// Copyright (c) 2015-2016 The Khronos Group Inc. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. #include #include #include #include #include #include #include #include #include #include #include #include #include "source/cfa.h" #include "source/opcode.h" #include "source/spirv_target_env.h" #include "source/spirv_validator_options.h" #include "source/val/basic_block.h" #include "source/val/construct.h" #include "source/val/function.h" #include "source/val/validate.h" #include "source/val/validation_state.h" namespace spvtools { namespace val { namespace { spv_result_t ValidatePhi(ValidationState_t& _, const Instruction* inst) { auto block = inst->block(); size_t num_in_ops = inst->words().size() - 3; if (num_in_ops % 2 != 0) { return _.diag(SPV_ERROR_INVALID_ID, inst) << "OpPhi does not have an equal number of incoming values and " "basic blocks."; } if (_.IsVoidType(inst->type_id())) { return _.diag(SPV_ERROR_INVALID_DATA, inst) << "OpPhi must not have void result type"; } if (_.IsPointerType(inst->type_id()) && _.addressing_model() == SpvAddressingModelLogical) { if (!_.features().variable_pointers && !_.features().variable_pointers_storage_buffer) { return _.diag(SPV_ERROR_INVALID_DATA, inst) << "Using pointers with OpPhi requires capability " << "VariablePointers or VariablePointersStorageBuffer"; } } const Instruction* type_inst = _.FindDef(inst->type_id()); assert(type_inst); const SpvOp type_opcode = type_inst->opcode(); if (!_.options()->before_hlsl_legalization) { if (type_opcode == SpvOpTypeSampledImage || (_.HasCapability(SpvCapabilityShader) && (type_opcode == SpvOpTypeImage || type_opcode == SpvOpTypeSampler))) { return _.diag(SPV_ERROR_INVALID_ID, inst) << "Result type cannot be Op" << spvOpcodeString(type_opcode); } } // Create a uniqued vector of predecessor ids for comparison against // incoming values. OpBranchConditional %cond %label %label produces two // predecessors in the CFG. std::vector pred_ids; std::transform(block->predecessors()->begin(), block->predecessors()->end(), std::back_inserter(pred_ids), [](const BasicBlock* b) { return b->id(); }); std::sort(pred_ids.begin(), pred_ids.end()); pred_ids.erase(std::unique(pred_ids.begin(), pred_ids.end()), pred_ids.end()); size_t num_edges = num_in_ops / 2; if (num_edges != pred_ids.size()) { return _.diag(SPV_ERROR_INVALID_ID, inst) << "OpPhi's number of incoming blocks (" << num_edges << ") does not match block's predecessor count (" << block->predecessors()->size() << ")."; } std::unordered_set observed_predecessors; for (size_t i = 3; i < inst->words().size(); ++i) { auto inc_id = inst->word(i); if (i % 2 == 1) { // Incoming value type must match the phi result type. auto inc_type_id = _.GetTypeId(inc_id); if (inst->type_id() != inc_type_id) { return _.diag(SPV_ERROR_INVALID_ID, inst) << "OpPhi's result type " << _.getIdName(inst->type_id()) << " does not match incoming value " << _.getIdName(inc_id) << " type " << _.getIdName(inc_type_id) << "."; } } else { if (_.GetIdOpcode(inc_id) != SpvOpLabel) { return _.diag(SPV_ERROR_INVALID_ID, inst) << "OpPhi's incoming basic block " << _.getIdName(inc_id) << " is not an OpLabel."; } // Incoming basic block must be an immediate predecessor of the phi's // block. if (!std::binary_search(pred_ids.begin(), pred_ids.end(), inc_id)) { return _.diag(SPV_ERROR_INVALID_ID, inst) << "OpPhi's incoming basic block " << _.getIdName(inc_id) << " is not a predecessor of " << _.getIdName(block->id()) << "."; } // We must not have already seen this predecessor as one of the phi's // operands. if (observed_predecessors.count(inc_id) != 0) { return _.diag(SPV_ERROR_INVALID_ID, inst) << "OpPhi references incoming basic block " << _.getIdName(inc_id) << " multiple times."; } // Note the fact that we have now observed this predecessor. observed_predecessors.insert(inc_id); } } return SPV_SUCCESS; } spv_result_t ValidateBranch(ValidationState_t& _, const Instruction* inst) { // target operands must be OpLabel const auto id = inst->GetOperandAs(0); const auto target = _.FindDef(id); if (!target || SpvOpLabel != target->opcode()) { return _.diag(SPV_ERROR_INVALID_ID, inst) << "'Target Label' operands for OpBranch must be the ID " "of an OpLabel instruction"; } return SPV_SUCCESS; } spv_result_t ValidateBranchConditional(ValidationState_t& _, const Instruction* inst) { // num_operands is either 3 or 5 --- if 5, the last two need to be literal // integers const auto num_operands = inst->operands().size(); if (num_operands != 3 && num_operands != 5) { return _.diag(SPV_ERROR_INVALID_ID, inst) << "OpBranchConditional requires either 3 or 5 parameters"; } // grab the condition operand and check that it is a bool const auto cond_id = inst->GetOperandAs(0); const auto cond_op = _.FindDef(cond_id); if (!cond_op || !cond_op->type_id() || !