// Copyright (c) 2018 Google LLC. // // 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. // Validates correctness of built-in variables. #include "validate.h" #include #include #include #include #include #include #include #include #include "diagnostic.h" #include "opcode.h" #include "spirv_target_env.h" #include "util/bitutils.h" #include "val/instruction.h" #include "val/validation_state.h" namespace libspirv { namespace { // Returns a short textual description of the id defined by the given // instruction. std::string GetIdDesc(const Instruction& inst) { std::ostringstream ss; ss << "ID <" << inst.id() << "> (Op" << spvOpcodeString(inst.opcode()) << ")"; return ss.str(); } // Gets underlying data type which is // - member type if instruction is OpTypeStruct // (member index is taken from decoration). // - data type if id creates a pointer. // - type of the constant if instruction is OpConst or OpSpecConst. // // Fails in any other case. The function is based on built-ins allowed by // the Vulkan spec. // TODO: If non-Vulkan validation rules are added then it might need // to be refactored. spv_result_t GetUnderlyingType(const ValidationState_t& _, const Decoration& decoration, const Instruction& inst, uint32_t* underlying_type) { if (decoration.struct_member_index() != Decoration::kInvalidMember) { assert(inst.opcode() == SpvOpTypeStruct); *underlying_type = inst.word(decoration.struct_member_index() + 2); return SPV_SUCCESS; } assert(inst.opcode() != SpvOpTypeStruct); if (spvOpcodeIsConstant(inst.opcode())) { *underlying_type = inst.type_id(); return SPV_SUCCESS; } uint32_t storage_class = 0; if (!_.GetPointerTypeInfo(inst.type_id(), underlying_type, &storage_class)) { return _.diag(SPV_ERROR_INVALID_DATA) << GetIdDesc(inst) << " is decorated with BuiltIn. BuiltIn decoration should only be " "applied to struct types, variables and constants."; } return SPV_SUCCESS; } // Returns Storage Class used by the instruction if applicable. // Returns SpvStorageClassMax if not. SpvStorageClass GetStorageClass(const Instruction& inst) { switch (inst.opcode()) { case SpvOpTypePointer: case SpvOpTypeForwardPointer: { return SpvStorageClass(inst.word(2)); } case SpvOpVariable: { return SpvStorageClass(inst.word(3)); } case SpvOpGenericCastToPtrExplicit: { return SpvStorageClass(inst.word(4)); } default: { break; } } return SpvStorageClassMax; } // Helper class managing validation of built-ins. // TODO: Generic functionality of this class can be moved into // ValidationState_t to be made available to other users. class BuiltInsValidator { public: BuiltInsValidator(const ValidationState_t& vstate) : _(vstate) {} // Run validation. spv_result_t Run(); private: // Goes through all decorations in the module, if decoration is BuiltIn // calls ValidateSingleBuiltInAtDefinition(). spv_result_t ValidateBuiltInsAtDefinition(); // Validates the instruction defining an id with built-in decoration. // Can be called multiple times for the same id, if multiple built-ins are // specified. Seeds id_to_at_reference_checks_ with decorated ids if needed. spv_result_t ValidateSingleBuiltInAtDefinition(const Decoration& decoration, const Instruction& inst); // The following section contains functions which are called when id defined // by |inst| is decorated with BuiltIn |decoration|. // Most functions are specific to a single built-in and have naming scheme: // ValidateXYZAtDefinition. Some functions are common to multiple kinds of // BuiltIn. spv_result_t ValidateClipOrCullDistanceAtDefinition( const Decoration& decoration, const Instruction& inst); spv_result_t ValidateFragCoordAtDefinition(const Decoration& decoration, const Instruction& inst); spv_result_t ValidateFragDepthAtDefinition(const Decoration& decoration, const Instruction& inst); spv_result_t ValidateFrontFacingAtDefinition(const Decoration& decoration, const Instruction& inst); spv_result_t ValidateHelperInvocationAtDefinition( const Decoration& decoration, const Instruction& inst); spv_result_t ValidateInvocationIdAtDefinition(const Decoration& decoration, const Instruction& inst); spv_result_t ValidateInstanceIndexAtDefinition(const Decoration& decoration, const Instruction& inst); spv_result_t ValidateLayerOrViewportIndexAtDefinition( const Decoration& decoration, const Instruction& inst); spv_result_t ValidatePatchVerticesAtDefinition(const Decoration& decoration, const Instruction& inst); spv_result_t ValidatePointCoordAtDefinition(const Decoration& decoration, const Instruction& inst); spv_result_t ValidatePointSizeAtDefinition(const Decoration& decoration, const Instruction& inst); spv_result_t ValidatePositionAtDefinition(const Decoration& decoration, const Instruction& inst); spv_result_t ValidatePrimitiveIdAtDefinition(const Decoration& decoration, const Instruction& inst); spv_result_t ValidateSampleIdAtDefinition(const Decoration& decoration, const Instruction& inst); spv_result_t ValidateSampleMaskAtDefinition(const Decoration& decoration, const Instruction& inst); spv_result_t ValidateSamplePositionAtDefinition(const Decoration& decoration, const Instruction& inst); spv_result_t ValidateTessCoordAtDefinition(const Decoration& decoration, const Instruction& inst); spv_result_t ValidateTessLevelOuterAtDefinition(const Decoration& decoration, const Instruction& inst); spv_result_t ValidateTessLevelInnerAtDefinition(const Decoration& decoration, const Instruction& inst); spv_result_t ValidateVertexIndexAtDefinition(const Decoration& decoration, const Instruction& inst); spv_result_t ValidateWorkgroupSizeAtDefinition(const Decoration& decoration, const Instruction& inst); // Used for GlobalInvocationId, LocalInvocationId, NumWorkgroups, WorkgroupId. spv_result_t ValidateComputeShaderI32Vec3InputAtDefinition( const Decoration& decoration, const Instruction& inst); // The following section contains functions which are called when id defined // by |referenced_inst| is // 1. referenced by |referenced_from_inst| // 2. dependent on |built_in_inst| which is decorated with BuiltIn // |decoration|. Most functions are specific to a single built-in and have // naming scheme: ValidateXYZAtReference. Some functions are common to // multiple kinds of BuiltIn. spv_result_t ValidateFragCoordAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst); spv_result_t ValidateFragDepthAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst); spv_result_t ValidateFrontFacingAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst); spv_result_t ValidateHelperInvocationAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst); spv_result_t ValidateInvocationIdAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst); spv_result_t ValidateInstanceIndexAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst); spv_result_t ValidatePatchVerticesAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst); spv_result_t ValidatePointCoordAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst); spv_result_t ValidatePointSizeAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst); spv_result_t ValidatePositionAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst); spv_result_t ValidatePrimitiveIdAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst); spv_result_t ValidateSampleIdAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst); spv_result_t ValidateSampleMaskAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst); spv_result_t ValidateSamplePositionAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst); spv_result_t ValidateTessCoordAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst); spv_result_t ValidateTessLevelAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst); spv_result_t ValidateVertexIndexAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst); spv_result_t ValidateLayerOrViewportIndexAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst); spv_result_t ValidateWorkgroupSizeAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst); spv_result_t ValidateClipOrCullDistanceAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst); // Used for GlobalInvocationId, LocalInvocationId, NumWorkgroups, WorkgroupId. spv_result_t ValidateComputeShaderI32Vec3InputAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst); // Validates that |built_in_inst| is not (even indirectly) referenced from // within a function which can be called with |execution_model|. // // |comment| - text explaining why the restriction was imposed. // |decoration| - BuiltIn decoration which causes the restriction. // |referenced_inst| - instruction which is dependent on |built_in_inst| and // defines the id which was referenced. // |referenced_from_inst| - instruction which references id defined by // |referenced_inst| from within a function. spv_result_t ValidateNotCalledWithExecutionModel( const char* comment, SpvExecutionModel execution_model, const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst); // The following section contains functions which check that the decorated // variable has the type specified in the function name. |diag| would be // called with a corresponding error message, if validation is not successful. spv_result_t ValidateBool( const Decoration& decoration, const Instruction& inst, const std::function& diag); spv_result_t ValidateI32( const Decoration& decoration, const Instruction& inst, const std::function& diag); spv_result_t ValidateI32Vec( const Decoration& decoration, const Instruction& inst, uint32_t num_components, const std::function& diag); spv_result_t ValidateI32Arr( const Decoration& decoration, const Instruction& inst, const std::function& diag); spv_result_t ValidateF32( const Decoration& decoration, const Instruction& inst, const std::function& diag); spv_result_t ValidateOptionalArrayedF32( const Decoration& decoration, const Instruction& inst, const std::function& diag); spv_result_t ValidateF32Helper( const Decoration& decoration, const