Decoder code structure is mostly in-place.

pull/13171/head
Joshua Haberman 14 years ago
parent 5511aa16b0
commit 58a70b55c6
  1. 20
      core/upb_stream.h
  2. 57
      core/upb_string.h
  3. 333
      stream/upb_decoder.c

@ -171,14 +171,18 @@ INLINE void upb_src_run(upb_src *src, upb_status *status);
/* upb_bytesrc ****************************************************************/
// Reads up to "count" bytes into "buf", returning the total number of bytes
// read. If <0, indicates error (check upb_bytesrc_status for details).
// read. If 0, indicates error and puts details in "status".
INLINE upb_strlen_t upb_bytesrc_read(upb_bytesrc *src, void *buf,
upb_strlen_t count);
upb_strlen_t count, upb_status *status);
// Like upb_bytesrc_read(), but modifies "str" in-place, possibly aliasing
// existing string data (which avoids a copy).
// existing string data (which avoids a copy). On the other hand, if
// the data was *not* already in an existing string, this copies it into
// a upb_string, and if the data needs to be put in a specific range of
// memory (because eg. you need to put it into a different kind of string
// object) then upb_bytesrc_get() could be better.
INLINE bool upb_bytesrc_getstr(upb_bytesrc *src, upb_string *str,
upb_strlen_t count);
upb_status *status);
// A convenience function for getting all the remaining data in a upb_bytesrc
// as a upb_string. Returns false and sets "status" if the operation fails.
@ -189,14 +193,6 @@ INLINE bool upb_value_getfullstr(upb_value val, upb_string *str,
return upb_bytesrc_getfullstr(upb_value_getbytesrc(val), str, status);
}
// Returns the current error status for the stream.
// Note! The "eof" flag works like feof() in C; it cannot report end-of-file
// until a read has failed due to eof. It cannot preemptively tell you that
// the next call will fail due to eof. Since these are the semantics that C
// and UNIX provide, we're stuck with them if we want to support eg. stdio.
INLINE upb_status *upb_bytesrc_status(upb_bytesrc *src);
INLINE bool upb_bytesrc_eof(upb_bytesrc *src);
/* upb_bytesink ***************************************************************/

@ -3,26 +3,39 @@
*
* Copyright (c) 2010 Joshua Haberman. See LICENSE for details.
*
* This file defines a simple string type. The overriding goal of upb_string
* is to avoid memcpy(), malloc(), and free() wheverever possible, while
* keeping both CPU and memory overhead low. Throughout upb there are
* situations where one wants to reference all or part of another string
* without copying. upb_string provides APIs for doing this.
* This file defines a simple string type which is length-delimited instead
* of NULL-terminated, and which has useful sharing semantics.
*
* The overriding goal of upb_string is to avoid memcpy(), malloc(), and free()
* wheverever possible, while keeping both CPU and memory overhead low.
* Throughout upb there are situations where one wants to reference all or part
* of another string without copying. upb_string provides APIs for doing this.
*
* Characteristics of upb_string:
* - strings are reference-counted.
* - strings are logically immutable.
* - strings are immutable (can be mutated only when first created or recycled).
* - if a string has no other referents, it can be "recycled" into a new string
* without having to reallocate the upb_string.
* - strings can be substrings of other strings (owning a ref on the source
* string).
* - strings are not thread-safe by default, but can be made so by calling a
* function. This is not the default because it causes extra CPU overhead.
*
* Reference-counted strings have recently fallen out of favor because of the
* performance impacts of doing thread-safe reference counting with atomic
* operations. We side-step this issue by not performing atomic operations
* unless the string has been marked thread-safe.
*
* Strings are expected to be 8-bit-clean, but "char*" is such an entrenched
* idiom that we go with it instead of making our pointers uint8_t*.
*
* WARNING: THE GETREF, UNREF, AND RECYCLE OPERATIONS ARE NOT THREAD_SAFE
* UNLESS THE STRING HAS BEEN MARKED SYNCHRONIZED! What this means is that if
* you are logically passing a reference to a upb_string to another thread
* (which implies that the other thread must eventually call unref of recycle),
* you have two options:
*
* - create a copy of the string that will be used in the other thread only.
* - call upb_string_get_synchronized_ref(), which will make getref, unref, and
* recycle thread-safe for this upb_string.
*/
#ifndef UPB_STRING_H
@ -83,10 +96,12 @@ struct _upb_string {
// longer needed, it should be unref'd, never freed directly.
upb_string *upb_string_new();
// Internal-only; clients should call upb_string_unref().
void _upb_string_free(upb_string *str);
// Releases a ref on the given string, which may free the memory. "str"
// can be NULL, in which case this is a no-op.
