// We always need asserts here #ifdef NDEBUG #undef NDEBUG #endif #include #include #include #include #include // kitchen sink, tests the full API // helpers static const uint8_t v128_bytes[] = { 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16}; BinaryenExpressionRef makeUnary(BinaryenModuleRef module, BinaryenOp op, BinaryenType inputType) { if (inputType == BinaryenTypeInt32()) return BinaryenUnary( module, op, BinaryenConst(module, BinaryenLiteralInt32(-10))); if (inputType == BinaryenTypeInt64()) return BinaryenUnary( module, op, BinaryenConst(module, BinaryenLiteralInt64(-22))); if (inputType == BinaryenTypeFloat32()) return BinaryenUnary( module, op, BinaryenConst(module, BinaryenLiteralFloat32(-33.612f))); if (inputType == BinaryenTypeFloat64()) return BinaryenUnary( module, op, BinaryenConst(module, BinaryenLiteralFloat64(-9005.841))); if (inputType == BinaryenTypeVec128()) return BinaryenUnary( module, op, BinaryenConst(module, BinaryenLiteralVec128(v128_bytes))); abort(); } BinaryenExpressionRef makeBinary(BinaryenModuleRef module, BinaryenOp op, BinaryenType type) { if (type == BinaryenTypeInt32()) { // use temp vars to ensure optimization doesn't change the order of // operation in our trace recording BinaryenExpressionRef temp = BinaryenConst(module, BinaryenLiteralInt32(-11)); return BinaryenBinary( module, op, BinaryenConst(module, BinaryenLiteralInt32(-10)), temp); } if (type == BinaryenTypeInt64()) { BinaryenExpressionRef temp = BinaryenConst(module, BinaryenLiteralInt64(-23)); return BinaryenBinary( module, op, BinaryenConst(module, BinaryenLiteralInt64(-22)), temp); } if (type == BinaryenTypeFloat32()) { BinaryenExpressionRef temp = BinaryenConst(module, BinaryenLiteralFloat32(-62.5f)); return BinaryenBinary( module, op, BinaryenConst(module, BinaryenLiteralFloat32(-33.612f)), temp); } if (type == BinaryenTypeFloat64()) { BinaryenExpressionRef temp = BinaryenConst(module, BinaryenLiteralFloat64(-9007.333)); return BinaryenBinary( module, op, BinaryenConst(module, BinaryenLiteralFloat64(-9005.841)), temp); } if (type == BinaryenTypeVec128()) { BinaryenExpressionRef temp = BinaryenConst(module, BinaryenLiteralVec128(v128_bytes)); return BinaryenBinary( module, op, BinaryenConst(module, BinaryenLiteralVec128(v128_bytes)), temp); } abort(); } BinaryenExpressionRef makeInt32(BinaryenModuleRef module, int x) { return BinaryenConst(module, BinaryenLiteralInt32(x)); } BinaryenExpressionRef makeFloat32(BinaryenModuleRef module, float x) { return BinaryenConst(module, BinaryenLiteralFloat32(x)); } BinaryenExpressionRef makeInt64(BinaryenModuleRef module, int64_t x) { return BinaryenConst(module, BinaryenLiteralInt64(x)); } BinaryenExpressionRef makeFloat64(BinaryenModuleRef module, double x) { return BinaryenConst(module, BinaryenLiteralFloat64(x)); } BinaryenExpressionRef makeVec128(BinaryenModuleRef module, uint8_t const* bytes) { return BinaryenConst(module, BinaryenLiteralVec128(bytes)); } BinaryenExpressionRef makeSomething(BinaryenModuleRef module) { return makeInt32(module, 1337); } BinaryenExpressionRef makeDroppedInt32(BinaryenModuleRef module, int x) { return BinaryenDrop(module, BinaryenConst(module, BinaryenLiteralInt32(x))); } BinaryenExpressionRef makeSIMDExtract(BinaryenModuleRef module, BinaryenOp op) { return BinaryenSIMDExtract(module, op, makeVec128(module, v128_bytes), 0); } BinaryenExpressionRef makeSIMDReplace(BinaryenModuleRef module, BinaryenOp op, BinaryenType type) { BinaryenExpressionRef val; if (type == BinaryenTypeInt32()) { val = makeInt32(module, 42); } if (type == BinaryenTypeInt64()) { val = makeInt64(module, 42); } if (type == BinaryenTypeFloat32()) { val = makeFloat32(module, 42.); } if (type == BinaryenTypeFloat64()) { val = makeFloat64(module, 42.); } if (!val) { abort(); } return BinaryenSIMDReplace( module, op, makeVec128(module, v128_bytes), 0, val); } BinaryenExpressionRef makeSIMDShuffle(BinaryenModuleRef module) { BinaryenExpressionRef left = makeVec128(module, v128_bytes); BinaryenExpressionRef right = makeVec128(module, v128_bytes); return BinaryenSIMDShuffle(module, left, right, (uint8_t[16]){}); } BinaryenExpressionRef makeSIMDTernary(BinaryenModuleRef module, BinaryenOp op) { BinaryenExpressionRef a = makeVec128(module, v128_bytes); BinaryenExpressionRef b = makeVec128(module, v128_bytes); BinaryenExpressionRef c = makeVec128(module, v128_bytes); return BinaryenSIMDTernary(module, op, a, b, c); } BinaryenExpressionRef makeSIMDShift(BinaryenModuleRef module, BinaryenOp op) { BinaryenExpressionRef vec = makeVec128(module, v128_bytes); return BinaryenSIMDShift(module, op, vec, makeInt32(module, 1)); } BinaryenExpressionRef makeMemoryInit(BinaryenModuleRef module) { BinaryenExpressionRef dest = makeInt32(module, 1024); BinaryenExpressionRef offset = makeInt32(module, 0); BinaryenExpressionRef size = makeInt32(module, 12); return BinaryenMemoryInit(module, "1", dest, offset, size, "0"); }; BinaryenExpressionRef makeDataDrop(BinaryenModuleRef module) { return BinaryenDataDrop(module, "1"); }; BinaryenExpressionRef makeMemoryCopy(BinaryenModuleRef module) { BinaryenExpressionRef dest = makeInt32(module, 2048); BinaryenExpressionRef source = makeInt32(module, 1024); BinaryenExpressionRef size = makeInt32(module, 12); return BinaryenMemoryCopy(module, dest, source, size, "0", "0"); }; BinaryenExpressionRef makeMemoryFill(BinaryenModuleRef module) { BinaryenExpressionRef dest = makeInt32(module, 0); BinaryenExpressionRef value = makeInt32(module, 42); BinaryenExpressionRef size = makeInt32(module, 1024); return BinaryenMemoryFill(module, dest, value, size, "0"); }; // tests void test_types() { BinaryenType valueType = 0xdeadbeef; BinaryenType none = BinaryenTypeNone(); printf("BinaryenTypeNone: %zd\n", none); assert(BinaryenTypeArity(none) == 0); BinaryenTypeExpand(none, &valueType); assert(valueType == 0xdeadbeef); BinaryenType unreachable = BinaryenTypeUnreachable(); printf("BinaryenTypeUnreachable: %zd\n", unreachable); assert(BinaryenTypeArity(unreachable) == 1); BinaryenTypeExpand(unreachable, &valueType); assert(valueType == unreachable); BinaryenType i32 = BinaryenTypeInt32(); printf("BinaryenTypeInt32: %zd\n", i32); assert(BinaryenTypeArity(i32) == 1); BinaryenTypeExpand(i32, &valueType); assert(valueType == i32); BinaryenType i64 = BinaryenTypeInt64(); printf("BinaryenTypeInt64: %zd\n", i64); assert(BinaryenTypeArity(i64) == 1); BinaryenTypeExpand(i64, &valueType); assert(valueType == i64); BinaryenType f32 = BinaryenTypeFloat32(); printf("BinaryenTypeFloat32: %zd\n", f32); assert(BinaryenTypeArity(f32) == 1); BinaryenTypeExpand(f32, &valueType); assert(valueType == f32); BinaryenType f64 = BinaryenTypeFloat64(); printf("BinaryenTypeFloat64: %zd\n", f64); assert(BinaryenTypeArity(f64) == 1); BinaryenTypeExpand(f64, &valueType); assert(valueType == f64); BinaryenType v128 = BinaryenTypeVec128(); printf("BinaryenTypeVec128: %zd\n", v128); assert(BinaryenTypeArity(v128) == 1); BinaryenTypeExpand(v128, &valueType); assert(valueType == v128); BinaryenType funcref = BinaryenTypeFuncref(); printf("BinaryenTypeFuncref: (ptr)\n"); assert(funcref == BinaryenTypeFuncref()); assert(BinaryenTypeArity(funcref) == 1); BinaryenTypeExpand(funcref, &valueType); assert(valueType == funcref); BinaryenType externref = BinaryenTypeExternref(); printf("BinaryenTypeExternref: (ptr)\n"); assert(externref == BinaryenTypeExternref()); assert(BinaryenTypeArity(externref) == 1); BinaryenTypeExpand(externref, &valueType); assert(valueType == externref); BinaryenType anyref = BinaryenTypeAnyref(); printf("BinaryenTypeAnyref: (ptr)\n"); assert(anyref == BinaryenTypeAnyref()); assert(BinaryenTypeArity(anyref) == 1); BinaryenTypeExpand(anyref, &valueType); assert(valueType == anyref); BinaryenType eqref = BinaryenTypeEqref(); printf("BinaryenTypeEqref: (ptr)\n"); assert(eqref == BinaryenTypeEqref()); assert(BinaryenTypeArity(eqref) == 1); BinaryenTypeExpand(eqref, &valueType); assert(valueType == eqref); BinaryenType i31ref = BinaryenTypeI31ref(); printf("BinaryenTypeI31ref: (ptr)\n"); assert(i31ref == BinaryenTypeI31ref()); assert(BinaryenTypeArity(i31ref) == 1); BinaryenTypeExpand(i31ref, &valueType); assert(valueType == i31ref); BinaryenType structref = BinaryenTypeStructref(); printf("BinaryenTypeStructref: (ptr)\n"); assert(structref == BinaryenTypeStructref()); assert(BinaryenTypeArity(structref) == 1); BinaryenTypeExpand(structref, &valueType); assert(valueType == structref); BinaryenType arrayref = BinaryenTypeArrayref(); printf("BinaryenTypeArrayref: (ptr)\n"); assert(arrayref == BinaryenTypeArrayref()); assert(BinaryenTypeArity(arrayref) == 1); BinaryenTypeExpand(arrayref, &valueType); assert(valueType == arrayref); BinaryenType stringref = BinaryenTypeStringref(); printf("BinaryenTypeStringref: (ptr)\n"); assert(BinaryenTypeArity(stringref) == 1); BinaryenTypeExpand(stringref, &valueType); assert(valueType == stringref); BinaryenType nullref = BinaryenTypeNullref(); printf("BinaryenTypeNullref: (ptr)\n"); assert(BinaryenTypeArity(nullref) == 1); BinaryenTypeExpand(nullref, &valueType); assert(valueType == nullref); BinaryenType nullexternref = BinaryenTypeNullExternref(); printf("BinaryenTypeNullExternref: (ptr)\n"); assert(BinaryenTypeArity(nullexternref) == 1); BinaryenTypeExpand(nullexternref, &valueType); assert(valueType == nullexternref); BinaryenType nullfuncref = BinaryenTypeNullFuncref(); printf("BinaryenTypeNullFuncref: (ptr)\n"); assert(BinaryenTypeArity(nullfuncref) == 1); BinaryenTypeExpand(nullfuncref, &valueType); assert(valueType == nullfuncref); printf("BinaryenTypeAuto: %zd\n", BinaryenTypeAuto()); BinaryenType