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// 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.
#include <algorithm>
#include <vector>
#include "source/diagnostic.h"
#include "source/spirv_constant.h"
#include "source/spirv_target_env.h"
#include "source/val/function.h"
#include "source/val/instruction.h"
#include "source/val/validate.h"
#include "source/val/validation_state.h"
namespace spvtools {
namespace val {
namespace {
// Returns true if \c inst is an input or output variable.
bool is_interface_variable(const Instruction* inst, bool is_spv_1_4) {
if (is_spv_1_4) {
// Starting in SPIR-V 1.4, all global variables are interface variables.
return inst->opcode() == SpvOpVariable &&
inst->word(3u) != SpvStorageClassFunction;
} else {
return inst->opcode() == SpvOpVariable &&
(inst->word(3u) == SpvStorageClassInput ||
inst->word(3u) == SpvStorageClassOutput);
}
}
// Checks that \c var is listed as an interface in all the entry points that use
// it.
spv_result_t check_interface_variable(ValidationState_t& _,
const Instruction* var) {
std::vector<const Function*> functions;
std::vector<const Instruction*> uses;
for (auto use : var->uses()) {
uses.push_back(use.first);
}
for (uint32_t i = 0; i < uses.size(); ++i) {
const auto user = uses[i];
if (const Function* func = user->function()) {
functions.push_back(func);
} else {
// In the rare case that the variable is used by another instruction in
// the global scope, continue searching for an instruction used in a
// function.
for (auto use : user->uses()) {
uses.push_back(use.first);
}
}
}
std::sort(functions.begin(), functions.end(),
[](const Function* lhs, const Function* rhs) {
return lhs->id() < rhs->id();
});
functions.erase(std::unique(functions.begin(), functions.end()),
functions.end());
std::vector<uint32_t> entry_points;
for (const auto func : functions) {
for (auto id : _.FunctionEntryPoints(func->id())) {
entry_points.push_back(id);
}
}
std::sort(entry_points.begin(), entry_points.end());
entry_points.erase(std::unique(entry_points.begin(), entry_points.end()),
entry_points.end());
for (auto id : entry_points) {
for (const auto& desc : _.entry_point_descriptions(id)) {
bool found = false;
for (auto interface : desc.interfaces) {
if (var->id() == interface) {
found = true;
break;
}
}
if (!found) {
return _.diag(SPV_ERROR_INVALID_ID, var)
<< "Interface variable id <" << var->id()
<< "> is used by entry point '" << desc.name << "' id <" << id
<< ">, but is not listed as an interface";
}
}
}
return SPV_SUCCESS;
}
// This function assumes a base location has been determined already. As such
// any further location decorations are invalid.
// TODO: if this code turns out to be slow, there is an opportunity to cache
// the result for a given type id.
spv_result_t NumConsumedLocations(ValidationState_t& _, const Instruction* type,
uint32_t* num_locations) {
*num_locations = 0;
switch (type->opcode()) {
case SpvOpTypeInt:
case SpvOpTypeFloat:
// Scalars always consume a single location.
*num_locations = 1;
break;
case SpvOpTypeVector:
// 3- and 4-component 64-bit vectors consume two locations.
if ((_.ContainsSizedIntOrFloatType(type->id(), SpvOpTypeInt, 64) ||
_.ContainsSizedIntOrFloatType(type->id(), SpvOpTypeFloat, 64)) &&
(type->GetOperandAs<uint32_t>(2) > 2)) {
*num_locations = 2;
} else {
*num_locations = 1;
}
break;
case SpvOpTypeMatrix:
// Matrices consume locations equal to the underlying vector type for
// each column.
NumConsumedLocations(_, _.FindDef(type->GetOperandAs<uint32_t>(1)),
num_locations);
*num_locations *= type->GetOperandAs<uint32_t>(2);
break;
case SpvOpTypeArray: {
// Arrays consume locations equal to the underlying type times the number
// of elements in the vector.