// can be NULL, in which case this is a no-op. WARNING: NOT THREAD_SAFE
// UNLESS THE STRING IS SYNCHRONIZED.
INLINE void upb_string_unref(upb_string *str) {
if (str && upb_atomic_read(&str->refcount) > 0 &&
upb_atomic_unref(&str->refcount)) {
@ -98,6 +113,7 @@ upb_string *upb_strdup(upb_string *s); // Forward-declare.
// Returns a string with the same contents as "str". The caller owns a ref on
// the returned string, which may or may not be the same object as "str.
// WARNING: NOT THREAD-SAFE UNLESS THE STRING IS SYNCHRONIZED!
INLINE upb_string *upb_string_getref(upb_string *str) {
int refcount = upb_atomic_read(&str->refcount);
if (refcount == _UPB_STRING_REFCOUNT_STACK) return upb_strdup(str);
@ -163,8 +179,11 @@ void upb_string_substr(upb_string *str, upb_string *target_str,
// data. Waiting for a clear use case before actually implementing it.
//
// Makes the string "str" a reference to the given string data. The caller
// guarantees that the given string data will not change or be deleted until
// a matching call to upb_string_detach().
// guarantees that the given string data will not change or be deleted until a
// matching call to upb_string_detach(), which may block until any concurrent
// readers have finished reading. upb_string_detach() preserves the contents
// of the string by copying the referenced data if there are any other
// referents.
// void upb_string_attach(upb_string *str, char *ptr, upb_strlen_t len);
// void upb_string_detach(upb_string *str);
@ -207,6 +226,22 @@ void upb_string_substr(upb_string *str, upb_string *target_str,
_UPB_STRING_INIT(str, sizeof(str)-1, _UPB_STRING_REFCOUNT_STACK)
#define UPB_STACK_STRING_LEN(str, len) \
_UPB_STRING_INIT(str, len, _UPB_STRING_REFCOUNT_STACK)
// A convenient way of specifying upb_strings as literals, like:
//
// upb_streql(UPB_STRLIT("expected"), other_str);
//
// However, this requires either C99 compound initializers or C++.
// Must ONLY be called with a string literal as its argument!
//#ifdef __cplusplus
//namespace upb {
//class String : public upb_string {
// // This constructor must ONLY be called with a string literal.
// String(const char *str) : upb_string(UPB_STATIC_STRING(str)) {}
//};
//}
//#define UPB_STRLIT(str) upb::String(str)
//#endif
#define UPB_STRLIT(str) &(upb_string)UPB_STATIC_STRING(str)
/* upb_string library functions ***********************************************/

@ -11,127 +11,39 @@
#include <stdlib.h>
#include "upb_def.h"
/* Functions to read wire values. *********************************************/
/* Pure Decoding **************************************************************/
// These functions are internal to the decode, but might be moved into an
// internal header file if we at some point in the future opt to do code
// generation, because the generated code would want to inline these functions.
// The same applies to the functions to read .proto values below.
const uint8_t *upb_get_v_uint64_t_full(const uint8_t *buf, const uint8_t *end,
uint64_t *val, upb_status *status);
// Gets a varint (wire type: UPB_WIRE_TYPE_VARINT).
INLINE const uint8_t *upb_get_v_uint64_t(const uint8_t *buf, const uint8_t *end,
uint64_t *val, upb_status *status)
{
// We inline this common case (1-byte varints), if that fails we dispatch to
// the full (non-inlined) version.
if((*buf & 0x80) == 0) {
*val = *buf & 0x7f;
return buf + 1;
} else {
return upb_get_v_uint64_t_full(buf, end, val, status);
}
}
// Gets a varint -- called when we only need 32 bits of it. Note that a 32-bit
// varint is not a true wire type.
INLINE const uint8_t *upb_get_v_uint32_t(const uint8_t *buf, const uint8_t *end,
uint32_t *val, upb_status *status)
{
uint64_t val64;
const uint8_t *ret = upb_get_v_uint64_t(buf, end, &val64, status);
*val = (uint32_t)val64; // Discard the high bits.
return ret;
}
// Gets a fixed-length 32-bit integer (wire type: UPB_WIRE_TYPE_32BIT).
