/* ** upb::Decoder (Bytecode Decoder VM) ** ** 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 #include #include "upb/pb/decoder.int.h" #include "upb/pb/varint.int.h" #ifdef UPB_DUMP_BYTECODE #include #endif #include "upb/port_def.inc" #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."; const char *kPbDecoderSubmessageTooLong = "Submessage end extends past enclosing submessage."; /* Error messages shared within this file. */ static const char *kUnterminatedVarint = "Unterminated varint."; /* upb_pbdecoder **************************************************************/ static opcode halt = OP_HALT; /* A dummy character we can point to when the user passes us a NULL buffer. * We need this because in C (NULL + 0) and (NULL - NULL) are undefined * behavior, which would invalidate functions like curbufleft(). */ static const char dummy_char; /* 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 size_t stacksize(upb_pbdecoder *d, size_t entries) { UPB_UNUSED(d); return entries * sizeof(upb_pbdecoder_frame); } static size_t callstacksize(upb_pbdecoder *d, size_t entries) { UPB_UNUSED(d); return entries * sizeof(uint32_t*); } static bool in_residual_buf(const upb_pbdecoder *d, const char *p); /* It's unfortunate that we have to micro-manage the compiler with * UPB_FORCEINLINE and UPB_NOINLINE, especially since this tuning is necessarily * specific to one hardware configuration. But empirically 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. */ static void seterr(upb_pbdecoder *d, const char *msg) { 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) { UPB_ASSERT(d->data_end >= d->ptr); return d->data_end - d->ptr; } /* How many bytes are available before end-of-buffer. */ static size_t bufleft(const upb_pbdecoder *d) { return d->end - d->ptr; } /* Overall stream offset of d->ptr. */ uint64_t offset(const upb_pbdecoder *d) { return d->bufstart_ofs + (d->ptr - d->buf); } /* How many bytes are available before the end of this delimited region. */ size_t delim_remaining(const upb_pbdecoder *d) { return d->top->end_ofs - offset(d); } /* Advances d->ptr. */ static void advance(upb_pbdecoder *d, size_t len) { UPB_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 <= (size_t)(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) { UPB_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. */ UPB_ASSERT(d->checkpoint != d->ptr); d->checkpoint = d->ptr; } /* 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 can be skipped over before passing actual data * again. Skipped bytes can pass a NULL buffer and the decoder guarantees they * won't actually be read. */ static int32_t skip(upb_pbdecoder *d, size_t bytes) { UPB_ASSERT(!in_residual_buf(d, d->ptr) || d->size_param == 0); UPB_ASSERT(d->skip == 0); if (bytes > delim_remaining(d)) { seterr(d, "Skipped value extended beyond enclosing submessage."); return (int32_t)upb_pbdecoder_suspend(d); } else if (bufleft(d) >= bytes) { /* Skipped data is all in current buffer, and more is still available. */ advance(d, bytes); d->skip = 0; return DECODE_OK; } else { /* Skipped data extends beyond currently available buffers. */ d->pc = d->last; d->skip = bytes - curbufleft(d); d->bufstart_ofs += (d->end - d->buf); d->residual_end = d->residual; switchtobuf(d, d->residual, d->residual_end); return (int32_t)(d->size_param + d->skip); } } /* 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->skip and d->residual_end could probably elegantly be represented * as a single variable, to more easily represent this invariant. */ UPB_ASSERT(!