SPIRV-Tools/include/spirv-tools/libspirv.hpp
Alastair Donaldson 5dcb576b69
spirv-reduce: Support reducing a specific function (#3774)
Motivated by integrating spirv-reduce into spirv-fuzz, so that an
added function can be made smaller during shrinking, this adds support
in spirv-reduce for asking reduction to be restricted to the
instructions of a single specified function.
2020-09-11 06:29:43 +01:00

354 lines
14 KiB
C++

// 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 INCLUDE_SPIRV_TOOLS_LIBSPIRV_HPP_
#define INCLUDE_SPIRV_TOOLS_LIBSPIRV_HPP_
#include <functional>
#include <memory>
#include <string>
#include <vector>
#include "spirv-tools/libspirv.h"
namespace spvtools {
// Message consumer. The C strings for source and message are only alive for the
// specific invocation.
using MessageConsumer = std::function<void(
spv_message_level_t /* level */, const char* /* source */,
const spv_position_t& /* position */, const char* /* message */
)>;
// C++ RAII wrapper around the C context object spv_context.
class Context {
public:
// Constructs a context targeting the given environment |env|.
//
// See specific API calls for how the target environment is interpeted
// (particularly assembly and validation).
//
// 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 Context(spv_target_env env);
// Enables move constructor/assignment operations.
Context(Context&& other);
Context& operator=(Context&& other);
// Disables copy constructor/assignment operations.
Context(const Context&) = delete;
Context& operator=(const Context&) = delete;
// Destructs this instance.
~Context();
// 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);
// Returns the underlying spv_context.
spv_context& CContext();
const spv_context& CContext() const;
private:
spv_context context_;
};
// A RAII wrapper around a validator options object.
class ValidatorOptions {
public:
ValidatorOptions() : options_(spvValidatorOptionsCreate()) {}
~ValidatorOptions() { spvValidatorOptionsDestroy(options_); }
// Allow implicit conversion to the underlying object.
operator spv_validator_options() const { return options_; }
// Sets a limit.
void SetUniversalLimit(spv_validator_limit limit_type, uint32_t limit) {
spvValidatorOptionsSetUniversalLimit(options_, limit_type, limit);
}
void SetRelaxStructStore(bool val) {
spvValidatorOptionsSetRelaxStoreStruct(options_, val);
}
// Enables VK_KHR_relaxed_block_layout when validating standard
// uniform/storage buffer/push-constant layout. If true, disables
// scalar block layout rules.
void SetRelaxBlockLayout(bool val) {
spvValidatorOptionsSetRelaxBlockLayout(options_, val);
}
// Enables VK_KHR_uniform_buffer_standard_layout when validating standard
// uniform layout. If true, disables scalar block layout rules.
void SetUniformBufferStandardLayout(bool val) {
spvValidatorOptionsSetUniformBufferStandardLayout(options_, val);
}
// Enables VK_EXT_scalar_block_layout when validating standard
// uniform/storage buffer/push-constant layout. If true, disables
// relaxed block layout rules.
void SetScalarBlockLayout(bool val) {
spvValidatorOptionsSetScalarBlockLayout(options_, val);
}
// Skips validating standard uniform/storage buffer/push-constant layout.
void SetSkipBlockLayout(bool val) {
spvValidatorOptionsSetSkipBlockLayout(options_, val);
}
// Records whether or not the validator should relax the rules on pointer
// usage in logical addressing mode.
//
// When relaxed, it will allow the following usage cases of pointers:
// 1) OpVariable allocating an object whose type is a pointer type
// 2) OpReturnValue returning a pointer value
void SetRelaxLogicalPointer(bool val) {
spvValidatorOptionsSetRelaxLogicalPointer(options_, val);
}
// Records whether or not the validator should relax the rules because it is
// expected that the optimizations will make the code legal.
//
// When relaxed, it will allow the following:
// 1) It will allow relaxed logical pointers. Setting this option will also
// set that option.
// 2) Pointers that are pass as parameters to function calls do not have to
// match the storage class of the formal parameter.
