// Copyright 2015 the V8 project authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "src/signature.h" #include "src/base/platform/elapsed-timer.h" #include "src/bit-vector.h" #include "src/flags.h" #include "src/handles.h" #include "src/objects-inl.h" #include "src/zone/zone-containers.h" #include "src/wasm/decoder.h" #include "src/wasm/function-body-decoder-impl.h" #include "src/wasm/function-body-decoder.h" #include "src/wasm/wasm-limits.h" #include "src/wasm/wasm-module.h" #include "src/wasm/wasm-opcodes.h" #include "src/ostreams.h" #include "src/compiler/wasm-compiler.h" namespace v8 { namespace internal { namespace wasm { #if DEBUG #define TRACE(...) \ do { \ if (FLAG_trace_wasm_decoder) PrintF(__VA_ARGS__); \ } while (false) #else #define TRACE(...) #endif #define CHECK_PROTOTYPE_OPCODE(flag) \ if (module_ != nullptr && module_->is_asm_js()) { \ error("Opcode not supported for asmjs modules"); \ } \ if (!FLAG_##flag) { \ error("Invalid opcode (enable with --" #flag ")"); \ break; \ } // An SsaEnv environment carries the current local variable renaming // as well as the current effect and control dependency in the TF graph. // It maintains a control state that tracks whether the environment // is reachable, has reached a control end, or has been merged. struct SsaEnv { enum State { kControlEnd, kUnreachable, kReached, kMerged }; State state; TFNode* control; TFNode* effect; TFNode** locals; bool go() { return state >= kReached; } void Kill(State new_state = kControlEnd) { state = new_state; locals = nullptr; control = nullptr; effect = nullptr; } void SetNotMerged() { if (state == kMerged) state = kReached; } }; // An entry on the value stack. struct Value { const byte* pc; TFNode* node; ValueType type; }; struct TryInfo : public ZoneObject { SsaEnv* catch_env; TFNode* exception; explicit TryInfo(SsaEnv* c) : catch_env(c), exception(nullptr) {} }; struct MergeValues { uint32_t arity; union { Value* array; Value first; } vals; // Either multiple values or a single value. Value& operator[](size_t i) { DCHECK_GT(arity, i); return arity == 1 ? vals.first : vals.array[i]; } }; static Value* NO_VALUE = nullptr; enum ControlKind { kControlIf, kControlBlock, kControlLoop, kControlTry }; // An entry on the control stack (i.e. if, block, loop). struct Control { const byte* pc; ControlKind kind; size_t stack_depth; // stack height at the beginning of the construct. SsaEnv* end_env; // end environment for the construct. SsaEnv* false_env; // false environment (only for if). TryInfo* try_info; // Information used for compiling try statements. int32_t previous_catch; // The previous Control (on the stack) with a catch. bool unreachable; // The current block has been ended. // Values merged into the end of this control construct. MergeValues merge; inline bool is_if() const { return kind == kControlIf; } inline bool is_block() const { return kind == kControlBlock; } inline bool is_loop() const { return kind == kControlLoop; } inline bool is_try() const { return kind == kControlTry; } // Named constructors. static Control Block(const byte* pc, size_t stack_depth, SsaEnv* end_env, int32_t previous_catch) { return {pc, kControlBlock, stack_depth, end_env, nullptr, nullptr, previous_catch, false, {0, {NO_VALUE}}}; } static Control If(const byte* pc, size_t stack_depth, SsaEnv* end_env, SsaEnv* false_env, int32_t previous_catch) { return {pc, kControlIf, stack_depth, end_env, false_env, nullptr, previous_catch, false, {0, {NO_VALUE}}}; } static Control Loop(const byte* pc, size_t stack_depth, SsaEnv* end_env, int32_t previous_catch) { return {pc, kControlLoop, stack_depth, end_env, nullptr, nullptr, previous_catch, false, {0, {NO_VALUE}}}; } static Control Try(const byte* pc, size_t stack_depth, SsaEnv* end_env, Zone* zone, SsaEnv* catch_env, int32_t previous_catch) { DCHECK_NOT_NULL(catch_env); TryInfo* try_info = new (zone) TryInfo(catch_env); return {pc, kControlTry, stack_depth, end_env, nullptr, try_info, previous_catch, false, {0, {NO_VALUE}}}; } }; namespace { inline unsigned GetShuffleMaskSize(WasmOpcode opcode) { switch (opcode) { case kExprS32x4Shuffle: return 4; case kExprS16x8Shuffle: return 8; case kExprS8x16Shuffle: return 16; default: UNREACHABLE(); return 0; } } } // namespace // Macros that build nodes only if there is a graph and the current SSA // environment is reachable from start. This avoids problems with malformed // TF graphs when decoding inputs that have unreachable code. #define BUILD(func, ...) \ (build() ? CheckForException(builder_->func(__VA_ARGS__)) : nullptr) #define BUILD0(func) (build() ? CheckForException(builder_->func()) : nullptr) // Generic Wasm bytecode decoder with utilities for decoding operands, // lengths, etc. class WasmDecoder : public Decoder { public: WasmDecoder(const WasmModule* module, FunctionSig* sig, const byte* start, const byte* end) : Decoder(start, end), module_(module), sig_(sig), local_types_(nullptr) {} const WasmModule* module_; FunctionSig* sig_; ZoneVector* local_types_; size_t total_locals() const { return local_types_ == nullptr ? 0 : local_types_->size(); } static bool DecodeLocals(Decoder* decoder, const FunctionSig* sig, ZoneVector* type_list) { DCHECK_NOT_NULL(type_list); DCHECK_EQ(0, type_list->size()); // Initialize from signature. if (sig != nullptr) { type_list->assign(sig->parameters().begin(), sig->parameters().end()); } // Decode local declarations, if any. uint32_t entries = decoder->consume_u32v("local decls count"); if (decoder->failed()) return false; TRACE("local decls count: %u\n", entries); while (entries-- > 0 && decoder->ok() && decoder->more()) { uint32_t count = decoder->consume_u32v("local count"); if (decoder->failed()) return false; if ((count + type_list->size()) > kV8MaxWasmFunctionLocals) { decoder->error(decoder->pc() - 1, "local count too large"); return false; } byte code = decoder->consume_u8("local type"); if (decoder->failed()) return false; ValueType type; switch (code) { case kLocalI32: type = kWasmI32; break; case kLocalI64: type = kWasmI64; break; case kLocalF32: type = kWasmF32; break; case kLocalF64: type = kWasmF64; break; case kLocalS128: type = kWasmS128; break; case kLocalS1x4: type = kWasmS1x4; break; case kLocalS1x8: type = kWasmS1x8; break; case kLocalS1x16: type = kWasmS1x16; break; default: decoder->error(decoder->pc() - 1, "invalid local type"); return false; } type_list->insert(type_list->end(), count, type); } DCHECK(decoder->ok()); return true; } static BitVector* AnalyzeLoopAssignment(Decoder* decoder, const byte* pc, int locals_count, Zone* zone) { if (pc >= decoder->end()) return nullptr; if (*pc != kExprLoop) return nullptr; BitVector* assigned = new (zone) BitVector(locals_count, zone); int depth = 0; // Iteratively process all AST nodes nested inside the loop. while (pc < decoder->end() && decoder->ok()) { WasmOpcode opcode = static_cast(*pc); unsigned length = 1; switch (opcode) { case kExprLoop: case kExprIf: case kExprBlock: case kExprTry: length = OpcodeLength(decoder, pc); depth++; break; case kExprSetLocal: // fallthru case kExprTeeLocal: { LocalIndexOperand operand(decoder, pc); if (assigned->length() > 0 && operand.index < static_cast(assigned->length())) { // Unverified code might have an out-of-bounds