SPIRV-Tools/source/val/validation_state.h

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// Copyright (c) 2015-2016 The Khronos Group 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 SOURCE_VAL_VALIDATION_STATE_H_
#define SOURCE_VAL_VALIDATION_STATE_H_
#include <algorithm>
#include <map>
#include <set>
#include <string>
#include <tuple>
#include <unordered_map>
#include <unordered_set>
#include <vector>
#include "source/assembly_grammar.h"
#include "source/diagnostic.h"
#include "source/disassemble.h"
#include "source/enum_set.h"
#include "source/latest_version_spirv_header.h"
#include "source/name_mapper.h"
#include "source/spirv_definition.h"
#include "source/spirv_validator_options.h"
#include "source/val/decoration.h"
#include "source/val/function.h"
#include "source/val/instruction.h"
#include "spirv-tools/libspirv.h"
namespace spvtools {
namespace val {
/// This enum represents the sections of a SPIRV module. See section 2.4
/// of the SPIRV spec for additional details of the order. The enumerant values
/// are in the same order as the vector returned by GetModuleOrder
enum ModuleLayoutSection {
kLayoutCapabilities, /// < Section 2.4 #1
kLayoutExtensions, /// < Section 2.4 #2
kLayoutExtInstImport, /// < Section 2.4 #3
kLayoutMemoryModel, /// < Section 2.4 #4
kLayoutEntryPoint, /// < Section 2.4 #5
kLayoutExecutionMode, /// < Section 2.4 #6
kLayoutDebug1, /// < Section 2.4 #7 > 1
kLayoutDebug2, /// < Section 2.4 #7 > 2
kLayoutDebug3, /// < Section 2.4 #7 > 3
kLayoutAnnotations, /// < Section 2.4 #8
kLayoutTypes, /// < Section 2.4 #9
kLayoutFunctionDeclarations, /// < Section 2.4 #10
kLayoutFunctionDefinitions /// < Section 2.4 #11
};
/// This class manages the state of the SPIR-V validation as it is being parsed.
class ValidationState_t {
public:
// Features that can optionally be turned on by a capability or environment.
struct Feature {
bool declare_int16_type = false; // Allow OpTypeInt with 16 bit width?
bool declare_float16_type = false; // Allow OpTypeFloat with 16 bit width?
bool free_fp_rounding_mode = false; // Allow the FPRoundingMode decoration
// and its vaules to be used without
// requiring any capability
// Allow functionalities enabled by VariablePointers capability.
bool variable_pointers = false;
// Allow functionalities enabled by VariablePointersStorageBuffer
// capability.
bool variable_pointers_storage_buffer = false;
// Permit group oerations Reduce, InclusiveScan, ExclusiveScan
bool group_ops_reduce_and_scans = false;
// Allow OpTypeInt with 8 bit width?
bool declare_int8_type = false;
// Target environment uses relaxed block layout.
// This is true for Vulkan 1.1 or later.
bool env_relaxed_block_layout = false;
// Allow an OpTypeInt with 8 bit width to be used in more than just int
// conversion opcodes
bool use_int8_type = false;
// Use scalar block layout. See VK_EXT_scalar_block_layout:
// Defines scalar alignment:
// - scalar alignment equals the scalar size in bytes
// - array alignment is same as its element alignment
// - array alignment is max alignment of any of its members
// - vector alignment is same as component alignment
// - matrix alignment is same as component alignment
// For struct in Uniform, StorageBuffer, PushConstant:
// - Offset of a member is multiple of scalar alignment of that member
// - ArrayStride and MatrixStride are multiples of scalar alignment
// Members need not be listed in offset order
bool scalar_block_layout = false;
Support SPIR-V 1.4 (#2550) * SPIR-V 1.4 headers, add SPV_ENV_UNIVERSAL_1_4 * Support --target-env spv1.4 in help for command line tools * Support asm/dis of UniformId decoration * Validate UniformId decoration * Fix version check on instructions and operands Also register decorations used with OpDecorateId * Extension lists can differ between enums that match Example: SubgroupMaskEq vs SubgroupMaskEqKHR * Validate scope value for Uniform decoration, for SPIR-V 1.4 * More unioning of exts * Preserve grammar order within an enum value * 1.4: Validate OpSelect over composites * Tools default to 1.4 * Add asm/dis test for OpCopyLogical * 1.4: asm/dis tests for PtrEqual, PtrNotEqual, PtrDiff * Basic asm/Dis test for OpCopyMemory * Test asm/dis OpCopyMemory with 2-memory access Add asm/dis tests for OpCopyMemorySized Requires grammar update to add second optional memory access operand to OpCopyMemory and OpCopyMemorySized * Validate one or two memory accesses on OpCopyMemory* * Check av/vis on CopyMemory source and target memory access This is a proposed rule. See https://gitlab.khronos.org/spirv/SPIR-V/issues/413 * Validate operation for OpSpecConstantOp * Validate NonWritable decoration Also permit NonWritable on members of UBO and SSBO. * SPIR-V 1.4: NonWrtiable can decorate Function and Private vars * Update optimizer CLI tests for SPIR-V 1.4 * Testing tools: Give expected SPIR-V version in message * SPIR-V 1.4 validation for entry point interfaces * Allow only unique interfaces * Allow all global variables * Check that all statically used global variables are listed * new tests * Add validation fixture CompileFailure * Add 1.4 validation for pointer comparisons * New tests * Validate with image operands SignExtend, ZeroExtend Since we don't actually know the image texel format, we can't fully validate. We need more context. But we can make sure we allow the new image operands in known-good cases. * Validate OpCopyLogical * Recursively checks subtypes * new tests * Add SPIR-V 1.4 tests for NoSignedWrap, NoUnsignedWrap * Allow scalar conditions in 1.4 with OpSelect * Allows scalar conditions with vector operands * new tests * Validate uniform id scope as an execution scope * Validate the values of memory and execution scopes are valid scope values * new test * Remove SPIR-V 1.4 Vulkan 1.0 environment * SPIR-V 1.4 requires Vulkan 1.1 * FIX: include string for spvLog * FIX: validate nonwritable * FIX: test case suite for member decorate string * FIX: test case for hlsl functionality1 * Validation test fixture: ease debugging * Use binary version for SPIR-V 1.4 specific features * Switch checks based on the SPIR-V version from the target environment to instead use the version from the binary * Moved header parsing into the ValidationState_t constructor (where version based features are set) * Added new versions of tests that assemble a 1.3 binary and validate a 1.4 environment * Fix test for update to SPIR-V 1.4 headers * Fix formatting * Ext inst lookup: Add Vulkan 1.1 env with SPIR-V 1.4 * Update spirv-val help * Operand version checks should use module version Use the module version instead of the target environment version. * Fix comment about two-access form of OpCopyMemory
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// SPIR-V 1.4 allows us to select between any two composite values
// of the same type.
bool select_between_composites = false;
// SPIR-V 1.4 allows two memory access operands for OpCopyMemory and
// OpCopyMemorySized.
bool copy_memory_permits_two_memory_accesses = false;
// SPIR-V 1.4 allows UConvert as a spec constant op in any environment.
// The Kernel capability already enables it, separately from this flag.
bool uconvert_spec_constant_op = false;
Support SPIR-V 1.4 (#2550) * SPIR-V 1.4 headers, add SPV_ENV_UNIVERSAL_1_4 * Support --target-env spv1.4 in help for command line tools * Support asm/dis of UniformId decoration * Validate UniformId decoration * Fix version check on instructions and operands Also register decorations used with OpDecorateId * Extension lists can differ between enums that match Example: SubgroupMaskEq vs SubgroupMaskEqKHR * Validate scope value for Uniform decoration, for SPIR-V 1.4 * More unioning of exts * Preserve grammar order within an enum value * 1.4: Validate OpSelect over composites * Tools default to 1.4 * Add asm/dis test for OpCopyLogical * 1.4: asm/dis tests for PtrEqual, PtrNotEqual, PtrDiff * Basic asm/Dis test for OpCopyMemory * Test asm/dis OpCopyMemory with 2-memory access Add asm/dis tests for OpCopyMemorySized Requires grammar update to add second optional memory access operand to OpCopyMemory and OpCopyMemorySized * Validate one or two memory accesses on OpCopyMemory* * Check av/vis on CopyMemory source and target memory access This is a proposed rule. See https://gitlab.khronos.org/spirv/SPIR-V/issues/413 * Validate operation for OpSpecConstantOp * Validate NonWritable decoration Also permit NonWritable on members of UBO and SSBO. * SPIR-V 1.4: NonWrtiable can decorate Function and Private vars * Update optimizer CLI tests for SPIR-V 1.4 * Testing tools: Give expected SPIR-V version in message * SPIR-V 1.4 validation for entry point interfaces * Allow only unique interfaces * Allow all global variables * Check that all statically used global variables are listed * new tests * Add validation fixture CompileFailure * Add 1.4 validation for pointer comparisons * New tests * Validate with image operands SignExtend, ZeroExtend Since we don't actually know the image texel format, we can't fully validate. We need more context. But we can make sure we allow the new image operands in known-good cases. * Validate OpCopyLogical * Recursively checks subtypes * new tests * Add SPIR-V 1.4 tests for NoSignedWrap, NoUnsignedWrap * Allow scalar conditions in 1.4 with OpSelect * Allows scalar conditions with vector operands * new tests * Validate uniform id scope as an execution scope * Validate the values of memory and execution scopes are valid scope values * new test * Remove SPIR-V 1.4 Vulkan 1.0 environment * SPIR-V 1.4 requires Vulkan 1.1 * FIX: include string for spvLog * FIX: validate nonwritable * FIX: test case suite for member decorate string * FIX: test case for hlsl functionality1 * Validation test fixture: ease debugging * Use binary version for SPIR-V 1.4 specific features * Switch checks based on the SPIR-V version from the target environment to instead use the version from the binary * Moved header parsing into the ValidationState_t constructor (where version based features are set) * Added new versions of tests that assemble a 1.3 binary and validate a 1.4 environment * Fix test for update to SPIR-V 1.4 headers * Fix formatting * Ext inst lookup: Add Vulkan 1.1 env with SPIR-V 1.4 * Update spirv-val help * Operand version checks should use module version Use the module version instead of the target environment version. * Fix comment about two-access form of OpCopyMemory
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// SPIR-V 1.4 allows Function and Private variables to be NonWritable
bool nonwritable_var_in_function_or_private = false;
};
ValidationState_t(const spv_const_context context,
const spv_const_validator_options opt,
const uint32_t* words, const size_t num_words,
const uint32_t max_warnings);
/// Returns the context
spv_const_context context() const { return context_; }
/// Returns the command line options
spv_const_validator_options options() const { return options_; }
/// Sets the ID of the generator for this module.