Instruction& inst, const std::function& diag, uint32_t underlying_type); spv_result_t ValidateF32Vec( const Decoration& decoration, const Instruction& inst, uint32_t num_components, const std::function& diag); spv_result_t ValidateOptionalArrayedF32Vec( const Decoration& decoration, const Instruction& inst, uint32_t num_components, const std::function& diag); spv_result_t ValidateF32VecHelper( const Decoration& decoration, const Instruction& inst, uint32_t num_components, const std::function& diag, uint32_t underlying_type); // If |num_components| is zero, the number of components is not checked. spv_result_t ValidateF32Arr( const Decoration& decoration, const Instruction& inst, uint32_t num_components, const std::function& diag); spv_result_t ValidateOptionalArrayedF32Arr( const Decoration& decoration, const Instruction& inst, uint32_t num_components, const std::function& diag); spv_result_t ValidateF32ArrHelper( const Decoration& decoration, const Instruction& inst, uint32_t num_components, const std::function& diag, uint32_t underlying_type); // Generates strings like "Member #0 of struct ID <2>". std::string GetDefinitionDesc(const Decoration& decoration, const Instruction& inst) const; // Generates strings like "ID <51> (OpTypePointer) is referencing ID <2> // (OpTypeStruct) which is decorated with BuiltIn Position". std::string GetReferenceDesc( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst, SpvExecutionModel execution_model = SpvExecutionModelMax) const; // Generates strings like "ID <51> (OpTypePointer) uses storage class // UniformConstant". std::string GetStorageClassDesc(const Instruction& inst) const; // Updates inner working of the class. Is called sequentially for every // instruction. void Update(const Instruction& inst); const ValidationState_t& _; // Mapping id -> list of rules which validate instruction referencing the // id. Rules can create new rules and add them to this container. // Using std::map, and not std::unordered_map to avoid iterator invalidation // during rehashing. std::map>> id_to_at_reference_checks_; // Id of the function we are currently inside. 0 if not inside a function. uint32_t function_id_ = 0; // Entry points which can (indirectly) call the current function. // The pointer either points to a vector inside to function_to_entry_points_ // or to no_entry_points_. The pointer is guaranteed to never be null. const std::vector no_entry_points; const std::vector* entry_points_ = &no_entry_points; // Execution models with which the current function can be called. std::set execution_models_; }; void BuiltInsValidator::Update(const Instruction& inst) { const SpvOp opcode = inst.opcode(); if (opcode == SpvOpFunction) { // Entering a function. assert(function_id_ == 0); function_id_ = inst.id(); execution_models_.clear(); entry_points_ = &_.FunctionEntryPoints(function_id_); // Collect execution models from all entry points from which the current // function can be called. for (const uint32_t entry_point : *entry_points_) { if (const auto* models = _.GetExecutionModels(entry_point)) { execution_models_.insert(models->begin(), models->end()); } } } if (opcode == SpvOpFunctionEnd) { // Exiting a function. assert(function_id_ != 0); function_id_ = 0; entry_points_ = &no_entry_points; execution_models_.clear(); } } std::string BuiltInsValidator::GetDefinitionDesc( const Decoration& decoration, const Instruction& inst) const { std::ostringstream ss; if (decoration.struct_member_index() != Decoration::kInvalidMember) { assert(inst.opcode() == SpvOpTypeStruct); ss << "Member #" << decoration.struct_member_index(); ss << " of struct ID <" << inst.id() << ">"; } else { ss << GetIdDesc(inst); } return ss.str(); } std::string BuiltInsValidator::GetReferenceDesc( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst, SpvExecutionModel execution_model) const { std::ostringstream ss; ss << GetIdDesc(referenced_from_inst) << " is referencing " << GetIdDesc(referenced_inst); if (built_in_inst.id() != referenced_inst.id()) { ss << " which is dependent on " << GetIdDesc(built_in_inst); } ss << " which is decorated with BuiltIn "; ss << _.grammar().lookupOperandName(SPV_OPERAND_TYPE_BUILT_IN, decoration.params()[0]); if (function_id_) { ss << " in function <" << function_id_ << ">"; if (execution_model != SpvExecutionModelMax) { ss << " called with execution model "; ss << _.grammar().lookupOperandName(SPV_OPERAND_TYPE_EXECUTION_MODEL, execution_model); } } ss << "."; return ss.str(); } std::string BuiltInsValidator::GetStorageClassDesc( const Instruction& inst) const { std::ostringstream ss; ss << GetIdDesc(inst) << " uses storage class "; ss << _.grammar().lookupOperandName(SPV_OPERAND_TYPE_STORAGE_CLASS, GetStorageClass(inst)); ss << "."; return ss.str(); } spv_result_t BuiltInsValidator::ValidateBool( const Decoration& decoration, const Instruction& inst, const std::function& diag) { uint32_t underlying_type = 0; if (spv_result_t error = GetUnderlyingType(_, decoration, inst, &underlying_type)) { return error; } if (!_.IsBoolScalarType(underlying_type)) { return diag(GetDefinitionDesc(decoration, inst) + " is not a bool scalar."); } return SPV_SUCCESS; } spv_result_t BuiltInsValidator::ValidateI32( const Decoration& decoration, const Instruction& inst, const std::function& diag) { uint32_t underlying_type = 0; if (spv_result_t error = GetUnderlyingType(_, decoration, inst, &underlying_type)) { return error; } if (!_.IsIntScalarType(underlying_type)) { return diag(GetDefinitionDesc(decoration, inst) + " is not an int scalar."); } const uint32_t bit_width = _.GetBitWidth(underlying_type); if (bit_width != 32) { std::ostringstream ss; ss << GetDefinitionDesc(decoration, inst) << " has bit width " << bit_width << "."; return diag(ss.str()); } return SPV_SUCCESS; } spv_result_t BuiltInsValidator::ValidateOptionalArrayedF32( const Decoration& decoration, const Instruction& inst, const std::function& diag) { uint32_t underlying_type = 0; if (spv_result_t error = GetUnderlyingType(_, decoration, inst, &underlying_type)) { return error; } // Strip the array, if present. if (_.GetIdOpcode(underlying_type) == SpvOpTypeArray) { underlying_type = _.FindDef(underlying_type)->word(2u); } return ValidateF32Helper(decoration, inst, diag, underlying_type); } spv_result_t BuiltInsValidator::ValidateF32( const Decoration& decoration, const Instruction& inst, const std::function& diag) { uint32_t underlying_type = 0; if (spv_result_t error = GetUnderlyingType(_, decoration, inst, &underlying_type)) { return error; } return ValidateF32Helper(decoration, inst, diag, underlying_type); } spv_result_t BuiltInsValidator::ValidateF32Helper( const Decoration& decoration, const Instruction& inst, const std::function& diag, uint32_t underlying_type) { if (!_.IsFloatScalarType(underlying_type)) { return diag(GetDefinitionDesc(decoration, inst) + " is not a float scalar."); } const uint32_t bit_width = _.GetBitWidth(underlying_type); if (bit_width != 32) { std::ostringstream ss; ss << GetDefinitionDesc(decoration, inst) << " has bit width " << bit_width << "."; return diag(ss.str()); } return SPV_SUCCESS; } spv_result_t BuiltInsValidator::ValidateI32Vec( const Decoration& decoration, const Instruction& inst, uint32_t num_components, const std::function& diag) { uint32_t underlying_type = 0; if (spv_result_t error = GetUnderlyingType(_, decoration, inst, &underlying_type)) { return error; } if (!_.IsIntVectorType(underlying_type)) { return diag(GetDefinitionDesc(decoration, inst) + " is not an int vector."); } const uint32_t actual_num_components = _.GetDimension(underlying_type); if (_.GetDimension(underlying_type) != num_components) { std::ostringstream ss; ss << GetDefinitionDesc(decoration, inst) << " has " << actual_num_components << " components."; return diag(ss.str()); } const uint32_t bit_width = _.GetBitWidth(underlying_type); if (bit_width != 32) { std::ostringstream ss; ss << GetDefinitionDesc(decoration, inst) << " has components with bit width " << bit_width << "."; return diag(ss.str()); } return SPV_SUCCESS; } spv_result_t BuiltInsValidator::ValidateOptionalArrayedF32Vec( const Decoration& decoration, const Instruction& inst, uint32_t num_components, const std::function& diag) { uint32_t underlying_type = 0; if (spv_result_t error = GetUnderlyingType(_, decoration, inst, &underlying_type)) { return error; } // Strip the array, if present. if (_.GetIdOpcode(underlying_type) == SpvOpTypeArray) { underlying_type = _.FindDef(underlying_type)->word(2u); } return ValidateF32VecHelper(decoration, inst, num_components, diag, underlying_type); } spv_result_t BuiltInsValidator::ValidateF32Vec( const Decoration& decoration, const Instruction& inst, uint32_t num_components, const std::function& diag) { uint32_t underlying_type = 0; if (spv_result_t error = GetUnderlyingType(_, decoration, inst, &underlying_type)) { return error; } return ValidateF32VecHelper(decoration, inst, num_components, diag, underlying_type); } spv_result_t BuiltInsValidator::ValidateF32VecHelper( const Decoration& decoration, const Instruction& inst, uint32_t num_components, const std::function& diag, uint32_t underlying_type) { if (!_.IsFloatVectorType(underlying_type)) { return diag(GetDefinitionDesc(decoration, inst) + " is not a float vector."); } const uint32_t actual_num_components = _.GetDimension(underlying_type); if (_.GetDimension(underlying_type) != num_components) { std::ostringstream ss; ss << GetDefinitionDesc(decoration, inst) << " has " << actual_num_components << " components."; return diag(ss.str()); } const uint32_t bit_width = _.GetBitWidth(underlying_type); if (bit_width != 32) { std::ostringstream ss; ss << GetDefinitionDesc(decoration, inst) << " has components with bit width " << bit_width << "."; return diag(ss.str()); } return SPV_SUCCESS; } spv_result_t BuiltInsValidator::ValidateI32Arr( const Decoration& decoration, const Instruction& inst, const std::function& diag) { uint32_t underlying_type = 0; if (spv_result_t error = GetUnderlyingType(_, decoration, inst, &underlying_type)) { return error; } const Instruction* const type_inst = _.FindDef(underlying_type); if (type_inst->opcode() != SpvOpTypeArray) { return diag(GetDefinitionDesc(decoration, inst) + " is not an array."); } const uint32_t component_type = type_inst->word(2); if (!