INLINE const uint8_t *upb_get_f_uint32_t(const uint8_t *buf, const uint8_t *end,
uint32_t *val, upb_status *status)
{
const uint8_t *uint32_end = buf + sizeof(uint32_t);
if(uint32_end > end) {
status->code = UPB_STATUS_NEED_MORE_DATA;
return end;
}
memcpy(val, buf, sizeof(uint32_t));
return uint32_end;
}
// Gets a fixed-length 64-bit integer (wire type: UPB_WIRE_TYPE_64BIT).
INLINE const uint8_t *upb_get_f_uint64_t(const uint8_t *buf, const uint8_t *end,
uint64_t *val, upb_status *status)
{
const uint8_t *uint64_end = buf + sizeof(uint64_t);
if(uint64_end > end) {
status->code = UPB_STATUS_NEED_MORE_DATA;
return end;
}
memcpy(val, buf, sizeof(uint64_t));
return uint64_end;
}
INLINE const uint8_t *upb_skip_v_uint64_t(const uint8_t *buf,
const uint8_t *end,
upb_status *status)
{
const uint8_t *const maxend = buf + 10;
uint8_t last = 0x80;
for(; buf < (uint8_t*)end && (last & 0x80); buf++)
last = *buf;
if(buf >= end && buf <= maxend && (last & 0x80)) {
status->code = UPB_STATUS_NEED_MORE_DATA;
buf = end;
} else if(buf > maxend) {
status->code = UPB_ERROR_UNTERMINATED_VARINT;
buf = end;
}
return buf;
}
// The key fast-path varint-decoding routine. There are a lot of possibilities
// for optimization/experimentation here.
INLINE bool upb_decode_varint_fast(uint8_t **buf, uint8_t *end, uint64_t &val,
upb_status *status) {
*high = 0;
uint32_t b;
uint8_t *ptr = p->ptr;
b = *(*buf++); *low = (b & 0x7f) ; if(!(b & 0x80)) goto done;
b = *(*buf++); *low |= (b & 0x7f) << 7; if(!(b & 0x80)) goto done;
b = *(*buf++); *low |= (b & 0x7f) << 14; if(!(b & 0x80)) goto done;
b = *(*buf++); *low |= (b & 0x7f) << 21; if(!(b & 0x80)) goto done;
b = *(*buf++); *low |= (b & 0x7f) << 28;
*high = (b & 0x7f) >> 3; if(!(b & 0x80)) goto done;
b = *(*buf++); *high |= (b & 0x7f) << 4; if(!(b & 0x80)) goto done;
b = *(*buf++); *high |= (b & 0x7f) << 11; if(!(b & 0x80)) goto done;
b = *(*buf++); *high |= (b & 0x7f) << 18; if(!(b & 0x80)) goto done;
b = *(*buf++); *high |= (b & 0x7f) << 25; if(!(b & 0x80)) goto done;
INLINE const uint8_t *upb_skip_f_uint32_t(const uint8_t *buf,
const uint8_t *end,
upb_status *status)
{
const uint8_t *uint32_end = buf + sizeof(uint32_t);
if(uint32_end > end) {
status->code = UPB_STATUS_NEED_MORE_DATA;
return end;
}
return uint32_end;
upb_seterr(status, UPB_ERROR, "Unterminated varint");
return false;
done:
return true;
}
INLINE const uint8_t *upb_skip_f_uint64_t(const uint8_t *buf,
const uint8_t *end,
upb_status *status)
{
const uint8_t *uint64_end = buf + sizeof(uint64_t);
if(uint64_end > end) {
status->code = UPB_STATUS_NEED_MORE_DATA;
return end;
}
return uint64_end;
}
/* Functions to read .proto values. *******************************************/
/* Decoding/Buffering of individual values ************************************/
// Performs zig-zag decoding, which is used by sint32 and sint64.
INLINE int32_t upb_zzdec_32(uint32_t n) { return (n >> 1) ^ -(int32_t)(n & 1); }
INLINE int64_t upb_zzdec_64(uint64_t n) { return (n >> 1) ^ -(int64_t)(n & 1); }
// Parses a tag, places the result in *tag.
INLINE const uint8_t *decode_tag(const uint8_t *buf, const uint8_t *end,
upb_tag *tag, upb_status *status)
{
uint32_t tag_int;
const uint8_t *ret = upb_get_v_uint32_t(buf, end, &tag_int, status);
tag->wire_type = (upb_wire_type_t)(tag_int & 0x07);
tag->field_number = tag_int >> 3;
return ret;
}
// The decoder keeps a stack with one entry per level of recursion.