// 3) Pointers that are actaul parameters on function calls do not have to
// point to the same type pointed as the formal parameter. The types just
// need to logically match.
void SetBeforeHlslLegalization(bool val) {
spvValidatorOptionsSetBeforeHlslLegalization(options_, val);
}
private:
spv_validator_options options_;
};
// A C++ wrapper around an optimization options object.
class OptimizerOptions {
public:
OptimizerOptions() : options_(spvOptimizerOptionsCreate()) {}
~OptimizerOptions() { spvOptimizerOptionsDestroy(options_); }
// Allow implicit conversion to the underlying object.
operator spv_optimizer_options() const { return options_; }
// Records whether or not the optimizer should run the validator before
// optimizing. If |run| is true, the validator will be run.
void set_run_validator(bool run) {
spvOptimizerOptionsSetRunValidator(options_, run);
}
// Records the validator options that should be passed to the validator if it
// is run.
void set_validator_options(const ValidatorOptions& val_options) {
spvOptimizerOptionsSetValidatorOptions(options_, val_options);
}
// Records the maximum possible value for the id bound.
void set_max_id_bound(uint32_t new_bound) {
spvOptimizerOptionsSetMaxIdBound(options_, new_bound);
}
// Records whether all bindings within the module should be preserved.
void set_preserve_bindings(bool preserve_bindings) {
spvOptimizerOptionsSetPreserveBindings(options_, preserve_bindings);
}
// Records whether all specialization constants within the module
// should be preserved.
void set_preserve_spec_constants(bool preserve_spec_constants) {
spvOptimizerOptionsSetPreserveSpecConstants(options_,
preserve_spec_constants);
}
private:
spv_optimizer_options options_;
};
// A C++ wrapper around a reducer options object.
class ReducerOptions {
public:
ReducerOptions() : options_(spvReducerOptionsCreate()) {}
~ReducerOptions() { spvReducerOptionsDestroy(options_); }
// Allow implicit conversion to the underlying object.
operator spv_reducer_options() const { // NOLINT(google-explicit-constructor)
return options_;
}
// See spvReducerOptionsSetStepLimit.
void set_step_limit(uint32_t step_limit) {
spvReducerOptionsSetStepLimit(options_, step_limit);
}
// See spvReducerOptionsSetFailOnValidationError.
void set_fail_on_validation_error(bool fail_on_validation_error) {
spvReducerOptionsSetFailOnValidationError(options_,
fail_on_validation_error);
}
// See spvReducerOptionsSetTargetFunction.
void set_target_function(uint32_t target_function) {
spvReducerOptionsSetTargetFunction(options_, target_function);
}
private:
spv_reducer_options options_;
};
// A C++ wrapper around a fuzzer options object.
class FuzzerOptions {
public:
FuzzerOptions() : options_(spvFuzzerOptionsCreate()) {}
~FuzzerOptions() { spvFuzzerOptionsDestroy(options_); }
// Allow implicit conversion to the underlying object.
operator spv_fuzzer_options() const { // NOLINT(google-explicit-constructor)
return options_;
}
// See spvFuzzerOptionsEnableReplayValidation.
void enable_replay_validation() {
spvFuzzerOptionsEnableReplayValidation(options_);
}
// See spvFuzzerOptionsSetRandomSeed.
void set_random_seed(uint32_t seed) {
spvFuzzerOptionsSetRandomSeed(options_, seed);
}
// See spvFuzzerOptionsSetReplayRange.
void set_replay_range(int32_t replay_range) {
spvFuzzerOptionsSetReplayRange(options_, replay_range);
}
// See spvFuzzerOptionsSetShrinkerStepLimit.
void set_shrinker_step_limit(uint32_t shrinker_step_limit) {
spvFuzzerOptionsSetShrinkerStepLimit(options_, shrinker_step_limit);
}
// See spvFuzzerOptionsEnableFuzzerPassValidation.
void enable_fuzzer_pass_validation() {
spvFuzzerOptionsEnableFuzzerPassValidation(options_);
}
private:
spv_fuzzer_options options_;
};
// C++ interface for SPIRV-Tools functionalities. It wraps the context
// (including target environment and the corresponding SPIR-V grammar) and
// provides methods for assembling, disassembling, and validating.