_.IsBoolScalarType(cond_op->type_id())) { return _.diag(SPV_ERROR_INVALID_ID, inst) << "Condition operand for " "OpBranchConditional must be " "of boolean type"; } // target operands must be OpLabel // note that we don't need to check that the target labels are in the same // function, // PerformCfgChecks already checks for that const auto true_id = inst->GetOperandAs(1); const auto true_target = _.FindDef(true_id); if (!true_target || SpvOpLabel != true_target->opcode()) { return _.diag(SPV_ERROR_INVALID_ID, inst) << "The 'True Label' operand for OpBranchConditional must be the " "ID of an OpLabel instruction"; } const auto false_id = inst->GetOperandAs(2); const auto false_target = _.FindDef(false_id); if (!false_target || SpvOpLabel != false_target->opcode()) { return _.diag(SPV_ERROR_INVALID_ID, inst) << "The 'False Label' operand for OpBranchConditional must be the " "ID of an OpLabel instruction"; } return SPV_SUCCESS; } spv_result_t ValidateSwitch(ValidationState_t& _, const Instruction* inst) { const auto num_operands = inst->operands().size(); // At least two operands (selector, default), any more than that are // literal/target. // target operands must be OpLabel for (size_t i = 2; i < num_operands; i += 2) { // literal, id const auto id = inst->GetOperandAs(i + 1); const auto target = _.FindDef(id); if (!target || SpvOpLabel != target->opcode()) { return _.diag(SPV_ERROR_INVALID_ID, inst) << "'Target Label' operands for OpSwitch must be IDs of an " "OpLabel instruction"; } } return SPV_SUCCESS; } spv_result_t ValidateReturnValue(ValidationState_t& _, const Instruction* inst) { const auto value_id = inst->GetOperandAs(0); const auto value = _.FindDef(value_id); if (!value || !value->type_id()) { return _.diag(SPV_ERROR_INVALID_ID, inst) << "OpReturnValue Value '" << _.getIdName(value_id) << "' does not represent a value."; } auto value_type = _.FindDef(value->type_id()); if (!value_type || SpvOpTypeVoid == value_type->opcode()) { return _.diag(SPV_ERROR_INVALID_ID, inst) << "OpReturnValue value's type '" << _.getIdName(value->type_id()) << "' is missing or void."; } const bool uses_variable_pointer = _.features().variable_pointers || _.features().variable_pointers_storage_buffer; if (_.addressing_model() == SpvAddressingModelLogical && SpvOpTypePointer == value_type->opcode() && !uses_variable_pointer && !_.options()->relax_logical_pointer) { return _.diag(SPV_ERROR_INVALID_ID, inst) << "OpReturnValue value's type '" << _.getIdName(value->type_id()) << "' is a pointer, which is invalid in the Logical addressing " "model."; } const auto function = inst->function(); const auto return_type = _.FindDef(function->GetResultTypeId()); if (!return_type || return_type->id() != value_type->id()) { return _.diag(SPV_ERROR_INVALID_ID, inst) << "OpReturnValue Value '" << _.getIdName(value_id) << "'s type does not match OpFunction's return type."; } return SPV_SUCCESS; } spv_result_t ValidateLoopMerge(ValidationState_t& _, const Instruction* inst) { const auto merge_id = inst->GetOperandAs(0); const auto merge = _.FindDef(merge_id); if (!merge || merge->opcode() != SpvOpLabel) { return _.diag(SPV_ERROR_INVALID_ID, inst) << "Merge Block " << _.getIdName(merge_id) << " must be an OpLabel"; } if (merge_id == inst->block()->id()) { return _.diag(SPV_ERROR_INVALID_ID, inst) << "Merge Block may not be the block containing the OpLoopMerge\n"; } const auto continue_id = inst->GetOperandAs(1); const auto continue_target = _.FindDef(continue_id); if (!continue_target || continue_target->opcode() != SpvOpLabel) { return _.diag(SPV_ERROR_INVALID_ID, inst) << "Continue Target " << _.getIdName(continue_id) << " must be an OpLabel"; } if (merge_id == continue_id) { return _.diag(SPV_ERROR_INVALID_ID, inst) << "Merge