void setGenerator(uint32_t gen) { generator_ = gen; }
/// Returns the ID of the generator for this module.
uint32_t generator() const { return generator_; }
/// Sets the SPIR-V version of this module.
void setVersion(uint32_t ver) { version_ = ver; }
/// Gets the SPIR-V version of this module.
uint32_t version() const { return version_; }
/// Forward declares the id in the module
spv_result_t ForwardDeclareId(uint32_t id);
/// Removes a forward declared ID if it has been defined
spv_result_t RemoveIfForwardDeclared(uint32_t id);
/// Registers an ID as a forward pointer
spv_result_t RegisterForwardPointer(uint32_t id);
/// Returns whether or not an ID is a forward pointer
bool IsForwardPointer(uint32_t id) const;
/// Assigns a name to an ID
void AssignNameToId(uint32_t id, std::string name);
/// Returns a string representation of the ID in the format <id>[Name] where
/// the <id> is the numeric valid of the id and the Name is a name assigned by
/// the OpName instruction
std::string getIdName(uint32_t id) const;
/// Accessor function for ID bound.
uint32_t getIdBound() const;
/// Mutator function for ID bound.
void setIdBound(uint32_t bound);
/// Returns the number of ID which have been forward referenced but not
/// defined
size_t unresolved_forward_id_count() const;
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/// Returns a vector of unresolved forward ids.
std::vector<uint32_t> UnresolvedForwardIds() const;
/// Returns true if the id has been defined
bool IsDefinedId(uint32_t id) const;
/// Increments the total number of instructions in the file.
void increment_total_instructions() { total_instructions_++; }
/// Increments the total number of functions in the file.
void increment_total_functions() { total_functions_++; }
/// Allocates internal storage. Note, calling this will invalidate any
/// pointers to |ordered_instructions_| or |module_functions_| and, hence,
/// should only be called at the beginning of validation.
void preallocateStorage();
/// Returns the current layout section which is being processed
ModuleLayoutSection current_layout_section() const;
/// Increments the module_layout_order_section_
void ProgressToNextLayoutSectionOrder();
/// Determines if the op instruction is part of the current section
bool IsOpcodeInCurrentLayoutSection(SpvOp op);
DiagnosticStream diag(spv_result_t error_code, const Instruction* inst);
/// Returns the function states
std::vector<Function>& functions();
/// Returns the function states
Function& current_function();
const Function& current_function() const;
/// Returns function state with the given id, or nullptr if no such function.
const Function* function(uint32_t id) const;
Function* function(uint32_t id);
/// Returns true if the called after a function instruction but before the
/// function end instruction
bool in_function_body() const;
/// Returns true if called after a label instruction but before a branch
/// instruction
bool in_block() const;
struct EntryPointDescription {
std::string name;
std::vector<uint32_t> interfaces;
};
/// Registers |id| as an entry point with |execution_model| and |interfaces|.
void RegisterEntryPoint(const uint32_t id, SpvExecutionModel execution_model,
EntryPointDescription&& desc) {
entry_points_.push_back(id);
entry_point_to_execution_models_[id].insert(execution_model);
entry_point_descriptions_[id].emplace_back(desc);
}
/// Returns a list of entry point function ids
const std::vector<uint32_t>& entry_points() const { return entry_points_; }
/// Returns the set of entry points that root call graphs that contain
/// recursion.
const std::set<uint32_t>& recursive_entry_points() const {
return recursive_entry_points_;
}
/// Registers execution mode for the given entry point.
void RegisterExecutionModeForEntryPoint(uint32_t entry_point,
SpvExecutionMode execution_mode) {
entry_point_to_execution_modes_[entry_point].insert(execution_mode);
}
/// Returns the interface descriptions of a given entry point.
const std::vector<EntryPointDescription>& entry_point_descriptions(
uint32_t entry_point) {
return entry_point_descriptions_.at(entry_point);
}
/// Returns Execution Models for the given Entry Point.