(d->skip && d->residual_end > d->residual)); /* We need to remember the original size_param, so that the value we return * is relative to it, even if we do some skipping first. */ d->size_param = size; d->handle = handle; /* Have to handle this case specially (ie. not with skip()) because the user * is allowed to pass a NULL buffer here, which won't allow us to safely * calculate a d->end or use our normal functions like curbufleft(). */ if (d->skip && d->skip >= size) { d->skip -= size; d->bufstart_ofs += size; buf = &dummy_char; size = 0; /* We can't just return now, because we might need to execute some ops * like CHECKDELIM, which could call some callbacks and pop the stack. */ } /* We need to pretend that this was the actual buffer param, since some of the * calculations assume that d->ptr/d->buf is relative to this. */ d->buf_param = buf; if (!buf) { /* NULL buf is ok if its entire span is covered by the "skip" above, but * by this point we know that "skip" doesn't cover the buffer. */ seterr(d, "Passed NULL buffer over non-skippable region."); return (int32_t)upb_pbdecoder_suspend(d); } if (d->residual_end > d->residual) { /* We have residual bytes from the last buffer. */ UPB_ASSERT(d->ptr == d->residual); } else { switchtobuf(d, buf, buf + size); } d->checkpoint = d->ptr; /* Handle skips that don't cover the whole buffer (as above). */ if (d->skip) { size_t skip_bytes = d->skip; d->skip = 0; CHECK_RETURN(skip(d, skip_bytes)); checkpoint(d); } /* If we're inside an unknown group, continue to parse unknown values. */ if (d->top->groupnum < 0) { CHECK_RETURN(upb_pbdecoder_skipunknown(d, -1, 0)); checkpoint(d); } 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 { size_t ret = d->size_param - (d->end - d->checkpoint); UPB_ASSERT(!in_residual_buf(d, d->checkpoint)); UPB_ASSERT(d->buf == d->buf_param || d->buf == &dummy_char); d->bufstart_ofs += (d->checkpoint - d->buf); d->residual_end = d->residual; switchtobuf(d, d->residual, d->residual_end); return ret; } } /* 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. */ UPB_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. */ size_t save; UPB_ASSERT(!in_residual_buf(d, d->checkpoint)); d->ptr = d->checkpoint; save = curbufleft(d); UPB_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; } /* Copies the next "bytes" bytes into "buf" and advances the stream. * Requires that this many bytes are available in the current buffer. */ UPB_FORCEINLINE static void consumebytes(upb_pbdecoder *d, void *buf, size_t bytes) { UPB_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. */ UPB_NOINLINE static int32_t getbytes_slow(upb_pbdecoder *d, void *buf, size_t bytes) { const size_t avail = curbufleft(d); consumebytes(d, buf, avail); bytes -= avail; UPB_ASSERT(bytes > 0); if (in_residual_buf(d, d->ptr)) { advancetobuf(d, d->buf_param, d->size_param); } if (curbufleft(d) >= bytes) { consumebytes(d, (char *)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 (int32_t)upb_pbdecoder_suspend(d); } else { return (int32_t)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. */ UPB_FORCEINLINE static 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); } } UPB_NOINLINE static 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((char *)buf + ret, d->buf_param, copy); ret += copy; } return ret; } UPB_FORCEINLINE static 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. */ UPB_NOINLINE int32_t upb_pbdecoder_decode_varint_slow(upb_pbdecoder *d, uint64_t *u64) { uint8_t byte = 0x80; int bitpos; *u64 = 0; for(bitpos = 0; bitpos < 70 && (byte & 0x80); bitpos += 7) { CHECK_RETURN(getbytes(d, &byte, 1)); *u64 |= (uint64_t)(byte & 0x7F) << bitpos; } if(bitpos == 70 && (byte & 0x80)) { seterr(d, kUnterminatedVarint); return (int32_t)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. */ UPB_FORCEINLINE static 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 (int32_t)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. */ UPB_FORCEINLINE static 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 (int32_t)upb_pbdecoder_suspend(d); } *u32 = (uint32_t)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. */ UPB_FORCEINLINE static 