src/tint/lang/spirv/writer/writer.h - dawn - Git at Google

 // Copyright 2023 The Tint Authors.
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //     http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.

 #ifndef SRC_TINT_LANG_SPIRV_WRITER_WRITER_H_
 #define SRC_TINT_LANG_SPIRV_WRITER_WRITER_H_

 #include <vector>

 #include "src/tint/ir/constant.h"
 #include "src/tint/lang/core/builtin/address_space.h"
 #include "src/tint/lang/core/builtin/builtin_value.h"
 #include "src/tint/lang/core/builtin/texel_format.h"
 #include "src/tint/lang/core/constant/value.h"
 #include "src/tint/lang/spirv/ast_writer/binary_writer.h"
 #include "src/tint/lang/spirv/ast_writer/function.h"
 #include "src/tint/lang/spirv/ast_writer/module.h"
 #include "src/tint/utils/containers/hashmap.h"
 #include "src/tint/utils/containers/vector.h"
 #include "src/tint/utils/diagnostic/diagnostic.h"
 #include "src/tint/utils/text/symbol.h"

 // Forward declarations
 namespace tint::ir {
 class Access;
 class Binary;
 class Bitcast;
 class Block;
 class BlockParam;
 class Construct;
 class ControlInstruction;
 class Convert;
 class CoreBuiltinCall;
 class ExitIf;
 class ExitLoop;
 class ExitSwitch;
 class Function;
 class If;
 class IntrinsicCall;
 class Let;
 class Load;
 class LoadVectorElement;
 class Loop;
 class Module;
 class MultiInBlock;
 class Store;
 class StoreVectorElement;
 class Switch;
 class Swizzle;
 class Terminator;
 class Unary;
 class UserCall;
 class Value;
 class Var;
 }  // namespace tint::ir
 namespace tint::type {
 class Struct;
 class Texture;
 class Type;
 }  // namespace tint::type

 namespace tint::writer::spirv {

 /// Implementation class for SPIR-V generator
 class GeneratorImplIr {
   public:
     /// Constructor
     /// @param module the Tint IR module to generate
     /// @param zero_init_workgroup_memory `true` to initialize all the variables in the Workgroup
     ///                                   storage class with OpConstantNull
     GeneratorImplIr(ir::Module* module, bool zero_init_workgroup_memory);

     /// @returns true on successful generation; false otherwise
     bool Generate();

     /// @returns the module that this generator has produced
     spirv::Module& Module() { return module_; }

     /// @returns the generated SPIR-V binary data
     const std::vector<uint32_t>& Result() const { return writer_.Result(); }

     /// @returns the list of diagnostics raised by the generator
     diag::List Diagnostics() const { return diagnostics_; }

     /// Get the result ID of the constant `constant`, emitting its instruction if necessary.
     /// @param constant the constant to get the ID for
     /// @returns the result ID of the constant
     uint32_t Constant(ir::Constant* constant);

     /// Get the result ID of the type `ty`, emitting a type declaration instruction if necessary.
     /// @param ty the type to get the ID for
     /// @param addrspace the optional address space that this type is being used for
     /// @returns the result ID of the type
     uint32_t Type(const type::Type* ty,
                   builtin::AddressSpace addrspace = builtin::AddressSpace::kUndefined);

   private:
     /// Convert a builtin to the corresponding SPIR-V enum value, taking into account the target
     /// address space. Adds any capabilities needed for the builtin.
     /// @param builtin the builtin to convert
     /// @param addrspace the address space the builtin is being used in
     /// @returns the enum value of the corresponding SPIR-V builtin
     uint32_t Builtin(builtin::BuiltinValue builtin, builtin::AddressSpace addrspace);

     /// Convert a texel format to the corresponding SPIR-V enum value, adding required capabilities.
     /// @param format the format to convert
     /// @returns the enum value of the corresponding SPIR-V texel format
     uint32_t TexelFormat(const builtin::TexelFormat format);

