| /* |
| * Copyright 2015 WebAssembly Community Group participants |
| * |
| * Licensed under the Apache License, Version 2.0 (the "License"); |
| * you may not use this file except in compliance with the License. |
| * You may obtain a copy of the License at |
| * |
| * http://www.apache.org/licenses/LICENSE-2.0 |
| * |
| * Unless required by applicable law or agreed to in writing, software |
| * distributed under the License is distributed on an "AS IS" BASIS, |
| * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. |
| * See the License for the specific language governing permissions and |
| * limitations under the License. |
| */ |
| |
| // |
| // Simple WebAssembly interpreter. This operates directly on the AST, |
| // for simplicity and clarity. A goal is for it to be possible for |
| // people to read this code and understand WebAssembly semantics. |
| // |
| |
| #ifndef wasm_wasm_interpreter_h |
| #define wasm_wasm_interpreter_h |
| |
| #include <cmath> |
| #include <limits.h> |
| #include <sstream> |
| |
| #include "ir/module-utils.h" |
| #include "support/bits.h" |
| #include "support/safe_integer.h" |
| #include "wasm-traversal.h" |
| #include "wasm.h" |
| |
| #ifdef WASM_INTERPRETER_DEBUG |
| #include "wasm-printing.h" |
| #endif |
| |
| namespace wasm { |
| |
| using namespace cashew; |
| |
| // Utilities |
| |
| extern Name WASM, RETURN_FLOW; |
| |
| // Stuff that flows around during executing expressions: a literal, or a change |
| // in control flow. |
| class Flow { |
| public: |
| Flow() = default; |
| Flow(Literal value) : value(value) {} |
| Flow(Name breakTo) : breakTo(breakTo) {} |
| |
| Literal value; |
| Name breakTo; // if non-null, a break is going on |
| |
| bool breaking() { return breakTo.is(); } |
| |
| void clearIf(Name target) { |
| if (breakTo == target) { |
| breakTo.clear(); |
| } |
| } |
| |
| friend std::ostream& operator<<(std::ostream& o, Flow& flow) { |
| o << "(flow " << (flow.breakTo.is() ? flow.breakTo.str : "-") << " : " |
| << flow.value << ')'; |
| return o; |
| } |
| }; |
| |
| // A list of literals, for function calls |
| typedef std::vector<Literal> LiteralList; |
| |
| // Debugging helpers |
| #ifdef WASM_INTERPRETER_DEBUG |
| class Indenter { |
| static int indentLevel; |
| |
| const char* entryName; |
| |
| public: |
| Indenter(const char* entry); |
| ~Indenter(); |
| |
| static void print(); |
| }; |
| |
| #define NOTE_ENTER(x) \ |
| Indenter _int_blah(x); \ |
| { \ |
| Indenter::print(); \ |
| std::cout << "visit " << x << " : " << curr << "\n"; \ |
| } |
| #define NOTE_ENTER_(x) \ |
| Indenter _int_blah(x); \ |
| { \ |
| Indenter::print(); \ |
| std::cout << "visit " << x << "\n"; \ |
| } |
| #define NOTE_NAME(p0) \ |
| { \ |
| Indenter::print(); \ |
| std::cout << "name " << '(' << Name(p0) << ")\n"; \ |
| } |
| #define NOTE_EVAL1(p0) \ |
| { \ |
| Indenter::print(); \ |
| std::cout << "eval " #p0 " (" << p0 << ")\n"; \ |
| } |
| #define NOTE_EVAL2(p0, p1) \ |
| { \ |
| Indenter::print(); \ |
| std::cout << "eval " #p0 " (" << p0 << "), " #p1 " (" << p1 << ")\n"; \ |
| } |
| #else // WASM_INTERPRETER_DEBUG |
| #define NOTE_ENTER(x) |
| #define NOTE_ENTER_(x) |
| #define NOTE_NAME(p0) |
| #define NOTE_EVAL1(p0) |
| #define NOTE_EVAL2(p0, p1) |
| #endif // WASM_INTERPRETER_DEBUG |
| |
| // Execute an expression |
| template<typename SubType> |
| class ExpressionRunner : public OverriddenVisitor<SubType, Flow> { |
| protected: |
| Index maxDepth; |
| |
| Index depth = 0; |
| |
| public: |
| ExpressionRunner(Index maxDepth) : maxDepth(maxDepth) {} |
| |
| Flow visit(Expression* curr) { |
| depth++; |
| if (depth > maxDepth) { |
| trap("interpreter recursion limit"); |
| } |
| auto ret = OverriddenVisitor<SubType, Flow>::visit(curr); |
| if (!ret.breaking() && |
| (curr->type.isConcrete() || ret.value.type.isConcrete())) { |
| #if 1 // def WASM_INTERPRETER_DEBUG |
| if (!Type::isSubType(ret.value.type, curr->type)) { |
| std::cerr << "expected " << curr->type << ", seeing " << ret.value.type |
| << " from\n" |
| << curr << '\n'; |
| } |
| #endif |
| assert(Type::isSubType(ret.value.type, curr->type)); |
| } |
| depth--; |
| return ret; |
| } |
| |
| Flow visitBlock(Block* curr) { |
| NOTE_ENTER("Block"); |
| // special-case Block, because Block nesting (in their first element) can be |
| // incredibly deep |
| std::vector<Block*> stack; |
| stack.push_back(curr); |
| while (curr->list.size() > 0 && curr->list[0]->is<Block>()) { |
| curr = curr->list[0]->cast<Block>(); |
| stack.push_back(curr); |
| } |
| Flow flow; |
| auto* top = stack.back(); |
| while (stack.size() > 0) { |
| curr = stack.back(); |
| stack.pop_back(); |
| if (flow.breaking()) { |
| flow.clearIf(curr->name); |
| continue; |
| } |
| auto& list = curr->list; |
| for (size_t i = 0; i < list.size(); i++) { |
| if (curr != top && i == 0) { |
| // one of the block recursions we already handled |
| continue; |
| } |
| flow = visit(list[i]); |
| if (flow.breaking()) { |
| flow.clearIf(curr->name); |
| break; |
| } |
| } |
| } |
| return flow; |
| } |
| Flow visitIf(If* curr) { |
| NOTE_ENTER("If"); |
| Flow flow = visit(curr->condition); |
| if (flow.breaking()) { |
| return flow; |
| } |
| NOTE_EVAL1(flow.value); |
| if (flow.value.geti32()) { |
| Flow flow = visit(curr->ifTrue); |
| if (!flow.breaking() && !curr->ifFalse) { |
| flow.value = Literal(); // if_else returns a value, but if does not |
| } |
| return flow; |
| } |
| if (curr->ifFalse) { |
| return visit(curr->ifFalse); |
| } |
| return Flow(); |
| } |
| Flow visitLoop(Loop* curr) { |
| NOTE_ENTER("Loop"); |
| while (1) { |
| Flow flow = visit(curr->body); |
| if (flow.breaking()) { |
| if (flow.breakTo == curr->name) { |
| continue; // lol |
| } |
| } |
| // loop does not loop automatically, only continue achieves that |
| return flow; |
| } |
| } |
| Flow visitBreak(Break* curr) { |
| NOTE_ENTER("Break"); |
| bool condition = true; |
| Flow flow; |
| if (curr->value) { |
| flow = visit(curr->value); |
| if (flow.breaking()) { |
| return flow; |
| } |
| } |
| if (curr->condition) { |
| Flow conditionFlow = visit(curr->condition); |
| if (conditionFlow.breaking()) { |
| return conditionFlow; |
| } |
| condition = conditionFlow.value.getInteger() != 0; |
| if (!condition) { |
| return flow; |
| } |
| } |
| flow.breakTo = curr->name; |
| return flow; |
| } |
| Flow visitSwitch(Switch* curr) { |
| NOTE_ENTER("Switch"); |
| Flow flow; |
| Literal value; |
| if (curr->value) { |
| flow = visit(curr->value); |
| if (flow.breaking()) { |
| return flow; |
| } |
| value = flow.value; |
| NOTE_EVAL1(value); |
| } |
| flow = visit(curr->condition); |
| if (flow.breaking()) { |
| return flow; |
| } |
| int64_t index = flow.value.getInteger(); |
| Name target = curr->default_; |
| if (index >= 0 && (size_t)index < curr->targets.size()) { |
| target = curr->targets[(size_t)index]; |
| } |
| flow.breakTo = target; |
| flow.value = value; |
| return flow; |
| } |
| |
| Flow visitConst(Const* curr) { |
| NOTE_ENTER("Const"); |
| NOTE_EVAL1(curr->value); |
| return Flow(curr->value); // heh |
| } |
| |
| // Unary and Binary nodes, the core math computations. We mostly just |
| // delegate to the Literal::* methods, except we handle traps here. |
| |
| Flow visitUnary(Unary* curr) { |
| NOTE_ENTER("Unary"); |
| Flow flow = visit(curr->value); |
| if (flow.breaking()) { |
| return flow; |
| } |
| Literal value = flow.value; |
| NOTE_EVAL1(value); |
| switch (curr->op) { |
| case ClzInt32: |
| case ClzInt64: |
| return value.countLeadingZeroes(); |
| case CtzInt32: |
| case CtzInt64: |
| return value.countTrailingZeroes(); |
| case PopcntInt32: |
| case PopcntInt64: |
| return value.popCount(); |
| case EqZInt32: |
| case EqZInt64: |
| return value.eqz(); |
| case ReinterpretInt32: |
| return value.castToF32(); |
| case ReinterpretInt64: |
| return value.castToF64(); |
| case ExtendSInt32: |
| return value.extendToSI64(); |