pair[] = {i32, i32}; BinaryenType i32_pair = BinaryenTypeCreate(pair, 2); assert(BinaryenTypeArity(i32_pair) == 2); pair[0] = pair[1] = none; BinaryenTypeExpand(i32_pair, pair); assert(pair[0] == i32 && pair[1] == i32); BinaryenType duplicate_pair = BinaryenTypeCreate(pair, 2); assert(duplicate_pair == i32_pair); pair[0] = pair[1] = f32; BinaryenType float_pair = BinaryenTypeCreate(pair, 2); assert(float_pair != i32_pair); BinaryenPackedType notPacked = BinaryenPackedTypeNotPacked(); printf("BinaryenPackedTypeNotPacked: %d\n", notPacked); BinaryenPackedType i8 = BinaryenPackedTypeInt8(); printf("BinaryenPackedTypeInt8: %d\n", i8); BinaryenPackedType i16 = BinaryenPackedTypeInt16(); printf("BinaryenPackedTypeInt16: %d\n", i16); printf("BinaryenHeapTypeExt: %zd\n", BinaryenHeapTypeExt()); printf("BinaryenHeapTypeFunc: %zd\n", BinaryenHeapTypeFunc()); printf("BinaryenHeapTypeAny: %zd\n", BinaryenHeapTypeAny()); printf("BinaryenHeapTypeEq: %zd\n", BinaryenHeapTypeEq()); printf("BinaryenHeapTypeI31: %zd\n", BinaryenHeapTypeI31()); printf("BinaryenHeapTypeStruct: %zd\n", BinaryenHeapTypeStruct()); printf("BinaryenHeapTypeArray: %zd\n", BinaryenHeapTypeArray()); printf("BinaryenHeapTypeString: %zd\n", BinaryenHeapTypeString()); printf("BinaryenHeapTypeNone: %zd\n", BinaryenHeapTypeNone()); printf("BinaryenHeapTypeNoext: %zd\n", BinaryenHeapTypeNoext()); printf("BinaryenHeapTypeNofunc: %zd\n", BinaryenHeapTypeNofunc()); assert(!BinaryenHeapTypeIsBottom(BinaryenHeapTypeExt())); assert(BinaryenHeapTypeIsBottom(BinaryenHeapTypeNoext())); assert(BinaryenHeapTypeGetBottom(BinaryenHeapTypeExt()) == BinaryenHeapTypeNoext()); BinaryenHeapType eq = BinaryenTypeGetHeapType(eqref); assert(eq == BinaryenHeapTypeEq()); BinaryenType ref_null_eq = BinaryenTypeFromHeapType(eq, true); assert(BinaryenTypeGetHeapType(ref_null_eq) == eq); assert(BinaryenTypeIsNullable(ref_null_eq)); BinaryenType ref_eq = BinaryenTypeFromHeapType(eq, false); assert(ref_eq != ref_null_eq); assert(BinaryenTypeGetHeapType(ref_eq) == eq); assert(!BinaryenTypeIsNullable(ref_eq)); } void test_features() { printf("BinaryenFeatureMVP: %d\n", BinaryenFeatureMVP()); printf("BinaryenFeatureAtomics: %d\n", BinaryenFeatureAtomics()); printf("BinaryenFeatureBulkMemory: %d\n", BinaryenFeatureBulkMemory()); printf("BinaryenFeatureMutableGlobals: %d\n", BinaryenFeatureMutableGlobals()); printf("BinaryenFeatureNontrappingFPToInt: %d\n", BinaryenFeatureNontrappingFPToInt()); printf("BinaryenFeatureSignExt: %d\n", BinaryenFeatureSignExt()); printf("BinaryenFeatureSIMD128: %d\n", BinaryenFeatureSIMD128()); printf("BinaryenFeatureExceptionHandling: %d\n", BinaryenFeatureExceptionHandling()); printf("BinaryenFeatureTailCall: %d\n", BinaryenFeatureTailCall()); printf("BinaryenFeatureReferenceTypes: %d\n", BinaryenFeatureReferenceTypes()); printf("BinaryenFeatureMultivalue: %d\n", BinaryenFeatureMultivalue()); printf("BinaryenFeatureGC: %d\n", BinaryenFeatureGC()); printf("BinaryenFeatureMemory64: %d\n", BinaryenFeatureMemory64()); printf("BinaryenFeatureRelaxedSIMD: %d\n", BinaryenFeatureRelaxedSIMD()); printf("BinaryenFeatureExtendedConst: %d\n", BinaryenFeatureExtendedConst()); printf("BinaryenFeatureStrings: %d\n", BinaryenFeatureStrings()); printf("BinaryenFeatureAll: %d\n", BinaryenFeatureAll()); } void test_read_with_feature() { BinaryenModuleRef module = BinaryenModuleCreate(); // Having multiple tables makes this module inherently not MVP compatible // and requires the externref feature enabled to parse successfully. BinaryenAddTable(module, "tab", 0, 100, BinaryenTypeFuncref()); BinaryenAddTable(module, "tab2", 0, 100, BinaryenTypeFuncref()); BinaryenFeatures features = BinaryenFeatureMVP() | BinaryenFeatureReferenceTypes(); BinaryenModuleSetFeatures(module, features); size_t bufferSize = 1024; char* buffer = malloc(bufferSize); size_t written = BinaryenModuleWrite(module, buffer, bufferSize); BinaryenModuleDispose(module); // See we can read the bytes and get a valid module from there. BinaryenModuleRef readModule = BinaryenModuleReadWithFeatures(buffer, written, features); int valid = BinaryenModuleValidate(readModule); assert(valid); BinaryenModuleDispose(readModule); free(buffer); } void test_core() { // Module creation BinaryenModuleRef module = BinaryenModuleCreate(); // Literals and consts BinaryenExpressionRef constI32 = BinaryenConst(module, BinaryenLiteralInt32(1)), constI64 = BinaryenConst(module, BinaryenLiteralInt64(2)), constF32 = BinaryenConst(module, BinaryenLiteralFloat32(3.14f)), constF64 = BinaryenConst(module, BinaryenLiteralFloat64(2.1828)), constF32Bits = BinaryenConst(module, BinaryenLiteralFloat32Bits(0xffff1234)), constF64Bits = BinaryenConst(module, BinaryenLiteralFloat64Bits(0xffff12345678abcdLL)), constV128 = BinaryenConst(module, BinaryenLiteralVec128(v128_bytes)); const char* switchValueNames[] = {"the-value"}; const char* switchBodyNames[] = {"the-nothing"}; BinaryenExpressionRef callOperands2[] = {makeInt32(module, 13), makeFloat64(module, 3.7)}; BinaryenExpressionRef callOperands4[] = {makeInt32(module, 13), makeInt64(module, 37), makeFloat32(module, 1.3f), makeFloat64(module, 3.7)}; BinaryenExpressionRef callOperands4b[] = {makeInt32(module, 13), makeInt64(module, 37), makeFloat32(module, 1.3f), makeFloat64(module, 3.7)}; BinaryenExpressionRef tupleElements4a[] = {makeInt32(module, 13), makeInt64(module, 37), makeFloat32(module, 1.3f), makeFloat64(module, 3.7)}; BinaryenExpressionRef tupleElements4b[] = {makeInt32(module, 13), makeInt64(module, 37), makeFloat32(module, 1.3f), makeFloat64(module, 3.7)}; BinaryenType iIfF_[4] = {BinaryenTypeInt32(), BinaryenTypeInt64(), BinaryenTypeFloat32(), BinaryenTypeFloat64()}; BinaryenType iIfF = BinaryenTypeCreate(iIfF_, 4); BinaryenExpressionRef temp1 = makeInt32(module, 1), temp2 = makeInt32(module, 2), temp3 = makeInt32(module, 3), temp4 = makeInt32(module, 4), temp5 = makeInt32(module, 5), temp6 = makeInt32(module, 0), temp7 = makeInt32(module, 1), temp8 = makeInt32(module, 0), temp9 = makeInt32(module, 1), temp10 = makeInt32(module, 1), temp11 = makeInt32(module, 3), temp12 = makeInt32(module, 5), temp13 = makeInt32(module, 10), temp14 = makeInt32(module, 11), temp15 = makeInt32(module, 110), temp16 = makeInt64(module, 111); BinaryenExpressionRef externrefExpr = BinaryenRefNull(module, BinaryenTypeNullExternref()); BinaryenExpressionRef funcrefExpr = BinaryenRefNull(module, BinaryenTypeNullFuncref()); funcrefExpr = BinaryenRefFunc(module, "kitchen()sinker", BinaryenTypeFuncref()); BinaryenExpressionRef i31refExpr = BinaryenRefI31(module, makeInt32(module, 1)); // Tags BinaryenAddTag(module, "a-tag", BinaryenTypeInt32(), BinaryenTypeNone()); BinaryenAddTable(module, "tab", 0, 100, BinaryenTypeFuncref()); // Exception handling // (try // (do // (throw $a-tag (i32.const 0)) // ) // (catch $a-tag // (drop (i32 pop)) // ) // (catch_all) // ) BinaryenExpressionRef tryBody = BinaryenThrow( module, "a-tag", (BinaryenExpressionRef[]){makeInt32(module, 0)}, 1); BinaryenExpressionRef catchBody = BinaryenDrop(module, BinaryenPop(module, BinaryenTypeInt32())); BinaryenExpressionRef catchAllBody = BinaryenNop(module); const char* catchTags[] = {"a-tag"}; BinaryenExpressionRef catchBodies[] = {catchBody, catchAllBody}; const char* emptyCatchTags[] = {}; BinaryenExpressionRef emptyCatchBodies[] = {}; BinaryenExpressionRef nopCatchBody[] = {BinaryenNop(module)}; BinaryenType i32 = BinaryenTypeInt32(); BinaryenType i64 = BinaryenTypeInt64(); BinaryenType f32 = BinaryenTypeFloat32(); BinaryenType f64 = BinaryenTypeFloat64(); BinaryenType v128 = BinaryenTypeVec128(); BinaryenType i8Array; BinaryenType i16Array; BinaryenType i32Struct; { TypeBuilderRef tb = TypeBuilderCreate(3); TypeBuilderSetArrayType( tb, 0, BinaryenTypeInt32(), BinaryenPackedTypeInt8(), true); TypeBuilderSetArrayType( tb, 1, BinaryenTypeInt32(), BinaryenPackedTypeInt16(), true); TypeBuilderSetStructType( tb, 2, (BinaryenType[]){BinaryenTypeInt32()}, (BinaryenPackedType[]){BinaryenPackedTypeNotPacked()}, (bool[]){true}, 1); BinaryenHeapType builtHeapTypes[3]; TypeBuilderBuildAndDispose(tb, (BinaryenHeapType*)&builtHeapTypes, 0, 0); i8Array = BinaryenTypeFromHeapType(builtHeapTypes[0], true); i16Array = BinaryenTypeFromHeapType(builtHeapTypes[1], true); i32Struct = BinaryenTypeFromHeapType(builtHeapTypes[2], true); } // Memory. Add it before creating any memory-using instructions. const char* segmentNames[] = {"0", "1"}; const char* segmentDatas[] = {"hello, world", "I am passive"}; bool segmentPassives[] = {false, true}; BinaryenExpressionRef segmentOffsets[] = { BinaryenConst(module, BinaryenLiteralInt32(10)), NULL}; BinaryenIndex segmentSizes[] = {12, 12}; BinaryenSetMemory(module, 1, 256, "mem", segmentNames, segmentDatas, segmentPassives, segmentOffsets, segmentSizes, 2, 1, 0, "0"); BinaryenAddDataSegment(module, NULL, NULL, true, NULL, "data segment 2", 14); BinaryenAddDataSegment(module, "seg", "0", false, BinaryenConst(module, BinaryenLiteralInt32(0)), "data segment 3", 14); BinaryenExpressionRef valueList[] = { // Unary