index. assigned->Add(operand.index); } length = 1 + operand.length; break; } case kExprEnd: depth--; break; default: length = OpcodeLength(decoder, pc); break; } if (depth <= 0) break; pc += length; } return decoder->ok() ? assigned : nullptr; } inline bool Validate(const byte* pc, LocalIndexOperand& operand) { if (operand.index < total_locals()) { if (local_types_) { operand.type = local_types_->at(operand.index); } else { operand.type = kWasmStmt; } return true; } errorf(pc + 1, "invalid local index: %u", operand.index); return false; } inline bool Validate(const byte* pc, GlobalIndexOperand& operand) { if (module_ != nullptr && operand.index < module_->globals.size()) { operand.global = &module_->globals[operand.index]; operand.type = operand.global->type; return true; } errorf(pc + 1, "invalid global index: %u", operand.index); return false; } inline bool Complete(const byte* pc, CallFunctionOperand& operand) { if (module_ != nullptr && operand.index < module_->functions.size()) { operand.sig = module_->functions[operand.index].sig; return true; } return false; } inline bool Validate(const byte* pc, CallFunctionOperand& operand) { if (Complete(pc, operand)) { return true; } errorf(pc + 1, "invalid function index: %u", operand.index); return false; } inline bool Complete(const byte* pc, CallIndirectOperand& operand) { if (module_ != nullptr && operand.index < module_->signatures.size()) { operand.sig = module_->signatures[operand.index]; return true; } return false; } inline bool Validate(const byte* pc, CallIndirectOperand& operand) { if (module_ == nullptr || module_->function_tables.empty()) { error("function table has to exist to execute call_indirect"); return false; } if (Complete(pc, operand)) { return true; } errorf(pc + 1, "invalid signature index: #%u", operand.index); return false; } inline bool Validate(const byte* pc, BreakDepthOperand& operand, ZoneVector& control) { if (operand.depth < control.size()) { operand.target = &control[control.size() - operand.depth - 1]; return true; } errorf(pc + 1, "invalid break depth: %u", operand.depth); return false; } bool Validate(const byte* pc, BranchTableOperand& operand, size_t block_depth) { if (operand.table_count >= kV8MaxWasmFunctionSize) { errorf(pc + 1, "invalid table count (> max function size): %u", operand.table_count); return false; } return checkAvailable(operand.table_count); } inline bool Validate(const byte* pc, WasmOpcode opcode, SimdLaneOperand& operand) { uint8_t num_lanes = 0; switch (opcode) { case kExprF32x4ExtractLane: case kExprF32x4ReplaceLane: case kExprI32x4ExtractLane: case kExprI32x4ReplaceLane: num_lanes = 4; break; case kExprI16x8ExtractLane: case kExprI16x8ReplaceLane: num_lanes = 8; break; case kExprI8x16ExtractLane: case kExprI8x16ReplaceLane: num_lanes = 16; break; default: UNREACHABLE(); break; } if (operand.lane < 0 || operand.lane >= num_lanes) { error(pc_ + 2, "invalid lane index"); return false; } else { return true; } } inline bool Validate(const byte* pc, WasmOpcode opcode, SimdShiftOperand& operand) { uint8_t max_shift = 0; switch (opcode) { case kExprI32x4Shl: case kExprI32x4ShrS: case kExprI32x4ShrU: max_shift = 32; break; case kExprI16x8Shl: case kExprI16x8ShrS: case kExprI16x8ShrU: max_shift = 16; break; case kExprI8x16Shl: case kExprI8x16ShrS: case kExprI8x16ShrU: max_shift = 8; break; default: UNREACHABLE(); break; } if (operand.shift < 0 || operand.shift >= max_shift) { error(pc_ + 2, "invalid shift amount"); return false; } else { return true; } } inline bool Validate(const byte* pc, WasmOpcode opcode, SimdShuffleOperand& operand) { unsigned lanes = GetShuffleMaskSize(opcode); uint8_t max_lane = 0; for (unsigned i = 0; i < lanes; i++) max_lane = std::max(max_lane, operand.shuffle[i]); if (operand.lanes != lanes || max_lane > 2 * lanes) { error(pc_ + 2, "invalid shuffle mask"); return false; } else { return true; } } static unsigned OpcodeLength(Decoder* decoder, const byte* pc) { WasmOpcode opcode = static_cast(*pc); switch (opcode) { #define DECLARE_OPCODE_CASE(name, opcode, sig) case kExpr##name: FOREACH_LOAD_MEM_OPCODE(DECLARE_OPCODE_CASE) FOREACH_STORE_MEM_OPCODE(DECLARE_OPCODE_CASE) #undef DECLARE_OPCODE_CASE { MemoryAccessOperand operand(decoder, pc, UINT32_MAX); return 1 + operand.length; } case kExprBr: case kExprBrIf: { BreakDepthOperand operand(decoder, pc); return 1 + operand.length; } case kExprSetGlobal: case kExprGetGlobal: { GlobalIndexOperand operand(decoder, pc); return 1 + operand.length; } case kExprCallFunction: { CallFunctionOperand operand(decoder, pc); return 1 + operand.length; } case kExprCallIndirect: { CallIndirectOperand operand(decoder, pc); return 1 + operand.length; } case kExprTry: case kExprIf: // fall thru case kExprLoop: case kExprBlock: { BlockTypeOperand operand(decoder, pc); return 1 + operand.length; } case kExprSetLocal: case kExprTeeLocal: case kExprGetLocal: case kExprCatch: { LocalIndexOperand operand(decoder, pc); return 1 + operand.length; } case kExprBrTable: { BranchTableOperand operand(decoder, pc); BranchTableIterator iterator(decoder, operand); return 1 + iterator.length(); } case kExprI32Const: { ImmI32Operand operand(decoder, pc); return 1 + operand.length; } case kExprI64Const: { ImmI64Operand operand(decoder, pc); return 1 + operand.length; } case kExprGrowMemory: case kExprMemorySize: { MemoryIndexOperand operand(decoder, pc); return 1 + operand.length; } case kExprF32Const: return 5; case kExprF64Const: return 9; case kSimdPrefix: { byte simd_index = decoder->read_u8(pc + 1, "simd_index"); WasmOpcode opcode = static_cast(kSimdPrefix << 8 | simd_index); switch (opcode) { #define DECLARE_OPCODE_CASE(name, opcode, sig) case kExpr##name: FOREACH_SIMD_0_OPERAND_OPCODE(DECLARE_OPCODE_CASE) #undef DECLARE_OPCODE_CASE { return 2; } #define DECLARE_OPCODE_CASE(name, opcode, sig) case kExpr##name: FOREACH_SIMD_1_OPERAND_OPCODE(DECLARE_OPCODE_CASE) #undef DECLARE_OPCODE_CASE { return 3; } // Shuffles contain a byte array to determine the shuffle. case kExprS32x4Shuffle: case kExprS16x8Shuffle: case kExprS8x16Shuffle: return 2 + GetShuffleMaskSize(opcode); default: decoder->error(pc, "invalid SIMD opcode"); return 2; } } default: return 1; } } std::pair StackEffect(const byte* pc) { WasmOpcode opcode = static_cast(*pc); // Handle "simple" opcodes with a fixed signature first. FunctionSig* sig = WasmOpcodes::Signature(opcode); if (!sig) sig = WasmOpcodes::AsmjsSignature(opcode); if (sig) return {sig->parameter_count(), sig->return_count()}; #define DECLARE_OPCODE_CASE(name, opcode, sig) case kExpr##name: // clang-format off switch (opcode) { case kExprSelect: return {3, 1}; FOREACH_STORE_MEM_OPCODE(DECLARE_OPCODE_CASE) return {2, 0}; FOREACH_LOAD_MEM_OPCODE(DECLARE_OPCODE_CASE) case kExprTeeLocal: case kExprGrowMemory: return {1, 1}; case kExprSetLocal: case kExprSetGlobal: case kExprDrop: case kExprBrIf: case kExprBrTable: case kExprIf: return {1, 0}; case kExprGetLocal: case kExprGetGlobal: case kExprI32Const: case kExprI64Const: case kExprF32Const: case kExprF64Const: case kExprMemorySize: return {0, 1}; case kExprCallFunction: { CallFunctionOperand operand(this, pc); CHECK(Complete(pc, operand)); return {operand.sig->parameter_count(), operand.sig->return_count()}; } case