| // Copyright 2022 The Dawn & Tint Authors |
| // |
| // Redistribution and use in source and binary forms, with or without |
| // modification, are permitted provided that the following conditions are met: |
| // |
| // 1. Redistributions of source code must retain the above copyright notice, this |
| // list of conditions and the following disclaimer. |
| // |
| // 2. Redistributions in binary form must reproduce the above copyright notice, |
| // this list of conditions and the following disclaimer in the documentation |
| // and/or other materials provided with the distribution. |
| // |
| // 3. Neither the name of the copyright holder nor the names of its |
| // contributors may be used to endorse or promote products derived from |
| // this software without specific prior written permission. |
| // |
| // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" |
| // AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE |
| // IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE |
| // DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE |
| // FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL |
| // DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR |
| // SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER |
| // CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, |
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| // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. |
| |
| #include "src/tint/lang/wgsl/resolver/uniformity.h" |
| |
| #include <limits> |
| #include <string> |
| #include <utility> |
| #include <vector> |
| |
| #include "src/tint/lang/core/builtin_value.h" |
| #include "src/tint/lang/wgsl/program/program_builder.h" |
| #include "src/tint/lang/wgsl/resolver/dependency_graph.h" |
| #include "src/tint/lang/wgsl/sem/block_statement.h" |
| #include "src/tint/lang/wgsl/sem/builtin_fn.h" |
| #include "src/tint/lang/wgsl/sem/for_loop_statement.h" |
| #include "src/tint/lang/wgsl/sem/function.h" |
| #include "src/tint/lang/wgsl/sem/if_statement.h" |
| #include "src/tint/lang/wgsl/sem/info.h" |
| #include "src/tint/lang/wgsl/sem/load.h" |
| #include "src/tint/lang/wgsl/sem/loop_statement.h" |
| #include "src/tint/lang/wgsl/sem/statement.h" |
| #include "src/tint/lang/wgsl/sem/switch_statement.h" |
| #include "src/tint/lang/wgsl/sem/value_constructor.h" |
| #include "src/tint/lang/wgsl/sem/value_conversion.h" |
| #include "src/tint/lang/wgsl/sem/variable.h" |
| #include "src/tint/lang/wgsl/sem/while_statement.h" |
| #include "src/tint/utils/containers/map.h" |
| #include "src/tint/utils/containers/scope_stack.h" |
| #include "src/tint/utils/containers/unique_vector.h" |
| #include "src/tint/utils/macros/defer.h" |
| #include "src/tint/utils/memory/block_allocator.h" |
| #include "src/tint/utils/rtti/switch.h" |
| #include "src/tint/utils/text/string_stream.h" |
| |
| // Set to `1` to dump the uniformity graph for each function in graphviz format. |
| #define TINT_DUMP_UNIFORMITY_GRAPH 0 |
| |
| #if TINT_DUMP_UNIFORMITY_GRAPH |
| #include <iostream> |
| #endif |
| |
| namespace tint::resolver { |
| |
| namespace { |
| |
| /// Unwraps `u->expr`'s chain of indirect (*) and address-of (&) expressions, returning the first |
| /// expression that is neither of these. |
| /// E.g. If `u` is `*(&(*(&p)))`, returns `p`. |
| const ast::Expression* UnwrapIndirectAndAddressOfChain(const ast::UnaryOpExpression* u) { |
| auto* e = u->expr; |
| while (true) { |
| auto* unary = e->As<ast::UnaryOpExpression>(); |
| if (unary && |
| (unary->op == core::UnaryOp::kIndirection || unary->op == core::UnaryOp::kAddressOf)) { |
| e = unary->expr; |
| } else { |
| break; |
| } |
| } |
| return e; |
| } |
| |
| /// CallSiteTag describes the uniformity requirements on the call sites of a function. |
| struct CallSiteTag { |