makeUnary(module, BinaryenClzInt32(), i32), makeUnary(module, BinaryenCtzInt64(), i64), makeUnary(module, BinaryenPopcntInt32(), i32), makeUnary(module, BinaryenNegFloat32(), f32), makeUnary(module, BinaryenAbsFloat64(), f64), makeUnary(module, BinaryenCeilFloat32(), f32), makeUnary(module, BinaryenFloorFloat64(), f64), makeUnary(module, BinaryenTruncFloat32(), f32), makeUnary(module, BinaryenNearestFloat32(), f32), makeUnary(module, BinaryenSqrtFloat64(), f64), makeUnary(module, BinaryenEqZInt32(), i32), makeUnary(module, BinaryenExtendSInt32(), i32), makeUnary(module, BinaryenExtendUInt32(), i32), makeUnary(module, BinaryenWrapInt64(), i64), makeUnary(module, BinaryenTruncSFloat32ToInt32(), f32), makeUnary(module, BinaryenTruncSFloat32ToInt64(), f32), makeUnary(module, BinaryenTruncUFloat32ToInt32(), f32), makeUnary(module, BinaryenTruncUFloat32ToInt64(), f32), makeUnary(module, BinaryenTruncSFloat64ToInt32(), f64), makeUnary(module, BinaryenTruncSFloat64ToInt64(), f64), makeUnary(module, BinaryenTruncUFloat64ToInt32(), f64), makeUnary(module, BinaryenTruncUFloat64ToInt64(), f64), makeUnary(module, BinaryenTruncSatSFloat32ToInt32(), f32), makeUnary(module, BinaryenTruncSatSFloat32ToInt64(), f32), makeUnary(module, BinaryenTruncSatUFloat32ToInt32(), f32), makeUnary(module, BinaryenTruncSatUFloat32ToInt64(), f32), makeUnary(module, BinaryenTruncSatSFloat64ToInt32(), f64), makeUnary(module, BinaryenTruncSatSFloat64ToInt64(), f64), makeUnary(module, BinaryenTruncSatUFloat64ToInt32(), f64), makeUnary(module, BinaryenTruncSatUFloat64ToInt64(), f64), makeUnary(module, BinaryenReinterpretFloat32(), f32), makeUnary(module, BinaryenReinterpretFloat64(), f64), makeUnary(module, BinaryenConvertSInt32ToFloat32(), i32), makeUnary(module, BinaryenConvertSInt32ToFloat64(), i32), makeUnary(module, BinaryenConvertUInt32ToFloat32(), i32), makeUnary(module, BinaryenConvertUInt32ToFloat64(), i32), makeUnary(module, BinaryenConvertSInt64ToFloat32(), i64), makeUnary(module, BinaryenConvertSInt64ToFloat64(), i64), makeUnary(module, BinaryenConvertUInt64ToFloat32(), i64), makeUnary(module, BinaryenConvertUInt64ToFloat64(), i64), makeUnary(module, BinaryenPromoteFloat32(), f32), makeUnary(module, BinaryenDemoteFloat64(), f64), makeUnary(module, BinaryenReinterpretInt32(), i32), makeUnary(module, BinaryenReinterpretInt64(), i64), makeUnary(module, BinaryenSplatVecI8x16(), i32), makeUnary(module, BinaryenSplatVecI16x8(), i32), makeUnary(module, BinaryenSplatVecI32x4(), i32), makeUnary(module, BinaryenSplatVecI64x2(), i64), makeUnary(module, BinaryenSplatVecF32x4(), f32), makeUnary(module, BinaryenSplatVecF64x2(), f64), makeUnary(module, BinaryenNotVec128(), v128), makeUnary(module, BinaryenAnyTrueVec128(), v128), makeUnary(module, BinaryenPopcntVecI8x16(), v128), makeUnary(module, BinaryenAbsVecI8x16(), v128), makeUnary(module, BinaryenNegVecI8x16(), v128), makeUnary(module, BinaryenAllTrueVecI8x16(), v128), makeUnary(module, BinaryenBitmaskVecI8x16(), v128), makeUnary(module, BinaryenAbsVecI16x8(), v128), makeUnary(module, BinaryenNegVecI16x8(), v128), makeUnary(module, BinaryenAllTrueVecI16x8(), v128), makeUnary(module, BinaryenBitmaskVecI16x8(), v128), makeUnary(module, BinaryenAbsVecI32x4(), v128), makeUnary(module, BinaryenNegVecI32x4(), v128), makeUnary(module, BinaryenAllTrueVecI32x4(), v128), makeUnary(module, BinaryenBitmaskVecI32x4(), v128), makeUnary(module, BinaryenAbsVecI64x2(), v128), makeUnary(module, BinaryenNegVecI64x2(), v128), makeUnary(module, BinaryenAllTrueVecI64x2(), v128), makeUnary(module, BinaryenBitmaskVecI64x2(), v128), makeUnary(module, BinaryenAbsVecF32x4(), v128), makeUnary(module, BinaryenNegVecF32x4(), v128), makeUnary(module, BinaryenSqrtVecF32x4(), v128), makeUnary(module, BinaryenAbsVecF64x2(), v128), makeUnary(module, BinaryenNegVecF64x2(), v128), makeUnary(module, BinaryenSqrtVecF64x2(), v128), makeUnary(module, BinaryenTruncSatSVecF32x4ToVecI32x4(), v128), makeUnary(module, BinaryenTruncSatUVecF32x4ToVecI32x4(), v128), makeUnary(module, BinaryenConvertSVecI32x4ToVecF32x4(), v128), makeUnary(module, BinaryenConvertUVecI32x4ToVecF32x4(), v128), makeUnary(module, BinaryenExtendLowSVecI8x16ToVecI16x8(), v128), makeUnary(module, BinaryenExtendHighSVecI8x16ToVecI16x8(), v128), makeUnary(module, BinaryenExtendLowUVecI8x16ToVecI16x8(), v128), makeUnary(module, BinaryenExtendHighUVecI8x16ToVecI16x8(), v128), makeUnary(module, BinaryenExtendLowSVecI16x8ToVecI32x4(), v128), makeUnary(module, BinaryenExtendHighSVecI16x8ToVecI32x4(), v128), makeUnary(module, BinaryenExtendLowUVecI16x8ToVecI32x4(), v128), makeUnary(module, BinaryenExtendHighUVecI16x8ToVecI32x4(), v128), makeUnary(module, BinaryenExtendLowSVecI32x4ToVecI64x2(), v128), makeUnary(module, BinaryenExtendHighSVecI32x4ToVecI64x2(), v128), makeUnary(module, BinaryenExtendLowUVecI32x4ToVecI64x2(), v128), makeUnary(module, BinaryenExtendHighUVecI32x4ToVecI64x2(), v128), makeUnary(module, BinaryenConvertLowSVecI32x4ToVecF64x2(), v128), makeUnary(module, BinaryenConvertLowUVecI32x4ToVecF64x2(), v128), makeUnary(module, BinaryenTruncSatZeroSVecF64x2ToVecI32x4(), v128), makeUnary(module, BinaryenTruncSatZeroUVecF64x2ToVecI32x4(), v128), makeUnary(module, BinaryenDemoteZeroVecF64x2ToVecF32x4(), v128), makeUnary(module, BinaryenPromoteLowVecF32x4ToVecF64x2(), v128), makeUnary(module, BinaryenRelaxedTruncSVecF32x4ToVecI32x4(), v128), makeUnary(module, BinaryenRelaxedTruncUVecF32x4ToVecI32x4(), v128), makeUnary(module, BinaryenRelaxedTruncZeroSVecF64x2ToVecI32x4(), v128), makeUnary(module, BinaryenRelaxedTruncZeroUVecF64x2ToVecI32x4(), v128), // Binary makeBinary(module, BinaryenAddInt32(), i32), makeBinary(module, BinaryenSubFloat64(), f64), makeBinary(module, BinaryenDivSInt32(), i32), makeBinary(module, BinaryenDivUInt64(), i64), makeBinary(module, BinaryenRemSInt64(), i64), makeBinary(module, BinaryenRemUInt32(), i32), makeBinary(module, BinaryenAndInt32(), i32), makeBinary(module, BinaryenOrInt64(), i64), makeBinary(module, BinaryenXorInt32(), i32), makeBinary(module, BinaryenShlInt64(), i64), makeBinary(module, BinaryenShrUInt64(), i64), makeBinary(module, BinaryenShrSInt32(), i32), makeBinary(module, BinaryenRotLInt32(), i32), makeBinary(module, BinaryenRotRInt64(), i64), makeBinary(module, BinaryenDivFloat32(), f32), makeBinary(module, BinaryenCopySignFloat64(), f64), makeBinary(module, BinaryenMinFloat32(), f32), makeBinary(module, BinaryenMaxFloat64(), f64), makeBinary(module, BinaryenEqInt32(), i32), makeBinary(module, BinaryenNeFloat32(), f32), makeBinary(module, BinaryenLtSInt32(), i32), makeBinary(module, BinaryenLtUInt64(), i64), makeBinary(module, BinaryenLeSInt64(), i64), makeBinary(module, BinaryenLeUInt32(), i32), makeBinary(module, BinaryenGtSInt64(), i64), makeBinary(module, BinaryenGtUInt32(), i32), makeBinary(module, BinaryenGeSInt32(), i32), makeBinary(module, BinaryenGeUInt64(), i64), makeBinary(module, BinaryenLtFloat32(), f32), makeBinary(module, BinaryenLeFloat64(), f64), makeBinary(module, BinaryenGtFloat64(), f64), makeBinary(module, BinaryenGeFloat32(), f32), makeBinary(module, BinaryenEqVecI8x16(), v128), makeBinary(module, BinaryenNeVecI8x16(), v128), makeBinary(module, BinaryenLtSVecI8x16(), v128), makeBinary(module, BinaryenLtUVecI8x16(), v128), makeBinary(module, BinaryenGtSVecI8x16(), v128), makeBinary(module, BinaryenGtUVecI8x16(), v128), makeBinary(module, BinaryenLeSVecI8x16(), v128), makeBinary(module, BinaryenLeUVecI8x16(), v128), makeBinary(module, BinaryenGeSVecI8x16(), v128), makeBinary(module, BinaryenGeUVecI8x16(), v128), makeBinary(module, BinaryenEqVecI16x8(), v128), makeBinary(module, BinaryenNeVecI16x8(), v128), makeBinary(module, BinaryenLtSVecI16x8(), v128), makeBinary(module, BinaryenLtUVecI16x8(), v128), makeBinary(module, BinaryenGtSVecI16x8(), v128), makeBinary(module, BinaryenGtUVecI16x8(), v128), makeBinary(module, BinaryenLeSVecI16x8(), v128), makeBinary(module, BinaryenLeUVecI16x8(), v128), makeBinary(module, BinaryenGeSVecI16x8(), v128), makeBinary(module, BinaryenGeUVecI16x8(), v128), makeBinary(module, BinaryenEqVecI32x4(), v128), makeBinary(module, BinaryenNeVecI32x4(), v128), makeBinary(module, BinaryenLtSVecI32x4(), v128), makeBinary(module, BinaryenLtUVecI32x4(), v128), makeBinary(module, BinaryenGtSVecI32x4(), v128), makeBinary(module, BinaryenGtUVecI32x4(), v128), makeBinary(module, BinaryenLeSVecI32x4(), v128), makeBinary(module, BinaryenLeUVecI32x4(), v128), makeBinary(module, BinaryenGeSVecI32x4(), v128), makeBinary(module, BinaryenGeUVecI32x4(), v128), makeBinary(module, BinaryenEqVecI64x2(), v128), makeBinary(module, BinaryenNeVecI64x2(), v128), makeBinary(module, BinaryenLtSVecI64x2(), v128), makeBinary(module, BinaryenGtSVecI64x2(), v128), makeBinary(module, BinaryenLeSVecI64x2(), v128), makeBinary(module, BinaryenGeSVecI64x2(), v128), makeBinary(module, BinaryenEqVecF32x4(), v128), makeBinary(module, BinaryenNeVecF32x4(), v128), makeBinary(module, BinaryenLtVecF32x4(), v128), makeBinary(module, BinaryenGtVecF32x4(), v128), makeBinary(module, BinaryenLeVecF32x4(), v128), makeBinary(module, BinaryenGeVecF32x4(), v128), makeBinary(module, BinaryenEqVecF64x2(), v128), makeBinary(module, BinaryenNeVecF64x2(), v128), makeBinary(module, BinaryenLtVecF64x2(), v128), makeBinary(module, BinaryenGtVecF64x2(), v128), makeBinary(module, BinaryenLeVecF64x2(), v128), makeBinary(module, BinaryenGeVecF64x2(), v128), makeBinary(module, BinaryenAndVec128(), v128), makeBinary(module, BinaryenOrVec128(), v128), makeBinary(module, BinaryenXorVec128(), v128), makeBinary(module, BinaryenAndNotVec128(), v128), makeBinary(module, BinaryenAddVecI8x16(), v128), makeBinary(module, BinaryenAddSatSVecI8x16(), v128), makeBinary(module, BinaryenAddSatUVecI8x16(), v128), makeBinary(module, BinaryenSubVecI8x16(), v128), makeBinary(module, BinaryenSubSatSVecI8x16(), v128), makeBinary(module, BinaryenSubSatUVecI8x16(), v128), makeBinary(module, BinaryenMinSVecI8x16(), v128), makeBinary(module, BinaryenMinUVecI8x16(), v128), makeBinary(module, BinaryenMaxSVecI8x16(), v128), makeBinary(module, BinaryenMaxUVecI8x16(), v128), makeBinary(module, BinaryenAvgrUVecI8x16(), v128), makeBinary(module, BinaryenAddVecI16x8(), v128), makeBinary(module, BinaryenAddSatSVecI16x8(), v128), makeBinary(module, BinaryenAddSatUVecI16x8(), v128), makeBinary(module, BinaryenSubVecI16x8(), v128), makeBinary(module, BinaryenSubSatSVecI16x8(), v128), makeBinary(module, BinaryenSubSatUVecI16x8(), v128), makeBinary(module, BinaryenMulVecI16x8(), v128), makeBinary(module, BinaryenMinSVecI16x8(), v128), makeBinary(module, BinaryenMinUVecI16x8(), v128), makeBinary(module, BinaryenMaxSVecI16x8(), v128), makeBinary(module, BinaryenMaxUVecI16x8(), v128), makeBinary(module, BinaryenAvgrUVecI16x8(), v128), makeBinary(module, BinaryenQ15MulrSatSVecI16x8(), v128), makeBinary(module, BinaryenExtMulLowSVecI16x8(), v128), makeBinary(module, BinaryenExtMulHighSVecI16x8(), v128), makeBinary(module, BinaryenExtMulLowUVecI16x8(), v128), makeBinary(module, BinaryenExtMulHighUVecI16x8(), v128), makeBinary(module, BinaryenAddVecI32x4(), v128), makeBinary(module, BinaryenSubVecI32x4(), v128), makeBinary(module, BinaryenMulVecI32x4(), v128), makeBinary(module, BinaryenAddVecI64x2(), v128), makeBinary(module, BinaryenSubVecI64x2(), v128), makeBinary(module, BinaryenMulVecI64x2(), v128), makeBinary(module, BinaryenExtMulLowSVecI64x2(), v128), makeBinary(module, BinaryenExtMulHighSVecI64x2(), v128), makeBinary(module, BinaryenExtMulLowUVecI64x2(), v128), makeBinary(module, BinaryenExtMulHighUVecI64x2(), v128), makeBinary(module, BinaryenAddVecF32x4(), v128), makeBinary(module, BinaryenSubVecF32x4(), v128), makeBinary(module, BinaryenMulVecF32x4(), v128), makeBinary(module, BinaryenMinSVecI32x4(), v128), makeBinary(module, BinaryenMinUVecI32x4(), v128), makeBinary(module, BinaryenMaxSVecI32x4(), v128), makeBinary(module, BinaryenMaxUVecI32x4(), v128), makeBinary(module, BinaryenDotSVecI16x8ToVecI32x4(), v128), makeBinary(module, BinaryenExtMulLowSVecI32x4(), v128), makeBinary(module, BinaryenExtMulHighSVecI32x4(), v128), makeBinary(module, BinaryenExtMulLowUVecI32x4(), v128), makeBinary(module, BinaryenExtMulHighUVecI32x4(), v128), makeBinary(module, BinaryenDivVecF32x4(), v128), makeBinary(module, BinaryenMinVecF32x4(), v128), makeBinary(module, BinaryenMaxVecF32x4(), v128), makeBinary(module, BinaryenPMinVecF32x4(), v128), makeBinary(module, BinaryenPMaxVecF32x4(), v128), makeUnary(module, BinaryenCeilVecF32x4(), v128), makeUnary(module, BinaryenFloorVecF32x4(), v128), makeUnary(module, BinaryenTruncVecF32x4(), v128), makeUnary(module, BinaryenNearestVecF32x4(), v128), makeBinary(module, BinaryenAddVecF64x2(), v128), makeBinary(module, BinaryenSubVecF64x2(), v128), makeBinary(module, BinaryenMulVecF64x2(), v128), makeBinary(module, BinaryenDivVecF64x2(), v128), makeBinary(module, BinaryenMinVecF64x2(), v128), makeBinary(module, BinaryenMaxVecF64x2(), v128), makeBinary(module, BinaryenPMinVecF64x2(), v128), makeBinary(module, BinaryenPMaxVecF64x2(), v128), makeUnary(module, BinaryenCeilVecF64x2(), v128), makeUnary(module, BinaryenFloorVecF64x2(), v128), makeUnary(module, BinaryenTruncVecF64x2(), v128), makeUnary(module, BinaryenNearestVecF64x2(), v128), makeUnary(module, BinaryenExtAddPairwiseSVecI8x16ToI16x8(), v128), makeUnary(module, BinaryenExtAddPairwiseUVecI8x16ToI16x8(), v128), makeUnary(module, BinaryenExtAddPairwiseSVecI16x8ToI32x4(), v128), makeUnary(module, BinaryenExtAddPairwiseUVecI16x8ToI32x4(), v128), makeBinary(module, BinaryenNarrowSVecI16x8ToVecI8x16(), v128), makeBinary(module, BinaryenNarrowUVecI16x8ToVecI8x16(), v128), makeBinary(module, BinaryenNarrowSVecI32x4ToVecI16x8(), v128), makeBinary(module, BinaryenNarrowUVecI32x4ToVecI16x8(), v128), makeBinary(module, BinaryenSwizzleVecI8x16(), v128), makeBinary(module, BinaryenRelaxedSwizzleVecI8x16(), v128), makeBinary(module, BinaryenRelaxedMinVecF32x4(), v128), makeBinary(module, BinaryenRelaxedMaxVecF32x4(), v128), makeBinary(module, BinaryenRelaxedMinVecF64x2(), v128), makeBinary(module, BinaryenRelaxedMaxVecF64x2(), v128), makeBinary(module, BinaryenRelaxedQ15MulrSVecI16x8(), v128), makeBinary(module, BinaryenDotI8x16I7x16SToVecI16x8(), v128), // SIMD lane manipulation makeSIMDExtract(module, BinaryenExtractLaneSVecI8x16()), makeSIMDExtract(module, BinaryenExtractLaneUVecI8x16()), makeSIMDExtract(module, BinaryenExtractLaneSVecI16x8()), makeSIMDExtract(module, BinaryenExtractLaneUVecI16x8()), makeSIMDExtract(module, BinaryenExtractLaneVecI32x4()), makeSIMDExtract(module, BinaryenExtractLaneVecI64x2()), makeSIMDExtract(module, BinaryenExtractLaneVecF32x4()), makeSIMDExtract(module, BinaryenExtractLaneVecF64x2()), makeSIMDReplace(module, BinaryenReplaceLaneVecI8x16(), i32), makeSIMDReplace(module, BinaryenReplaceLaneVecI16x8(), i32), makeSIMDReplace(module, BinaryenReplaceLaneVecI32x4(), i32), makeSIMDReplace(module, BinaryenReplaceLaneVecI64x2(), i64), makeSIMDReplace(module, BinaryenReplaceLaneVecF32x4(), f32), makeSIMDReplace(module, BinaryenReplaceLaneVecF64x2(), f64), // SIMD shift makeSIMDShift(module, BinaryenShlVecI8x16()), makeSIMDShift(module, BinaryenShrSVecI8x16()), makeSIMDShift(module, BinaryenShrUVecI8x16()), makeSIMDShift(module, BinaryenShlVecI16x8()), makeSIMDShift(module, BinaryenShrSVecI16x8()), makeSIMDShift(module, BinaryenShrUVecI16x8()), makeSIMDShift(module, BinaryenShlVecI32x4()), makeSIMDShift(module, BinaryenShrSVecI32x4()), makeSIMDShift(module, BinaryenShrUVecI32x4()), makeSIMDShift(module, BinaryenShlVecI64x2()), makeSIMDShift(module, BinaryenShrSVecI64x2()), makeSIMDShift(module, BinaryenShrUVecI64x2()), // SIMD load BinaryenSIMDLoad( module, BinaryenLoad8SplatVec128(), 0, 1, makeInt32(module, 128), "0"), BinaryenSIMDLoad( module, BinaryenLoad16SplatVec128(), 16, 1, makeInt32(module, 128), "0"), BinaryenSIMDLoad( module, BinaryenLoad32SplatVec128(), 16, 4, makeInt32(module, 128), "0"), BinaryenSIMDLoad( module, BinaryenLoad64SplatVec128(), 0, 4, makeInt32(module, 128), "0"), BinaryenSIMDLoad( module, BinaryenLoad8x8SVec128(), 0, 8, makeInt32(module, 128), "0"), BinaryenSIMDLoad( module, BinaryenLoad8x8UVec128(), 0, 8, makeInt32(module, 128), "0"), BinaryenSIMDLoad( module, BinaryenLoad16x4SVec128(), 0, 8, makeInt32(module, 128), "0"), BinaryenSIMDLoad( module, BinaryenLoad16x4UVec128(), 0, 8, makeInt32(module, 128), "0"), BinaryenSIMDLoad( module, BinaryenLoad32x2SVec128(), 0, 8, makeInt32(module, 128), "0"), BinaryenSIMDLoad( module, BinaryenLoad32x2UVec128(), 0, 8, makeInt32(module, 128), "0"), BinaryenSIMDLoad( module, BinaryenLoad32ZeroVec128(), 0, 4, makeInt32(module, 128), "0"), BinaryenSIMDLoad( module, BinaryenLoad64ZeroVec128(), 0, 8, makeInt32(module, 128), "0"), // SIMD load/store lane BinaryenSIMDLoadStoreLane(module, BinaryenLoad8LaneVec128(), 0, 1, 0, makeInt32(module, 128), makeVec128(module, v128_bytes), "0"), BinaryenSIMDLoadStoreLane(module, BinaryenLoad16LaneVec128(), 0, 2, 0, makeInt32(module, 128), makeVec128(module, v128_bytes), "0"), BinaryenSIMDLoadStoreLane(module, BinaryenLoad32LaneVec128(), 0, 4, 0, makeInt32(module, 128), makeVec128(module, v128_bytes), "0"), BinaryenSIMDLoadStoreLane(module, BinaryenLoad64LaneVec128(), 0, 8, 0, makeInt32(module, 128), makeVec128(module, v128_bytes), "0"), BinaryenSIMDLoadStoreLane(module, BinaryenStore8LaneVec128(), 0, 1, 0, makeInt32(module, 128), makeVec128(module, v128_bytes), "0"), BinaryenSIMDLoadStoreLane(module, BinaryenStore16LaneVec128(), 0, 2, 0, makeInt32(module, 128), makeVec128(module, v128_bytes), "0"), BinaryenSIMDLoadStoreLane(module, BinaryenStore32LaneVec128(), 0, 4, 0, makeInt32(module, 128), makeVec128(module, v128_bytes), "0"), BinaryenSIMDLoadStoreLane(module, BinaryenStore64LaneVec128(), 0, 8, 0, makeInt32(module, 128), makeVec128(module, v128_bytes), "0"), // Other SIMD makeSIMDShuffle(module), makeSIMDTernary(module, BinaryenBitselectVec128()), makeSIMDTernary(module, BinaryenRelaxedFmaVecF32x4()), makeSIMDTernary(module, BinaryenRelaxedFmsVecF32x4()), makeSIMDTernary(module, BinaryenRelaxedFmaVecF64x2()), makeSIMDTernary(module, BinaryenRelaxedFmsVecF64x2()), makeSIMDTernary(module, BinaryenLaneselectI8x16()), makeSIMDTernary(module, BinaryenLaneselectI16x8()), makeSIMDTernary(module, BinaryenLaneselectI32x4()), makeSIMDTernary(module, BinaryenLaneselectI64x2()), makeSIMDTernary(module, BinaryenDotI8x16I7x16AddSToVecI32x4()), // Bulk memory makeMemoryInit(module), makeDataDrop(module), makeMemoryCopy(module), makeMemoryFill(module), // All the rest BinaryenBlock(module, NULL, NULL, 0, -1), // block with no name and no type BinaryenIf(module, temp1, temp2, temp3), BinaryenIf(module, temp4, temp5, NULL), BinaryenLoop(module, "in", makeInt32(module, 0)), BinaryenLoop(module, NULL, makeInt32(module, 0)), BinaryenBreak(module, "the-value", temp6, temp7), BinaryenBreak(module, "the-nothing", makeInt32(module, 2), NULL), BinaryenBreak(module, "the-value", NULL, makeInt32(module, 3)), BinaryenBreak(module, "the-nothing", NULL, NULL), BinaryenSwitch(module, switchValueNames, 1, "the-value", temp8, temp9), BinaryenSwitch( module, switchBodyNames, 1, "the-nothing", makeInt32(module, 2), NULL), BinaryenUnary( module, BinaryenEqZInt32(), // check the output type of the call node BinaryenCall( module, "kitchen()sinker", callOperands4, 4, BinaryenTypeInt32())), BinaryenUnary(module, BinaryenEqZInt32(), // check the output type of the call node BinaryenUnary(module, BinaryenTruncSFloat32ToInt32(), BinaryenCall(module, "an-imported", callOperands2, 2, BinaryenTypeFloat32()))), BinaryenUnary(module, BinaryenEqZInt32(), // check the output type of the call node BinaryenCallIndirect(module, "tab", makeInt32(module, 2449), callOperands4b, 4, iIfF, BinaryenTypeInt32())), BinaryenDrop(module, BinaryenLocalGet(module, 