/// Returns nullptr if none found (would trigger assertion).
const std::set<SpvExecutionModel>* GetExecutionModels(
uint32_t entry_point) const {
const auto it = entry_point_to_execution_models_.find(entry_point);
if (it == entry_point_to_execution_models_.end()) {
assert(0);
return nullptr;
}
return &it->second;
}
/// Returns Execution Modes for the given Entry Point.
/// Returns nullptr if none found.
const std::set<SpvExecutionMode>* GetExecutionModes(
uint32_t entry_point) const {
const auto it = entry_point_to_execution_modes_.find(entry_point);
if (it == entry_point_to_execution_modes_.end()) {
return nullptr;
}
return &it->second;
}
/// Traverses call tree and computes function_to_entry_points_.
/// Note: called after fully parsing the binary.
void ComputeFunctionToEntryPointMapping();
/// Traverse call tree and computes recursive_entry_points_.
/// Note: called after fully parsing the binary and calling
/// ComputeFunctionToEntryPointMapping.
void ComputeRecursiveEntryPoints();
/// Returns all the entry points that can call |func|.
const std::vector<uint32_t>& FunctionEntryPoints(uint32_t func) const;
/// Returns all the entry points that statically use |id|.
///
/// Note: requires ComputeFunctionToEntryPointMapping to have been called.
std::set<uint32_t> EntryPointReferences(uint32_t id) const;
/// Inserts an <id> to the set of functions that are target of OpFunctionCall.
void AddFunctionCallTarget(const uint32_t id) {
function_call_targets_.insert(id);
current_function().AddFunctionCallTarget(id);
}
/// Returns whether or not a function<id> is the target of OpFunctionCall.
bool IsFunctionCallTarget(const uint32_t id) {
return (function_call_targets_.find(id) != function_call_targets_.end());
}
bool IsFunctionCallDefined(const uint32_t id) {
return (id_to_function_.find(id) != id_to_function_.end());
}
/// Registers the capability and its dependent capabilities
void RegisterCapability(SpvCapability cap);
/// Registers the extension.
void RegisterExtension(Extension ext);
/// Registers the function in the module. Subsequent instructions will be
/// called against this function
spv_result_t RegisterFunction(uint32_t id, uint32_t ret_type_id,
SpvFunctionControlMask function_control,
uint32_t function_type_id);
/// Register a function end instruction
spv_result_t RegisterFunctionEnd();
/// Returns true if the capability is enabled in the module.
bool HasCapability(SpvCapability cap) const {
return module_capabilities_.Contains(cap);
}
/// Returns a reference to the set of capabilities in the module.
/// This is provided for debuggability.
const CapabilitySet& module_capabilities() const {
return module_capabilities_;
}
/// Returns true if the extension is enabled in the module.
bool HasExtension(Extension ext) const {
return module_extensions_.Contains(ext);
}
/// Returns true if any of the capabilities is enabled, or if |capabilities|
/// is an empty set.
bool HasAnyOfCapabilities(const CapabilitySet& capabilities) const;
/// Returns true if any of the extensions is enabled, or if |extensions|
/// is an empty set.
bool HasAnyOfExtensions(const ExtensionSet& extensions) const;
/// Sets the addressing model of this module (logical/physical).
void set_addressing_model(SpvAddressingModel am);
/// Returns true if the OpMemoryModel was found.
bool has_memory_model_specified() const {
return addressing_model_ != SpvAddressingModelMax &&
memory_model_ != SpvMemoryModelMax;
}
/// Returns the addressing model of this module, or Logical if uninitialized.
SpvAddressingModel addressing_model() const;
/// Returns the addressing model of this module, or Logical if uninitialized.
uint32_t pointer_size_and_alignment() const {
return pointer_size_and_alignment_;
}
/// Sets the memory model of this module.
void set_memory_model(SpvMemoryModel mm);
/// Returns the memory model of this module, or Simple if uninitialized.
SpvMemoryModel memory_model() const;
const AssemblyGrammar& grammar() const { return grammar_; }
/// Inserts the instruction into the list of ordered instructions in the file.