_.IsIntScalarType(component_type)) { return diag(GetDefinitionDesc(decoration, inst) + " components are not int scalar."); } const uint32_t bit_width = _.GetBitWidth(component_type); if (bit_width != 32) { std::ostringstream ss; ss << GetDefinitionDesc(decoration, inst) << " has components with bit width " << bit_width << "."; return diag(ss.str()); } return SPV_SUCCESS; } spv_result_t BuiltInsValidator::ValidateF32Arr( const Decoration& decoration, const Instruction& inst, uint32_t num_components, const std::function& diag) { uint32_t underlying_type = 0; if (spv_result_t error = GetUnderlyingType(_, decoration, inst, &underlying_type)) { return error; } return ValidateF32ArrHelper(decoration, inst, num_components, diag, underlying_type); } spv_result_t BuiltInsValidator::ValidateOptionalArrayedF32Arr( const Decoration& decoration, const Instruction& inst, uint32_t num_components, const std::function& diag) { uint32_t underlying_type = 0; if (spv_result_t error = GetUnderlyingType(_, decoration, inst, &underlying_type)) { return error; } // Strip an extra layer of arraying if present. if (_.GetIdOpcode(underlying_type) == SpvOpTypeArray) { uint32_t subtype = _.FindDef(underlying_type)->word(2u); if (_.GetIdOpcode(subtype) == SpvOpTypeArray) { underlying_type = subtype; } } return ValidateF32ArrHelper(decoration, inst, num_components, diag, underlying_type); } spv_result_t BuiltInsValidator::ValidateF32ArrHelper( const Decoration& decoration, const Instruction& inst, uint32_t num_components, const std::function& diag, uint32_t underlying_type) { const Instruction* const type_inst = _.FindDef(underlying_type); if (type_inst->opcode() != SpvOpTypeArray) { return diag(GetDefinitionDesc(decoration, inst) + " is not an array."); } const uint32_t component_type = type_inst->word(2); if (!_.IsFloatScalarType(component_type)) { return diag(GetDefinitionDesc(decoration, inst) + " components are not float scalar."); } const uint32_t bit_width = _.GetBitWidth(component_type); if (bit_width != 32) { std::ostringstream ss; ss << GetDefinitionDesc(decoration, inst) << " has components with bit width " << bit_width << "."; return diag(ss.str()); } if (num_components != 0) { uint64_t actual_num_components = 0; if (!_.GetConstantValUint64(type_inst->word(3), &actual_num_components)) { assert(0 && "Array type definition is corrupt"); } if (actual_num_components != num_components) { std::ostringstream ss; ss << GetDefinitionDesc(decoration, inst) << " has " << actual_num_components << " components."; return diag(ss.str()); } } return SPV_SUCCESS; } spv_result_t BuiltInsValidator::ValidateNotCalledWithExecutionModel( const char* comment, SpvExecutionModel execution_model, const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst) { if (function_id_) { if (execution_models_.count(execution_model)) { const char* execution_model_str = _.grammar().lookupOperandName( SPV_OPERAND_TYPE_EXECUTION_MODEL, execution_model); const char* built_in_str = _.grammar().lookupOperandName( SPV_OPERAND_TYPE_BUILT_IN, decoration.params()[0]); return _.diag(SPV_ERROR_INVALID_DATA) << comment << " " << GetIdDesc(referenced_inst) << " depends on " << GetIdDesc(built_in_inst) << " which is decorated with BuiltIn " << built_in_str << "." << " Id <" << referenced_inst.id() << "> is later referenced by " << GetIdDesc(referenced_from_inst) << " in function <" << function_id_ << "> which is called with execution model " << execution_model_str << "."; } } else { // Propagate this rule to all dependant ids in the global scope. id_to_at_reference_checks_[referenced_from_inst.id()].push_back( std::bind(&BuiltInsValidator::ValidateNotCalledWithExecutionModel, this, comment, execution_model, decoration, built_in_inst, referenced_from_inst, std::placeholders::_1)); } return SPV_SUCCESS; } spv_result_t BuiltInsValidator::ValidateClipOrCullDistanceAtDefinition( const Decoration& decoration, const Instruction& inst) { // Seed at reference checks with this built-in. return ValidateClipOrCullDistanceAtReference(decoration, inst, inst, inst); } spv_result_t BuiltInsValidator::ValidateClipOrCullDistanceAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst) { if (spvIsVulkanEnv(_.context()->target_env)) { const SpvStorageClass storage_class = GetStorageClass(referenced_from_inst); if (storage_class != SpvStorageClassMax && storage_class != SpvStorageClassInput && storage_class != SpvStorageClassOutput) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn " << _.grammar().lookupOperandName(SPV_OPERAND_TYPE_BUILT_IN, decoration.params()[0]) << " to be only used for variables with Input or Output storage " "class. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst) << " " << GetStorageClassDesc(referenced_from_inst); } if (storage_class == SpvStorageClassInput) { assert(function_id_ == 0); id_to_at_reference_checks_[referenced_from_inst.id()].push_back(std::bind( &BuiltInsValidator::ValidateNotCalledWithExecutionModel, this, "Vulkan spec doesn't allow BuiltIn ClipDistance/CullDistance to be " "used for variables with Input storage class if execution model is " "Vertex.", SpvExecutionModelVertex, decoration, built_in_inst, referenced_from_inst, std::placeholders::_1)); } if (storage_class == SpvStorageClassOutput) { assert(function_id_ == 0); id_to_at_reference_checks_[referenced_from_inst.id()].push_back(std::bind( &BuiltInsValidator::ValidateNotCalledWithExecutionModel, this, "Vulkan spec doesn't allow BuiltIn ClipDistance/CullDistance to be " "used for variables with Output storage class if execution model is " "Fragment.", SpvExecutionModelFragment, decoration, built_in_inst, referenced_from_inst, std::placeholders::_1)); } for (const SpvExecutionModel execution_model : execution_models_) { switch (execution_model) { case SpvExecutionModelFragment: case SpvExecutionModelVertex: { if (spv_result_t error = ValidateF32Arr( decoration, built_in_inst, /* Any number of components */ 0, [this, &decoration](const std::string& message) -> spv_result_t { return _.diag(SPV_ERROR_INVALID_DATA) << "According to the Vulkan spec BuiltIn " << _.grammar().lookupOperandName( SPV_OPERAND_TYPE_BUILT_IN, decoration.params()[0]) << " variable needs to be a 32-bit float array. " << message; })) { return error; } break; } case SpvExecutionModelTessellationControl: case SpvExecutionModelTessellationEvaluation: case SpvExecutionModelGeometry: { if (decoration.struct_member_index() != Decoration::kInvalidMember) { // The outer level of array is applied on the variable. if (spv_result_t error = ValidateF32Arr( decoration, built_in_inst, /* Any number of components */ 0, [this, &decoration](const std::string& message) -> spv_result_t { return _.diag(SPV_ERROR_INVALID_DATA) << "According to the Vulkan spec BuiltIn " << _.grammar().lookupOperandName( SPV_OPERAND_TYPE_BUILT_IN, decoration.params()[0]) << " variable needs to be a 32-bit float array. " << message; })) { return error; } } else { if (spv_result_t error = ValidateOptionalArrayedF32Arr( decoration, built_in_inst, /* Any number of components */ 0, [this, &decoration](const std::string& message) -> spv_result_t { return _.diag(SPV_ERROR_INVALID_DATA) << "According to the Vulkan spec BuiltIn " << _.grammar().lookupOperandName( SPV_OPERAND_TYPE_BUILT_IN, decoration.params()[0]) << " variable needs to be a 32-bit float array. " << message; })) { return error; } } break; } default: { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn " << _.grammar().lookupOperandName(SPV_OPERAND_TYPE_BUILT_IN, decoration.params()[0]) << " to be used only with Fragment, Vertex, " "TessellationControl, TessellationEvaluation or Geometry " "execution models. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst, execution_model); } } } } if (function_id_ == 0) { // Propagate this rule to all dependant ids in the global scope. id_to_at_reference_checks_[referenced_from_inst.id()].push_back( std::bind(&BuiltInsValidator::ValidateClipOrCullDistanceAtReference, this, decoration, built_in_inst, referenced_from_inst, std::placeholders::_1)); } return SPV_SUCCESS; } spv_result_t BuiltInsValidator::ValidateFragCoordAtDefinition( const Decoration& decoration, const Instruction& inst) { if (spvIsVulkanEnv(_.context()->target_env)) { if (spv_result_t error = ValidateF32Vec( decoration, inst, 4, [this](const std::string& message) -> spv_result_t { return _.diag(SPV_ERROR_INVALID_DATA) << "According to the Vulkan spec BuiltIn FragCoord " "variable needs to be a 4-component 32-bit float " "vector. " << message; })) { return error; } } // Seed at reference checks with this built-in. return ValidateFragCoordAtReference(decoration, inst, inst, inst); } spv_result_t BuiltInsValidator::ValidateFragCoordAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst) { if (spvIsVulkanEnv(_.context()->target_env)) { const SpvStorageClass storage_class = GetStorageClass(referenced_from_inst); if (storage_class != SpvStorageClassMax && storage_class != SpvStorageClassInput) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn FragCoord to be only used for " "variables with Input storage class. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst) << " " << GetStorageClassDesc(referenced_from_inst); } for (const SpvExecutionModel execution_model : execution_models_) { if (execution_model != SpvExecutionModelFragment) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn FragCoord to be used only with " "Fragment execution model. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst, execution_model); } } } if (function_id_ == 0) { // Propagate this rule to all dependant ids in the global scope. id_to_at_reference_checks_[referenced_from_inst.id()].push_back(std::bind( &BuiltInsValidator::ValidateFragCoordAtReference, this, decoration, built_in_inst, referenced_from_inst, std::placeholders::_1)); } return SPV_SUCCESS; } spv_result_t BuiltInsValidator::ValidateFragDepthAtDefinition( const Decoration& decoration, const Instruction& inst) { if (spvIsVulkanEnv(_.context()->target_env)) { if (spv_result_t error = ValidateF32( decoration, inst, [this](const std::string& message) -> spv_result_t { return _.diag(SPV_ERROR_INVALID_DATA) << "According to the Vulkan spec BuiltIn FragDepth " "variable needs to be a 32-bit float scalar. " << message; })) { return error; } } // Seed at reference checks with this built-in. return ValidateFragDepthAtReference(decoration, inst, inst, inst); } spv_result_t BuiltInsValidator::ValidateFragDepthAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst) { if (spvIsVulkanEnv(_.context()->target_env)) { const SpvStorageClass storage_class = GetStorageClass(referenced_from_inst); if (storage_class != SpvStorageClassMax && storage_class != SpvStorageClassOutput) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn FragDepth to be only used for " "variables with Output storage class. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst) << " " << GetStorageClassDesc(referenced_from_inst); } for (const SpvExecutionModel execution_model : execution_models_) { if (execution_model != SpvExecutionModelFragment) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn FragDepth to be used only with " "Fragment execution model. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst, execution_model); } } for (const uint32_t entry_point : *entry_points_) { // Every entry point from which this function is called needs to have // Execution Mode DepthReplacing. const auto* modes = _.GetExecutionModes(entry_point); if (!modes || !modes->count(SpvExecutionModeDepthReplacing)) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec requires DepthReplacing execution mode to be " "declared when using BuiltIn FragDepth. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst); } } } if (function_id_ == 0) { // Propagate this rule to all dependant ids in the global scope. id_to_at_reference_checks_[referenced_from_inst.id()].push_back(std::bind( &BuiltInsValidator::ValidateFragDepthAtReference, this, decoration, built_in_inst, referenced_from_inst, std::placeholders::_1)); } return SPV_SUCCESS; } spv_result_t BuiltInsValidator::ValidateFrontFacingAtDefinition( const Decoration& decoration, const Instruction& inst) { if (spvIsVulkanEnv(_.context()->target_env)) { if (spv_result_t error = ValidateBool( decoration, inst, [this](const std::string& message) -> spv_result_t { return _.diag(SPV_ERROR_INVALID_DATA) << "According to the Vulkan spec BuiltIn FrontFacing " "variable needs to be a bool scalar. " << message; })) { return error; } } // Seed at reference checks with this built-in. return ValidateFrontFacingAtReference(decoration, inst, inst, inst); } spv_result_t BuiltInsValidator::ValidateFrontFacingAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst) { if (spvIsVulkanEnv(_.context()->target_env)) { const SpvStorageClass storage_class = GetStorageClass(referenced_from_inst); if (storage_class != SpvStorageClassMax && storage_class != SpvStorageClassInput) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn FrontFacing to be only used for " "variables with Input storage class. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst) << " " << GetStorageClassDesc(referenced_from_inst); } for (const SpvExecutionModel execution_model : execution_models_) { if (execution_model != SpvExecutionModelFragment) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn FrontFacing to be used only with " "Fragment execution model. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst, execution_model); } } } if (function_id_ == 0) { // Propagate this rule to all dependant ids in the global scope. id_to_at_reference_checks_[referenced_from_inst.id()].push_back(std::bind( &BuiltInsValidator::ValidateFrontFacingAtReference, this, decoration, built_in_inst, referenced_from_inst, std::placeholders::_1)); } return SPV_SUCCESS; } spv_result_t BuiltInsValidator::ValidateHelperInvocationAtDefinition( const Decoration& decoration, const Instruction& inst) { if (spvIsVulkanEnv(_.context()->target_env)) { if (spv_result_t error = ValidateBool( decoration, inst, [this](const std::string& message) -> spv_result_t { return _.diag(SPV_ERROR_INVALID_DATA) << "According to the Vulkan spec BuiltIn HelperInvocation " "variable needs to be a bool scalar. " << message; })) { return error; } } // Seed at reference checks with this built-in. return ValidateHelperInvocationAtReference(decoration, inst, inst, inst); } spv_result_t BuiltInsValidator::ValidateHelperInvocationAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst) { if (spvIsVulkanEnv(_.context()->target_env)) { const SpvStorageClass storage_class = GetStorageClass(referenced_from_inst); if (storage_class != SpvStorageClassMax && storage_class != SpvStorageClassInput) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn HelperInvocation to be only used " "for variables with Input storage class. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst) << " " << GetStorageClassDesc(referenced_from_inst); } for (const SpvExecutionModel execution_model : execution_models_) { if (execution_model != SpvExecutionModelFragment) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn HelperInvocation to be used only " "with Fragment execution model. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst, execution_model); } } } if (function_id_ == 0) { // Propagate this rule to all dependant ids in the global scope. id_to_at_reference_checks_[referenced_from_inst.id()].push_back( std::bind(&BuiltInsValidator::ValidateHelperInvocationAtReference, this, decoration, built_in_inst, referenced_from_inst, std::placeholders::_1)); } return SPV_SUCCESS; } spv_result_t BuiltInsValidator::ValidateInvocationIdAtDefinition( const Decoration& decoration, const Instruction& inst) { if (spvIsVulkanEnv(_.context()->target_env)) { if (spv_result_t error = ValidateI32( decoration, inst, [this](const std::string& message) -> spv_result_t { return _.diag(SPV_ERROR_INVALID_DATA) << "According to the Vulkan spec BuiltIn InvocationId " "variable needs to be a 32-bit int scalar. " << message; })) { return error; } } // Seed at reference checks with this built-in. return ValidateInvocationIdAtReference(decoration, inst, inst, inst); } spv_result_t BuiltInsValidator::ValidateInvocationIdAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst) { if (spvIsVulkanEnv(_.context()->target_env)) { const SpvStorageClass storage_class = GetStorageClass(referenced_from_inst); if (storage_class != SpvStorageClassMax && storage_class != SpvStorageClassInput) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn InvocationId to be only used for " "variables with Input storage class. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst) << " " << GetStorageClassDesc(referenced_from_inst); } for (const SpvExecutionModel execution_model : execution_models_) { if (execution_model != SpvExecutionModelTessellationControl && execution_model != SpvExecutionModelGeometry) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn InvocationId to be used only " "with TessellationControl or Geometry execution models. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst, execution_model); } } } if (function_id_ == 0) { // Propagate this rule to all dependant ids in the global scope. id_to_at_reference_checks_[referenced_from_inst.id()].push_back(std::bind( &BuiltInsValidator::ValidateInvocationIdAtReference, this, decoration, built_in_inst, referenced_from_inst, std::placeholders::_1)); } return SPV_SUCCESS; } spv_result_t BuiltInsValidator::ValidateInstanceIndexAtDefinition( const Decoration& decoration, const Instruction& inst) { if (spvIsVulkanEnv(_.context()->target_env)) { if (spv_result_t error = ValidateI32( decoration, inst, [this](const std::string& message) -> spv_result_t { return _.diag(SPV_ERROR_INVALID_DATA) << "According to the Vulkan spec BuiltIn InstanceIndex " "variable needs to be a 32-bit int scalar. " << message; })) { return error; } } // Seed at reference checks with this built-in. return ValidateInstanceIndexAtReference(decoration, inst, inst, inst); } spv_result_t BuiltInsValidator::ValidateInstanceIndexAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst) { if (spvIsVulkanEnv(_.context()->target_env)) { const SpvStorageClass storage_class = GetStorageClass(referenced_from_inst); if (storage_class != SpvStorageClassMax && storage_class != SpvStorageClassInput) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn InstanceIndex to be only used for " "variables with Input storage class. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst) << " " << GetStorageClassDesc(referenced_from_inst); } for (const SpvExecutionModel execution_model : execution_models_) { if (execution_model != SpvExecutionModelVertex) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn InstanceIndex to be used only " "with Vertex execution model. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst, execution_model); } } } if (function_id_ == 0) { // Propagate this rule to all dependant ids in the global scope. id_to_at_reference_checks_[referenced_from_inst.id()].push_back(std::bind( &BuiltInsValidator::ValidateInstanceIndexAtReference, this, decoration, built_in_inst, referenced_from_inst, std::placeholders::_1)); } return SPV_SUCCESS; } spv_result_t BuiltInsValidator::ValidatePatchVerticesAtDefinition( const Decoration& decoration, const Instruction& inst) { if (spvIsVulkanEnv(_.context()->target_env)) { if (spv_result_t error = ValidateI32( decoration, inst, [this](const std::string& message) -> spv_result_t { return _.diag(SPV_ERROR_INVALID_DATA) << "According to the Vulkan spec BuiltIn PatchVertices " "variable needs to be a 32-bit int scalar. " << message; })) { return error; } } // Seed at reference checks with this built-in. return ValidatePatchVerticesAtReference(decoration, inst, inst, inst); } spv_result_t BuiltInsValidator::ValidatePatchVerticesAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst) { if (spvIsVulkanEnv(_.context()->target_env)) { const SpvStorageClass storage_class = GetStorageClass(referenced_from_inst); if (storage_class != SpvStorageClassMax && storage_class != SpvStorageClassInput) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn PatchVertices to be only used for " "variables with Input storage class. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst) << " " << GetStorageClassDesc(referenced_from_inst); } for (const SpvExecutionModel execution_model : execution_models_) { if (execution_model != SpvExecutionModelTessellationControl && execution_model != SpvExecutionModelTessellationEvaluation) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn PatchVertices to be used only " "with TessellationControl or TessellationEvaluation " "execution models. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst, execution_model); } } } if (function_id_ == 0) { // Propagate this rule to all dependant ids in the global scope. id_to_at_reference_checks_[referenced_from_inst.id()].push_back(std::bind( &BuiltInsValidator::ValidatePatchVerticesAtReference, this, decoration, built_in_inst, referenced_from_inst, std::placeholders::_1)); } return SPV_SUCCESS; } spv_result_t BuiltInsValidator::ValidatePointCoordAtDefinition( const Decoration& decoration, const Instruction& inst) { if (spvIsVulkanEnv(_.context()->target_env)) { if (spv_result_t error = ValidateF32Vec( decoration, inst, 2, [this](const std::string& message) -> spv_result_t { return _.diag(SPV_ERROR_INVALID_DATA) << "According to the Vulkan spec BuiltIn PointCoord " "variable needs to be a 2-component 32-bit float " "vector. " << message; })) { return error; } } // Seed at reference checks with this built-in. return ValidatePointCoordAtReference(decoration, inst, inst, inst); } spv_result_t BuiltInsValidator::ValidatePointCoordAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst) { if (spvIsVulkanEnv(_.context()->target_env)) { const SpvStorageClass storage_class = GetStorageClass(referenced_from_inst); if (storage_class != SpvStorageClassMax && storage_class != SpvStorageClassInput) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn PointCoord to be only used for " "variables with Input storage class. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst) << " " << GetStorageClassDesc(referenced_from_inst); } for (const SpvExecutionModel execution_model : execution_models_) { if (execution_model != SpvExecutionModelFragment) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn PointCoord to be used only with " "Fragment execution model. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst, execution_model); } } } if (function_id_ == 0) { // Propagate this rule to all dependant ids in the global scope. id_to_at_reference_checks_[referenced_from_inst.id()].push_back(std::bind( &BuiltInsValidator::ValidatePointCoordAtReference, this, decoration, built_in_inst, referenced_from_inst, std::placeholders::_1)); } return SPV_SUCCESS; } spv_result_t BuiltInsValidator::ValidatePointSizeAtDefinition( const Decoration& decoration, const Instruction& inst) { // Seed at reference checks with this built-in. return ValidatePointSizeAtReference(decoration, inst, inst, inst); } spv_result_t BuiltInsValidator::ValidatePointSizeAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst) { if (spvIsVulkanEnv(_.context()->target_env)) { const SpvStorageClass storage_class = GetStorageClass(referenced_from_inst); if (storage_class != SpvStorageClassMax && storage_class != SpvStorageClassInput && storage_class != SpvStorageClassOutput) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn PointSize to be only used for " "variables with Input or Output storage class. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst) << " " << GetStorageClassDesc(referenced_from_inst); } if (storage_class == SpvStorageClassInput) { assert(function_id_ == 0); id_to_at_reference_checks_[referenced_from_inst.id()].push_back(std::bind( &BuiltInsValidator::ValidateNotCalledWithExecutionModel, this, "Vulkan spec doesn't allow BuiltIn PointSize to be used for " "variables with Input storage class if execution model is Vertex.", SpvExecutionModelVertex, decoration, built_in_inst, referenced_from_inst, std::placeholders::_1)); } for (const SpvExecutionModel execution_model : execution_models_) { switch (execution_model) { case SpvExecutionModelVertex: { if (spv_result_t error = ValidateF32( decoration, built_in_inst, [this](const std::string& message) -> spv_result_t { return _.diag(SPV_ERROR_INVALID_DATA) << "According to the Vulkan spec BuiltIn PointSize " "variable needs to be a 32-bit float scalar. " << message; })) { return error; } break; } case SpvExecutionModelTessellationControl: case SpvExecutionModelTessellationEvaluation: case SpvExecutionModelGeometry: { // PointSize can be a per-vertex variable for tessellation control, // tessellation evaluation and geometry shader stages. In such cases // variables will have an array of 32-bit floats. if (decoration.struct_member_index() != Decoration::kInvalidMember) { // The array is on the variable, so this must be a 32-bit float. if (spv_result_t error = ValidateF32( decoration, built_in_inst, [this](const std::string& message) -> spv_result_t { return _.diag(SPV_ERROR_INVALID_DATA) << "According to the Vulkan spec BuiltIn " "PointSize " "variable needs to be a 32-bit float scalar. " << message; })) { return error; } } else { if (spv_result_t error = ValidateOptionalArrayedF32( decoration, built_in_inst, [this](const std::string& message) -> spv_result_t { return _.diag(SPV_ERROR_INVALID_DATA) << "According to the Vulkan spec BuiltIn " "PointSize " "variable needs to be a 32-bit float scalar. " << message; })) { return error; } } break; } default: { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn PointSize to be used only with " "Vertex, TessellationControl, TessellationEvaluation or " "Geometry execution models. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst, execution_model); } } } } if (function_id_ == 0) { // Propagate this rule to all dependant ids in the global scope. id_to_at_reference_checks_[referenced_from_inst.id()].push_back(std::bind( &BuiltInsValidator::ValidatePointSizeAtReference, this, decoration, built_in_inst, referenced_from_inst, std::placeholders::_1)); } return SPV_SUCCESS; } spv_result_t BuiltInsValidator::ValidatePositionAtDefinition( const Decoration& decoration, const Instruction& inst) { // Seed at reference checks with this built-in. return ValidatePositionAtReference(decoration, inst, inst, inst); } spv_result_t BuiltInsValidator::ValidatePositionAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst) { if (spvIsVulkanEnv(_.context()->target_env)) { const SpvStorageClass storage_class = GetStorageClass(referenced_from_inst); if (storage_class != SpvStorageClassMax && storage_class != SpvStorageClassInput && storage_class != SpvStorageClassOutput) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn Position to be only used for " "variables with Input or Output storage class. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst) << " " << GetStorageClassDesc(referenced_from_inst); } if (storage_class == SpvStorageClassInput) { assert(function_id_ == 0); id_to_at_reference_checks_[referenced_from_inst.id()].push_back(std::bind( &BuiltInsValidator::ValidateNotCalledWithExecutionModel, this, "Vulkan spec doesn't allow BuiltIn Position to be used for variables " "with Input storage class if execution model is Vertex.", SpvExecutionModelVertex, decoration, built_in_inst, referenced_from_inst, std::placeholders::_1)); } for (const SpvExecutionModel execution_model : execution_models_) { switch (execution_model) { case SpvExecutionModelVertex: { if (spv_result_t error = ValidateF32Vec( decoration, built_in_inst, 4, [this](const std::string& message) -> spv_result_t { return _.diag(SPV_ERROR_INVALID_DATA) << "According to the Vulkan spec BuiltIn Position " "variable needs to be a 4-component 32-bit float " "vector. " << message; })) { return error; } break; } case SpvExecutionModelGeometry: case SpvExecutionModelTessellationControl: case SpvExecutionModelTessellationEvaluation: { // Position can be a per-vertex variable for tessellation control, // tessellation evaluation and geometry shader stages. In such cases // variables will have an array of 4-component 32-bit float vectors. if (decoration.struct_member_index() != Decoration::kInvalidMember) { // The array is on the variable, so this must be a 4-component // 32-bit float vector. if (spv_result_t error = ValidateF32Vec( decoration, built_in_inst, 4, [this](const std::string& message) -> spv_result_t { return _.diag(SPV_ERROR_INVALID_DATA) << "According to the Vulkan spec BuiltIn Position " "variable needs to be a 4-component 32-bit " "float vector. " << message; })) { return error; } } else { if (spv_result_t error = ValidateOptionalArrayedF32Vec( decoration, built_in_inst, 4, [this](const std::string& message) -> spv_result_t { return _.diag(SPV_ERROR_INVALID_DATA) << "According to the Vulkan spec BuiltIn Position " "variable needs to be a 4-component 32-bit " "float vector. " << message; })) { return error; } } break; } default: { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn Position to be used only " "with Vertex, TessellationControl, TessellationEvaluation" " or Geometry execution models. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst, execution_model); } } } } if (function_id_ == 0) { // Propagate this rule to all dependant ids in the global scope. id_to_at_reference_checks_[referenced_from_inst.id()].push_back(std::bind( &BuiltInsValidator::ValidatePositionAtReference, this, decoration, built_in_inst, referenced_from_inst, std::placeholders::_1)); } return SPV_SUCCESS; } spv_result_t BuiltInsValidator::ValidatePrimitiveIdAtDefinition( const Decoration& decoration, const Instruction& inst) { if (spvIsVulkanEnv(_.context()->target_env)) { if (spv_result_t error = ValidateI32( decoration, inst, [this](const std::string& message) -> spv_result_t { return _.diag(SPV_ERROR_INVALID_DATA) << "According to the Vulkan spec BuiltIn PrimitiveId " "variable needs to be a 32-bit int scalar. " << message; })) { return error; } } // Seed at reference checks with this built-in. return ValidatePrimitiveIdAtReference(decoration, inst, inst, inst); } spv_result_t BuiltInsValidator::ValidatePrimitiveIdAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst) { if (spvIsVulkanEnv(_.context()->target_env)) { const SpvStorageClass storage_class = GetStorageClass(referenced_from_inst); if (storage_class != SpvStorageClassMax && storage_class != SpvStorageClassInput && storage_class != SpvStorageClassOutput) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn PrimitiveId to be only used for " "variables with Input or Output storage class. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst) << " " << GetStorageClassDesc(referenced_from_inst); } if (storage_class == SpvStorageClassOutput) { assert(function_id_ == 0); id_to_at_reference_checks_[referenced_from_inst.id()].push_back(std::bind( &BuiltInsValidator::ValidateNotCalledWithExecutionModel, this, "Vulkan spec doesn't allow BuiltIn PrimitiveId to be used for " "variables with Output storage class if execution model is " "TessellationControl.", SpvExecutionModelTessellationControl, decoration, built_in_inst, referenced_from_inst, std::placeholders::_1)); id_to_at_reference_checks_[referenced_from_inst.id()].push_back(std::bind( &BuiltInsValidator::ValidateNotCalledWithExecutionModel, this, "Vulkan spec doesn't allow BuiltIn PrimitiveId to be used for " "variables with Output storage class if execution model is " "TessellationEvaluation.", SpvExecutionModelTessellationEvaluation, decoration, built_in_inst, referenced_from_inst, std::placeholders::_1)); id_to_at_reference_checks_[referenced_from_inst.id()].push_back(std::bind( &BuiltInsValidator::ValidateNotCalledWithExecutionModel, this, "Vulkan spec doesn't allow BuiltIn PrimitiveId to be used for " "variables with Output storage class if execution model is " "Fragment.", SpvExecutionModelFragment, decoration, built_in_inst, referenced_from_inst, std::placeholders::_1)); } for (const SpvExecutionModel execution_model : execution_models_) { switch (execution_model) { case SpvExecutionModelFragment: case SpvExecutionModelTessellationControl: case SpvExecutionModelTessellationEvaluation: case SpvExecutionModelGeometry: { // Ok. break; } default: { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn PrimitiveId to be used only " "with Fragment, TessellationControl, " "TessellationEvaluation or Geometry execution models. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst, execution_model); } } } } if (function_id_ == 0) { // Propagate this rule to all dependant ids in the global scope. id_to_at_reference_checks_[referenced_from_inst.id()].push_back(std::bind( &BuiltInsValidator::ValidatePrimitiveIdAtReference, this, decoration, built_in_inst, referenced_from_inst, std::placeholders::_1)); } return SPV_SUCCESS; } spv_result_t BuiltInsValidator::ValidateSampleIdAtDefinition( const Decoration& decoration, const Instruction& inst) { if (spvIsVulkanEnv(_.context()->target_env)) { if (spv_result_t error = ValidateI32( decoration, inst, [this](const std::string& message) -> spv_result_t { return _.diag(SPV_ERROR_INVALID_DATA) << "According to the Vulkan spec BuiltIn SampleId " "variable needs to be a 32-bit int scalar. " << message; })) { return error; } } // Seed at reference checks with this built-in. return ValidateSampleIdAtReference(decoration, inst, inst, inst); } spv_result_t BuiltInsValidator::ValidateSampleIdAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst) { if (spvIsVulkanEnv(_.context()->target_env)) { const SpvStorageClass storage_class = GetStorageClass(referenced_from_inst); if (storage_class != SpvStorageClassMax && storage_class != SpvStorageClassInput) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn SampleId to be only used for " "variables with Input storage class. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst) << " " << GetStorageClassDesc(referenced_from_inst); } for (const SpvExecutionModel execution_model : execution_models_) { if (execution_model != SpvExecutionModelFragment) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn SampleId to be used only with " "Fragment execution model. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst, execution_model); } } } if (function_id_ == 0) { // Propagate this rule to all dependant ids in the global scope. id_to_at_reference_checks_[referenced_from_inst.id()].push_back(std::bind( &BuiltInsValidator::ValidateSampleIdAtReference, this, decoration, built_in_inst, referenced_from_inst, std::placeholders::_1)); } return SPV_SUCCESS; } spv_result_t BuiltInsValidator::ValidateSampleMaskAtDefinition( const Decoration& decoration, const Instruction& inst) { if (spvIsVulkanEnv(_.context()->target_env)) { if (spv_result_t error = ValidateI32Arr( decoration, inst, [this](const std::string& message) -> spv_result_t { return _.diag(SPV_ERROR_INVALID_DATA) << "According to the Vulkan spec BuiltIn SampleMask " "variable needs to be a 32-bit int array. " << message; })) { return error; } } // Seed at reference checks with this built-in. return ValidateSampleMaskAtReference(decoration, inst, inst, inst); } spv_result_t BuiltInsValidator::ValidateSampleMaskAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst) { if (spvIsVulkanEnv(_.context()->target_env)) { const SpvStorageClass storage_class = GetStorageClass(referenced_from_inst); if (storage_class != SpvStorageClassMax && storage_class != SpvStorageClassInput && storage_class != SpvStorageClassOutput) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn SampleMask to be only used for " "variables with Input or Output storage class. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst) << " " << GetStorageClassDesc(referenced_from_inst); } for (const SpvExecutionModel execution_model : execution_models_) { if (execution_model != SpvExecutionModelFragment) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn SampleMask to be used only " "with " "Fragment execution model. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst, execution_model); } } } if (function_id_ == 0) { // Propagate this rule to all dependant ids in the global scope. id_to_at_reference_checks_[referenced_from_inst.id()].push_back(std::bind( &BuiltInsValidator::ValidateSampleMaskAtReference, this, decoration, built_in_inst, referenced_from_inst, std::placeholders::_1)); } return SPV_SUCCESS; } spv_result_t BuiltInsValidator::ValidateSamplePositionAtDefinition( const Decoration& decoration, const Instruction& inst) { if (spvIsVulkanEnv(_.context()->target_env)) { if (spv_result_t error = ValidateF32Vec( decoration, inst, 2, [this](const std::string& message) -> spv_result_t { return _.diag(SPV_ERROR_INVALID_DATA) << "According to the Vulkan spec BuiltIn SamplePosition " "variable needs to be a 2-component 32-bit float " "vector. " << message; })) { return error; } } // Seed at reference checks with this built-in. return ValidateSamplePositionAtReference(decoration, inst, inst, inst); } spv_result_t BuiltInsValidator::ValidateSamplePositionAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst) { if (spvIsVulkanEnv(_.context()->target_env)) { const SpvStorageClass storage_class = GetStorageClass(referenced_from_inst); if (storage_class != SpvStorageClassMax && storage_class != SpvStorageClassInput) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn SamplePosition to be only used " "for " "variables with Input storage class. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst) << " " << GetStorageClassDesc(referenced_from_inst); } for (const SpvExecutionModel execution_model : execution_models_) { if (execution_model != SpvExecutionModelFragment) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn SamplePosition to be used only " "with " "Fragment execution model. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst, execution_model); } } } if (function_id_ == 0) { // Propagate this rule to all dependant ids in the global scope. id_to_at_reference_checks_[referenced_from_inst.id()].push_back(std::bind( &BuiltInsValidator::ValidateSamplePositionAtReference, this, decoration, built_in_inst, referenced_from_inst, std::placeholders::_1)); } return SPV_SUCCESS; } spv_result_t BuiltInsValidator::ValidateTessCoordAtDefinition( const Decoration& decoration, const Instruction& inst) { if (spvIsVulkanEnv(_.context()->target_env)) { if (spv_result_t error = ValidateF32Vec( decoration, inst, 3, [this](const std::string& message) -> spv_result_t { return _.diag(SPV_ERROR_INVALID_DATA) << "According to the Vulkan spec BuiltIn TessCoord " "variable needs to be a 3-component 32-bit float " "vector. " << message; })) { return error; } } // Seed at reference checks with this built-in. return ValidateTessCoordAtReference(decoration, inst, inst, inst); } spv_result_t BuiltInsValidator::ValidateTessCoordAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst) { if (spvIsVulkanEnv(_.context()->target_env)) { const SpvStorageClass storage_class = GetStorageClass(referenced_from_inst); if (storage_class != SpvStorageClassMax && storage_class != SpvStorageClassInput) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn TessCoord to be only used for " "variables with Input storage class. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst) << " " << GetStorageClassDesc(referenced_from_inst); } for (const SpvExecutionModel execution_model : execution_models_) { if (execution_model != SpvExecutionModelTessellationEvaluation) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn TessCoord to be used only with " "TessellationEvaluation execution model. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst, execution_model); } } } if (function_id_ == 0) { // Propagate this rule to all dependant ids in the global scope. id_to_at_reference_checks_[referenced_from_inst.id()].push_back(std::bind( &BuiltInsValidator::ValidateTessCoordAtReference, this, decoration, built_in_inst, referenced_from_inst, std::placeholders::_1)); } return SPV_SUCCESS; } spv_result_t BuiltInsValidator::ValidateTessLevelOuterAtDefinition( const Decoration& decoration, const Instruction& inst) { if (spvIsVulkanEnv(_.context()->target_env)) { if (spv_result_t error = ValidateF32Arr( decoration, inst, 4, [this](const std::string& message) -> spv_result_t { return _.diag(SPV_ERROR_INVALID_DATA) << "According to the Vulkan spec BuiltIn TessLevelOuter " "variable needs to be a 4-component 32-bit float " "array. " << message; })) { return error; } } // Seed at reference checks with this built-in. return ValidateTessLevelAtReference(decoration, inst, inst, inst); } spv_result_t BuiltInsValidator::ValidateTessLevelInnerAtDefinition( const Decoration& decoration, const Instruction& inst) { if (spvIsVulkanEnv(_.context()->target_env)) { if (spv_result_t error = ValidateF32Arr( decoration, inst, 2, [this](const std::string& message) -> spv_result_t { return _.diag(SPV_ERROR_INVALID_DATA) << "According to the Vulkan spec BuiltIn TessLevelOuter " "variable needs to be a 2-component 32-bit float " "array. " << message; })) { return error; } } // Seed at reference checks with this built-in. return ValidateTessLevelAtReference(decoration, inst, inst, inst); } spv_result_t BuiltInsValidator::ValidateTessLevelAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst) { if (spvIsVulkanEnv(_.context()->target_env)) { const SpvStorageClass storage_class = GetStorageClass(referenced_from_inst); if (storage_class != SpvStorageClassMax && storage_class != SpvStorageClassInput && storage_class != SpvStorageClassOutput) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn " << _.grammar().lookupOperandName(SPV_OPERAND_TYPE_BUILT_IN, decoration.params()[0]) << " to be only used for variables with Input or Output storage " "class. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst) << " " << GetStorageClassDesc(referenced_from_inst); } if (storage_class == SpvStorageClassInput) { assert(function_id_ == 0); id_to_at_reference_checks_[referenced_from_inst.id()].push_back(std::bind( &BuiltInsValidator::ValidateNotCalledWithExecutionModel, this, "Vulkan spec doesn't allow TessLevelOuter/TessLevelInner to be " "used " "for variables with Input storage class if execution model is " "TessellationControl.", SpvExecutionModelTessellationControl, decoration, built_in_inst, referenced_from_inst, std::placeholders::_1)); } if (storage_class == SpvStorageClassOutput) { assert(function_id_ == 0); id_to_at_reference_checks_[referenced_from_inst.id()].push_back(std::bind( &BuiltInsValidator::ValidateNotCalledWithExecutionModel, this, "Vulkan spec doesn't allow TessLevelOuter/TessLevelInner to be " "used " "for variables with Output storage class if execution model is " "TessellationEvaluation.", SpvExecutionModelTessellationEvaluation, decoration, built_in_inst, referenced_from_inst, std::placeholders::_1)); } for (const SpvExecutionModel execution_model : execution_models_) { switch (execution_model) { case SpvExecutionModelTessellationControl: case SpvExecutionModelTessellationEvaluation: { // Ok. break; } default: { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn " << _.grammar().lookupOperandName(SPV_OPERAND_TYPE_BUILT_IN, decoration.params()[0]) << " to be used only with TessellationControl or " "TessellationEvaluation execution models. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst, execution_model); } } } } if (function_id_ == 0) { // Propagate this rule to all dependant ids in the global scope. id_to_at_reference_checks_[referenced_from_inst.id()].push_back(std::bind( &BuiltInsValidator::ValidateTessLevelAtReference, this, decoration, built_in_inst, referenced_from_inst, std::placeholders::_1)); } return SPV_SUCCESS; } spv_result_t BuiltInsValidator::ValidateVertexIndexAtDefinition( const Decoration& decoration, const Instruction& inst) { if (spvIsVulkanEnv(_.context()->target_env)) { if (spv_result_t error = ValidateI32( decoration, inst, [this](const std::string& message) -> spv_result_t { return _.diag(SPV_ERROR_INVALID_DATA) << "According to the Vulkan spec BuiltIn VertexIndex " "variable needs to be a 32-bit int scalar. " << message; })) { return error; } } // Seed at reference checks with this built-in. return ValidateVertexIndexAtReference(decoration, inst, inst, inst); } spv_result_t BuiltInsValidator::ValidateVertexIndexAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst) { if (spvIsVulkanEnv(_.context()->target_env)) { const SpvStorageClass storage_class = GetStorageClass(referenced_from_inst); if (storage_class != SpvStorageClassMax && storage_class != SpvStorageClassInput) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn VertexIndex to be only used for " "variables with Input storage class. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst) << " " << GetStorageClassDesc(referenced_from_inst); } for (const SpvExecutionModel execution_model : execution_models_) { if (execution_model != SpvExecutionModelVertex) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn VertexIndex to be used only " "with " "Vertex execution model. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst, execution_model); } } } if (function_id_ == 0) { // Propagate this rule to all dependant ids in the global scope. id_to_at_reference_checks_[referenced_from_inst.id()].push_back(std::bind( &BuiltInsValidator::ValidateVertexIndexAtReference, this, decoration, built_in_inst, referenced_from_inst, std::placeholders::_1)); } return SPV_SUCCESS; } spv_result_t BuiltInsValidator::ValidateLayerOrViewportIndexAtDefinition( const Decoration& decoration, const Instruction& inst) { if (spvIsVulkanEnv(_.context()->target_env)) { if (spv_result_t error = ValidateI32( decoration, inst, [this, &decoration](const std::string& message) -> spv_result_t { return _.diag(SPV_ERROR_INVALID_DATA) << "According to the Vulkan spec BuiltIn " << _.grammar().lookupOperandName(SPV_OPERAND_TYPE_BUILT_IN, decoration.params()[0]) << "variable needs to be a 32-bit int scalar. " << message; })) { return error; } } // Seed at reference checks with this built-in. return ValidateLayerOrViewportIndexAtReference(decoration, inst, inst, inst); } spv_result_t BuiltInsValidator::ValidateLayerOrViewportIndexAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst) { if (spvIsVulkanEnv(_.context()->target_env)) { const SpvStorageClass storage_class = GetStorageClass(referenced_from_inst); if (storage_class != SpvStorageClassMax && storage_class != SpvStorageClassInput && storage_class != SpvStorageClassOutput) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn " << _.grammar().lookupOperandName(SPV_OPERAND_TYPE_BUILT_IN, decoration.params()[0]) << " to be only used for variables with Input or Output storage " "class. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst) << " " << GetStorageClassDesc(referenced_from_inst); } if (storage_class == SpvStorageClassInput) { assert(function_id_ == 0); id_to_at_reference_checks_[referenced_from_inst.id()].push_back(std::bind( &BuiltInsValidator::ValidateNotCalledWithExecutionModel, this, "Vulkan spec doesn't allow BuiltIn Layer and " "ViewportIndex to be " "used for variables with Input storage class if " "execution model is " "Geometry.", SpvExecutionModelGeometry, decoration, built_in_inst, referenced_from_inst, std::placeholders::_1)); } if (storage_class == SpvStorageClassOutput) { assert(function_id_ == 0); id_to_at_reference_checks_[referenced_from_inst.id()].push_back(std::bind( &BuiltInsValidator::ValidateNotCalledWithExecutionModel, this, "Vulkan spec doesn't allow BuiltIn Layer and " "ViewportIndex to be " "used for variables with Output storage class if " "execution model is " "Fragment.", SpvExecutionModelFragment, decoration, built_in_inst, referenced_from_inst, std::placeholders::_1)); } for (const SpvExecutionModel execution_model : execution_models_) { switch (execution_model) { case SpvExecutionModelGeometry: case SpvExecutionModelFragment: { // Ok. break; } default: { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn " << _.grammar().lookupOperandName(SPV_OPERAND_TYPE_BUILT_IN, decoration.params()[0]) << " to be used only with Fragment or Geometry execution " "models. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst, execution_model); } } } } if (function_id_ == 0) { // Propagate this rule to all dependant ids in the global scope. id_to_at_reference_checks_[referenced_from_inst.id()].push_back( std::bind(&BuiltInsValidator::ValidateLayerOrViewportIndexAtReference, this, decoration, built_in_inst, referenced_from_inst, std::placeholders::_1)); } return SPV_SUCCESS; } spv_result_t BuiltInsValidator::ValidateComputeShaderI32Vec3InputAtDefinition( const Decoration& decoration, const Instruction& inst) { if (spvIsVulkanEnv(_.context()->target_env)) { if (spv_result_t error = ValidateI32Vec( decoration, inst, 3, [this, &decoration](const std::string& message) -> spv_result_t { return _.diag(SPV_ERROR_INVALID_DATA) << "According to the Vulkan spec BuiltIn " << _.grammar().lookupOperandName(SPV_OPERAND_TYPE_BUILT_IN, decoration.params()[0]) << " variable needs to be a 3-component 32-bit int " "vector. " << message; })) { return error; } } // Seed at reference checks with this built-in. return ValidateComputeShaderI32Vec3InputAtReference(decoration, inst, inst, inst); } spv_result_t BuiltInsValidator::ValidateComputeShaderI32Vec3InputAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst) { if (spvIsVulkanEnv(_.context()->target_env)) { const SpvStorageClass storage_class = GetStorageClass(referenced_from_inst); if (storage_class != SpvStorageClassMax && storage_class != SpvStorageClassInput) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn " << _.grammar().lookupOperandName(SPV_OPERAND_TYPE_BUILT_IN, decoration.params()[0]) << " to be only used for variables with Input storage class. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst) << " " << GetStorageClassDesc(referenced_from_inst); } for (const SpvExecutionModel execution_model : execution_models_) { if (execution_model != SpvExecutionModelGLCompute) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn " << _.grammar().lookupOperandName(SPV_OPERAND_TYPE_BUILT_IN, decoration.params()[0]) << " to be used only with GLCompute execution model. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst, execution_model); } } } if (function_id_ == 0) { // Propagate this rule to all dependant ids in the global scope. id_to_at_reference_checks_[referenced_from_inst.id()].push_back(std::bind( &BuiltInsValidator::ValidateComputeShaderI32Vec3InputAtReference, this, decoration, built_in_inst, referenced_from_inst, std::placeholders::_1)); } return SPV_SUCCESS; } spv_result_t BuiltInsValidator::ValidateWorkgroupSizeAtDefinition( const Decoration& decoration, const Instruction& inst) { if (spvIsVulkanEnv(_.context()->target_env)) { if (!spvOpcodeIsConstant(inst.opcode())) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec requires BuiltIn WorkgroupSize to be a " "constant. " << GetIdDesc(inst) << " is not a constant."; } if (spv_result_t error = ValidateI32Vec( decoration, inst, 3, [this](const std::string& message) -> spv_result_t { return _.diag(SPV_ERROR_INVALID_DATA) << "According to the Vulkan spec BuiltIn WorkgroupSize " "variable " "needs to be a 3-component 32-bit int vector. " << message; })) { return error; } } // Seed at reference checks with this built-in. return ValidateWorkgroupSizeAtReference(decoration, inst, inst, inst); } spv_result_t BuiltInsValidator::ValidateWorkgroupSizeAtReference( const Decoration& decoration, const Instruction& built_in_inst, const Instruction& referenced_inst, const Instruction& referenced_from_inst) { if (spvIsVulkanEnv(_.context()->target_env)) { for (const SpvExecutionModel execution_model : execution_models_) { if (execution_model != SpvExecutionModelGLCompute) { return _.diag(SPV_ERROR_INVALID_DATA) << "Vulkan spec allows BuiltIn " << _.grammar().lookupOperandName(SPV_OPERAND_TYPE_BUILT_IN, decoration.params()[0]) << " to be used only with GLCompute execution model. " << GetReferenceDesc(decoration, built_in_inst, referenced_inst, referenced_from_inst, execution_model); } } } if (function_id_ == 0) { // Propagate this rule to all dependant ids in the global scope. id_to_at_reference_checks_[referenced_from_inst.id()].push_back(std::bind( &BuiltInsValidator::ValidateWorkgroupSizeAtReference, this, decoration, built_in_inst, referenced_from_inst, std::placeholders::_1)); } return SPV_SUCCESS; } spv_result_t BuiltInsValidator::ValidateSingleBuiltInAtDefinition( const Decoration& decoration, const Instruction& inst) { const SpvBuiltIn label = SpvBuiltIn(decoration.params()[0]); // If you are adding a new BuiltIn enum, please register it here. // If the newly added enum has validation rules associated with it // consider leaving a TODO and/or creating an issue. switch (label) { case SpvBuiltInClipDistance: case SpvBuiltInCullDistance: { return ValidateClipOrCullDistanceAtDefinition(decoration, inst); } case SpvBuiltInFragCoord: { return ValidateFragCoordAtDefinition(decoration, inst); } case SpvBuiltInFragDepth: { return ValidateFragDepthAtDefinition(decoration, inst); } case SpvBuiltInFrontFacing: { return ValidateFrontFacingAtDefinition(decoration, inst); } case SpvBuiltInGlobalInvocationId: case SpvBuiltInLocalInvocationId: case SpvBuiltInNumWorkgroups: case SpvBuiltInWorkgroupId: { return ValidateComputeShaderI32Vec3InputAtDefinition(decoration, inst); } case SpvBuiltInHelperInvocation: { return ValidateHelperInvocationAtDefinition(decoration, inst); } case SpvBuiltInInvocationId: { return ValidateInvocationIdAtDefinition(decoration, inst); } case SpvBuiltInInstanceIndex: { return ValidateInstanceIndexAtDefinition(decoration, inst); } case SpvBuiltInLayer: case SpvBuiltInViewportIndex: { return ValidateLayerOrViewportIndexAtDefinition(decoration, inst); } case SpvBuiltInPatchVertices: { return ValidatePatchVerticesAtDefinition(decoration, inst); } case SpvBuiltInPointCoord: { return ValidatePointCoordAtDefinition(decoration, inst); } case SpvBuiltInPointSize: { return ValidatePointSizeAtDefinition(decoration, inst); } case SpvBuiltInPosition: { return ValidatePositionAtDefinition(decoration, inst); } case SpvBuiltInPrimitiveId: { return ValidatePrimitiveIdAtDefinition(decoration, inst); } case SpvBuiltInSampleId: { return ValidateSampleIdAtDefinition(decoration, inst); } case SpvBuiltInSampleMask: { return ValidateSampleMaskAtDefinition(decoration, inst); } case SpvBuiltInSamplePosition: { return ValidateSamplePositionAtDefinition(decoration, inst); } case SpvBuiltInTessCoord: { return ValidateTessCoordAtDefinition(decoration, inst); } case SpvBuiltInTessLevelOuter: { return ValidateTessLevelOuterAtDefinition(decoration, inst); } case SpvBuiltInTessLevelInner: { return ValidateTessLevelInnerAtDefinition(decoration, inst); } case SpvBuiltInVertexIndex: { return ValidateVertexIndexAtDefinition(decoration, inst); } case SpvBuiltInWorkgroupSize: { return ValidateWorkgroupSizeAtDefinition(decoration, inst); } case SpvBuiltInVertexId: case SpvBuiltInInstanceId: case SpvBuiltInLocalInvocationIndex: case SpvBuiltInWorkDim: case SpvBuiltInGlobalSize: case SpvBuiltInEnqueuedWorkgroupSize: case SpvBuiltInGlobalOffset: case SpvBuiltInGlobalLinearId: case SpvBuiltInSubgroupSize: case SpvBuiltInSubgroupMaxSize: case SpvBuiltInNumSubgroups: case SpvBuiltInNumEnqueuedSubgroups: case SpvBuiltInSubgroupId: case SpvBuiltInSubgroupLocalInvocationId: case SpvBuiltInSubgroupEqMaskKHR: case SpvBuiltInSubgroupGeMaskKHR: case SpvBuiltInSubgroupGtMaskKHR: case SpvBuiltInSubgroupLeMaskKHR: case SpvBuiltInSubgroupLtMaskKHR: case SpvBuiltInBaseVertex: case SpvBuiltInBaseInstance: case SpvBuiltInDrawIndex: case SpvBuiltInDeviceIndex: case SpvBuiltInViewIndex: case SpvBuiltInBaryCoordNoPerspAMD: case SpvBuiltInBaryCoordNoPerspCentroidAMD: case SpvBuiltInBaryCoordNoPerspSampleAMD: case SpvBuiltInBaryCoordSmoothAMD: case SpvBuiltInBaryCoordSmoothCentroidAMD: case SpvBuiltInBaryCoordSmoothSampleAMD: case SpvBuiltInBaryCoordPullModelAMD: case SpvBuiltInFragStencilRefEXT: case SpvBuiltInViewportMaskNV: case SpvBuiltInSecondaryPositionNV: case SpvBuiltInSecondaryViewportMaskNV: case SpvBuiltInPositionPerViewNV: case SpvBuiltInViewportMaskPerViewNV: case SpvBuiltInFullyCoveredEXT: case SpvBuiltInMax: { // No validation rules (for the moment). break; } } return SPV_SUCCESS; } spv_result_t BuiltInsValidator::ValidateBuiltInsAtDefinition() { for (const auto& kv : _.id_decorations()) { const uint32_t id = kv.first; const auto& decorations = kv.second; if (decorations.empty()) { continue; } const Instruction* inst = _.FindDef(id); assert(inst); for (const auto& decoration : kv.second) { if (decoration.dec_type() != SpvDecorationBuiltIn) { continue; } if (spv_result_t error = ValidateSingleBuiltInAtDefinition(decoration, *inst)) { return error; } } } return SPV_SUCCESS; } spv_result_t BuiltInsValidator::Run() { // First pass: validate all built-ins at definition and seed // id_to_at_reference_checks_ with built-ins. if (auto error = ValidateBuiltInsAtDefinition()) { return error; } if (id_to_at_reference_checks_.empty()) { // No validation tasks were seeded. Nothing else to do. return SPV_SUCCESS; } // Second pass: validate every id reference in the module using // rules in id_to_at_reference_checks_. for (const Instruction& inst : _.ordered_instructions()) { Update(inst); std::set already_checked; for (const auto& operand : inst.operands()) { if (!spvIsIdType(operand.type)) { // Not id. continue; } const uint32_t id = inst.word(operand.offset); if (id == inst.id()) { // No need to check result id. continue; } if (!already_checked.insert(id).second) { // The instruction has already referenced this id. continue; } // Instruction references the id. Run all checks associated with the id // on the instruction. id_to_at_reference_checks_ can be modified in the // process, iterators are safe because it's a tree-based map. const auto it = id_to_at_reference_checks_.find(id); if (it != id_to_at_reference_checks_.end()) { for (const auto& check : it->second) { if (spv_result_t error = check(inst)) { return error; } } } } } return SPV_SUCCESS; } } // anonymous namespace // Validates correctness of built-in variables. spv_result_t ValidateBuiltIns(const ValidationState_t& _) { if (!spvIsVulkanEnv(_.context()->target_env)) { // Early return. All currently implemented rules are based on Vulkan spec. // // TODO: If you are adding validation rules for environments other than // Vulkan (or general rules which are not environment independent), then you // need to modify or remove this condition. Consider also adding early // returns into BuiltIn-specific rules, so that the system doesn't spawn new // rules which don't do anything. return SPV_SUCCESS; } BuiltInsValidator validator(_); return validator.Run(); } } // namespace libspirv