0, BinaryenTypeInt32())), BinaryenLocalSet(module, 0, makeInt32(module, 101)), BinaryenDrop( module, BinaryenLocalTee(module, 0, makeInt32(module, 102), BinaryenTypeInt32())), BinaryenLoad( module, 4, 0, 0, 0, BinaryenTypeInt32(), makeInt32(module, 1), "0"), BinaryenLoad( module, 2, 1, 2, 1, BinaryenTypeInt64(), makeInt32(module, 8), "0"), BinaryenLoad( module, 4, 0, 0, 0, BinaryenTypeFloat32(), makeInt32(module, 2), "0"), BinaryenLoad( module, 8, 0, 2, 8, BinaryenTypeFloat64(), makeInt32(module, 9), "0"), BinaryenStore(module, 4, 0, 0, temp13, temp14, BinaryenTypeInt32(), "0"), BinaryenStore(module, 8, 2, 4, temp15, temp16, BinaryenTypeInt64(), "0"), BinaryenSelect(module, temp10, temp11, temp12, BinaryenTypeAuto()), BinaryenReturn(module, makeInt32(module, 1337)), // Tail call BinaryenReturnCall( module, "kitchen()sinker", callOperands4, 4, BinaryenTypeInt32()), BinaryenReturnCallIndirect(module, "tab", makeInt32(module, 2449), callOperands4b, 4, iIfF, BinaryenTypeInt32()), // Reference types BinaryenRefIsNull(module, externrefExpr), BinaryenRefIsNull(module, funcrefExpr), BinaryenSelect( module, temp10, BinaryenRefNull(module, BinaryenTypeNullFuncref()), BinaryenRefFunc(module, "kitchen()sinker", BinaryenTypeFuncref()), BinaryenTypeFuncref()), // GC BinaryenRefEq(module, BinaryenRefNull(module, BinaryenTypeNullref()), BinaryenRefNull(module, BinaryenTypeNullref())), BinaryenRefAs(module, BinaryenRefAsNonNull(), BinaryenRefNull(module, BinaryenTypeNullref())), BinaryenRefAs(module, BinaryenRefAsExternInternalize(), BinaryenRefNull(module, BinaryenTypeNullExternref())), BinaryenRefAs(module, BinaryenRefAsExternExternalize(), BinaryenRefNull(module, BinaryenTypeNullref())), // Exception handling BinaryenTry(module, NULL, tryBody, catchTags, 1, catchBodies, 2, NULL), // (try $try_outer // (do // (try // (do // (throw $a-tag (i32.const 0)) // ) // (delegate $try_outer) // ) // ) // (catch_all) // ) BinaryenTry(module, "try_outer", BinaryenTry(module, NULL, tryBody, emptyCatchTags, 0, emptyCatchBodies, 0, "try_outer"), emptyCatchTags, 0, nopCatchBody, 1, NULL), // Atomics BinaryenAtomicStore( module, 4, 0, temp6, BinaryenAtomicLoad(module, 4, 0, BinaryenTypeInt32(), temp6, "0"), BinaryenTypeInt32(), "0"), BinaryenDrop(module, BinaryenAtomicWait( module, temp6, temp6, temp16, BinaryenTypeInt32(), "0")), BinaryenDrop(module, BinaryenAtomicNotify(module, temp6, temp6, "0")), BinaryenAtomicFence(module), // Tuples BinaryenTupleMake(module, tupleElements4a, 4), BinaryenTupleExtract( module, BinaryenTupleMake(module, tupleElements4b, 4), 2), // Pop BinaryenPop(module, BinaryenTypeInt32()), BinaryenPop(module, BinaryenTypeInt64()), BinaryenPop(module, BinaryenTypeFloat32()), BinaryenPop(module, BinaryenTypeFloat64()), BinaryenPop(module, BinaryenTypeFuncref()), BinaryenPop(module, BinaryenTypeExternref()), BinaryenPop(module, iIfF), // Memory BinaryenMemorySize(module, "0", false), BinaryenMemoryGrow(module, makeInt32(module, 0), "0", false), // GC BinaryenRefI31(module, makeInt32(module, 0)), BinaryenI31Get(module, i31refExpr, 1), BinaryenI31Get(module, BinaryenRefI31(module, makeInt32(module, 2)), 0), BinaryenRefTest( module, BinaryenGlobalGet(module, "i8Array-global", i8Array), i8Array), BinaryenRefCast( module, BinaryenGlobalGet(module, "i8Array-global", i8Array), i8Array), BinaryenStructNew(module, 0, 0, BinaryenTypeGetHeapType(i32Struct)), BinaryenStructNew(module, (BinaryenExpressionRef[]){makeInt32(module, 0)}, 1, BinaryenTypeGetHeapType(i32Struct)), BinaryenStructGet(module, 0, BinaryenGlobalGet(module, "i32Struct-global", i32Struct), BinaryenTypeInt32(), false), BinaryenStructSet(module, 0, BinaryenGlobalGet(module, "i32Struct-global", i32Struct), makeInt32(module, 0)), BinaryenArrayNew( module, BinaryenTypeGetHeapType(i8Array), makeInt32(module, 3), 0), BinaryenArrayNew(module, BinaryenTypeGetHeapType(i8Array), makeInt32(module, 3), makeInt32(module, 42)), BinaryenArrayNewData(module, BinaryenTypeGetHeapType(i8Array), "0", makeInt32(module, 0), makeInt32(module, 2)), BinaryenArrayNewFixed(module, BinaryenTypeGetHeapType(i8Array), (BinaryenExpressionRef[]){makeInt32(module, 1), makeInt32(module, 2), makeInt32(module, 3)}, 3), BinaryenArrayGet(module, BinaryenGlobalGet(module, "i8Array-global", i8Array), makeInt32(module, 0), BinaryenTypeInt32(), true), BinaryenArraySet(module, BinaryenGlobalGet(module, "i8Array-global", i8Array), makeInt32(module, 0), makeInt32(module, 42)), BinaryenArrayLen(module, BinaryenGlobalGet(module, "i8Array-global", i8Array)), BinaryenArrayCopy(module, BinaryenGlobalGet(module, "i8Array-global", i8Array), makeInt32(module, 0), BinaryenGlobalGet(module, "i8Array-global", i8Array), makeInt32(module, 1), makeInt32(module, 2)), // Strings BinaryenStringNew(module, BinaryenStringNewLossyUTF8Array(), BinaryenGlobalGet(module, "i8Array-global", i8Array), makeInt32(module, 0), makeInt32(module, 0)), BinaryenStringNew(module, BinaryenStringNewWTF16Array(), BinaryenGlobalGet(module, "i16Array-global", i8Array), makeInt32(module, 0), makeInt32(module, 0)), BinaryenStringNew( module, BinaryenStringNewFromCodePoint(), makeInt32(module, 1), 0, 0), BinaryenStringConst(module, "hello world"), BinaryenStringMeasure( module, BinaryenStringMeasureUTF8(), BinaryenGlobalGet(module, "string-global", BinaryenTypeStringref())), BinaryenStringMeasure( module, BinaryenStringMeasureWTF16(), BinaryenGlobalGet(module, "string-global", BinaryenTypeStringref())), BinaryenStringEncode( module, BinaryenStringEncodeLossyUTF8Array(), BinaryenGlobalGet(module, "string-global", BinaryenTypeStringref()), BinaryenGlobalGet(module, "i8Array-global", i8Array), makeInt32(module, 0)), BinaryenStringEncode( module, BinaryenStringEncodeWTF16Array(), BinaryenGlobalGet(module, "string-global", BinaryenTypeStringref()), BinaryenGlobalGet(module, "i16Array-global", i16Array), makeInt32(module, 0)), BinaryenStringConcat( module, BinaryenGlobalGet(module, "string-global", BinaryenTypeStringref()), BinaryenGlobalGet(module, "string-global", BinaryenTypeStringref())), BinaryenStringEq( module, BinaryenStringEqEqual(), BinaryenGlobalGet(module, "string-global", BinaryenTypeStringref()), BinaryenGlobalGet(module, "string-global", BinaryenTypeStringref())), BinaryenStringEq( module, BinaryenStringEqCompare(), BinaryenGlobalGet(module, "string-global", BinaryenTypeStringref()), BinaryenGlobalGet(module, "string-global", BinaryenTypeStringref())), BinaryenStringWTF16Get( module, BinaryenGlobalGet(module, "string-global", BinaryenTypeStringref()), makeInt32(module, 0)), BinaryenStringSliceWTF( module, BinaryenGlobalGet(module, "string-global", BinaryenTypeStringref()), makeInt32(module, 0), makeInt32(module, 0)), // Other BinaryenNop(module), BinaryenUnreachable(module), }; BinaryenExpressionPrint( valueList[3]); // test printing a standalone expression // Make the main body of the function. and one block with a return value, one // without BinaryenExpressionRef value = BinaryenBlock(module, "the-value", valueList, sizeof(valueList) / sizeof(BinaryenExpressionRef), BinaryenTypeAuto()); BinaryenExpressionRef droppedValue = BinaryenDrop(module, value); BinaryenExpressionRef nothing = BinaryenBlock(module, "the-nothing", &droppedValue, 1, -1); BinaryenExpressionRef bodyList[] = {nothing, makeInt32(module, 42)}; BinaryenExpressionRef body = BinaryenBlock(module, "the-body", bodyList, 2, BinaryenTypeAuto()); // Create the function BinaryenType localTypes[] = {BinaryenTypeInt32(), BinaryenTypeExternref()}; BinaryenFunctionRef sinker = BinaryenAddFunction( module, "kitchen()sinker", iIfF, BinaryenTypeInt32(), localTypes, 2, body); BinaryenIndex numLocals = BinaryenFunctionGetNumLocals(sinker); BinaryenIndex numParams = BinaryenTypeArity(BinaryenFunctionGetParams(sinker)); BinaryenIndex newLocalIdx = BinaryenFunctionAddVar(sinker, BinaryenTypeFloat32()); assert(newLocalIdx == numLocals); assert(BinaryenFunctionGetNumLocals(sinker) == numLocals + 1); assert(BinaryenFunctionGetVar(sinker, newLocalIdx - numParams) == BinaryenTypeFloat32()); // Globals BinaryenAddGlobal( module, "a-global", BinaryenTypeInt32(), 0, makeInt32(module, 7)); BinaryenAddGlobal(module, "a-mutable-global", BinaryenTypeFloat32(), 1, makeFloat32(module, 7.5)); BinaryenAddGlobal( module, "i8Array-global", i8Array, true, BinaryenArrayNew( module, BinaryenTypeGetHeapType(i8Array), makeInt32(module, 0), 0)); BinaryenAddGlobal( module, "i16Array-global", i16Array, true, BinaryenArrayNew( module, BinaryenTypeGetHeapType(i16Array), makeInt32(module, 0), 0)); BinaryenAddGlobal( module, "i32Struct-global", i32Struct, true, BinaryenStructNew(module, 0, 0, BinaryenTypeGetHeapType(i32Struct))); BinaryenAddGlobal(module, "string-global", BinaryenTypeStringref(), true, BinaryenStringConst(module, "")); // Imports BinaryenType iF_[2] = {BinaryenTypeInt32(), BinaryenTypeFloat64()}; BinaryenType iF = BinaryenTypeCreate(iF_, 2); BinaryenAddFunctionImport( module, "an-imported", "module", "base", iF, BinaryenTypeFloat32()); // Exports BinaryenAddFunctionExport(module, "kitchen()sinker", "kitchen_sinker"); // Function table. One per module const char* funcNames[] = {BinaryenFunctionGetName(sinker)}; BinaryenAddTable(module, "0", 1, 1, BinaryenTypeFuncref()); BinaryenAddActiveElementSegment( module, "0", "0", funcNames, 1, BinaryenConst(module, BinaryenLiteralInt32(0))); BinaryenAddPassiveElementSegment(module, "passive", funcNames, 1); BinaryenAddPassiveElementSegment(module, "p2", funcNames, 1); BinaryenRemoveElementSegment(module, "p2"); BinaryenExpressionRef funcrefExpr1 = BinaryenRefFunc(module, "kitchen()sinker", BinaryenTypeFuncref()); BinaryenExpressionPrint(BinaryenTableSet( module, "0", BinaryenConst(module, BinaryenLiteralInt32(0)), funcrefExpr1)); BinaryenExpressionRef funcrefExpr2 = BinaryenTableGet(module, "0", BinaryenConst(module, BinaryenLiteralInt32(0)), BinaryenTypeFuncref()); BinaryenExpressionPrint(funcrefExpr2); BinaryenExpressionRef tablesize = BinaryenTableSize(module, "0"); BinaryenExpressionPrint(tablesize); const char* table = BinaryenTableSizeGetTable(tablesize); BinaryenTableSizeSetTable(tablesize, table); BinaryenExpressionRef valueExpr = BinaryenRefNull(module, BinaryenTypeNullFuncref()); BinaryenExpressionRef sizeExpr = makeInt32(module, 0); BinaryenExpressionRef growExpr = BinaryenTableGrow(module, "0", valueExpr, sizeExpr); BinaryenExpressionPrint(growExpr); // Start function. One per module BinaryenFunctionRef starter = BinaryenAddFunction(module, "starter", BinaryenTypeNone(), BinaryenTypeNone(), NULL, 0, BinaryenNop(module)); BinaryenSetStart(module, starter); // A bunch of our code needs drop(), auto-add it BinaryenModuleAutoDrop(module); BinaryenFeatures features = BinaryenFeatureAll(); BinaryenModuleSetFeatures(module, features); assert(BinaryenModuleGetFeatures(module) == features); // Print it out BinaryenModulePrint(module); // Verify it validates int valid = BinaryenModuleValidate(module); assert(valid); // Verify no error occurs when writing out the code to binary. size_t bufferSize = 10 * 1024 * 1024; char* buffer = malloc(bufferSize); size_t written = BinaryenModuleWrite(module, buffer, bufferSize); // We wrote bytes, and we did not reach the end of the buffer (which would // truncate). assert(written > 0 && written < bufferSize); // Clean up the module, which owns all the objects we created above BinaryenModuleDispose(module); // See we can read the bytes and get a valid module from there. BinaryenModuleRef readModule = BinaryenModuleRead(buffer, written); BinaryenModuleSetFeatures(readModule, BinaryenFeatureAll()); valid = BinaryenModuleValidate(readModule); assert(valid); BinaryenModuleDispose(readModule); free(buffer); } void test_unreachable() { BinaryenModuleRef module = BinaryenModuleCreate(); BinaryenExpressionRef body = BinaryenCallIndirect(module, "invalid-table", BinaryenUnreachable(module), NULL, 0, BinaryenTypeNone(), BinaryenTypeInt64()); BinaryenFunctionRef fn = BinaryenAddFunction(module, "unreachable-fn", BinaryenTypeNone(), BinaryenTypeInt32(), NULL, 0, body); assert(BinaryenModuleValidate(module)); BinaryenModulePrint(module); BinaryenModuleDispose(module); } BinaryenExpressionRef makeCallCheck(BinaryenModuleRef module, int x) { BinaryenExpressionRef callOperands[] = {makeInt32(module, x)}; return BinaryenCall(module, "check", callOperands, 1, BinaryenTypeNone()); } void test_relooper() { BinaryenModuleRef module = BinaryenModuleCreate(); BinaryenType localTypes[] = {BinaryenTypeInt32()}; BinaryenAddFunctionImport(module, "check", "module", "check", BinaryenTypeInt32(), BinaryenTypeNone()); { // trivial: just one block RelooperRef relooper = RelooperCreate(module); RelooperBlockRef block = RelooperAddBlock(relooper, makeCallCheck(module, 1337)); BinaryenExpressionRef body = RelooperRenderAndDispose(relooper, block, 0); BinaryenFunctionRef sinker = BinaryenAddFunction(module, "just-one-block", BinaryenTypeNone(), BinaryenTypeNone(), localTypes, 1, body); } { // two blocks RelooperRef relooper = RelooperCreate(module); RelooperBlockRef block0 = RelooperAddBlock(relooper, makeCallCheck(module, 0)); RelooperBlockRef block1 = RelooperAddBlock(relooper, makeCallCheck(module, 1)); RelooperAddBranch( block0, block1, NULL, NULL); // no condition, no code on branch BinaryenExpressionRef body = RelooperRenderAndDispose(relooper, block0, 0); BinaryenFunctionRef sinker = BinaryenAddFunction(module, "two-blocks", BinaryenTypeNone(), BinaryenTypeNone(), localTypes, 1, body); } { // two blocks with code between them RelooperRef relooper = RelooperCreate(module); RelooperBlockRef block0 = RelooperAddBlock(relooper, makeCallCheck(module, 0)); RelooperBlockRef block1 = RelooperAddBlock(relooper, makeCallCheck(module, 1)); RelooperAddBranch( block0, block1, NULL, makeDroppedInt32(module, 77)); // code on branch BinaryenExpressionRef body = RelooperRenderAndDispose(relooper, block0, 0); BinaryenFunctionRef sinker = BinaryenAddFunction(module, "two-blocks-plus-code", BinaryenTypeNone(), BinaryenTypeNone(), localTypes, 1, body); } { // two blocks in a loop RelooperRef relooper = RelooperCreate(module); RelooperBlockRef block0 = RelooperAddBlock(relooper, makeCallCheck(module, 0)); RelooperBlockRef block1 = RelooperAddBlock(relooper, makeCallCheck(module, 1)); RelooperAddBranch(block0, block1, NULL, NULL); RelooperAddBranch(block1, block0, NULL, NULL); BinaryenExpressionRef body = RelooperRenderAndDispose(relooper, block0, 0); BinaryenFunctionRef sinker = BinaryenAddFunction(module, "loop", BinaryenTypeNone(), BinaryenTypeNone(), localTypes, 1, body); } { // two blocks in a loop with codes RelooperRef relooper = RelooperCreate(module); RelooperBlockRef block0 = RelooperAddBlock(relooper, makeCallCheck(module, 0)); RelooperBlockRef block1 = RelooperAddBlock(relooper, makeCallCheck(module, 1)); RelooperAddBranch(block0, block1, NULL, makeDroppedInt32(module, 33)); RelooperAddBranch(block1, block0, NULL, makeDroppedInt32(module, -66)); BinaryenExpressionRef body = RelooperRenderAndDispose(relooper, block0, 0); BinaryenFunctionRef sinker = BinaryenAddFunction(module, "loop-plus-code", BinaryenTypeNone(), BinaryenTypeNone(), localTypes, 1, body); } { // split RelooperRef relooper = RelooperCreate(module); RelooperBlockRef block0 = RelooperAddBlock(relooper, makeCallCheck(module, 0)); RelooperBlockRef block1 = RelooperAddBlock(relooper, makeCallCheck(module, 1)); RelooperBlockRef block2 = RelooperAddBlock(relooper, makeCallCheck(module, 2)); RelooperAddBranch(block0, block1, makeInt32(module, 55), NULL); RelooperAddBranch(block0, block2, NULL, NULL); BinaryenExpressionRef body = RelooperRenderAndDispose(relooper, block0, 0); BinaryenFunctionRef sinker = BinaryenAddFunction(module, "split", BinaryenTypeNone(), BinaryenTypeNone(), localTypes, 1, body); } { // split + code RelooperRef relooper = RelooperCreate(module); RelooperBlockRef block0 = RelooperAddBlock(relooper, makeCallCheck(module, 0)); RelooperBlockRef block1 = RelooperAddBlock(relooper, makeCallCheck(module, 1)); RelooperBlockRef block2 = RelooperAddBlock(relooper, makeCallCheck(module, 2)); BinaryenExpressionRef temp = makeDroppedInt32(module, 10); RelooperAddBranch(block0, block1, makeInt32(module, 55), temp); RelooperAddBranch(block0, block2, NULL, makeDroppedInt32(module, 20)); BinaryenExpressionRef body = RelooperRenderAndDispose(relooper, block0, 0); BinaryenFunctionRef sinker = BinaryenAddFunction(module, "split-plus-code", BinaryenTypeNone(), BinaryenTypeNone(), localTypes, 1, body); } { // if RelooperRef relooper = RelooperCreate(module); RelooperBlockRef block0 = RelooperAddBlock(relooper, makeCallCheck(module, 0)); RelooperBlockRef block1 = RelooperAddBlock(relooper, makeCallCheck(module, 1)); RelooperBlockRef block2 = RelooperAddBlock(relooper, makeCallCheck(module, 2)); RelooperAddBranch(block0, block1, makeInt32(module, 55), NULL); RelooperAddBranch(block0, block2, NULL, NULL); RelooperAddBranch(block1, block2, NULL, NULL); BinaryenExpressionRef body = RelooperRenderAndDispose(relooper, block0, 0); BinaryenFunctionRef sinker = BinaryenAddFunction(module, "if", BinaryenTypeNone(), BinaryenTypeNone(), localTypes, 1, body); } { // if + code RelooperRef relooper = RelooperCreate(module); RelooperBlockRef block0 = RelooperAddBlock(relooper, makeCallCheck(module, 0)); RelooperBlockRef block1 = RelooperAddBlock(relooper, makeCallCheck(module, 1)); RelooperBlockRef block2 = RelooperAddBlock(relooper, makeCallCheck(module, 2)); BinaryenExpressionRef temp = makeDroppedInt32(module, -1); RelooperAddBranch(block0, block1, makeInt32(module, 55), temp); RelooperAddBranch(block0, block2, NULL, makeDroppedInt32(module, -2)); RelooperAddBranch(block1, block2, NULL, makeDroppedInt32(module, -3)); BinaryenExpressionRef body = RelooperRenderAndDispose(relooper, block0, 0); BinaryenFunctionRef sinker = BinaryenAddFunction(module, "if-plus-code", BinaryenTypeNone(), BinaryenTypeNone(), localTypes, 1, body); } { // if-else RelooperRef relooper = RelooperCreate(module); RelooperBlockRef block0 = RelooperAddBlock(relooper, makeCallCheck(module, 0)); RelooperBlockRef block1 = RelooperAddBlock(relooper, makeCallCheck(module, 1)); RelooperBlockRef block2 = RelooperAddBlock(relooper, makeCallCheck(module, 2)); RelooperBlockRef block3 = RelooperAddBlock(relooper, makeCallCheck(module, 3)); RelooperAddBranch(block0, block1, makeInt32(module, 55), NULL); RelooperAddBranch(block0, block2, NULL, NULL); RelooperAddBranch(block1, block3, NULL, NULL); RelooperAddBranch(block2, block3, NULL, NULL); BinaryenExpressionRef body = RelooperRenderAndDispose(relooper, block0, 0); BinaryenFunctionRef sinker = BinaryenAddFunction(module, "if-else", BinaryenTypeNone(), BinaryenTypeNone(), localTypes, 1, body); } { // loop+tail RelooperRef relooper = RelooperCreate(module); RelooperBlockRef block0 = RelooperAddBlock(relooper, makeCallCheck(module, 0)); RelooperBlockRef block1 = RelooperAddBlock(relooper, makeCallCheck(module, 1)); RelooperBlockRef block2 = RelooperAddBlock(relooper, makeCallCheck(module, 2)); RelooperAddBranch(block0, block1, NULL, NULL); RelooperAddBranch(block1, block0, makeInt32(module, 10), NULL); RelooperAddBranch(block1, block2, NULL, NULL); BinaryenExpressionRef body = RelooperRenderAndDispose(relooper, block0, 