NumConsumedLocations(_, _.FindDef(type->GetOperandAs<uint32_t>(1)),
num_locations);
bool is_int = false;
bool is_const = false;
uint32_t value = 0;
// Attempt to evaluate the number of array elements.
std::tie(is_int, is_const, value) =
_.EvalInt32IfConst(type->GetOperandAs<uint32_t>(2));
if (is_int && is_const) *num_locations *= value;
break;
}
case SpvOpTypeStruct: {
// Members cannot have location decorations at this point.
if (_.HasDecoration(type->id(), SpvDecorationLocation)) {
return _.diag(SPV_ERROR_INVALID_DATA, type)
<< "Members cannot be assigned a location";
}
// Structs consume locations equal to the sum of the locations consumed
// by the members.
for (uint32_t i = 1; i < type->operands().size(); ++i) {
uint32_t member_locations = 0;
if (auto error = NumConsumedLocations(
_, _.FindDef(type->GetOperandAs<uint32_t>(i)),
&member_locations)) {
return error;
}
*num_locations += member_locations;
}
break;
}
default:
break;
}
return SPV_SUCCESS;
}
// Returns the number of components consumed by types that support a component
// decoration.
uint32_t NumConsumedComponents(ValidationState_t& _, const Instruction* type) {
uint32_t num_components = 0;
switch (type->opcode()) {
case SpvOpTypeInt:
case SpvOpTypeFloat:
// 64-bit types consume two components.
if (type->GetOperandAs<uint32_t>(1) == 64) {
num_components = 2;
} else {
num_components = 1;
}
break;
case SpvOpTypeVector:
// Vectors consume components equal to the underlying type's consumption
// times the number of elements in the vector. Note that 3- and 4-element
// vectors cannot have a component decoration (i.e. assumed to be zero).
num_components =
NumConsumedComponents(_, _.FindDef(type->GetOperandAs<uint32_t>(1)));
num_components *= type->GetOperandAs<uint32_t>(2);
break;
default:
// This is an error that is validated elsewhere.
break;
}
return num_components;
}
// Populates |locations| (and/or |output_index1_locations|) with the use
// location and component coordinates for |variable|. Indices are calculated as
// 4 * location + component.
spv_result_t GetLocationsForVariable(
ValidationState_t& _, const Instruction* entry_point,
const Instruction* variable, std::unordered_set<uint32_t>* locations,
std::unordered_set<uint32_t>* output_index1_locations) {
const bool is_fragment = entry_point->GetOperandAs<SpvExecutionModel>(0) ==
SpvExecutionModelFragment;
const bool is_output =
variable->GetOperandAs<SpvStorageClass>(2) == SpvStorageClassOutput;
auto ptr_type_id = variable->GetOperandAs<uint32_t>(0);
auto ptr_type = _.FindDef(ptr_type_id);
auto type_id = ptr_type->GetOperandAs<uint32_t>(2);
auto type = _.FindDef(type_id);
// Check for Location, Component and Index decorations on the variable. The
// validator allows duplicate decorations if the location/component/index are
// equal. Also track Patch and PerTaskNV decorations.
bool has_location = false;
uint32_t location = 0;
bool has_component = false;
uint32_t component = 0;
bool has_index = false;
uint32_t index = 0;
bool has_patch = false;
bool has_per_task_nv = false;
bool has_per_vertex_nv = false;
for (auto& dec : _.id_decorations(variable->id())) {
if (dec.dec_type() == SpvDecorationLocation) {
if (has_location && dec.params()[0] != location) {
return _.diag(SPV_ERROR_INVALID_DATA, variable)
<< "Variable has conflicting location decorations";
}
has_location = true;
location = dec.params()[0];
} else if (dec.dec_type() == SpvDecorationComponent) {
if (has_component && dec.params()[0] != component) {
return _.diag(SPV_ERROR_INVALID_DATA, variable)
<< "Variable has conflicting component decorations";
}
has_component = true;
component = dec.params()[0];
} else if (dec.dec_type() == SpvDecorationIndex) {
if (!is_output || !is_fragment) {
return _.diag(SPV_ERROR_INVALID_DATA, variable)
<< "Index can only be applied to Fragment output variables";
}
if (has_index && dec.params()[0] != index) {
return _.diag(SPV_ERROR_INVALID_DATA, variable)
<< "Variable has conflicting index decorations";
}
has_index = true;
index = dec.params()[0];
} else if (dec.dec_type() == SpvDecorationBuiltIn) {
// Don't check built-ins.