     /// Get the result ID of the constant `constant`, emitting its instruction if necessary.
     /// @param constant the constant to get the ID for
     /// @returns the result ID of the constant
     uint32_t Constant(const constant::Value* constant);

     /// Get the result ID of the OpConstantNull instruction for `type`, emitting it if necessary.
     /// @param type the type to get the ID for
     /// @returns the result ID of the OpConstantNull instruction
     uint32_t ConstantNull(const type::Type* type);

     /// Get the ID of the label for `block`.
     /// @param block the block to get the label ID for
     /// @returns the ID of the block's label
     uint32_t Label(ir::Block* block);

     /// Get the result ID of the value `value`, emitting its instruction if necessary.
     /// @param value the value to get the ID for
     /// @returns the result ID of the value
     uint32_t Value(ir::Value* value);

     /// Get the result ID of the instruction result `value`, emitting its instruction if necessary.
     /// @param inst the instruction to get the ID for
     /// @returns the result ID of the instruction
     uint32_t Value(ir::Instruction* inst);

     /// Get the result ID of the OpUndef instruction with type `ty`, emitting it if necessary.
     /// @param ty the type of the undef value
     /// @returns the result ID of the instruction
     uint32_t Undef(const type::Type* ty);

     /// Emit a struct type.
     /// @param id the result ID to use
     /// @param addrspace the optional address space that this type is being used for
     /// @param str the struct type to emit
     void EmitStructType(uint32_t id,
                         const type::Struct* str,
                         builtin::AddressSpace addrspace = builtin::AddressSpace::kUndefined);

     /// Emit a texture type.
     /// @param id the result ID to use
     /// @param texture the texture type to emit
     void EmitTextureType(uint32_t id, const type::Texture* texture);

     /// Emit a function.
     /// @param func the function to emit
     void EmitFunction(ir::Function* func);

     /// Emit entry point declarations for a function.
     /// @param func the function to emit entry point declarations for
     /// @param id the result ID of the function declaration
     void EmitEntryPoint(ir::Function* func, uint32_t id);

     /// Emit a block, including the initial OpLabel, OpPhis and instructions.
     /// @param block the block to emit
     void EmitBlock(ir::Block* block);

     /// Emit all OpPhi nodes for incoming branches to @p block.
     /// @param block the block to emit the OpPhis for
     void EmitIncomingPhis(ir::MultiInBlock* block);

     /// Emit all instructions of @p block.
     /// @param block the block's instructions to emit
     void EmitBlockInstructions(ir::Block* block);

     /// Emit the root block.
     /// @param root_block the root block to emit
     void EmitRootBlock(ir::Block* root_block);

     /// Emit an `if` flow node.
     /// @param i the if node to emit
     void EmitIf(ir::If* i);

     /// Emit an access instruction
     /// @param access the access instruction to emit
     void EmitAccess(ir::Access* access);

     /// Emit a binary instruction.
     /// @param binary the binary instruction to emit
     void EmitBinary(ir::Binary* binary);

     /// Emit a bitcast instruction.
     /// @param bitcast the bitcast instruction to emit
     void EmitBitcast(ir::Bitcast* bitcast);

     /// Emit a builtin function call instruction.
     /// @param call the builtin call instruction to emit
     void EmitCoreBuiltinCall(ir::CoreBuiltinCall* call);

     /// Emit a construct instruction.
     /// @param construct the construct instruction to emit
     void EmitConstruct(ir::Construct* construct);

     /// Emit a convert instruction.
     /// @param convert the convert instruction to emit
     void EmitConvert(ir::Convert* convert);

     /// Emit an intrinsic call instruction.
     /// @param call the intrinsic call instruction to emit
     void EmitIntrinsicCall(ir::IntrinsicCall* call);

     /// Emit a load instruction.
     /// @param load the load instruction to emit
     void EmitLoad(ir::Load* load);

     /// Emit a load vector element instruction.
     /// @param load the load vector element instruction to emit
     void EmitLoadVectorElement(ir::LoadVectorElement* load);

