//===- LLVMDialect.cpp - MLIR SPIR-V dialect ------------------------------===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// // // This file defines the SPIR-V dialect in MLIR. // //===----------------------------------------------------------------------===// #include "mlir/Dialect/SPIRV/IR/SPIRVDialect.h" #include "SPIRVParsingUtils.h" #include "mlir/Dialect/GPU/IR/CompilationInterfaces.h" #include "mlir/Dialect/SPIRV/IR/SPIRVOps.h" #include "mlir/Dialect/SPIRV/IR/SPIRVTypes.h" #include "mlir/Dialect/SPIRV/IR/TargetAndABI.h" #include "mlir/Dialect/UB/IR/UBOps.h" #include "mlir/IR/Builders.h" #include "mlir/IR/BuiltinTypes.h" #include "mlir/IR/DialectImplementation.h" #include "mlir/IR/MLIRContext.h" #include "mlir/Parser/Parser.h" #include "mlir/Transforms/InliningUtils.h" #include "llvm/ADT/DenseMap.h" #include "llvm/ADT/Sequence.h" #include "llvm/ADT/SetVector.h" #include "llvm/ADT/StringExtras.h" #include "llvm/ADT/StringMap.h" #include "llvm/ADT/TypeSwitch.h" #include "llvm/Support/raw_ostream.h" using namespace mlir; using namespace mlir::spirv; #include "mlir/Dialect/SPIRV/IR/SPIRVOpsDialect.cpp.inc" //===----------------------------------------------------------------------===// // InlinerInterface //===----------------------------------------------------------------------===// /// Returns true if the given region contains spirv.Return or spirv.ReturnValue /// ops. static inline bool containsReturn(Region ®ion) { return llvm::any_of(region, [](Block &block) { Operation *terminator = block.getTerminator(); return isa(terminator); }); } namespace { /// This class defines the interface for inlining within the SPIR-V dialect. struct SPIRVInlinerInterface : public DialectInlinerInterface { using DialectInlinerInterface::DialectInlinerInterface; /// All call operations within SPIRV can be inlined. bool isLegalToInline(Operation *call, Operation *callable, bool wouldBeCloned) const final { return true; } /// Returns true if the given region 'src' can be inlined into the region /// 'dest' that is attached to an operation registered to the current dialect. bool isLegalToInline(Region *dest, Region *src, bool wouldBeCloned, IRMapping &) const final { // Return true here when inlining into spirv.func, spirv.mlir.selection, and // spirv.mlir.loop operations. auto *op = dest->getParentOp(); return isa(op); } /// Returns true if the given operation 'op', that is registered to this /// dialect, can be inlined into the region 'dest' that is attached to an /// operation registered to the current dialect. bool isLegalToInline(Operation *op, Region *dest, bool wouldBeCloned, IRMapping &) const final { // TODO: Enable inlining structured control flows with return. if ((isa(op)) && containsReturn(op->getRegion(0))) return false; // TODO: we need to filter OpKill here to avoid inlining it to // a loop continue construct: // https://github.com/KhronosGroup/SPIRV-Headers/issues/86 // However OpKill is fragment shader specific and we don't support it yet. return true; } /// Handle the given inlined terminator by replacing it with a new operation /// as necessary. void handleTerminator(Operation *op, Block *newDest) const final { if (auto returnOp = dyn_cast(op)) { OpBuilder(op).create(op->getLoc(), newDest); op->erase(); } else if (auto retValOp = dyn_cast(op)) { llvm_unreachable("unimplemented spirv.ReturnValue in inliner"); } } /// Handle the given inlined terminator by replacing it with a new operation /// as necessary. void handleTerminator(Operation *op, ValueRange valuesToRepl) const final { // Only spirv.ReturnValue needs to be handled here. auto retValOp = dyn_cast(op); if (!retValOp) return; // Replace the values directly with the return operands. assert(valuesToRepl.size() == 1 && "spirv.ReturnValue expected to only handle one result"); valuesToRepl.front().replaceAllUsesWith(retValOp.getValue()); } }; } // namespace //===----------------------------------------------------------------------===// // SPIR-V