| enum { |
| CallSiteRequiredToBeUniform, |
| CallSiteNoRestriction, |
| } tag; |
| wgsl::DiagnosticSeverity severity = wgsl::DiagnosticSeverity::kUndefined; |
| }; |
| |
| /// FunctionTag describes a functions effects on uniformity. |
| enum FunctionTag { |
| ReturnValueMayBeNonUniform, |
| NoRestriction, |
| }; |
| |
| /// ParameterTag describes the uniformity requirements of values passed to a function parameter. |
| struct ParameterTag { |
| enum { |
| ParameterValueRequiredToBeUniform, |
| ParameterContentsRequiredToBeUniform, |
| ParameterNoRestriction, |
| } tag; |
| wgsl::DiagnosticSeverity severity = wgsl::DiagnosticSeverity::kUndefined; |
| }; |
| |
| /// Node represents a node in the graph of control flow and value nodes within the analysis of a |
| /// single function. |
| struct Node { |
| /// Constructor |
| /// @param a the corresponding AST node |
| explicit Node(const ast::Node* a) : ast(a) {} |
| |
| #if TINT_DUMP_UNIFORMITY_GRAPH |
| /// The node tag. |
| std::string tag; |
| #endif |
| |
| /// Type describes the type of the node, which is used to determine additional diagnostic |
| /// information. |
| enum Type { |
| kRegular, |
| kFunctionCallArgumentValue, |
| kFunctionCallArgumentContents, |
| kFunctionCallPointerArgumentResult, |
| kFunctionCallReturnValue, |
| }; |
| |
| /// The type of the node. |
| Type type = kRegular; |
| |
| /// `true` if this node represents a potential control flow change. |
| bool affects_control_flow = false; |
| |
| /// The corresponding AST node, or nullptr. |
| const ast::Node* ast = nullptr; |
| |
| /// The function call argument index, if applicable. |
| uint32_t arg_index = 0xffffffffu; |
| |
| /// The set of edges from this node to other nodes in the graph. |
| UniqueVector<Node*, 4> edges; |
| |
| /// The node that this node was visited from, or nullptr if not visited. |
| Node* visited_from = nullptr; |
| |
| /// Add an edge to the `to` node. |
| /// @param to the destination node |
| void AddEdge(Node* to) { |
| TINT_ASSERT(to != nullptr); |
| edges.Add(to); |
| } |
| }; |
| |
| /// ParameterInfo holds information about the uniformity requirements and effects for a particular |
| /// function parameter. |
| struct ParameterInfo { |
| /// The semantic node in corresponds to this parameter. |
| const sem::Parameter* sem; |
| /// The parameter's direct uniformity requirements. |
| ParameterTag tag_direct = {ParameterTag::ParameterNoRestriction}; |
| /// The parameter's uniformity requirements that affect the function return value. |
| ParameterTag tag_retval = {ParameterTag::ParameterNoRestriction}; |
| /// Will be `true` if this function may cause the contents of this pointer parameter to become |
| /// non-uniform. |
| bool pointer_may_become_non_uniform = false; |
| /// The parameters that are required to be uniform for the contents of this pointer parameter to |
| /// be uniform at function exit. |
| Vector<const sem::Parameter*, 8> ptr_output_source_param_values; |
| /// The pointer parameters whose contents are required to be uniform for the contents of this |
| /// pointer parameter to be uniform at function exit. |
| Vector<const sem::Parameter*, 8> ptr_output_source_param_contents; |
| /// The node in the graph that corresponds to this parameter's (immutable) value. |
| Node* value; |
| /// The node in the graph that corresponds to this pointer parameter's initial contents. |
| Node* ptr_input_contents = nullptr; |
| /// The node in the graph that corresponds to this pointer parameter's contents on return. |
| Node* ptr_output_contents = nullptr; |
| }; |
| |
| /// FunctionInfo holds information about the uniformity requirements and effects for a particular |
| /// function, as well as the control flow graph. |
| struct FunctionInfo { |
| /// Constructor |
| /// @param func the AST function |