return SPV_SUCCESS;
} else if (dec.dec_type() == SpvDecorationPatch) {
has_patch = true;
} else if (dec.dec_type() == SpvDecorationPerTaskNV) {
has_per_task_nv = true;
} else if (dec.dec_type() == SpvDecorationPerVertexNV) {
has_per_vertex_nv = true;
}
}
// Vulkan 14.1.3: Tessellation control and mesh per-vertex outputs and
// tessellation control, evaluation and geometry per-vertex inputs have a
// layer of arraying that is not included in interface matching.
bool is_arrayed = false;
switch (entry_point->GetOperandAs<SpvExecutionModel>(0)) {
case SpvExecutionModelTessellationControl:
if (!has_patch) {
is_arrayed = true;
}
break;
case SpvExecutionModelTessellationEvaluation:
if (!is_output && !has_patch) {
is_arrayed = true;
}
break;
case SpvExecutionModelGeometry:
if (!is_output) {
is_arrayed = true;
}
break;
case SpvExecutionModelFragment:
if (!is_output && has_per_vertex_nv) {
is_arrayed = true;
}
break;
case SpvExecutionModelMeshNV:
if (is_output && !has_per_task_nv) {
is_arrayed = true;
}
break;
default:
break;
}
// Unpack arrayness.
if (is_arrayed && (type->opcode() == SpvOpTypeArray ||
type->opcode() == SpvOpTypeRuntimeArray)) {
type_id = type->GetOperandAs<uint32_t>(1);
type = _.FindDef(type_id);
}
if (type->opcode() == SpvOpTypeStruct) {
// Don't check built-ins.
if (_.HasDecoration(type_id, SpvDecorationBuiltIn)) return SPV_SUCCESS;
}
// Only block-decorated structs don't need a location on the variable.
const bool is_block = _.HasDecoration(type_id, SpvDecorationBlock);
if (!has_location && !is_block) {
return _.diag(SPV_ERROR_INVALID_DATA, variable)
<< "Variable must be decorated with a location";
}
const std::string storage_class = is_output ? "output" : "input";
if (has_location) {
auto sub_type = type;
bool is_int = false;
bool is_const = false;
uint32_t array_size = 1;
// If the variable is still arrayed, mark the locations/components per
// index.
if (type->opcode() == SpvOpTypeArray) {
// Determine the array size if possible and get the element type.
std::tie(is_int, is_const, array_size) =
_.EvalInt32IfConst(type->GetOperandAs<uint32_t>(2));
if (!is_int || !is_const) array_size = 1;
auto sub_type_id = type->GetOperandAs<uint32_t>(1);
sub_type = _.FindDef(sub_type_id);
}
for (uint32_t array_idx = 0; array_idx < array_size; ++array_idx) {
uint32_t num_locations = 0;
if (auto error = NumConsumedLocations(_, sub_type, &num_locations))
return error;
uint32_t num_components = NumConsumedComponents(_, sub_type);
uint32_t array_location = location + (num_locations * array_idx);
uint32_t start = array_location * 4;
uint32_t end = (array_location + num_locations) * 4;
if (num_components != 0) {
start += component;
end = array_location * 4 + component + num_components;
}
auto locs = locations;
if (has_index && index == 1) locs = output_index1_locations;
for (uint32_t i = start; i < end; ++i) {
if (!locs->insert(i).second) {
return _.diag(SPV_ERROR_INVALID_DATA, entry_point)
<< "Entry-point has conflicting " << storage_class
<< " location assignment at location " << i / 4
<< ", component " << i % 4;
}
}
}
} else {
// For Block-decorated structs with no location assigned to the variable,
// each member of the block must be assigned a location. Also record any
// member component assignments. The validator allows duplicate decorations
// if they agree on the location/component.