Instruction* AddOrderedInstruction(const spv_parsed_instruction_t* inst);
/// Registers the instruction. This will add the instruction to the list of
/// definitions and register sampled image consumers.
void RegisterInstruction(Instruction* inst);
/// Registers the debug instruction information.
void RegisterDebugInstruction(const Instruction* inst);
/// Registers the decoration for the given <id>
void RegisterDecorationForId(uint32_t id, const Decoration& dec) {
auto& dec_list = id_decorations_[id];
auto lb = std::find(dec_list.begin(), dec_list.end(), dec);
if (lb == dec_list.end()) {
dec_list.push_back(dec);
}
}
/// Registers the list of decorations for the given <id>
template <class InputIt>
void RegisterDecorationsForId(uint32_t id, InputIt begin, InputIt end) {
std::vector<Decoration>& cur_decs = id_decorations_[id];
cur_decs.insert(cur_decs.end(), begin, end);
}
/// Registers the list of decorations for the given member of the given
/// structure.
template <class InputIt>
void RegisterDecorationsForStructMember(uint32_t struct_id,
uint32_t member_index, InputIt begin,
InputIt end) {
RegisterDecorationsForId(struct_id, begin, end);
for (auto& decoration : id_decorations_[struct_id]) {
decoration.set_struct_member_index(member_index);
}
}
/// Returns all the decorations for the given <id>. If no decorations exist
/// for the <id>, it registers an empty vector for it in the map and
/// returns the empty vector.
std::vector<Decoration>& id_decorations(uint32_t id) {
return id_decorations_[id];
}
// Returns const pointer to the internal decoration container.
const std::map<uint32_t, std::vector<Decoration>>& id_decorations() const {
return id_decorations_;
}
/// Returns true if the given id <id> has the given decoration <dec>,
/// otherwise returns false.
bool HasDecoration(uint32_t id, SpvDecoration dec) {
const auto& decorations = id_decorations_.find(id);
if (decorations == id_decorations_.end()) return false;
return std::any_of(
decorations->second.begin(), decorations->second.end(),
[dec](const Decoration& d) { return dec == d.dec_type(); });
}
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/// Finds id's def, if it exists. If found, returns the definition otherwise
/// nullptr
const Instruction* FindDef(uint32_t id) const;
/// Finds id's def, if it exists. If found, returns the definition otherwise
/// nullptr
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Instruction* FindDef(uint32_t id);
/// Returns the instructions in the order they appear in the binary
const std::vector<Instruction>& ordered_instructions() const {
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return ordered_instructions_;
}
/// Returns a map of instructions mapped by their result id
const std::unordered_map<uint32_t, Instruction*>& all_definitions() const {
return all_definitions_;
}
/// Returns a vector containing the instructions that consume the given
/// SampledImage id.
std::vector<Instruction*> getSampledImageConsumers(uint32_t id) const;
/// Records cons_id as a consumer of sampled_image_id.
void RegisterSampledImageConsumer(uint32_t sampled_image_id,
Instruction* consumer);
/// Returns the set of Global Variables.
std::unordered_set<uint32_t>& global_vars() { return global_vars_; }
/// Returns the set of Local Variables.
std::unordered_set<uint32_t>& local_vars() { return local_vars_; }
/// Returns the number of Global Variables.
size_t num_global_vars() { return global_vars_.size(); }
/// Returns the number of Local Variables.
size_t num_local_vars() { return local_vars_.size(); }
/// Inserts a new <id> to the set of Global Variables.
void registerGlobalVariable(const uint32_t id) { global_vars_.insert(id); }
/// Inserts a new <id> to the set of Local Variables.
void registerLocalVariable(const uint32_t id) { local_vars_.insert(id); }
// Returns true if using relaxed block layout, equivalent to
// VK_KHR_relaxed_block_layout.
bool IsRelaxedBlockLayout() const {
return features_.env_relaxed_block_layout || options()->relax_block_layout;
}
/// Sets the struct nesting depth for a given struct ID
void set_struct_nesting_depth(uint32_t id, uint32_t depth) {
struct_nesting_depth_[id] = depth;
}
/// Returns the nesting depth of a given structure ID
uint32_t struct_nesting_depth(uint32_t id) {
return struct_nesting_depth_[id];
}
/// Records the has a nested block/bufferblock decorated struct for a given
/// struct ID
void SetHasNestedBlockOrBufferBlockStruct(uint32_t id, bool has) {
struct_has_nested_blockorbufferblock_struct_[id] = has;
}
/// For a given struct ID returns true if it has a nested block/bufferblock
/// decorated struct
bool GetHasNestedBlockOrBufferBlockStruct(uint32_t id) {
return struct_has_nested_blockorbufferblock_struct_[id];
}
/// Records that the structure type has a member decorated with a built-in.
void RegisterStructTypeWithBuiltInMember(uint32_t id) {
builtin_structs_.insert(id);
}
/// Returns true if the struct type with the given Id has a BuiltIn member.
bool IsStructTypeWithBuiltInMember(uint32_t id) const {
return (builtin_structs_.find(id) != builtin_structs_.end());
}
// Returns the state of optional features.
const Feature& features() const { return features_; }
/// Adds the instruction data to unique_type_declarations_.
