0x%tx", p + getofs(instr) - begin);
break;
case OP_TAG1:
case OP_TAG2: {
fprintf(f, " tag:0x%x", instr >> 16);
if (getofs(instr)) {
fprintf(f, " =>0x%tx", p + getofs(instr) - begin);
}
break;
}
case OP_TAGN: {
uint64_t tag = *p++;
tag |= (uint64_t)*p++ << 32;
fprintf(f, " tag:0x%llx", (long long)tag);
fprintf(f, " n:%d", instr >> 16);
if (getofs(instr)) {
fprintf(f, " =>0x%tx", p + getofs(instr) - begin);
}
break;
}
}
fputs("\n", f);
}
}
#endif
static uint64_t get_encoded_tag(const upb_fielddef *f, int wire_type) {
uint32_t tag = (upb_fielddef_number(f) << 3) | wire_type;
uint64_t encoded_tag = upb_vencode32(tag);
// No tag should be greater than 5 bytes.
assert(encoded_tag <= 0xffffffffff);
return encoded_tag;
}
static void putchecktag(compiler *c, const upb_fielddef *f,
int wire_type, int dest) {
uint64_t tag = get_encoded_tag(f, wire_type);
switch (upb_value_size(tag)) {
case 1:
putop(c, OP_TAG1, dest, tag);
break;
case 2:
putop(c, OP_TAG2, dest, tag);
break;
default:
putop(c, OP_TAGN, dest, tag);
break;
}
}
static upb_selector_t getsel(const upb_fielddef *f, upb_handlertype_t type) {
upb_selector_t selector;
bool ok = upb_handlers_getselector(f, type, &selector);
UPB_ASSERT_VAR(ok, ok);
return selector;
}
// Takes an existing, primary dispatch table entry and repacks it with a
// different alternate wire type. Called when we are inserting a secondary
// dispatch table entry for an alternate wire type.
static uint64_t repack(uint64_t dispatch, int new_wt2) {
uint64_t ofs;
uint8_t wt1;
uint8_t old_wt2;
upb_pbdecoder_unpackdispatch(dispatch, &ofs, &wt1, &old_wt2);
assert(old_wt2 == NO_WIRE_TYPE); // wt2 should not be set yet.
return upb_pbdecoder_packdispatch(ofs, wt1, new_wt2);
}
// Marks the current bytecode position as the dispatch target for this message,
// field, and wire type.
static void dispatchtarget(compiler *c, upb_pbdecodermethod *method,
const upb_fielddef *f, int wire_type) {
// Offset is relative to msg base.
uint64_t ofs = pcofs(c) - method->code_base.ofs;
uint32_t fn = upb_fielddef_number(f);
upb_inttable *d = &method->dispatch;
upb_value v;
if (upb_inttable_remove(d, fn, &v)) {
// TODO: prioritize based on packed setting in .proto file.
uint64_t repacked = repack(upb_value_getuint64(v), wire_type);
upb_inttable_insert(d, fn, upb_value_uint64(repacked));
upb_inttable_insert(d, fn + UPB_MAX_FIELDNUMBER, upb_value_uint64(ofs));
} else {
uint64_t val = upb_pbdecoder_packdispatch(ofs, wire_type, NO_WIRE_TYPE);
upb_inttable_insert(d, fn, upb_value_uint64(val));
}
}
static void putpush(compiler *c, const upb_fielddef *f) {
if (upb_fielddef_descriptortype(f) == UPB_DESCRIPTOR_TYPE_MESSAGE) {
putop(c, OP_PUSHLENDELIM);
} else {
uint32_t fn = upb_fielddef_number(f);
if (fn >= 1 << 24) {
putop(c, OP_PUSHTAGDELIM, 0);
putop(c, OP_SETBIGGROUPNUM, fn);
} else {
putop(c, OP_PUSHTAGDELIM, fn);
}
}
}
static upb_pbdecodermethod *find_submethod(const compiler *c,
const upb_pbdecodermethod *method,
const upb_fielddef *f) {
const upb_handlers *sub =
upb_handlers_getsubhandlers(method->dest_handlers_, f);
upb_value v;
return upb_inttable_lookupptr(&c->group->methods, sub, &v)
? upb_value_getptr(v)
: NULL;
}
static void putsel(compiler *c, opcode op, upb_selector_t sel,
const upb_handlers *h) {
if (upb_handlers_gethandler(h, sel)) {
putop(c, op, sel);
}
}
// Puts an opcode to call a callback, but only if a callback actually exists for
// this field and handler type.
static void maybeput(compiler *c, opcode op, const upb_handlers *h,
const upb_fielddef *f, upb_handlertype_t type) {
putsel(c, op, getsel(f, type), h);
}
static bool haslazyhandlers(const upb_handlers *h, const upb_fielddef *f) {
if (!upb_fielddef_lazy(f))
return false;
return upb_handlers_gethandler(h, getsel(f, UPB_HANDLER_STARTSTR)) ||
upb_handlers_gethandler(h, getsel(f, UPB_HANDLER_STRING)) ||
upb_handlers_gethandler(h, getsel(f, UPB_HANDLER_ENDSTR));
}
/* bytecode compiler code generation ******************************************/
// Symbolic names for our local labels.
#define LABEL_LOOPSTART 1 // Top of a repeated field loop.
#define LABEL_LOOPBREAK 2 // To jump out of a repeated loop
#define LABEL_FIELD 3 // Jump backward to find the most recent field.
#define LABEL_ENDMSG 4 // To reach the OP_ENDMSG instr for this msg.
// Generates bytecode to parse a single non-lazy message field.
static void generate_msgfield(compiler *c, const upb_fielddef *f,
upb_pbdecodermethod *method) {
const upb_handlers *h = upb_pbdecodermethod_desthandlers(method);
const upb_pbdecodermethod *sub_m = find_submethod(c, method, f);
if (!sub_m) {
// Don't emit any code for this field at all; it will be parsed as an
// unknown field.
return;
}
label(c, LABEL_FIELD);
int wire_type =
(upb_fielddef_descriptortype(f) == UPB_DESCRIPTOR_TYPE_MESSAGE)
? UPB_WIRE_TYPE_DELIMITED
: UPB_WIRE_TYPE_START_GROUP;
if (upb_fielddef_isseq(f)) {
putop(c, OP_CHECKDELIM, LABEL_ENDMSG);
putchecktag(c, f, wire_type, LABEL_DISPATCH);
dispatchtarget(c, method, f, wire_type);
putop(c, OP_PUSHTAGDELIM, 0);
putop(c, OP_STARTSEQ, getsel(f, UPB_HANDLER_STARTSEQ));
label(c, LABEL_LOOPSTART);
putpush(c, f);
putop(c, OP_STARTSUBMSG, getsel(f, UPB_HANDLER_STARTSUBMSG));
putop(c, OP_CALL, sub_m);
putop(c, OP_POP);
maybeput(c, OP_ENDSUBMSG, h, f, UPB_HANDLER_ENDSUBMSG);
if (wire_type == UPB_WIRE_TYPE_DELIMITED) {
putop(c, OP_SETDELIM);
}
putop(c, OP_CHECKDELIM, LABEL_LOOPBREAK);
putchecktag(c, f, wire_type, LABEL_LOOPBREAK);
putop(c, OP_BRANCH, -LABEL_LOOPSTART);
label(c, LABEL_LOOPBREAK);
putop(c, OP_POP);
maybeput(c, OP_ENDSEQ, h, f, UPB_HANDLER_ENDSEQ);
} else {
putop(c, OP_CHECKDELIM, LABEL_ENDMSG);
putchecktag(c, f, wire_type, LABEL_DISPATCH);
dispatchtarget(c, method, f, wire_type);
putpush(c, f);
putop(c, OP_STARTSUBMSG, getsel(f, UPB_HANDLER_STARTSUBMSG));
putop(c, OP_CALL, sub_m);
putop(c, OP_POP);
maybeput(c, OP_ENDSUBMSG, h, f, UPB_HANDLER_ENDSUBMSG);
if (wire_type == UPB_WIRE_TYPE_DELIMITED) {
putop(c, OP_SETDELIM);
}
}
}
// Generates bytecode to parse a single string or lazy submessage field.
static void generate_delimfield(compiler *c, const upb_fielddef *f,
upb_pbdecodermethod *method) {
const upb_handlers *h = upb_pbdecodermethod_desthandlers(method);
label(c, LABEL_FIELD);
if (upb_fielddef_isseq(f)) {
putop(c, OP_CHECKDELIM, LABEL_ENDMSG);
putchecktag(c, f, UPB_WIRE_TYPE_DELIMITED, LABEL_DISPATCH);
dispatchtarget(c, method, f, UPB_WIRE_TYPE_DELIMITED);
putop(c, OP_PUSHTAGDELIM, 0);
putop(c, OP_STARTSEQ, getsel(f, UPB_HANDLER_STARTSEQ));
label(c, LABEL_LOOPSTART);
putop(c, OP_PUSHLENDELIM);
putop(c, OP_STARTSTR, getsel(f, UPB_HANDLER_STARTSTR));
// Need to emit even if no handler to skip past the string.
putop(c, OP_STRING, getsel(f, UPB_HANDLER_STRING));
putop(c, OP_POP);
maybeput(c, OP_ENDSTR, h, f, UPB_HANDLER_ENDSTR);
putop(c, OP_SETDELIM);
putop(c, OP_CHECKDELIM, LABEL_LOOPBREAK);
putchecktag(c, f, UPB_WIRE_TYPE_DELIMITED, LABEL_LOOPBREAK);
putop(c, OP_BRANCH, -LABEL_LOOPSTART);
label(c, LABEL_LOOPBREAK);
putop(c, OP_POP);
maybeput(c, OP_ENDSEQ, h, f, UPB_HANDLER_ENDSEQ);
} else {
putop(c, OP_CHECKDELIM, LABEL_ENDMSG);
putchecktag(c, f, UPB_WIRE_TYPE_DELIMITED, LABEL_DISPATCH);
dispatchtarget(c, method, f, UPB_WIRE_TYPE_DELIMITED);
putop(c, OP_PUSHLENDELIM);
putop(c, OP_STARTSTR, getsel(f, UPB_HANDLER_STARTSTR));
putop(c, OP_STRING, getsel(f, UPB_HANDLER_STRING));
putop(c, OP_POP);
maybeput(c, OP_ENDSTR, h, f, UPB_HANDLER_ENDSTR);
putop(c, OP_SETDELIM);
}
}
// Generates bytecode to parse a single primitive field.
static void generate_primitivefield(compiler *c, const upb_fielddef *f,
upb_pbdecodermethod *method) {
label(c, LABEL_FIELD);
const upb_handlers *h = upb_pbdecodermethod_desthandlers(method);
upb_descriptortype_t descriptor_type = upb_fielddef_descriptortype(f);
// From a decoding perspective, ENUM is the same as INT32.
if (descriptor_type == UPB_DESCRIPTOR_TYPE_ENUM)
descriptor_type = UPB_DESCRIPTOR_TYPE_INT32;
opcode parse_type = (opcode)descriptor_type;
// TODO(haberman): generate packed or non-packed first depending on "packed"
// setting in the fielddef. This will favor (in speed) whichever was
// specified.
assert((int)parse_type >= 0 && parse_type <= OP_MAX);
upb_selector_t sel = getsel(f, upb_handlers_getprimitivehandlertype(f));
int wire_type = upb_pb_native_wire_types[upb_fielddef_descriptortype(f)];
if (upb_fielddef_isseq(f)) {
putop(c, OP_CHECKDELIM, LABEL_ENDMSG);
putchecktag(c, f, UPB_WIRE_TYPE_DELIMITED, LABEL_DISPATCH);
dispatchtarget(c, method, f, UPB_WIRE_TYPE_DELIMITED);
putop(c, OP_PUSHLENDELIM);
putop(c, OP_STARTSEQ, getsel(f, UPB_HANDLER_STARTSEQ)); // Packed
label(c, LABEL_LOOPSTART);
putop(c, parse_type, sel);
putop(c, OP_CHECKDELIM, LABEL_LOOPBREAK);
putop(c, OP_BRANCH, -LABEL_LOOPSTART);
dispatchtarget(c, method, f, wire_type);
putop(c, OP_PUSHTAGDELIM, 0);
putop(c, OP_STARTSEQ, getsel(f, UPB_HANDLER_STARTSEQ)); // Non-packed
label(c, LABEL_LOOPSTART);
putop(c, parse_type, sel);
putop(c, OP_CHECKDELIM, LABEL_LOOPBREAK);
putchecktag(c, f, wire_type, LABEL_LOOPBREAK);
putop(c, OP_BRANCH, -LABEL_LOOPSTART);
label(c, LABEL_LOOPBREAK);
putop(c, OP_POP); // Packed and non-packed join.
maybeput(c, OP_ENDSEQ, h, f, UPB_HANDLER_ENDSEQ);
putop(c, OP_SETDELIM); // Could remove for non-packed by dup ENDSEQ.
} else {
putop(c, OP_CHECKDELIM, LABEL_ENDMSG);
putchecktag(c, f, wire_type, LABEL_DISPATCH);
dispatchtarget(c, method, f, wire_type);
putop(c, parse_type, sel);
}
}
// Adds bytecode for parsing the given message to the given decoderplan,
// while adding all dispatch targets to this message's dispatch table.
static void compile_method(compiler *c, upb_pbdecodermethod *method) {
assert(method);
// Clear all entries in the dispatch table.
upb_inttable_uninit(&method->dispatch);
upb_inttable_init(&method->dispatch, UPB_CTYPE_UINT64);
const upb_handlers *h = upb_pbdecodermethod_desthandlers(method);
const upb_msgdef *md = upb_handlers_msgdef(h);
method->code_base.ofs = pcofs(c);
putop(c, OP_SETDISPATCH, &method->dispatch);
putsel(c, OP_STARTMSG, UPB_STARTMSG_SELECTOR, h);
label(c, LABEL_FIELD);
Update upb amalgamation.
10 years ago
uint32_t* start_pc = c->pc;
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upb_msg_field_iter i;
for(upb_msg_field_begin(&i, md);
!upb_msg_field_done(&i);
upb_msg_field_next(&i)) {
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10 years ago
const upb_fielddef *f = upb_msg_iter_field(&i);
upb_fieldtype_t type = upb_fielddef_type(f);
if (type == UPB_TYPE_MESSAGE && !(haslazyhandlers(h, f) && c->lazy)) {
generate_msgfield(c, f, method);
} else if (type == UPB_TYPE_STRING || type == UPB_TYPE_BYTES ||
type == UPB_TYPE_MESSAGE) {
generate_delimfield(c, f, method);
} else {
generate_primitivefield(c, f, method);
}
}
Update upb amalgamation.
10 years ago
// If there were no fields, or if no handlers were defined, we need to
// generate a non-empty loop body so that we can at least dispatch for unknown
// fields and check for the end of the message.
if (c->pc == start_pc) {
// Check for end-of-message.
putop(c, OP_CHECKDELIM, LABEL_ENDMSG);
// Unconditionally dispatch.
putop(c, OP_DISPATCH, 0);
}
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
// For now we just loop back to the last field of the message (or if none,
Update upb amalgamation.
10 years ago
// the DISPATCH opcode for the message).
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
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putop(c, OP_BRANCH, -LABEL_FIELD);
// Insert both a label and a dispatch table entry for this end-of-msg.
label(c, LABEL_ENDMSG);
upb_value val = upb_value_uint64(pcofs(c) - method->code_base.ofs);
upb_inttable_insert(&method->dispatch, DISPATCH_ENDMSG, val);
putsel(c, OP_ENDMSG, UPB_ENDMSG_SELECTOR, h);
putop(c, OP_RET);
upb_inttable_compact(&method->dispatch);
}
// Populate "methods" with new upb_pbdecodermethod objects reachable from "h".
// Returns the method for these handlers.
//
// Generates a new method for every destination handlers reachable from "h".
static void find_methods(compiler *c, const upb_handlers *h) {
upb_value v;
if (upb_inttable_lookupptr(&c->group->methods, h, &v))
return;
newmethod(h, c->group);
// Find submethods.
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upb_msg_field_iter i;
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10 years ago
const upb_msgdef *md = upb_handlers_msgdef(h);
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for(upb_msg_field_begin(&i, md);
!upb_msg_field_done(&i);
upb_msg_field_next(&i)) {
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const upb_fielddef *f = upb_msg_iter_field(&i);
const upb_handlers *sub_h;
if (upb_fielddef_type(f) == UPB_TYPE_MESSAGE &&
(sub_h = upb_handlers_getsubhandlers(h, f)) != NULL) {
// We only generate a decoder method for submessages with handlers.
// Others will be parsed as unknown fields.
find_methods(c, sub_h);
}
}
}
// (Re-)compile bytecode for all messages in "msgs."
// Overwrites any existing bytecode in "c".
static void compile_methods(compiler *c) {
// Start over at the beginning of the bytecode.
c->pc = c->group->bytecode;
upb_inttable_iter i;
upb_inttable_begin(&i, &c->group->methods);
for(; !upb_inttable_done(&i); upb_inttable_next(&i)) {
upb_pbdecodermethod *method = upb_value_getptr(upb_inttable_iter_value(&i));
compile_method(c, method);
}
}
static void set_bytecode_handlers(mgroup *g) {
upb_inttable_iter i;
upb_inttable_begin(&i, &g->methods);
for(; !upb_inttable_done(&i); upb_inttable_next(&i)) {
upb_pbdecodermethod *m = upb_value_getptr(upb_inttable_iter_value(&i));
m->code_base.ptr = g->bytecode + m->code_base.ofs;
upb_byteshandler *h = &m->input_handler_;
upb_byteshandler_setstartstr(h, upb_pbdecoder_startbc, m->code_base.ptr);
upb_byteshandler_setstring(h, upb_pbdecoder_decode, g);
upb_byteshandler_setendstr(h, upb_pbdecoder_end, m);
}
}
Support oneofs in MRI Ruby C extension.
10 years ago
/* JIT setup. *****************************************************************/
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10 years ago
#ifdef UPB_USE_JIT_X64
static void sethandlers(mgroup *g, bool allowjit) {
g->jit_code = NULL;
if (allowjit) {
// Compile byte-code into machine code, create handlers.
upb_pbdecoder_jit(g);
} else {
set_bytecode_handlers(g);
}
}
#else // UPB_USE_JIT_X64
static void sethandlers(mgroup *g, bool allowjit) {
// No JIT compiled in; use bytecode handlers unconditionally.
UPB_UNUSED(allowjit);
set_bytecode_handlers(g);
}
#endif // UPB_USE_JIT_X64
// TODO(haberman): allow this to be constructed for an arbitrary set of dest
// handlers and other mgroups (but verify we have a transitive closure).
const mgroup *mgroup_new(const upb_handlers *dest, bool allowjit, bool lazy,
const void *owner) {
UPB_UNUSED(allowjit);
assert(upb_handlers_isfrozen(dest));
mgroup *g = newgroup(owner);
compiler *c = newcompiler(g, lazy);
find_methods(c, dest);
// We compile in two passes:
// 1. all messages are assigned relative offsets from the beginning of the
// bytecode (saved in method->code_base).
// 2. forwards OP_CALL instructions can be correctly linked since message
// offsets have been previously assigned.