Dialect //===----------------------------------------------------------------------===// void SPIRVDialect::initialize() { registerAttributes(); registerTypes(); // Add SPIR-V ops. addOperations< #define GET_OP_LIST #include "mlir/Dialect/SPIRV/IR/SPIRVOps.cpp.inc" >(); addInterfaces(); // Allow unknown operations because SPIR-V is extensible. allowUnknownOperations(); declarePromisedInterface(); } std::string SPIRVDialect::getAttributeName(Decoration decoration) { return llvm::convertToSnakeFromCamelCase(stringifyDecoration(decoration)); } //===----------------------------------------------------------------------===// // Type Parsing //===----------------------------------------------------------------------===// // Forward declarations. template static std::optional parseAndVerify(SPIRVDialect const &dialect, DialectAsmParser &parser); template <> std::optional parseAndVerify(SPIRVDialect const &dialect, DialectAsmParser &parser); template <> std::optional parseAndVerify(SPIRVDialect const &dialect, DialectAsmParser &parser); static Type parseAndVerifyType(SPIRVDialect const &dialect, DialectAsmParser &parser) { Type type; SMLoc typeLoc = parser.getCurrentLocation(); if (parser.parseType(type)) return Type(); // Allow SPIR-V dialect types if (&type.getDialect() == &dialect) return type; // Check other allowed types if (auto t = llvm::dyn_cast(type)) { if (type.isBF16()) { parser.emitError(typeLoc, "cannot use 'bf16' to compose SPIR-V types"); return Type(); } } else if (auto t = llvm::dyn_cast(type)) { if (!ScalarType::isValid(t)) { parser.emitError(typeLoc, "only 1/8/16/32/64-bit integer type allowed but found ") << type; return Type(); } } else if (auto t = llvm::dyn_cast(type)) { if (t.getRank() != 1) { parser.emitError(typeLoc, "only 1-D vector allowed but found ") << t; return Type(); } if (t.getNumElements() > 4) { parser.emitError( typeLoc, "vector length has to be less than or equal to 4 but found ") << t.getNumElements(); return Type(); } } else { parser.emitError(typeLoc, "cannot use ") << type << " to compose SPIR-V types"; return Type(); } return type; } static Type parseAndVerifyMatrixType(SPIRVDialect const &dialect, DialectAsmParser &parser) { Type type; SMLoc typeLoc = parser.getCurrentLocation(); if (parser.parseType(type)) return Type(); if (auto t = llvm::dyn_cast(type)) { if (t.getRank() != 1) { parser.emitError(typeLoc, "only 1-D vector allowed but found ") << t; return Type(); } if (t.getNumElements() > 4 || t.getNumElements() < 2) { parser.emitError(typeLoc, "matrix columns size has to be less than or equal " "to 4 and greater than or equal 2, but found ") << t.getNumElements(); return Type(); } if (!llvm::isa(t.getElementType())) { parser.emitError(typeLoc, "matrix columns' elements must be of " "Float type, got ") << t.getElementType(); return Type(); } } else { parser.emitError(typeLoc, "matrix must be composed using vector " "type, got ") << type; return Type(); } return type; } static Type parseAndVerifySampledImageType(SPIRVDialect const &dialect, DialectAsmParser &parser) { Type type; SMLoc typeLoc = parser.getCurrentLocation(); if (parser.parseType(type)) return Type(); if (!llvm::isa(type)) { parser.emitError(typeLoc, "sampled image must be composed using image type, got ") << type; return Type(); } return type; } /// Parses an optional `, stride = N` assembly segment. If no parsing failure /// occurs, writes `N` to `stride` if existing and writes 0 to `stride` if /// missing. static LogicalResult parseOptionalArrayStride(const SPIRVDialect &dialect, DialectAsmParser &parser, unsigned &stride) { if (failed(parser.parseOptionalComma())) { stride = 0; return success(); } if (parser.parseKeyword("stride") || parser.parseEqual()) return failure(); SMLoc strideLoc = parser.getCurrentLocation(); std::optional optStride = parseAndVerify(dialect, parser); if (!optStride) return failure(); if (!