/// Returns false if an identical type declaration already exists.
bool RegisterUniqueTypeDeclaration(const Instruction* inst);
// Returns type_id of the scalar component of |id|.
// |id| can be either
// - scalar, vector or matrix type
// - object of either scalar, vector or matrix type
uint32_t GetComponentType(uint32_t id) const;
// Returns
// - 1 for scalar types or objects
// - vector size for vector types or objects
// - num columns for matrix types or objects
// Should not be called with any other arguments (will return zero and invoke
// assertion).
uint32_t GetDimension(uint32_t id) const;
// Returns bit width of scalar or component.
// |id| can be
// - scalar, vector or matrix type
// - object of either scalar, vector or matrix type
// Will invoke assertion and return 0 if |id| is none of the above.
uint32_t GetBitWidth(uint32_t id) const;
// Provides detailed information on matrix type.
// Returns false iff |id| is not matrix type.
bool GetMatrixTypeInfo(uint32_t id, uint32_t* num_rows, uint32_t* num_cols,
uint32_t* column_type, uint32_t* component_type) const;
// Collects struct member types into |member_types|.
// Returns false iff not struct type or has no members.
// Deletes prior contents of |member_types|.
bool GetStructMemberTypes(uint32_t struct_type_id,
std::vector<uint32_t>* member_types) const;
// Returns true iff |id| is a type corresponding to the name of the function.
// Only works for types not for objects.
bool IsVoidType(uint32_t id) const;
bool IsFloatScalarType(uint32_t id) const;
bool IsFloatVectorType(uint32_t id) const;
bool IsFloatScalarOrVectorType(uint32_t id) const;
bool IsFloatMatrixType(uint32_t id) const;
bool IsIntScalarType(uint32_t id) const;
bool IsIntVectorType(uint32_t id) const;
bool IsIntScalarOrVectorType(uint32_t id) const;
bool IsUnsignedIntScalarType(uint32_t id) const;
bool IsUnsignedIntVectorType(uint32_t id) const;
bool IsSignedIntScalarType(uint32_t id) const;
bool IsSignedIntVectorType(uint32_t id) const;
bool IsBoolScalarType(uint32_t id) const;
bool IsBoolVectorType(uint32_t id) const;
bool IsBoolScalarOrVectorType(uint32_t id) const;
bool IsPointerType(uint32_t id) const;
bool IsCooperativeMatrixType(uint32_t id) const;
bool IsFloatCooperativeMatrixType(uint32_t id) const;
bool IsIntCooperativeMatrixType(uint32_t id) const;
bool IsUnsignedIntCooperativeMatrixType(uint32_t id) const;
// Returns true if |id| is a type id that contains |type| (or integer or
// floating point type) of |width| bits.
bool ContainsSizedIntOrFloatType(uint32_t id, SpvOp type,
uint32_t width) const;
// Returns true if |id| is a type id that contains a 8- or 16-bit int or
// 16-bit float that is not generally enabled for use.
bool ContainsLimitedUseIntOrFloatType(uint32_t id) const;
// Gets value from OpConstant and OpSpecConstant as uint64.
// Returns false on failure (no instruction, wrong instruction, not int).
bool GetConstantValUint64(uint32_t id, uint64_t* val) const;
// Returns type_id if id has type or zero otherwise.
uint32_t GetTypeId(uint32_t id) const;
// Returns opcode of the instruction which issued the id or OpNop if the
// instruction is not registered.
SpvOp GetIdOpcode(uint32_t id) const;
// Returns type_id for given id operand if it has a type or zero otherwise.
// |operand_index| is expected to be pointing towards an operand which is an
// id.
uint32_t GetOperandTypeId(const Instruction* inst,
size_t operand_index) const;
// Provides information on pointer type. Returns false iff not pointer type.
bool GetPointerTypeInfo(uint32_t id, uint32_t* data_type,
uint32_t* storage_class) const;
// Is the ID the type of a pointer to a uniform block: Block-decorated struct
// in uniform storage class? The result is only valid after internal method
// CheckDecorationsOfBuffers has been called.
bool IsPointerToUniformBlock(uint32_t type_id) const {
return pointer_to_uniform_block_.find(type_id) !=
pointer_to_uniform_block_.cend();
}
// Save the ID of a pointer to uniform block.
void RegisterPointerToUniformBlock(uint32_t type_id) {
pointer_to_uniform_block_.insert(type_id);
}
// Is the ID the type of a struct used as a uniform block?