| case ExtendUInt32: |
| return value.extendToUI64(); |
| case WrapInt64: |
| return value.wrapToI32(); |
| case ConvertUInt32ToFloat32: |
| case ConvertUInt64ToFloat32: |
| return value.convertUIToF32(); |
| case ConvertUInt32ToFloat64: |
| case ConvertUInt64ToFloat64: |
| return value.convertUIToF64(); |
| case ConvertSInt32ToFloat32: |
| case ConvertSInt64ToFloat32: |
| return value.convertSIToF32(); |
| case ConvertSInt32ToFloat64: |
| case ConvertSInt64ToFloat64: |
| return value.convertSIToF64(); |
| case ExtendS8Int32: |
| case ExtendS8Int64: |
| return value.extendS8(); |
| case ExtendS16Int32: |
| case ExtendS16Int64: |
| return value.extendS16(); |
| case ExtendS32Int64: |
| return value.extendS32(); |
| |
| case NegFloat32: |
| case NegFloat64: |
| return value.neg(); |
| case AbsFloat32: |
| case AbsFloat64: |
| return value.abs(); |
| case CeilFloat32: |
| case CeilFloat64: |
| return value.ceil(); |
| case FloorFloat32: |
| case FloorFloat64: |
| return value.floor(); |
| case TruncFloat32: |
| case TruncFloat64: |
| return value.trunc(); |
| case NearestFloat32: |
| case NearestFloat64: |
| return value.nearbyint(); |
| case SqrtFloat32: |
| case SqrtFloat64: |
| return value.sqrt(); |
| case TruncSFloat32ToInt32: |
| case TruncSFloat64ToInt32: |
| case TruncSFloat32ToInt64: |
| case TruncSFloat64ToInt64: |
| return truncSFloat(curr, value); |
| case TruncUFloat32ToInt32: |
| case TruncUFloat64ToInt32: |
| case TruncUFloat32ToInt64: |
| case TruncUFloat64ToInt64: |
| return truncUFloat(curr, value); |
| case TruncSatSFloat32ToInt32: |
| case TruncSatSFloat64ToInt32: |
| return value.truncSatToSI32(); |
| case TruncSatSFloat32ToInt64: |
| case TruncSatSFloat64ToInt64: |
| return value.truncSatToSI64(); |
| case TruncSatUFloat32ToInt32: |
| case TruncSatUFloat64ToInt32: |
| return value.truncSatToUI32(); |
| case TruncSatUFloat32ToInt64: |
| case TruncSatUFloat64ToInt64: |
| return value.truncSatToUI64(); |
| case ReinterpretFloat32: |
| return value.castToI32(); |
| case PromoteFloat32: |
| return value.extendToF64(); |
| case ReinterpretFloat64: |
| return value.castToI64(); |
| case DemoteFloat64: |
| return value.demote(); |
| case SplatVecI8x16: |
| return value.splatI8x16(); |
| case SplatVecI16x8: |
| return value.splatI16x8(); |
| case SplatVecI32x4: |
| return value.splatI32x4(); |
| case SplatVecI64x2: |
| return value.splatI64x2(); |
| case SplatVecF32x4: |
| return value.splatF32x4(); |
| case SplatVecF64x2: |
| return value.splatF64x2(); |
| case NotVec128: |
| return value.notV128(); |
| case NegVecI8x16: |
| return value.negI8x16(); |
| case AnyTrueVecI8x16: |
| return value.anyTrueI8x16(); |
| case AllTrueVecI8x16: |
| return value.allTrueI8x16(); |
| case NegVecI16x8: |
| return value.negI16x8(); |
| case AnyTrueVecI16x8: |
| return value.anyTrueI16x8(); |
| case AllTrueVecI16x8: |
| return value.allTrueI16x8(); |
| case NegVecI32x4: |
| return value.negI32x4(); |
| case AnyTrueVecI32x4: |
| return value.anyTrueI32x4(); |
| case AllTrueVecI32x4: |
| return value.allTrueI32x4(); |
| case NegVecI64x2: |
| return value.negI64x2(); |
| case AnyTrueVecI64x2: |
| return value.anyTrueI64x2(); |
| case AllTrueVecI64x2: |
| return value.allTrueI64x2(); |
| case AbsVecF32x4: |
| return value.absF32x4(); |
| case NegVecF32x4: |
| return value.negF32x4(); |
| case SqrtVecF32x4: |
| return value.sqrtF32x4(); |
| case AbsVecF64x2: |
| return value.absF64x2(); |
| case NegVecF64x2: |
| return value.negF64x2(); |
| case SqrtVecF64x2: |
| return value.sqrtF64x2(); |
| case TruncSatSVecF32x4ToVecI32x4: |
| return value.truncSatToSI32x4(); |
| case TruncSatUVecF32x4ToVecI32x4: |
| return value.truncSatToUI32x4(); |
| case TruncSatSVecF64x2ToVecI64x2: |
| return value.truncSatToSI64x2(); |
| case TruncSatUVecF64x2ToVecI64x2: |
| return value.truncSatToUI64x2(); |
| case ConvertSVecI32x4ToVecF32x4: |
| return value.convertSToF32x4(); |
| case ConvertUVecI32x4ToVecF32x4: |
| return value.convertUToF32x4(); |
| case ConvertSVecI64x2ToVecF64x2: |
| return value.convertSToF64x2(); |
| case ConvertUVecI64x2ToVecF64x2: |
| return value.convertUToF64x2(); |
| case WidenLowSVecI8x16ToVecI16x8: |
| return value.widenLowSToVecI16x8(); |
| case WidenHighSVecI8x16ToVecI16x8: |
| return value.widenHighSToVecI16x8(); |
| case WidenLowUVecI8x16ToVecI16x8: |
| return value.widenLowUToVecI16x8(); |
| case WidenHighUVecI8x16ToVecI16x8: |
| return value.widenHighUToVecI16x8(); |
| case WidenLowSVecI16x8ToVecI32x4: |
| return value.widenLowSToVecI32x4(); |
| case WidenHighSVecI16x8ToVecI32x4: |
| return value.widenHighSToVecI32x4(); |
| case WidenLowUVecI16x8ToVecI32x4: |
| return value.widenLowUToVecI32x4(); |
| case WidenHighUVecI16x8ToVecI32x4: |
| return value.widenHighUToVecI32x4(); |
| case InvalidUnary: |
| WASM_UNREACHABLE("invalid unary op"); |
| } |
| WASM_UNREACHABLE("invalid op"); |
| } |
| Flow visitBinary(Binary* curr) { |
| NOTE_ENTER("Binary"); |
| Flow flow = visit(curr->left); |
| if (flow.breaking()) { |
| return flow; |
| } |
| Literal left = flow.value; |
| flow = visit(curr->right); |
| if (flow.breaking()) { |
| return flow; |
| } |
| Literal right = flow.value; |
| NOTE_EVAL2(left, right); |
| assert(curr->left->type.isConcrete() ? left.type == curr->left->type |
| : true); |
| assert(curr->right->type.isConcrete() ? right.type == curr->right->type |
| : true); |
| switch (curr->op) { |
| case AddInt32: |
| case AddInt64: |
| case AddFloat32: |
| case AddFloat64: |
| return left.add(right); |
| case SubInt32: |
| case SubInt64: |
| case SubFloat32: |
| case SubFloat64: |
| return left.sub(right); |
| case MulInt32: |
| case MulInt64: |
| case MulFloat32: |
| case MulFloat64: |
| return left.mul(right); |
| case DivSInt32: { |
| if (right.getInteger() == 0) { |
| trap("i32.div_s by 0"); |
| } |
| if (left.getInteger() == std::numeric_limits<int32_t>::min() && |
| right.getInteger() == -1) { |
| trap("i32.div_s overflow"); // signed division overflow |
| } |
| return left.divS(right); |
| } |
| case DivUInt32: { |
| if (right.getInteger() == 0) { |
| trap("i32.div_u by 0"); |
| } |
| return left.divU(right); |
| } |
| case RemSInt32: { |
| if (right.getInteger() == 0) { |
| trap("i32.rem_s by 0"); |
| } |
| if (left.getInteger() == std::numeric_limits<int32_t>::min() && |
| right.getInteger() == -1) { |
| return Literal(int32_t(0)); |
| } |
| return left.remS(right); |
| } |
| case RemUInt32: { |
| if (right.getInteger() == 0) { |
| trap("i32.rem_u by 0"); |
| } |
| return left.remU(right); |
| } |
| case DivSInt64: { |
| if (right.getInteger() == 0) { |
| trap("i64.div_s by 0"); |
| } |
| if (left.getInteger() == LLONG_MIN && right.getInteger() == -1LL) { |
| trap("i64.div_s overflow"); // signed division overflow |
| } |
| return left.divS(right); |
| } |
| case DivUInt64: { |
| if (right.getInteger() == 0) { |
| trap("i64.div_u by 0"); |
| } |
| return left.divU(right); |
| } |
| case RemSInt64: { |
| if (right.getInteger() == 0) { |
| trap("i64.rem_s by 0"); |
| } |
| if (left.getInteger() == LLONG_MIN && right.getInteger() == -1LL) { |
| return Literal(int64_t(0)); |
| } |
| return left.remS(right); |
| } |
| case RemUInt64: { |
| if (right.getInteger() == 0) { |
| trap("i64.rem_u by 0"); |
| } |
| return left.remU(right); |
| } |
| case DivFloat32: |
| case DivFloat64: |
| return left.div(right); |
| case AndInt32: |
| case AndInt64: |
| return left.and_(right); |
| case OrInt32: |
| case OrInt64: |
| return left.or_(right); |
| case XorInt32: |
| case XorInt64: |
| return left.xor_(right); |
| case ShlInt32: |
| case ShlInt64: |
| return left.shl(right); |
| case ShrUInt32: |
| case ShrUInt64: |
| return left.shrU(right); |
| case ShrSInt32: |
| case ShrSInt64: |
| return left.shrS(right); |
| case RotLInt32: |
| case RotLInt64: |
| return left.rotL(right); |
| case RotRInt32: |
| case RotRInt64: |
| return left.rotR(right); |
| |
| case EqInt32: |
| case EqInt64: |
