include/spirv-tools/optimizer.hpp - platform/external/shaderc/spirv-tools - Git at Google

 // Copyright (c) 2016 Google Inc.
 //
 // 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 SPIRV_TOOLS_OPTIMIZER_HPP_
 #define SPIRV_TOOLS_OPTIMIZER_HPP_

 #include <memory>
 #include <string>
 #include <unordered_map>
 #include <vector>

 #include "libspirv.hpp"

 namespace spvtools {

 // C++ interface for SPIR-V optimization functionalities. It wraps the context
 // (including target environment and the corresponding SPIR-V grammar) and
 // provides methods for registering optimization passes and optimizing.
 //
 // Instances of this class provides basic thread-safety guarantee.
 class Optimizer {
  public:
   // The token for an optimization pass. It is returned via one of the
   // Create*Pass() standalone functions at the end of this header file and
   // consumed by the RegisterPass() method. Tokens are one-time objects that
   // only support move; copying is not allowed.
   struct PassToken {
     struct Impl;  // Opaque struct for holding inernal data.

     PassToken(std::unique_ptr<Impl>);

     // Tokens can only be moved. Copying is disabled.
     PassToken(const PassToken&) = delete;
     PassToken(PassToken&&);
     PassToken& operator=(const PassToken&) = delete;
     PassToken& operator=(PassToken&&);

     ~PassToken();

     std::unique_ptr<Impl> impl_;  // Unique pointer to internal data.
   };

   // Constructs an instance with the given target |env|, which is used to decode
   // the binaries to be optimized later.
   //
   // The constructed instance will have an empty message consumer, which just
   // ignores all messages from the library. Use SetMessageConsumer() to supply
   // one if messages are of concern.
   explicit Optimizer(spv_target_env env);

   // Disables copy/move constructor/assignment operations.
   Optimizer(const Optimizer&) = delete;
   Optimizer(Optimizer&&) = delete;
   Optimizer& operator=(const Optimizer&) = delete;
   Optimizer& operator=(Optimizer&&) = delete;

   // Destructs this instance.
   ~Optimizer();

   // Sets the message consumer to the given |consumer|. The |consumer| will be
   // invoked once for each message communicated from the library.
   void SetMessageConsumer(MessageConsumer consumer);

   // Registers the given |pass| to this optimizer. Passes will be run in the
   // exact order of registration. The token passed in will be consumed by this
   // method.
   Optimizer& RegisterPass(PassToken&& pass);

   // Optimizes the given SPIR-V module |original_binary| and writes the
   // optimized binary into |optimized_binary|.
   // Returns true on successful optimization, whether or not the module is
   // modified. Returns false if errors occur when processing |original_binary|
   // using any of the registered passes. In that case, no further passes are
   // excuted and the contents in |optimized_binary| may be invalid.
   //
   // It's allowed to alias |original_binary| to the start of |optimized_binary|.
   bool Run(const uint32_t* original_binary, size_t original_binary_size,
            std::vector<uint32_t>* optimized_binary) const;

  private:
   struct Impl;                  // Opaque struct for holding internal data.
   std::unique_ptr<Impl> impl_;  // Unique pointer to internal data.
 };

 // Creates a null pass.
 // A null pass does nothing to the SPIR-V module to be optimized.
 Optimizer::PassToken CreateNullPass();

 // Creates a strip-debug-info pass.
 // A strip-debug-info pass removes all debug instructions (as documented in
 // Section 3.32.2 of the SPIR-V spec) of the SPIR-V module to be optimized.
 Optimizer::PassToken CreateStripDebugInfoPass();

 // Creates a set-spec-constant-default-value pass.
 // A set-spec-constant-default-value pass sets the default values for the
 // spec constants that have SpecId decorations (i.e., those defined by
 // OpSpecConstant{|True|False} instructions).
 Optimizer::PassToken CreateSetSpecConstantDefaultValuePass(
     const std::unordered_map<uint32_t, std::string>& id_value_map);

 // Creates a freeze-spec-constant-value pass.
 // A freeze-spec-constant pass specializes the value of spec constants to
 // their default values. This pass only processes the spec constants that have
 // SpecId decorations (defined by OpSpecConstant, OpSpecConstantTrue, or
 // OpSpecConstantFalse instructions) and replaces them with their normal
 // counterparts (OpConstant, OpConstantTrue, or OpConstantFalse). The
 // corresponding SpecId annotation instructions will also be removed. This
 // pass does not fold the newly added normal constants and does not process
 // other spec constants defined by OpSpecConstantComposite or
 // OpSpecConstantOp.
 Optimizer::PassToken CreateFreezeSpecConstantValuePass();