     /// Emit a loop instruction.
     /// @param loop the loop instruction to emit
     void EmitLoop(ir::Loop* loop);

     /// Emit a store instruction.
     /// @param store the store instruction to emit
     void EmitStore(ir::Store* store);

     /// Emit a store vector element instruction.
     /// @param store the store vector element instruction to emit
     void EmitStoreVectorElement(ir::StoreVectorElement* store);

     /// Emit a switch instruction.
     /// @param swtch the switch instruction to emit
     void EmitSwitch(ir::Switch* swtch);

     /// Emit a swizzle instruction.
     /// @param swizzle the swizzle instruction to emit
     void EmitSwizzle(ir::Swizzle* swizzle);

     /// Emit a unary instruction.
     /// @param unary the unary instruction to emit
     void EmitUnary(ir::Unary* unary);

     /// Emit a user call instruction.
     /// @param call the user call instruction to emit
     void EmitUserCall(ir::UserCall* call);

     /// Emit a var instruction.
     /// @param var the var instruction to emit
     void EmitVar(ir::Var* var);

     /// Emit a let instruction.
     /// @param let the let instruction to emit
     void EmitLet(ir::Let* let);

     /// Emit a terminator instruction.
     /// @param term the terminator instruction to emit
     void EmitTerminator(ir::Terminator* term);

     /// Emit the OpPhis for the given flow control instruction.
     /// @param inst the flow control instruction
     void EmitExitPhis(ir::ControlInstruction* inst);

     ir::Module* ir_;
     spirv::Module module_;
     BinaryWriter writer_;
     diag::List diagnostics_;

     /// A function type used for an OpTypeFunction declaration.
     struct FunctionType {
         uint32_t return_type_id;
         utils::Vector<uint32_t, 4> param_type_ids;

         /// Hasher provides a hash function for the FunctionType.
         struct Hasher {
             /// @param ft the FunctionType to create a hash for
             /// @return the hash value
             inline std::size_t operator()(const FunctionType& ft) const {
                 size_t hash = utils::Hash(ft.return_type_id);
                 for (auto& p : ft.param_type_ids) {
                     hash = utils::HashCombine(hash, p);
                 }
                 return hash;
             }
         };

         /// Equality operator for FunctionType.
         bool operator==(const FunctionType& other) const {
             return (param_type_ids == other.param_type_ids) &&
                    (return_type_id == other.return_type_id);
         }
     };

     /// The map of types to their result IDs.
     utils::Hashmap<const type::Type*, uint32_t, 8> types_;

     /// The map of function types to their result IDs.
     utils::Hashmap<FunctionType, uint32_t, 8, FunctionType::Hasher> function_types_;

     /// The map of constants to their result IDs.
     utils::Hashmap<const constant::Value*, uint32_t, 16> constants_;

     /// The map of types to the result IDs of their OpConstantNull instructions.
     utils::Hashmap<const type::Type*, uint32_t, 4> constant_nulls_;

     /// The map of types to the result IDs of their OpUndef instructions.
     utils::Hashmap<const type::Type*, uint32_t, 4> undef_values_;

     /// The map of non-constant values to their result IDs.
     utils::Hashmap<ir::Value*, uint32_t, 8> values_;

     /// The map of blocks to the IDs of their label instructions.
     utils::Hashmap<ir::Block*, uint32_t, 8> block_labels_;

     /// The map of extended instruction set names to their result IDs.
     utils::Hashmap<std::string_view, uint32_t, 2> imports_;

     /// The current function that is being emitted.
     Function current_function_;

     /// The merge block for the current if statement
     uint32_t if_merge_label_ = 0;

     /// The header block for the current loop statement
     uint32_t loop_header_label_ = 0;

     /// The merge block for the current loop statement
     uint32_t loop_merge_label_ = 0;

     /// The merge block for the current switch statement
     uint32_t switch_merge_label_ = 0;

     bool zero_init_workgroup_memory_ = false;
 };

 }  // namespace tint::writer::spirv

 #endif  // SRC_TINT_LANG_SPIRV_WRITER_WRITER_H_
	// Copyright 2023 The Tint Authors.
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// http://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.