| case EqFloat32: |
| case EqFloat64: |
| return left.eq(right); |
| case NeInt32: |
| case NeInt64: |
| case NeFloat32: |
| case NeFloat64: |
| return left.ne(right); |
| case LtSInt32: |
| case LtSInt64: |
| return left.ltS(right); |
| case LtUInt32: |
| case LtUInt64: |
| return left.ltU(right); |
| case LeSInt32: |
| case LeSInt64: |
| return left.leS(right); |
| case LeUInt32: |
| case LeUInt64: |
| return left.leU(right); |
| case GtSInt32: |
| case GtSInt64: |
| return left.gtS(right); |
| case GtUInt32: |
| case GtUInt64: |
| return left.gtU(right); |
| case GeSInt32: |
| case GeSInt64: |
| return left.geS(right); |
| case GeUInt32: |
| case GeUInt64: |
| return left.geU(right); |
| case LtFloat32: |
| case LtFloat64: |
| return left.lt(right); |
| case LeFloat32: |
| case LeFloat64: |
| return left.le(right); |
| case GtFloat32: |
| case GtFloat64: |
| return left.gt(right); |
| case GeFloat32: |
| case GeFloat64: |
| return left.ge(right); |
| |
| case CopySignFloat32: |
| case CopySignFloat64: |
| return left.copysign(right); |
| case MinFloat32: |
| case MinFloat64: |
| return left.min(right); |
| case MaxFloat32: |
| case MaxFloat64: |
| return left.max(right); |
| |
| case EqVecI8x16: |
| return left.eqI8x16(right); |
| case NeVecI8x16: |
| return left.neI8x16(right); |
| case LtSVecI8x16: |
| return left.ltSI8x16(right); |
| case LtUVecI8x16: |
| return left.ltUI8x16(right); |
| case GtSVecI8x16: |
| return left.gtSI8x16(right); |
| case GtUVecI8x16: |
| return left.gtUI8x16(right); |
| case LeSVecI8x16: |
| return left.leSI8x16(right); |
| case LeUVecI8x16: |
| return left.leUI8x16(right); |
| case GeSVecI8x16: |
| return left.geSI8x16(right); |
| case GeUVecI8x16: |
| return left.geUI8x16(right); |
| case EqVecI16x8: |
| return left.eqI16x8(right); |
| case NeVecI16x8: |
| return left.neI16x8(right); |
| case LtSVecI16x8: |
| return left.ltSI16x8(right); |
| case LtUVecI16x8: |
| return left.ltUI16x8(right); |
| case GtSVecI16x8: |
| return left.gtSI16x8(right); |
| case GtUVecI16x8: |
| return left.gtUI16x8(right); |
| case LeSVecI16x8: |
| return left.leSI16x8(right); |
| case LeUVecI16x8: |
| return left.leUI16x8(right); |
| case GeSVecI16x8: |
| return left.geSI16x8(right); |
| case GeUVecI16x8: |
| return left.geUI16x8(right); |
| case EqVecI32x4: |
| return left.eqI32x4(right); |
| case NeVecI32x4: |
| return left.neI32x4(right); |
| case LtSVecI32x4: |
| return left.ltSI32x4(right); |
| case LtUVecI32x4: |
| return left.ltUI32x4(right); |
| case GtSVecI32x4: |
| return left.gtSI32x4(right); |
| case GtUVecI32x4: |
| return left.gtUI32x4(right); |
| case LeSVecI32x4: |
| return left.leSI32x4(right); |
| case LeUVecI32x4: |
| return left.leUI32x4(right); |
| case GeSVecI32x4: |
| return left.geSI32x4(right); |
| case GeUVecI32x4: |
| return left.geUI32x4(right); |
| case EqVecF32x4: |
| return left.eqF32x4(right); |
| case NeVecF32x4: |
| return left.neF32x4(right); |
| case LtVecF32x4: |
| return left.ltF32x4(right); |
| case GtVecF32x4: |
| return left.gtF32x4(right); |
| case LeVecF32x4: |
| return left.leF32x4(right); |
| case GeVecF32x4: |
| return left.geF32x4(right); |
| case EqVecF64x2: |
| return left.eqF64x2(right); |
| case NeVecF64x2: |
| return left.neF64x2(right); |
| case LtVecF64x2: |
| return left.ltF64x2(right); |
| case GtVecF64x2: |
| return left.gtF64x2(right); |
| case LeVecF64x2: |
| return left.leF64x2(right); |
| case GeVecF64x2: |
| return left.geF64x2(right); |
| |
| case AndVec128: |
| return left.andV128(right); |
| case OrVec128: |
| return left.orV128(right); |
| case XorVec128: |
| return left.xorV128(right); |
| case AndNotVec128: |
| return left.andV128(right.notV128()); |
| |
| case AddVecI8x16: |
| return left.addI8x16(right); |
| case AddSatSVecI8x16: |
| return left.addSaturateSI8x16(right); |
| case AddSatUVecI8x16: |
| return left.addSaturateUI8x16(right); |
| case SubVecI8x16: |
| return left.subI8x16(right); |
| case SubSatSVecI8x16: |
| return left.subSaturateSI8x16(right); |
| case SubSatUVecI8x16: |
| return left.subSaturateUI8x16(right); |
| case MulVecI8x16: |
| return left.mulI8x16(right); |
| case MinSVecI8x16: |
| return left.minSI8x16(right); |
| case MinUVecI8x16: |
| return left.minUI8x16(right); |
| case MaxSVecI8x16: |
| return left.maxSI8x16(right); |
| case MaxUVecI8x16: |
| return left.maxUI8x16(right); |
| case AvgrUVecI8x16: |
| return left.avgrUI8x16(right); |
| case AddVecI16x8: |
| return left.addI16x8(right); |
| case AddSatSVecI16x8: |
| return left.addSaturateSI16x8(right); |
| case AddSatUVecI16x8: |
| return left.addSaturateUI16x8(right); |
| case SubVecI16x8: |
| return left.subI16x8(right); |
| case SubSatSVecI16x8: |
| return left.subSaturateSI16x8(right); |
| case SubSatUVecI16x8: |
| return left.subSaturateUI16x8(right); |
| case MulVecI16x8: |
| return left.mulI16x8(right); |
| case MinSVecI16x8: |
| return left.minSI16x8(right); |
| case MinUVecI16x8: |
| return left.minUI16x8(right); |
| case MaxSVecI16x8: |
| return left.maxSI16x8(right); |
| case MaxUVecI16x8: |
| return left.maxUI16x8(right); |
| case AvgrUVecI16x8: |
| return left.avgrUI16x8(right); |
| case AddVecI32x4: |
| return left.addI32x4(right); |
| case SubVecI32x4: |
| return left.subI32x4(right); |
| case MulVecI32x4: |
| return left.mulI32x4(right); |
| case MinSVecI32x4: |
| return left.minSI32x4(right); |
| case MinUVecI32x4: |
| return left.minUI32x4(right); |
| case MaxSVecI32x4: |
| return left.maxSI32x4(right); |
| case MaxUVecI32x4: |
| return left.maxUI32x4(right); |
| case DotSVecI16x8ToVecI32x4: |
| return left.dotSI16x8toI32x4(right); |
| case AddVecI64x2: |
| return left.addI64x2(right); |
| case SubVecI64x2: |
| return left.subI64x2(right); |
| |
| case AddVecF32x4: |
| return left.addF32x4(right); |
| case SubVecF32x4: |
| return left.subF32x4(right); |
| case MulVecF32x4: |
| return left.mulF32x4(right); |
| case DivVecF32x4: |
| return left.divF32x4(right); |
| case MinVecF32x4: |
| return left.minF32x4(right); |
| case MaxVecF32x4: |
| return left.maxF32x4(right); |
| case AddVecF64x2: |
| return left.addF64x2(right); |
| case SubVecF64x2: |
| return left.subF64x2(right); |
| case MulVecF64x2: |
| return left.mulF64x2(right); |
| case DivVecF64x2: |
| return left.divF64x2(right); |
| case MinVecF64x2: |
| return left.minF64x2(right); |
| case MaxVecF64x2: |
| return left.maxF64x2(right); |
| |
| case NarrowSVecI16x8ToVecI8x16: |
| return left.narrowSToVecI8x16(right); |
| case NarrowUVecI16x8ToVecI8x16: |
| return left.narrowUToVecI8x16(right); |
| case NarrowSVecI32x4ToVecI16x8: |
| return left.narrowSToVecI16x8(right); |
| case NarrowUVecI32x4ToVecI16x8: |
| return left.narrowUToVecI16x8(right); |
| |
| case SwizzleVec8x16: |
| return left.swizzleVec8x16(right); |
| |
| case InvalidBinary: |
| WASM_UNREACHABLE("invalid binary op"); |
| } |
| WASM_UNREACHABLE("invalid op"); |
| } |
| Flow visitSIMDExtract(SIMDExtract* curr) { |
| NOTE_ENTER("SIMDExtract"); |
| Flow flow = this->visit(curr->vec); |
| if (flow.breaking()) { |
| return flow; |
| } |
| Literal vec = flow.value; |
| switch (curr->op) { |
| case ExtractLaneSVecI8x16: |
| return vec.extractLaneSI8x16(curr->index); |
| case ExtractLaneUVecI8x16: |
| return vec.extractLaneUI8x16(curr->index); |
| case ExtractLaneSVecI16x8: |
| return vec.extractLaneSI16x8(curr->index); |
| case ExtractLaneUVecI16x8: |
| return vec.extractLaneUI16x8(curr->index); |
| case ExtractLaneVecI32x4: |
| return vec.extractLaneI32x4(curr->index); |
| case ExtractLaneVecI64x2: |
| return vec.extractLaneI64x2(curr->index); |
| case ExtractLaneVecF32x4: |
| return vec.extractLaneF32x4(curr->index); |
| case ExtractLaneVecF64x2: |
| return vec.extractLaneF64x2(curr->index); |
| } |
| WASM_UNREACHABLE("invalid op"); |
| } |
| Flow visitSIMDReplace(SIMDReplace* curr) { |
| NOTE_ENTER("SIMDReplace"); |
| Flow flow = this->visit(curr->vec); |
| if (flow.breaking()) { |
| return flow; |