// upb_decoder_frame is one frame of that stack.
typedef struct {
@ -144,6 +56,7 @@ struct upb_decoder {
// Immutable state of the decoder.
upb_src src;
upb_dispatcher dispatcher;
upb_bytesrc *bytesrc;
upb_msgdef *toplevel_msgdef;
upb_decoder_frame stack[UPB_MAX_NESTING];
@ -158,50 +71,33 @@ struct upb_decoder {
// Current input buffer.
upb_string *buf;
// The offset within the overall stream represented by the *beginning* of buf.
upb_strlen_t buf_stream_offset;
// Our current offset *within* buf. Will be negative if we are buffering
// from previous buffers in tmpbuf.
// Our current offset *within* buf.
upb_strlen_t buf_offset;
// Holds any bytes we have from previous buffers. The number of bytes we
// have encoded here is -buf_offset, if buf_offset<0, 0 otherwise.
uint8_t tmpbuf[UPB_MAX_ENCODED_SIZE];
// The offset within the overall stream represented by the *beginning* of buf.
upb_strlen_t buf_stream_offset;
};
upb_flow_t upb_decode_varint(upb_decoder *d, ptrs *p,
uint32_t *low, uint32_t *high) {
if (p->end - p->ptr > UPB_MAX_ENCODED_SIZE) {
// Fast path; we know we have a complete varint in our existing buffer.
*high = 0;
uint32_t b;
uint8_t *ptr = p->ptr;
b = *(buf++); *low = (b & 0x7f) ; if(!(b & 0x80)) goto done;
b = *(buf++); *low |= (b & 0x7f) << 7; if(!(b & 0x80)) goto done;
b = *(buf++); *low |= (b & 0x7f) << 14; if(!(b & 0x80)) goto done;
b = *(buf++); *low |= (b & 0x7f) << 21; if(!(b & 0x80)) goto done;
b = *(buf++); *low |= (b & 0x7f) << 28;
*high = (b & 0x7f) >> 3; if(!(b & 0x80)) goto done;
b = *(buf++); *high |= (b & 0x7f) << 4; if(!(b & 0x80)) goto done;
b = *(buf++); *high |= (b & 0x7f) << 11; if(!(b & 0x80)) goto done;
b = *(buf++); *high |= (b & 0x7f) << 18; if(!(b & 0x80)) goto done;
b = *(buf++); *high |= (b & 0x7f) << 25; if(!(b & 0x80)) goto done;
if(bytes_available >= 10) {
upb_seterr(&d->src.status, UPB_STATUS_ERROR, "Varint was unterminated "
"after 10 bytes, stream offset: %u", upb_decoder_offset(d));
return false;
// Called only from the slow path, this function copies the next "len" bytes
// from the stream to "data", adjusting "buf" and "end" appropriately.
INLINE bool upb_getbuf(upb_decoder *d, void *data, size_t len,
uint8_t **buf, uint8_t **end) {
while (len > 0) {
memcpy(data, *buf, *end-*buf);
len -= (*end-*buf);
if (!upb_bytesrc_getstr(d->bytesrc, d->buf, d->status)) return false;
*buf = upb_string_getrobuf(d->buf);
*end = *buf + upb_string_len(d->buf);
}
}
done:
p->ptr = ptr;
} else {
// Slow path: we may have to combine one or more buffers to get a whole
// varint worth of data.
// We use this path when we don't have UPB_MAX_ENCODED_SIZE contiguous bytes
// available in our current buffer. We don't inline this because we accept
// that it will be slow and we don't want to pay for two copies of it.
static bool upb_decode_varint_slow(upb_decoder *d) {
uint8_t buf[UPB_MAX_ENCODED_SIZE];
uint8_t *p = buf, *end = buf + sizeof(buf);
for(ing bitpos = 0; p < end && getbyte(d, p) && (last & 0x80); p++, bitpos += 7)
for(int bitpos = 0; p < end && getbyte(d, p) && (last & 0x80); p++, bitpos += 7)
*val |= ((uint64_t)((last = *p) & 0x7F)) << bitpos;
if(d->status->code == UPB_EOF && (last & 0x80)) {
@ -214,10 +110,69 @@ upb_flow_t upb_decode_varint(upb_decoder *d, ptrs *p,
// Success.
return;
}
ungetbytes(d, buf, p - buf);
}
INLINE bool upb_decode_tag(upb_decoder *d, const uint8_t **_buf,
const uint8_t **end, upb_tag *tag) {
const uint8_t *buf = *_buf, *end = *_end;
uint32_t tag_int;
// Nearly all tag varints will be either 1 byte (1-16) or 2 bytes (17-2048).