//
// Could avoid the second pass by linking OP_CALL instructions somehow.
compile_methods(c);
compile_methods(c);
g->bytecode_end = c->pc;
freecompiler(c);
#ifdef UPB_DUMP_BYTECODE
FILE *f = fopen("/tmp/upb-bytecode", "wb");
assert(f);
dumpbc(g->bytecode, g->bytecode_end, stderr);
dumpbc(g->bytecode, g->bytecode_end, f);
fclose(f);
#endif
sethandlers(g, allowjit);
return g;
}
/* upb_pbcodecache ************************************************************/
void upb_pbcodecache_init(upb_pbcodecache *c) {
upb_inttable_init(&c->groups, UPB_CTYPE_CONSTPTR);
c->allow_jit_ = true;
}
void upb_pbcodecache_uninit(upb_pbcodecache *c) {
upb_inttable_iter i;
upb_inttable_begin(&i, &c->groups);
for(; !upb_inttable_done(&i); upb_inttable_next(&i)) {
const mgroup *group = upb_value_getconstptr(upb_inttable_iter_value(&i));
upb_refcounted_unref(UPB_UPCAST(group), c);
}
upb_inttable_uninit(&c->groups);
}
bool upb_pbcodecache_allowjit(const upb_pbcodecache *c) {
return c->allow_jit_;
}
bool upb_pbcodecache_setallowjit(upb_pbcodecache *c, bool allow) {
if (upb_inttable_count(&c->groups) > 0)
return false;
c->allow_jit_ = allow;
return true;
}
const upb_pbdecodermethod *upb_pbcodecache_getdecodermethod(
upb_pbcodecache *c, const upb_pbdecodermethodopts *opts) {
// Right now we build a new DecoderMethod every time.
// TODO(haberman): properly cache methods by their true key.
const mgroup *g = mgroup_new(opts->handlers, c->allow_jit_, opts->lazy, c);
upb_inttable_push(&c->groups, upb_value_constptr(g));
upb_value v;
bool ok = upb_inttable_lookupptr(&g->methods, opts->handlers, &v);
UPB_ASSERT_VAR(ok, ok);
return upb_value_getptr(v);
}
/* upb_pbdecodermethodopts ****************************************************/
void upb_pbdecodermethodopts_init(upb_pbdecodermethodopts *opts,
const upb_handlers *h) {
opts->handlers = h;
opts->lazy = false;
}
void upb_pbdecodermethodopts_setlazy(upb_pbdecodermethodopts *opts, bool lazy) {
opts->lazy = lazy;
}
/*
* upb - a minimalist implementation of protocol buffers.
*
* Copyright (c) 2008-2013 Google Inc. See LICENSE for details.
* Author: Josh Haberman <jhaberman@gmail.com>
*
* This file implements a VM for the interpreted (bytecode) decoder.
*
* Bytecode must previously have been generated using the bytecode compiler in
* compile_decoder.c. This decoder then walks through the bytecode op-by-op to
* parse the input.
*
* Decoding is fully resumable; we just keep a pointer to the current bytecode
* instruction and resume from there. A fair amount of the logic here is to
* handle the fact that values can span buffer seams and we have to be able to
* be capable of suspending/resuming from any byte in the stream. This
* sometimes requires keeping a few trailing bytes from the last buffer around
* in the "residual" buffer.
*/
#include <inttypes.h>
#include <setjmp.h>
#include <stdarg.h>
#include <stddef.h>
#include <stdlib.h>
#ifdef UPB_DUMP_BYTECODE
#include <stdio.h>
#endif
#define CHECK_SUSPEND(x) if (!(x)) return upb_pbdecoder_suspend(d);
// Error messages that are shared between the bytecode and JIT decoders.
const char *kPbDecoderStackOverflow = "Nesting too deep.";
// Error messages shared within this file.
static const char *kUnterminatedVarint = "Unterminated varint.";
/* upb_pbdecoder **************************************************************/
static opcode halt = OP_HALT;
// Whether an op consumes any of the input buffer.
static bool consumes_input(opcode op) {
switch (op) {
case OP_SETDISPATCH:
case OP_STARTMSG:
case OP_ENDMSG:
case OP_STARTSEQ:
case OP_ENDSEQ:
case OP_STARTSUBMSG:
case OP_ENDSUBMSG:
case OP_STARTSTR:
case OP_ENDSTR:
case OP_PUSHTAGDELIM:
case OP_POP:
case OP_SETDELIM:
case OP_SETBIGGROUPNUM:
case OP_CHECKDELIM:
case OP_CALL:
case OP_RET:
case OP_BRANCH:
return false;
default:
return true;
}
}
static bool in_residual_buf(const upb_pbdecoder *d, const char *p);
// It's unfortunate that we have to micro-manage the compiler this way,
// especially since this tuning is necessarily specific to one hardware
// configuration. But emperically on a Core i7, performance increases 30-50%
// with these annotations. Every instance where these appear, gcc 4.2.1 made
// the wrong decision and degraded performance in benchmarks.
#define FORCEINLINE static inline __attribute__((always_inline))
#define NOINLINE __attribute__((noinline))
static void seterr(upb_pbdecoder *d, const char *msg) {
// TODO(haberman): encapsulate this access to pipeline->status, but not sure
// exactly what that interface should look like.
upb_status_seterrmsg(d->status, msg);
}
void upb_pbdecoder_seterr(upb_pbdecoder *d, const char *msg) {
seterr(d, msg);
}
/* Buffering ******************************************************************/
// We operate on one buffer at a time, which is either the user's buffer passed
// to our "decode" callback or some residual bytes from the previous buffer.
// How many bytes can be safely read from d->ptr without reading past end-of-buf
// or past the current delimited end.
static size_t curbufleft(const upb_pbdecoder *d) {
assert(d->data_end >= d->ptr);
return d->data_end - d->ptr;
}
// Overall stream offset of d->ptr.
uint64_t offset(const upb_pbdecoder *d) {
return d->bufstart_ofs + (d->ptr - d->buf);
}
// Advances d->ptr.
static void advance(upb_pbdecoder *d, size_t len) {
assert(curbufleft(d) >= len);
d->ptr += len;
}
static bool in_buf(const char *p, const char *buf, const char *end) {
return p >= buf && p <= end;
}
static bool in_residual_buf(const upb_pbdecoder *d, const char *p) {
return in_buf(p, d->residual, d->residual_end);
}
// Calculates the delim_end value, which is affected by both the current buffer
// and the parsing stack, so must be called whenever either is updated.
static void set_delim_end(upb_pbdecoder *d) {
size_t delim_ofs = d->top->end_ofs - d->bufstart_ofs;
if (delim_ofs <= (d->end - d->buf)) {
d->delim_end = d->buf + delim_ofs;
d->data_end = d->delim_end;
} else {
d->data_end = d->end;
d->delim_end = NULL;
}
}
static void switchtobuf(upb_pbdecoder *d, const char *buf, const char *end) {
d->ptr = buf;
d->buf = buf;
d->end = end;
set_delim_end(d);
}
static void advancetobuf(upb_pbdecoder *d, const char *buf, size_t len) {
assert(curbufleft(d) == 0);
d->bufstart_ofs += (d->end - d->buf);
switchtobuf(d, buf, buf + len);
}
static void checkpoint(upb_pbdecoder *d) {
// The assertion here is in the interests of efficiency, not correctness.
// We are trying to ensure that we don't checkpoint() more often than
// necessary.
assert(d->checkpoint != d->ptr);
d->checkpoint = d->ptr;
}
// Resumes the decoder from an initial state or from a previous suspend.
int32_t upb_pbdecoder_resume(upb_pbdecoder *d, void *p, const char *buf,
size_t size, const upb_bufhandle *handle) {
UPB_UNUSED(p); // Useless; just for the benefit of the JIT.
d->buf_param = buf;
d->size_param = size;
d->handle = handle;
if (d->residual_end > d->residual) {
// We have residual bytes from the last buffer.
assert(d->ptr == d->residual);
} else {
switchtobuf(d, buf, buf + size);
}
d->checkpoint = d->ptr;
if (d->top->groupnum < 0) {
CHECK_RETURN(upb_pbdecoder_skipunknown(d, -1, 0));
d->checkpoint = d->ptr;
}
return DECODE_OK;
}
// Suspends the decoder at the last checkpoint, without saving any residual
// bytes. If there are any unconsumed bytes, returns a short byte count.
size_t upb_pbdecoder_suspend(upb_pbdecoder *d) {
d->pc = d->last;
if (d->checkpoint == d->residual) {
// Checkpoint was in residual buf; no user bytes were consumed.
d->ptr = d->residual;
return 0;
} else {
assert(!in_residual_buf(d, d->checkpoint));
assert(d->buf == d->buf_param);
size_t consumed = d->checkpoint - d->buf;
d->bufstart_ofs += consumed;
d->residual_end = d->residual;
switchtobuf(d, d->residual, d->residual_end);
return consumed;
}
}
// Suspends the decoder at the last checkpoint, and saves any unconsumed
// bytes in our residual buffer. This is necessary if we need more user
// bytes to form a complete value, which might not be contiguous in the
// user's buffers. Always consumes all user bytes.
static size_t suspend_save(upb_pbdecoder *d) {
// We hit end-of-buffer before we could parse a full value.
// Save any unconsumed bytes (if any) to the residual buffer.
d->pc = d->last;
if (d->checkpoint == d->residual) {
// Checkpoint was in residual buf; append user byte(s) to residual buf.
assert((d->residual_end - d->residual) + d->size_param <=
sizeof(d->residual));
if (!in_residual_buf(d, d->ptr)) {
d->bufstart_ofs -= (d->residual_end - d->residual);
}
memcpy(d->residual_end, d->buf_param, d->size_param);
d->residual_end += d->size_param;
} else {
// Checkpoint was in user buf; old residual bytes not needed.
assert(!in_residual_buf(d, d->checkpoint));
d->ptr = d->checkpoint;
size_t save = curbufleft(d);
assert(save <= sizeof(d->residual));
memcpy(d->residual, d->ptr, save);
d->residual_end = d->residual + save;
d->bufstart_ofs = offset(d);
}
switchtobuf(d, d->residual, d->residual_end);
return d->size_param;
}
// Skips "bytes" bytes in the stream, which may be more than available. If we
// skip more bytes than are available, we return a long read count to the caller
// indicating how many bytes the caller should skip before passing a new buffer.
static int32_t skip(upb_pbdecoder *d, size_t bytes) {
assert(!in_residual_buf(d, d->ptr) || d->size_param == 0);
if (curbufleft(d) >= bytes) {
// Skipped data is all in current buffer.
advance(d, bytes);
return DECODE_OK;
} else {
// Skipped data extends beyond currently available buffers.
d->pc = d->last;
size_t skip = bytes - curbufleft(d);
d->bufstart_ofs += (d->end - d->buf) + skip;
d->residual_end = d->residual;
switchtobuf(d, d->residual, d->residual_end);
return d->size_param + skip;
}
}
// Copies the next "bytes" bytes into "buf" and advances the stream.
// Requires that this many bytes are available in the current buffer.
FORCEINLINE void consumebytes(upb_pbdecoder *d, void *buf, size_t bytes) {
assert(bytes <= curbufleft(d));
memcpy(buf, d->ptr, bytes);
advance(d, bytes);
}
// Slow path for getting the next "bytes" bytes, regardless of whether they are
// available in the current buffer or not. Returns a status code as described
// in decoder.int.h.
static NOINLINE int32_t getbytes_slow(upb_pbdecoder *d, void *buf,
size_t bytes) {
const size_t avail = curbufleft(d);
consumebytes(d, buf, avail);
bytes -= avail;
assert(bytes > 0);
if (in_residual_buf(d, d->ptr)) {
advancetobuf(d, d->buf_param, d->size_param);
}
if (curbufleft(d) >= bytes) {
consumebytes(d, buf + avail, bytes);
return DECODE_OK;
} else if (d->data_end == d->delim_end) {
seterr(d, "Submessage ended in the middle of a value or group");
return upb_pbdecoder_suspend(d);
} else {
return suspend_save(d);
}
}
// Gets the next "bytes" bytes, regardless of whether they are available in the
// current buffer or not. Returns a status code as described in decoder.int.h.
FORCEINLINE int32_t getbytes(upb_pbdecoder *d, void *buf, size_t bytes) {
if (curbufleft(d) >= bytes) {
// Buffer has enough data to satisfy.
consumebytes(d, buf, bytes);
return DECODE_OK;
} else {
return getbytes_slow(d, buf, bytes);
}
}
static NOINLINE size_t peekbytes_slow(upb_pbdecoder *d, void *buf,
size_t bytes) {
size_t ret = curbufleft(d);
memcpy(buf, d->ptr, ret);
if (in_residual_buf(d, d->ptr)) {
size_t copy = UPB_MIN(bytes - ret, d->size_param);
memcpy(buf + ret, d->buf_param, copy);
ret += copy;
}
return ret;
}
FORCEINLINE size_t peekbytes(upb_pbdecoder *d, void *buf, size_t bytes) {
if (curbufleft(d) >= bytes) {
memcpy(buf, d->ptr, bytes);
return bytes;
} else {
return peekbytes_slow(d, buf, bytes);
}
}
/* Decoding of wire types *****************************************************/
// Slow path for decoding a varint from the current buffer position.
// Returns a status code as described in decoder.int.h.
NOINLINE int32_t upb_pbdecoder_decode_varint_slow(upb_pbdecoder *d,
uint64_t *u64) {
*u64 = 0;
uint8_t byte = 0x80;
int bitpos;
for(bitpos = 0; bitpos < 70 && (byte & 0x80); bitpos += 7) {
int32_t ret = getbytes(d, &byte, 1);
if (ret >= 0) return ret;
*u64 |= (uint64_t)(byte & 0x7F) << bitpos;
}
if(bitpos == 70 && (byte & 0x80)) {
seterr(d, kUnterminatedVarint);
return upb_pbdecoder_suspend(d);
}
return DECODE_OK;
}
// Decodes a varint from the current buffer position.
// Returns a status code as described in decoder.int.h.
FORCEINLINE int32_t decode_varint(upb_pbdecoder *d, uint64_t *u64) {
if (curbufleft(d) > 0 && !(*d->ptr & 0x80)) {
*u64 = *d->ptr;
advance(d, 1);
return DECODE_OK;
} else if (curbufleft(d) >= 10) {
// Fast case.
upb_decoderet r = upb_vdecode_fast(d->ptr);
if (r.p == NULL) {
seterr(d, kUnterminatedVarint);
return upb_pbdecoder_suspend(d);
}
advance(d, r.p - d->ptr);
*u64 = r.val;
return DECODE_OK;
} else {
// Slow case -- varint spans buffer seam.
return upb_pbdecoder_decode_varint_slow(d, u64);
}
}
// Decodes a 32-bit varint from the current buffer position.
// Returns a status code as described in decoder.int.h.
FORCEINLINE int32_t decode_v32(upb_pbdecoder *d, uint32_t *u32) {
uint64_t u64;
int32_t ret = decode_varint(d, &u64);
if (ret >= 0) return ret;
if (u64 > UINT32_MAX) {
seterr(d, "Unterminated 32-bit varint");
// TODO(haberman) guarantee that this function return is >= 0 somehow,
// so we know this path will always be treated as error by our caller.
// Right now the size_t -> int32_t can overflow and produce negative values.
*u32 = 0;
return upb_pbdecoder_suspend(d);
}
*u32 = u64;
return DECODE_OK;
}
// Decodes a fixed32 from the current buffer position.
// Returns a status code as described in decoder.int.h.
// TODO: proper byte swapping for big-endian machines.
FORCEINLINE int32_t decode_fixed32(upb_pbdecoder *d, uint32_t *u32) {
return getbytes(d, u32, 4);
}
// Decodes a fixed64 from the current buffer position.
// Returns a status code as described in decoder.int.h.
// TODO: proper byte swapping for big-endian machines.
FORCEINLINE int32_t decode_fixed64(upb_pbdecoder *d, uint64_t *u64) {
return getbytes(d, u64, 8);
}
// Non-static versions of the above functions.
// These are called by the JIT for fallback paths.
int32_t upb_pbdecoder_decode_f32(upb_pbdecoder *d, uint32_t *u32) {
return decode_fixed32(d, u32);
}
int32_t upb_pbdecoder_decode_f64(upb_pbdecoder *d, uint64_t *u64) {
return decode_fixed64(d, u64);
}
static double as_double(uint64_t n) { double d; memcpy(&d, &n, 8); return d; }
static float as_float(uint32_t n) { float f; memcpy(&f, &n, 4); return f; }
// Pushes a frame onto the decoder stack.
static bool decoder_push(upb_pbdecoder *d, uint64_t end) {
upb_pbdecoder_frame *fr = d->top;
if (end > fr->end_ofs) {
seterr(d, "Submessage end extends past enclosing submessage.");
return false;
} else if ((fr + 1) == d->limit) {
seterr(d, kPbDecoderStackOverflow);
return false;
}
fr++;
fr->end_ofs = end;
fr->dispatch = NULL;
fr->groupnum = 0;
d->top = fr;
return true;
}
static bool pushtagdelim(upb_pbdecoder *d, uint32_t arg) {
// While we expect to see an "end" tag (either ENDGROUP or a non-sequence
// field number) prior to hitting any enclosing submessage end, pushing our
// existing delim end prevents us from continuing to parse values from a
// corrupt proto that doesn't give us an END tag in time.
if (!decoder_push(d, d->top->end_ofs))
return false;
d->top->groupnum = arg;
return true;
}
// Pops a frame from the decoder stack.
static void decoder_pop(upb_pbdecoder *d) { d->top--; }
NOINLINE int32_t upb_pbdecoder_checktag_slow(upb_pbdecoder *d,
uint64_t expected) {
uint64_t data = 0;
size_t bytes = upb_value_size(expected);
size_t read = peekbytes(d, &data, bytes);
if (read == bytes && data == expected) {
// Advance past matched bytes.
int32_t ok = getbytes(d, &data, read);
UPB_ASSERT_VAR(ok, ok < 0);
return DECODE_OK;
} else if (read < bytes && memcmp(&data, &expected, read) == 0) {
return suspend_save(d);
} else {
return DECODE_MISMATCH;
}
}
int32_t upb_pbdecoder_skipunknown(upb_pbdecoder *d, int32_t fieldnum,
uint8_t wire_type) {
if (fieldnum >= 0)
goto have_tag;
while (true) {
uint32_t tag;
CHECK_RETURN(decode_v32(d, &tag));
wire_type = tag & 0x7;
fieldnum = tag >> 3;
have_tag:
if (fieldnum == 0) {
seterr(d, "Saw invalid field number (0)");
return upb_pbdecoder_suspend(d);
}
// TODO: deliver to unknown field callback.
switch (wire_type) {
case UPB_WIRE_TYPE_32BIT:
CHECK_RETURN(skip(d, 4));
break;
case UPB_WIRE_TYPE_64BIT:
CHECK_RETURN(skip(d, 8));
break;
case UPB_WIRE_TYPE_VARINT: {
uint64_t u64;
CHECK_RETURN(decode_varint(d, &u64));
break;
}
case UPB_WIRE_TYPE_DELIMITED: {
uint32_t len;
CHECK_RETURN(decode_v32(d, &len));
CHECK_RETURN(skip(d, len));
break;
}
case UPB_WIRE_TYPE_START_GROUP:
CHECK_SUSPEND(pushtagdelim(d, -fieldnum));
break;
case UPB_WIRE_TYPE_END_GROUP:
if (fieldnum == -d->top->groupnum) {
decoder_pop(d);
} else if (fieldnum == d->top->groupnum) {
return DECODE_ENDGROUP;
} else {
seterr(d, "Unmatched ENDGROUP tag.");
return upb_pbdecoder_suspend(d);
}
break;
default:
seterr(d, "Invalid wire type");
return upb_pbdecoder_suspend(d);
}
if (d->top->groupnum >= 0) {
return DECODE_OK;
}
if (d->ptr == d->delim_end) {
seterr(d, "Enclosing submessage ended in the middle of value or group");
// Unlike most errors we notice during parsing, right now we have consumed
// all of the user's input.