Block and Continue Target must be different ids"; } const auto loop_control = inst->GetOperandAs(2); if ((loop_control >> SpvLoopControlUnrollShift) & 0x1 && (loop_control >> SpvLoopControlDontUnrollShift) & 0x1) { return _.diag(SPV_ERROR_INVALID_DATA, inst) << "Unroll and DontUnroll loop controls must not both be specified"; } if ((loop_control >> SpvLoopControlDontUnrollShift) & 0x1 && (loop_control >> SpvLoopControlPeelCountShift) & 0x1) { return _.diag(SPV_ERROR_INVALID_DATA, inst) << "PeelCount and DontUnroll " "loop controls must not " "both be specified"; } if ((loop_control >> SpvLoopControlDontUnrollShift) & 0x1 && (loop_control >> SpvLoopControlPartialCountShift) & 0x1) { return _.diag(SPV_ERROR_INVALID_DATA, inst) << "PartialCount and " "DontUnroll loop controls " "must not both be specified"; } uint32_t operand = 3; if ((loop_control >> SpvLoopControlDependencyLengthShift) & 0x1) { ++operand; } if ((loop_control >> SpvLoopControlMinIterationsShift) & 0x1) { ++operand; } if ((loop_control >> SpvLoopControlMaxIterationsShift) & 0x1) { ++operand; } if ((loop_control >> SpvLoopControlIterationMultipleShift) & 0x1) { if (inst->operands().size() < operand || inst->GetOperandAs(operand) == 0) { return _.diag(SPV_ERROR_INVALID_DATA, inst) << "IterationMultiple loop " "control operand must be " "greater than zero"; } ++operand; } if ((loop_control >> SpvLoopControlPeelCountShift) & 0x1) { ++operand; } if ((loop_control >> SpvLoopControlPartialCountShift) & 0x1) { ++operand; } // That the right number of operands is present is checked by the parser. The // above code tracks operands for expanded validation checking in the future. return SPV_SUCCESS; } } // namespace void printDominatorList(const BasicBlock& b) { std::cout << b.id() << " is dominated by: "; const BasicBlock* bb = &b; while (bb->immediate_dominator() != bb) { bb = bb->immediate_dominator(); std::cout << bb->id() << " "; } } #define CFG_ASSERT(ASSERT_FUNC, TARGET) \ if (spv_result_t rcode = ASSERT_FUNC(_, TARGET)) return rcode spv_result_t FirstBlockAssert(ValidationState_t& _, uint32_t target) { if (_.current_function().IsFirstBlock(target)) { return _.diag(SPV_ERROR_INVALID_CFG, _.FindDef(_.current_function().id())) << "First block " << _.getIdName(target) << " of function " << _.getIdName(_.current_function().id()) << " is targeted by block " << _.getIdName(_.current_function().current_block()->id()); } return SPV_SUCCESS; } spv_result_t MergeBlockAssert(ValidationState_t& _, uint32_t merge_block) { if (_.current_function().IsBlockType(merge_block, kBlockTypeMerge)) { return _.diag(SPV_ERROR_INVALID_CFG, _.FindDef(_.current_function().id())) << "Block " << _.getIdName(merge_block) << " is already a merge block for another header"; } return SPV_SUCCESS; } /// Update the continue construct's exit blocks once the backedge blocks are /// identified in the CFG. void UpdateContinueConstructExitBlocks( Function& function, const std::vector>& back_edges) { auto& constructs = function.constructs(); // TODO(umar): Think of a faster way to do this for (auto& edge : back_edges) { uint32_t back_edge_block_id; uint32_t loop_header_block_id; std::tie(back_edge_block_id, loop_header_block_id) = edge; auto is_this_header = [=](Construct& c) { return c.type() == ConstructType::kLoop && c.entry_block()->id() == loop_header_block_id; }; for (auto construct : constructs) { if (is_this_header(construct)) { Construct* continue_construct = construct.corresponding_constructs().back(); assert(continue_construct->type() == ConstructType::kContinue); BasicBlock* back_edge_block; std::tie(back_edge_block, std::ignore) = function.GetBlock(back_edge_block_id); continue_construct->set_exit(back_edge_block); } } } } std::tuple ConstructNames( ConstructType type) { std::string construct_name, header_name, exit_name; switch (type) { case ConstructType::kSelection: construct_name = "selection"; header_name = "selection header"; exit_name = "merge block"; break; case ConstructType::kLoop: construct_name = "loop"; header_name = "loop header"; exit_name = "merge block"; break; case ConstructType::kContinue: construct_name = "continue"; header_name = "continue target"; exit_name = "back-edge block"; break; case ConstructType::kCase: construct_name = "case"; header_name = "case entry block"; exit_name = "case exit block"; break; default: assert(1 == 0 && "Not defined type"); } return std::make_tuple(construct_name, header_name, exit_name); } /// Constructs an error message for construct validation errors std::string ConstructErrorString(const Construct& construct, const std::string& header_string, const std::string& exit_string, const std::string& dominate_text) { std::string construct_name, header_name, exit_name; std::tie(construct_name, header_name, exit_name) = ConstructNames(construct.type()); // TODO(umar): Add header block for continue constructs to error message return "The " + construct_name + " construct with the " + header_name + " " + header_string + " " + dominate_text + " the " + exit_name + " " + exit_string; } // Finds the fall through case construct of |target_block| and records it in // |case_fall_through|. Returns SPV_ERROR_INVALID_CFG if the case construct // headed by |target_block| branches to multiple case constructs. spv_result_t FindCaseFallThrough( ValidationState_t& _, BasicBlock* target_block, uint32_t* case_fall_through, const BasicBlock* merge, const std::unordered_set& case_targets, Function* function) { std::vector stack; stack.push_back(target_block); std::unordered_set visited; bool target_reachable = target_block->reachable(); int target_depth = function->GetBlockDepth(target_block); while (!stack.empty()) { auto block = stack.back(); stack.pop_back(); if (block == merge) continue; if (!visited.insert(block).second) continue; if (target_reachable && block->reachable() && target_block->dominates(*block)) { // Still in the case construct. for (auto successor : *block->successors()) { stack.push_back(successor); } } else { // Exiting the case construct to non-merge block. if (!case_targets.count(block->id())) { int depth = function->GetBlockDepth(block); if ((depth < target_depth) || (depth == target_depth && block->is_type(kBlockTypeContinue))) { continue; } return _.diag(SPV_ERROR_INVALID_CFG, target_block->label()) << "Case construct that targets " << _.getIdName(target_block->id()) << " has invalid branch to block " << _.getIdName(block->id()) << " (not another case construct, corresponding merge, outer " "loop merge or outer loop continue)"; } if (*case_fall_through == 0u) { if (target_block != block) { *case_fall_through = block->id(); } } else if (*case_fall_through != block->id()) { // Case construct has at most one branch to another case construct. return _.diag(SPV_ERROR_INVALID_CFG, target_block->label()) << "Case construct that targets " << _.getIdName(target_block->id()) << " has branches to multiple other case construct targets " << _.getIdName(*case_fall_through) << " and " << _.getIdName(block->id()); } } } return SPV_SUCCESS; } spv_result_t StructuredSwitchChecks(ValidationState_t& _, Function* function, const Instruction* switch_inst, const BasicBlock* header, const BasicBlock* merge) { std::unordered_set case_targets; for (uint32_t i = 1; i < switch_inst->operands().size(); i += 2) { uint32_t target = switch_inst->GetOperandAs(i); if (target != merge->id()) case_targets.insert(target); } // Tracks how many times each case construct is targeted by another case // construct. std::map num_fall_through_targeted; uint32_t default_case_fall_through = 0u; uint32_t default_target = switch_inst->GetOperandAs(1u); bool default_appears_multiple_times = false; for (uint32_t i = 3; i < switch_inst->operands().size(); i += 2) { if (default_target == switch_inst->GetOperandAs(i)) { default_appears_multiple_times = true; break; } } std::unordered_map seen_to_fall_through; for (uint32_t i = 1; i < switch_inst->operands().size(); i += 2) { uint32_t target = switch_inst->GetOperandAs(i); if (target == merge->id()) continue; uint32_t case_fall_through = 0u; auto seen_iter = seen_to_fall_through.find(target); if (seen_iter == seen_to_fall_through.end()) { const auto target_block = function->GetBlock(target).first; // OpSwitch must dominate all its case constructs. if (header->reachable() && target_block->reachable() && !header->dominates(*target_block)) { return _.diag(SPV_ERROR_INVALID_CFG, header->label()) << "Selection header " << _.getIdName(header->id()) << " does not dominate its case construct " << _.getIdName(target); } if (auto error = FindCaseFallThrough(_, target_block, &case_fall_through, merge, case_targets, function)) { return error; } // Track how many time the fall through case has been targeted. if (case_fall_through != 0u) { auto where = num_fall_through_targeted.lower_bound(case_fall_through); if (where == num_fall_through_targeted.end() || where->first != case_fall_through) { num_fall_through_targeted.insert( where, std::make_pair(case_fall_through, 1)); } else { where->second++; } } seen_to_fall_through.insert(std::make_pair(target, case_fall_through)); } else { case_fall_through = seen_iter->second; } if (case_fall_through == default_target && !default_appears_multiple_times) { case_fall_through = default_case_fall_through; } if (case_fall_through != 0u) { bool is_default = i == 1; if (is_default) { default_case_fall_through = case_fall_through; } else { // Allow code like: // case x: // case y: // ... // case z: // // Where x and y target the same block and fall through to z. uint32_t j = i; while ((j + 2 < switch_inst->operands().size()) && target == switch_inst->GetOperandAs(j + 2)) { j += 2; } // If Target T1 branches to Target T2, or if Target T1 branches to the // Default target and the Default target branches to Target T2, then T1 // must immediately precede T2 in the list of OpSwitch Target operands. if ((switch_inst->operands().size() < j + 2) || (case_fall_through != switch_inst->GetOperandAs(j + 2))) { return _.diag(SPV_ERROR_INVALID_CFG, switch_inst) << "Case construct that targets " << _.getIdName(target) << " has branches to the case construct that targets " << _.getIdName(case_fall_through) << ", but does not immediately precede it in the " "OpSwitch's target list"; } } } } // Each case construct must be branched to by at most one other case // construct. for (const auto& pair : num_fall_through_targeted) { if (pair.second > 1) { return _.diag(SPV_ERROR_INVALID_CFG, _.FindDef(pair.first)) << "Multiple case constructs have branches to the case construct " "that targets " << _.getIdName(pair.first); } } return SPV_SUCCESS; } // Validates that all CFG divergences (i.e. conditional branch or switch) are // structured correctly. Either divergence is preceded by a merge instruction // or the divergence introduces at most one unseen label. spv_result_t ValidateStructuredSelections( ValidationState_t& _, const std::vector& postorder) { std::unordered_set seen; for (auto iter = postorder.rbegin(); iter != postorder.rend(); ++iter) { const auto* block = *iter; const auto* terminator = block->terminator(); if (!terminator) continue; const auto index = terminator - &_.ordered_instructions()[0]; auto* merge = &_.ordered_instructions()[index - 1]; // Marks merges and continues as seen. if (merge->opcode() == SpvOpSelectionMerge) { seen.insert(merge->GetOperandAs(0)); } else if (merge->opcode() == SpvOpLoopMerge) { seen.insert(merge->GetOperandAs(0)); seen.insert(merge->GetOperandAs(1)); } else { // Only track the pointer if it is a merge instruction. merge = nullptr; } // Skip unreachable blocks. if (!block->reachable()) continue; if (terminator->opcode() == SpvOpBranchConditional) { const auto true_label = terminator->GetOperandAs(1); const auto false_label = terminator->GetOperandAs(2); // Mark the upcoming blocks as seen now, but only error out if this block // was missing a merge instruction and both labels hadn't been seen // previously. const bool both_unseen = seen.insert(true_label).second && seen.insert(false_label).second; if (!merge && both_unseen) { return _.diag(SPV_ERROR_INVALID_CFG, terminator) << "Selection must be structured"; } } else if (terminator->opcode() == SpvOpSwitch) { uint32_t count = 0; // Mark the targets as seen now, but only error out if this block was // missing a merge instruction and there were multiple unseen labels. for (uint32_t i = 1; i < terminator->operands().size(); i += 2) { const auto target = terminator->GetOperandAs(i); if (seen.insert(target).second) { count++; } } if (!merge && count > 1) { return _.diag(SPV_ERROR_INVALID_CFG, terminator) << "Selection must be structured"; } } } return SPV_SUCCESS; } spv_result_t StructuredControlFlowChecks( ValidationState_t& _, Function* function, const std::vector>& back_edges, const std::vector& postorder) { /// Check all backedges target only loop