kExprCallIndirect: { CallIndirectOperand operand(this, pc); CHECK(Complete(pc, operand)); // Indirect calls pop an additional argument for the table index. return {operand.sig->parameter_count() + 1, operand.sig->return_count()}; } case kExprBr: case kExprBlock: case kExprLoop: case kExprEnd: case kExprElse: case kExprNop: case kExprReturn: case kExprUnreachable: return {0, 0}; default: V8_Fatal(__FILE__, __LINE__, "unimplemented opcode: %x", opcode); return {0, 0}; } #undef DECLARE_OPCODE_CASE // clang-format on } }; static const int32_t kNullCatch = -1; // The full WASM decoder for bytecode. Verifies bytecode and, optionally, // generates a TurboFan IR graph. class WasmFullDecoder : public WasmDecoder { public: WasmFullDecoder(Zone* zone, const wasm::WasmModule* module, const FunctionBody& body) : WasmFullDecoder(zone, module, nullptr, body) {} WasmFullDecoder(Zone* zone, TFBuilder* builder, const FunctionBody& body) : WasmFullDecoder(zone, builder->module_env() == nullptr ? nullptr : builder->module_env()->module, builder, body) {} bool Decode() { if (FLAG_wasm_code_fuzzer_gen_test) { PrintRawWasmCode(start_, end_); } base::ElapsedTimer decode_timer; if (FLAG_trace_wasm_decode_time) { decode_timer.Start(); } stack_.clear(); control_.clear(); if (end_ < pc_) { error("function body end < start"); return false; } DCHECK_EQ(0, local_types_->size()); WasmDecoder::DecodeLocals(this, sig_, local_types_); InitSsaEnv(); DecodeFunctionBody(); if (failed()) return TraceFailed(); if (!control_.empty()) { // Generate a better error message whether the unterminated control // structure is the function body block or an innner structure. if (control_.size() > 1) { error(control_.back().pc, "unterminated control structure"); } else { error("function body must end with \"end\" opcode."); } return TraceFailed(); } if (!last_end_found_) { error("function body must end with \"end\" opcode."); return false; } if (FLAG_trace_wasm_decode_time) { double ms = decode_timer.Elapsed().InMillisecondsF(); PrintF("wasm-decode %s (%0.3f ms)\n\n", ok() ? "ok" : "failed", ms); } else { TRACE("wasm-decode %s\n\n", ok() ? "ok" : "failed"); } return true; } bool TraceFailed() { TRACE("wasm-error module+%-6d func+%d: %s\n\n", baserel(start_ + error_offset_), error_offset_, error_msg_.c_str()); return false; } private: WasmFullDecoder(Zone* zone, const wasm::WasmModule* module, TFBuilder* builder, const FunctionBody& body) : WasmDecoder(module, body.sig, body.start, body.end), zone_(zone), builder_(builder), base_(body.base), local_type_vec_(zone), stack_(zone), control_(zone), last_end_found_(false), current_catch_(kNullCatch) { local_types_ = &local_type_vec_; } static const size_t kErrorMsgSize = 128; Zone* zone_; TFBuilder* builder_; const byte* base_; SsaEnv* ssa_env_; ZoneVector local_type_vec_; // types of local variables. ZoneVector stack_; // stack of values. ZoneVector control_; // stack of blocks, loops, and ifs. bool last_end_found_; int32_t current_catch_; TryInfo* current_try_info() { return control_[current_catch_].try_info; } inline bool build() { return builder_ && ssa_env_->go(); } void InitSsaEnv() { TFNode* start = nullptr; SsaEnv* ssa_env = reinterpret_cast(zone_->New(sizeof(SsaEnv))); size_t size = sizeof(TFNode*) * EnvironmentCount(); ssa_env->state = SsaEnv::kReached; ssa_env->locals = size > 0 ? reinterpret_cast(zone_->New(size)) : nullptr; if (builder_) { start = builder_->Start(static_cast(sig_->parameter_count() + 1)); // Initialize local variables. uint32_t index = 0; while (index < sig_->parameter_count()) { ssa_env->locals[index] = builder_->Param(index); index++; } while (index < local_type_vec_.size()) { ValueType type = local_type_vec_[index]; TFNode* node = DefaultValue(type); while (index < local_type_vec_.size() && local_type_vec_[index] == type) { // Do a whole run of like-typed locals at a time. ssa_env->locals[index++] = node; } } } ssa_env->control = start; ssa_env->effect = start; SetEnv("initial", ssa_env); if (builder_) { // The function-prologue stack check is associated with position 0, which // is never a position of any instruction in the function. builder_->StackCheck(0); } } TFNode* DefaultValue(ValueType type) { switch (type) { case kWasmI32: return builder_->Int32Constant(0); case kWasmI64: return builder_->Int64Constant(0); case kWasmF32: return builder_->Float32Constant(0); case kWasmF64: return builder_->Float64Constant(0); case kWasmS128: return builder_->S128Zero(); case kWasmS1x4: return builder_->S1x4Zero(); case kWasmS1x8: return builder_->S1x8Zero(); case kWasmS1x16: return builder_->S1x16Zero(); default: UNREACHABLE(); return nullptr; } } char* indentation() { static const int kMaxIndent = 64; static char bytes[kMaxIndent + 1]; for (int i = 0; i < kMaxIndent; ++i) bytes[i] = ' '; bytes[kMaxIndent] = 0; if (stack_.size() < kMaxIndent / 2) { bytes[stack_.size() * 2] = 0; } return bytes; } bool CheckHasMemory() { if (!module_->has_memory) { error(pc_ - 1, "memory instruction with no memory"); } return module_->has_memory; } // Decodes the body of a function. void DecodeFunctionBody() { TRACE("wasm-decode %p...%p (module+%d, %d bytes) %s\n", reinterpret_cast(start_), reinterpret_cast(end_), baserel(pc_), static_cast(end_ - start_), builder_ ? "graph building" : ""); { // Set up initial function block. SsaEnv* break_env = ssa_env_; SetEnv("initial env", Steal(break_env)); PushBlock(break_env); Control* c = &control_.back(); c->merge.arity = static_cast(sig_->return_count()); if (c->merge.arity == 1) { c->merge.vals.first = {pc_, nullptr, sig_->GetReturn(0)}; } else if (c->merge.arity > 1) { c->merge.vals.array = zone_->NewArray(c->merge.arity); for (unsigned i = 0; i < c->merge.arity; i++) { c->merge.vals.array[i] = {pc_, nullptr, sig_->GetReturn(i)}; } } } while (pc_ < end_) { // decoding loop. unsigned len = 1; WasmOpcode opcode = static_cast(*pc_); #if DEBUG if (FLAG_trace_wasm_decoder && !WasmOpcodes::IsPrefixOpcode(opcode)) { TRACE(" @%-8d #%-20s|", startrel(pc_), WasmOpcodes::OpcodeName(opcode)); } #endif FunctionSig* sig = WasmOpcodes::Signature(opcode); if (sig) { BuildSimpleOperator(opcode, sig); } else { // Complex bytecode. switch (opcode) { case kExprNop: break; case kExprBlock: { // The break environment is the outer environment. BlockTypeOperand operand(this, pc_); SsaEnv* break_env = ssa_env_; PushBlock(break_env); SetEnv("block:start", Steal(break_env)); SetBlockType(&control_.back(), operand); len = 1 + operand.length; break; } case kExprThrow: { CHECK_PROTOTYPE_OPCODE(wasm_eh_prototype); Value value = Pop(0, kWasmI32); BUILD(Throw, value.node); // TODO(titzer): Throw should end control, but currently we build a // (reachable) runtime call instead of connecting it directly to // end. // EndControl(); break; } case kExprTry: { CHECK_PROTOTYPE_OPCODE(wasm_eh_prototype); BlockTypeOperand operand(this, pc_); SsaEnv* outer_env = ssa_env_; SsaEnv* try_env = Steal(outer_env); SsaEnv* catch_env = UnreachableEnv(); PushTry(outer_env, catch_env); SetEnv("try_catch:start", try_env); SetBlockType(&control_.back(), operand); len = 1 + operand.length; break; } case kExprCatch: { CHECK_PROTOTYPE_OPCODE(wasm_eh_prototype); LocalIndexOperand operand(this, pc_); len = 1 + operand.length; if (control_.empty()) { error("catch does not match any try"); break; } Control* c = &control_.back(); if (!c->is_try()) { error("catch does not match any try"); break; } if (c->try_info->catch_env == nullptr) { error(pc_, "catch already present for try with catch"); break; } FallThruTo(c); stack_.resize(c->stack_depth); DCHECK_NOT_NULL(c->try_info); SsaEnv* catch_env = c->try_info->catch_env; c->try_info->catch_env = nullptr; SetEnv("catch:begin", catch_env); current_catch_ = c->previous_catch; if (Validate(pc_, operand)) { if (ssa_env_->locals) { TFNode* exception_as_i32 = BUILD(Catch, c->try_info->exception, position()); ssa_env_->locals[operand.index] = exception_as_i32; } } break; } case kExprLoop: { BlockTypeOperand operand(this, pc_); SsaEnv* finish_try_env = Steal(ssa_env_); // The continue environment is the inner environment. SsaEnv* loop_body_env = PrepareForLoop(pc_, finish_try_env); SetEnv("loop:start", loop_body_env); ssa_env_->SetNotMerged(); PushLoop(finish_try_env); SetBlockType(&control_.back(), operand); len = 1 + operand.length; break; } case kExprIf: { // Condition on top of stack. Split environments for branches. BlockTypeOperand operand(this, pc_); Value cond = Pop(0, kWasmI32); TFNode* if_true = nullptr; TFNode* if_false = nullptr; BUILD(BranchNoHint, cond.node, &if_true, &if_false); SsaEnv* end_env = ssa_env_; SsaEnv* false_env = Split(ssa_env_); false_env->control = if_false; SsaEnv* true_env = Steal(ssa_env_); true_env->control = if_true; PushIf(end_env, false_env); SetEnv("if:true", true_env); SetBlockType(&control_.back(), operand); len = 1 + operand.length; break; } case kExprElse: { if (control_.empty()) { error("else does not match any if"); break; } Control* c = &control_.back(); if (!c->is_if()) { error(pc_, "else does not match an if"); break; } if (c->false_env == nullptr) { error(pc_, "else already present for if"); break; } FallThruTo(c); stack_.resize(c->stack_depth); // Switch to environment for false branch. SetEnv("if_else:false", c->false_env); c->false_env = nullptr; // record that an else is already seen break; } case kExprEnd: { if (control_.empty()) { error("end does not match any if, try, or block"); return; } const char* name = "block:end"; Control* c = &control_.back(); if (c->is_loop()) { // A loop just leaves the values on the stack. TypeCheckFallThru(c); if (c->unreachable) PushEndValues(c); PopControl(); SetEnv("loop:end", ssa_env_); break; } if (c->is_if()) { if (c->false_env != nullptr) { // End the true branch of a one-armed if. Goto(c->false_env, c->end_env); if (!c->unreachable && stack_.size() != c->stack_depth) { error("end of if expected empty stack"); stack_.resize(c->stack_depth); } if (c->merge.arity > 0) { error("non-void one-armed if"); } name = "if:merge"; } else { // End the false branch of a two-armed if. name = "if_else:merge"; } } else if (c->is_try()) { name = "try:end"; // validate that catch was seen. if (c->try_info->catch_env != nullptr) { error(pc_, "missing catch in try"); break; } } FallThruTo(c); SetEnv(name, c->end_env); PushEndValues(c); if (control_.size() == 1) { // If at the last (implicit) control, check we are at end. if (pc_ + 1 != end_) { error(pc_ + 1, "trailing code after function end"); break; } last_end_found_ = true; if (ssa_env_->go()) { // The result of the block is the return value. TRACE(" @%-8d #xx:%-20s|", startrel(pc_), "(implicit) return"); DoReturn(); TRACE("\n"); } else { TypeCheckFallThru(c); } } PopControl(); break; } case kExprSelect: { Value cond = Pop(2, kWasmI32); Value fval = Pop(); Value tval = Pop(0, fval.type); if (build()) { TFNode* controls[2]; builder_->BranchNoHint(cond.node, &controls[0], &controls[1]); TFNode* merge = builder_->Merge(2, controls); TFNode* vals[2] = {tval.node, fval.node}; TFNode* phi = builder_->Phi(tval.type, 2, vals, merge); Push(tval.type, phi); ssa_env_->control = merge; } else { Push(tval.type == kWasmVar ? fval.type : tval.type, nullptr); } break; } case kExprBr: { BreakDepthOperand operand(this, pc_); if (Validate(pc_, operand, control_)) { BreakTo(operand.depth); } len = 1 + operand.length; EndControl(); break; } case kExprBrIf: { BreakDepthOperand operand(this, pc_); Value cond = Pop(0, kWasmI32); if (ok() && Validate(pc_, operand, control_)) { SsaEnv* fenv = ssa_env_; SsaEnv* tenv = Split(fenv); fenv->SetNotMerged(); BUILD(BranchNoHint, cond.node, &tenv->control, &fenv->control); ssa_env_ = tenv; BreakTo(operand.depth); ssa_env_ = fenv; } len = 1 + operand.length; break; } case kExprBrTable: { BranchTableOperand operand(this, pc_); BranchTableIterator iterator(this, operand); if (Validate(pc_, operand, control_.size())) { Value key = Pop(0, kWasmI32); if (failed()) break; SsaEnv* break_env = ssa_env_; if (operand.table_count > 0) { // Build branches to the various blocks based on the table. TFNode* sw = BUILD(Switch, operand.table_count + 1, key.node); SsaEnv* copy = Steal(break_env); ssa_env_ = copy; MergeValues* merge = nullptr; while (ok() && iterator.has_next()) { uint32_t i = iterator.cur_index(); const byte* pos = iterator.pc(); uint32_t target = iterator.next(); if (target >= control_.size()) { error(pos, "improper branch in br_table"); break; } ssa_env_ = Split(copy); ssa_env_->control = (i == operand.table_count) ? BUILD(IfDefault, sw) : BUILD(IfValue, i, sw); BreakTo(target); // Check that label types match up. static MergeValues loop_dummy = {0, {nullptr}}; Control* c = &control_[control_.size() - target - 1]; MergeValues* current = c->is_loop() ? &loop_dummy : &c->merge; if (i == 0) { merge = current; } else if (merge->arity != current->arity) { errorf(pos, "inconsistent arity in br_table target %d" " (previous was %u, this one %u)", i, merge->arity, current->arity); } else if (control_.back().unreachable) { for (uint32_t j = 0; ok() && j < merge->arity; ++j) { if ((*merge)[j].type != (*current)[j].type) { errorf(pos, "type error in br_table target %d operand %d" " (previous expected %s, this one %s)", i, j, WasmOpcodes::TypeName((*merge)[j].type), WasmOpcodes::TypeName((*current)[j].type)); } } } } if (failed()) break; } else { // Only a default target. Do the equivalent of br. const byte* pos = iterator.pc(); uint32_t target = iterator.next(); if (target >= control_.size()) { error(pos, "improper branch in br_table"); break; } BreakTo(target); } // br_table ends the control flow like br. ssa_env_ = break_env; } len = 1 + iterator.length(); EndControl(); break; } case kExprReturn: { DoReturn(); break; } case kExprUnreachable: { BUILD(Unreachable, position()); EndControl(); break; } case kExprI32Const: { ImmI32Operand operand(this, pc_); Push(kWasmI32, BUILD(Int32Constant, operand.value)); len = 1 + operand.length; break; } case kExprI64Const: { ImmI64Operand operand(this, pc_); Push(kWasmI64, BUILD(Int64Constant, operand.value)); len = 1 + operand.length; break; } case kExprF32Const: { ImmF32Operand operand(this, pc_); Push(kWasmF32, BUILD(Float32Constant, operand.value)); len = 1 + operand.length; break; } case kExprF64Const: { ImmF64Operand operand(this, pc_); Push(kWasmF64, BUILD(Float64Constant, operand.value)); len = 1 + operand.length; break; } case kExprGetLocal: { LocalIndexOperand operand(this, pc_); if (Validate(pc_, operand)) { if (build()) { Push(operand.type, ssa_env_->locals[operand.index]); } else { Push(operand.type, nullptr); } } len = 1 + operand.length; break; } case kExprSetLocal: { LocalIndexOperand operand(this, pc_); if (Validate(pc_, operand)) { Value val = Pop(0, local_type_vec_[operand.index]); if (ssa_env_->locals) ssa_env_->locals[operand.index] = val.node; } len = 1 + operand.length; break; } case kExprTeeLocal: { LocalIndexOperand operand(this, pc_); if (Validate(pc_, operand)) { Value val = Pop(0, local_type_vec_[operand.index]); if (ssa_env_->locals) ssa_env_->locals[operand.index] = val.node; Push(val.type, val.node); } len = 1 + operand.length; break; } case kExprDrop: { Pop(); break; } case kExprGetGlobal: { GlobalIndexOperand operand(this, pc_); if (Validate(pc_, operand)) { Push(operand.type, BUILD(GetGlobal, operand.index)); } len = 1 + operand.length; break; } case kExprSetGlobal: { GlobalIndexOperand operand(this, pc_); if (Validate(pc_, operand)) { if (operand.global->mutability) { Value val = Pop(0, operand.type); BUILD(SetGlobal, operand.index, val.node); } else { errorf(pc_, "immutable global #%u cannot be assigned", operand.index); } } len = 1 + operand.length; break; } case kExprI32LoadMem8S: len = DecodeLoadMem(kWasmI32, MachineType::Int8()); break; case kExprI32LoadMem8U: len = DecodeLoadMem(kWasmI32, MachineType::Uint8()); break; case kExprI32LoadMem16S: len = DecodeLoadMem(kWasmI32, MachineType::Int16()); break; case kExprI32LoadMem16U: len = DecodeLoadMem(kWasmI32, MachineType::Uint16()); break; case kExprI32LoadMem: len = DecodeLoadMem(kWasmI32, MachineType::Int32()); break; case kExprI64LoadMem8S: len = DecodeLoadMem(kWasmI64, MachineType::Int8()); break; case kExprI64LoadMem8U: len = DecodeLoadMem(kWasmI64, MachineType::Uint8()); break; case kExprI64LoadMem16S: len = DecodeLoadMem(kWasmI64, MachineType::Int16()); break; case kExprI64LoadMem16U: len = DecodeLoadMem(kWasmI64, MachineType::Uint16()); break; case kExprI64LoadMem32S: len = DecodeLoadMem(kWasmI64, MachineType::Int32()); break; case kExprI64LoadMem32U: len = DecodeLoadMem(kWasmI64, MachineType::Uint32()); break; case kExprI64LoadMem: len = DecodeLoadMem(kWasmI64, MachineType::Int64()); break; case kExprF32LoadMem: len = DecodeLoadMem(kWasmF32, MachineType::Float32()); break; case kExprF64LoadMem: len = DecodeLoadMem(kWasmF64, MachineType::Float64()); break; case kExprS128LoadMem: CHECK_PROTOTYPE_OPCODE(wasm_simd_prototype); len = DecodeLoadMem(kWasmS128, MachineType::Simd128()); break; case kExprI32StoreMem8: len = DecodeStoreMem(kWasmI32, MachineType::Int8()); break; case kExprI32StoreMem16: len = DecodeStoreMem(kWasmI32, MachineType::Int16()); break; case kExprI32StoreMem: len = DecodeStoreMem(kWasmI32, MachineType::Int32()); break; case kExprI64StoreMem8: len = DecodeStoreMem(kWasmI64, MachineType::Int8()); break; case kExprI64StoreMem16: len = DecodeStoreMem(kWasmI64, MachineType::Int16()); break; case kExprI64StoreMem32: len = DecodeStoreMem(kWasmI64, MachineType::Int32()); break; case kExprI64StoreMem: len = DecodeStoreMem(kWasmI64, MachineType::Int64()); break; case kExprF32StoreMem: len = DecodeStoreMem(kWasmF32, MachineType::Float32()); break; case kExprF64StoreMem: len = DecodeStoreMem(kWasmF64, MachineType::Float64()); break; case kExprS128StoreMem: CHECK_PROTOTYPE_OPCODE(wasm_simd_prototype); len = DecodeStoreMem(kWasmS128, MachineType::Simd128()); break; case kExprGrowMemory: { if (!CheckHasMemory()) break; MemoryIndexOperand operand(this, pc_); DCHECK_NOT_NULL(module_); if (module_->is_wasm()) { Value val = Pop(0, kWasmI32); Push(kWasmI32, BUILD(GrowMemory, val.node)); } else { error("grow_memory is not supported for asmjs modules"); } len = 1 + operand.length; break; } case kExprMemorySize: { if (!CheckHasMemory()) break; MemoryIndexOperand operand(this, pc_); Push(kWasmI32, BUILD(CurrentMemoryPages)); len = 1 + operand.length; break; } case kExprCallFunction: { CallFunctionOperand operand(this, pc_); if (Validate(pc_, operand)) { TFNode** buffer = PopArgs(operand.sig); TFNode** rets = nullptr; BUILD(CallDirect, operand.index, buffer, &rets, position()); PushReturns(operand.sig, rets); } len = 1 + operand.length; break; } case kExprCallIndirect: { CallIndirectOperand operand(this, pc_); if (Validate(pc_, operand)) { Value index = Pop(0, kWasmI32); TFNode** buffer = PopArgs(operand.sig); if (buffer) buffer[0] = index.node; TFNode** rets = nullptr; BUILD(CallIndirect, operand.index, buffer, &rets, position()); PushReturns(operand.sig, rets); } len = 1 + operand.length; break; } case kSimdPrefix: { CHECK_PROTOTYPE_OPCODE(wasm_simd_prototype); len++; byte simd_index = read_u8(pc_ + 1, "simd index"); opcode = static_cast(opcode << 8 | simd_index); TRACE(" @%-4d #%-20s|", startrel(pc_), WasmOpcodes::OpcodeName(opcode)); len += DecodeSimdOpcode(opcode); break; } case kAtomicPrefix: { if (module_ == nullptr || !module_->is_asm_js()) { error("Atomics are allowed only in AsmJs modules"); break; } if (!FLAG_wasm_atomics_prototype) { error("Invalid opcode (enable with --wasm_atomics_prototype)"); break; } len = 2; byte atomic_opcode = read_u8(pc_ + 1, "atomic index"); opcode = static_cast(opcode << 8 | atomic_opcode); sig = WasmOpcodes::AtomicSignature(opcode); if (sig) { BuildAtomicOperator(opcode); } break; } default: { // Deal with special asmjs opcodes. if (module_ != nullptr && module_->is_asm_js()) { sig = WasmOpcodes::AsmjsSignature(opcode); if (sig) { BuildSimpleOperator(opcode, sig); } } else { error("Invalid opcode"); return; } } } } #if DEBUG if (FLAG_trace_wasm_decoder) { PrintF(" "); for (size_t i = 0; i < control_.size(); ++i) { Control* c = &control_[i]; enum ControlKind { kControlIf, kControlBlock, kControlLoop, kControlTry }; switch (c->kind) { case kControlIf: PrintF("I"); break; case kControlBlock: PrintF("B"); break; case kControlLoop: PrintF("L"); break; case kControlTry: PrintF("T"); break; default: break; } PrintF("%u", c->merge.arity); if (c->unreachable) PrintF("*"); } PrintF(" | "); for (size_t i = 0; i < stack_.size(); ++i) { Value& val = stack_[i]; WasmOpcode opcode = static_cast(*val.pc); if (WasmOpcodes::IsPrefixOpcode(opcode)) { opcode = static_cast(opcode << 8 | *(val.pc + 1)); } PrintF(" %c@%d:%s", WasmOpcodes::ShortNameOf(val.type), static_cast(val.pc - start_), WasmOpcodes::OpcodeName(opcode)); switch (opcode) { case kExprI32Const: { ImmI32Operand operand(this, val.pc); PrintF("[%d]", operand.value); break; } case kExprGetLocal: { LocalIndexOperand operand(this, val.pc); PrintF("[%u]", operand.index); break; } case kExprSetLocal: // fallthru case kExprTeeLocal: { LocalIndexOperand operand(this, val.pc); PrintF("[%u]", operand.index); break; } default: break; } if (val.node == nullptr) PrintF("?"); } PrintF("\n"); } #endif pc_ += len; } // end decode loop if (pc_ > end_ && ok()) error("Beyond end of code"); } void EndControl() { ssa_env_->Kill(SsaEnv::kControlEnd); if (!control_.empty()) { stack_.resize(control_.back().stack_depth); control_.back().unreachable = true; } } void SetBlockType(Control* c, BlockTypeOperand& operand) { c->merge.arity = operand.arity; if (c->merge.arity == 1) { c->merge.vals.first = {pc_, nullptr, operand.read_entry(0)}; } else if (c->merge.arity > 1) { c->merge.vals.array = zone_->NewArray(c->merge.arity); for (unsigned i = 0; i < c->merge.arity; i++) { c->merge.vals.array[i] = {pc_, nullptr, operand.read_entry(i)}; } } } TFNode** PopArgs(FunctionSig* sig) { if (build()) { int count = static_cast(sig->parameter_count()); TFNode** buffer = builder_->Buffer(count + 1); buffer[0] = nullptr; // reserved for code object or function index. for (int i = count - 1; i >= 0; i--) { buffer[i + 1] = Pop(i, sig->GetParam(i)).node; } return buffer; } else { int count = static_cast(sig->parameter_count()); for (int i = count - 1; i >= 0; i--) { Pop(i, sig->GetParam(i)); } return nullptr; } } ValueType GetReturnType(FunctionSig* sig) { return sig->return_count() == 0 ? kWasmStmt : sig->GetReturn(); } void PushBlock(SsaEnv* end_env) { control_.emplace_back( Control::Block(pc_, stack_.size(), end_env, current_catch_)); } void PushLoop(SsaEnv* end_env) { control_.emplace_back( Control::Loop(pc_, stack_.size(), end_env, current_catch_)); } void PushIf(SsaEnv* end_env, SsaEnv* false_env) { control_.emplace_back( Control::If(pc_, stack_.size(), end_env, false_env, current_catch_)); } void PushTry(SsaEnv* end_env, SsaEnv* catch_env) { control_.emplace_back(Control::Try(pc_, stack_.size(), end_env, zone_, catch_env, current_catch_)); current_catch_ = static_cast(control_.size() - 1); } void PopControl() { control_.pop_back(); } int DecodeLoadMem(ValueType type, MachineType mem_type) { if (!CheckHasMemory()) return 0; MemoryAccessOperand operand( this, pc_, ElementSizeLog2Of(mem_type.representation())); Value index = Pop(0, kWasmI32); TFNode* node = BUILD(LoadMem, type, mem_type, index.node, operand.offset, operand.alignment, position()); Push(type, node); return 1 + operand.length; } int DecodeStoreMem(ValueType type, MachineType mem_type) { if (!CheckHasMemory()) return 0; MemoryAccessOperand operand( this, pc_, ElementSizeLog2Of(mem_type.representation())); Value val = Pop(1, type); Value index = Pop(0, kWasmI32); BUILD(StoreMem, mem_type, index.node, operand.offset, operand.alignment, val.node, position()); return 1 + operand.length; } unsigned SimdExtractLane(WasmOpcode opcode, ValueType type) { SimdLaneOperand operand(this, pc_); if (Validate(pc_, opcode, operand)) { compiler::NodeVector inputs(1, zone_); inputs[0] = Pop(0, ValueType::kSimd128).node; TFNode* node = BUILD(SimdLaneOp, opcode, operand.lane, inputs); Push(type, node); } return operand.length; } unsigned SimdReplaceLane(WasmOpcode opcode, ValueType type) { SimdLaneOperand operand(this, pc_); if (Validate(pc_, opcode, operand)) { compiler::NodeVector inputs(2, zone_); inputs[1] = Pop(1, type).node; inputs[0] = Pop(0, ValueType::kSimd128).node; TFNode* node = BUILD(SimdLaneOp, opcode, operand.lane, inputs); Push(ValueType::kSimd128, node); } return operand.length; } unsigned SimdShiftOp(WasmOpcode opcode) { SimdShiftOperand operand(this, pc_); if (Validate(pc_, opcode, operand)) { compiler::NodeVector inputs(1, zone_); inputs[0] = Pop(0, ValueType::kSimd128).node; TFNode* node = BUILD(SimdShiftOp, opcode, operand.shift, inputs); Push(ValueType::kSimd128, node); } return operand.length; } unsigned SimdShuffleOp(WasmOpcode opcode) { SimdShuffleOperand operand(this, pc_, GetShuffleMaskSize(opcode)); if (Validate(pc_, opcode, operand)) { compiler::NodeVector inputs(2, zone_); inputs[1] = Pop(1, ValueType::kSimd128).node; inputs[0] = Pop(0, ValueType::kSimd128).node; TFNode* node = BUILD(SimdShuffleOp, operand.shuffle, operand.lanes, inputs); Push(ValueType::kSimd128, node); } return operand.lanes; } unsigned DecodeSimdOpcode(WasmOpcode opcode) { unsigned len = 0; switch (opcode) { case kExprF32x4ExtractLane: { len = SimdExtractLane(opcode, ValueType::kFloat32); break; } case kExprI32x4ExtractLane: case kExprI16x8ExtractLane: case kExprI8x16ExtractLane: { len = SimdExtractLane(opcode, ValueType::kWord32); break; } case kExprF32x4ReplaceLane: { len = SimdReplaceLane(opcode, ValueType::kFloat32); break; } case kExprI32x4ReplaceLane: case kExprI16x8ReplaceLane: case kExprI8x16ReplaceLane: { len = SimdReplaceLane(opcode, ValueType::kWord32); break; } case kExprI32x4Shl: case kExprI32x4ShrS: case kExprI32x4ShrU: case kExprI16x8Shl: case kExprI16x8ShrS: case kExprI16x8ShrU: case kExprI8x16Shl: case kExprI8x16ShrS: case kExprI8x16ShrU: { len = SimdShiftOp(opcode); break; } case kExprS32x4Shuffle: case kExprS16x8Shuffle: case kExprS8x16Shuffle: { len = SimdShuffleOp(opcode); break; } default: { FunctionSig* sig = WasmOpcodes::Signature(opcode); if (sig != nullptr) { compiler::NodeVector inputs(sig->parameter_count(), zone_); for (size_t i = sig->parameter_count(); i > 0; i--) { Value val = Pop(static_cast(i - 1), sig->GetParam(i - 1)); inputs[i - 1] = val.node; } TFNode* node = BUILD(SimdOp, opcode, inputs); Push(GetReturnType(sig), node); } else { error("invalid simd opcode"); } } } return len; } void BuildAtomicOperator(WasmOpcode opcode) { UNIMPLEMENTED(); } void DoReturn() { int count = static_cast(sig_->return_count()); TFNode** buffer = nullptr; if (build()) buffer = builder_->Buffer(count); // Pop return values off the stack in reverse order. for (int i = count - 1; i >= 0; i--) { Value val = Pop(i, sig_->GetReturn(i)); if (buffer) buffer[i] = val.node; } BUILD(Return, count, buffer); EndControl(); } void Push(ValueType type, TFNode* node) { if (type != kWasmStmt) { stack_.push_back({pc_, node, type}); } } void PushEndValues(Control* c) { DCHECK_EQ(c, &control_.back()); stack_.resize(c->stack_depth); if (c->merge.arity == 1) { stack_.push_back(c->merge.vals.first); } else { for (unsigned i = 0; i < c->merge.arity; i++) { stack_.push_back(c->merge.vals.array[i]); } } DCHECK_EQ(c->stack_depth + c->merge.arity, stack_.size()); } void PushReturns(FunctionSig* sig, TFNode** rets) { for (size_t i = 0; i < sig->return_count(); i++) { // When verifying only, then {rets} will be null, so push null. Push(sig->GetReturn(i), rets ? rets[i] : nullptr); } } const char* SafeOpcodeNameAt(const byte* pc) { if (pc >= end_) return ""; return WasmOpcodes::OpcodeName(static_cast(*pc)); } Value Pop(int index, ValueType expected) { Value val = Pop(); if (val.type != expected && val.type != kWasmVar && expected != kWasmVar) { errorf(val.pc, "%s[%d] expected type %s, found %s of type %s", SafeOpcodeNameAt(pc_), index, WasmOpcodes::TypeName(expected), SafeOpcodeNameAt(val.pc), WasmOpcodes::TypeName(val.type)); } return val; } Value Pop() { size_t limit = control_.empty() ? 