//
// There are three different options for how to handle this case:
//
// 1. decode() = short count, error = set
// 2. decode() = full count, error = set
// 3. decode() = full count, error NOT set, short count and error will
// be reported on next call to decode() (or end())
//
// (1) and (3) have the advantage that they preserve the invariant that an
// error occurs iff decode() returns a short count.
//
// (2) and (3) have the advantage of reflecting the fact that all of the
// bytes were in fact parsed (and possibly delivered to the unknown field
// handler, in the future when that is supported).
//
// (3) requires extra state in the decode (a place to store the "permanent
// error" that we should return for all subsequent attempts to decode).
// But we likely want this anyway.
//
// Right now we do (1), thanks to the fact that we checkpoint *after* this
// check. (3) may be a better choice long term; unclear at the moment.
return upb_pbdecoder_suspend(d);
}
checkpoint(d);
}
}
static void goto_endmsg(upb_pbdecoder *d) {
upb_value v;
bool found = upb_inttable_lookup32(d->top->dispatch, DISPATCH_ENDMSG, &v);
UPB_ASSERT_VAR(found, found);
d->pc = d->top->base + upb_value_getuint64(v);
}
// Parses a tag and jumps to the corresponding bytecode instruction for this
// field.
//
// If the tag is unknown (or the wire type doesn't match), parses the field as
// unknown. If the tag is a valid ENDGROUP tag, jumps to the bytecode
// instruction for the end of message.
static int32_t dispatch(upb_pbdecoder *d) {
upb_inttable *dispatch = d->top->dispatch;
// Decode tag.
uint32_t tag;
CHECK_RETURN(decode_v32(d, &tag));
uint8_t wire_type = tag & 0x7;
uint32_t fieldnum = tag >> 3;
// Lookup tag. Because of packed/non-packed compatibility, we have to
// check the wire type against two possibilities.
upb_value val;
if (fieldnum != DISPATCH_ENDMSG &&
upb_inttable_lookup32(dispatch, fieldnum, &val)) {
uint64_t v = upb_value_getuint64(val);
if (wire_type == (v & 0xff)) {
d->pc = d->top->base + (v >> 16);
return DECODE_OK;
} else if (wire_type == ((v >> 8) & 0xff)) {
bool found =
upb_inttable_lookup(dispatch, fieldnum + UPB_MAX_FIELDNUMBER, &val);
UPB_ASSERT_VAR(found, found);
d->pc = d->top->base + upb_value_getuint64(val);
return DECODE_OK;
}
}
// Unknown field or ENDGROUP.
int32_t ret = upb_pbdecoder_skipunknown(d, fieldnum, wire_type);
if (ret == DECODE_ENDGROUP) {
goto_endmsg(d);
return DECODE_OK;
} else {
d->pc = d->last - 1; // Rewind to CHECKDELIM.
return ret;
}
}
// Callers know that the stack is more than one deep because the opcodes that
// call this only occur after PUSH operations.
upb_pbdecoder_frame *outer_frame(upb_pbdecoder *d) {
assert(d->top != d->stack);
return d->top - 1;
}
/* The main decoding loop *****************************************************/
// The main decoder VM function. Uses traditional bytecode dispatch loop with a
// switch() statement.
size_t upb_pbdecoder_decode(void *closure, const void *hd, const char *buf,
size_t size, const upb_bufhandle *handle) {
upb_pbdecoder *d = closure;
const mgroup *group = hd;
assert(buf);
int32_t result = upb_pbdecoder_resume(d, NULL, buf, size, handle);
if (result == DECODE_ENDGROUP) {
goto_endmsg(d);
}
CHECK_RETURN(result);
UPB_UNUSED(group);
#define VMCASE(op, code) \
case op: { code; if (consumes_input(op)) checkpoint(d); break; }
#define PRIMITIVE_OP(type, wt, name, convfunc, ctype) \
VMCASE(OP_PARSE_ ## type, { \
ctype val; \
CHECK_RETURN(decode_ ## wt(d, &val)); \
upb_sink_put ## name(&d->top->sink, arg, (convfunc)(val)); \
})
while(1) {
d->last = d->pc;
int32_t instruction = *d->pc++;
opcode op = getop(instruction);
uint32_t arg = instruction >> 8;
int32_t longofs = arg;
assert(d->ptr != d->residual_end);
#ifdef UPB_DUMP_BYTECODE
fprintf(stderr, "s_ofs=%d buf_ofs=%d data_rem=%d buf_rem=%d delim_rem=%d "
"%x %s (%d)\n",
(int)offset(d),
(int)(d->ptr - d->buf),
(int)(d->data_end - d->ptr),
(int)(d->end - d->ptr),
(int)((d->top->end_ofs - d->bufstart_ofs) - (d->ptr - d->buf)),
(int)(d->pc - 1 - group->bytecode),
upb_pbdecoder_getopname(op),
arg);
#endif
switch (op) {
// Technically, we are losing data if we see a 32-bit varint that is not
// properly sign-extended. We could detect this and error about the data
// loss, but proto2 does not do this, so we pass.
PRIMITIVE_OP(INT32, varint, int32, int32_t, uint64_t)
PRIMITIVE_OP(INT64, varint, int64, int64_t, uint64_t)
PRIMITIVE_OP(UINT32, varint, uint32, uint32_t, uint64_t)
PRIMITIVE_OP(UINT64, varint, uint64, uint64_t, uint64_t)
PRIMITIVE_OP(FIXED32, fixed32, uint32, uint32_t, uint32_t)
PRIMITIVE_OP(FIXED64, fixed64, uint64, uint64_t, uint64_t)
PRIMITIVE_OP(SFIXED32, fixed32, int32, int32_t, uint32_t)
PRIMITIVE_OP(SFIXED64, fixed64, int64, int64_t, uint64_t)
PRIMITIVE_OP(BOOL, varint, bool, bool, uint64_t)
PRIMITIVE_OP(DOUBLE, fixed64, double, as_double, uint64_t)
PRIMITIVE_OP(FLOAT, fixed32, float, as_float, uint32_t)
PRIMITIVE_OP(SINT32, varint, int32, upb_zzdec_32, uint64_t)
PRIMITIVE_OP(SINT64, varint, int64, upb_zzdec_64, uint64_t)
VMCASE(OP_SETDISPATCH,
d->top->base = d->pc - 1;
memcpy(&d->top->dispatch, d->pc, sizeof(void*));
d->pc += sizeof(void*) / sizeof(uint32_t);
)
VMCASE(OP_STARTMSG,
CHECK_SUSPEND(upb_sink_startmsg(&d->top->sink));
)
VMCASE(OP_ENDMSG,
CHECK_SUSPEND(upb_sink_endmsg(&d->top->sink, d->status));
)
VMCASE(OP_STARTSEQ,
upb_pbdecoder_frame *outer = outer_frame(d);
CHECK_SUSPEND(upb_sink_startseq(&outer->sink, arg, &d->top->sink));
)
VMCASE(OP_ENDSEQ,
CHECK_SUSPEND(upb_sink_endseq(&d->top->sink, arg));
)
VMCASE(OP_STARTSUBMSG,
upb_pbdecoder_frame *outer = outer_frame(d);
CHECK_SUSPEND(upb_sink_startsubmsg(&outer->sink, arg, &d->top->sink));
)
VMCASE(OP_ENDSUBMSG,
CHECK_SUSPEND(upb_sink_endsubmsg(&d->top->sink, arg));
)
VMCASE(OP_STARTSTR,
uint32_t len = d->top->end_ofs - offset(d);
upb_pbdecoder_frame *outer = outer_frame(d);
CHECK_SUSPEND(upb_sink_startstr(&outer->sink, arg, len, &d->top->sink));
if (len == 0) {
d->pc++; // Skip OP_STRING.
}
)
VMCASE(OP_STRING,
uint32_t len = curbufleft(d);
size_t n = upb_sink_putstring(&d->top->sink, arg, d->ptr, len, handle);
if (n > len) {
if (n > d->top->end_ofs - offset(d)) {
seterr(d, "Tried to skip past end of string.");
return upb_pbdecoder_suspend(d);
} else {
int32_t ret = skip(d, n);
// This shouldn't return DECODE_OK, because n > len.
assert(ret >= 0);
return ret;
}
}
advance(d, n);
if (n < len || d->delim_end == NULL) {
// We aren't finished with this string yet.
d->pc--; // Repeat OP_STRING.
if (n > 0) checkpoint(d);
return upb_pbdecoder_suspend(d);
}
)
VMCASE(OP_ENDSTR,
CHECK_SUSPEND(upb_sink_endstr(&d->top->sink, arg));
)
VMCASE(OP_PUSHTAGDELIM,
CHECK_SUSPEND(pushtagdelim(d, arg));
)
VMCASE(OP_SETBIGGROUPNUM,
d->top->groupnum = *d->pc++;
)
VMCASE(OP_POP,
assert(d->top > d->stack);
decoder_pop(d);
)
VMCASE(OP_PUSHLENDELIM,
uint32_t len;
CHECK_RETURN(decode_v32(d, &len));
CHECK_SUSPEND(decoder_push(d, offset(d) + len));
set_delim_end(d);
)
VMCASE(OP_SETDELIM,
set_delim_end(d);
)
VMCASE(OP_CHECKDELIM,
// We are guaranteed of this assert because we never allow ourselves to
// consume bytes beyond data_end, which covers delim_end when non-NULL.
assert(!(d->delim_end && d->ptr > d->delim_end));
if (d->ptr == d->delim_end)
d->pc += longofs;
)
VMCASE(OP_CALL,
d->callstack[d->call_len++] = d->pc;
d->pc += longofs;
)
VMCASE(OP_RET,
assert(d->call_len > 0);
d->pc = d->callstack[--d->call_len];
)
VMCASE(OP_BRANCH,
d->pc += longofs;
)
VMCASE(OP_TAG1,
CHECK_SUSPEND(curbufleft(d) > 0);
uint8_t expected = (arg >> 8) & 0xff;
if (*d->ptr == expected) {
advance(d, 1);
} else {
int8_t shortofs;
badtag:
shortofs = arg;
if (shortofs == LABEL_DISPATCH) {
CHECK_RETURN(dispatch(d));
} else {
d->pc += shortofs;
break; // Avoid checkpoint().
}
}
)
VMCASE(OP_TAG2,
CHECK_SUSPEND(curbufleft(d) > 0);
uint16_t expected = (arg >> 8) & 0xffff;
if (curbufleft(d) >= 2) {
uint16_t actual;
memcpy(&actual, d->ptr, 2);
if (expected == actual) {
advance(d, 2);
} else {
goto badtag;
}
} else {
int32_t result = upb_pbdecoder_checktag_slow(d, expected);
if (result == DECODE_MISMATCH) goto badtag;
if (result >= 0) return result;
}
)
VMCASE(OP_TAGN, {
uint64_t expected;
memcpy(&expected, d->pc, 8);
d->pc += 2;
int32_t result = upb_pbdecoder_checktag_slow(d, expected);
if (result == DECODE_MISMATCH) goto badtag;
if (result >= 0) return result;
})
Update upb amalgamation.
10 years ago
VMCASE(OP_DISPATCH, {
CHECK_RETURN(dispatch(d));
})
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
VMCASE(OP_HALT, {
return size;
})
}
}
}
void *upb_pbdecoder_startbc(void *closure, const void *pc, size_t size_hint) {
upb_pbdecoder *d = closure;
UPB_UNUSED(size_hint);
d->call_len = 1;
d->pc = pc;
return d;
}
void *upb_pbdecoder_startjit(void *closure, const void *hd, size_t size_hint) {
UPB_UNUSED(hd);
UPB_UNUSED(size_hint);
upb_pbdecoder *d = closure;
d->call_len = 0;
return d;
}
bool upb_pbdecoder_end(void *closure, const void *handler_data) {
upb_pbdecoder *d = closure;
const upb_pbdecodermethod *method = handler_data;
if (d->residual_end > d->residual) {
seterr(d, "Unexpected EOF");
return false;
}
if (d->top->end_ofs != UINT64_MAX) {
seterr(d, "Unexpected EOF inside delimited string");
return false;
}
// Message ends here.
uint64_t end = offset(d);
d->top->end_ofs = end;
char dummy;
#ifdef UPB_USE_JIT_X64
const mgroup *group = (const mgroup*)method->group;
if (group->jit_code) {
if (d->top != d->stack)
d->stack->end_ofs = 0;
group->jit_code(closure, method->code_base.ptr, &dummy, 0, NULL);
} else {
#endif
d->stack->end_ofs = end;
const uint32_t *p = d->pc;
// Check the previous bytecode, but guard against beginning.
if (p != method->code_base.ptr) p--;
if (getop(*p) == OP_CHECKDELIM) {
// Rewind from OP_TAG* to OP_CHECKDELIM.
assert(getop(*d->pc) == OP_TAG1 ||
getop(*d->pc) == OP_TAG2 ||
Update upb amalgamation.
10 years ago
getop(*d->pc) == OP_TAGN ||
getop(*d->pc == OP_DISPATCH));
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
d->pc = p;
}
upb_pbdecoder_decode(closure, handler_data, &dummy, 0, NULL);
#ifdef UPB_USE_JIT_X64
}
#endif
if (d->call_len != 0) {
seterr(d, "Unexpected EOF");
return false;
}
return true;
}
void upb_pbdecoder_init(upb_pbdecoder *d, const upb_pbdecodermethod *m,
upb_status *s) {
d->limit = &d->stack[UPB_DECODER_MAX_NESTING];
upb_bytessink_reset(&d->input_, &m->input_handler_, d);
d->method_ = m;
d->callstack[0] = &halt;
d->status = s;
upb_pbdecoder_reset(d);
}
void upb_pbdecoder_reset(upb_pbdecoder *d) {
d->top = d->stack;
d->top->end_ofs = UINT64_MAX;
d->top->groupnum = 0;
d->bufstart_ofs = 0;
d->ptr = d->residual;
d->buf = d->residual;
d->end = d->residual;
d->residual_end = d->residual;
d->call_len = 1;
}
uint64_t upb_pbdecoder_bytesparsed(const upb_pbdecoder *d) {
return offset(d);
}
// Not currently required, but to support outgrowing the static stack we need
// this.
void upb_pbdecoder_uninit(upb_pbdecoder *d) {
UPB_UNUSED(d);
}
const upb_pbdecodermethod *upb_pbdecoder_method(const upb_pbdecoder *d) {
return d->method_;
}
bool upb_pbdecoder_resetoutput(upb_pbdecoder *d, upb_sink* sink) {
// TODO(haberman): do we need to test whether the decoder is already on the
// stack (like calling this from within a callback)? Should we support
// rebinding the output at all?
assert(sink);
if (d->method_->dest_handlers_) {
if (sink->handlers != d->method_->dest_handlers_)
return false;
}
upb_sink_reset(&d->top->sink, sink->handlers, sink->closure);
return true;
}
upb_bytessink *upb_pbdecoder_input(upb_pbdecoder *d) {
return &d->input_;
}
/*
* upb - a minimalist implementation of protocol buffers.
*
* Copyright (c) 2014 Google Inc. See LICENSE for details.
* Author: Josh Haberman <jhaberman@gmail.com>
*
* Since we are implementing pure handlers (ie. without any out-of-band access
* to pre-computed lengths), we have to buffer all submessages before we can
* emit even their first byte.
*
* Not knowing the size of submessages also means we can't write a perfect
* zero-copy implementation, even with buffering. Lengths are stored as
* varints, which means that we don't know how many bytes to reserve for the
* length until we know what the length is.
*
* This leaves us with three main choices:
*
* 1. buffer all submessage data in a temporary buffer, then copy it exactly
* once into the output buffer.
*
* 2. attempt to buffer data directly into the output buffer, estimating how
* many bytes each length will take. When our guesses are wrong, use
* memmove() to grow or shrink the allotted space.
*
* 3. buffer directly into the output buffer, allocating a max length
* ahead-of-time for each submessage length. If we overallocated, we waste
* space, but no memcpy() or memmove() is required. This approach requires
* defining a maximum size for submessages and rejecting submessages that
* exceed that size.
*
* (2) and (3) have the potential to have better performance, but they are more
* complicated and subtle to implement:
*
* (3) requires making an arbitrary choice of the maximum message size; it
* wastes space when submessages are shorter than this and fails
* completely when they are longer. This makes it more finicky and
* requires configuration based on the input. It also makes it impossible
* to perfectly match the output of reference encoders that always use the
* optimal amount of space for each length.
*
* (2) requires guessing the the size upfront, and if multiple lengths are
* guessed wrong the minimum required number of memmove() operations may
* be complicated to compute correctly. Implemented properly, it may have
* a useful amortized or average cost, but more investigation is required
* to determine this and what the optimal algorithm is to achieve it.
*
* (1) makes you always pay for exactly one copy, but its implementation is
* the simplest and its performance is predictable.
*
* So for now, we implement (1) only. If we wish to optimize later, we should
* be able to do it without affecting users.
*
* The strategy is to buffer the segments of data that do *not* depend on
* unknown lengths in one buffer, and keep a separate buffer of segment pointers
* and lengths. When the top-level submessage ends, we can go beginning to end,
* alternating the writing of lengths with memcpy() of the rest of the data.
* At the top level though, no buffering is required.
*/
#include <stdlib.h>
/* low-level buffering ********************************************************/
// Low-level functions for interacting with the output buffer.
// TODO(haberman): handle pushback
static void putbuf(upb_pb_encoder *e, const char *buf, size_t len) {
size_t n = upb_bytessink_putbuf(e->output_, e->subc, buf, len, NULL);
UPB_ASSERT_VAR(n, n == len);
}
static upb_pb_encoder_segment *top(upb_pb_encoder *e) {
return &e->segbuf[*e->top];
}
// Call to ensure that at least "bytes" bytes are available for writing at
// e->ptr. Returns false if the bytes could not be allocated.
static bool reserve(upb_pb_encoder *e, size_t bytes) {
if ((e->limit - e->ptr) < bytes) {
size_t needed = bytes + (e->ptr - e->buf);
size_t old_size = e->limit - e->buf;
size_t new_size = old_size;
while (new_size < needed) {
new_size *= 2;
}
char *realloc_from = (e->buf == e->initbuf) ? NULL : e->buf;
char *new_buf = realloc(realloc_from, new_size);
if (new_buf == NULL) {
return false;
}
if (realloc_from == NULL) {
memcpy(new_buf, e->initbuf, old_size);
}
e->ptr = new_buf + (e->ptr - e->buf);
e->runbegin = new_buf + (e->runbegin - e->buf);
e->limit = new_buf + new_size;
e->buf = new_buf;
}
return true;
}
// Call when "bytes" bytes have been writte at e->ptr. The caller *must* have
// previously called reserve() with at least this many bytes.
static void encoder_advance(upb_pb_encoder *e, size_t bytes) {
assert((e->limit - e->ptr) >= bytes);
e->ptr += bytes;
}
// Call when all of the bytes for a handler have been written. Flushes the
// bytes if possible and necessary, returning false if this failed.
static bool commit(upb_pb_encoder *e) {
if (!e->top) {
// We aren't inside a delimited region. Flush our accumulated bytes to
// the output.