| } |
| Literal vec = flow.value; |
| flow = this->visit(curr->value); |
| if (flow.breaking()) { |
| return flow; |
| } |
| Literal value = flow.value; |
| switch (curr->op) { |
| case ReplaceLaneVecI8x16: |
| return vec.replaceLaneI8x16(value, curr->index); |
| case ReplaceLaneVecI16x8: |
| return vec.replaceLaneI16x8(value, curr->index); |
| case ReplaceLaneVecI32x4: |
| return vec.replaceLaneI32x4(value, curr->index); |
| case ReplaceLaneVecI64x2: |
| return vec.replaceLaneI64x2(value, curr->index); |
| case ReplaceLaneVecF32x4: |
| return vec.replaceLaneF32x4(value, curr->index); |
| case ReplaceLaneVecF64x2: |
| return vec.replaceLaneF64x2(value, curr->index); |
| } |
| WASM_UNREACHABLE("invalid op"); |
| } |
| Flow visitSIMDShuffle(SIMDShuffle* curr) { |
| NOTE_ENTER("SIMDShuffle"); |
| Flow flow = this->visit(curr->left); |
| if (flow.breaking()) { |
| return flow; |
| } |
| Literal left = flow.value; |
| flow = this->visit(curr->right); |
| if (flow.breaking()) { |
| return flow; |
| } |
| Literal right = flow.value; |
| return left.shuffleV8x16(right, curr->mask); |
| } |
| Flow visitSIMDTernary(SIMDTernary* curr) { |
| NOTE_ENTER("SIMDBitselect"); |
| Flow flow = this->visit(curr->a); |
| if (flow.breaking()) { |
| return flow; |
| } |
| Literal a = flow.value; |
| flow = this->visit(curr->b); |
| if (flow.breaking()) { |
| return flow; |
| } |
| Literal b = flow.value; |
| flow = this->visit(curr->c); |
| if (flow.breaking()) { |
| return flow; |
| } |
| Literal c = flow.value; |
| switch (curr->op) { |
| case Bitselect: |
| return c.bitselectV128(a, b); |
| default: |
| // TODO: implement qfma/qfms |
| WASM_UNREACHABLE("not implemented"); |
| } |
| } |
| Flow visitSIMDShift(SIMDShift* curr) { |
| NOTE_ENTER("SIMDShift"); |
| Flow flow = this->visit(curr->vec); |
| if (flow.breaking()) { |
| return flow; |
| } |
| Literal vec = flow.value; |
| flow = this->visit(curr->shift); |
| if (flow.breaking()) { |
| return flow; |
| } |
| Literal shift = flow.value; |
| switch (curr->op) { |
| case ShlVecI8x16: |
| return vec.shlI8x16(shift); |
| case ShrSVecI8x16: |
| return vec.shrSI8x16(shift); |
| case ShrUVecI8x16: |
| return vec.shrUI8x16(shift); |
| case ShlVecI16x8: |
| return vec.shlI16x8(shift); |
| case ShrSVecI16x8: |
| return vec.shrSI16x8(shift); |
| case ShrUVecI16x8: |
| return vec.shrUI16x8(shift); |
| case ShlVecI32x4: |
| return vec.shlI32x4(shift); |
| case ShrSVecI32x4: |
| return vec.shrSI32x4(shift); |
| case ShrUVecI32x4: |
| return vec.shrUI32x4(shift); |
| case ShlVecI64x2: |
| return vec.shlI64x2(shift); |
| case ShrSVecI64x2: |
| return vec.shrSI64x2(shift); |
| case ShrUVecI64x2: |
| return vec.shrUI64x2(shift); |
| } |
| WASM_UNREACHABLE("invalid op"); |
| } |
| Flow visitSelect(Select* curr) { |
| NOTE_ENTER("Select"); |
| Flow ifTrue = visit(curr->ifTrue); |
| if (ifTrue.breaking()) { |
| return ifTrue; |
| } |
| Flow ifFalse = visit(curr->ifFalse); |
| if (ifFalse.breaking()) { |
| return ifFalse; |
| } |
| Flow condition = visit(curr->condition); |
| if (condition.breaking()) { |
| return condition; |
| } |
| NOTE_EVAL1(condition.value); |
| return condition.value.geti32() ? ifTrue : ifFalse; // ;-) |
| } |
| Flow visitDrop(Drop* curr) { |
| NOTE_ENTER("Drop"); |
| Flow value = visit(curr->value); |
| if (value.breaking()) { |
| return value; |
| } |
| return Flow(); |
| } |
| Flow visitReturn(Return* curr) { |
| NOTE_ENTER("Return"); |
| Flow flow; |
| if (curr->value) { |
| flow = visit(curr->value); |
| if (flow.breaking()) { |
| return flow; |
| } |
| NOTE_EVAL1(flow.value); |
| } |
| flow.breakTo = RETURN_FLOW; |
| return flow; |
| } |
| Flow visitNop(Nop* curr) { |
| NOTE_ENTER("Nop"); |
| return Flow(); |
| } |
| Flow visitUnreachable(Unreachable* curr) { |
| NOTE_ENTER("Unreachable"); |
| trap("unreachable"); |
| WASM_UNREACHABLE("unreachable"); |
| } |
| |
| Literal truncSFloat(Unary* curr, Literal value) { |
| double val = value.getFloat(); |
| if (std::isnan(val)) { |
| trap("truncSFloat of nan"); |
| } |
| if (curr->type == Type::i32) { |
| if (value.type == Type::f32) { |
| if (!isInRangeI32TruncS(value.reinterpreti32())) { |
| trap("i32.truncSFloat overflow"); |
| } |
| } else { |
| if (!isInRangeI32TruncS(value.reinterpreti64())) { |
| trap("i32.truncSFloat overflow"); |
| } |
| } |
| return Literal(int32_t(val)); |
| } else { |
| if (value.type == Type::f32) { |
| if (!isInRangeI64TruncS(value.reinterpreti32())) { |
| trap("i64.truncSFloat overflow"); |
| } |
| } else { |
| if (!isInRangeI64TruncS(value.reinterpreti64())) { |
| trap("i64.truncSFloat overflow"); |
| } |
| } |
| return Literal(int64_t(val)); |
| } |
| } |
| |
| Literal truncUFloat(Unary* curr, Literal value) { |
| double val = value.getFloat(); |
| if (std::isnan(val)) { |
| trap("truncUFloat of nan"); |
| } |
| if (curr->type == Type::i32) { |
| if (value.type == Type::f32) { |
| if (!isInRangeI32TruncU(value.reinterpreti32())) { |
| trap("i32.truncUFloat overflow"); |
| } |
| } else { |
| if (!isInRangeI32TruncU(value.reinterpreti64())) { |
| trap("i32.truncUFloat overflow"); |
| } |
| } |
| return Literal(uint32_t(val)); |
| } else { |
| if (value.type == Type::f32) { |
| if (!isInRangeI64TruncU(value.reinterpreti32())) { |
| trap("i64.truncUFloat overflow"); |
| } |
| } else { |
| if (!isInRangeI64TruncU(value.reinterpreti64())) { |
| trap("i64.truncUFloat overflow"); |
| } |
| } |
| return Literal(uint64_t(val)); |
| } |
| } |
| Flow visitAtomicFence(AtomicFence* curr) { |
| // Wasm currently supports only sequentially consistent atomics, in which |
| // case atomic_fence can be lowered to nothing. |
| NOTE_ENTER("AtomicFence"); |
| return Flow(); |
| } |
| |
| Flow visitCall(Call*) { WASM_UNREACHABLE("unimp"); } |
| Flow visitCallIndirect(CallIndirect*) { WASM_UNREACHABLE("unimp"); } |
| Flow visitLocalGet(LocalGet*) { WASM_UNREACHABLE("unimp"); } |
| Flow visitLocalSet(LocalSet*) { WASM_UNREACHABLE("unimp"); } |
| Flow visitGlobalSet(GlobalSet*) { WASM_UNREACHABLE("unimp"); } |
| Flow visitLoad(Load* curr) { WASM_UNREACHABLE("unimp"); } |
| Flow visitStore(Store* curr) { WASM_UNREACHABLE("unimp"); } |
| Flow visitHost(Host* curr) { WASM_UNREACHABLE("unimp"); } |
| Flow visitMemoryInit(MemoryInit* curr) { WASM_UNREACHABLE("unimp"); } |
| Flow visitDataDrop(DataDrop* curr) { WASM_UNREACHABLE("unimp"); } |
| Flow visitMemoryCopy(MemoryCopy* curr) { WASM_UNREACHABLE("unimp"); } |
| Flow visitMemoryFill(MemoryFill* curr) { WASM_UNREACHABLE("unimp"); } |
| Flow visitAtomicRMW(AtomicRMW*) { WASM_UNREACHABLE("unimp"); } |
| Flow visitAtomicCmpxchg(AtomicCmpxchg*) { WASM_UNREACHABLE("unimp"); } |
| Flow visitAtomicWait(AtomicWait*) { WASM_UNREACHABLE("unimp"); } |
| Flow visitAtomicNotify(AtomicNotify*) { WASM_UNREACHABLE("unimp"); } |
| Flow visitSIMDLoad(SIMDLoad*) { WASM_UNREACHABLE("unimp"); } |
| Flow visitSIMDLoadSplat(SIMDLoad*) { WASM_UNREACHABLE("unimp"); } |
| Flow visitSIMDLoadExtend(SIMDLoad*) { WASM_UNREACHABLE("unimp"); } |
| Flow visitPush(Push*) { WASM_UNREACHABLE("unimp"); } |
| Flow visitPop(Pop*) { WASM_UNREACHABLE("unimp"); } |
| Flow visitRefNull(RefNull* curr) { |
| NOTE_ENTER("RefNull"); |
| return Literal::makeNullref(); |
| } |
| Flow visitRefIsNull(RefIsNull* curr) { |
| NOTE_ENTER("RefIsNull"); |
| Flow flow = visit(curr->value); |
| if (flow.breaking()) { |
| return flow; |
| } |
| Literal value = flow.value; |
| NOTE_EVAL1(value); |
| return Literal(value.type == Type::nullref); |
| } |
| Flow visitRefFunc(RefFunc* curr) { |
| NOTE_ENTER("RefFunc"); |
| NOTE_NAME(curr->func); |
| return Literal::makeFuncref(curr->func); |
| } |
| // TODO Implement EH instructions |
| Flow visitTry(Try*) { WASM_UNREACHABLE("unimp"); } |
| Flow visitThrow(Throw*) { WASM_UNREACHABLE("unimp"); } |
| Flow visitRethrow(Rethrow*) { WASM_UNREACHABLE("unimp"); } |
| Flow visitBrOnExn(BrOnExn*) { WASM_UNREACHABLE("unimp"); } |
| |