0); BinaryenFunctionRef sinker = BinaryenAddFunction(module, "loop-tail", BinaryenTypeNone(), BinaryenTypeNone(), localTypes, 1, body); } { // nontrivial loop + phi to head RelooperRef relooper = RelooperCreate(module); RelooperBlockRef block0 = RelooperAddBlock(relooper, makeCallCheck(module, 0)); RelooperBlockRef block1 = RelooperAddBlock(relooper, makeCallCheck(module, 1)); RelooperBlockRef block2 = RelooperAddBlock(relooper, makeCallCheck(module, 2)); RelooperBlockRef block3 = RelooperAddBlock(relooper, makeCallCheck(module, 3)); RelooperBlockRef block4 = RelooperAddBlock(relooper, makeCallCheck(module, 4)); RelooperBlockRef block5 = RelooperAddBlock(relooper, makeCallCheck(module, 5)); RelooperBlockRef block6 = RelooperAddBlock(relooper, makeCallCheck(module, 6)); RelooperAddBranch(block0, block1, NULL, makeDroppedInt32(module, 10)); RelooperAddBranch(block1, block2, makeInt32(module, -2), NULL); RelooperAddBranch(block1, block6, NULL, makeDroppedInt32(module, 20)); RelooperAddBranch(block2, block3, makeInt32(module, -6), NULL); RelooperAddBranch(block2, block1, NULL, makeDroppedInt32(module, 30)); RelooperAddBranch(block3, block4, makeInt32(module, -10), NULL); RelooperAddBranch(block3, block5, NULL, NULL); RelooperAddBranch(block4, block5, NULL, NULL); RelooperAddBranch(block5, block6, NULL, makeDroppedInt32(module, 40)); BinaryenExpressionRef body = RelooperRenderAndDispose(relooper, block0, 0); BinaryenFunctionRef sinker = BinaryenAddFunction(module, "nontrivial-loop-plus-phi-to-head", BinaryenTypeNone(), BinaryenTypeNone(), localTypes, 1, body); } { // switch RelooperRef relooper = RelooperCreate(module); BinaryenExpressionRef temp = makeInt32(module, -99); RelooperBlockRef block0 = RelooperAddBlockWithSwitch(relooper, makeCallCheck(module, 0), temp); // TODO: this example is not very good, the blocks should end in a |return| // as otherwise they // fall through to each other. A relooper block should end in // something that stops control flow, if it doesn't have branches // going out RelooperBlockRef block1 = RelooperAddBlock(relooper, makeCallCheck(module, 1)); RelooperBlockRef block2 = RelooperAddBlock(relooper, makeCallCheck(module, 2)); RelooperBlockRef block3 = RelooperAddBlock(relooper, makeCallCheck(module, 3)); BinaryenIndex to_block1[] = {2, 5}; RelooperAddBranchForSwitch(block0, block1, to_block1, 2, NULL); BinaryenIndex to_block2[] = {4}; RelooperAddBranchForSwitch( block0, block2, to_block2, 1, makeDroppedInt32(module, 55)); RelooperAddBranchForSwitch(block0, block3, NULL, 0, NULL); BinaryenExpressionRef body = RelooperRenderAndDispose(relooper, block0, 0); BinaryenFunctionRef sinker = BinaryenAddFunction(module, "switch", BinaryenTypeNone(), BinaryenTypeNone(), localTypes, 1, body); } { // duff's device RelooperRef relooper = RelooperCreate(module); RelooperBlockRef block0 = RelooperAddBlock(relooper, makeCallCheck(module, 0)); RelooperBlockRef block1 = RelooperAddBlock(relooper, makeCallCheck(module, 1)); RelooperBlockRef block2 = RelooperAddBlock(relooper, makeCallCheck(module, 2)); RelooperAddBranch(block0, block1, makeInt32(module, 10), NULL); RelooperAddBranch(block0, block2, NULL, NULL); RelooperAddBranch(block1, block2, NULL, NULL); RelooperAddBranch(block2, block1, NULL, NULL); BinaryenExpressionRef body = RelooperRenderAndDispose(relooper, block0, 3); // use $3 as the helper var BinaryenType localTypes[] = {BinaryenTypeInt32(), BinaryenTypeInt32(), BinaryenTypeInt64(), BinaryenTypeInt32(), BinaryenTypeFloat32(), BinaryenTypeFloat64(), BinaryenTypeInt32()}; BinaryenFunctionRef sinker = BinaryenAddFunction(module, "duffs-device", BinaryenTypeNone(), BinaryenTypeNone(), localTypes, sizeof(localTypes) / sizeof(BinaryenType), body); } { // return in a block RelooperRef relooper = RelooperCreate(module); BinaryenExpressionRef listList[] = { makeCallCheck(module, 42), BinaryenReturn(module, makeInt32(module, 1337))}; BinaryenExpressionRef list = BinaryenBlock(module, "the-list", listList, 2, -1); RelooperBlockRef block = RelooperAddBlock(relooper, list); BinaryenExpressionRef body = RelooperRenderAndDispose(relooper, block, 0); BinaryenFunctionRef sinker = BinaryenAddFunction(module, "return", BinaryenTypeNone(), BinaryenTypeInt32(), localTypes, 1, body); } printf("raw:\n"); BinaryenModulePrint(module); assert(BinaryenModuleValidate(module)); BinaryenModuleOptimize(module); assert(BinaryenModuleValidate(module)); printf("optimized:\n"); BinaryenModulePrint(module); BinaryenModuleDispose(module); } void test_binaries() { char buffer[1024]; size_t size; { // create a module and write it to binary BinaryenModuleRef module = BinaryenModuleCreate(); BinaryenType ii_[2] = {BinaryenTypeInt32(), BinaryenTypeInt32()}; BinaryenType ii = BinaryenTypeCreate(ii_, 2); BinaryenExpressionRef x = BinaryenLocalGet(module, 0, BinaryenTypeInt32()), y = BinaryenLocalGet(module, 1, BinaryenTypeInt32()); BinaryenExpressionRef add = BinaryenBinary(module, BinaryenAddInt32(), x, y); BinaryenFunctionRef adder = BinaryenAddFunction( module, "adder", ii, BinaryenTypeInt32(), NULL, 0, add); BinaryenSetDebugInfo(1); // include names section size = BinaryenModuleWrite(module, buffer, 1024); // write out the module BinaryenSetDebugInfo(0); BinaryenModuleDispose(module); } assert(size > 0); assert(size < 512); // this is a tiny module // read the module from the binary BinaryenModuleRef module = BinaryenModuleRead(buffer, size); // validate, print, and free assert(BinaryenModuleValidate(module)); printf("module loaded from binary form:\n"); BinaryenModulePrint(module); // write the s-expr representation of the module. BinaryenModuleWriteText(module, buffer, 1024); printf("module s-expr printed (in memory):\n%s\n", buffer); // write the s-expr representation to a pointer which is managed by the // caller char* text = BinaryenModuleAllocateAndWriteText(module); printf("module s-expr printed (in memory, caller-owned):\n%s\n", text); free(text); // write StackIR text = BinaryenModuleAllocateAndWriteStackIR(module); printf("module s-expr printed (StackIR):\n%s\n", text); free(text); BinaryenModuleDispose(module); } void test_interpret() { // create a simple module with a start method that prints a number, and // interpret it, printing that number. BinaryenModuleRef module = BinaryenModuleCreate(); BinaryenType iparams[2] = {BinaryenTypeInt32()}; BinaryenAddFunctionImport(module, "print-i32", "spectest", "print", BinaryenTypeInt32(), BinaryenTypeNone()); BinaryenExpressionRef callOperands[] = {makeInt32(module, 1234)}; BinaryenExpressionRef call = BinaryenCall(module, "print-i32", callOperands, 1, BinaryenTypeNone()); BinaryenFunctionRef starter = BinaryenAddFunction( module, "starter", BinaryenTypeNone(), BinaryenTypeNone(), NULL, 0, call); BinaryenSetStart(module, starter); BinaryenModulePrint(module); assert(BinaryenModuleValidate(module)); BinaryenModuleInterpret(module); BinaryenModuleDispose(module); } void test_nonvalid() { // create a module that fails to validate { BinaryenModuleRef module = BinaryenModuleCreate(); BinaryenType localTypes[] = {BinaryenTypeInt32()}; BinaryenFunctionRef func = BinaryenAddFunction( module, "func", BinaryenTypeNone(), BinaryenTypeNone(), localTypes, 1, BinaryenLocalSet(module, 0, makeInt64(module, 1234)) // wrong type! ); BinaryenModulePrint(module); printf("validation: %d\n", BinaryenModuleValidate(module)); BinaryenModuleDispose(module); } } void test_color_status() { int i; // save old state const int old_state = BinaryenAreColorsEnabled(); // Check that we can set the state to both {0, 1} for (i = 0; i <= 1; i++) { BinaryenSetColorsEnabled(i); assert(BinaryenAreColorsEnabled() == i); } BinaryenSetColorsEnabled(old_state); } void test_for_each() { BinaryenIndex i; BinaryenModuleRef module = BinaryenModuleCreate(); BinaryenFunctionRef fns[3] = {}; fns[0] = BinaryenAddFunction(module, "fn0", BinaryenTypeNone(), BinaryenTypeNone(), NULL, 0, BinaryenNop(module)); fns[1] = BinaryenAddFunction(module, "fn1", BinaryenTypeNone(), BinaryenTypeNone(), NULL, 0, BinaryenNop(module)); fns[2] = BinaryenAddFunction(module, "fn2", BinaryenTypeNone(), BinaryenTypeNone(), NULL, 0, BinaryenNop(module)); { for (i = 0; i < BinaryenGetNumFunctions(module); i++) { assert(BinaryenGetFunctionByIndex(module, i) == fns[i]); } BinaryenExportRef exps[3] = {0}; exps[0] = BinaryenAddFunctionExport(module, "fn0", "export0"); exps[1] = BinaryenAddFunctionExport(module, "fn1", "export1"); exps[2] = BinaryenAddFunctionExport(module, "fn2", "export2"); for (i = 0; i < BinaryenGetNumExports(module); i++) { assert(BinaryenGetExportByIndex(module, i) == exps[i]); } const char* segmentNames[] = {"0", "1"}; const char* segmentDatas[] = {"hello, world", "segment data 2"}; const uint32_t expected_offsets[] = {10, 125}; bool segmentPassives[] = {false, false}; BinaryenIndex segmentSizes[] = {12, 14}; BinaryenExpressionRef segmentOffsets[] = { BinaryenConst(module, BinaryenLiteralInt32(expected_offsets[0])), BinaryenGlobalGet(module, "a-global", BinaryenTypeInt32())}; BinaryenSetMemory(module, 1, 256, "mem", segmentNames, segmentDatas, segmentPassives, segmentOffsets, segmentSizes, 2, 0, 0, "0"); BinaryenAddGlobal(module, "a-global", BinaryenTypeInt32(), 0, makeInt32(module, expected_offsets[1])); for (i = 0; i < BinaryenGetNumMemorySegments(module); i++) { char out[15] = {}; assert(BinaryenGetMemorySegmentByteOffset(module, segmentNames[i]) == expected_offsets[i]); assert(BinaryenGetMemorySegmentByteLength(module, segmentNames[i]) == segmentSizes[i]); BinaryenCopyMemorySegmentData(module, segmentNames[i], out); assert(0 == strcmp(segmentDatas[i], out)); } } { const