// The result is only valid after internal method CheckDecorationsOfBuffers
// has been called.
bool IsStructForUniformBlock(uint32_t type_id) const {
return struct_for_uniform_block_.find(type_id) !=
struct_for_uniform_block_.cend();
}
// Save the ID of a struct of a uniform block.
void RegisterStructForUniformBlock(uint32_t type_id) {
struct_for_uniform_block_.insert(type_id);
}
// Is the ID the type of a pointer to a storage buffer: BufferBlock-decorated
// struct in uniform storage class, or Block-decorated struct in StorageBuffer
// storage class? The result is only valid after internal method
// CheckDecorationsOfBuffers has been called.
bool IsPointerToStorageBuffer(uint32_t type_id) const {
return pointer_to_storage_buffer_.find(type_id) !=
pointer_to_storage_buffer_.cend();
}
// Save the ID of a pointer to a storage buffer.
void RegisterPointerToStorageBuffer(uint32_t type_id) {
pointer_to_storage_buffer_.insert(type_id);
}
// Is the ID the type of a struct for storage buffer?
// The result is only valid after internal method CheckDecorationsOfBuffers
// has been called.
bool IsStructForStorageBuffer(uint32_t type_id) const {
return struct_for_storage_buffer_.find(type_id) !=
struct_for_storage_buffer_.cend();
}
// Save the ID of a struct of a storage buffer.
void RegisterStructForStorageBuffer(uint32_t type_id) {
struct_for_storage_buffer_.insert(type_id);
}
// Is the ID the type of a pointer to a storage image? That is, the pointee
// type is an image type which is known to not use a sampler.
bool IsPointerToStorageImage(uint32_t type_id) const {
return pointer_to_storage_image_.find(type_id) !=
pointer_to_storage_image_.cend();
}
// Save the ID of a pointer to a storage image.
void RegisterPointerToStorageImage(uint32_t type_id) {
pointer_to_storage_image_.insert(type_id);
}
// Tries to evaluate a 32-bit signed or unsigned scalar integer constant.
// Returns tuple <is_int32, is_const_int32, value>.
// OpSpecConstant* return |is_const_int32| as false since their values cannot
// be relied upon during validation.
std::tuple<bool, bool, uint32_t> EvalInt32IfConst(uint32_t id) const;
// Returns the disassembly string for the given instruction.
std::string Disassemble(const Instruction& inst) const;
// Returns the disassembly string for the given instruction.
std::string Disassemble(const uint32_t* words, uint16_t num_words) const;
// Returns whether type m1 and type m2 are cooperative matrices with
// the same "shape" (matching scope, rows, cols). If any are specialization
// constants, we assume they can match because we can't prove they don't.
spv_result_t CooperativeMatrixShapesMatch(const Instruction* inst,
uint32_t m1, uint32_t m2);
// Returns true if |lhs| and |rhs| logically match and, if the decorations of
// |rhs| are a subset of |lhs|.
//
// 1. Must both be either OpTypeArray or OpTypeStruct
// 2. If OpTypeArray, then
// * Length must be the same
// * Element type must match or logically match
// 3. If OpTypeStruct, then
// * Both have same number of elements
// * Element N for both structs must match or logically match
//
// If |check_decorations| is false, then the decorations are not checked.
bool LogicallyMatch(const Instruction* lhs, const Instruction* rhs,
bool check_decorations);
// Traces |inst| to find a single base pointer. Returns the base pointer.
// Will trace through the following instructions:
// * OpAccessChain
// * OpInBoundsAccessChain
// * OpPtrAccessChain
// * OpInBoundsPtrAccessChain
// * OpCopyObject
const Instruction* TracePointer(const Instruction* inst) const;
// Validates the storage class for the target environment.
bool IsValidStorageClass(SpvStorageClass storage_class) const;
private:
ValidationState_t(const ValidationState_t&);
const spv_const_context context_;
/// Stores the Validator command line options. Must be a valid options object.
const spv_const_validator_options options_;
/// The SPIR-V binary module we're validating.
const uint32_t* words_;
const size_t num_words_;
/// The generator of the SPIR-V.
uint32_t generator_ = 0;
/// The version of the SPIR-V.
uint32_t version_ = 0;
/// The total number of instructions in the binary.
size_t total_instructions_ = 0;
/// The total number of functions in the binary.
size_t total_functions_ = 0;
/// IDs which have been forward declared but have not been defined
std::unordered_set<uint32_t> unresolved_forward_ids_;
/// IDs that have been declared as forward pointers.
std::unordered_set<uint32_t> forward_pointer_ids_;
/// Stores a vector of instructions that use the result of a given
/// OpSampledImage instruction.
std::unordered_map<uint32_t, std::vector<Instruction*>>
sampled_image_consumers_;
/// A map of operand IDs and their names defined by the OpName instruction
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std::unordered_map<uint32_t, std::string> operand_names_;
/// The section of the code being processed
ModuleLayoutSection current_layout_section_;
/// A list of functions in the module.