headers and have exactly one /// back-edge branching to it // Map a loop header to blocks with back-edges to the loop header. std::map> loop_latch_blocks; for (auto back_edge : back_edges) { uint32_t back_edge_block; uint32_t header_block; std::tie(back_edge_block, header_block) = back_edge; if (!function->IsBlockType(header_block, kBlockTypeLoop)) { return _.diag(SPV_ERROR_INVALID_CFG, _.FindDef(back_edge_block)) << "Back-edges (" << _.getIdName(back_edge_block) << " -> " << _.getIdName(header_block) << ") can only be formed between a block and a loop header."; } loop_latch_blocks[header_block].insert(back_edge_block); } // Check the loop headers have exactly one back-edge branching to it for (BasicBlock* loop_header : function->ordered_blocks()) { if (!loop_header->reachable()) continue; if (!loop_header->is_type(kBlockTypeLoop)) continue; auto loop_header_id = loop_header->id(); auto num_latch_blocks = loop_latch_blocks[loop_header_id].size(); if (num_latch_blocks != 1) { return _.diag(SPV_ERROR_INVALID_CFG, _.FindDef(loop_header_id)) << "Loop header " << _.getIdName(loop_header_id) << " is targeted by " << num_latch_blocks << " back-edge blocks but the standard requires exactly one"; } } // Check construct rules for (const Construct& construct : function->constructs()) { auto header = construct.entry_block(); auto merge = construct.exit_block(); if (header->reachable() && !merge) { std::string construct_name, header_name, exit_name; std::tie(construct_name, header_name, exit_name) = ConstructNames(construct.type()); return _.diag(SPV_ERROR_INTERNAL, _.FindDef(header->id())) << "Construct " + construct_name + " with " + header_name + " " + _.getIdName(header->id()) + " does not have a " + exit_name + ". This may be a bug in the validator."; } // If the exit block is reachable then it's dominated by the // header. if (merge && merge->reachable()) { if (!header->dominates(*merge)) { return _.diag(SPV_ERROR_INVALID_CFG, _.FindDef(merge->id())) << ConstructErrorString(construct, _.getIdName(header->id()), _.getIdName(merge->id()), "does not dominate"); } // If it's really a merge block for a selection or loop, then it must be // *strictly* dominated by the header. if (construct.ExitBlockIsMergeBlock() && (header == merge)) { return _.diag(SPV_ERROR_INVALID_CFG, _.FindDef(merge->id())) << ConstructErrorString(construct, _.getIdName(header->id()), _.getIdName(merge->id()), "does not strictly dominate"); } } // Check post-dominance for continue constructs. But dominance and // post-dominance only make sense when the construct is reachable. if (header->reachable() && construct.type() == ConstructType::kContinue) { if (!merge->postdominates(*header)) { return _.diag(SPV_ERROR_INVALID_CFG, _.FindDef(merge->id())) << ConstructErrorString(construct, _.getIdName(header->id()), _.getIdName(merge->id()), "is not post dominated by"); } } Construct::ConstructBlockSet construct_blocks = construct.blocks(function); std::string construct_name, header_name, exit_name; std::tie(construct_name, header_name, exit_name) = ConstructNames(construct.type()); for (auto block : construct_blocks) { // Check that all exits from the construct are via structured exits. for (auto succ : *block->successors()) { if (block->reachable() && !construct_blocks.count(succ) && !construct.IsStructuredExit(_, succ)) { return _.diag(SPV_ERROR_INVALID_CFG, _.FindDef(block->id())) << "block " << _.getIdName(block->id()) << " exits the " << construct_name << " headed by " << _.getIdName(header->id()) << ", but not via a structured exit"; } } if (block == header) continue; // Check that for all non-header blocks, all predecessors are within this // construct. for (auto pred : *block->predecessors()) { if (pred->reachable() && !construct_blocks.count(pred)) { return _.diag(SPV_ERROR_INVALID_CFG, _.FindDef(pred->id())) << "block " << pred->id() << " branches to the " << construct_name << " construct, but not to the " << header_name << " " << header->id(); } } if (block->is_type(BlockType::kBlockTypeSelection) || block->is_type(BlockType::kBlockTypeLoop)) { size_t index = (block->terminator() - &_.ordered_instructions()[0]) - 1; const auto& merge_inst = _.ordered_instructions()[index]; if (merge_inst.opcode() == SpvOpSelectionMerge || merge_inst.opcode() == SpvOpLoopMerge) { uint32_t