 // Creates a fold-spec-constant-op-and-composite pass.
 // A fold-spec-constant-op-and-composite pass folds spec constants defined by
 // OpSpecConstantOp or OpSpecConstantComposite instruction, to normal Constants
 // defined by OpConstantTrue, OpConstantFalse, OpConstant, OpConstantNull, or
 // OpConstantComposite instructions. Note that spec constants defined with
 // OpSpecConstant, OpSpecConstantTrue, or OpSpecConstantFalse instructions are
 // not handled, as these instructions indicate their value are not determined
 // and can be changed in future. A spec constant is foldable if all of its
 // value(s) can be determined from the module. E.g., an integer spec constant
 // defined with OpSpecConstantOp instruction can be folded if its value won't
 // change later. This pass will replace the original OpSpecContantOp instruction
 // with an OpConstant instruction. When folding composite spec constants,
 // new instructions may be inserted to define the components of the composite
 // constant first, then the original spec constants will be replaced by
 // OpConstantComposite instructions.
 //
 // There are some operations not supported yet:
 //   OpSConvert, OpFConvert, OpQuantizeToF16 and
 //   all the operations under Kernel capability.
 // TODO(qining): Add support for the operations listed above.
 Optimizer::PassToken CreateFoldSpecConstantOpAndCompositePass();

 // Creates a unify-constant pass.
 // A unify-constant pass de-duplicates the constants. Constants with the exact
 // same value and identical form will be unified and only one constant will
 // be kept for each unique pair of type and value.
 // There are several cases not handled by this pass:
 //  1) Constants defined by OpConstantNull instructions (null constants) and
 //  constants defined by OpConstantFalse, OpConstant or OpConstantComposite
 //  with value 0 (zero-valued normal constants) are not considered equivalent.
 //  So null constants won't be used to replace zero-valued normal constants,
 //  vice versa.
 //  2) Whenever there are decorations to the constant's result id id, the
 //  constant won't be handled, which means, it won't be used to replace any
 //  other constants, neither can other constants replace it.
 //  3) NaN in float point format with different bit patterns are not unified.
 Optimizer::PassToken CreateUnifyConstantPass();

 // Creates a eliminate-dead-constant pass.
 // A eliminate-dead-constant pass removes dead constants, including normal
 // contants defined by OpConstant, OpConstantComposite, OpConstantTrue, or
 // OpConstantFalse and spec constants defined by OpSpecConstant,
 // OpSpecConstantComposite, OpSpecConstantTrue, OpSpecConstantFalse or
 // OpSpecConstantOp.
 Optimizer::PassToken CreateEliminateDeadConstantPass();

 }  // namespace spvtools

 #endif  // SPIRV_TOOLS_OPTIMIZER_HPP_
	// Copyright (c) 2016 Google Inc.
	//
	// 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 SPIRV_TOOLS_OPTIMIZER_HPP_
	#define SPIRV_TOOLS_OPTIMIZER_HPP_

	#include <memory>
	#include <string>
	#include <unordered_map>
	#include <vector>

	#include "libspirv.hpp"

	namespace spvtools {

	// C++ interface for SPIR-V optimization functionalities. It wraps the context
	// (including target environment and the corresponding SPIR-V grammar) and
	// provides methods for registering optimization passes and optimizing.
	//
	// Instances of this class provides basic thread-safety guarantee.
	class Optimizer {
	public:
	// The token for an optimization pass. It is returned via one of the
	// Create*Pass() standalone functions at the end of this header file and
	// consumed by the RegisterPass() method. Tokens are one-time objects that
	// only support move; copying is not allowed.
	struct PassToken {
	struct Impl; // Opaque struct for holding inernal data.

	PassToken(std::unique_ptr<Impl>);

	// Tokens can only be moved. Copying is disabled.
	PassToken(const PassToken&) = delete;
	PassToken(PassToken&&);
	PassToken& operator=(const PassToken&) = delete;
	PassToken& operator=(PassToken&&);

	~PassToken();

	std::unique_ptr<Impl> impl_; // Unique pointer to internal data.
	};

	// Constructs an instance with the given target \|env\|, which is used to decode
	// the binaries to be optimized later.
	//
	// The constructed instance will have an empty message consumer, which just
	// ignores all messages from the library. Use SetMessageConsumer() to supply
	// one if messages are of concern.
	explicit Optimizer(spv_target_env env);

	// Disables copy/move constructor/assignment operations.
	Optimizer(const Optimizer&) = delete;
	Optimizer(Optimizer&&) = delete;
	Optimizer& operator=(const Optimizer&) = delete;
	Optimizer& operator=(Optimizer&&) = delete;

	// Destructs this instance.
	~Optimizer();

	// Sets the message consumer to the given \|consumer\|. The \|consumer\| will be
	// invoked once for each message communicated from the library.
	void SetMessageConsumer(MessageConsumer consumer);

	// Registers the given \|pass\| to this optimizer. Passes will be run in the
	// exact order of registration. The token passed in will be consumed by this
	// method.
	Optimizer& RegisterPass(PassToken&& pass);