0 : control_.back().stack_depth; if (stack_.size() <= limit) { // Popping past the current control start in reachable code. Value val = {pc_, nullptr, kWasmVar}; if (!control_.back().unreachable) { errorf(pc_, "%s found empty stack", SafeOpcodeNameAt(pc_)); } return val; } Value val = stack_.back(); stack_.pop_back(); return val; } int baserel(const byte* ptr) { return base_ ? static_cast(ptr - base_) : 0; } int startrel(const byte* ptr) { return static_cast(ptr - start_); } void BreakTo(unsigned depth) { Control* c = &control_[control_.size() - depth - 1]; if (c->is_loop()) { // This is the inner loop block, which does not have a value. Goto(ssa_env_, c->end_env); } else { // Merge the value(s) into the end of the block. size_t expected = control_.back().stack_depth + c->merge.arity; if (stack_.size() < expected && !control_.back().unreachable) { errorf( pc_, "expected at least %u values on the stack for br to @%d, found %d", c->merge.arity, startrel(c->pc), static_cast(stack_.size() - c->stack_depth)); return; } MergeValuesInto(c); } } void FallThruTo(Control* c) { DCHECK_EQ(c, &control_.back()); // Merge the value(s) into the end of the block. size_t expected = c->stack_depth + c->merge.arity; if (stack_.size() == expected || (stack_.size() < expected && c->unreachable)) { MergeValuesInto(c); c->unreachable = false; return; } errorf(pc_, "expected %u elements on the stack for fallthru to @%d", c->merge.arity, startrel(c->pc)); } inline Value& GetMergeValueFromStack(Control* c, size_t i) { return stack_[stack_.size() - c->merge.arity + i]; } void TypeCheckFallThru(Control* c) { DCHECK_EQ(c, &control_.back()); // Fallthru must match arity exactly. int arity = static_cast(c->merge.arity); if (c->stack_depth + arity < stack_.size() || (c->stack_depth + arity != stack_.size() && !c->unreachable)) { errorf(pc_, "expected %d elements on the stack for fallthru to @%d", arity, startrel(c->pc)); return; } // Typecheck the values left on the stack. size_t avail = stack_.size() - c->stack_depth; for (size_t i = avail >= c->merge.arity ? 0 : c->merge.arity - avail; i < c->merge.arity; i++) { Value& val = GetMergeValueFromStack(c, i); Value& old = c->merge[i]; if (val.type != old.type) { errorf(pc_, "type error in merge[%zu] (expected %s, got %s)", i, WasmOpcodes::TypeName(old.type), WasmOpcodes::TypeName(val.type)); return; } } } void MergeValuesInto(Control* c) { SsaEnv* target = c->end_env; bool first = target->state == SsaEnv::kUnreachable; bool reachable = ssa_env_->go(); Goto(ssa_env_, target); size_t avail = stack_.size() - control_.back().stack_depth; for (size_t i = avail >= c->merge.arity ? 0 : c->merge.arity - avail; i < c->merge.arity; i++) { Value& val = GetMergeValueFromStack(c, i); Value& old = c->merge[i]; if (val.type != old.type && val.type != kWasmVar) { errorf(pc_, "type error in merge[%zu] (expected %s, got %s)", i, WasmOpcodes::TypeName(old.type), WasmOpcodes::TypeName(val.type)); return; } if (builder_ && reachable) { DCHECK_NOT_NULL(val.node); old.node = first ? val.node : CreateOrMergeIntoPhi(old.type, target->control, old.node, val.node); } } } void SetEnv(const char* reason, SsaEnv* env) { #if DEBUG if (FLAG_trace_wasm_decoder) { char state = 'X'; if (env) { switch (env->state) { case SsaEnv::kReached: state = 'R'; break; case SsaEnv::kUnreachable: state = 'U'; break; case SsaEnv::kMerged: state = 'M'; break; case SsaEnv::kControlEnd: state = 'E'; break; } } PrintF("{set_env = %p, state = %c, reason = %s", static_cast(env), state, reason); if (env && env->control) { PrintF(", control = "); compiler::WasmGraphBuilder::PrintDebugName(env->control); } PrintF("}\n"); } #endif ssa_env_ = env; if (builder_) { builder_->set_control_ptr(&env->control); builder_->set_effect_ptr(&env->effect); } } TFNode* CheckForException(TFNode* node) { if (node == nullptr) { return nullptr; } const bool inside_try_scope = current_catch_ != kNullCatch; if (!inside_try_scope) { return node; } TFNode* if_success = nullptr; TFNode* if_exception = nullptr; if (!builder_->ThrowsException(node, &if_success, &if_exception)) { return node; } SsaEnv* success_env = Steal(ssa_env_); success_env->control = if_success; SsaEnv* exception_env = Split(success_env); exception_env->control = if_exception; TryInfo* try_info = current_try_info(); Goto(exception_env, try_info->catch_env); TFNode* exception = try_info->exception; if (exception == nullptr) { DCHECK_EQ(SsaEnv::kReached, try_info->catch_env->state); try_info->exception = if_exception; } else { DCHECK_EQ(SsaEnv::kMerged, try_info->catch_env->state); try_info->exception = CreateOrMergeIntoPhi(kWasmI32, try_info->catch_env->control, try_info->exception, if_exception); } SetEnv("if_success", success_env); return node; } void Goto(SsaEnv* from, SsaEnv* to) { DCHECK_NOT_NULL(to); if (!from->go()) return; switch (to->state) { case SsaEnv::kUnreachable: { // Overwrite destination. to->state = SsaEnv::kReached; to->locals = from->locals; to->control = from->control; to->effect = from->effect; break; } case SsaEnv::kReached: { // Create a new merge. to->state = SsaEnv::kMerged; if (!builder_) break; // Merge control. TFNode* controls[] = {to->control, from->control}; TFNode* merge = builder_->Merge(2, controls); to->control = merge; // Merge effects. if (from->effect != to->effect) { TFNode* effects[] = {to->effect, from->effect, merge}; to->effect = builder_->EffectPhi(2, effects, merge); } // Merge SSA values. for (int i = EnvironmentCount() - 1; i >= 0; i--) { TFNode* a = to->locals[i]; TFNode* b = from->locals[i]; if (a != b) { TFNode* vals[] = {a, b}; to->locals[i] = builder_->Phi(local_type_vec_[i], 2, vals, merge); } } break; } case SsaEnv::kMerged: { if (!builder_) break; TFNode* merge = to->control; // Extend the existing merge. builder_->AppendToMerge(merge, from->control); // Merge effects. if (builder_->IsPhiWithMerge(to->effect, merge)) { builder_->AppendToPhi(to->effect, from->effect); } else if (to->effect != from->effect) { uint32_t count = builder_->InputCount(merge); TFNode** effects = builder_->Buffer(count); for (uint32_t j = 0; j < count - 1; j++) { effects[j] = to->effect; } effects[count - 1] = from->effect; to->effect = builder_->EffectPhi(count, effects, merge); } // Merge locals. for (int i = EnvironmentCount() - 1; i >= 0; i--) { TFNode* tnode = to->locals[i]; TFNode* fnode = from->locals[i]; if (builder_->IsPhiWithMerge(tnode, merge)) { builder_->AppendToPhi(tnode, fnode); } else if (tnode != fnode) { uint32_t count = builder_->InputCount(merge); TFNode** vals = builder_->Buffer(count); for (uint32_t j = 0; j < count - 1; j++) { vals[j] = tnode; } vals[count - 1] = fnode; to->locals[i] = builder_->Phi(local_type_vec_[i], count, vals, merge); } } break; } default: UNREACHABLE(); } return from->Kill(); } TFNode* CreateOrMergeIntoPhi(ValueType type, TFNode* merge, TFNode* tnode, TFNode* fnode) { DCHECK_NOT_NULL(builder_); if (builder_->IsPhiWithMerge(tnode, merge)) { builder_->AppendToPhi(tnode, fnode); } else if (tnode != fnode) { uint32_t count = builder_->InputCount(merge); TFNode** vals = builder_->Buffer(count); for (uint32_t j = 0; j < count - 1; j++) vals[j] = tnode; vals[count - 1] = fnode; return builder_->Phi(type, count, vals, merge); } return tnode; } SsaEnv* PrepareForLoop(const byte* pc, SsaEnv* env) { if (!builder_) return Split(env); if (!env->go()) return Split(env); env->state = SsaEnv::kMerged; env->control = builder_->Loop(env->control); env->effect = builder_->EffectPhi(1, &env->effect, env->control); builder_->Terminate(env->effect, env->control); BitVector* assigned = AnalyzeLoopAssignment( this, pc, static_cast(total_locals()), zone_); if (failed()) return env; if (assigned != nullptr) { // Only introduce phis for variables assigned in this loop. for (int i = EnvironmentCount() - 1; i >= 0; i--) { if (!assigned->Contains(i)) continue; env->locals[i] = builder_->Phi(local_type_vec_[i], 1, &env->locals[i], env->control); } SsaEnv* loop_body_env = Split(env); builder_->StackCheck(position(), &(loop_body_env->effect), &(loop_body_env->control)); return loop_body_env; } // Conservatively introduce phis for all local variables. for (int i = EnvironmentCount() - 1; i >= 0; i--) { env->locals[i] = builder_->Phi(local_type_vec_[i], 1, &env->locals[i], env->control); } SsaEnv* loop_body_env = Split(env); builder_->StackCheck(position(), &(loop_body_env->effect), &(loop_body_env->control)); return loop_body_env; } // Create a complete copy of the {from}. SsaEnv* Split(SsaEnv* from) { DCHECK_NOT_NULL(from); SsaEnv* result = reinterpret_cast(zone_->New(sizeof(SsaEnv))); size_t size = sizeof(TFNode*) * EnvironmentCount(); result->control = from->control; result->effect = from->effect; if (from->go()) { result->state = SsaEnv::kReached; result->locals = size > 0 ? reinterpret_cast(zone_->New(size)) : nullptr; memcpy(result->locals, from->locals, size); } else { result->state = SsaEnv::kUnreachable; result->locals = nullptr; } return result; } // Create a copy of {from} that steals its state and leaves {from} // unreachable. SsaEnv* Steal(SsaEnv* from) { DCHECK_NOT_NULL(from); if (!from->go()) return UnreachableEnv(); SsaEnv* result = reinterpret_cast(zone_->New(sizeof(SsaEnv))); result->state = SsaEnv::kReached; result->locals = from->locals; result->control = from->control; result->effect = from->effect; from->Kill(SsaEnv::kUnreachable); return result; } // Create an unreachable environment. SsaEnv* UnreachableEnv() { SsaEnv* result = reinterpret_cast(zone_->New(sizeof(SsaEnv))); result->state = SsaEnv::kUnreachable; result->control = nullptr; result->effect = nullptr; result->locals = nullptr; return result; } int EnvironmentCount() { if (builder_) return static_cast(local_type_vec_.size()); return 0; // if we aren't building a graph, don't bother with SSA renaming. } virtual void onFirstError() { end_ = pc_; // Terminate decoding loop. builder_ = nullptr; // Don't build any more nodes. TRACE(" !%s\n", error_msg_.c_str()); } inline wasm::WasmCodePosition position() { int offset = static_cast(pc_ - start_); DCHECK_EQ(pc_ - start_, offset); // overflows cannot happen return offset; } inline void BuildSimpleOperator(WasmOpcode opcode, FunctionSig* sig) { TFNode* node; switch (sig->parameter_count()) { case 1: { Value val = Pop(0, sig->GetParam(0)); node = BUILD(Unop, opcode, val.node, position()); break; } case 2: { Value rval = Pop(1, sig->GetParam(1)); Value lval = Pop(0, sig->GetParam(0)); node = BUILD(Binop, opcode, lval.node, rval.node, position()); break; } default: UNREACHABLE(); node = nullptr; break; } Push(GetReturnType(sig), node); } }; bool DecodeLocalDecls(BodyLocalDecls* decls, const byte* start, const byte* end) { Decoder decoder(start, end); if (WasmDecoder::DecodeLocals(&decoder, nullptr, &decls->type_list)) { DCHECK(decoder.ok()); decls->encoded_size = decoder.pc_offset(); return true; } return false; } BytecodeIterator::BytecodeIterator(const byte* start, const byte* end, BodyLocalDecls* decls) : Decoder(start, end) { if (decls != nullptr) { if (DecodeLocalDecls(decls, start, end)) { pc_ += decls->encoded_size; if (pc_ > end_) pc_ = end_; } } } DecodeResult VerifyWasmCode(AccountingAllocator* allocator, const wasm::WasmModule* module, FunctionBody& body) { Zone zone(allocator, ZONE_NAME); WasmFullDecoder decoder(&zone, module, body); decoder.Decode(); return decoder.toResult(nullptr); } DecodeResult BuildTFGraph(AccountingAllocator* allocator, TFBuilder* builder, FunctionBody& body) { Zone zone(allocator, ZONE_NAME); WasmFullDecoder decoder(&zone, builder, body); decoder.Decode(); return decoder.toResult(nullptr); } unsigned OpcodeLength(const byte* pc, const byte* end) { Decoder decoder(pc, end); return WasmDecoder::OpcodeLength(&decoder, pc); } std::pair StackEffect(const WasmModule* module, FunctionSig* sig, const byte* pc, const byte* end) { WasmDecoder decoder(module, sig, pc, end); return decoder.StackEffect(pc); } void PrintRawWasmCode(const byte* start, const byte* end) { AccountingAllocator allocator; PrintRawWasmCode(&allocator, FunctionBodyForTesting(start, end), nullptr); } namespace { const char* RawOpcodeName(WasmOpcode opcode) { switch (opcode) { #define DECLARE_NAME_CASE(name, opcode, sig) \ case kExpr##name: \ return "kExpr" #name; FOREACH_OPCODE(DECLARE_NAME_CASE) #undef DECLARE_NAME_CASE default: break; } return "Unknown"; } } // namespace bool PrintRawWasmCode(AccountingAllocator* allocator, const FunctionBody& body, const wasm::WasmModule* module) { OFStream os(stdout); Zone zone(allocator, ZONE_NAME); WasmFullDecoder decoder(&zone, module, body); int line_nr = 0; // Print the function signature. if (body.sig) { os << "// signature: " << *body.sig << std::endl; ++line_nr; } // Print the local declarations. BodyLocalDecls decls(&zone); BytecodeIterator i(body.start, body.end, &decls); if (body.start != i.pc() && !FLAG_wasm_code_fuzzer_gen_test) { os << "// locals: "; if (!decls.type_list.empty()) { ValueType type = decls.type_list[0]; uint32_t count = 0; for (size_t pos = 0; pos < decls.type_list.size(); ++pos) { if (decls.type_list[pos] == type) { ++count; } else { os << " " << count << " " << WasmOpcodes::TypeName(type); type = decls.type_list[pos]; count = 1; } } } os << std::endl; ++line_nr; for (const byte* locals = body.start; locals < i.pc(); locals++) { os << (locals == body.start ? "0x" : " 0x") << AsHex(*locals, 2) << ","; } os << std::endl; ++line_nr; } os << "// body: " << std::endl; ++line_nr; unsigned control_depth = 0; for (; i.has_next(); i.next()) { unsigned length = WasmDecoder::OpcodeLength(&decoder, i.pc()); WasmOpcode opcode = i.current(); if (opcode == kExprElse) control_depth--; int num_whitespaces = control_depth < 32 ? 2 * control_depth : 64; // 64 whitespaces const char* padding = " "; os.write(padding, num_whitespaces); os << RawOpcodeName(opcode) << ","; for (size_t j = 1; j < length; ++j) { os << " 0x" << AsHex(i.pc()[j], 2) << ","; } switch (opcode) { case kExprElse: os << " // @" << i.pc_offset(); control_depth++; break; case kExprLoop: case kExprIf: case kExprBlock: case kExprTry: { BlockTypeOperand operand(&i, i.pc()); os << " // @" << i.pc_offset(); for (unsigned i = 0; i < operand.arity; i++) { os << " " << WasmOpcodes::TypeName(operand.read_entry(i)); } control_depth++; break; } case kExprEnd: os << " // @" << i.pc_offset(); control_depth--; break; case kExprBr: { BreakDepthOperand operand(&i, i.pc()); os << " // depth=" << operand.depth; break; } case kExprBrIf: { BreakDepthOperand operand(&i, i.pc()); os << " // depth=" << operand.depth; break; } case kExprBrTable: { BranchTableOperand operand(&i, i.pc()); os << " // entries=" << operand.table_count; break; } case kExprCallIndirect: { CallIndirectOperand operand(&i, i.pc()); os << " // sig #" << operand.index; if (decoder.Complete(i.pc(), operand)) { os << ": " << *operand.sig; } break; } case kExprCallFunction: { CallFunctionOperand operand(&i, i.pc()); os << " // function #" << operand.index; if (decoder.Complete(i.pc(), operand)) { os << ": " << *operand.sig; } break; } default: break; } os << std::endl; ++line_nr; } return decoder.ok(); } BitVector* AnalyzeLoopAssignmentForTesting(Zone* zone, size_t num_locals, const byte* start, const byte* end) { Decoder decoder(start, end); return WasmDecoder::AnalyzeLoopAssignment(&decoder, start, static_cast(num_locals), zone); } } // namespace wasm } // namespace internal } // namespace v8