merge_id = merge_inst.GetOperandAs(0); auto merge_block = function->GetBlock(merge_id).first; if (merge_block->reachable() && !construct_blocks.count(merge_block)) { return _.diag(SPV_ERROR_INVALID_CFG, _.FindDef(block->id())) << "Header block " << _.getIdName(block->id()) << " is contained in the " << construct_name << " construct headed by " << _.getIdName(header->id()) << ", but its merge block " << _.getIdName(merge_id) << " is not"; } } } } // Checks rules for case constructs. if (construct.type() == ConstructType::kSelection && header->terminator()->opcode() == SpvOpSwitch) { const auto terminator = header->terminator(); if (auto error = StructuredSwitchChecks(_, function, terminator, header, merge)) { return error; } } } if (auto error = ValidateStructuredSelections(_, postorder)) { return error; } return SPV_SUCCESS; } spv_result_t PerformCfgChecks(ValidationState_t& _) { for (auto& function : _.functions()) { // Check all referenced blocks are defined within a function if (function.undefined_block_count() != 0) { std::string undef_blocks("{"); bool first = true; for (auto undefined_block : function.undefined_blocks()) { undef_blocks += _.getIdName(undefined_block); if (!first) { undef_blocks += " "; } first = false; } return _.diag(SPV_ERROR_INVALID_CFG, _.FindDef(function.id())) << "Block(s) " << undef_blocks << "}" << " are referenced but not defined in function " << _.getIdName(function.id()); } // Set each block's immediate dominator and immediate postdominator, // and find all back-edges. // // We want to analyze all the blocks in the function, even in degenerate // control flow cases including unreachable blocks. So use the augmented // CFG to ensure we cover all the blocks. std::vector postorder; std::vector postdom_postorder; std::vector> back_edges; auto ignore_block = [](const BasicBlock*) {}; auto ignore_edge = [](const BasicBlock*, const BasicBlock*) {}; if (!function.ordered_blocks().empty()) { /// calculate dominators CFA::DepthFirstTraversal( function.first_block(), function.AugmentedCFGSuccessorsFunction(), ignore_block, [&](const BasicBlock* b) { postorder.push_back(b); }, ignore_edge); auto edges = CFA::CalculateDominators( postorder, function.AugmentedCFGPredecessorsFunction()); for (auto edge : edges) { if (edge.first != edge.second) edge.first->SetImmediateDominator(edge.second); } /// calculate post dominators CFA::DepthFirstTraversal( function.pseudo_exit_block(), function.AugmentedCFGPredecessorsFunction(), ignore_block, [&](const BasicBlock* b) { postdom_postorder.push_back(b); }, ignore_edge); auto postdom_edges = CFA::CalculateDominators( postdom_postorder, function.AugmentedCFGSuccessorsFunction()); for (auto edge : postdom_edges) { edge.first->SetImmediatePostDominator(edge.second); } /// calculate back edges. CFA::DepthFirstTraversal( function.pseudo_entry_block(), function .AugmentedCFGSuccessorsFunctionIncludingHeaderToContinueEdge(), ignore_block, ignore_block, [&](const BasicBlock* from, const BasicBlock* to) { back_edges.emplace_back(from->id(), to->id()); }); } UpdateContinueConstructExitBlocks(function, back_edges); auto& blocks = function.ordered_blocks(); if (!blocks.empty()) { // Check if the order of blocks in the binary appear before the blocks // they dominate for (auto block = begin(blocks) + 1; block != end(blocks); ++block) { if (auto idom = (*block)->immediate_dominator()) { if (idom != function.pseudo_entry_block() && block == std::find(begin(blocks), block, idom)) { return _.diag(SPV_ERROR_INVALID_CFG, _.FindDef(idom->id())) << "Block " << _.getIdName((*block)->id()) << " appears in the binary before its dominator " << _.getIdName(idom->id()); } } } // If we have structed control flow, check that no block has a control // flow nesting depth larger than the limit. if (_.HasCapability(SpvCapabilityShader)) { const int control_flow_nesting_depth_limit = _.options()->universal_limits_.max_control_flow_nesting_depth; for (auto block = begin(blocks); block != end(blocks); ++block) { if (function.GetBlockDepth(*block) > control_flow_nesting_depth_limit) { return _.diag(SPV_ERROR_INVALID_CFG, _.FindDef((*block)->id())) << "Maximum Control Flow nesting depth exceeded."; } } } } /// Structured control flow checks are only required for shader