| virtual void trap(const char* why) { WASM_UNREACHABLE("unimp"); } |
| }; |
| |
| // Execute an constant expression in a global init or memory offset. |
| template<typename GlobalManager> |
| class ConstantExpressionRunner |
| : public ExpressionRunner<ConstantExpressionRunner<GlobalManager>> { |
| GlobalManager& globals; |
| |
| public: |
| ConstantExpressionRunner(GlobalManager& globals, Index maxDepth) |
| : ExpressionRunner<ConstantExpressionRunner<GlobalManager>>(maxDepth), |
| globals(globals) {} |
| |
| Flow visitGlobalGet(GlobalGet* curr) { return Flow(globals[curr->name]); } |
| }; |
| |
| // |
| // An instance of a WebAssembly module, which can execute it via AST |
| // interpretation. |
| // |
| // To embed this interpreter, you need to provide an ExternalInterface instance |
| // (see below) which provides the embedding-specific details, that is, how to |
| // connect to the embedding implementation. |
| // |
| // To call into the interpreter, use callExport. |
| // |
| |
| template<typename GlobalManager, typename SubType> class ModuleInstanceBase { |
| public: |
| // |
| // You need to implement one of these to create a concrete interpreter. The |
| // ExternalInterface provides embedding-specific functionality like calling |
| // an imported function or accessing memory. |
| // |
| struct ExternalInterface { |
| virtual void init(Module& wasm, SubType& instance) {} |
| virtual void importGlobals(GlobalManager& globals, Module& wasm) = 0; |
| virtual Literal callImport(Function* import, LiteralList& arguments) = 0; |
| virtual Literal callTable(Index index, |
| Signature sig, |
| LiteralList& arguments, |
| Type result, |
| SubType& instance) = 0; |
| virtual void growMemory(Address oldSize, Address newSize) = 0; |
| virtual void trap(const char* why) = 0; |
| |
| // the default impls for load and store switch on the sizes. you can either |
| // customize load/store, or the sub-functions which they call |
| virtual Literal load(Load* load, Address addr) { |
| switch (load->type.getSingle()) { |
| case Type::i32: { |
| switch (load->bytes) { |
| case 1: |
| return load->signed_ ? Literal((int32_t)load8s(addr)) |
| : Literal((int32_t)load8u(addr)); |
| case 2: |
| return load->signed_ ? Literal((int32_t)load16s(addr)) |
| : Literal((int32_t)load16u(addr)); |
| case 4: |
| return Literal((int32_t)load32s(addr)); |
| default: |
| WASM_UNREACHABLE("invalid size"); |
| } |
| break; |
| } |
| case Type::i64: { |
| switch (load->bytes) { |
| case 1: |
| return load->signed_ ? Literal((int64_t)load8s(addr)) |
| : Literal((int64_t)load8u(addr)); |
| case 2: |
| return load->signed_ ? Literal((int64_t)load16s(addr)) |
| : Literal((int64_t)load16u(addr)); |
| case 4: |
| return load->signed_ ? Literal((int64_t)load32s(addr)) |
| : Literal((int64_t)load32u(addr)); |
| case 8: |
| return Literal((int64_t)load64s(addr)); |
| default: |
| WASM_UNREACHABLE("invalid size"); |
| } |
| break; |
| } |
| case Type::f32: |
| return Literal(load32u(addr)).castToF32(); |
| case Type::f64: |
| return Literal(load64u(addr)).castToF64(); |
| case Type::v128: |
| return Literal(load128(addr).data()); |
| case Type::funcref: |
| case Type::anyref: |
| case Type::nullref: |
| case Type::exnref: |
| case Type::none: |
| case Type::unreachable: |
| WASM_UNREACHABLE("unexpected type"); |
| } |
| WASM_UNREACHABLE("invalid type"); |
| } |
| virtual void store(Store* store, Address addr, Literal value) { |
| switch (store->valueType.getSingle()) { |
| case Type::i32: { |
| switch (store->bytes) { |
| case 1: |
| store8(addr, value.geti32()); |
| break; |
| case 2: |
| store16(addr, value.geti32()); |
| break; |
| case 4: |
| store32(addr, value.geti32()); |
| break; |
| default: |
| WASM_UNREACHABLE("invalid store size"); |
| } |
| break; |
| } |
| case Type::i64: { |
| switch (store->bytes) { |
| case 1: |
| store8(addr, value.geti64()); |
| break; |
| case 2: |
| store16(addr, value.geti64()); |
| break; |
| case 4: |
| store32(addr, value.geti64()); |
| break; |
| case 8: |
| store64(addr, value.geti64()); |
| break; |
| default: |
| WASM_UNREACHABLE("invalid store size"); |
| } |
| break; |
| } |
| // write floats carefully, ensuring all bits reach memory |
| case Type::f32: |
| store32(addr, value.reinterpreti32()); |
| break; |
| case Type::f64: |
| store64(addr, value.reinterpreti64()); |
| break; |
| case Type::v128: |
| store128(addr, value.getv128()); |
| break; |
| case Type::funcref: |
| case Type::anyref: |
| case Type::nullref: |
| case Type::exnref: |
| case Type::none: |
| case Type::unreachable: |
| WASM_UNREACHABLE("unexpected type"); |
| } |
| } |
| |
| virtual int8_t load8s(Address addr) { WASM_UNREACHABLE("unimp"); } |
| virtual uint8_t load8u(Address addr) { WASM_UNREACHABLE("unimp"); } |
| virtual int16_t load16s(Address addr) { WASM_UNREACHABLE("unimp"); } |
| virtual uint16_t load16u(Address addr) { WASM_UNREACHABLE("unimp"); } |
| virtual int32_t load32s(Address addr) { WASM_UNREACHABLE("unimp"); } |
| virtual uint32_t load32u(Address addr) { WASM_UNREACHABLE("unimp"); } |
| virtual int64_t load64s(Address addr) { WASM_UNREACHABLE("unimp"); } |
| virtual uint64_t load64u(Address addr) { WASM_UNREACHABLE("unimp"); } |
| virtual std::array<uint8_t, 16> load128(Address addr) { |
| WASM_UNREACHABLE("unimp"); |
| } |
| |
| virtual void store8(Address addr, int8_t value) { |
| WASM_UNREACHABLE("unimp"); |
| } |
| virtual void store16(Address addr, int16_t value) { |
| WASM_UNREACHABLE("unimp"); |
| } |
| virtual void store32(Address addr, int32_t value) { |
| WASM_UNREACHABLE("unimp"); |
| } |
| virtual void store64(Address addr, int64_t value) { |
| WASM_UNREACHABLE("unimp"); |
| } |
| virtual void store128(Address addr, const std::array<uint8_t, 16>&) { |
| WASM_UNREACHABLE("unimp"); |
| } |
| |
| virtual void tableStore(Address addr, Name entry) { |
| WASM_UNREACHABLE("unimp"); |
| } |
| }; |
| |
| SubType* self() { return static_cast<SubType*>(this); } |
| |
| Module& wasm; |
| |
| // Values of globals |
| GlobalManager globals; |
| |
| // Multivalue ABI support (see push/pop). |
| std::vector<Literal> multiValues; |
| |
| ModuleInstanceBase(Module& wasm, ExternalInterface* externalInterface) |
| : wasm(wasm), externalInterface(externalInterface) { |
| // import globals from the outside |
| externalInterface->importGlobals(globals, wasm); |
| // prepare memory |
| memorySize = wasm.memory.initial; |
| // generate internal (non-imported) globals |
| ModuleUtils::iterDefinedGlobals(wasm, [&](Global* global) { |
| globals[global->name] = |
| ConstantExpressionRunner<GlobalManager>(globals, maxDepth) |
| .visit(global->init) |
| .value; |
| }); |
| |
| // initialize the rest of the external interface |
| externalInterface->init(wasm, *self()); |
| |
| initializeTableContents(); |
| initializeMemoryContents(); |
| |
| // run start, if present |
| if (wasm.start.is()) { |
| LiteralList arguments; |
| callFunction(wasm.start, arguments); |
| } |
| } |
| |
| // call an exported function |
| Literal callExport(Name name, const LiteralList& arguments) { |
| Export* export_ = wasm.getExportOrNull(name); |
| if (!export_) { |
| externalInterface->trap("callExport not found"); |
| } |
| return callFunction(export_->value, arguments); |
| } |
| |
| Literal callExport(Name name) { return callExport(name, LiteralList()); } |
| |
| // get an exported global |
| Literal getExport(Name name) { |
| Export* export_ = wasm.getExportOrNull(name); |
| if (!export_) { |
| externalInterface->trap("getExport external not found"); |
| } |
| Name internalName = export_->value; |
| auto iter = globals.find(internalName); |
| if (iter == globals.end()) { |
| externalInterface->trap("getExport internal not found"); |
| } |
| return iter->second; |
| } |
| |
| std::string printFunctionStack() { |
| std::string ret = "/== (binaryen interpreter stack trace)\n"; |
| for (int i = int(functionStack.size()) - 1; i >= 0; i--) { |