(stride = *optStride)) { parser.emitError(strideLoc, "ArrayStride must be greater than zero"); return failure(); } return success(); } // element-type ::= integer-type // | floating-point-type // | vector-type // | spirv-type // // array-type ::= `!spirv.array` `<` integer-literal `x` element-type // (`,` `stride` `=` integer-literal)? `>` static Type parseArrayType(SPIRVDialect const &dialect, DialectAsmParser &parser) { if (parser.parseLess()) return Type(); SmallVector countDims; SMLoc countLoc = parser.getCurrentLocation(); if (parser.parseDimensionList(countDims, /*allowDynamic=*/false)) return Type(); if (countDims.size() != 1) { parser.emitError(countLoc, "expected single integer for array element count"); return Type(); } // According to the SPIR-V spec: // "Length is the number of elements in the array. It must be at least 1." int64_t count = countDims[0]; if (count == 0) { parser.emitError(countLoc, "expected array length greater than 0"); return Type(); } Type elementType = parseAndVerifyType(dialect, parser); if (!elementType) return Type(); unsigned stride = 0; if (failed(parseOptionalArrayStride(dialect, parser, stride))) return Type(); if (parser.parseGreater()) return Type(); return ArrayType::get(elementType, count, stride); } // cooperative-matrix-type ::= // `!spirv.coopmatrix` `<` rows `x` columns `x` element-type `,` // scope `,` use `>` static Type parseCooperativeMatrixType(SPIRVDialect const &dialect, DialectAsmParser &parser) { if (parser.parseLess()) return {}; SmallVector dims; SMLoc countLoc = parser.getCurrentLocation(); if (parser.parseDimensionList(dims, /*allowDynamic=*/false)) return {}; if (dims.size() != 2) { parser.emitError(countLoc, "expected row and column count"); return {}; } auto elementTy = parseAndVerifyType(dialect, parser); if (!elementTy) return {}; Scope scope; if (parser.parseComma() || spirv::parseEnumKeywordAttr(scope, parser, "scope ")) return {}; CooperativeMatrixUseKHR use; if (parser.parseComma() || spirv::parseEnumKeywordAttr(use, parser, "use ")) return {}; if (parser.parseGreater()) return {}; return CooperativeMatrixType::get(elementTy, dims[0], dims[1], scope, use); } // joint-matrix-type ::= `!spirv.jointmatrix` `<`rows `x` columns `x` // element-type // `,` layout `,` scope`>` static Type parseJointMatrixType(SPIRVDialect const &dialect, DialectAsmParser &parser) { if (parser.parseLess()) return Type(); SmallVector dims; SMLoc countLoc = parser.getCurrentLocation(); if (parser.parseDimensionList(dims, /*allowDynamic=*/false)) return Type(); if (dims.size() != 2) { parser.emitError(countLoc, "expected rows and columns size"); return Type(); } auto elementTy = parseAndVerifyType(dialect, parser); if (!elementTy) return Type(); MatrixLayout matrixLayout; if (parser.parseComma() || spirv::parseEnumKeywordAttr(matrixLayout, parser, "matrixLayout ")) return Type(); Scope scope; if (parser.parseComma() || spirv::parseEnumKeywordAttr(scope, parser, "scope ")) return Type(); if (parser.parseGreater()) return Type(); return JointMatrixINTELType::get(elementTy, scope, dims[0], dims[1], matrixLayout); } // TODO: Reorder methods to be utilities first and parse*Type // methods in alphabetical order // // storage-class ::= `UniformConstant` // | `Uniform` // | `Workgroup` // | // // pointer-type ::= `!spirv.ptr<` element-type `,` storage-class `>` static Type parsePointerType(SPIRVDialect const &dialect, DialectAsmParser &parser) { if (parser.parseLess()) return Type(); auto pointeeType = parseAndVerifyType(dialect, parser); if (!pointeeType) return Type(); StringRef storageClassSpec; SMLoc storageClassLoc = parser.getCurrentLocation(); if (parser.parseComma() || parser.parseKeyword(&storageClassSpec)) return Type(); auto storageClass = symbolizeStorageClass(storageClassSpec); if (!storageClass) { parser.emitError(storageClassLoc, "unknown storage class: ") << storageClassSpec; return Type(); } if (parser.parseGreater()) return Type(); return