capabilities if (_.HasCapability(SpvCapabilityShader)) { if (auto error = StructuredControlFlowChecks(_, &function, back_edges, postorder)) return error; } } return SPV_SUCCESS; } spv_result_t CfgPass(ValidationState_t& _, const Instruction* inst) { SpvOp opcode = inst->opcode(); switch (opcode) { case SpvOpLabel: if (auto error = _.current_function().RegisterBlock(inst->id())) return error; // TODO(github:1661) This should be done in the // ValidationState::RegisterInstruction method but because of the order of // passes the OpLabel ends up not being part of the basic block it starts. _.current_function().current_block()->set_label(inst); break; case SpvOpLoopMerge: { uint32_t merge_block = inst->GetOperandAs(0); uint32_t continue_block = inst->GetOperandAs(1); CFG_ASSERT(MergeBlockAssert, merge_block); if (auto error = _.current_function().RegisterLoopMerge(merge_block, continue_block)) return error; } break; case SpvOpSelectionMerge: { uint32_t merge_block = inst->GetOperandAs(0); CFG_ASSERT(MergeBlockAssert, merge_block); if (auto error = _.current_function().RegisterSelectionMerge(merge_block)) return error; } break; case SpvOpBranch: { uint32_t target = inst->GetOperandAs(0); CFG_ASSERT(FirstBlockAssert, target); _.current_function().RegisterBlockEnd({target}); } break; case SpvOpBranchConditional: { uint32_t tlabel = inst->GetOperandAs(1); uint32_t flabel = inst->GetOperandAs(2); CFG_ASSERT(FirstBlockAssert, tlabel); CFG_ASSERT(FirstBlockAssert, flabel); _.current_function().RegisterBlockEnd({tlabel, flabel}); } break; case SpvOpSwitch: { std::vector cases; for (size_t i = 1; i < inst->operands().size(); i += 2) { uint32_t target = inst->GetOperandAs(i); CFG_ASSERT(FirstBlockAssert, target); cases.push_back(target); } _.current_function().RegisterBlockEnd({cases}); } break; case SpvOpReturn: { const uint32_t return_type = _.current_function().GetResultTypeId(); const Instruction* return_type_inst = _.FindDef(return_type); assert(return_type_inst); if (return_type_inst->opcode() != SpvOpTypeVoid) return _.diag(SPV_ERROR_INVALID_CFG, inst) << "OpReturn can only be called from a function with void " << "return type."; _.current_function().RegisterBlockEnd(std::vector()); break; } case SpvOpKill: case SpvOpReturnValue: case SpvOpUnreachable: case SpvOpTerminateInvocation: case SpvOpIgnoreIntersectionKHR: case SpvOpTerminateRayKHR: _.current_function().RegisterBlockEnd(std::vector()); if (opcode == SpvOpKill) { _.current_function().RegisterExecutionModelLimitation( SpvExecutionModelFragment, "OpKill requires Fragment execution model"); } if (opcode == SpvOpTerminateInvocation) { _.current_function().RegisterExecutionModelLimitation( SpvExecutionModelFragment, "OpTerminateInvocation requires Fragment execution model"); } if (opcode == SpvOpIgnoreIntersectionKHR) { _.current_function().RegisterExecutionModelLimitation( SpvExecutionModelAnyHitKHR, "OpIgnoreIntersectionKHR requires AnyHit execution model"); } if (opcode == SpvOpTerminateRayKHR) { _.current_function().RegisterExecutionModelLimitation( SpvExecutionModelAnyHitKHR, "OpTerminateRayKHR requires AnyHit execution model"); } break; default: break; } return SPV_SUCCESS; } void ReachabilityPass(ValidationState_t& _) { for (auto& f : _.functions()) { std::vector stack; auto entry = f.first_block(); // Skip function declarations. if (entry) stack.push_back(entry); while (!stack.empty()) { auto block = stack.back(); stack.pop_back(); if (block->reachable()) continue; block->set_reachable(true); for (auto succ : *block->successors()) { stack.push_back(succ); } } } } spv_result_t ControlFlowPass(ValidationState_t& _, const Instruction* inst) { switch (inst->opcode()) { case SpvOpPhi: if (auto error = ValidatePhi(_, inst)) return error; break; case SpvOpBranch: if (auto error = ValidateBranch(_, inst)) return error; break; case SpvOpBranchConditional: if (auto error = ValidateBranchConditional(_, inst)) return error; break; case SpvOpReturnValue: if (auto error = ValidateReturnValue(_, inst)) return error; break; case SpvOpSwitch: if (auto error = ValidateSwitch(_, inst)) return error; break; case SpvOpLoopMerge: if (auto error = ValidateLoopMerge(_, inst)) return error; break; default: break; } return SPV_SUCCESS; } } // namespace val } // namespace spvtools