	#ifndef SRC_TINT_LANG_SPIRV_WRITER_WRITER_H_
	#define SRC_TINT_LANG_SPIRV_WRITER_WRITER_H_

	#include <vector>

	#include "src/tint/ir/constant.h"
	#include "src/tint/lang/core/builtin/address_space.h"
	#include "src/tint/lang/core/builtin/builtin_value.h"
	#include "src/tint/lang/core/builtin/texel_format.h"
	#include "src/tint/lang/core/constant/value.h"
	#include "src/tint/lang/spirv/ast_writer/binary_writer.h"
	#include "src/tint/lang/spirv/ast_writer/function.h"
	#include "src/tint/lang/spirv/ast_writer/module.h"
	#include "src/tint/utils/containers/hashmap.h"
	#include "src/tint/utils/containers/vector.h"
	#include "src/tint/utils/diagnostic/diagnostic.h"
	#include "src/tint/utils/text/symbol.h"

	// Forward declarations
	namespace tint::ir {
	class Access;
	class Binary;
	class Bitcast;
	class Block;
	class BlockParam;
	class Construct;
	class ControlInstruction;
	class Convert;
	class CoreBuiltinCall;
	class ExitIf;
	class ExitLoop;
	class ExitSwitch;
	class Function;
	class If;
	class IntrinsicCall;
	class Let;
	class Load;
	class LoadVectorElement;
	class Loop;
	class Module;
	class MultiInBlock;
	class Store;
	class StoreVectorElement;
	class Switch;
	class Swizzle;
	class Terminator;
	class Unary;
	class UserCall;
	class Value;
	class Var;
	} // namespace tint::ir
	namespace tint::type {
	class Struct;
	class Texture;
	class Type;
	} // namespace tint::type

	namespace tint::writer::spirv {

	/// Implementation class for SPIR-V generator
	class GeneratorImplIr {
	public:
	/// Constructor
	/// @param module the Tint IR module to generate
	/// @param zero_init_workgroup_memory `true` to initialize all the variables in the Workgroup
	/// storage class with OpConstantNull
	GeneratorImplIr(ir::Module* module, bool zero_init_workgroup_memory);

	/// @returns true on successful generation; false otherwise
	bool Generate();

	/// @returns the module that this generator has produced
	spirv::Module& Module() { return module_; }

	/// @returns the generated SPIR-V binary data
	const std::vector<uint32_t>& Result() const { return writer_.Result(); }

	/// @returns the list of diagnostics raised by the generator
	diag::List Diagnostics() const { return diagnostics_; }

	/// Get the result ID of the constant `constant`, emitting its instruction if necessary.
	/// @param constant the constant to get the ID for
	/// @returns the result ID of the constant
	uint32_t Constant(ir::Constant* constant);

	/// Get the result ID of the type `ty`, emitting a type declaration instruction if necessary.
	/// @param ty the type to get the ID for
	/// @param addrspace the optional address space that this type is being used for
	/// @returns the result ID of the type
	uint32_t Type(const type::Type* ty,
	builtin::AddressSpace addrspace = builtin::AddressSpace::kUndefined);

	private:
	/// Convert a builtin to the corresponding SPIR-V enum value, taking into account the target
	/// address space. Adds any capabilities needed for the builtin.
	/// @param builtin the builtin to convert
	/// @param addrspace the address space the builtin is being used in
	/// @returns the enum value of the corresponding SPIR-V builtin
	uint32_t Builtin(builtin::BuiltinValue builtin, builtin::AddressSpace addrspace);

	/// Convert a texel format to the corresponding SPIR-V enum value, adding required capabilities.
	/// @param format the format to convert
	/// @returns the enum value of the corresponding SPIR-V texel format
	uint32_t TexelFormat(const builtin::TexelFormat format);