//
// TODO(haberman): in the future we may want to delay flushing for
// efficiency reasons.
putbuf(e, e->buf, e->ptr - e->buf);
e->ptr = e->buf;
}
return true;
}
// Writes the given bytes to the buffer, handling reserve/advance.
static bool encode_bytes(upb_pb_encoder *e, const void *data, size_t len) {
if (!reserve(e, len)) {
return false;
}
memcpy(e->ptr, data, len);
encoder_advance(e, len);
return true;
}
// Finish the current run by adding the run totals to the segment and message
// length.
static void accumulate(upb_pb_encoder *e) {
assert(e->ptr >= e->runbegin);
size_t run_len = e->ptr - e->runbegin;
e->segptr->seglen += run_len;
top(e)->msglen += run_len;
e->runbegin = e->ptr;
}
// Call to indicate the start of delimited region for which the full length is
// not yet known. All data will be buffered until the length is known.
// Delimited regions may be nested; their lengths will all be tracked properly.
static bool start_delim(upb_pb_encoder *e) {
if (e->top) {
// We are already buffering, advance to the next segment and push it on the
// stack.
accumulate(e);
if (++e->top == e->stacklimit) {
// TODO(haberman): grow stack?
return false;
}
if (++e->segptr == e->seglimit) {
upb_pb_encoder_segment *realloc_from =
(e->segbuf == e->seginitbuf) ? NULL : e->segbuf;
size_t old_size =
(e->seglimit - e->segbuf) * sizeof(upb_pb_encoder_segment);
size_t new_size = old_size * 2;
upb_pb_encoder_segment *new_buf = realloc(realloc_from, new_size);
if (new_buf == NULL) {
return false;
}
if (realloc_from == NULL) {
memcpy(new_buf, e->seginitbuf, old_size);
}
e->segptr = new_buf + (e->segptr - e->segbuf);
e->seglimit = new_buf + (new_size / sizeof(upb_pb_encoder_segment));
e->segbuf = new_buf;
}
} else {
// We were previously at the top level, start buffering.
e->segptr = e->segbuf;
e->top = e->stack;
e->runbegin = e->ptr;
}
*e->top = e->segptr - e->segbuf;
e->segptr->seglen = 0;
e->segptr->msglen = 0;
return true;
}
// Call to indicate the end of a delimited region. We now know the length of
// the delimited region. If we are not nested inside any other delimited
// regions, we can now emit all of the buffered data we accumulated.
static bool end_delim(upb_pb_encoder *e) {
accumulate(e);
size_t msglen = top(e)->msglen;
if (e->top == e->stack) {
// All lengths are now available, emit all buffered data.
char buf[UPB_PB_VARINT_MAX_LEN];
upb_pb_encoder_segment *s;
const char *ptr = e->buf;
for (s = e->segbuf; s <= e->segptr; s++) {
size_t lenbytes = upb_vencode64(s->msglen, buf);
putbuf(e, buf, lenbytes);
putbuf(e, ptr, s->seglen);
ptr += s->seglen;
}
e->ptr = e->buf;
e->top = NULL;
} else {
// Need to keep buffering; propagate length info into enclosing submessages.
--e->top;
top(e)->msglen += msglen + upb_varint_size(msglen);
}
return true;
}
/* tag_t **********************************************************************/
// A precomputed (pre-encoded) tag and length.
typedef struct {
uint8_t bytes;
char tag[7];
} tag_t;
// Allocates a new tag for this field, and sets it in these handlerattr.
static void new_tag(upb_handlers *h, const upb_fielddef *f, upb_wiretype_t wt,
upb_handlerattr *attr) {
uint32_t n = upb_fielddef_number(f);
tag_t *tag = malloc(sizeof(tag_t));
tag->bytes = upb_vencode64((n << 3) | wt, tag->tag);
upb_handlerattr_init(attr);
upb_handlerattr_sethandlerdata(attr, tag);
upb_handlers_addcleanup(h, tag, free);
}
static bool encode_tag(upb_pb_encoder *e, const tag_t *tag) {
return encode_bytes(e, tag->tag, tag->bytes);
}
/* encoding of wire types *****************************************************/
static bool encode_fixed64(upb_pb_encoder *e, uint64_t val) {
// TODO(haberman): byte-swap for big endian.
return encode_bytes(e, &val, sizeof(uint64_t));
}
static bool encode_fixed32(upb_pb_encoder *e, uint32_t val) {
// TODO(haberman): byte-swap for big endian.
return encode_bytes(e, &val, sizeof(uint32_t));
}
static bool encode_varint(upb_pb_encoder *e, uint64_t val) {
if (!reserve(e, UPB_PB_VARINT_MAX_LEN)) {
return false;
}
encoder_advance(e, upb_vencode64(val, e->ptr));
return true;
}
static uint64_t dbl2uint64(double d) {
uint64_t ret;
memcpy(&ret, &d, sizeof(uint64_t));
return ret;
}
static uint32_t flt2uint32(float d) {
uint32_t ret;
memcpy(&ret, &d, sizeof(uint32_t));
return ret;
}
/* encoding of proto types ****************************************************/
static bool startmsg(void *c, const void *hd) {
upb_pb_encoder *e = c;
UPB_UNUSED(hd);
if (e->depth++ == 0) {
upb_bytessink_start(e->output_, 0, &e->subc);
}
return true;
}
static bool endmsg(void *c, const void *hd, upb_status *status) {
upb_pb_encoder *e = c;
UPB_UNUSED(hd);
UPB_UNUSED(status);
if (--e->depth == 0) {
upb_bytessink_end(e->output_);
}
return true;
}
static void *encode_startdelimfield(void *c, const void *hd) {
bool ok = encode_tag(c, hd) && commit(c) && start_delim(c);
return ok ? c : UPB_BREAK;
}
static bool encode_enddelimfield(void *c, const void *hd) {
UPB_UNUSED(hd);
return end_delim(c);
}
static void *encode_startgroup(void *c, const void *hd) {
return (encode_tag(c, hd) && commit(c)) ? c : UPB_BREAK;
}
static bool encode_endgroup(void *c, const void *hd) {
return encode_tag(c, hd) && commit(c);
}
static void *encode_startstr(void *c, const void *hd, size_t size_hint) {
UPB_UNUSED(size_hint);
return encode_startdelimfield(c, hd);
}
static size_t encode_strbuf(void *c, const void *hd, const char *buf,
size_t len, const upb_bufhandle *h) {
UPB_UNUSED(hd);
UPB_UNUSED(h);
return encode_bytes(c, buf, len) ? len : 0;
}
#define T(type, ctype, convert, encode) \
static bool encode_scalar_##type(void *e, const void *hd, ctype val) { \
return encode_tag(e, hd) && encode(e, (convert)(val)) && commit(e); \
} \
static bool encode_packed_##type(void *e, const void *hd, ctype val) { \
UPB_UNUSED(hd); \
return encode(e, (convert)(val)); \
}
T(double, double, dbl2uint64, encode_fixed64)
T(float, float, flt2uint32, encode_fixed32);
T(int64, int64_t, uint64_t, encode_varint);
T(int32, int32_t, uint32_t, encode_varint);
T(fixed64, uint64_t, uint64_t, encode_fixed64);
T(fixed32, uint32_t, uint32_t, encode_fixed32);
T(bool, bool, bool, encode_varint);
T(uint32, uint32_t, uint32_t, encode_varint);
T(uint64, uint64_t, uint64_t, encode_varint);
T(enum, int32_t, uint32_t, encode_varint);
T(sfixed32, int32_t, uint32_t, encode_fixed32);
T(sfixed64, int64_t, uint64_t, encode_fixed64);
T(sint32, int32_t, upb_zzenc_32, encode_varint);
T(sint64, int64_t, upb_zzenc_64, encode_varint);
#undef T
/* code to build the handlers *************************************************/
static void newhandlers_callback(const void *closure, upb_handlers *h) {
UPB_UNUSED(closure);
upb_handlers_setstartmsg(h, startmsg, NULL);
upb_handlers_setendmsg(h, endmsg, NULL);
const upb_msgdef *m = upb_handlers_msgdef(h);
Support oneofs in MRI Ruby C extension.
10 years ago
upb_msg_field_iter i;
for(upb_msg_field_begin(&i, m);
!upb_msg_field_done(&i);
upb_msg_field_next(&i)) {
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
const upb_fielddef *f = upb_msg_iter_field(&i);
bool packed = upb_fielddef_isseq(f) && upb_fielddef_isprimitive(f) &&
upb_fielddef_packed(f);
upb_handlerattr attr;
upb_wiretype_t wt =
packed ? UPB_WIRE_TYPE_DELIMITED
: upb_pb_native_wire_types[upb_fielddef_descriptortype(f)];
// Pre-encode the tag for this field.
new_tag(h, f, wt, &attr);
if (packed) {
upb_handlers_setstartseq(h, f, encode_startdelimfield, &attr);
upb_handlers_setendseq(h, f, encode_enddelimfield, &attr);
}
#define T(upper, lower, upbtype) \
case UPB_DESCRIPTOR_TYPE_##upper: \
if (packed) { \
upb_handlers_set##upbtype(h, f, encode_packed_##lower, &attr); \
} else { \
upb_handlers_set##upbtype(h, f, encode_scalar_##lower, &attr); \
} \
break;
switch (upb_fielddef_descriptortype(f)) {
T(DOUBLE, double, double);
T(FLOAT, float, float);
T(INT64, int64, int64);
T(INT32, int32, int32);
T(FIXED64, fixed64, uint64);
T(FIXED32, fixed32, uint32);
T(BOOL, bool, bool);
T(UINT32, uint32, uint32);
T(UINT64, uint64, uint64);
T(ENUM, enum, int32);
T(SFIXED32, sfixed32, int32);
T(SFIXED64, sfixed64, int64);
T(SINT32, sint32, int32);
T(SINT64, sint64, int64);
case UPB_DESCRIPTOR_TYPE_STRING:
case UPB_DESCRIPTOR_TYPE_BYTES:
upb_handlers_setstartstr(h, f, encode_startstr, &attr);
upb_handlers_setendstr(h, f, encode_enddelimfield, &attr);
upb_handlers_setstring(h, f, encode_strbuf, &attr);
break;
case UPB_DESCRIPTOR_TYPE_MESSAGE:
upb_handlers_setstartsubmsg(h, f, encode_startdelimfield, &attr);
upb_handlers_setendsubmsg(h, f, encode_enddelimfield, &attr);
break;
case UPB_DESCRIPTOR_TYPE_GROUP: {
// Endgroup takes a different tag (wire_type = END_GROUP).
upb_handlerattr attr2;
new_tag(h, f, UPB_WIRE_TYPE_END_GROUP, &attr2);
upb_handlers_setstartsubmsg(h, f, encode_startgroup, &attr);
upb_handlers_setendsubmsg(h, f, encode_endgroup, &attr2);
upb_handlerattr_uninit(&attr2);
break;
}
}
#undef T
upb_handlerattr_uninit(&attr);
}
}
/* public API *****************************************************************/
const upb_handlers *upb_pb_encoder_newhandlers(const upb_msgdef *m,
const void *owner) {
return upb_handlers_newfrozen(m, owner, newhandlers_callback, NULL);
}
#define ARRAYSIZE(x) (sizeof(x) / sizeof(x[0]))
void upb_pb_encoder_init(upb_pb_encoder *e, const upb_handlers *h) {
e->output_ = NULL;
e->subc = NULL;
e->buf = e->initbuf;
e->ptr = e->buf;
e->limit = e->buf + ARRAYSIZE(e->initbuf);
e->segbuf = e->seginitbuf;
e->seglimit = e->segbuf + ARRAYSIZE(e->seginitbuf);
e->stacklimit = e->stack + ARRAYSIZE(e->stack);
upb_sink_reset(&e->input_, h, e);
}
void upb_pb_encoder_uninit(upb_pb_encoder *e) {
if (e->buf != e->initbuf) {
free(e->buf);
}
if (e->segbuf != e->seginitbuf) {
free(e->segbuf);
}
}
void upb_pb_encoder_resetoutput(upb_pb_encoder *e, upb_bytessink *output) {
upb_pb_encoder_reset(e);
e->output_ = output;
e->subc = output->closure;
}
void upb_pb_encoder_reset(upb_pb_encoder *e) {
e->segptr = NULL;
e->top = NULL;
e->depth = 0;
}
upb_sink *upb_pb_encoder_input(upb_pb_encoder *e) { return &e->input_; }
/*
* upb - a minimalist implementation of protocol buffers.
*
* Copyright (c) 2010-2012 Google Inc. See LICENSE for details.
* Author: Josh Haberman <jhaberman@gmail.com>
*/
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
upb_def **upb_load_defs_from_descriptor(const char *str, size_t len, int *n,
void *owner, upb_status *status) {
// Create handlers.
const upb_handlers *reader_h = upb_descreader_newhandlers(&reader_h);
upb_pbdecodermethodopts opts;
upb_pbdecodermethodopts_init(&opts, reader_h);
const upb_pbdecodermethod *decoder_m =
upb_pbdecodermethod_new(&opts, &decoder_m);
upb_pbdecoder decoder;
upb_descreader reader;
upb_pbdecoder_init(&decoder, decoder_m, status);
upb_descreader_init(&reader, reader_h, status);
upb_pbdecoder_resetoutput(&decoder, upb_descreader_input(&reader));
// Push input data.
bool ok = upb_bufsrc_putbuf(str, len, upb_pbdecoder_input(&decoder));
upb_def **ret = NULL;
if (!ok) goto cleanup;
upb_def **defs = upb_descreader_getdefs(&reader, owner, n);
ret = malloc(sizeof(upb_def*) * (*n));
memcpy(ret, defs, sizeof(upb_def*) * (*n));
cleanup:
upb_pbdecoder_uninit(&decoder);
upb_descreader_uninit(&reader);
upb_handlers_unref(reader_h, &reader_h);
upb_pbdecodermethod_unref(decoder_m, &decoder_m);
return ret;
}
bool upb_load_descriptor_into_symtab(upb_symtab *s, const char *str, size_t len,
upb_status *status) {
int n;
upb_def **defs = upb_load_defs_from_descriptor(str, len, &n, &defs, status);
if (!defs) return false;
bool success = upb_symtab_add(s, defs, n, &defs, status);
free(defs);
return success;
}
char *upb_readfile(const char *filename, size_t *len) {
FILE *f = fopen(filename, "rb");
if(!f) return NULL;
if(fseek(f, 0, SEEK_END) != 0) goto error;
long size = ftell(f);
if(size < 0) goto error;
if(fseek(f, 0, SEEK_SET) != 0) goto error;
char *buf = malloc(size + 1);
if(size && fread(buf, size, 1, f) != 1) goto error;
fclose(f);
if (len) *len = size;
return buf;
error:
fclose(f);
return NULL;
}
bool upb_load_descriptor_file_into_symtab(upb_symtab *symtab, const char *fname,
upb_status *status) {
size_t len;
char *data = upb_readfile(fname, &len);
if (!data) {
if (status) upb_status_seterrf(status, "Couldn't read file: %s", fname);
return false;
}
bool success = upb_load_descriptor_into_symtab(symtab, data, len, status);
free(data);
return success;
}
/*
* upb - a minimalist implementation of protocol buffers.
*
* Copyright (c) 2009 Google Inc. See LICENSE for details.
* Author: Josh Haberman <jhaberman@gmail.com>
*
* OPT: This is not optimized at all. It uses printf() which parses the format
* string every time, and it allocates memory for every put.
*/
#include <ctype.h>
#include <float.h>
#include <inttypes.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#define CHECK(x) if ((x) < 0) goto err;
static const char *shortname(const char *longname) {
const char *last = strrchr(longname, '.');
return last ? last + 1 : longname;
}
static int indent(upb_textprinter *p) {
int i;
if (!p->single_line_)
for (i = 0; i < p->indent_depth_; i++)
upb_bytessink_putbuf(p->output_, p->subc, " ", 2, NULL);
return 0;
}
static int endfield(upb_textprinter *p) {
const char ch = (p->single_line_ ? ' ' : '\n');
upb_bytessink_putbuf(p->output_, p->subc, &ch, 1, NULL);
return 0;
}
static int putescaped(upb_textprinter *p, const char *buf, size_t len,
bool preserve_utf8) {
// Based on CEscapeInternal() from Google's protobuf release.
char dstbuf[4096], *dst = dstbuf, *dstend = dstbuf + sizeof(dstbuf);
const char *end = buf + len;
// I think hex is prettier and more useful, but proto2 uses octal; should
// investigate whether it can parse hex also.
const bool use_hex = false;
bool last_hex_escape = false; // true if last output char was \xNN
for (; buf < end; buf++) {
if (dstend - dst < 4) {
upb_bytessink_putbuf(p->output_, p->subc, dstbuf, dst - dstbuf, NULL);
dst = dstbuf;
}
bool is_hex_escape = false;
switch (*buf) {
case '\n': *(dst++) = '\\'; *(dst++) = 'n'; break;
case '\r': *(dst++) = '\\'; *(dst++) = 'r'; break;
case '\t': *(dst++) = '\\'; *(dst++) = 't'; break;
case '\"': *(dst++) = '\\'; *(dst++) = '\"'; break;
case '\'': *(dst++) = '\\'; *(dst++) = '\''; break;
case '\\': *(dst++) = '\\'; *(dst++) = '\\'; break;
default:
// Note that if we emit \xNN and the buf character after that is a hex
// digit then that digit must be escaped too to prevent it being
// interpreted as part of the character code by C.
if ((!preserve_utf8 || (uint8_t)*buf < 0x80) &&
(!isprint(*buf) || (last_hex_escape && isxdigit(*buf)))) {
sprintf(dst, (use_hex ? "\\x%02x" : "\\%03o"), (uint8_t)*buf);
is_hex_escape = use_hex;
dst += 4;
} else {
*(dst++) = *buf; break;
}
}
last_hex_escape = is_hex_escape;
}
// Flush remaining data.
upb_bytessink_putbuf(p->output_, p->subc, dstbuf, dst - dstbuf, NULL);
return 0;
}
bool putf(upb_textprinter *p, const char *fmt, ...) {
va_list args;
va_start(args, fmt);
// Run once to get the length of the string.
va_list args_copy;
va_copy(args_copy, args);
int len = vsnprintf(NULL, 0, fmt, args_copy);
va_end(args_copy);
// + 1 for NULL terminator (vsnprintf() requires it even if we don't).