std::unordered_map<uint32_t, uint32_t> member_locations;
std::unordered_map<uint32_t, uint32_t> member_components;
for (auto& dec : _.id_decorations(type_id)) {
if (dec.dec_type() == SpvDecorationLocation) {
auto where = member_locations.find(dec.struct_member_index());
if (where == member_locations.end()) {
member_locations[dec.struct_member_index()] = dec.params()[0];
} else if (where->second != dec.params()[0]) {
return _.diag(SPV_ERROR_INVALID_DATA, type)
<< "Member index " << dec.struct_member_index()
<< " has conflicting location assignments";
}
} else if (dec.dec_type() == SpvDecorationComponent) {
auto where = member_components.find(dec.struct_member_index());
if (where == member_components.end()) {
member_components[dec.struct_member_index()] = dec.params()[0];
} else if (where->second != dec.params()[0]) {
return _.diag(SPV_ERROR_INVALID_DATA, type)
<< "Member index " << dec.struct_member_index()
<< " has conflicting component assignments";
}
}
}
for (uint32_t i = 1; i < type->operands().size(); ++i) {
auto where = member_locations.find(i - 1);
if (where == member_locations.end()) {
return _.diag(SPV_ERROR_INVALID_DATA, type)
<< "Member index " << i - 1
<< " is missing a location assignment";
}
location = where->second;
auto member = _.FindDef(type->GetOperandAs<uint32_t>(i));
uint32_t num_locations = 0;
if (auto error = NumConsumedLocations(_, member, &num_locations))
return error;
// If the component is not specified, it is assumed to be zero.
uint32_t num_components = NumConsumedComponents(_, member);
component = 0;
if (member_components.count(i - 1)) {
component = member_components[i - 1];
}
uint32_t start = location * 4;
uint32_t end = (location + num_locations) * 4;
if (num_components != 0) {
start += component;
end = location * 4 + component + num_components;
}
for (uint32_t l = start; l < end; ++l) {
if (!locations->insert(l).second) {
return _.diag(SPV_ERROR_INVALID_DATA, entry_point)
<< "Entry-point has conflicting " << storage_class
<< " location assignment at location " << l / 4
<< ", component " << l % 4;
}
}
}
}
return SPV_SUCCESS;
}
spv_result_t ValidateLocations(ValidationState_t& _,
const Instruction* entry_point) {
// According to Vulkan 14.1 only the following execution models have
// locations assigned.
switch (entry_point->GetOperandAs<SpvExecutionModel>(0)) {
case SpvExecutionModelVertex:
case SpvExecutionModelTessellationControl:
case SpvExecutionModelTessellationEvaluation:
case SpvExecutionModelGeometry:
case SpvExecutionModelFragment:
break;
default:
return SPV_SUCCESS;
}
// Locations are stored as a combined location and component values.
std::unordered_set<uint32_t> input_locations;
std::unordered_set<uint32_t> output_locations_index0;
std::unordered_set<uint32_t> output_locations_index1;
for (uint32_t i = 3; i < entry_point->operands().size(); ++i) {
auto interface_id = entry_point->GetOperandAs<uint32_t>(i);
auto interface_var = _.FindDef(interface_id);
auto storage_class = interface_var->GetOperandAs<SpvStorageClass>(2);
if (storage_class != SpvStorageClassInput &&
storage_class != SpvStorageClassOutput) {
continue;
}
auto locations = (storage_class == SpvStorageClassInput)
? &input_locations
: &output_locations_index0;
if (auto error = GetLocationsForVariable(
_, entry_point, interface_var, locations, &output_locations_index1))
return error;
}
return SPV_SUCCESS;
}
} // namespace
spv_result_t ValidateInterfaces(ValidationState_t& _) {
bool is_spv_1_4 = _.version() >= SPV_SPIRV_VERSION_WORD(1, 4);
for (auto& inst : _.ordered_instructions()) {
if (is_interface_variable(&inst, is_spv_1_4)) {
if (auto error = check_interface_variable(_, &inst)) {
return error;
}
}
}
if (spvIsVulkanEnv(_.context()->target_env)) {
for (auto& inst : _.ordered_instructions()) {
if (inst.opcode() == SpvOpEntryPoint) {
if (auto error = ValidateLocations(_, &inst)) {
return error;
}
}
if (inst.opcode() == SpvOpTypeVoid) break;
}
}
return SPV_SUCCESS;
}
} // namespace val
} // namespace spvtools