	/// Get the result ID of the constant `constant`, emitting its instruction if necessary.
	/// @param constant the constant to get the ID for
	/// @returns the result ID of the constant
	uint32_t Constant(const constant::Value* constant);

	/// Get the result ID of the OpConstantNull instruction for `type`, emitting it if necessary.
	/// @param type the type to get the ID for
	/// @returns the result ID of the OpConstantNull instruction
	uint32_t ConstantNull(const type::Type* type);

	/// Get the ID of the label for `block`.
	/// @param block the block to get the label ID for
	/// @returns the ID of the block's label
	uint32_t Label(ir::Block* block);

	/// Get the result ID of the value `value`, emitting its instruction if necessary.
	/// @param value the value to get the ID for
	/// @returns the result ID of the value
	uint32_t Value(ir::Value* value);

	/// Get the result ID of the instruction result `value`, emitting its instruction if necessary.
	/// @param inst the instruction to get the ID for
	/// @returns the result ID of the instruction
	uint32_t Value(ir::Instruction* inst);

	/// Get the result ID of the OpUndef instruction with type `ty`, emitting it if necessary.
	/// @param ty the type of the undef value
	/// @returns the result ID of the instruction
	uint32_t Undef(const type::Type* ty);

	/// Emit a struct type.
	/// @param id the result ID to use
	/// @param addrspace the optional address space that this type is being used for
	/// @param str the struct type to emit
	void EmitStructType(uint32_t id,
	const type::Struct* str,
	builtin::AddressSpace addrspace = builtin::AddressSpace::kUndefined);

	/// Emit a texture type.
	/// @param id the result ID to use
	/// @param texture the texture type to emit
	void EmitTextureType(uint32_t id, const type::Texture* texture);

	/// Emit a function.
	/// @param func the function to emit
	void EmitFunction(ir::Function* func);

	/// Emit entry point declarations for a function.
	/// @param func the function to emit entry point declarations for
	/// @param id the result ID of the function declaration
	void EmitEntryPoint(ir::Function* func, uint32_t id);

	/// Emit a block, including the initial OpLabel, OpPhis and instructions.
	/// @param block the block to emit
	void EmitBlock(ir::Block* block);

	/// Emit all OpPhi nodes for incoming branches to @p block.
	/// @param block the block to emit the OpPhis for
	void EmitIncomingPhis(ir::MultiInBlock* block);

	/// Emit all instructions of @p block.
	/// @param block the block's instructions to emit
	void EmitBlockInstructions(ir::Block* block);

	/// Emit the root block.
	/// @param root_block the root block to emit
	void EmitRootBlock(ir::Block* root_block);

	/// Emit an `if` flow node.
	/// @param i the if node to emit
	void EmitIf(ir::If* i);

	/// Emit an access instruction
	/// @param access the access instruction to emit
	void EmitAccess(ir::Access* access);

	/// Emit a binary instruction.
	/// @param binary the binary instruction to emit
	void EmitBinary(ir::Binary* binary);

	/// Emit a bitcast instruction.
	/// @param bitcast the bitcast instruction to emit
	void EmitBitcast(ir::Bitcast* bitcast);

	/// Emit a builtin function call instruction.
	/// @param call the builtin call instruction to emit
	void EmitCoreBuiltinCall(ir::CoreBuiltinCall* call);

	/// Emit a construct instruction.
	/// @param construct the construct instruction to emit
	void EmitConstruct(ir::Construct* construct);

	/// Emit a convert instruction.
	/// @param convert the convert instruction to emit
	void EmitConvert(ir::Convert* convert);

	/// Emit an intrinsic call instruction.
	/// @param call the intrinsic call instruction to emit
	void EmitIntrinsicCall(ir::IntrinsicCall* call);

	/// Emit a load instruction.
	/// @param load the load instruction to emit
	void EmitLoad(ir::Load* load);

	/// Emit a load vector element instruction.
	/// @param load the load vector element instruction to emit
	void EmitLoadVectorElement(ir::LoadVectorElement* load);

	/// Emit a loop instruction.
	/// @param loop the loop instruction to emit
	void EmitLoop(ir::Loop* loop);