| /// @param b the program builder |
| FunctionInfo(const ast::Function* func, const ProgramBuilder& b) { |
| name = func->name->symbol.Name(); |
| callsite_tag = {CallSiteTag::CallSiteNoRestriction}; |
| function_tag = NoRestriction; |
| |
| // Create special nodes. |
| required_to_be_uniform_error = CreateNode({"RequiredToBeUniform_Error"}); |
| required_to_be_uniform_warning = CreateNode({"RequiredToBeUniform_Warning"}); |
| required_to_be_uniform_info = CreateNode({"RequiredToBeUniform_Info"}); |
| may_be_non_uniform = CreateNode({"MayBeNonUniform"}); |
| cf_start = CreateNode({"CF_start"}); |
| if (func->return_type) { |
| value_return = CreateNode({"Value_return"}); |
| } |
| |
| // Create nodes for parameters. |
| parameters.Resize(func->params.Length()); |
| for (size_t i = 0; i < func->params.Length(); i++) { |
| auto* param = func->params[i]; |
| auto param_name = param->name->symbol.Name(); |
| auto* sem = b.Sem().Get(param); |
| parameters[i].sem = sem; |
| |
| parameters[i].value = CreateNode({"param_", param_name}); |
| if (sem->Type()->Is<core::type::Pointer>()) { |
| // Create extra nodes for a pointer parameter's initial contents and its contents |
| // when the function returns. |
| parameters[i].ptr_input_contents = |
| CreateNode({"ptrparam_", param_name, "_input_contents"}); |
| parameters[i].ptr_output_contents = |
| CreateNode({"ptrparam_", param_name, "_output_contents"}); |
| variables.Set(sem, parameters[i].ptr_input_contents); |
| local_var_decls.Add(sem); |
| } else { |
| variables.Set(sem, parameters[i].value); |
| } |
| } |
| } |
| |
| /// The name of the function. |
| std::string name; |
| |
| /// The call site uniformity requirements. |
| CallSiteTag callsite_tag; |
| /// The function's uniformity effects. |
| FunctionTag function_tag; |
| /// The uniformity requirements of the function's parameters. |
| Vector<ParameterInfo, 8> parameters; |
| |
| /// The control flow graph. |
| BlockAllocator<Node> nodes; |
| |
| /// Special `RequiredToBeUniform` nodes. |
| Node* required_to_be_uniform_error = nullptr; |
| Node* required_to_be_uniform_warning = nullptr; |
| Node* required_to_be_uniform_info = nullptr; |
| /// Special `MayBeNonUniform` node. |
| Node* may_be_non_uniform = nullptr; |
| /// Special `CF_start` node. |
| Node* cf_start = nullptr; |
| /// Special `Value_return` node. |
| Node* value_return = nullptr; |
| |
| /// Map from variables to their value nodes in the graph, scoped with respect to control flow. |
| ScopeStack<const sem::Variable*, Node*> variables; |
| |
| /// The set of mutable variables declared in the function that are in scope at any given point |
| /// in the analysis. This includes the contents of parameters to the function that are pointers. |
| /// This is used by the analysis for if statements and loops to know which variables need extra |
| /// nodes to capture their state when entering/exiting those constructs. |
| Hashset<const sem::Variable*, 8> local_var_decls; |
| |
| /// The set of partial pointer variables - pointers that point to a subobject (into an array or |
| /// struct). |
| Hashset<const sem::Variable*, 4> partial_ptrs; |
| |
| /// LoopSwitchInfo tracks information about the value of variables for a control flow construct. |
| struct LoopSwitchInfo { |
| /// The type of this control flow construct. |
| std::string type; |
| /// The input values for local variables at the start of this construct. |
| Hashmap<const sem::Variable*, Node*, 4> var_in_nodes; |
| /// The exit values for local variables at the end of this construct. |
| Hashmap<const sem::Variable*, Node*, 4> var_exit_nodes; |
| }; |
| |
| /// @returns the RequiredToBeUniform node that corresponds to `severity` |
| Node* RequiredToBeUniform(wgsl::DiagnosticSeverity severity) { |
| switch (severity) { |