//
// Instances of this class provide basic thread-safety guarantee.
class SpirvTools {
public:
enum {
// Default assembling option used by assemble():
kDefaultAssembleOption = SPV_TEXT_TO_BINARY_OPTION_NONE,
// Default disassembling option used by Disassemble():
// * Avoid prefix comments from decoding the SPIR-V module header, and
// * Use friendly names for variables.
kDefaultDisassembleOption = SPV_BINARY_TO_TEXT_OPTION_NO_HEADER |
SPV_BINARY_TO_TEXT_OPTION_FRIENDLY_NAMES
};
// Constructs an instance targeting the given environment |env|.
//
// 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 SpirvTools(spv_target_env env);
// Disables copy/move constructor/assignment operations.
SpirvTools(const SpirvTools&) = delete;
SpirvTools(SpirvTools&&) = delete;
SpirvTools& operator=(const SpirvTools&) = delete;
SpirvTools& operator=(SpirvTools&&) = delete;
// Destructs this instance.
~SpirvTools();
// 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);
// Assembles the given assembly |text| and writes the result to |binary|.
// Returns true on successful assembling. |binary| will be kept untouched if
// assembling is unsuccessful.
// The SPIR-V binary version is set to the highest version of SPIR-V supported
// by the target environment with which this SpirvTools object was created.
bool Assemble(const std::string& text, std::vector<uint32_t>* binary,
uint32_t options = kDefaultAssembleOption) const;
// |text_size| specifies the number of bytes in |text|. A terminating null
// character is not required to present in |text| as long as |text| is valid.
// The SPIR-V binary version is set to the highest version of SPIR-V supported
// by the target environment with which this SpirvTools object was created.
bool Assemble(const char* text, size_t text_size,
std::vector<uint32_t>* binary,
uint32_t options = kDefaultAssembleOption) const;
// Disassembles the given SPIR-V |binary| with the given |options| and writes
// the assembly to |text|. Returns true on successful disassembling. |text|
// will be kept untouched if diassembling is unsuccessful.
bool Disassemble(const std::vector<uint32_t>& binary, std::string* text,
uint32_t options = kDefaultDisassembleOption) const;
// |binary_size| specifies the number of words in |binary|.
bool Disassemble(const uint32_t* binary, size_t binary_size,
std::string* text,
uint32_t options = kDefaultDisassembleOption) const;
// Validates the given SPIR-V |binary|. Returns true if no issues are found.
// Otherwise, returns false and communicates issues via the message consumer
// registered.
// Validates for SPIR-V spec rules for the SPIR-V version named in the
// binary's header (at word offset 1). Additionally, if the target
// environment is a client API (such as Vulkan 1.1), then validate for that
// client API version, to the extent that it is verifiable from data in the
// binary itself.
bool Validate(const std::vector<uint32_t>& binary) const;
// Like the previous overload, but provides the binary as a pointer and size:
// |binary_size| specifies the number of words in |binary|.
// Validates for SPIR-V spec rules for the SPIR-V version named in the
// binary's header (at word offset 1). Additionally, if the target
// environment is a client API (such as Vulkan 1.1), then validate for that
// client API version, to the extent that it is verifiable from data in the
// binary itself.
bool Validate(const uint32_t* binary, size_t binary_size) const;
// Like the previous overload, but takes an options object.
// Validates for SPIR-V spec rules for the SPIR-V version named in the
// binary's header (at word offset 1). Additionally, if the target
// environment is a client API (such as Vulkan 1.1), then validate for that
// client API version, to the extent that it is verifiable from data in the
// binary itself, or in the validator options.
bool Validate(const uint32_t* binary, size_t binary_size,
spv_validator_options options) const;
// Was this object successfully constructed.
bool IsValid() const;
private:
struct Impl; // Opaque struct for holding the data fields used by this class.
std::unique_ptr<Impl> impl_; // Unique pointer to implementation data.
};
} // namespace spvtools
#endif // INCLUDE_SPIRV_TOOLS_LIBSPIRV_HPP_