/* We encode backwards, to avoid pre-computing lengths (one-pass encode). */ #include "upb/encode.h" #include #include "upb/msg.h" #include "upb/upb.h" #include "upb/port_def.inc" #define UPB_PB_VARINT_MAX_LEN 10 #define CHK(x) do { if (!(x)) { return false; } } while(0) static size_t upb_encode_varint(uint64_t val, char *buf) { size_t i; if (val < 128) { buf[0] = val; return 1; } i = 0; while (val) { uint8_t byte = val & 0x7fU; val >>= 7; if (val) byte |= 0x80U; buf[i++] = byte; } return i; } static uint32_t upb_zzencode_32(int32_t n) { return ((uint32_t)n << 1) ^ (n >> 31); } static uint64_t upb_zzencode_64(int64_t n) { return ((uint64_t)n << 1) ^ (n >> 63); } typedef struct { upb_alloc *alloc; char *buf, *ptr, *limit; } upb_encstate; static size_t upb_roundup_pow2(size_t bytes) { size_t ret = 128; while (ret < bytes) { ret *= 2; } return ret; } static bool upb_encode_growbuffer(upb_encstate *e, size_t bytes) { size_t old_size = e->limit - e->buf; size_t new_size = upb_roundup_pow2(bytes + (e->limit - e->ptr)); char *new_buf = upb_realloc(e->alloc, e->buf, old_size, new_size); CHK(new_buf); /* We want previous data at the end, realloc() put it at the beginning. */ if (old_size > 0) { memmove(new_buf + new_size - old_size, e->buf, old_size); } e->ptr = new_buf + new_size - (e->limit - e->ptr); e->limit = new_buf + new_size; e->buf = new_buf; return true; } /* 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 upb_encode_reserve(upb_encstate *e, size_t bytes) { CHK(UPB_LIKELY((size_t)(e->ptr - e->buf) >= bytes) || upb_encode_growbuffer(e, bytes)); e->ptr -= bytes; return true; } /* Writes the given bytes to the buffer, handling reserve/advance. */ static bool upb_put_bytes(upb_encstate *e, const void *data, size_t len) { if (len == 0) return true; CHK(upb_encode_reserve(e, len)); memcpy(e->ptr, data, len); return true; } static bool upb_put_fixed64(upb_encstate *e, uint64_t val) { /* TODO(haberman): byte-swap for big endian. */ return upb_put_bytes(e, &val, sizeof(uint64_t)); } static bool upb_put_fixed32(upb_encstate *e, uint32_t val) { /* TODO(haberman): byte-swap for big endian. */ return upb_put_bytes(e, &val, sizeof(uint32_t)); } static bool upb_put_varint(upb_encstate *e, uint64_t val) { size_t len; char *start; CHK(upb_encode_reserve(e, UPB_PB_VARINT_MAX_LEN)); len = upb_encode_varint(val, e->ptr); start = e->ptr + UPB_PB_VARINT_MAX_LEN - len; memmove(start, e->ptr, len); e->ptr = start; return true; } static bool upb_put_double(upb_encstate *e, double d) { uint64_t u64; UPB_ASSERT(sizeof(double) == sizeof(uint64_t)); memcpy(&u64, &d, sizeof(uint64_t)); return upb_put_fixed64(e, u64); } static bool upb_put_float(upb_encstate *e, float d) { uint32_t u32; UPB_ASSERT(sizeof(float) == sizeof(uint32_t)); memcpy(&u32, &d, sizeof(uint32_t)); return upb_put_fixed32(e, u32); } static uint32_t upb_readcase(const char *msg, const upb_msglayout_field *f) { uint32_t ret; uint32_t offset = ~f->presence; memcpy(&ret, msg + offset, sizeof(ret)); return ret; } static bool upb_readhasbit(const char *msg, const upb_msglayout_field *f) { uint32_t hasbit = f->presence; UPB_ASSERT(f->presence > 0); return msg[hasbit / 8] & (1 << (hasbit % 8)); } static bool upb_put_tag(upb_encstate *e, int field_number, int wire_type) { return upb_put_varint(e, (field_number << 3) | wire_type); } static bool upb_put_fixedarray(upb_encstate *e, const upb_array *arr, size_t size) { size_t bytes = arr->len * size; const void* data = _upb_array_constptr(arr); return upb_put_bytes(e, data, bytes) && upb_put_varint(e, bytes); } bool upb_encode_message(upb_encstate *e, const char *msg, const upb_msglayout *m, size_t *size); static bool upb_encode_scalarfield(upb_encstate *e, const void *_field_mem, const upb_msglayout *m, const upb_msglayout_field *f, bool