char *str = malloc(len + 1);
if (!str) return false;
int written = vsnprintf(str, len + 1, fmt, args);
va_end(args);
UPB_ASSERT_VAR(written, written == len);
bool ok = upb_bytessink_putbuf(p->output_, p->subc, str, len, NULL);
free(str);
return ok;
}
/* handlers *******************************************************************/
static bool textprinter_startmsg(void *c, const void *hd) {
UPB_UNUSED(hd);
upb_textprinter *p = c;
if (p->indent_depth_ == 0) {
upb_bytessink_start(p->output_, 0, &p->subc);
}
return true;
}
static bool textprinter_endmsg(void *c, const void *hd, upb_status *s) {
UPB_UNUSED(hd);
UPB_UNUSED(s);
upb_textprinter *p = c;
if (p->indent_depth_ == 0) {
upb_bytessink_end(p->output_);
}
return true;
}
#define TYPE(name, ctype, fmt) \
static bool textprinter_put ## name(void *closure, const void *handler_data, \
ctype val) { \
upb_textprinter *p = closure; \
const upb_fielddef *f = handler_data; \
CHECK(indent(p)); \
putf(p, "%s: " fmt, upb_fielddef_name(f), val); \
CHECK(endfield(p)); \
return true; \
err: \
return false; \
}
static bool textprinter_putbool(void *closure, const void *handler_data,
bool val) {
upb_textprinter *p = closure;
const upb_fielddef *f = handler_data;
CHECK(indent(p));
putf(p, "%s: %s", upb_fielddef_name(f), val ? "true" : "false");
CHECK(endfield(p));
return true;
err:
return false;
}
#define STRINGIFY_HELPER(x) #x
#define STRINGIFY_MACROVAL(x) STRINGIFY_HELPER(x)
TYPE(int32, int32_t, "%" PRId32)
TYPE(int64, int64_t, "%" PRId64)
TYPE(uint32, uint32_t, "%" PRIu32);
TYPE(uint64, uint64_t, "%" PRIu64)
TYPE(float, float, "%." STRINGIFY_MACROVAL(FLT_DIG) "g")
TYPE(double, double, "%." STRINGIFY_MACROVAL(DBL_DIG) "g")
#undef TYPE
// Output a symbolic value from the enum if found, else just print as int32.
static bool textprinter_putenum(void *closure, const void *handler_data,
int32_t val) {
upb_textprinter *p = closure;
const upb_fielddef *f = handler_data;
const upb_enumdef *enum_def = upb_downcast_enumdef(upb_fielddef_subdef(f));
const char *label = upb_enumdef_iton(enum_def, val);
if (label) {
indent(p);
putf(p, "%s: %s", upb_fielddef_name(f), label);
endfield(p);
} else {
if (!textprinter_putint32(closure, handler_data, val))
return false;
}
return true;
}
static void *textprinter_startstr(void *closure, const void *handler_data,
size_t size_hint) {
const upb_fielddef *f = handler_data;
UPB_UNUSED(size_hint);
upb_textprinter *p = closure;
indent(p);
putf(p, "%s: \"", upb_fielddef_name(f));
return p;
}
static bool textprinter_endstr(void *closure, const void *handler_data) {
UPB_UNUSED(handler_data);
upb_textprinter *p = closure;
putf(p, "\"");
endfield(p);
return true;
}
static size_t textprinter_putstr(void *closure, const void *hd, const char *buf,
size_t len, const upb_bufhandle *handle) {
UPB_UNUSED(handle);
upb_textprinter *p = closure;
const upb_fielddef *f = hd;
CHECK(putescaped(p, buf, len, upb_fielddef_type(f) == UPB_TYPE_STRING));
return len;
err:
return 0;
}
static void *textprinter_startsubmsg(void *closure, const void *handler_data) {
upb_textprinter *p = closure;
const char *name = handler_data;
CHECK(indent(p));
putf(p, "%s {%c", name, p->single_line_ ? ' ' : '\n');
p->indent_depth_++;
return p;
err:
return UPB_BREAK;
}
static bool textprinter_endsubmsg(void *closure, const void *handler_data) {
UPB_UNUSED(handler_data);
upb_textprinter *p = closure;
p->indent_depth_--;
CHECK(indent(p));
upb_bytessink_putbuf(p->output_, p->subc, "}", 1, NULL);
CHECK(endfield(p));
return true;
err:
return false;
}
/* Public API *****************************************************************/
void upb_textprinter_init(upb_textprinter *p, const upb_handlers *h) {
p->single_line_ = false;
p->indent_depth_ = 0;
upb_sink_reset(&p->input_, h, p);
}
void upb_textprinter_uninit(upb_textprinter *p) {
UPB_UNUSED(p);
}
void upb_textprinter_reset(upb_textprinter *p, bool single_line) {
p->single_line_ = single_line;
p->indent_depth_ = 0;
}
static void onmreg(const void *c, upb_handlers *h) {
UPB_UNUSED(c);
const upb_msgdef *m = upb_handlers_msgdef(h);
upb_handlers_setstartmsg(h, textprinter_startmsg, NULL);
upb_handlers_setendmsg(h, textprinter_endmsg, NULL);
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upb_msg_field_iter i;
for(upb_msg_field_begin(&i, m);
!upb_msg_field_done(&i);
upb_msg_field_next(&i)) {
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upb_fielddef *f = upb_msg_iter_field(&i);
upb_handlerattr attr = UPB_HANDLERATTR_INITIALIZER;
upb_handlerattr_sethandlerdata(&attr, f);
switch (upb_fielddef_type(f)) {
case UPB_TYPE_INT32:
upb_handlers_setint32(h, f, textprinter_putint32, &attr);
break;
case UPB_TYPE_INT64:
upb_handlers_setint64(h, f, textprinter_putint64, &attr);
break;
case UPB_TYPE_UINT32:
upb_handlers_setuint32(h, f, textprinter_putuint32, &attr);
break;
case UPB_TYPE_UINT64:
upb_handlers_setuint64(h, f, textprinter_putuint64, &attr);
break;
case UPB_TYPE_FLOAT:
upb_handlers_setfloat(h, f, textprinter_putfloat, &attr);
break;
case UPB_TYPE_DOUBLE:
upb_handlers_setdouble(h, f, textprinter_putdouble, &attr);
break;
case UPB_TYPE_BOOL:
upb_handlers_setbool(h, f, textprinter_putbool, &attr);
break;
case UPB_TYPE_STRING:
case UPB_TYPE_BYTES:
upb_handlers_setstartstr(h, f, textprinter_startstr, &attr);
upb_handlers_setstring(h, f, textprinter_putstr, &attr);
upb_handlers_setendstr(h, f, textprinter_endstr, &attr);
break;
case UPB_TYPE_MESSAGE: {
const char *name =
upb_fielddef_istagdelim(f)
? shortname(upb_msgdef_fullname(upb_fielddef_msgsubdef(f)))
: upb_fielddef_name(f);
upb_handlerattr_sethandlerdata(&attr, name);
upb_handlers_setstartsubmsg(h, f, textprinter_startsubmsg, &attr);
upb_handlers_setendsubmsg(h, f, textprinter_endsubmsg, &attr);
break;
}
case UPB_TYPE_ENUM:
upb_handlers_setint32(h, f, textprinter_putenum, &attr);
break;
}
}
}
const upb_handlers *upb_textprinter_newhandlers(const upb_msgdef *m,
const void *owner) {
return upb_handlers_newfrozen(m, owner, &onmreg, NULL);
}
upb_sink *upb_textprinter_input(upb_textprinter *p) { return &p->input_; }
bool upb_textprinter_resetoutput(upb_textprinter *p, upb_bytessink *output) {
p->output_ = output;
return true;
}
void upb_textprinter_setsingleline(upb_textprinter *p, bool single_line) {
p->single_line_ = single_line;
}
/*
* upb - a minimalist implementation of protocol buffers.
*
* Copyright (c) 2011 Google Inc. See LICENSE for details.
* Author: Josh Haberman <jhaberman@gmail.com>
*/
// Index is descriptor type.
const uint8_t upb_pb_native_wire_types[] = {
UPB_WIRE_TYPE_END_GROUP, // ENDGROUP
UPB_WIRE_TYPE_64BIT, // DOUBLE
UPB_WIRE_TYPE_32BIT, // FLOAT
UPB_WIRE_TYPE_VARINT, // INT64
UPB_WIRE_TYPE_VARINT, // UINT64
UPB_WIRE_TYPE_VARINT, // INT32
UPB_WIRE_TYPE_64BIT, // FIXED64
UPB_WIRE_TYPE_32BIT, // FIXED32
UPB_WIRE_TYPE_VARINT, // BOOL
UPB_WIRE_TYPE_DELIMITED, // STRING
UPB_WIRE_TYPE_START_GROUP, // GROUP
UPB_WIRE_TYPE_DELIMITED, // MESSAGE
UPB_WIRE_TYPE_DELIMITED, // BYTES
UPB_WIRE_TYPE_VARINT, // UINT32
UPB_WIRE_TYPE_VARINT, // ENUM
UPB_WIRE_TYPE_32BIT, // SFIXED32
UPB_WIRE_TYPE_64BIT, // SFIXED64
UPB_WIRE_TYPE_VARINT, // SINT32
UPB_WIRE_TYPE_VARINT, // SINT64
};
// A basic branch-based decoder, uses 32-bit values to get good performance
// on 32-bit architectures (but performs well on 64-bits also).
// This scheme comes from the original Google Protobuf implementation (proto2).
upb_decoderet upb_vdecode_max8_branch32(upb_decoderet r) {
upb_decoderet err = {NULL, 0};
const char *p = r.p;
uint32_t low = (uint32_t)r.val;
uint32_t high = 0;
uint32_t b;
b = *(p++); low |= (b & 0x7fU) << 14; if (!(b & 0x80)) goto done;
b = *(p++); low |= (b & 0x7fU) << 21; if (!(b & 0x80)) goto done;
b = *(p++); low |= (b & 0x7fU) << 28;
high = (b & 0x7fU) >> 4; if (!(b & 0x80)) goto done;
b = *(p++); high |= (b & 0x7fU) << 3; if (!(b & 0x80)) goto done;
b = *(p++); high |= (b & 0x7fU) << 10; if (!(b & 0x80)) goto done;
b = *(p++); high |= (b & 0x7fU) << 17; if (!(b & 0x80)) goto done;
b = *(p++); high |= (b & 0x7fU) << 24; if (!(b & 0x80)) goto done;
b = *(p++); high |= (b & 0x7fU) << 31; if (!(b & 0x80)) goto done;
return err;
done:
r.val = ((uint64_t)high << 32) | low;
r.p = p;
return r;
}
// Like the previous, but uses 64-bit values.
upb_decoderet upb_vdecode_max8_branch64(upb_decoderet r) {
const char *p = r.p;
uint64_t val = r.val;
uint64_t b;
upb_decoderet err = {NULL, 0};
b = *(p++); val |= (b & 0x7fU) << 14; if (!(b & 0x80)) goto done;
b = *(p++); val |= (b & 0x7fU) << 21; if (!(b & 0x80)) goto done;
b = *(p++); val |= (b & 0x7fU) << 28; if (!(b & 0x80)) goto done;
b = *(p++); val |= (b & 0x7fU) << 35; if (!(b & 0x80)) goto done;
b = *(p++); val |= (b & 0x7fU) << 42; if (!(b & 0x80)) goto done;
b = *(p++); val |= (b & 0x7fU) << 49; if (!(b & 0x80)) goto done;
b = *(p++); val |= (b & 0x7fU) << 56; if (!(b & 0x80)) goto done;
b = *(p++); val |= (b & 0x7fU) << 63; if (!(b & 0x80)) goto done;
return err;
done:
r.val = val;
r.p = p;
return r;
}
// Given an encoded varint v, returns an integer with a single bit set that
// indicates the end of the varint. Subtracting one from this value will
// yield a mask that leaves only bits that are part of the varint. Returns
// 0 if the varint is unterminated.
static uint64_t upb_get_vstopbit(uint64_t v) {
uint64_t cbits = v | 0x7f7f7f7f7f7f7f7fULL;
return ~cbits & (cbits+1);
}
// A branchless decoder. Credit to Pascal Massimino for the bit-twiddling.
upb_decoderet upb_vdecode_max8_massimino(upb_decoderet r) {
uint64_t b;
memcpy(&b, r.p, sizeof(b));
uint64_t stop_bit = upb_get_vstopbit(b);
b = (b & 0x7f7f7f7f7f7f7f7fULL) & (stop_bit - 1);
b += b & 0x007f007f007f007fULL;
b += 3 * (b & 0x0000ffff0000ffffULL);
b += 15 * (b & 0x00000000ffffffffULL);
if (stop_bit == 0) {
// Error: unterminated varint.
upb_decoderet err_r = {(void*)0, 0};
return err_r;
}
upb_decoderet my_r = {r.p + ((__builtin_ctzll(stop_bit) + 1) / 8),
r.val | (b << 7)};
return my_r;
}
// A branchless decoder. Credit to Daniel Wright for the bit-twiddling.
upb_decoderet upb_vdecode_max8_wright(upb_decoderet r) {
uint64_t b;
memcpy(&b, r.p, sizeof(b));
uint64_t stop_bit = upb_get_vstopbit(b);
b &= (stop_bit - 1);
b = ((b & 0x7f007f007f007f00ULL) >> 1) | (b & 0x007f007f007f007fULL);
b = ((b & 0xffff0000ffff0000ULL) >> 2) | (b & 0x0000ffff0000ffffULL);
b = ((b & 0xffffffff00000000ULL) >> 4) | (b & 0x00000000ffffffffULL);
if (stop_bit == 0) {
// Error: unterminated varint.
upb_decoderet err_r = {(void*)0, 0};
return err_r;
}
upb_decoderet my_r = {r.p + ((__builtin_ctzll(stop_bit) + 1) / 8),
r.val | (b << 14)};
return my_r;
}
#line 1 "upb/json/parser.rl"
/*
* upb - a minimalist implementation of protocol buffers.
*
* Copyright (c) 2014 Google Inc. See LICENSE for details.
* Author: Josh Haberman <jhaberman@gmail.com>
*
* A parser that uses the Ragel State Machine Compiler to generate
* the finite automata.
*
* Ragel only natively handles regular languages, but we can manually
* program it a bit to handle context-free languages like JSON, by using
* the "fcall" and "fret" constructs.
*
* This parser can handle the basics, but needs several things to be fleshed
* out:
*
* - handling of unicode escape sequences (including high surrogate pairs).
* - properly check and report errors for unknown fields, stack overflow,
* improper array nesting (or lack of nesting).
* - handling of base64 sequences with padding characters.
* - handling of push-back (non-success returns from sink functions).
* - handling of keys/escape-sequences/etc that span input buffers.
*/
#include <stdio.h>
#include <stdint.h>
#include <assert.h>
#include <string.h>
#include <stdlib.h>
#include <errno.h>
#define PARSER_CHECK_RETURN(x) if (!(x)) return false
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// Used to signal that a capture has been suspended.
static char suspend_capture;
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static upb_selector_t getsel_for_handlertype(upb_json_parser *p,
upb_handlertype_t type) {
upb_selector_t sel;
bool ok = upb_handlers_getselector(p->top->f, type, &sel);
UPB_ASSERT_VAR(ok, ok);
return sel;
}
static upb_selector_t parser_getsel(upb_json_parser *p) {
return getsel_for_handlertype(
p, upb_handlers_getprimitivehandlertype(p->top->f));
}
static bool check_stack(upb_json_parser *p) {
if ((p->top + 1) == p->limit) {
upb_status_seterrmsg(p->status, "Nesting too deep");
return false;
}
return true;
}
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// There are GCC/Clang built-ins for overflow checking which we could start
// using if there was any performance benefit to it.
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static bool checked_add(size_t a, size_t b, size_t *c) {
if (SIZE_MAX - a < b) return false;
*c = a + b;
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return true;
}
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static size_t saturating_multiply(size_t a, size_t b) {
// size_t is unsigned, so this is defined behavior even on overflow.
size_t ret = a * b;
if (b != 0 && ret / b != a) {
ret = SIZE_MAX;
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}
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return ret;
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}
Update upb amalgamation.
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/* Base64 decoding ************************************************************/
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
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// TODO(haberman): make this streaming.
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static const signed char b64table[] = {
-1, -1, -1, -1, -1, -1, -1, -1,
-1, -1, -1, -1, -1, -1, -1, -1,
-1, -1, -1, -1, -1, -1, -1, -1,
-1, -1, -1, -1, -1, -1, -1, -1,
-1, -1, -1, -1, -1, -1, -1, -1,
-1, -1, -1, 62/*+*/, -1, -1, -1, 63/*/ */,
52/*0*/, 53/*1*/, 54/*2*/, 55/*3*/, 56/*4*/, 57/*5*/, 58/*6*/, 59/*7*/,
60/*8*/, 61/*9*/, -1, -1, -1, -1, -1, -1,
-1, 0/*A*/, 1/*B*/, 2/*C*/, 3/*D*/, 4/*E*/, 5/*F*/, 6/*G*/,
07/*H*/, 8/*I*/, 9/*J*/, 10/*K*/, 11/*L*/, 12/*M*/, 13/*N*/, 14/*O*/,
15/*P*/, 16/*Q*/, 17/*R*/, 18/*S*/, 19/*T*/, 20/*U*/, 21/*V*/, 22/*W*/,
23/*X*/, 24/*Y*/, 25/*Z*/, -1, -1, -1, -1, -1,
-1, 26/*a*/, 27/*b*/, 28/*c*/, 29/*d*/, 30/*e*/, 31/*f*/, 32/*g*/,
33/*h*/, 34/*i*/, 35/*j*/, 36/*k*/, 37/*l*/, 38/*m*/, 39/*n*/, 40/*o*/,
41/*p*/, 42/*q*/, 43/*r*/, 44/*s*/, 45/*t*/, 46/*u*/, 47/*v*/, 48/*w*/,
49/*x*/, 50/*y*/, 51/*z*/, -1, -1, -1, -1, -1,
-1, -1, -1, -1, -1, -1, -1, -1,
-1, -1, -1, -1, -1, -1, -1, -1,
-1, -1, -1, -1, -1, -1, -1, -1,
-1, -1, -1, -1, -1, -1, -1, -1,
-1, -1, -1, -1, -1, -1, -1, -1,
-1, -1, -1, -1, -1, -1, -1, -1,
-1, -1, -1, -1, -1, -1, -1, -1,
-1, -1, -1, -1, -1, -1, -1, -1,
-1, -1, -1, -1, -1, -1, -1, -1,
-1, -1, -1, -1, -1, -1, -1, -1,
-1, -1, -1, -1, -1, -1, -1, -1,
-1, -1, -1, -1, -1, -1, -1, -1,
-1, -1, -1, -1, -1, -1, -1, -1,
-1, -1, -1, -1, -1, -1, -1, -1,
-1, -1, -1, -1, -1, -1, -1, -1,
-1, -1, -1, -1, -1, -1, -1, -1
};
// Returns the table value sign-extended to 32 bits. Knowing that the upper
// bits will be 1 for unrecognized characters makes it easier to check for
// this error condition later (see below).
int32_t b64lookup(unsigned char ch) { return b64table[ch]; }
// Returns true if the given character is not a valid base64 character or
// padding.
bool nonbase64(unsigned char ch) { return b64lookup(ch) == -1 && ch != '='; }
static bool base64_push(upb_json_parser *p, upb_selector_t sel, const char *ptr,
size_t len) {
const char *limit = ptr + len;
for (; ptr < limit; ptr += 4) {
if (limit - ptr < 4) {
upb_status_seterrf(p->status,
"Base64 input for bytes field not a multiple of 4: %s",
upb_fielddef_name(p->top->f));
return false;
}
uint32_t val = b64lookup(ptr[0]) << 18 |
b64lookup(ptr[1]) << 12 |
b64lookup(ptr[2]) << 6 |
b64lookup(ptr[3]);
// Test the upper bit; returns true if any of the characters returned -1.
if (val & 0x80000000) {
goto otherchar;
}
char output[3];
output[0] = val >> 16;
output[1] = (val >> 8) & 0xff;
output[2] = val & 0xff;
upb_sink_putstring(&p->top->sink, sel, output, 3, NULL);
}
return true;
otherchar:
if (nonbase64(ptr[0]) || nonbase64(ptr[1]) || nonbase64(ptr[2]) ||
nonbase64(ptr[3]) ) {
upb_status_seterrf(p->status,
"Non-base64 characters in bytes field: %s",
upb_fielddef_name(p->top->f));
return false;
} if (ptr[2] == '=') {
// Last group contains only two input bytes, one output byte.
if (ptr[0] == '=' || ptr[1] == '=' || ptr[3] != '=') {
goto badpadding;
}
uint32_t val = b64lookup(ptr[0]) << 18 |
b64lookup(ptr[1]) << 12;
assert(!(val & 0x80000000));
char output = val >> 16;
upb_sink_putstring(&p->top->sink, sel, &output, 1, NULL);
return true;
} else {
// Last group contains only three input bytes, two output bytes.
if (ptr[0] == '=' || ptr[1] == '=' || ptr[2] == '=') {
goto badpadding;
}
uint32_t val = b64lookup(ptr[0]) << 18 |
b64lookup(ptr[1]) << 12 |
b64lookup(ptr[2]) << 6;
char output[2];
output[0] = val >> 16;
output[1] = (val >> 8) & 0xff;
upb_sink_putstring(&p->top->sink, sel, output, 2, NULL);
return true;
}
badpadding:
upb_status_seterrf(p->status,
"Incorrect base64 padding for field: %s (%.*s)",
upb_fielddef_name(p->top->f),
4, ptr);
return false;
}
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/* Accumulate buffer **********************************************************/
// Functionality for accumulating a buffer.