| ret += std::string("|: ") + functionStack[i].str + "\n"; |
| } |
| ret += std::string("\\==\n"); |
| return ret; |
| } |
| |
| private: |
| // Keep a record of call depth, to guard against excessive recursion. |
| size_t callDepth; |
| |
| // Function name stack. We maintain this explicitly to allow printing of |
| // stack traces. |
| std::vector<Name> functionStack; |
| |
| std::unordered_set<size_t> droppedSegments; |
| |
| void initializeTableContents() { |
| for (auto& segment : wasm.table.segments) { |
| Address offset = |
| (uint32_t)ConstantExpressionRunner<GlobalManager>(globals, maxDepth) |
| .visit(segment.offset) |
| .value.geti32(); |
| if (offset + segment.data.size() > wasm.table.initial) { |
| externalInterface->trap("invalid offset when initializing table"); |
| } |
| for (size_t i = 0; i != segment.data.size(); ++i) { |
| externalInterface->tableStore(offset + i, segment.data[i]); |
| } |
| } |
| } |
| |
| void initializeMemoryContents() { |
| Const offset; |
| offset.value = Literal(uint32_t(0)); |
| offset.finalize(); |
| |
| // apply active memory segments |
| for (size_t i = 0, e = wasm.memory.segments.size(); i < e; ++i) { |
| Memory::Segment& segment = wasm.memory.segments[i]; |
| if (segment.isPassive) { |
| continue; |
| } |
| |
| Const size; |
| size.value = Literal(uint32_t(segment.data.size())); |
| size.finalize(); |
| |
| MemoryInit init; |
| init.segment = i; |
| init.dest = segment.offset; |
| init.offset = &offset; |
| init.size = &size; |
| init.finalize(); |
| |
| DataDrop drop; |
| drop.segment = i; |
| drop.finalize(); |
| |
| // we don't actually have a function, but we need one in order to visit |
| // the memory.init and data.drop instructions. |
| Function dummyFunc; |
| FunctionScope dummyScope(&dummyFunc, {}); |
| RuntimeExpressionRunner runner(*this, dummyScope, maxDepth); |
| runner.visit(&init); |
| runner.visit(&drop); |
| } |
| } |
| |
| class FunctionScope { |
| public: |
| std::vector<Literal> locals; |
| Function* function; |
| |
| FunctionScope(Function* function, const LiteralList& arguments) |
| : function(function) { |
| if (function->sig.params.size() != arguments.size()) { |
| std::cerr << "Function `" << function->name << "` expects " |
| << function->sig.params.size() << " parameters, got " |
| << arguments.size() << " arguments." << std::endl; |
| WASM_UNREACHABLE("invalid param count"); |
| } |
| locals.resize(function->getNumLocals()); |
| const std::vector<Type>& params = function->sig.params.expand(); |
| for (size_t i = 0; i < function->getNumLocals(); i++) { |
| if (i < arguments.size()) { |
| assert(i < params.size()); |
| if (!Type::isSubType(arguments[i].type, params[i])) { |
| std::cerr << "Function `" << function->name << "` expects type " |
| << params[i] << " for parameter " << i << ", got " |
| << arguments[i].type << "." << std::endl; |
| WASM_UNREACHABLE("invalid param count"); |
| } |
| locals[i] = arguments[i]; |
| } else { |
| assert(function->isVar(i)); |
| locals[i] = Literal::makeZero(function->getLocalType(i)); |
| } |
| } |
| } |
| }; |
| |
| // Executes expressions with concrete runtime info, the function and module at |
| // runtime |
| class RuntimeExpressionRunner |
| : public ExpressionRunner<RuntimeExpressionRunner> { |
| ModuleInstanceBase& instance; |
| FunctionScope& scope; |
| |
| public: |
| RuntimeExpressionRunner(ModuleInstanceBase& instance, |
| FunctionScope& scope, |
| Index maxDepth) |
| : ExpressionRunner<RuntimeExpressionRunner>(maxDepth), instance(instance), |
| scope(scope) {} |
| |
| Flow generateArguments(const ExpressionList& operands, |
| LiteralList& arguments) { |
| NOTE_ENTER_("generateArguments"); |
| arguments.reserve(operands.size()); |
| for (auto expression : operands) { |
| Flow flow = this->visit(expression); |
| if (flow.breaking()) { |
| return flow; |
| } |
| NOTE_EVAL1(flow.value); |
| arguments.push_back(flow.value); |
| } |
| return Flow(); |
| } |
| |
| Flow visitCall(Call* curr) { |
| NOTE_ENTER("Call"); |
| NOTE_NAME(curr->target); |
| LiteralList arguments; |
| Flow flow = generateArguments(curr->operands, arguments); |
| if (flow.breaking()) { |
| return flow; |
| } |
| auto* func = instance.wasm.getFunction(curr->target); |
| Flow ret; |
| if (func->imported()) { |
| ret = instance.externalInterface->callImport(func, arguments); |
| } else { |
| ret = instance.callFunctionInternal(curr->target, arguments); |
| } |
| #ifdef WASM_INTERPRETER_DEBUG |
| std::cout << "(returned to " << scope.function->name << ")\n"; |
| #endif |
| // TODO: make this a proper tail call (return first) |
| if (curr->isReturn) { |
| Const c; |
| c.value = ret.value; |
| c.finalize(); |
| Return return_; |
| return_.value = &c; |
| return this->visit(&return_); |
| } |
| return ret; |
| } |
| Flow visitCallIndirect(CallIndirect* curr) { |
| NOTE_ENTER("CallIndirect"); |
| LiteralList arguments; |
| Flow flow = generateArguments(curr->operands, arguments); |
| if (flow.breaking()) { |
| return flow; |
| } |
| Flow target = this->visit(curr->target); |
| if (target.breaking()) { |
| return target; |
| } |
| Index index = target.value.geti32(); |
| Type type = curr->isReturn ? scope.function->sig.results : curr->type; |
| Flow ret = instance.externalInterface->callTable( |
| index, curr->sig, arguments, type, *instance.self()); |
| // TODO: make this a proper tail call (return first) |
| if (curr->isReturn) { |
| Const c; |
| c.value = ret.value; |
| c.finalize(); |
| Return return_; |
| return_.value = &c; |
| return this->visit(&return_); |
| } |
| return ret; |
| } |
| |
| Flow visitLocalGet(LocalGet* curr) { |
| NOTE_ENTER("LocalGet"); |
| auto index = curr->index; |
| NOTE_EVAL1(index); |
| NOTE_EVAL1(scope.locals[index]); |
| return scope.locals[index]; |
| } |
| Flow visitLocalSet(LocalSet* curr) { |
| NOTE_ENTER("LocalSet"); |
| auto index = curr->index; |
| Flow flow = this->visit(curr->value); |
| if (flow.breaking()) { |
| return flow; |
| } |
| NOTE_EVAL1(index); |
| NOTE_EVAL1(flow.value); |
| assert(curr->isTee() ? Type::isSubType(flow.value.type, curr->type) |
| : true); |
| scope.locals[index] = flow.value; |
| return curr->isTee() ? flow : Flow(); |
| } |
| |
| Flow visitGlobalGet(GlobalGet* curr) { |
| NOTE_ENTER("GlobalGet"); |
| auto name = curr->name; |
| NOTE_EVAL1(name); |
| assert(instance.globals.find(name) != instance.globals.end()); |
| NOTE_EVAL1(instance.globals[name]); |
| return instance.globals[name]; |
| } |
| Flow visitGlobalSet(GlobalSet* curr) { |
| NOTE_ENTER("GlobalSet"); |
| auto name = curr->name; |
| Flow flow = this->visit(curr->value); |
| if (flow.breaking()) { |
| return flow; |
| } |
| NOTE_EVAL1(name); |
| NOTE_EVAL1(flow.value); |
| instance.globals[name] = flow.value; |
| return Flow(); |
| } |
| |
| Flow visitLoad(Load* curr) { |
| NOTE_ENTER("Load"); |
| Flow flow = this->visit(curr->ptr); |
| if (flow.breaking()) { |
| return flow; |
| } |
| NOTE_EVAL1(flow); |
| auto addr = instance.getFinalAddress(curr, flow.value); |
| auto ret = instance.externalInterface->load(curr, addr); |
| NOTE_EVAL1(addr); |
| NOTE_EVAL1(ret); |
| return ret; |
| } |
| Flow visitStore(Store* curr) { |
| NOTE_ENTER("Store"); |
| Flow ptr = this->visit(curr->ptr); |
| if (ptr.breaking()) { |
| return ptr; |
| } |
| Flow value = this->visit(curr->value); |
| if (value.breaking()) { |
| return value; |
| } |
| auto addr = instance.getFinalAddress(curr, ptr.value); |
| NOTE_EVAL1(addr); |
| NOTE_EVAL1(value); |
| instance.externalInterface->store(curr, addr, value.value); |
| return Flow(); |
| } |
| |
| Flow visitAtomicRMW(AtomicRMW* curr) { |
| NOTE_ENTER("AtomicRMW"); |
| Flow ptr = this->visit(curr->ptr); |
| if (ptr.breaking()) { |
| return ptr; |
| } |
| auto value = this->visit(curr->value); |
| if (value.breaking()) { |
| return value; |
| } |
| NOTE_EVAL1(ptr); |
| auto addr = instance.getFinalAddress(curr, ptr.value); |
| NOTE_EVAL1(addr); |
| NOTE_EVAL1(value); |