if (end - buf < 2) goto slow; // unlikely.
tag_int = *buf & 0x7f;
if ((*(buf++) & 0x80) == 0) goto done; // predictable if fields are in order
tag_int |= (*buf & 0x7f) << 7;
if ((*(buf++) & 0x80) != 0) goto slow; // unlikely.
slow:
if (!upb_decode_varint_slow(d, _buf, _end)) return false;
buf = *_buf; // Trick the next line into not overwriting us.
done:
*_buf = buf;
tag->wire_type = (upb_wire_type_t)(tag_int & 0x07);
tag->field_number = tag_int >> 3;
return true;
}
INLINE bool upb_decode_varint(upb_decoder *d, ptrs *p,
uint32_t *low, uint32_t *high) {
if (p->end - p->ptr >= UPB_MAX_VARINT_ENCODED_SIZE)
return upb_decode_varint_fast(d);
else
return upb_decode_varint_slow(d);
}
INLINE bool upb_decode_fixed(upb_decoder *d, upb_wire_type_t wt,
uint8_t **buf, uint8_t **end, upb_value *val) {
static const char table = {0, 8, 0, 0, 0, 4};
size_t bytes = table[wt];
if (*end - *buf >= bytes) {
// Common (fast) case.
memcpy(&val, *buf, bytes);
*buf += bytes;
} else {
if (!upb_getbuf(d, &val, bytes, buf, end)) return false;
}
return true;
}
// "val" initially holds the length of the string, this is replaced by the
// contents of the string.
INLINE bool upb_decode_string(upb_decoder *d, upb_value *val, upb_string **str) {
upb_string_recycle(str);
upb_strlen_t len = upb_valu_getint32(*val);
if (*end - *buf >= len) {
// Common (fast) case.
upb_string_substr(*str, d->buf, *buf - upb_string_getrobuf(d->buf), len);
*buf += len;
} else {
if (!upb_getbuf(d, upb_string_getrwbuf(*str, len), len, buf, end))
return false;
}
return true;
}
/* The main decoding loop *****************************************************/
static const void *get_msgend(upb_decoder *d)
{
if(d->top->end_offset > 0)
@ -238,36 +193,29 @@ INLINE bool upb_check_type(upb_wire_type_t wt, upb_field_type_t ft) {
return upb_types[ft].expected_wire_type == wt;
}
// Pushes a new stack frame for a submessage with the given len (which will
// be zero if the submessage is a group).
static const uint8_t *push(upb_decoder *d, const uint8_t *start,
static bool upb_push(upb_decoder *d, const uint8_t *start,
uint32_t submsg_len, upb_fielddef *f,
upb_status *status)
{
d->top->field = f;
d->top++;
if(d->top >= d->limit) {
upb_seterr(status, UPB_ERROR_MAX_NESTING_EXCEEDED,
"Nesting exceeded maximum (%d levels)\n",
UPB_MAX_NESTING);
return NULL;
upb_seterr(status, UPB_ERROR, "Nesting too deep.");
return false;
}
upb_decoder_frame *frame = d->top;
frame->end_offset = d->completed_offset + submsg_len;
frame->msgdef = upb_downcast_msgdef(f->def);
upb_dispatch_startsubmsg(&d->dispatcher, f);
return get_msgend(d);
d->top->end_offset = d->completed_offset + submsg_len;
d->top->msgdef = upb_downcast_msgdef(f->def);
*submsg_end = get_msgend(d);
if (!upb_dispatch_startsubmsg(&d->dispatcher, f)) return false;
return true;
}
// Pops a stack frame, returning a pointer for where the next submsg should
// end (or a pointer that is out of range for a group).
static const void *pop(upb_decoder *d, const uint8_t *start, upb_status *status)
static bool upb_pop(upb_decoder *d, const uint8_t *start, upb_status *status)
{
d->top--;
upb_dispatch_endsubmsg(&d->dispatcher);
return get_msgend(d);
*submsg_end = get_msgend(d);
return true;
}
void upb_decoder_run(upb_src *src, upb_status *status) {
@ -278,11 +226,13 @@ void upb_decoder_run(upb_src *src, upb_status *status) {
upb_msgdef *msgdef = d->top->msgdef;
upb_string *str = NULL;
upb_dispatch_startmsg(&d->dispatcher);
// Main loop: executed once per tag/field pair.
while(1) {
// Parse/handle tag.
upb_tag tag;
CHECK(decode_tag(d, &buf, &end, &tag));
CHECK(upb_decode_tag(d, &buf, &end, &tag));
// Decode wire data. Hopefully this branch will predict pretty well
// since most types will read a varint here.