//
// Some parts of the parser need an entire value as a contiguous string. For
// example, to look up a member name in a hash table, or to turn a string into
// a number, the relevant library routines need the input string to be in
// contiguous memory, even if the value spanned two or more buffers in the
// input. These routines handle that.
//
// In the common case we can just point to the input buffer to get this
// contiguous string and avoid any actual copy. So we optimistically begin
// this way. But there are a few cases where we must instead copy into a
// separate buffer:
//
// 1. The string was not contiguous in the input (it spanned buffers).
//
// 2. The string included escape sequences that need to be interpreted to get
// the true value in a contiguous buffer.
static void assert_accumulate_empty(upb_json_parser *p) {
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UPB_UNUSED(p);
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assert(p->accumulated == NULL);
assert(p->accumulated_len == 0);
}
static void accumulate_clear(upb_json_parser *p) {
p->accumulated = NULL;
p->accumulated_len = 0;
}
// Used internally by accumulate_append().
static bool accumulate_realloc(upb_json_parser *p, size_t need) {
size_t new_size = UPB_MAX(p->accumulate_buf_size, 128);
while (new_size < need) {
new_size = saturating_multiply(new_size, 2);
}
void *mem = realloc(p->accumulate_buf, new_size);
if (!mem) {
upb_status_seterrmsg(p->status, "Out of memory allocating buffer.");
return false;
}
p->accumulate_buf = mem;
p->accumulate_buf_size = new_size;
return true;
}
// Logically appends the given data to the append buffer.
// If "can_alias" is true, we will try to avoid actually copying, but the buffer
// must be valid until the next accumulate_append() call (if any).
static bool accumulate_append(upb_json_parser *p, const char *buf, size_t len,
bool can_alias) {
if (!p->accumulated && can_alias) {
p->accumulated = buf;
p->accumulated_len = len;
return true;
}
size_t need;
if (!checked_add(p->accumulated_len, len, &need)) {
upb_status_seterrmsg(p->status, "Integer overflow.");
return false;
}
if (need > p->accumulate_buf_size && !accumulate_realloc(p, need)) {
return false;
}
if (p->accumulated != p->accumulate_buf) {
memcpy(p->accumulate_buf, p->accumulated, p->accumulated_len);
p->accumulated = p->accumulate_buf;
}
memcpy(p->accumulate_buf + p->accumulated_len, buf, len);
p->accumulated_len += len;
return true;
}
// Returns a pointer to the data accumulated since the last accumulate_clear()
// call, and writes the length to *len. This with point either to the input
// buffer or a temporary accumulate buffer.
static const char *accumulate_getptr(upb_json_parser *p, size_t *len) {
assert(p->accumulated);
*len = p->accumulated_len;
return p->accumulated;
}
/* Mult-part text data ********************************************************/
// When we have text data in the input, it can often come in multiple segments.
// For example, there may be some raw string data followed by an escape
// sequence. The two segments are processed with different logic. Also buffer
// seams in the input can cause multiple segments.
//
// As we see segments, there are two main cases for how we want to process them:
//
// 1. we want to push the captured input directly to string handlers.
//
// 2. we need to accumulate all the parts into a contiguous buffer for further
// processing (field name lookup, string->number conversion, etc).
// This is the set of states for p->multipart_state.
enum {
// We are not currently processing multipart data.
MULTIPART_INACTIVE = 0,
// We are processing multipart data by accumulating it into a contiguous
// buffer.
MULTIPART_ACCUMULATE = 1,
// We are processing multipart data by pushing each part directly to the
// current string handlers.
MULTIPART_PUSHEAGERLY = 2
};
// Start a multi-part text value where we accumulate the data for processing at
// the end.
static void multipart_startaccum(upb_json_parser *p) {
assert_accumulate_empty(p);
assert(p->multipart_state == MULTIPART_INACTIVE);
p->multipart_state = MULTIPART_ACCUMULATE;
}
// Start a multi-part text value where we immediately push text data to a string
// value with the given selector.
static void multipart_start(upb_json_parser *p, upb_selector_t sel) {
assert_accumulate_empty(p);
assert(p->multipart_state == MULTIPART_INACTIVE);
p->multipart_state = MULTIPART_PUSHEAGERLY;
p->string_selector = sel;
}
static bool multipart_text(upb_json_parser *p, const char *buf, size_t len,
bool can_alias) {
switch (p->multipart_state) {
case MULTIPART_INACTIVE:
upb_status_seterrmsg(
p->status, "Internal error: unexpected state MULTIPART_INACTIVE");
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
return false;
Update upb amalgamation.
10 years ago
case MULTIPART_ACCUMULATE:
if (!accumulate_append(p, buf, len, can_alias)) {
return false;
}
break;
case MULTIPART_PUSHEAGERLY: {
const upb_bufhandle *handle = can_alias ? p->handle : NULL;
upb_sink_putstring(&p->top->sink, p->string_selector, buf, len, handle);
break;
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
}
}
return true;
}
Update upb amalgamation.
10 years ago
// Note: this invalidates the accumulate buffer! Call only after reading its
// contents.
static void multipart_end(upb_json_parser *p) {
assert(p->multipart_state != MULTIPART_INACTIVE);
p->multipart_state = MULTIPART_INACTIVE;
accumulate_clear(p);
}
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
Update upb amalgamation.
10 years ago
/* Input capture **************************************************************/
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
Update upb amalgamation.
10 years ago
// Functionality for capturing a region of the input as text. Gracefully
// handles the case where a buffer seam occurs in the middle of the captured
// region.
static void capture_begin(upb_json_parser *p, const char *ptr) {
assert(p->multipart_state != MULTIPART_INACTIVE);
assert(p->capture == NULL);
p->capture = ptr;
}
static bool capture_end(upb_json_parser *p, const char *ptr) {
assert(p->capture);
if (multipart_text(p, p->capture, ptr - p->capture, true)) {
p->capture = NULL;
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
return true;
} else {
return false;
}
Update upb amalgamation.
10 years ago
}
// This is called at the end of each input buffer (ie. when we have hit a
// buffer seam). If we are in the middle of capturing the input, this
// processes the unprocessed capture region.
static void capture_suspend(upb_json_parser *p, const char **ptr) {
if (!p->capture) return;
if (multipart_text(p, p->capture, *ptr - p->capture, false)) {
// We use this as a signal that we were in the middle of capturing, and
// that capturing should resume at the beginning of the next buffer.
//
// We can't use *ptr here, because we have no guarantee that this pointer
// will be valid when we resume (if the underlying memory is freed, then
// using the pointer at all, even to compare to NULL, is likely undefined
// behavior).
p->capture = &suspend_capture;
} else {
// Need to back up the pointer to the beginning of the capture, since
// we were not able to actually preserve it.
*ptr = p->capture;
}
}
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
Update upb amalgamation.
10 years ago
static void capture_resume(upb_json_parser *p, const char *ptr) {
if (p->capture) {
assert(p->capture == &suspend_capture);
p->capture = ptr;
}
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
}
Update upb amalgamation.
10 years ago
/* Callbacks from the parser **************************************************/
// These are the functions called directly from the parser itself.
// We define these in the same order as their declarations in the parser.
static char escape_char(char in) {
switch (in) {
case 'r': return '\r';
case 't': return '\t';
case 'n': return '\n';
case 'f': return '\f';
case 'b': return '\b';
case '/': return '/';
case '"': return '"';
case '\\': return '\\';
default:
assert(0);
return 'x';
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
}
}
Update upb amalgamation.
10 years ago
static bool escape(upb_json_parser *p, const char *ptr) {
char ch = escape_char(*ptr);
return multipart_text(p, &ch, 1, false);
}
static void start_hex(upb_json_parser *p) {
p->digit = 0;
}
static void hexdigit(upb_json_parser *p, const char *ptr) {
char ch = *ptr;
p->digit <<= 4;
if (ch >= '0' && ch <= '9') {
p->digit += (ch - '0');
} else if (ch >= 'a' && ch <= 'f') {
p->digit += ((ch - 'a') + 10);
} else {
assert(ch >= 'A' && ch <= 'F');
p->digit += ((ch - 'A') + 10);
}
}
static bool end_hex(upb_json_parser *p) {
uint32_t codepoint = p->digit;
// emit the codepoint as UTF-8.
char utf8[3]; // support \u0000 -- \uFFFF -- need only three bytes.
int length = 0;
if (codepoint <= 0x7F) {
utf8[0] = codepoint;
length = 1;
} else if (codepoint <= 0x07FF) {
utf8[1] = (codepoint & 0x3F) | 0x80;
codepoint >>= 6;
utf8[0] = (codepoint & 0x1F) | 0xC0;
length = 2;
} else /* codepoint <= 0xFFFF */ {
utf8[2] = (codepoint & 0x3F) | 0x80;
codepoint >>= 6;
utf8[1] = (codepoint & 0x3F) | 0x80;
codepoint >>= 6;
utf8[0] = (codepoint & 0x0F) | 0xE0;
length = 3;
}
// TODO(haberman): Handle high surrogates: if codepoint is a high surrogate
// we have to wait for the next escape to get the full code point).
return multipart_text(p, utf8, length, false);
}
static void start_text(upb_json_parser *p, const char *ptr) {
capture_begin(p, ptr);
}
static bool end_text(upb_json_parser *p, const char *ptr) {
return capture_end(p, ptr);
}
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
static void start_number(upb_json_parser *p, const char *ptr) {
Update upb amalgamation.
10 years ago
multipart_startaccum(p);
capture_begin(p, ptr);
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
}
Update upb amalgamation.
10 years ago
static bool end_number(upb_json_parser *p, const char *ptr) {
if (!capture_end(p, ptr)) {
return false;
}
// strtol() and friends unfortunately do not support specifying the length of
// the input string, so we need to force a copy into a NULL-terminated buffer.
if (!multipart_text(p, "\0", 1, false)) {
return false;
}
size_t len;
const char *buf = accumulate_getptr(p, &len);
const char *myend = buf + len - 1; // One for NULL.
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
char *end;
switch (upb_fielddef_type(p->top->f)) {
case UPB_TYPE_ENUM:
case UPB_TYPE_INT32: {
long val = strtol(p->accumulated, &end, 0);
if (val > INT32_MAX || val < INT32_MIN || errno == ERANGE || end != myend)
Update upb amalgamation.
10 years ago
goto err;
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
else
upb_sink_putint32(&p->top->sink, parser_getsel(p), val);
break;
}
case UPB_TYPE_INT64: {
long long val = strtoll(p->accumulated, &end, 0);
if (val > INT64_MAX || val < INT64_MIN || errno == ERANGE || end != myend)
Update upb amalgamation.
10 years ago
goto err;
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
else
upb_sink_putint64(&p->top->sink, parser_getsel(p), val);
break;
}
case UPB_TYPE_UINT32: {
unsigned long val = strtoul(p->accumulated, &end, 0);
if (val > UINT32_MAX || errno == ERANGE || end != myend)
Update upb amalgamation.
10 years ago
goto err;
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
else
upb_sink_putuint32(&p->top->sink, parser_getsel(p), val);
break;
}
case UPB_TYPE_UINT64: {
unsigned long long val = strtoull(p->accumulated, &end, 0);
if (val > UINT64_MAX || errno == ERANGE || end != myend)
Update upb amalgamation.
10 years ago
goto err;
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
else
upb_sink_putuint64(&p->top->sink, parser_getsel(p), val);
break;
}
case UPB_TYPE_DOUBLE: {
double val = strtod(p->accumulated, &end);
if (errno == ERANGE || end != myend)
Update upb amalgamation.
10 years ago
goto err;
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
else
upb_sink_putdouble(&p->top->sink, parser_getsel(p), val);
break;
}
case UPB_TYPE_FLOAT: {
float val = strtof(p->accumulated, &end);
if (errno == ERANGE || end != myend)
Update upb amalgamation.
10 years ago
goto err;
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
else
upb_sink_putfloat(&p->top->sink, parser_getsel(p), val);
break;
}
default:
assert(false);
}
Update upb amalgamation.
10 years ago
multipart_end(p);
return true;
err:
upb_status_seterrf(p->status, "error parsing number: %s", buf);
multipart_end(p);
return false;
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
}
Update upb amalgamation.
10 years ago
static bool parser_putbool(upb_json_parser *p, bool val) {
if (upb_fielddef_type(p->top->f) != UPB_TYPE_BOOL) {
upb_status_seterrf(p->status,
"Boolean value specified for non-bool field: %s",
upb_fielddef_name(p->top->f));
return false;
}
bool ok = upb_sink_putbool(&p->top->sink, parser_getsel(p), val);
UPB_ASSERT_VAR(ok, ok);
return true;
}
static bool start_stringval(upb_json_parser *p) {
assert(p->top->f);
if (upb_fielddef_isstring(p->top->f)) {
if (!check_stack(p)) return false;
// Start a new parser frame: parser frames correspond one-to-one with
// handler frames, and string events occur in a sub-frame.
upb_jsonparser_frame *inner = p->top + 1;
upb_selector_t sel = getsel_for_handlertype(p, UPB_HANDLER_STARTSTR);
upb_sink_startstr(&p->top->sink, sel, 0, &inner->sink);
inner->m = p->top->m;
inner->f = p->top->f;
p->top = inner;
if (upb_fielddef_type(p->top->f) == UPB_TYPE_STRING) {
// For STRING fields we push data directly to the handlers as it is
// parsed. We don't do this yet for BYTES fields, because our base64
// decoder is not streaming.
//
// TODO(haberman): make base64 decoding streaming also.
multipart_start(p, getsel_for_handlertype(p, UPB_HANDLER_STRING));
return true;
} else {
multipart_startaccum(p);
return true;
}
} else if (upb_fielddef_type(p->top->f) == UPB_TYPE_ENUM) {
// No need to push a frame -- symbolic enum names in quotes remain in the
// current parser frame.
//
// Enum string values must accumulate so we can look up the value in a table
// once it is complete.
multipart_startaccum(p);
return true;
} else {
upb_status_seterrf(p->status,
"String specified for non-string/non-enum field: %s",
upb_fielddef_name(p->top->f));
return false;
}
}
static bool end_stringval(upb_json_parser *p) {
bool ok = true;
switch (upb_fielddef_type(p->top->f)) {
case UPB_TYPE_BYTES:
if (!base64_push(p, getsel_for_handlertype(p, UPB_HANDLER_STRING),
p->accumulated, p->accumulated_len)) {
return false;
}
// Fall through.
case UPB_TYPE_STRING: {
upb_selector_t sel = getsel_for_handlertype(p, UPB_HANDLER_ENDSTR);
upb_sink_endstr(&p->top->sink, sel);
p->top--;
break;
}
case UPB_TYPE_ENUM: {
// Resolve enum symbolic name to integer value.
const upb_enumdef *enumdef =
(const upb_enumdef*)upb_fielddef_subdef(p->top->f);
size_t len;
const char *buf = accumulate_getptr(p, &len);
int32_t int_val = 0;
ok = upb_enumdef_ntoi(enumdef, buf, len, &int_val);
if (ok) {
upb_selector_t sel = parser_getsel(p);
upb_sink_putint32(&p->top->sink, sel, int_val);
} else {
upb_status_seterrf(p->status, "Enum value unknown: '%.*s'", len, buf);
}
break;
}
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
default:
Update upb amalgamation.
10 years ago
assert(false);
upb_status_seterrmsg(p->status, "Internal error in JSON decoder");
ok = false;
break;
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
}
Update upb amalgamation.
10 years ago
multipart_end(p);
return ok;
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
}
Update upb amalgamation.
10 years ago
static void start_member(upb_json_parser *p) {
assert(!p->top->f);
multipart_startaccum(p);
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
}
Update upb amalgamation.
10 years ago
static bool end_member(upb_json_parser *p) {
assert(!p->top->f);
size_t len;
const char *buf = accumulate_getptr(p, &len);
const upb_fielddef *f = upb_msgdef_ntof(p->top->m, buf, len);
if (!f) {
// TODO(haberman): Ignore unknown fields if requested/configured to do so.
upb_status_seterrf(p->status, "No such field: %.*s\n", (int)len, buf);
return false;
}
p->top->f = f;
multipart_end(p);
return true;
}
static void clear_member(upb_json_parser *p) { p->top->f = NULL; }
static bool start_subobject(upb_json_parser *p) {
assert(p->top->f);
if (!upb_fielddef_issubmsg(p->top->f)) {
upb_status_seterrf(p->status,
"Object specified for non-message/group field: %s",
upb_fielddef_name(p->top->f));
return false;
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
}
Update upb amalgamation.
10 years ago
if (!check_stack(p)) return false;
upb_jsonparser_frame *inner = p->top + 1;
upb_selector_t sel = getsel_for_handlertype(p, UPB_HANDLER_STARTSUBMSG);
upb_sink_startsubmsg(&p->top->sink, sel, &inner->sink);
inner->m = upb_fielddef_msgsubdef(p->top->f);
inner->f = NULL;
p->top = inner;
return true;
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
}
Update upb amalgamation.