	// Optimizes the given SPIR-V module \|original_binary\| and writes the
	// optimized binary into \|optimized_binary\|.
	// Returns true on successful optimization, whether or not the module is
	// modified. Returns false if errors occur when processing \|original_binary\|
	// using any of the registered passes. In that case, no further passes are
	// excuted and the contents in \|optimized_binary\| may be invalid.
	//
	// It's allowed to alias \|original_binary\| to the start of \|optimized_binary\|.
	bool Run(const uint32_t* original_binary, size_t original_binary_size,
	std::vector<uint32_t>* optimized_binary) const;

	private:
	struct Impl; // Opaque struct for holding internal data.
	std::unique_ptr<Impl> impl_; // Unique pointer to internal data.
	};

	// Creates a null pass.
	// A null pass does nothing to the SPIR-V module to be optimized.
	Optimizer::PassToken CreateNullPass();

	// Creates a strip-debug-info pass.
	// A strip-debug-info pass removes all debug instructions (as documented in
	// Section 3.32.2 of the SPIR-V spec) of the SPIR-V module to be optimized.
	Optimizer::PassToken CreateStripDebugInfoPass();

	// Creates a set-spec-constant-default-value pass.
	// A set-spec-constant-default-value pass sets the default values for the
	// spec constants that have SpecId decorations (i.e., those defined by
	// OpSpecConstant{\|True\|False} instructions).
	Optimizer::PassToken CreateSetSpecConstantDefaultValuePass(
	const std::unordered_map<uint32_t, std::string>& id_value_map);

	// Creates a freeze-spec-constant-value pass.
	// A freeze-spec-constant pass specializes the value of spec constants to
	// their default values. This pass only processes the spec constants that have
	// SpecId decorations (defined by OpSpecConstant, OpSpecConstantTrue, or
	// OpSpecConstantFalse instructions) and replaces them with their normal
	// counterparts (OpConstant, OpConstantTrue, or OpConstantFalse). The
	// corresponding SpecId annotation instructions will also be removed. This
	// pass does not fold the newly added normal constants and does not process
	// other spec constants defined by OpSpecConstantComposite or
	// OpSpecConstantOp.
	Optimizer::PassToken CreateFreezeSpecConstantValuePass();

	// Creates a fold-spec-constant-op-and-composite pass.
	// A fold-spec-constant-op-and-composite pass folds spec constants defined by
	// OpSpecConstantOp or OpSpecConstantComposite instruction, to normal Constants
	// defined by OpConstantTrue, OpConstantFalse, OpConstant, OpConstantNull, or
	// OpConstantComposite instructions. Note that spec constants defined with
	// OpSpecConstant, OpSpecConstantTrue, or OpSpecConstantFalse instructions are
	// not handled, as these instructions indicate their value are not determined
	// and can be changed in future. A spec constant is foldable if all of its
	// value(s) can be determined from the module. E.g., an integer spec constant
	// defined with OpSpecConstantOp instruction can be folded if its value won't
	// change later. This pass will replace the original OpSpecContantOp instruction
	// with an OpConstant instruction. When folding composite spec constants,
	// new instructions may be inserted to define the components of the composite
	// constant first, then the original spec constants will be replaced by
	// OpConstantComposite instructions.
	//
	// There are some operations not supported yet:
	// OpSConvert, OpFConvert, OpQuantizeToF16 and
	// all the operations under Kernel capability.
	// TODO(qining): Add support for the operations listed above.
	Optimizer::PassToken CreateFoldSpecConstantOpAndCompositePass();

	// Creates a unify-constant pass.
	// A unify-constant pass de-duplicates the constants. Constants with the exact
	// same value and identical form will be unified and only one constant will
	// be kept for each unique pair of type and value.
	// There are several cases not handled by this pass:
	// 1) Constants defined by OpConstantNull instructions (null constants) and
	// constants defined by OpConstantFalse, OpConstant or OpConstantComposite
	// with value 0 (zero-valued normal constants) are not considered equivalent.
	// So null constants won't be used to replace zero-valued normal constants,
	// vice versa.
	// 2) Whenever there are decorations to the constant's result id id, the
	// constant won't be handled, which means, it won't be used to replace any
	// other constants, neither can other constants replace it.
	// 3) NaN in float point format with different bit patterns are not unified.
	Optimizer::PassToken CreateUnifyConstantPass();

	// Creates a eliminate-dead-constant pass.
	// A eliminate-dead-constant pass removes dead constants, including normal
	// contants defined by OpConstant, OpConstantComposite, OpConstantTrue, or
	// OpConstantFalse and spec constants defined by OpSpecConstant,
	// OpSpecConstantComposite, OpSpecConstantTrue, OpSpecConstantFalse or
	// OpSpecConstantOp.
	Optimizer::PassToken CreateEliminateDeadConstantPass();

	} // namespace spvtools

	#endif // SPIRV_TOOLS_OPTIMIZER_HPP_