	/// Emit a store instruction.
	/// @param store the store instruction to emit
	void EmitStore(ir::Store* store);

	/// Emit a store vector element instruction.
	/// @param store the store vector element instruction to emit
	void EmitStoreVectorElement(ir::StoreVectorElement* store);

	/// Emit a switch instruction.
	/// @param swtch the switch instruction to emit
	void EmitSwitch(ir::Switch* swtch);

	/// Emit a swizzle instruction.
	/// @param swizzle the swizzle instruction to emit
	void EmitSwizzle(ir::Swizzle* swizzle);

	/// Emit a unary instruction.
	/// @param unary the unary instruction to emit
	void EmitUnary(ir::Unary* unary);

	/// Emit a user call instruction.
	/// @param call the user call instruction to emit
	void EmitUserCall(ir::UserCall* call);

	/// Emit a var instruction.
	/// @param var the var instruction to emit
	void EmitVar(ir::Var* var);

	/// Emit a let instruction.
	/// @param let the let instruction to emit
	void EmitLet(ir::Let* let);

	/// Emit a terminator instruction.
	/// @param term the terminator instruction to emit
	void EmitTerminator(ir::Terminator* term);

	/// Emit the OpPhis for the given flow control instruction.
	/// @param inst the flow control instruction
	void EmitExitPhis(ir::ControlInstruction* inst);

	ir::Module* ir_;
	spirv::Module module_;
	BinaryWriter writer_;
	diag::List diagnostics_;

	/// A function type used for an OpTypeFunction declaration.
	struct FunctionType {
	uint32_t return_type_id;
	utils::Vector<uint32_t, 4> param_type_ids;

	/// Hasher provides a hash function for the FunctionType.
	struct Hasher {
	/// @param ft the FunctionType to create a hash for
	/// @return the hash value
	inline std::size_t operator()(const FunctionType& ft) const {
	size_t hash = utils::Hash(ft.return_type_id);
	for (auto& p : ft.param_type_ids) {
	hash = utils::HashCombine(hash, p);
	}
	return hash;
	}
	};

	/// Equality operator for FunctionType.
	bool operator==(const FunctionType& other) const {
	return (param_type_ids == other.param_type_ids) &&
	(return_type_id == other.return_type_id);
	}
	};

	/// The map of types to their result IDs.
	utils::Hashmap<const type::Type*, uint32_t, 8> types_;

	/// The map of function types to their result IDs.
	utils::Hashmap<FunctionType, uint32_t, 8, FunctionType::Hasher> function_types_;

	/// The map of constants to their result IDs.
	utils::Hashmap<const constant::Value*, uint32_t, 16> constants_;

	/// The map of types to the result IDs of their OpConstantNull instructions.
	utils::Hashmap<const type::Type*, uint32_t, 4> constant_nulls_;

	/// The map of types to the result IDs of their OpUndef instructions.
	utils::Hashmap<const type::Type*, uint32_t, 4> undef_values_;

	/// The map of non-constant values to their result IDs.
	utils::Hashmap<ir::Value*, uint32_t, 8> values_;

	/// The map of blocks to the IDs of their label instructions.
	utils::Hashmap<ir::Block*, uint32_t, 8> block_labels_;

	/// The map of extended instruction set names to their result IDs.
	utils::Hashmap<std::string_view, uint32_t, 2> imports_;

	/// The current function that is being emitted.
	Function current_function_;

	/// The merge block for the current if statement
	uint32_t if_merge_label_ = 0;

	/// The header block for the current loop statement
	uint32_t loop_header_label_ = 0;

	/// The merge block for the current loop statement
	uint32_t loop_merge_label_ = 0;

	/// The merge block for the current switch statement
	uint32_t switch_merge_label_ = 0;

	bool zero_init_workgroup_memory_ = false;
	};

	} // namespace tint::writer::spirv

	#endif // SRC_TINT_LANG_SPIRV_WRITER_WRITER_H_