PointerType::get(pointeeType, *storageClass); } // runtime-array-type ::= `!spirv.rtarray` `<` element-type // (`,` `stride` `=` integer-literal)? `>` static Type parseRuntimeArrayType(SPIRVDialect const &dialect, DialectAsmParser &parser) { if (parser.parseLess()) return Type(); Type elementType = parseAndVerifyType(dialect, parser); if (!elementType) return Type(); unsigned stride = 0; if (failed(parseOptionalArrayStride(dialect, parser, stride))) return Type(); if (parser.parseGreater()) return Type(); return RuntimeArrayType::get(elementType, stride); } // matrix-type ::= `!spirv.matrix` `<` integer-literal `x` element-type `>` static Type parseMatrixType(SPIRVDialect const &dialect, DialectAsmParser &parser) { if (parser.parseLess()) return Type(); SmallVector countDims; SMLoc countLoc = parser.getCurrentLocation(); if (parser.parseDimensionList(countDims, /*allowDynamic=*/false)) return Type(); if (countDims.size() != 1) { parser.emitError(countLoc, "expected single unsigned " "integer for number of columns"); return Type(); } int64_t columnCount = countDims[0]; // According to the specification, Matrices can have 2, 3, or 4 columns if (columnCount < 2 || columnCount > 4) { parser.emitError(countLoc, "matrix is expected to have 2, 3, or 4 " "columns"); return Type(); } Type columnType = parseAndVerifyMatrixType(dialect, parser); if (!columnType) return Type(); if (parser.parseGreater()) return Type(); return MatrixType::get(columnType, columnCount); } // Specialize this function to parse each of the parameters that define an // ImageType. By default it assumes this is an enum type. template static std::optional parseAndVerify(SPIRVDialect const &dialect, DialectAsmParser &parser) { StringRef enumSpec; SMLoc enumLoc = parser.getCurrentLocation(); if (parser.parseKeyword(&enumSpec)) { return std::nullopt; } auto val = spirv::symbolizeEnum(enumSpec); if (!val) parser.emitError(enumLoc, "unknown attribute: '") << enumSpec << "'"; return val; } template <> std::optional parseAndVerify(SPIRVDialect const &dialect, DialectAsmParser &parser) { // TODO: Further verify that the element type can be sampled auto ty = parseAndVerifyType(dialect, parser); if (!ty) return std::nullopt; return ty; } template static std::optional parseAndVerifyInteger(SPIRVDialect const &dialect, DialectAsmParser &parser) { IntTy offsetVal = std::numeric_limits::max(); if (parser.parseInteger(offsetVal)) return std::nullopt; return offsetVal; } template <> std::optional parseAndVerify(SPIRVDialect const &dialect, DialectAsmParser &parser) { return parseAndVerifyInteger(dialect, parser); } namespace { // Functor object to parse a comma separated list of specs. The function // parseAndVerify does the actual parsing and verification of individual // elements. This is a functor since parsing the last element of the list // (termination condition) needs partial specialization. template struct ParseCommaSeparatedList { std::optional> operator()(SPIRVDialect const &dialect, DialectAsmParser &parser) const { auto parseVal = parseAndVerify(dialect, parser); if (!parseVal) return std::nullopt; auto numArgs = std::tuple_size>::value; if (numArgs != 0 && failed(parser.parseComma())) return std::nullopt; auto remainingValues = ParseCommaSeparatedList{}(dialect, parser); if (!remainingValues) return std::nullopt; return std::tuple_cat(std::tuple(parseVal.value()), remainingValues.value()); } }; // Partial specialization of the function to parse a comma separated list of // specs to parse the last element of the list. template struct ParseCommaSeparatedList { std::optional> operator()(SPIRVDialect const &dialect, DialectAsmParser &parser) const { if (auto value = parseAndVerify(dialect, parser)) return std::tuple(*value); return std::nullopt; } }; } // namespace // dim ::= `1D` | `2D` | `3D` | `Cube` | // // depth-info ::= `NoDepth` | `IsDepth` | `DepthUnknown` // // arrayed-info ::= `NonArrayed` | `Arrayed` // // sampling-info ::= `SingleSampled` | `MultiSampled` // // sampler-use-info ::= `SamplerUnknown` | `NeedSampler` | `NoSampler` // // format ::= `Unknown` | `Rgba32f` | // // image-type ::= `!spirv.image<` element-type `,` dim `,` depth-info `,` // arrayed-info `,` sampling-info `,` // sampler-use-info `,` format `>` static Type parseImageType(SPIRVDialect const &dialect, DialectAsmParser &parser) { if (parser.parseLess()) return Type(); auto value = ParseCommaSeparatedList{}(dialect, parser); if (!value) return Type(); if (parser.parseGreater()) return Type(); return ImageType::get(*value); } // sampledImage-type :: = `!spirv.sampledImage<` image-type `>` static Type parseSampledImageType(SPIRVDialect const &dialect, DialectAsmParser &parser) { if (parser.parseLess()) return Type(); Type parsedType = parseAndVerifySampledImageType(dialect, parser); if (!parsedType) return Type(); if (parser.parseGreater()) return Type(); return SampledImageType::get(parsedType); } // Parse decorations associated with a member. static ParseResult parseStructMemberDecorations( SPIRVDialect const &dialect, DialectAsmParser &parser, ArrayRef memberTypes, SmallVectorImpl &offsetInfo, SmallVectorImpl &memberDecorationInfo) { // Check if the first element is offset. SMLoc offsetLoc = parser.getCurrentLocation(); StructType::OffsetInfo offset = 0; OptionalParseResult offsetParseResult = parser.parseOptionalInteger(offset); if (offsetParseResult.has_value()) { if (failed(*offsetParseResult)) return failure(); if (offsetInfo.size() != memberTypes.size() - 1) { return parser.emitError(offsetLoc, "offset specification must be given for " "all members"); } offsetInfo.push_back(offset); } // Check for no spirv::Decorations. if (succeeded(parser.parseOptionalRSquare())) return success(); // If there was an offset, make sure to parse the comma. if (offsetParseResult.has_value() && parser.parseComma()) return failure(); // Check for spirv::Decorations. auto parseDecorations = [&]() { auto memberDecoration = parseAndVerify(dialect, parser); if (!memberDecoration) return failure(); // Parse member decoration value if it exists. if (succeeded(parser.parseOptionalEqual())) { auto memberDecorationValue = parseAndVerifyInteger(dialect, parser); if (!memberDecorationValue) return failure(); memberDecorationInfo.emplace_back( static_cast(memberTypes.size() - 1), 1, memberDecoration.value(), memberDecorationValue.value()); } else { memberDecorationInfo.emplace_back( static_cast(memberTypes.size() - 1), 0, memberDecoration.value(), 0); } return success(); }; if (failed(parser.parseCommaSeparatedList(parseDecorations)) || failed(parser.parseRSquare())) return failure(); return success(); } // struct-member-decoration ::= integer-literal? spirv-decoration* // struct-type ::= // `!spirv.struct<` (id `,`)? // `(` // (spirv-type (`[` struct-member-decoration `]`)?)* // `)>` static Type parseStructType(SPIRVDialect const &dialect, DialectAsmParser &parser) { // TODO: This function is quite lengthy. Break it down into smaller chunks. if (parser.parseLess()) return Type(); StringRef identifier; FailureOr cyclicParse; // Check if this is an identified struct type. if (succeeded(parser.parseOptionalKeyword(&identifier))) { // Check if this is a possible recursive reference. auto structType = StructType::getIdentified(dialect.getContext(), identifier); cyclicParse = parser.tryStartCyclicParse(structType); if (succeeded(parser.parseOptionalGreater())) { if (succeeded(cyclicParse)) { parser.emitError( parser.getNameLoc(), "recursive struct reference not nested in struct definition"); return Type(); } return structType; } if (failed(parser.parseComma())) return Type(); if (failed(cyclicParse)) { parser.emitError(parser.getNameLoc(), "identifier already used for an enclosing struct"); return Type(); } } if (failed(parser.parseLParen())) return Type(); if (succeeded(parser.parseOptionalRParen()) && succeeded(parser.parseOptionalGreater())) { return