10 years ago
static void end_subobject(upb_json_parser *p) {
p->top--;
upb_selector_t sel = getsel_for_handlertype(p, UPB_HANDLER_ENDSUBMSG);
upb_sink_endsubmsg(&p->top->sink, sel);
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
}
Update upb amalgamation.
10 years ago
static bool start_array(upb_json_parser *p) {
assert(p->top->f);
if (!upb_fielddef_isseq(p->top->f)) {
upb_status_seterrf(p->status,
"Array specified for non-repeated field: %s",
upb_fielddef_name(p->top->f));
return false;
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
}
Update upb amalgamation.
10 years ago
if (!check_stack(p)) return false;
upb_jsonparser_frame *inner = p->top + 1;
upb_selector_t sel = getsel_for_handlertype(p, UPB_HANDLER_STARTSEQ);
upb_sink_startseq(&p->top->sink, sel, &inner->sink);
inner->m = p->top->m;
inner->f = p->top->f;
p->top = inner;
return true;
}
static void end_array(upb_json_parser *p) {
assert(p->top > p->stack);
p->top--;
upb_selector_t sel = getsel_for_handlertype(p, UPB_HANDLER_ENDSEQ);
upb_sink_endseq(&p->top->sink, sel);
}
static void start_object(upb_json_parser *p) {
upb_sink_startmsg(&p->top->sink);
}
static void end_object(upb_json_parser *p) {
upb_status status;
upb_sink_endmsg(&p->top->sink, &status);
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
}
Update upb amalgamation.
10 years ago
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
#define CHECK_RETURN_TOP(x) if (!(x)) goto error
Update upb amalgamation.
10 years ago
/* The actual parser **********************************************************/
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
// What follows is the Ragel parser itself. The language is specified in Ragel
// and the actions call our C functions above.
Update upb amalgamation.
10 years ago
//
// Ragel has an extensive set of functionality, and we use only a small part of
// it. There are many action types but we only use a few:
//
// ">" -- transition into a machine
// "%" -- transition out of a machine
// "@" -- transition into a final state of a machine.
//
// "@" transitions are tricky because a machine can transition into a final
// state repeatedly. But in some cases we know this can't happen, for example
// a string which is delimited by a final '"' can only transition into its
// final state once, when the closing '"' is seen.
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
Support oneofs in MRI Ruby C extension.
10 years ago
#line 905 "upb/json/parser.rl"
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
Support oneofs in MRI Ruby C extension.
10 years ago
#line 817 "upb/json/parser.c"
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
static const char _json_actions[] = {
0, 1, 0, 1, 2, 1, 3, 1,
Update upb amalgamation.
10 years ago
5, 1, 6, 1, 7, 1, 8, 1,
10, 1, 12, 1, 13, 1, 14, 1,
15, 1, 16, 1, 17, 1, 21, 1,
25, 1, 27, 2, 3, 8, 2, 4,
5, 2, 6, 2, 2, 6, 8, 2,
11, 9, 2, 13, 15, 2, 14, 15,
2, 18, 1, 2, 19, 27, 2, 20,
9, 2, 22, 27, 2, 23, 27, 2,
24, 27, 2, 26, 27, 3, 14, 11,
9
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
};
static const unsigned char _json_key_offsets[] = {
Update upb amalgamation.
10 years ago
0, 0, 4, 9, 14, 15, 19, 24,
29, 34, 38, 42, 45, 48, 50, 54,
58, 60, 62, 67, 69, 71, 80, 86,
92, 98, 104, 106, 115, 116, 116, 116,
121, 126, 131, 132, 133, 134, 135, 135,
136, 137, 138, 138, 139, 140, 141, 141,
146, 151, 152, 156, 161, 166, 171, 175,
175, 178, 178, 178
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
};
static const char _json_trans_keys[] = {
32, 123, 9, 13, 32, 34, 125, 9,
Update upb amalgamation.
10 years ago
13, 32, 34, 125, 9, 13, 34, 32,
58, 9, 13, 32, 93, 125, 9, 13,
32, 44, 125, 9, 13, 32, 44, 125,
9, 13, 32, 34, 9, 13, 45, 48,
49, 57, 48, 49, 57, 46, 69, 101,
48, 57, 69, 101, 48, 57, 43, 45,
48, 57, 48, 57, 48, 57, 46, 69,
101, 48, 57, 34, 92, 34, 92, 34,
47, 92, 98, 102, 110, 114, 116, 117,
48, 57, 65, 70, 97, 102, 48, 57,
65, 70, 97, 102, 48, 57, 65, 70,
97, 102, 48, 57, 65, 70, 97, 102,
34, 92, 34, 45, 91, 102, 110, 116,
123, 48, 57, 34, 32, 93, 125, 9,
13, 32, 44, 93, 9, 13, 32, 93,
125, 9, 13, 97, 108, 115, 101, 117,
108, 108, 114, 117, 101, 32, 34, 125,
9, 13, 32, 34, 125, 9, 13, 34,
32, 58, 9, 13, 32, 93, 125, 9,
13, 32, 44, 125, 9, 13, 32, 44,
125, 9, 13, 32, 34, 9, 13, 32,
9, 13, 0
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
};
static const char _json_single_lengths[] = {
Update upb amalgamation.
10 years ago
0, 2, 3, 3, 1, 2, 3, 3,
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
3, 2, 2, 1, 3, 0, 2, 2,
0, 0, 3, 2, 2, 9, 0, 0,
Update upb amalgamation.
10 years ago
0, 0, 2, 7, 1, 0, 0, 3,
3, 3, 1, 1, 1, 1, 0, 1,
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
1, 1, 0, 1, 1, 1, 0, 3,
Update upb amalgamation.
10 years ago
3, 1, 2, 3, 3, 3, 2, 0,
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
1, 0, 0, 0
};
static const char _json_range_lengths[] = {
Update upb amalgamation.
10 years ago
0, 1, 1, 1, 0, 1, 1, 1,
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
1, 1, 1, 1, 0, 1, 1, 1,
1, 1, 1, 0, 0, 0, 3, 3,
Update upb amalgamation.
10 years ago
3, 3, 0, 1, 0, 0, 0, 1,
1, 1, 0, 0, 0, 0, 0, 0,
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
0, 0, 0, 0, 0, 0, 0, 1,
Update upb amalgamation.
10 years ago
1, 0, 1, 1, 1, 1, 1, 0,
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
1, 0, 0, 0
};
static const short _json_index_offsets[] = {
Update upb amalgamation.
10 years ago
0, 0, 4, 9, 14, 16, 20, 25,
30, 35, 39, 43, 46, 50, 52, 56,
60, 62, 64, 69, 72, 75, 85, 89,
93, 97, 101, 104, 113, 115, 116, 117,
122, 127, 132, 134, 136, 138, 140, 141,
143, 145, 147, 148, 150, 152, 154, 155,
160, 165, 167, 171, 176, 181, 186, 190,
191, 194, 195, 196
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
};
static const char _json_indicies[] = {
0, 2, 0, 1, 3, 4, 5, 3,
Update upb amalgamation.
10 years ago
1, 6, 7, 8, 6, 1, 9, 1,
10, 11, 10, 1, 11, 1, 1, 11,
12, 13, 14, 15, 13, 1, 16, 17,
8, 16, 1, 17, 7, 17, 1, 18,
19, 20, 1, 19, 20, 1, 22, 23,
23, 21, 24, 1, 23, 23, 24, 21,
25, 25, 26, 1, 26, 1, 26, 21,
22, 23, 23, 20, 21, 28, 29, 27,
31, 32, 30, 33, 33, 33, 33, 33,
33, 33, 33, 34, 1, 35, 35, 35,
1, 36, 36, 36, 1, 37, 37, 37,
1, 38, 38, 38, 1, 40, 41, 39,
42, 43, 44, 45, 46, 47, 48, 43,
1, 49, 1, 50, 51, 53, 54, 1,
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
53, 52, 55, 56, 54, 55, 1, 56,
Update upb amalgamation.
10 years ago
1, 1, 56, 52, 57, 1, 58, 1,
59, 1, 60, 1, 61, 62, 1, 63,
1, 64, 1, 65, 66, 1, 67, 1,
68, 1, 69, 70, 71, 72, 70, 1,
73, 74, 75, 73, 1, 76, 1, 77,
78, 77, 1, 78, 1, 1, 78, 79,
80, 81, 82, 80, 1, 83, 84, 75,
83, 1, 84, 74, 84, 1, 85, 86,
86, 1, 1, 1, 1, 0
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
};
static const char _json_trans_targs[] = {
1, 0, 2, 3, 4, 56, 3, 4,
Update upb amalgamation.
10 years ago
56, 5, 5, 6, 7, 8, 9, 56,
8, 9, 11, 12, 18, 57, 13, 15,
14, 16, 17, 20, 58, 21, 20, 58,
21, 19, 22, 23, 24, 25, 26, 20,
58, 21, 28, 30, 31, 34, 39, 43,
47, 29, 59, 59, 32, 31, 29, 32,
33, 35, 36, 37, 38, 59, 40, 41,
42, 59, 44, 45, 46, 59, 48, 49,
55, 48, 49, 55, 50, 50, 51, 52,
53, 54, 55, 53, 54, 59, 56
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
};
static const char _json_trans_actions[] = {
Update upb amalgamation.
10 years ago
0, 0, 0, 21, 77, 53, 0, 47,
23, 17, 0, 0, 15, 19, 19, 50,
0, 0, 0, 0, 0, 1, 0, 0,
0, 0, 0, 3, 13, 0, 0, 35,
5, 11, 0, 38, 7, 7, 7, 41,
44, 9, 62, 56, 25, 0, 0, 0,
31, 29, 33, 59, 15, 0, 27, 0,
0, 0, 0, 0, 0, 68, 0, 0,
0, 71, 0, 0, 0, 65, 21, 77,
53, 0, 47, 23, 17, 0, 0, 15,
19, 19, 50, 0, 0, 74, 0
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
};
static const int json_start = 1;
static const int json_first_final = 56;
static const int json_error = 0;
static const int json_en_number_machine = 10;
static const int json_en_string_machine = 19;
static const int json_en_value_machine = 27;
static const int json_en_main = 1;
Support oneofs in MRI Ruby C extension.
10 years ago
#line 908 "upb/json/parser.rl"
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
size_t parse(void *closure, const void *hd, const char *buf, size_t size,
const upb_bufhandle *handle) {
UPB_UNUSED(hd);
UPB_UNUSED(handle);
upb_json_parser *parser = closure;
Update upb amalgamation.
10 years ago
parser->handle = handle;
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
// Variables used by Ragel's generated code.
int cs = parser->current_state;
int *stack = parser->parser_stack;
int top = parser->parser_top;
const char *p = buf;
const char *pe = buf + size;
Update upb amalgamation.
10 years ago
capture_resume(parser, buf);
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
Support oneofs in MRI Ruby C extension.
10 years ago
#line 988 "upb/json/parser.c"
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
{
int _klen;
unsigned int _trans;
const char *_acts;
unsigned int _nacts;
const char *_keys;
if ( p == pe )
goto _test_eof;
if ( cs == 0 )
goto _out;
_resume:
_keys = _json_trans_keys + _json_key_offsets[cs];
_trans = _json_index_offsets[cs];
_klen = _json_single_lengths[cs];
if ( _klen > 0 ) {
const char *_lower = _keys;
const char *_mid;
const char *_upper = _keys + _klen - 1;
while (1) {
if ( _upper < _lower )
break;
_mid = _lower + ((_upper-_lower) >> 1);
if ( (*p) < *_mid )
_upper = _mid - 1;
else if ( (*p) > *_mid )
_lower = _mid + 1;
else {
_trans += (unsigned int)(_mid - _keys);
goto _match;
}
}
_keys += _klen;
_trans += _klen;
}
_klen = _json_range_lengths[cs];
if ( _klen > 0 ) {
const char *_lower = _keys;
const char *_mid;
const char *_upper = _keys + (_klen<<1) - 2;
while (1) {
if ( _upper < _lower )
break;
_mid = _lower + (((_upper-_lower) >> 1) & ~1);
if ( (*p) < _mid[0] )
_upper = _mid - 2;
else if ( (*p) > _mid[1] )
_lower = _mid + 2;
else {
_trans += (unsigned int)((_mid - _keys)>>1);
goto _match;
}
}
_trans += _klen;
}
_match:
_trans = _json_indicies[_trans];
cs = _json_trans_targs[_trans];
if ( _json_trans_actions[_trans] == 0 )
goto _again;
_acts = _json_actions + _json_trans_actions[_trans];
_nacts = (unsigned int) *_acts++;
while ( _nacts-- > 0 )
{
switch ( *_acts++ )
{
case 0:
Support oneofs in MRI Ruby C extension.
10 years ago
#line 820 "upb/json/parser.rl"
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
{ p--; {cs = stack[--top]; goto _again;} }
break;
case 1:
Support oneofs in MRI Ruby C extension.
10 years ago
#line 821 "upb/json/parser.rl"
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
{ p--; {stack[top++] = cs; cs = 10; goto _again;} }
break;
case 2:
Support oneofs in MRI Ruby C extension.
10 years ago
#line 825 "upb/json/parser.rl"
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
{ start_text(parser, p); }
break;
case 3:
Support oneofs in MRI Ruby C extension.
10 years ago
#line 826 "upb/json/parser.rl"
Update upb amalgamation.
10 years ago
{ CHECK_RETURN_TOP(end_text(parser, p)); }
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
break;
case 4:
Support oneofs in MRI Ruby C extension.
10 years ago
#line 832 "upb/json/parser.rl"
Update upb amalgamation.
10 years ago
{ start_hex(parser); }
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
break;
case 5:
Support oneofs in MRI Ruby C extension.
10 years ago
#line 833 "upb/json/parser.rl"
Update upb amalgamation.
10 years ago
{ hexdigit(parser, p); }
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
break;
case 6:
Support oneofs in MRI Ruby C extension.
10 years ago
#line 834 "upb/json/parser.rl"
Update upb amalgamation.
10 years ago
{ CHECK_RETURN_TOP(end_hex(parser)); }
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
break;
case 7:
Support oneofs in MRI Ruby C extension.
10 years ago
#line 840 "upb/json/parser.rl"
Update upb amalgamation.
10 years ago
{ CHECK_RETURN_TOP(escape(parser, p)); }
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
break;
case 8:
Support oneofs in MRI Ruby C extension.
10 years ago
#line 846 "upb/json/parser.rl"
Update upb amalgamation.
10 years ago
{ p--; {cs = stack[--top]; goto _again;} }
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
break;
case 9:
Support oneofs in MRI Ruby C extension.
10 years ago
#line 849 "upb/json/parser.rl"
Update upb amalgamation.
10 years ago
{ {stack[top++] = cs; cs = 19; goto _again;} }
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
break;
case 10:
Support oneofs in MRI Ruby C extension.
10 years ago
#line 851 "upb/json/parser.rl"
Update upb amalgamation.
10 years ago
{ p--; {stack[top++] = cs; cs = 27; goto _again;} }
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
break;
case 11:
Support oneofs in MRI Ruby C extension.
10 years ago
#line 856 "upb/json/parser.rl"
Update upb amalgamation.
10 years ago
{ start_member(parser); }
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
break;
case 12:
Support oneofs in MRI Ruby C extension.
10 years ago
#line 857 "upb/json/parser.rl"
Update upb amalgamation.
10 years ago
{ CHECK_RETURN_TOP(end_member(parser)); }
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
break;
case 13:
Support oneofs in MRI Ruby C extension.
10 years ago
#line 860 "upb/json/parser.rl"
Update upb amalgamation.
10 years ago
{ clear_member(parser); }
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
break;
case 14:
Support oneofs in MRI Ruby C extension.
10 years ago
#line 866 "upb/json/parser.rl"
Update upb amalgamation.
10 years ago
{ start_object(parser); }
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
break;
case 15:
Support oneofs in MRI Ruby C extension.
10 years ago
#line 869 "upb/json/parser.rl"
Update upb amalgamation.
10 years ago
{ end_object(parser); }
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
break;
case 16:
Support oneofs in MRI Ruby C extension.
10 years ago
#line 875 "upb/json/parser.rl"
Update upb amalgamation.
10 years ago
{ CHECK_RETURN_TOP(start_array(parser)); }
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
break;
case 17:
Support oneofs in MRI Ruby C extension.
10 years ago
#line 879 "upb/json/parser.rl"
Update upb amalgamation.
10 years ago
{ end_array(parser); }
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
break;
case 18:
Support oneofs in MRI Ruby C extension.
10 years ago
#line 884 "upb/json/parser.rl"
Update upb amalgamation.
10 years ago
{ start_number(parser, p); }
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
break;
case 19:
Support oneofs in MRI Ruby C extension.
10 years ago
#line 885 "upb/json/parser.rl"
Update upb amalgamation.
10 years ago
{ CHECK_RETURN_TOP(end_number(parser, p)); }
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
break;
case 20:
Support oneofs in MRI Ruby C extension.
10 years ago
#line 887 "upb/json/parser.rl"
Update upb amalgamation.
10 years ago
{ CHECK_RETURN_TOP(start_stringval(parser)); }
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
break;
case 21:
Support oneofs in MRI Ruby C extension.
10 years ago
#line 888 "upb/json/parser.rl"
Update upb amalgamation.
10 years ago
{ CHECK_RETURN_TOP(end_stringval(parser)); }
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
break;
case 22:
Support oneofs in MRI Ruby C extension.
10 years ago
#line 890 "upb/json/parser.rl"
Update upb amalgamation.
10 years ago
{ CHECK_RETURN_TOP(parser_putbool(parser, true)); }
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
break;
case 23:
Support oneofs in MRI Ruby C extension.
10 years ago
#line 892 "upb/json/parser.rl"
Update upb amalgamation.
10 years ago
{ CHECK_RETURN_TOP(parser_putbool(parser, false)); }
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
break;
case 24:
Support oneofs in MRI Ruby C extension.
10 years ago
#line 894 "upb/json/parser.rl"
Update upb amalgamation.
10 years ago
{ /* null value */ }
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
break;
case 25:
Support oneofs in MRI Ruby C extension.
10 years ago
#line 896 "upb/json/parser.rl"
Update upb amalgamation.
10 years ago
{ CHECK_RETURN_TOP(start_subobject(parser)); }
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
break;
case 26:
Support oneofs in MRI Ruby C extension.
10 years ago
#line 897 "upb/json/parser.rl"
Update upb amalgamation.
10 years ago
{ end_subobject(parser); }
break;
case 27:
Support oneofs in MRI Ruby C extension.
10 years ago
#line 902 "upb/json/parser.rl"
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
{ p--; {cs = stack[--top]; goto _again;} }
break;
Support oneofs in MRI Ruby C extension.
10 years ago
#line 1174 "upb/json/parser.c"
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
}
}
_again:
if ( cs == 0 )
goto _out;
if ( ++p != pe )
goto _resume;
_test_eof: {}
_out: {}
}
Support oneofs in MRI Ruby C extension.
10 years ago
#line 927 "upb/json/parser.rl"
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
if (p != pe) {
upb_status_seterrf(parser->status, "Parse error at %s\n", p);
Update upb amalgamation.