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. */ UPB_FORCEINLINE static 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, kPbDecoderSubmessageTooLong); return false; } else if (fr == 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--; } UPB_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(ok < 0); return DECODE_OK; } else if (read < bytes && memcmp(&data, &expected, read) == 0) { return (int32_t)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 (int32_t)upb_pbdecoder_suspend(d); } 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: if (!pushtagdelim(d, -fieldnum)) { return (int32_t)upb_pbdecoder_suspend(d); } 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 (int32_t)upb_pbdecoder_suspend(d); } break; default: seterr(d, "Invalid wire type"); return (int32_t)upb_pbdecoder_suspend(d); } if (d->top->groupnum >= 0) { /* TODO: More code needed for handling unknown groups. */ upb_sink_putunknown(d->top->sink, d->checkpoint, d->ptr - d->checkpoint); return DECODE_OK; } /* Unknown group -- continue looping over unknown fields. */ 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(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; uint32_t tag; uint8_t wire_type; uint32_t fieldnum; upb_value val; int32_t retval; /* Decode tag. */ CHECK_RETURN(decode_v32(d, &tag)); wire_type = tag & 0x7; fieldnum = tag >> 3; /* Lookup tag. Because of packed/non-packed compatibility, we have to * check the wire type against two possibilities. */ 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(found); d->pc = d->top->base + upb_value_getuint64(val); return DECODE_OK; } } /* We have some unknown fields (or ENDGROUP) to parse. The DISPATCH or TAG * bytecode that triggered this is preceded by a CHECKDELIM bytecode which * we need to back up to, so that when we're done skipping unknown data we * can re-check the delimited end. */ d->last--; /* Necessary if we get suspended */ d->pc = d->last; UPB_ASSERT(getop(*d->last) == OP_CHECKDELIM); /* Unknown field or ENDGROUP. */ retval = upb_pbdecoder_skipunknown(d, fieldnum, wire_type); CHECK_RETURN(retval); if (retval == DECODE_ENDGROUP) { goto_endmsg(d); return DECODE_OK; } return DECODE_OK; } /* 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) { UPB_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 run_decoder_vm(upb_pbdecoder *d, const mgroup *group, const upb_bufhandle* handle) { #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) { int32_t instruction; opcode op; uint32_t arg; int32_t longofs; d->last = d->pc; instruction = *d->pc++; op = getop(instruction); arg = instruction >> 8; longofs = arg; UPB_ASSERT(d->ptr != d->residual_end); UPB_UNUSED(group); #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, upb_sink subsink = (d->top + 1)->sink; CHECK_SUSPEND(upb_sink_endsubmsg(d->top->sink, subsink, arg)); ) VMCASE(OP_STARTSTR, uint32_t len = (uint32_t)delim_remaining(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 = (uint32_t)curbufleft(d); size_t n = upb_sink_putstring(d->top->sink, arg, d->ptr, len, handle); if (n > len) { if (n > delim_remaining(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. */ UPB_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, UPB_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. */ UPB_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, UPB_ASSERT(d->call_len > 0); d->pc = d->callstack[--d->call_len]; ) VMCASE(OP_BRANCH, d->pc += longofs; ) VMCASE(OP_TAG1, uint8_t expected; CHECK_SUSPEND(curbufleft(d) > 0); 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, uint16_t expected; CHECK_SUSPEND(curbufleft(d) > 0); 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; int32_t result; memcpy(&expected, d->pc, 8); d->pc += 2; result = upb_pbdecoder_checktag_slow(d, expected); if (result == DECODE_MISMATCH) goto badtag; if (result >= 0) return result; }) VMCASE(OP_DISPATCH, { CHECK_RETURN(dispatch(d)); }) VMCASE(OP_HALT, { return