| case wgsl::DiagnosticSeverity::kError: |
| return required_to_be_uniform_error; |
| case wgsl::DiagnosticSeverity::kWarning: |
| return required_to_be_uniform_warning; |
| case wgsl::DiagnosticSeverity::kInfo: |
| return required_to_be_uniform_info; |
| default: |
| TINT_UNREACHABLE() << "unhandled severity"; |
| return nullptr; |
| } |
| } |
| |
| /// @returns a LoopSwitchInfo for the given statement, allocating the LoopSwitchInfo if this is |
| /// the first call with the given statement. |
| LoopSwitchInfo& LoopSwitchInfoFor(const sem::Statement* stmt) { |
| return *loop_switch_infos.GetOrAdd(stmt, |
| [&] { return loop_switch_info_allocator.Create(); }); |
| } |
| |
| /// Disassociates the LoopSwitchInfo for the given statement. |
| void RemoveLoopSwitchInfoFor(const sem::Statement* stmt) { loop_switch_infos.Remove(stmt); } |
| |
| /// Create a new node. |
| /// @param tag_list a string list that will be used to identify the node for debugging purposes |
| /// @param ast the optional AST node that this node corresponds to |
| /// @returns the new node |
| Node* CreateNode([[maybe_unused]] std::initializer_list<std::string_view> tag_list, |
| const ast::Node* ast = nullptr) { |
| auto* node = nodes.Create(ast); |
| |
| #if TINT_DUMP_UNIFORMITY_GRAPH |
| // Make the tag unique and set it. |
| // This only matters if we're dumping the graph. |
| std::string tag = ""; |
| for (auto& t : tag_list) { |
| tag += t; |
| } |
| std::string unique_tag = tag; |
| int suffix = 0; |
| while (tags_.Contains(unique_tag)) { |
| unique_tag = tag + "_$" + std::to_string(++suffix); |
| } |
| tags_.Add(unique_tag); |
| node->tag = name + "." + unique_tag; |
| #endif |
| |
| return node; |
| } |
| |
| /// Reset the visited status of every node in the graph. |
| void ResetVisited() { |
| for (auto* node : nodes.Objects()) { |
| node->visited_from = nullptr; |
| } |
| } |
| |
| private: |
| /// A list of tags that have already been used within the current function. |
| Hashset<std::string, 8> tags_; |
| |
| /// Map from control flow statements to the corresponding LoopSwitchInfo structure. |
| Hashmap<const sem::Statement*, LoopSwitchInfo*, 8> loop_switch_infos; |
| |
| /// Allocator of LoopSwitchInfos |
| BlockAllocator<LoopSwitchInfo> loop_switch_info_allocator; |
| }; |
| |
| /// UniformityGraph is used to analyze the uniformity requirements and effects of functions in a |
| /// module. |
| class UniformityGraph { |
| public: |
| /// Constructor. |
| /// @param builder the program to analyze |
| explicit UniformityGraph(ProgramBuilder& builder) |
| : b(builder), sem_(b.Sem()), diagnostics_(builder.Diagnostics()) {} |
| |
| /// Destructor. |
| ~UniformityGraph() {} |
| |
| /// Build and analyze the graph to determine whether the program satisfies the uniformity |
| /// constraints of WGSL. |
| /// @param dependency_graph the dependency-ordered module-scope declarations |
| /// @returns true if all uniformity constraints are satisfied, otherise false |
| bool Build(const DependencyGraph& dependency_graph) { |
| #if TINT_DUMP_UNIFORMITY_GRAPH |
| std::cout << "digraph G {\n"; |
| std::cout << "rankdir=BT\n"; |
| #endif |
| |
| // Process all functions in the module. |
| bool success = true; |
| for (auto* decl : dependency_graph.ordered_globals) { |
| if (auto* func = decl->As<ast::Function>()) { |
| if (!ProcessFunction(func)) { |
| success = false; |
| break; |
| } |
| } |
| } |
| |
| #if TINT_DUMP_UNIFORMITY_GRAPH |
| std::cout << "\n}\n"; |
| #endif |
| |
| return success; |
| } |
| |
| private: |
| const ProgramBuilder& b; |
| const sem::Info& sem_; |
| diag::List& diagnostics_; |
| |
| /// Map of analyzed function results. |
| Hashmap<const ast::Function*, FunctionInfo, 8> functions_; |
| |
| /// The function currently being analyzed. |