char* funcNames[] = {BinaryenFunctionGetName(fns[0]), BinaryenFunctionGetName(fns[1]), BinaryenFunctionGetName(fns[2])}; BinaryenExpressionRef constExprRef = BinaryenConst(module, BinaryenLiteralInt32(0)); BinaryenAddTable(module, "0", 1, 1, BinaryenTypeFuncref()); BinaryenAddActiveElementSegment( module, "0", "0", funcNames, 3, constExprRef); assert(1 == BinaryenGetNumElementSegments(module)); BinaryenElementSegmentRef segment = BinaryenGetElementSegmentByIndex(module, 0); assert(constExprRef == BinaryenElementSegmentGetOffset(segment)); for (i = 0; i != BinaryenElementSegmentGetLength(segment); ++i) { const char* str = BinaryenElementSegmentGetData(segment, i); assert(0 == strcmp(funcNames[i], str)); } } BinaryenModulePrint(module); BinaryenModuleDispose(module); } void test_func_opt() { BinaryenModuleRef module = BinaryenModuleCreate(); BinaryenType ii_[2] = {BinaryenTypeInt32(), BinaryenTypeInt32()}; BinaryenType ii = BinaryenTypeCreate(ii_, 2); BinaryenExpressionRef x = BinaryenConst(module, BinaryenLiteralInt32(1)), y = BinaryenConst(module, BinaryenLiteralInt32(3)); BinaryenExpressionRef add = BinaryenBinary(module, BinaryenAddInt32(), x, y); BinaryenFunctionRef adder = BinaryenAddFunction( module, "adder", BinaryenTypeNone(), BinaryenTypeInt32(), NULL, 0, add); puts("module with a function to optimize:"); BinaryenModulePrint(module); assert(BinaryenModuleValidate(module)); BinaryenFunctionOptimize(adder, module); assert(BinaryenModuleValidate(module)); puts("optimized:"); BinaryenModulePrint(module); BinaryenModuleDispose(module); } void test_typebuilder() { printf("TypeBuilderErrorReasonSelfSupertype: %d\n", TypeBuilderErrorReasonSelfSupertype()); printf("TypeBuilderErrorReasonInvalidSupertype: %d\n", TypeBuilderErrorReasonInvalidSupertype()); printf("TypeBuilderErrorReasonForwardSupertypeReference: %d\n", TypeBuilderErrorReasonForwardSupertypeReference()); printf("TypeBuilderErrorReasonForwardChildReference: %d\n", TypeBuilderErrorReasonForwardChildReference()); TypeBuilderRef builder = TypeBuilderCreate(0); assert(TypeBuilderGetSize(builder) == 0); TypeBuilderGrow(builder, 4); assert(TypeBuilderGetSize(builder) == 4); // Create a recursive array of its own type const BinaryenIndex tempArrayIndex = 0; BinaryenHeapType tempArrayHeapType = TypeBuilderGetTempHeapType(builder, tempArrayIndex); BinaryenType tempArrayType = TypeBuilderGetTempRefType(builder, tempArrayHeapType, true); TypeBuilderSetArrayType(builder, tempArrayIndex, tempArrayType, BinaryenPackedTypeNotPacked(), true); TypeBuilderSetOpen(builder, tempArrayIndex); // Create a recursive struct with a field of its own type const BinaryenIndex tempStructIndex = 1; BinaryenHeapType tempStructHeapType = TypeBuilderGetTempHeapType(builder, tempStructIndex); BinaryenType tempStructType = TypeBuilderGetTempRefType(builder, tempStructHeapType, true); { BinaryenType fieldTypes[] = {tempStructType}; BinaryenPackedType fieldPackedTypes[] = {BinaryenPackedTypeNotPacked()}; bool fieldMutables[] = {true}; TypeBuilderSetStructType( builder, tempStructIndex, fieldTypes, fieldPackedTypes, fieldMutables, 1); TypeBuilderSetOpen(builder, tempStructIndex); } // Create a recursive signature with parameter and result including its own // type const BinaryenIndex tempSignatureIndex = 2; BinaryenHeapType tempSignatureHeapType = TypeBuilderGetTempHeapType(builder, tempSignatureIndex); BinaryenType tempSignatureType = TypeBuilderGetTempRefType(builder, tempSignatureHeapType, true); { BinaryenType paramTypes[] = {tempSignatureType, tempArrayType}; TypeBuilderSetSignatureType( builder, tempSignatureIndex, TypeBuilderGetTempTupleType(builder, (BinaryenType*)¶mTypes, 2), tempSignatureType); TypeBuilderSetOpen(builder, tempSignatureIndex); } // Create a subtype (with an additional immutable packed field) const BinaryenIndex tempSubStructIndex = 3; BinaryenHeapType tempSubStructHeapType = TypeBuilderGetTempHeapType(builder, tempSubStructIndex); BinaryenType tempSubStructType = TypeBuilderGetTempRefType(builder, tempSubStructHeapType, true); { BinaryenType fieldTypes[] = { tempStructType, BinaryenTypeInt32()}; // must repeat existing fields BinaryenPackedType fieldPackedTypes[] = {BinaryenPackedTypeNotPacked(), BinaryenPackedTypeInt8()}; bool fieldMutables[] = {true, false}; TypeBuilderSetStructType(builder, tempSubStructIndex, fieldTypes, fieldPackedTypes, fieldMutables, 2); TypeBuilderSetOpen(builder, tempSubStructIndex); } TypeBuilderSetSubType(builder, tempSubStructIndex, tempStructHeapType); // Build the type hierarchy and dispose the builder BinaryenHeapType heapTypes[4]; BinaryenIndex errorIndex; TypeBuilderErrorReason errorReason; bool didBuildAndDispose = TypeBuilderBuildAndDispose( builder, (BinaryenHeapType*)&heapTypes, &errorIndex, &errorReason); assert(didBuildAndDispose); BinaryenHeapType arrayHeapType = heapTypes[tempArrayIndex]; assert(!BinaryenHeapTypeIsSignature(arrayHeapType)); assert(!BinaryenHeapTypeIsStruct(arrayHeapType)); assert(BinaryenHeapTypeIsArray(arrayHeapType)); assert(!BinaryenHeapTypeIsBottom(arrayHeapType)); assert(BinaryenHeapTypeIsSubType(arrayHeapType, BinaryenHeapTypeArray())); BinaryenType arrayType = BinaryenTypeFromHeapType(arrayHeapType, true); assert(BinaryenArrayTypeGetElementType(arrayHeapType) == arrayType); assert(BinaryenArrayTypeGetElementPackedType(arrayHeapType) == BinaryenPackedTypeNotPacked()); assert(BinaryenArrayTypeIsElementMutable(arrayHeapType)); BinaryenHeapType structHeapType = heapTypes[tempStructIndex]; assert(!BinaryenHeapTypeIsSignature(structHeapType)); assert(BinaryenHeapTypeIsStruct(structHeapType)); assert(!BinaryenHeapTypeIsArray(structHeapType)); assert(!BinaryenHeapTypeIsBottom(structHeapType)); assert(BinaryenHeapTypeIsSubType(structHeapType, BinaryenHeapTypeStruct())); BinaryenType structType = BinaryenTypeFromHeapType(structHeapType, true); assert(BinaryenStructTypeGetNumFields(structHeapType) == 1); assert(BinaryenStructTypeGetFieldType(structHeapType, 0) == structType); assert(BinaryenStructTypeGetFieldPackedType(structHeapType, 0) == BinaryenPackedTypeNotPacked()); assert(BinaryenStructTypeIsFieldMutable(structHeapType, 0)); BinaryenHeapType signatureHeapType = heapTypes[tempSignatureIndex]; assert(BinaryenHeapTypeIsSignature(signatureHeapType)); assert(!BinaryenHeapTypeIsStruct(signatureHeapType)); assert(!BinaryenHeapTypeIsArray(signatureHeapType)); assert(!BinaryenHeapTypeIsBottom(signatureHeapType)); assert(BinaryenHeapTypeIsSubType(signatureHeapType, BinaryenHeapTypeFunc())); BinaryenType signatureType = BinaryenTypeFromHeapType(signatureHeapType, true); BinaryenType signatureParams = BinaryenSignatureTypeGetParams(signatureHeapType); assert(BinaryenTypeArity(signatureParams) == 2); BinaryenType expandedSignatureParams[2]; BinaryenTypeExpand(signatureParams, (BinaryenType*)expandedSignatureParams); assert(expandedSignatureParams[0] == signatureType); assert(expandedSignatureParams[1] == arrayType); BinaryenType signatureResults = BinaryenSignatureTypeGetResults(signatureHeapType); assert(BinaryenTypeArity(signatureResults) == 1); assert(signatureResults == signatureType); BinaryenHeapType subStructHeapType = heapTypes[tempSubStructIndex]; assert(!BinaryenHeapTypeIsSignature(subStructHeapType)); assert(BinaryenHeapTypeIsStruct(subStructHeapType)); assert(!BinaryenHeapTypeIsArray(subStructHeapType)); assert(!BinaryenHeapTypeIsBottom(subStructHeapType)); assert( BinaryenHeapTypeIsSubType(subStructHeapType, BinaryenHeapTypeStruct())); assert(BinaryenHeapTypeIsSubType(subStructHeapType, structHeapType)); BinaryenType subStructType = BinaryenTypeFromHeapType(subStructHeapType, true); assert(BinaryenStructTypeGetNumFields(subStructHeapType) == 2); assert(BinaryenStructTypeGetFieldType(subStructHeapType, 0) == structType); assert(BinaryenStructTypeGetFieldType(subStructHeapType, 1) == BinaryenTypeInt32()); assert(BinaryenStructTypeGetFieldPackedType(subStructHeapType, 0) == BinaryenPackedTypeNotPacked()); assert(BinaryenStructTypeGetFieldPackedType(subStructHeapType, 1) == BinaryenPackedTypeInt8()); assert(BinaryenStructTypeIsFieldMutable(subStructHeapType, 0)); assert(!BinaryenStructTypeIsFieldMutable(subStructHeapType, 1)); // Build a simple test module, validate and print it BinaryenModuleRef module = BinaryenModuleCreate(); BinaryenModuleSetTypeName(module, arrayHeapType, "SomeArray"); BinaryenModuleSetTypeName(module, structHeapType, "SomeStruct"); BinaryenModuleSetFieldName(module, structHeapType, 0, "SomeField"); BinaryenModuleSetTypeName(module, signatureHeapType, "SomeSignature"); BinaryenModuleSetTypeName(module, subStructHeapType, "SomeSubStruct"); BinaryenModuleSetFieldName(module, subStructHeapType, 0, "SomeField"); BinaryenModuleSetFieldName(module, subStructHeapType, 1, "SomePackedField"); BinaryenModuleSetFeatures( module, BinaryenFeatureReferenceTypes() | BinaryenFeatureGC()); { BinaryenType varTypes[] = { arrayType, structType, signatureType, subStructType}; BinaryenAddFunction(module, "test", BinaryenTypeNone(), BinaryenTypeNone(), varTypes, 4, BinaryenNop(module)); // Also test adding a function using the HeapType-using API. BinaryenAddFunctionWithHeapType( module, "test2", signatureHeapType, NULL, 0, BinaryenUnreachable(module)); } bool didValidate = BinaryenModuleValidate(module); assert(didValidate); printf("module with recursive GC types:\n"); BinaryenModulePrint(module); BinaryenModuleDispose(module); } int main() { test_types(); test_features(); test_core(); test_unreachable(); test_relooper(); test_binaries(); test_interpret(); test_nonvalid(); test_color_status(); test_for_each(); test_func_opt(); test_typebuilder(); return 0; }