| auto loaded = instance.doAtomicLoad(addr, curr->bytes, curr->type); |
| NOTE_EVAL1(loaded); |
| auto computed = value.value; |
| switch (curr->op) { |
| case Add: |
| computed = computed.add(value.value); |
| break; |
| case Sub: |
| computed = computed.sub(value.value); |
| break; |
| case And: |
| computed = computed.and_(value.value); |
| break; |
| case Or: |
| computed = computed.or_(value.value); |
| break; |
| case Xor: |
| computed = computed.xor_(value.value); |
| break; |
| case Xchg: |
| computed = value.value; |
| break; |
| } |
| instance.doAtomicStore(addr, curr->bytes, computed); |
| return loaded; |
| } |
| Flow visitAtomicCmpxchg(AtomicCmpxchg* curr) { |
| NOTE_ENTER("AtomicCmpxchg"); |
| Flow ptr = this->visit(curr->ptr); |
| if (ptr.breaking()) { |
| return ptr; |
| } |
| NOTE_EVAL1(ptr); |
| auto expected = this->visit(curr->expected); |
| if (expected.breaking()) { |
| return expected; |
| } |
| auto replacement = this->visit(curr->replacement); |
| if (replacement.breaking()) { |
| return replacement; |
| } |
| auto addr = instance.getFinalAddress(curr, ptr.value); |
| NOTE_EVAL1(addr); |
| NOTE_EVAL1(expected); |
| NOTE_EVAL1(replacement); |
| auto loaded = instance.doAtomicLoad(addr, curr->bytes, curr->type); |
| NOTE_EVAL1(loaded); |
| if (loaded == expected.value) { |
| instance.doAtomicStore(addr, curr->bytes, replacement.value); |
| } |
| return loaded; |
| } |
| Flow visitAtomicWait(AtomicWait* curr) { |
| NOTE_ENTER("AtomicWait"); |
| Flow ptr = this->visit(curr->ptr); |
| if (ptr.breaking()) { |
| return ptr; |
| } |
| NOTE_EVAL1(ptr); |
| auto expected = this->visit(curr->expected); |
| NOTE_EVAL1(expected); |
| if (expected.breaking()) { |
| return expected; |
| } |
| auto timeout = this->visit(curr->timeout); |
| NOTE_EVAL1(timeout); |
| if (timeout.breaking()) { |
| return timeout; |
| } |
| auto bytes = curr->expectedType.getByteSize(); |
| auto addr = instance.getFinalAddress(ptr.value, bytes); |
| auto loaded = instance.doAtomicLoad(addr, bytes, curr->expectedType); |
| NOTE_EVAL1(loaded); |
| if (loaded != expected.value) { |
| return Literal(int32_t(1)); // not equal |
| } |
| // TODO: add threads support! |
| // for now, just assume we are woken up |
| return Literal(int32_t(0)); // woken up |
| } |
| Flow visitAtomicNotify(AtomicNotify* curr) { |
| NOTE_ENTER("AtomicNotify"); |
| Flow ptr = this->visit(curr->ptr); |
| if (ptr.breaking()) { |
| return ptr; |
| } |
| NOTE_EVAL1(ptr); |
| auto count = this->visit(curr->notifyCount); |
| NOTE_EVAL1(count); |
| if (count.breaking()) { |
| return count; |
| } |
| // TODO: add threads support! |
| return Literal(int32_t(0)); // none woken up |
| } |
| Flow visitSIMDLoad(SIMDLoad* curr) { |
| NOTE_ENTER("SIMDLoad"); |
| switch (curr->op) { |
| case LoadSplatVec8x16: |
| case LoadSplatVec16x8: |
| case LoadSplatVec32x4: |
| case LoadSplatVec64x2: |
| return visitSIMDLoadSplat(curr); |
| case LoadExtSVec8x8ToVecI16x8: |
| case LoadExtUVec8x8ToVecI16x8: |
| case LoadExtSVec16x4ToVecI32x4: |
| case LoadExtUVec16x4ToVecI32x4: |
| case LoadExtSVec32x2ToVecI64x2: |
| case LoadExtUVec32x2ToVecI64x2: |
| return visitSIMDLoadExtend(curr); |
| } |
| WASM_UNREACHABLE("invalid op"); |
| } |
| Flow visitSIMDLoadSplat(SIMDLoad* curr) { |
| Load load; |
| load.type = Type::i32; |
| load.bytes = curr->getMemBytes(); |
| load.signed_ = false; |
| load.offset = curr->offset; |
| load.align = curr->align; |
| load.isAtomic = false; |
| load.ptr = curr->ptr; |
| Literal (Literal::*splat)() const = nullptr; |
| switch (curr->op) { |
| case LoadSplatVec8x16: |
| splat = &Literal::splatI8x16; |
| break; |
| case LoadSplatVec16x8: |
| splat = &Literal::splatI16x8; |
| break; |
| case LoadSplatVec32x4: |
| splat = &Literal::splatI32x4; |
| break; |
| case LoadSplatVec64x2: |
| load.type = Type::i64; |
| splat = &Literal::splatI64x2; |
| break; |
| default: |
| WASM_UNREACHABLE("invalid op"); |
| } |
| load.finalize(); |
| Flow flow = this->visit(&load); |
| if (flow.breaking()) { |
| return flow; |
| } |
| return (flow.value.*splat)(); |
| } |
| Flow visitSIMDLoadExtend(SIMDLoad* curr) { |
| Flow flow = this->visit(curr->ptr); |
| if (flow.breaking()) { |
| return flow; |
| } |
| NOTE_EVAL1(flow); |
| Address src(uint32_t(flow.value.geti32())); |
| auto loadLane = [&](Address addr) { |
| switch (curr->op) { |
| case LoadExtSVec8x8ToVecI16x8: |
| return Literal(int32_t(instance.externalInterface->load8s(addr))); |
| case LoadExtUVec8x8ToVecI16x8: |
| return Literal(int32_t(instance.externalInterface->load8u(addr))); |
| case LoadExtSVec16x4ToVecI32x4: |
| return Literal(int32_t(instance.externalInterface->load16s(addr))); |
| case LoadExtUVec16x4ToVecI32x4: |
| return Literal(int32_t(instance.externalInterface->load16u(addr))); |
| case LoadExtSVec32x2ToVecI64x2: |
| return Literal(int64_t(instance.externalInterface->load32s(addr))); |
| case LoadExtUVec32x2ToVecI64x2: |
| return Literal(int64_t(instance.externalInterface->load32u(addr))); |
| default: |
| WASM_UNREACHABLE("unexpected op"); |
| } |
| WASM_UNREACHABLE("invalid op"); |
| }; |
| auto fillLanes = [&](auto lanes, size_t laneBytes) { |
| for (auto& lane : lanes) { |
| lane = loadLane( |
| instance.getFinalAddress(Literal(uint32_t(src)), laneBytes)); |
| src = Address(uint32_t(src) + laneBytes); |
| } |
| return Literal(lanes); |
| }; |
| switch (curr->op) { |
| case LoadExtSVec8x8ToVecI16x8: |
| case LoadExtUVec8x8ToVecI16x8: { |
| std::array<Literal, 8> lanes; |
| return fillLanes(lanes, 1); |
| } |
| case LoadExtSVec16x4ToVecI32x4: |
| case LoadExtUVec16x4ToVecI32x4: { |
| std::array<Literal, 4> lanes; |
| return fillLanes(lanes, 2); |
| } |
| case LoadExtSVec32x2ToVecI64x2: |
| case LoadExtUVec32x2ToVecI64x2: { |
| std::array<Literal, 2> lanes; |
| return fillLanes(lanes, 4); |
| } |
| default: |
| WASM_UNREACHABLE("unexpected op"); |
| } |
| WASM_UNREACHABLE("invalid op"); |
| } |
| Flow visitHost(Host* curr) { |
| NOTE_ENTER("Host"); |
| switch (curr->op) { |
| case MemorySize: |
| return Literal(int32_t(instance.memorySize)); |
| case MemoryGrow: { |
| auto fail = Literal(int32_t(-1)); |
| Flow flow = this->visit(curr->operands[0]); |
| if (flow.breaking()) { |
| return flow; |
| } |
| int32_t ret = instance.memorySize; |
| uint32_t delta = flow.value.geti32(); |
| if (delta > uint32_t(-1) / Memory::kPageSize) { |
| return fail; |
| } |
| if (instance.memorySize >= uint32_t(-1) - delta) { |
| return fail; |
| } |
| uint32_t newSize = instance.memorySize + delta; |
| if (newSize > instance.wasm.memory.max) { |
| return fail; |
| } |
| instance.externalInterface->growMemory(instance.memorySize * |
| Memory::kPageSize, |
| newSize * Memory::kPageSize); |
| instance.memorySize = newSize; |
| return Literal(int32_t(ret)); |
| } |
| } |
| WASM_UNREACHABLE("invalid op"); |
| } |
| Flow visitMemoryInit(MemoryInit* curr) { |
| NOTE_ENTER("MemoryInit"); |
| Flow dest = this->visit(curr->dest); |
| if (dest.breaking()) { |
| return dest; |
| } |
| Flow offset = this->visit(curr->offset); |
| if (offset.breaking()) { |
| return offset; |
| } |
| Flow size = this->visit(curr->size); |
| if (size.breaking()) { |
| return size; |
| } |
| NOTE_EVAL1(dest); |
| NOTE_EVAL1(offset); |
| NOTE_EVAL1(size); |
| |
| assert(curr->segment < instance.wasm.memory.segments.size()); |
| Memory::Segment& segment = instance.wasm.memory.segments[curr->segment]; |
| |
| Address destVal(uint32_t(dest.value.geti32())); |
| Address offsetVal(uint32_t(offset.value.geti32())); |
| Address sizeVal(uint32_t(size.value.geti32())); |
| |
| if (offsetVal + sizeVal > 0 && |
| instance.droppedSegments.count(curr->segment)) { |
| trap("out of bounds segment access in memory.init"); |
| } |
| if ((uint64_t)offsetVal + sizeVal > segment.data.size()) { |
| trap("out of bounds segment access in memory.init"); |
| } |
| if ((uint64_t)destVal + sizeVal > |
| (uint64_t)instance.memorySize * Memory::kPageSize) { |