skip_zero_value) { const char *field_mem = _field_mem; #define CASE(ctype, type, wire_type, encodeval) do { \ ctype val = *(ctype*)field_mem; \ if (skip_zero_value && val == 0) { \ return true; \ } \ return upb_put_ ## type(e, encodeval) && \ upb_put_tag(e, f->number, wire_type); \ } while(0) switch (f->descriptortype) { case UPB_DESCRIPTOR_TYPE_DOUBLE: CASE(double, double, UPB_WIRE_TYPE_64BIT, val); case UPB_DESCRIPTOR_TYPE_FLOAT: CASE(float, float, UPB_WIRE_TYPE_32BIT, val); case UPB_DESCRIPTOR_TYPE_INT64: case UPB_DESCRIPTOR_TYPE_UINT64: CASE(uint64_t, varint, UPB_WIRE_TYPE_VARINT, val); case UPB_DESCRIPTOR_TYPE_UINT32: CASE(uint32_t, varint, UPB_WIRE_TYPE_VARINT, val); case UPB_DESCRIPTOR_TYPE_INT32: case UPB_DESCRIPTOR_TYPE_ENUM: CASE(int32_t, varint, UPB_WIRE_TYPE_VARINT, (int64_t)val); case UPB_DESCRIPTOR_TYPE_SFIXED64: case UPB_DESCRIPTOR_TYPE_FIXED64: CASE(uint64_t, fixed64, UPB_WIRE_TYPE_64BIT, val); case UPB_DESCRIPTOR_TYPE_FIXED32: case UPB_DESCRIPTOR_TYPE_SFIXED32: CASE(uint32_t, fixed32, UPB_WIRE_TYPE_32BIT, val); case UPB_DESCRIPTOR_TYPE_BOOL: CASE(bool, varint, UPB_WIRE_TYPE_VARINT, val); case UPB_DESCRIPTOR_TYPE_SINT32: CASE(int32_t, varint, UPB_WIRE_TYPE_VARINT, upb_zzencode_32(val)); case UPB_DESCRIPTOR_TYPE_SINT64: CASE(int64_t, varint, UPB_WIRE_TYPE_VARINT, upb_zzencode_64(val)); case UPB_DESCRIPTOR_TYPE_STRING: case UPB_DESCRIPTOR_TYPE_BYTES: { upb_strview view = *(upb_strview*)field_mem; if (skip_zero_value && view.size == 0) { return true; } return upb_put_bytes(e, view.data, view.size) && upb_put_varint(e, view.size) && upb_put_tag(e, f->number, UPB_WIRE_TYPE_DELIMITED); } case UPB_DESCRIPTOR_TYPE_GROUP: { size_t size; void *submsg = *(void **)field_mem; const upb_msglayout *subm = m->submsgs[f->submsg_index]; if (submsg == NULL) { return true; } return upb_put_tag(e, f->number, UPB_WIRE_TYPE_END_GROUP) && upb_encode_message(e, submsg, subm, &size) && upb_put_tag(e, f->number, UPB_WIRE_TYPE_START_GROUP); } case UPB_DESCRIPTOR_TYPE_MESSAGE: { size_t size; void *submsg = *(void **)field_mem; const upb_msglayout *subm = m->submsgs[f->submsg_index]; if (submsg == NULL) { return true; } return upb_encode_message(e, submsg, subm, &size) && upb_put_varint(e, size) && upb_put_tag(e, f->number, UPB_WIRE_TYPE_DELIMITED); } } #undef CASE UPB_UNREACHABLE(); } static bool upb_encode_array(upb_encstate *e, const char *field_mem, const upb_msglayout *m, const upb_msglayout_field *f) { const upb_array *arr = *(const upb_array**)field_mem; if (arr == NULL || arr->len == 0) { return true; } #define VARINT_CASE(ctype, encode) { \ const ctype *start = _upb_array_constptr(arr); \ const ctype *ptr = start + arr->len; \ size_t pre_len = e->limit - e->ptr; \ do { \ ptr--; \ CHK(upb_put_varint(e, encode)); \ } while (ptr != start); \ CHK(upb_put_varint(e, e->limit - e->ptr - pre_len)); \ } \ break; \ do { ; } while(0) switch (f->descriptortype) { case UPB_DESCRIPTOR_TYPE_DOUBLE: CHK(upb_put_fixedarray(e, arr, sizeof(double))); break; case UPB_DESCRIPTOR_TYPE_FLOAT: CHK(upb_put_fixedarray(e, arr, sizeof(float))); break; case UPB_DESCRIPTOR_TYPE_SFIXED64: case UPB_DESCRIPTOR_TYPE_FIXED64: CHK(upb_put_fixedarray(e, arr, sizeof(uint64_t))); break; case UPB_DESCRIPTOR_TYPE_FIXED32: case UPB_DESCRIPTOR_TYPE_SFIXED32: CHK(upb_put_fixedarray(e, arr, sizeof(uint32_t))); break; case UPB_DESCRIPTOR_TYPE_INT64: case UPB_DESCRIPTOR_TYPE_UINT64: VARINT_CASE(uint64_t, *ptr); case UPB_DESCRIPTOR_TYPE_UINT32: VARINT_CASE(uint32_t, *ptr); case UPB_DESCRIPTOR_TYPE_INT32: case UPB_DESCRIPTOR_TYPE_ENUM: VARINT_CASE(int32_t, (int64_t)*ptr); case UPB_DESCRIPTOR_TYPE_BOOL: VARINT_CASE(bool, *ptr); case UPB_DESCRIPTOR_TYPE_SINT32: VARINT_CASE(int32_t, upb_zzencode_32(*ptr)); case UPB_DESCRIPTOR_TYPE_SINT64: VARINT_CASE(int64_t, upb_zzencode_64(*ptr)); case