10 years ago
} else {
capture_suspend(parser, &p);
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
}
error:
// Save parsing state back to parser.
parser->current_state = cs;
parser->parser_top = top;
return p - buf;
}
bool end(void *closure, const void *hd) {
UPB_UNUSED(closure);
UPB_UNUSED(hd);
return true;
}
Update upb amalgamation.
10 years ago
/* Public API *****************************************************************/
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
void upb_json_parser_init(upb_json_parser *p, upb_status *status) {
p->limit = p->stack + UPB_JSON_MAX_DEPTH;
Update upb amalgamation.
10 years ago
p->accumulate_buf = NULL;
p->accumulate_buf_size = 0;
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upb_byteshandler_init(&p->input_handler_);
upb_byteshandler_setstring(&p->input_handler_, parse, NULL);
upb_byteshandler_setendstr(&p->input_handler_, end, NULL);
upb_bytessink_reset(&p->input_, &p->input_handler_, p);
p->status = status;
}
void upb_json_parser_uninit(upb_json_parser *p) {
upb_byteshandler_uninit(&p->input_handler_);
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free(p->accumulate_buf);
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}
void upb_json_parser_reset(upb_json_parser *p) {
p->top = p->stack;
p->top->f = NULL;
int cs;
int top;
// Emit Ragel initialization of the parser.
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#line 1236 "upb/json/parser.c"
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{
cs = json_start;
top = 0;
}
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#line 975 "upb/json/parser.rl"
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p->current_state = cs;
p->parser_top = top;
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accumulate_clear(p);
p->multipart_state = MULTIPART_INACTIVE;
p->capture = NULL;
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
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}
void upb_json_parser_resetoutput(upb_json_parser *p, upb_sink *sink) {
upb_json_parser_reset(p);
upb_sink_reset(&p->top->sink, sink->handlers, sink->closure);
p->top->m = upb_handlers_msgdef(sink->handlers);
p->accumulated = NULL;
}
upb_bytessink *upb_json_parser_input(upb_json_parser *p) {
return &p->input_;
}
/*
* upb - a minimalist implementation of protocol buffers.
*
* Copyright (c) 2014 Google Inc. See LICENSE for details.
* Author: Josh Haberman <jhaberman@gmail.com>
*
* This currently uses snprintf() to format primitives, and could be optimized
* further.
*/
#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#include <stdint.h>
// StringPiece; a pointer plus a length.
typedef struct {
const char *ptr;
size_t len;
} strpc;
strpc *newstrpc(upb_handlers *h, const upb_fielddef *f) {
strpc *ret = malloc(sizeof(*ret));
ret->ptr = upb_fielddef_name(f);
ret->len = strlen(ret->ptr);
upb_handlers_addcleanup(h, ret, free);
return ret;
}
// ------------ JSON string printing: values, maps, arrays --------------------
static void print_data(
upb_json_printer *p, const char *buf, unsigned int len) {
// TODO: Will need to change if we support pushback from the sink.
size_t n = upb_bytessink_putbuf(p->output_, p->subc_, buf, len, NULL);
UPB_ASSERT_VAR(n, n == len);
}
static void print_comma(upb_json_printer *p) {
if (!p->first_elem_[p->depth_]) {
print_data(p, ",", 1);
}
p->first_elem_[p->depth_] = false;
}
// Helpers that print properly formatted elements to the JSON output stream.
// Used for escaping control chars in strings.
static const char kControlCharLimit = 0x20;
static inline bool is_json_escaped(char c) {
// See RFC 4627.
unsigned char uc = (unsigned char)c;
return uc < kControlCharLimit || uc == '"' || uc == '\\';
}
static inline char* json_nice_escape(char c) {
switch (c) {
case '"': return "\\\"";
case '\\': return "\\\\";
case '\b': return "\\b";
case '\f': return "\\f";
case '\n': return "\\n";
case '\r': return "\\r";
case '\t': return "\\t";
default: return NULL;
}
}
// Write a properly escaped string chunk. The surrounding quotes are *not*
// printed; this is so that the caller has the option of emitting the string
// content in chunks.
static void putstring(upb_json_printer *p, const char *buf, unsigned int len) {
const char* unescaped_run = NULL;
for (unsigned int i = 0; i < len; i++) {
char c = buf[i];
// Handle escaping.
if (is_json_escaped(c)) {
// Use a "nice" escape, like \n, if one exists for this character.
const char* escape = json_nice_escape(c);
// If we don't have a specific 'nice' escape code, use a \uXXXX-style
// escape.
char escape_buf[8];
if (!escape) {
unsigned char byte = (unsigned char)c;
snprintf(escape_buf, sizeof(escape_buf), "\\u%04x", (int)byte);
escape = escape_buf;
}
// N.B. that we assume that the input encoding is equal to the output
// encoding (both UTF-8 for now), so for chars >= 0x20 and != \, ", we
// can simply pass the bytes through.
// If there's a current run of unescaped chars, print that run first.
if (unescaped_run) {
print_data(p, unescaped_run, &buf[i] - unescaped_run);
unescaped_run = NULL;
}
// Then print the escape code.
print_data(p, escape, strlen(escape));
} else {
// Add to the current unescaped run of characters.
if (unescaped_run == NULL) {
unescaped_run = &buf[i];
}
}
}
// If the string ended in a run of unescaped characters, print that last run.
if (unescaped_run) {
print_data(p, unescaped_run, &buf[len] - unescaped_run);
}
}
#define CHKLENGTH(x) if (!(x)) return -1;
// Helpers that format floating point values according to our custom formats.
// Right now we use %.8g and %.17g for float/double, respectively, to match
// proto2::util::JsonFormat's defaults. May want to change this later.
static size_t fmt_double(double val, char* buf, size_t length) {
size_t n = snprintf(buf, length, "%.17g", val);
CHKLENGTH(n > 0 && n < length);
return n;
}
static size_t fmt_float(float val, char* buf, size_t length) {
size_t n = snprintf(buf, length, "%.8g", val);
CHKLENGTH(n > 0 && n < length);
return n;
}
static size_t fmt_bool(bool val, char* buf, size_t length) {
size_t n = snprintf(buf, length, "%s", (val ? "true" : "false"));
CHKLENGTH(n > 0 && n < length);
return n;
}
static size_t fmt_int64(long val, char* buf, size_t length) {
size_t n = snprintf(buf, length, "%ld", val);
CHKLENGTH(n > 0 && n < length);
return n;
}
static size_t fmt_uint64(unsigned long long val, char* buf, size_t length) {
size_t n = snprintf(buf, length, "%llu", val);
CHKLENGTH(n > 0 && n < length);
return n;
}
// Print a map key given a field name. Called by scalar field handlers and by
// startseq for repeated fields.
static bool putkey(void *closure, const void *handler_data) {
upb_json_printer *p = closure;
const strpc *key = handler_data;
print_comma(p);
print_data(p, "\"", 1);
putstring(p, key->ptr, key->len);
print_data(p, "\":", 2);
return true;
}
#define CHKFMT(val) if ((val) == -1) return false;
#define CHK(val) if (!(val)) return false;
#define TYPE_HANDLERS(type, fmt_func) \
static bool put##type(void *closure, const void *handler_data, type val) { \
upb_json_printer *p = closure; \
UPB_UNUSED(handler_data); \
char data[64]; \
size_t length = fmt_func(val, data, sizeof(data)); \
CHKFMT(length); \
print_data(p, data, length); \
return true; \
} \
static bool scalar_##type(void *closure, const void *handler_data, \
type val) { \
CHK(putkey(closure, handler_data)); \
CHK(put##type(closure, handler_data, val)); \
return true; \
} \
static bool repeated_##type(void *closure, const void *handler_data, \
type val) { \
upb_json_printer *p = closure; \
print_comma(p); \
CHK(put##type(closure, handler_data, val)); \
return true; \
}
TYPE_HANDLERS(double, fmt_double);
TYPE_HANDLERS(float, fmt_float);
TYPE_HANDLERS(bool, fmt_bool);
TYPE_HANDLERS(int32_t, fmt_int64);
TYPE_HANDLERS(uint32_t, fmt_int64);
TYPE_HANDLERS(int64_t, fmt_int64);
TYPE_HANDLERS(uint64_t, fmt_uint64);
#undef TYPE_HANDLERS
typedef struct {
void *keyname;
const upb_enumdef *enumdef;
} EnumHandlerData;
static bool scalar_enum(void *closure, const void *handler_data,
int32_t val) {
const EnumHandlerData *hd = handler_data;
upb_json_printer *p = closure;
CHK(putkey(closure, hd->keyname));
const char *symbolic_name = upb_enumdef_iton(hd->enumdef, val);
if (symbolic_name) {
print_data(p, "\"", 1);
putstring(p, symbolic_name, strlen(symbolic_name));
print_data(p, "\"", 1);
} else {
putint32_t(closure, NULL, val);
}
return true;
}
static bool repeated_enum(void *closure, const void *handler_data,
int32_t val) {
const EnumHandlerData *hd = handler_data;
upb_json_printer *p = closure;
print_comma(p);
const char *symbolic_name = upb_enumdef_iton(hd->enumdef, val);
if (symbolic_name) {
print_data(p, "\"", 1);
putstring(p, symbolic_name, strlen(symbolic_name));
print_data(p, "\"", 1);
} else {
putint32_t(closure, NULL, val);
}
return true;
}
static void *scalar_startsubmsg(void *closure, const void *handler_data) {
return putkey(closure, handler_data) ? closure : UPB_BREAK;
}
static void *repeated_startsubmsg(void *closure, const void *handler_data) {
UPB_UNUSED(handler_data);
upb_json_printer *p = closure;
print_comma(p);
return closure;
}
static bool startmap(void *closure, const void *handler_data) {
UPB_UNUSED(handler_data);
upb_json_printer *p = closure;
if (p->depth_++ == 0) {
upb_bytessink_start(p->output_, 0, &p->subc_);
}
p->first_elem_[p->depth_] = true;
print_data(p, "{", 1);
return true;
}
static bool endmap(void *closure, const void *handler_data, upb_status *s) {
UPB_UNUSED(handler_data);
UPB_UNUSED(s);
upb_json_printer *p = closure;
if (--p->depth_ == 0) {
upb_bytessink_end(p->output_);
}
print_data(p, "}", 1);
return true;
}
static void *startseq(void *closure, const void *handler_data) {
upb_json_printer *p = closure;
CHK(putkey(closure, handler_data));
p->depth_++;
p->first_elem_[p->depth_] = true;
print_data(p, "[", 1);
return closure;
}
static bool endseq(void *closure, const void *handler_data) {
UPB_UNUSED(handler_data);
upb_json_printer *p = closure;
print_data(p, "]", 1);
p->depth_--;
return true;
}
static size_t putstr(void *closure, const void *handler_data, const char *str,
size_t len, const upb_bufhandle *handle) {
UPB_UNUSED(handler_data);
UPB_UNUSED(handle);
upb_json_printer *p = closure;
putstring(p, str, len);
return len;
}
// This has to Base64 encode the bytes, because JSON has no "bytes" type.
static size_t putbytes(void *closure, const void *handler_data, const char *str,
size_t len, const upb_bufhandle *handle) {
UPB_UNUSED(handler_data);
UPB_UNUSED(handle);
upb_json_printer *p = closure;
// This is the regular base64, not the "web-safe" version.
static const char base64[] =
"ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789+/";
// Base64-encode.
char data[16000];
const char *limit = data + sizeof(data);
const unsigned char *from = (const unsigned char*)str;
char *to = data;
size_t remaining = len;
while (remaining > 2) {
// TODO(haberman): handle encoded lengths > sizeof(data)
UPB_ASSERT_VAR(limit, (limit - to) >= 4);
to[0] = base64[from[0] >> 2];
to[1] = base64[((from[0] & 0x3) << 4) | (from[1] >> 4)];
to[2] = base64[((from[1] & 0xf) << 2) | (from[2] >> 6)];
to[3] = base64[from[2] & 0x3f];
remaining -= 3;
to += 4;
from += 3;
}
switch (remaining) {
case 2:
to[0] = base64[from[0] >> 2];
to[1] = base64[((from[0] & 0x3) << 4) | (from[1] >> 4)];
to[2] = base64[(from[1] & 0xf) << 2];
to[3] = '=';
to += 4;
from += 2;
break;
case 1:
to[0] = base64[from[0] >> 2];
to[1] = base64[((from[0] & 0x3) << 4)];
to[2] = '=';
to[3] = '=';
to += 4;
from += 1;
break;
}
size_t bytes = to - data;
print_data(p, "\"", 1);
putstring(p, data, bytes);
print_data(p, "\"", 1);
return len;
}
static void *scalar_startstr(void *closure, const void *handler_data,
size_t size_hint) {
UPB_UNUSED(handler_data);
UPB_UNUSED(size_hint);
upb_json_printer *p = closure;
CHK(putkey(closure, handler_data));
print_data(p, "\"", 1);
return p;
}
static size_t scalar_str(void *closure, const void *handler_data,
const char *str, size_t len,
const upb_bufhandle *handle) {
CHK(putstr(closure, handler_data, str, len, handle));
return len;
}
static bool scalar_endstr(void *closure, const void *handler_data) {
UPB_UNUSED(handler_data);
upb_json_printer *p = closure;
print_data(p, "\"", 1);
return true;
}
static void *repeated_startstr(void *closure, const void *handler_data,
size_t size_hint) {
UPB_UNUSED(handler_data);
UPB_UNUSED(size_hint);
upb_json_printer *p = closure;
print_comma(p);
print_data(p, "\"", 1);
return p;
}
static size_t repeated_str(void *closure, const void *handler_data,
const char *str, size_t len,
const upb_bufhandle *handle) {
CHK(putstr(closure, handler_data, str, len, handle));
return len;
}
static bool repeated_endstr(void *closure, const void *handler_data) {
UPB_UNUSED(handler_data);
upb_json_printer *p = closure;
print_data(p, "\"", 1);
return true;
}
static size_t scalar_bytes(void *closure, const void *handler_data,
const char *str, size_t len,
const upb_bufhandle *handle) {
CHK(putkey(closure, handler_data));
CHK(putbytes(closure, handler_data, str, len, handle));
return len;
}
static size_t repeated_bytes(void *closure, const void *handler_data,
const char *str, size_t len,
const upb_bufhandle *handle) {
upb_json_printer *p = closure;
print_comma(p);
CHK(putbytes(closure, handler_data, str, len, handle));
return len;
}
void printer_sethandlers(const void *closure, upb_handlers *h) {
UPB_UNUSED(closure);
upb_handlerattr empty_attr = UPB_HANDLERATTR_INITIALIZER;
upb_handlers_setstartmsg(h, startmap, &empty_attr);
upb_handlers_setendmsg(h, endmap, &empty_attr);
#define TYPE(type, name, ctype) \
case type: \
if (upb_fielddef_isseq(f)) { \
upb_handlers_set##name(h, f, repeated_##ctype, &empty_attr); \
} else { \
upb_handlers_set##name(h, f, scalar_##ctype, &name_attr); \
} \
break;
Support oneofs in MRI Ruby C extension.
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upb_msg_field_iter i;
upb_msg_field_begin(&i, upb_handlers_msgdef(h));
for(; !upb_msg_field_done(&i); upb_msg_field_next(&i)) {
Rename protobuf Ruby module to google/protobuf and rework its build system. The Ruby module build now uses an amalgamated distribution of upb, and successfully builds a Ruby gem called 'google-protobuf' with module 'google/protobuf'.
10 years ago
const upb_fielddef *f = upb_msg_iter_field(&i);
upb_handlerattr name_attr = UPB_HANDLERATTR_INITIALIZER;
upb_handlerattr_sethandlerdata(&name_attr, newstrpc(h, f));
if (upb_fielddef_isseq(f)) {
upb_handlers_setstartseq(h, f, startseq, &name_attr);
upb_handlers_setendseq(h, f, endseq, &empty_attr);
}
switch (upb_fielddef_type(f)) {
TYPE(UPB_TYPE_FLOAT, float, float);
TYPE(UPB_TYPE_DOUBLE, double, double);
TYPE(UPB_TYPE_BOOL, bool, bool);
TYPE(UPB_TYPE_INT32, int32, int32_t);
TYPE(UPB_TYPE_UINT32, uint32, uint32_t);
TYPE(UPB_TYPE_INT64, int64, int64_t);
TYPE(UPB_TYPE_UINT64, uint64, uint64_t);
case UPB_TYPE_ENUM: {
// For now, we always emit symbolic names for enums. We may want an
// option later to control this behavior, but we will wait for a real
// need first.
EnumHandlerData *hd = malloc(sizeof(EnumHandlerData));
hd->enumdef = (const upb_enumdef *)upb_fielddef_subdef(f);
hd->keyname = newstrpc(h, f);
upb_handlers_addcleanup(h, hd, free);
upb_handlerattr enum_attr = UPB_HANDLERATTR_INITIALIZER;
upb_handlerattr_sethandlerdata(&enum_attr, hd);
if (upb_fielddef_isseq(f)) {
upb_handlers_setint32(h, f, repeated_enum, &enum_attr);
} else {
upb_handlers_setint32(h, f, scalar_enum, &enum_attr);
}
upb_handlerattr_uninit(&enum_attr);
break;
}
case UPB_TYPE_STRING:
if (upb_fielddef_isseq(f)) {
upb_handlers_setstartstr(h, f, repeated_startstr, &empty_attr);
upb_handlers_setstring(h, f, repeated_str, &empty_attr);
upb_handlers_setendstr(h, f, repeated_endstr, &empty_attr);
} else {
upb_handlers_setstartstr(h, f, scalar_startstr, &name_attr);
upb_handlers_setstring(h, f, scalar_str, &empty_attr);
upb_handlers_setendstr(h, f, scalar_endstr, &empty_attr);
}
break;
case UPB_TYPE_BYTES:
// XXX: this doesn't support strings that span buffers yet. The base64
// encoder will need to be made resumable for this to work properly.
if (upb_fielddef_isseq(f)) {
upb_handlers_setstring(h, f, repeated_bytes, &empty_attr);
} else {
upb_handlers_setstring(h, f, scalar_bytes, &name_attr);
}
break;
case UPB_TYPE_MESSAGE:
if (upb_fielddef_isseq(f)) {
upb_handlers_setstartsubmsg(h, f, repeated_startsubmsg, &name_attr);
} else {
upb_handlers_setstartsubmsg(h, f, scalar_startsubmsg, &name_attr);
}
break;
}
upb_handlerattr_uninit(&name_attr);
}
upb_handlerattr_uninit(&empty_attr);
#undef TYPE
}
/* Public API *****************************************************************/
void upb_json_printer_init(upb_json_printer *p, const upb_handlers *h) {
p->output_ = NULL;
p->depth_ = 0;
upb_sink_reset(&p->input_, h, p);
}
void upb_json_printer_uninit(upb_json_printer *p) {
UPB_UNUSED(p);
}
void upb_json_printer_reset(upb_json_printer *p) {
p->depth_ = 0;
}
void upb_json_printer_resetoutput(upb_json_printer *p, upb_bytessink *output) {
upb_json_printer_reset(p);
p->output_ = output;
}
upb_sink *upb_json_printer_input(upb_json_printer *p) {
return &p->input_;
}
const upb_handlers *upb_json_printer_newhandlers(const upb_msgdef *md,
const void *owner) {
return upb_handlers_newfrozen(md, owner, printer_sethandlers, NULL);
}