d->size_param; }) } } } /* BytesHandler handlers ******************************************************/ void *upb_pbdecoder_startbc(void *closure, const void *pc, size_t size_hint) { upb_pbdecoder *d = closure; UPB_UNUSED(size_hint); d->top->end_ofs = UINT64_MAX; d->bufstart_ofs = 0; d->call_len = 1; d->callstack[0] = &halt; d->pc = pc; d->skip = 0; return d; } bool upb_pbdecoder_end(void *closure, const void *handler_data) { upb_pbdecoder *d = closure; const upb_pbdecodermethod *method = handler_data; uint64_t end; char dummy; if (d->residual_end > d->residual) { seterr(d, "Unexpected EOF: decoder still has buffered unparsed data"); return false; } if (d->skip) { seterr(d, "Unexpected EOF inside skipped data"); return false; } if (d->top->end_ofs != UINT64_MAX) { seterr(d, "Unexpected EOF inside delimited string"); return false; } /* The user's end() call indicates that the message ends here. */ end = offset(d); d->top->end_ofs = end; { const uint32_t *p = d->pc; d->stack->end_ofs = end; /* 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. */ UPB_ASSERT(getop(*d->pc) == OP_TAG1 || getop(*d->pc) == OP_TAG2 || getop(*d->pc) == OP_TAGN || getop(*d->pc) == OP_DISPATCH); d->pc = p; } upb_pbdecoder_decode(closure, handler_data, &dummy, 0, NULL); } if (d->call_len != 0) { seterr(d, "Unexpected EOF inside submessage or group"); return false; } return true; } size_t upb_pbdecoder_decode(void *decoder, const void *group, const char *buf, size_t size, const upb_bufhandle *handle) { int32_t result = upb_pbdecoder_resume(decoder, NULL, buf, size, handle); if (result == DECODE_ENDGROUP) goto_endmsg(decoder); CHECK_RETURN(result); return run_decoder_vm(decoder, group, handle); } /* Public API *****************************************************************/ void upb_pbdecoder_reset(upb_pbdecoder *d) { d->top = d->stack; d->top->groupnum = 0; d->ptr = d->residual; d->buf = d->residual; d->end = d->residual; d->residual_end = d->residual; } upb_pbdecoder *upb_pbdecoder_create(upb_arena *a, const upb_pbdecodermethod *m, upb_sink sink, upb_status *status) { const size_t default_max_nesting = 64; upb_pbdecoder *d = upb_arena_malloc(a, sizeof(upb_pbdecoder)); if (!d) return NULL; d->method_ = m; d->callstack = upb_arena_malloc(a, callstacksize(d, default_max_nesting)); d->stack = upb_arena_malloc(a, stacksize(d, default_max_nesting)); if (!d->stack || !d->callstack) { return NULL; } d->arena = a; d->limit = d->stack + default_max_nesting - 1; d->stack_size = default_max_nesting; d->status = status; upb_pbdecoder_reset(d); upb_bytessink_reset(&d->input_, &m->input_handler_, d); if (d->method_->dest_handlers_) { if (sink.handlers != d->method_->dest_handlers_) return NULL; } d->top->sink = sink; return d; } uint64_t upb_pbdecoder_bytesparsed(const upb_pbdecoder *d) { return offset(d); } const upb_pbdecodermethod *upb_pbdecoder_method(const upb_pbdecoder *d) { return d->method_; } upb_bytessink upb_pbdecoder_input(upb_pbdecoder *d) { return d->input_; } size_t upb_pbdecoder_maxnesting(const upb_pbdecoder *d) { return d->stack_size; } bool upb_pbdecoder_setmaxnesting(upb_pbdecoder *d, size_t max) { UPB_ASSERT(d->top >= d->stack); if (max < (size_t)(d->top - d->stack)) { /* Can't set a limit smaller than what we are currently at. */ return false; } if (max > d->stack_size) { /* Need to reallocate stack and callstack to accommodate. */ size_t old_size = stacksize(d, d->stack_size); size_t new_size = stacksize(d, max); void *p = upb_arena_realloc(d->arena, d->stack, old_size, new_size); if (!p) { return false; } d->stack = p; old_size = callstacksize(d, d->stack_size); new_size = callstacksize(d, max); p = upb_arena_realloc(d->arena, d->callstack, old_size, new_size); if (!p) { return false; } d->callstack = p; d->stack_size = max; } d->limit = d->stack + max - 1; return true; }