/// Pointers to objects in this container are guaranteed to be stable and
/// valid until the end of lifetime of the validation state.
std::vector<Function> module_functions_;
/// Capabilities declared in the module
CapabilitySet module_capabilities_;
/// Extensions declared in the module
ExtensionSet module_extensions_;
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/// List of all instructions in the order they appear in the binary
std::vector<Instruction> ordered_instructions_;
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/// Instructions that can be referenced by Ids
std::unordered_map<uint32_t, Instruction*> all_definitions_;
/// IDs that are entry points, ie, arguments to OpEntryPoint.
std::vector<uint32_t> entry_points_;
/// Maps an entry point id to its desciptions.
std::unordered_map<uint32_t, std::vector<EntryPointDescription>>
entry_point_descriptions_;
/// IDs that are entry points, ie, arguments to OpEntryPoint, and root a call
/// graph that recurses.
std::set<uint32_t> recursive_entry_points_;
/// Functions IDs that are target of OpFunctionCall.
std::unordered_set<uint32_t> function_call_targets_;
/// ID Bound from the Header
uint32_t id_bound_;
/// Set of Global Variable IDs (Storage Class other than 'Function')
std::unordered_set<uint32_t> global_vars_;
/// Set of Local Variable IDs ('Function' Storage Class)
std::unordered_set<uint32_t> local_vars_;
/// Set of struct types that have members with a BuiltIn decoration.
std::unordered_set<uint32_t> builtin_structs_;
/// Structure Nesting Depth
std::unordered_map<uint32_t, uint32_t> struct_nesting_depth_;
/// Structure has nested blockorbufferblock struct
std::unordered_map<uint32_t, bool>
struct_has_nested_blockorbufferblock_struct_;
/// Stores the list of decorations for a given <id>
std::map<uint32_t, std::vector<Decoration>> id_decorations_;
/// Stores type declarations which need to be unique (i.e. non-aggregates),
/// in the form [opcode, operand words], result_id is not stored.
/// Using ordered set to avoid the need for a vector hash function.
/// The size of this container is expected not to exceed double-digits.
std::set<std::vector<uint32_t>> unique_type_declarations_;
AssemblyGrammar grammar_;
SpvAddressingModel addressing_model_;
SpvMemoryModel memory_model_;
// pointer size derived from addressing model. Assumes all storage classes
// have the same pointer size (for physical pointer types).
uint32_t pointer_size_and_alignment_;
/// NOTE: See correspoding getter functions
bool in_function_;
/// The state of optional features. These are determined by capabilities
/// declared by the module and the environment.
Feature features_;
/// Maps function ids to function stat objects.
std::unordered_map<uint32_t, Function*> id_to_function_;
/// Mapping entry point -> execution models. It is presumed that the same
/// function could theoretically be used as 'main' by multiple OpEntryPoint
/// instructions.
std::unordered_map<uint32_t, std::set<SpvExecutionModel>>
entry_point_to_execution_models_;
/// Mapping entry point -> execution modes.
std::unordered_map<uint32_t, std::set<SpvExecutionMode>>
entry_point_to_execution_modes_;
/// Mapping function -> array of entry points inside this
/// module which can (indirectly) call the function.
std::unordered_map<uint32_t, std::vector<uint32_t>> function_to_entry_points_;
const std::vector<uint32_t> empty_ids_;
// The IDs of types of pointers to Block-decorated structs in Uniform storage
// class. This is populated at the start of ValidateDecorations.
std::unordered_set<uint32_t> pointer_to_uniform_block_;
// The IDs of struct types for uniform blocks.
// This is populated at the start of ValidateDecorations.
std::unordered_set<uint32_t> struct_for_uniform_block_;
// The IDs of types of pointers to BufferBlock-decorated structs in Uniform
// storage class, or Block-decorated structs in StorageBuffer storage class.
// This is populated at the start of ValidateDecorations.
std::unordered_set<uint32_t> pointer_to_storage_buffer_;
// The IDs of struct types for storage buffers.
// This is populated at the start of ValidateDecorations.
std::unordered_set<uint32_t> struct_for_storage_buffer_;
// The IDs of types of pointers to storage images. This is populated in the
// TypePass.
std::unordered_set<uint32_t> pointer_to_storage_image_;
/// Maps ids to friendly names.
std::unique_ptr<spvtools::FriendlyNameMapper> friendly_mapper_;
spvtools::NameMapper name_mapper_;
/// Variables used to reduce the number of diagnostic messages.
uint32_t num_of_warnings_;
uint32_t max_num_of_warnings_;
};
} // namespace val
} // namespace spvtools
#endif // SOURCE_VAL_VALIDATION_STATE_H_