| FunctionInfo* current_function_; |
| |
| /// Create a new node. |
| /// @param tag_list a string list that will be used to identify the node for debugging purposes |
| /// @param ast the optional AST node that this node corresponds to |
| /// @returns the new node |
| inline Node* CreateNode(std::initializer_list<std::string_view> tag_list, |
| const ast::Node* ast = nullptr) { |
| return current_function_->CreateNode(std::move(tag_list), ast); |
| } |
| |
| /// Get the symbol name of an AST expression. |
| /// @param expr the expression to get the symbol name of |
| /// @returns the symbol name |
| inline std::string NameFor(const ast::IdentifierExpression* expr) { |
| return expr->identifier->symbol.Name(); |
| } |
| |
| /// @param var the variable to get the name of |
| /// @returns the name of the variable @p var |
| inline std::string NameFor(const ast::Variable* var) { return var->name->symbol.Name(); } |
| |
| /// @param var the variable to get the name of |
| /// @returns the name of the variable @p var |
| inline std::string NameFor(const sem::Variable* var) { return NameFor(var->Declaration()); } |
| |
| /// @param fn the function to get the name of |
| /// @returns the name of the function @p fn |
| inline std::string NameFor(const sem::Function* fn) { |
| return fn->Declaration()->name->symbol.Name(); |
| } |
| |
| /// Process a function. |
| /// @param func the function to process |
| /// @returns true if there are no uniformity issues, false otherwise |
| bool ProcessFunction(const ast::Function* func) { |
| current_function_ = &functions_.Add(func, FunctionInfo(func, b)).value; |
| |
| // Process function body. |
| if (func->body) { |
| ProcessStatement(current_function_->cf_start, func->body); |
| } |
| |
| #if TINT_DUMP_UNIFORMITY_GRAPH |
| // Dump the graph for this function as a subgraph. |
| std::cout << "\nsubgraph cluster_" << current_function_->name << " {\n"; |
| std::cout << " label=" << current_function_->name << ";"; |
| for (auto* node : current_function_->nodes.Objects()) { |
| std::cout << "\n \"" << node->tag << "\";"; |
| for (auto* edge : node->edges) { |
| std::cout << "\n \"" << node->tag << "\" -> \"" << edge->tag << "\";"; |
| } |
| } |
| std::cout << "\n}\n"; |
| #endif |
| |
| /// Helper to generate a tag for the uniformity requirements of the parameter at `index`. |
| auto get_param_tag = [&](UniqueVector<Node*, 4>& reachable, size_t index) { |
| auto* param = sem_.Get(func->params[index]); |
| auto& param_info = current_function_->parameters[index]; |
| if (param->Type()->Is<core::type::Pointer>()) { |
| // For pointers, we distinguish between requiring uniformity of the contents versus |
| // the pointer itself. |
| if (reachable.Contains(param_info.ptr_input_contents)) { |
| return ParameterTag::ParameterContentsRequiredToBeUniform; |
| } else if (reachable.Contains(param_info.value)) { |
| return ParameterTag::ParameterValueRequiredToBeUniform; |
| } |
| } else if (reachable.Contains(current_function_->variables.Get(param))) { |
| // For non-pointers, the requirement is always on the value. |
| return ParameterTag::ParameterValueRequiredToBeUniform; |
| } |
| return ParameterTag::ParameterNoRestriction; |
| }; |
| |
| // Look at which nodes are reachable from "RequiredToBeUniform". |
| { |
| UniqueVector<Node*, 4> reachable; |
| auto traverse = [&](wgsl::DiagnosticSeverity severity) { |
| Traverse(current_function_->RequiredToBeUniform(severity), &reachable); |
| if (reachable.Contains(current_function_->may_be_non_uniform)) { |
| MakeError(*current_function_, current_function_->may_be_non_uniform, severity); |
| return false; |
| } |
| if (reachable.Contains(current_function_->cf_start)) { |
| if (current_function_->callsite_tag.tag == CallSiteTag::CallSiteNoRestriction) { |