| trap("out of bounds memory access in memory.init"); |
| } |
| for (size_t i = 0; i < sizeVal; ++i) { |
| Literal addr(uint32_t(destVal + i)); |
| instance.externalInterface->store8(instance.getFinalAddress(addr, 1), |
| segment.data[offsetVal + i]); |
| } |
| return {}; |
| } |
| Flow visitDataDrop(DataDrop* curr) { |
| NOTE_ENTER("DataDrop"); |
| instance.droppedSegments.insert(curr->segment); |
| return {}; |
| } |
| Flow visitMemoryCopy(MemoryCopy* curr) { |
| NOTE_ENTER("MemoryCopy"); |
| Flow dest = this->visit(curr->dest); |
| if (dest.breaking()) { |
| return dest; |
| } |
| Flow source = this->visit(curr->source); |
| if (source.breaking()) { |
| return source; |
| } |
| Flow size = this->visit(curr->size); |
| if (size.breaking()) { |
| return size; |
| } |
| NOTE_EVAL1(dest); |
| NOTE_EVAL1(source); |
| NOTE_EVAL1(size); |
| Address destVal(uint32_t(dest.value.geti32())); |
| Address sourceVal(uint32_t(source.value.geti32())); |
| Address sizeVal(uint32_t(size.value.geti32())); |
| |
| if ((uint64_t)sourceVal + sizeVal > |
| (uint64_t)instance.memorySize * Memory::kPageSize || |
| (uint64_t)destVal + sizeVal > |
| (uint64_t)instance.memorySize * Memory::kPageSize) { |
| trap("out of bounds segment access in memory.copy"); |
| } |
| |
| int64_t start = 0; |
| int64_t end = sizeVal; |
| int step = 1; |
| // Reverse direction if source is below dest |
| if (sourceVal < destVal) { |
| start = int64_t(sizeVal) - 1; |
| end = -1; |
| step = -1; |
| } |
| for (int64_t i = start; i != end; i += step) { |
| instance.externalInterface->store8( |
| instance.getFinalAddress(Literal(uint32_t(destVal + i)), 1), |
| instance.externalInterface->load8s( |
| instance.getFinalAddress(Literal(uint32_t(sourceVal + i)), 1))); |
| } |
| return {}; |
| } |
| Flow visitMemoryFill(MemoryFill* curr) { |
| NOTE_ENTER("MemoryFill"); |
| Flow dest = this->visit(curr->dest); |
| if (dest.breaking()) { |
| return dest; |
| } |
| Flow value = this->visit(curr->value); |
| if (value.breaking()) { |
| return value; |
| } |
| Flow size = this->visit(curr->size); |
| if (size.breaking()) { |
| return size; |
| } |
| NOTE_EVAL1(dest); |
| NOTE_EVAL1(value); |
| NOTE_EVAL1(size); |
| Address destVal(uint32_t(dest.value.geti32())); |
| Address sizeVal(uint32_t(size.value.geti32())); |
| |
| if ((uint64_t)destVal + sizeVal > |
| (uint64_t)instance.memorySize * Memory::kPageSize) { |
| trap("out of bounds memory access in memory.fill"); |
| } |
| uint8_t val(value.value.geti32()); |
| for (size_t i = 0; i < sizeVal; ++i) { |
| instance.externalInterface->store8( |
| instance.getFinalAddress(Literal(uint32_t(destVal + i)), 1), val); |
| } |
| return {}; |
| } |
| Flow visitPush(Push* curr) { |
| NOTE_ENTER("Push"); |
| Flow value = this->visit(curr->value); |
| if (value.breaking()) { |
| return value; |
| } |
| instance.multiValues.push_back(value.value); |
| return Flow(); |
| } |
| Flow visitPop(Pop* curr) { |
| NOTE_ENTER("Pop"); |
| assert(!instance.multiValues.empty()); |
| auto ret = instance.multiValues.back(); |
| instance.multiValues.pop_back(); |
| return ret; |
| } |
| |
| void trap(const char* why) override { |
| instance.externalInterface->trap(why); |
| } |
| }; |
| |
| public: |
| // Call a function, starting an invocation. |
| Literal callFunction(Name name, const LiteralList& arguments) { |
| // if the last call ended in a jump up the stack, it might have left stuff |
| // for us to clean up here |
| callDepth = 0; |
| functionStack.clear(); |
| return callFunctionInternal(name, arguments); |
| } |
| |
| // Internal function call. Must be public so that callTable implementations |
| // can use it (refactor?) |
| Literal callFunctionInternal(Name name, const LiteralList& arguments) { |
| if (callDepth > maxDepth) { |
| externalInterface->trap("stack limit"); |
| } |
| auto previousCallDepth = callDepth; |
| callDepth++; |
| auto previousFunctionStackSize = functionStack.size(); |
| functionStack.push_back(name); |
| |
| Function* function = wasm.getFunction(name); |
| assert(function); |
| FunctionScope scope(function, arguments); |
| |
| #ifdef WASM_INTERPRETER_DEBUG |
| std::cout << "entering " << function->name << "\n with arguments:\n"; |
| for (unsigned i = 0; i < arguments.size(); ++i) { |
| std::cout << " $" << i << ": " << arguments[i] << '\n'; |
| } |
| #endif |
| |
| Flow flow = |
| RuntimeExpressionRunner(*this, scope, maxDepth).visit(function->body); |
| // cannot still be breaking, it means we missed our stop |
| assert(!flow.breaking() || flow.breakTo == RETURN_FLOW); |
| Literal ret = flow.value; |
| if (!Type::isSubType(ret.type, function->sig.results)) { |
| std::cerr << "calling " << function->name << " resulted in " << ret |
| << " but the function type is " << function->sig.results |
| << '\n'; |
| WASM_UNREACHABLE("unexpect result type"); |
| } |
| // may decrease more than one, if we jumped up the stack |
| callDepth = previousCallDepth; |
| // if we jumped up the stack, we also need to pop higher frames |
| while (functionStack.size() > previousFunctionStackSize) { |
| functionStack.pop_back(); |
| } |
| #ifdef WASM_INTERPRETER_DEBUG |
| std::cout << "exiting " << function->name << " with " << ret << '\n'; |
| #endif |
| return ret; |
| } |
| |
| protected: |
| Address memorySize; // in pages |
| |
| static const Index maxDepth = 250; |
| |
| void trapIfGt(uint64_t lhs, uint64_t rhs, const char* msg) { |
| if (lhs > rhs) { |
| std::stringstream ss; |
| ss << msg << ": " << lhs << " > " << rhs; |
| externalInterface->trap(ss.str().c_str()); |
| } |
| } |
| |
| template<class LS> Address getFinalAddress(LS* curr, Literal ptr) { |
| Address memorySizeBytes = memorySize * Memory::kPageSize; |
| uint64_t addr = ptr.type == Type::i32 ? ptr.geti32() : ptr.geti64(); |
| trapIfGt(curr->offset, memorySizeBytes, "offset > memory"); |
| trapIfGt(addr, memorySizeBytes - curr->offset, "final > memory"); |
| addr += curr->offset; |
| trapIfGt(curr->bytes, memorySizeBytes, "bytes > memory"); |
| checkLoadAddress(addr, curr->bytes); |
| return addr; |
| } |
| |
| Address getFinalAddress(Literal ptr, Index bytes) { |
| Address memorySizeBytes = memorySize * Memory::kPageSize; |
| uint64_t addr = ptr.type == Type::i32 ? ptr.geti32() : ptr.geti64(); |
| trapIfGt(addr, memorySizeBytes - bytes, "highest > memory"); |
| return addr; |
| } |
| |
| void checkLoadAddress(Address addr, Index bytes) { |
| Address memorySizeBytes = memorySize * Memory::kPageSize; |
| trapIfGt(addr, memorySizeBytes - bytes, "highest > memory"); |
| } |
| |
| Literal doAtomicLoad(Address addr, Index bytes, Type type) { |
| checkLoadAddress(addr, bytes); |
| Const ptr; |
| ptr.value = Literal(int32_t(addr)); |
| ptr.type = Type::i32; |
| Load load; |
| load.bytes = bytes; |
| load.signed_ = true; |
| load.align = bytes; |
| load.isAtomic = true; // understatement |
| load.ptr = &ptr; |
| load.type = type; |
| return externalInterface->load(&load, addr); |
| } |
| |
| void doAtomicStore(Address addr, Index bytes, Literal toStore) { |
| Const ptr; |
| ptr.value = Literal(int32_t(addr)); |
| ptr.type = Type::i32; |
| Const value; |
| value.value = toStore; |
| value.type = toStore.type; |
| Store store; |
| store.bytes = bytes; |
| store.align = bytes; |
| store.isAtomic = true; // understatement |
| store.ptr = &ptr; |
| store.value = &value; |
| store.valueType = value.type; |
| return externalInterface->store(&store, addr, toStore); |
| } |
| |
| ExternalInterface* externalInterface; |
| }; |
| |
| // The default ModuleInstance uses a trivial global manager |
| using TrivialGlobalManager = std::map<Name, Literal>; |
| class ModuleInstance |
| : public ModuleInstanceBase<TrivialGlobalManager, ModuleInstance> { |
| public: |
| ModuleInstance(Module& wasm, ExternalInterface* externalInterface) |
| : ModuleInstanceBase(wasm, externalInterface) {} |
| }; |
| |
| } // namespace wasm |
| |
| #endif // wasm_wasm_interpreter_h |