UPB_DESCRIPTOR_TYPE_STRING: case UPB_DESCRIPTOR_TYPE_BYTES: { const upb_strview *start = _upb_array_constptr(arr); const upb_strview *ptr = start + arr->len; do { ptr--; CHK(upb_put_bytes(e, ptr->data, ptr->size) && upb_put_varint(e, ptr->size) && upb_put_tag(e, f->number, UPB_WIRE_TYPE_DELIMITED)); } while (ptr != start); return true; } case UPB_DESCRIPTOR_TYPE_GROUP: { const void *const*start = _upb_array_constptr(arr); const void *const*ptr = start + arr->len; const upb_msglayout *subm = m->submsgs[f->submsg_index]; do { size_t size; ptr--; CHK(upb_put_tag(e, f->number, UPB_WIRE_TYPE_END_GROUP) && upb_encode_message(e, *ptr, subm, &size) && upb_put_tag(e, f->number, UPB_WIRE_TYPE_START_GROUP)); } while (ptr != start); return true; } case UPB_DESCRIPTOR_TYPE_MESSAGE: { const void *const*start = _upb_array_constptr(arr); const void *const*ptr = start + arr->len; const upb_msglayout *subm = m->submsgs[f->submsg_index]; do { size_t size; ptr--; CHK(upb_encode_message(e, *ptr, subm, &size) && upb_put_varint(e, size) && upb_put_tag(e, f->number, UPB_WIRE_TYPE_DELIMITED)); } while (ptr != start); return true; } } #undef VARINT_CASE /* We encode all primitive arrays as packed, regardless of what was specified * in the .proto file. Could special case 1-sized arrays. */ CHK(upb_put_tag(e, f->number, UPB_WIRE_TYPE_DELIMITED)); return true; } static bool upb_encode_map(upb_encstate *e, const char *field_mem, const upb_msglayout *m, const upb_msglayout_field *f) { const upb_map *map = *(const upb_map**)field_mem; const upb_msglayout *entry = m->submsgs[f->submsg_index]; const upb_msglayout_field *key_field = &entry->fields[0]; const upb_msglayout_field *val_field = &entry->fields[1]; upb_strtable_iter i; if (map == NULL) { return true; } upb_strtable_begin(&i, &map->table); for(; !upb_strtable_done(&i); upb_strtable_next(&i)) { size_t pre_len = e->limit - e->ptr; size_t size; upb_strview key = upb_strtable_iter_key(&i); const upb_value val = upb_strtable_iter_value(&i); const void *keyp = map->key_size == UPB_MAPTYPE_STRING ? (void *)&key : key.data; const void *valp = map->val_size == UPB_MAPTYPE_STRING ? upb_value_getptr(val) : &val; CHK(upb_encode_scalarfield(e, valp, entry, val_field, false)); CHK(upb_encode_scalarfield(e, keyp, entry, key_field, false)); size = (e->limit - e->ptr) - pre_len; CHK(upb_put_varint(e, size)); CHK(upb_put_tag(e, f->number, UPB_WIRE_TYPE_DELIMITED)); } return true; } bool upb_encode_message(upb_encstate *e, const char *msg, const upb_msglayout *m, size_t *size) { int i; size_t pre_len = e->limit - e->ptr; const char *unknown; size_t unknown_size; unknown = upb_msg_getunknown(msg, &unknown_size); if (unknown) { upb_put_bytes(e, unknown, unknown_size); } for (i = m->field_count - 1; i >= 0; i--) { const upb_msglayout_field *f = &m->fields[i]; if (f->label == UPB_LABEL_REPEATED) { CHK(upb_encode_array(e, msg + f->offset, m, f)); } else if (f->label == UPB_LABEL_MAP) { CHK(upb_encode_map(e, msg + f->offset, m, f)); } else { bool skip_empty = false; if (f->presence == 0) { /* Proto3 presence. */ skip_empty = true; } else if (f->presence > 0) { /* Proto2 presence: hasbit. */ if (!upb_readhasbit(msg, f)) { continue; } } else { /* Field is in a oneof. */ if (upb_readcase(msg, f) != f->number) { continue; } } CHK(upb_encode_scalarfield(e, msg + f->offset, m, f, skip_empty)); } } *size = (e->limit - e->ptr) - pre_len; return true; } char *upb_encode(const void *msg, const upb_msglayout *m, upb_arena *arena, size_t *size) { upb_encstate e; e.alloc = upb_arena_alloc(arena); e.buf = NULL; e.limit = NULL; e.ptr = NULL; if (!upb_encode_message(&e, msg, m, size)) { *size = 0; return NULL; } *size = e.limit - e.ptr; if (*size == 0) { static char ch; return &ch; } else { UPB_ASSERT(e.ptr); return e.ptr; } } #undef CHK