StructType::getEmpty(dialect.getContext(), identifier); } StructType idStructTy; if (!identifier.empty()) idStructTy = StructType::getIdentified(dialect.getContext(), identifier); SmallVector memberTypes; SmallVector offsetInfo; SmallVector memberDecorationInfo; do { Type memberType; if (parser.parseType(memberType)) return Type(); memberTypes.push_back(memberType); if (succeeded(parser.parseOptionalLSquare())) if (parseStructMemberDecorations(dialect, parser, memberTypes, offsetInfo, memberDecorationInfo)) return Type(); } while (succeeded(parser.parseOptionalComma())); if (!offsetInfo.empty() && memberTypes.size() != offsetInfo.size()) { parser.emitError(parser.getNameLoc(), "offset specification must be given for all members"); return Type(); } if (failed(parser.parseRParen()) || failed(parser.parseGreater())) return Type(); if (!identifier.empty()) { if (failed(idStructTy.trySetBody(memberTypes, offsetInfo, memberDecorationInfo))) return Type(); return idStructTy; } return StructType::get(memberTypes, offsetInfo, memberDecorationInfo); } // spirv-type ::= array-type // | element-type // | image-type // | pointer-type // | runtime-array-type // | sampled-image-type // | struct-type Type SPIRVDialect::parseType(DialectAsmParser &parser) const { StringRef keyword; if (parser.parseKeyword(&keyword)) return Type(); if (keyword == "array") return parseArrayType(*this, parser); if (keyword == "coopmatrix") return parseCooperativeMatrixType(*this, parser); if (keyword == "jointmatrix") return parseJointMatrixType(*this, parser); if (keyword == "image") return parseImageType(*this, parser); if (keyword == "ptr") return parsePointerType(*this, parser); if (keyword == "rtarray") return parseRuntimeArrayType(*this, parser); if (keyword == "sampled_image") return parseSampledImageType(*this, parser); if (keyword == "struct") return parseStructType(*this, parser); if (keyword == "matrix") return parseMatrixType(*this, parser); parser.emitError(parser.getNameLoc(), "unknown SPIR-V type: ") << keyword; return Type(); } //===----------------------------------------------------------------------===// // Type Printing //===----------------------------------------------------------------------===// static void print(ArrayType type, DialectAsmPrinter &os) { os << "array<" << type.getNumElements() << " x " << type.getElementType(); if (unsigned stride = type.getArrayStride()) os << ", stride=" << stride; os << ">"; } static void print(RuntimeArrayType type, DialectAsmPrinter &os) { os << "rtarray<" << type.getElementType(); if (unsigned stride = type.getArrayStride()) os << ", stride=" << stride; os << ">"; } static void print(PointerType type, DialectAsmPrinter &os) { os << "ptr<" << type.getPointeeType() << ", " << stringifyStorageClass(type.getStorageClass()) << ">"; } static void print(ImageType type, DialectAsmPrinter &os) { os << "image<" << type.getElementType() << ", " << stringifyDim(type.getDim()) << ", " << stringifyImageDepthInfo(type.getDepthInfo()) << ", " << stringifyImageArrayedInfo(type.getArrayedInfo()) << ", " << stringifyImageSamplingInfo(type.getSamplingInfo()) << ", " << stringifyImageSamplerUseInfo(type.getSamplerUseInfo()) << ", " << stringifyImageFormat(type.getImageFormat()) << ">"; } static void print(SampledImageType type, DialectAsmPrinter &os) { os << "sampled_image<" << type.getImageType() << ">"; } static void print(StructType type, DialectAsmPrinter &os) { FailureOr cyclicPrint; os << "struct<"; if (type.isIdentified()) { os << type.getIdentifier(); cyclicPrint = os.tryStartCyclicPrint(type); if (failed(cyclicPrint)) { os << ">"; return; } os << ", "; } os << "("; auto printMember = [&](unsigned i) { os << type.getElementType(i); SmallVector decorations; type.getMemberDecorations(i, decorations); if (type.hasOffset() || !decorations.empty()) { os << " ["; if (type.hasOffset()) { os << type.getMemberOffset(i); if (!decorations.empty()) os << ", "; } auto eachFn = [&os](spirv::StructType::MemberDecorationInfo decoration) { os << stringifyDecoration(decoration.decoration); if (decoration.hasValue) { os << "=" << decoration.decorationValue; } }; llvm::interleaveComma(decorations, os, eachFn); os << "]"; } }; llvm::interleaveComma(llvm::seq(0, type.getNumElements()), os, printMember); os << ")>"; } static void print(CooperativeMatrixType type, DialectAsmPrinter &os) { os << "coopmatrix<" << type.getRows() << "x" << type.getColumns() << "x" << type.getElementType() << ", " << type.getScope() << ", " << type.getUse() << ">"; } static void print(JointMatrixINTELType type, DialectAsmPrinter &os) { os << "jointmatrix<" << type.getRows() << "x" << type.getColumns() << "x"; os << type.getElementType() << ", " << stringifyMatrixLayout(type.getMatrixLayout()); os << ", " << stringifyScope(type.getScope()) << ">"; } static void print(MatrixType type, DialectAsmPrinter &os) { os << "matrix<" << type.getNumColumns() << " x " << type.getColumnType(); os << ">"; } void SPIRVDialect::printType(Type type, DialectAsmPrinter &os) const { TypeSwitch(type) .Case([&](auto type) { print(type, os); }) .Default([](Type) { llvm_unreachable("unhandled SPIR-V type"); }); } //===----------------------------------------------------------------------===// // Constant //===----------------------------------------------------------------------===// Operation *SPIRVDialect::materializeConstant(OpBuilder &builder, Attribute value, Type type, Location loc) { if (auto poison = dyn_cast(value)) return builder.create(loc, type, poison); if (!spirv::ConstantOp::isBuildableWith(type)) return nullptr; return builder.create(loc, type, value); } //===----------------------------------------------------------------------===// // Shader Interface ABI //===----------------------------------------------------------------------===// LogicalResult SPIRVDialect::verifyOperationAttribute(Operation *op, NamedAttribute attribute) { StringRef symbol = attribute.getName().strref(); Attribute attr = attribute.getValue(); if (symbol == spirv::getEntryPointABIAttrName()) { if (!llvm::isa(attr)) { return op->emitError("'") << symbol << "' attribute must be an entry point ABI attribute"; } } else if (symbol == spirv::getTargetEnvAttrName()) { if (!llvm::isa(attr)) return op->emitError("'") << symbol << "' must be a spirv::TargetEnvAttr"; } else { return op->emitError("found unsupported '") << symbol << "' attribute on operation"; } return success(); } /// Verifies the given SPIR-V `attribute` attached to a value of the given /// `valueType` is valid. static LogicalResult verifyRegionAttribute(Location loc, Type valueType, NamedAttribute attribute) { StringRef symbol = attribute.getName().strref(); Attribute attr = attribute.getValue(); if (symbol == spirv::getInterfaceVarABIAttrName()) { auto varABIAttr = llvm::dyn_cast(attr); if (!varABIAttr) return emitError(loc, "'") << symbol << "' must be a spirv::InterfaceVarABIAttr"; if (varABIAttr.getStorageClass() && !valueType.isIntOrIndexOrFloat()) return emitError(loc, "'") << symbol << "' attribute cannot specify storage class " "when attaching to a non-scalar value"; return success(); } if (symbol == spirv::DecorationAttr::name) { if (!isa(attr)) return emitError(loc, "'") << symbol << "' must be a spirv::DecorationAttr"; return success(); } return emitError(loc, "found unsupported '") << symbol << "' attribute on region argument"; } LogicalResult SPIRVDialect::verifyRegionArgAttribute(Operation *op, unsigned regionIndex, unsigned argIndex, NamedAttribute attribute) { auto funcOp = dyn_cast(op); if (!funcOp) return success(); Type argType = funcOp.getArgumentTypes()[argIndex]; return verifyRegionAttribute(op->getLoc(), argType, attribute); } LogicalResult SPIRVDialect::verifyRegionResultAttribute( Operation *op, unsigned /*regionIndex*/, unsigned /*resultIndex*/, NamedAttribute attribute) { return op->emitError("cannot attach SPIR-V attributes to region result"); }