@ -290,24 +240,19 @@ void upb_decoder_run(upb_src *src, upb_status *status) {
switch (tag.wire_type) {
case UPB_WIRE_TYPE_END_GROUP:
if(!isgroup(submsg_end)) {
upb_seterr(status, UPB_STATUS_ERROR, "End group seen but current "
"message is not a group, byte offset: %zd",
d->completed_offset + (completed - start));
upb_seterr(status, UPB_ERROR, "Unexpected END_GROUP tag.");
goto err;
}
submsg_end = pop(d, start, status, &msgdef);
completed = buf;
goto check_msgend;
CHECK(upb_pop(d, start, status, &msgdef, &submsg_end));
goto check_msgend; // We have no value to dispatch.
case UPB_WIRE_TYPE_VARINT:
case UPB_WIRE_TYPE_DELIMITED:
// For the delimited case we are parsing the length.
CHECK(upb_decode_varint(d, &buf, &end, &val));
break;
case UPB_WIRE_TYPE_32BIT:
CHECK(upb_decode_32bit(d, &buf, &end, &val));
break;
case UPB_WIRE_TYPE_64BIT:
CHECK(upb_decode_64bit(d, &buf, &end, &val));
CHECK(upb_decode_fixed(d, tag.wire_type, &buf, &end, &val));
break;
}
@ -315,24 +260,31 @@ void upb_decoder_run(upb_src *src, upb_status *status) {
upb_fielddef *f = upb_msg_itof(msgdef, tag.field_number);
if (!f) {
// Unknown field.
if (tag.wire_type == UPB_WIRE_TYPE_DELIMITED)
CHECK(upb_decode_string(d, &val, &str));
CHECK(upb_dispatch_unknownval(d, tag.field_number, val));
} else if (!upb_check_type(tag.wire_type, f->type)) {
// Field has incorrect type.
// TODO: put more details in this error msg.
upb_seterr(status, UPB_ERROR, "Field had incorrect type.");
goto err;
}
// Perform any further massaging of the data now that we have the fielddef.
// Now we can distinguish strings from submessages, and we know about
// zig-zag-encoded types.
// TODO: handle packed encoding.
// TODO: if we were being paranoid, we could check for 32-bit-varint types
// that the top 32 bits all match the highest bit of the low 32 bits.
// If this is not true we are losing data. But the main protobuf library
// doesn't check this, and it would slow us down, so pass for now.
switch (f->type) {
case UPB_TYPE(MESSAGE):
case UPB_TYPE(GROUP):
CHECK(push(d, start, upb_value_getint32(val), f, status, &msgdef));
goto check_msgend;
CHECK(upb_push(d, start, upb_value_getint32(val), f, status, &msgdef));
goto check_msgend; // We have no value to dispatch.
case UPB_TYPE(STRING):
case UPB_TYPE(BYTES):
CHECK(upb_decode_string(d, str, upb_value_getint32(val)));
upb_value_setstr(&val, str);
CHECK(upb_decode_string(d, &val, &str));
break;
case UPB_TYPE(SINT32):
upb_value_setint32(&val, upb_zzdec_32(upb_value_getint32(val)));
@ -341,26 +293,27 @@ void upb_decoder_run(upb_src *src, upb_status *status) {
upb_value_setint64(&val, upb_zzdec_64(upb_value_getint64(val)));
break;
default:
// Other types need no further processing at this point.
break; // Other types need no further processing at this point.
}
CHECK(upb_dispatch_value(d->sink, f, val, status));
check_msgend:
while(buf >= submsg_end) {
if(buf > submsg_end) {
upb_seterr(status, UPB_ERROR, "Expected submsg end offset "
"did not lie on a tag/value boundary.");
upb_seterr(status, UPB_ERROR, "Bad submessage end.")
goto err;
}
submsg_end = pop(d, start, status, &msgdef);
CHECK(upb_pop(d, start, status, &msgdef, &submsg_end));
}
completed = buf;
}
CHECK(upb_dispatch_endmsg(&d->dispatcher));
return;
err:
read = (char*)completed - (char*)start;
d->completed_offset += read;
return read;
if (upb_ok(status)) {
upb_seterr(status, UPB_ERROR, "Callback returned UPB_BREAK");
}
}
void upb_decoder_sethandlers(upb_src *src, upb_handlers *handlers) {

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