| current_function_->callsite_tag = {CallSiteTag::CallSiteRequiredToBeUniform, |
| severity}; |
| } |
| } |
| |
| // Set the tags to capture the direct uniformity requirements of each parameter. |
| for (size_t i = 0; i < func->params.Length(); i++) { |
| if (current_function_->parameters[i].tag_direct.tag == |
| ParameterTag::ParameterNoRestriction) { |
| current_function_->parameters[i].tag_direct = {get_param_tag(reachable, i), |
| severity}; |
| } |
| } |
| return true; |
| }; |
| if (!traverse(wgsl::DiagnosticSeverity::kError)) { |
| return false; |
| } else { |
| if (traverse(wgsl::DiagnosticSeverity::kWarning)) { |
| traverse(wgsl::DiagnosticSeverity::kInfo); |
| } |
| } |
| } |
| |
| // If "Value_return" exists, look at which nodes are reachable from it. |
| if (current_function_->value_return) { |
| current_function_->ResetVisited(); |
| |
| UniqueVector<Node*, 4> reachable; |
| Traverse(current_function_->value_return, &reachable); |
| if (reachable.Contains(current_function_->may_be_non_uniform)) { |
| current_function_->function_tag = ReturnValueMayBeNonUniform; |
| } |
| |
| // Set the tags to capture the uniformity requirements of each parameter with respect to |
| // the function return value. |
| for (size_t i = 0; i < func->params.Length(); i++) { |
| current_function_->parameters[i].tag_retval = {get_param_tag(reachable, i)}; |
| } |
| } |
| |
| // Traverse the graph for each pointer parameter. |
| for (size_t i = 0; i < func->params.Length(); i++) { |
| auto& param_info = current_function_->parameters[i]; |
| if (param_info.ptr_output_contents == nullptr) { |
| continue; |
| } |
| |
| // Reset "visited" state for all nodes. |
| current_function_->ResetVisited(); |
| |
| UniqueVector<Node*, 4> reachable; |
| Traverse(param_info.ptr_output_contents, &reachable); |
| if (reachable.Contains(current_function_->may_be_non_uniform)) { |
| param_info.pointer_may_become_non_uniform = true; |
| } |
| |
| // Check every parameter to see if it feeds into this parameter's output value. |
| // This includes checking this parameter (as it may feed into its own output value), so |
| // we do not skip the `i==j` case. |
| for (size_t j = 0; j < func->params.Length(); j++) { |
| auto tag = get_param_tag(reachable, j); |
| auto* source_param = sem_.Get(func->params[j]); |
| if (tag == ParameterTag::ParameterContentsRequiredToBeUniform) { |
| param_info.ptr_output_source_param_contents.Push(source_param); |
| } else if (tag == ParameterTag::ParameterValueRequiredToBeUniform) { |
| param_info.ptr_output_source_param_values.Push(source_param); |
| } |
| } |
| } |
| |
| return true; |
| } |
| |
| /// Process a statement, returning the new control flow node. |
| /// @param cf the input control flow node |
| /// @param stmt the statement to process d |
| /// @returns the new control flow node |
| Node* ProcessStatement(Node* cf, const ast::Statement* stmt) { |
| return Switch( |
| stmt, |
| |
| [&](const ast::AssignmentStatement* a) { |
| if (a->lhs->Is<ast::PhonyExpression>()) { |
| auto [cf_r, _] = ProcessExpression(cf, a->rhs); |
| return cf_r; |
| } |
| auto [cf_l, v_l, ident] = ProcessLValueExpression(cf, a->lhs); |
| auto [cf_r, v_r] = ProcessExpression(cf_l, a->rhs); |
| v_l->AddEdge(v_r); |
| |
| // Update the variable node for the LHS variable. |
| current_function_->variables.Set(ident, v_l); |
| |
| return cf_r; |
| }, |
| |
| [&](const ast::BlockStatement* block) { |
| Hashmap<const sem::Variable*, Node*, 4> scoped_assignments; |
| auto* sem = sem_.Get(block); |
| { |
| // Push a new scope for variable assignments in the block. |
| current_function_->variables.Push(); |
| TINT_DEFER(current_function_->variables.Pop()); |
| |
| for (auto* s : block->statements) { |
| cf = ProcessStatement(cf, s); |
| if (!sem_.Get(s)->Behaviors().Contains(sem::Behavior::kNext)) { |
| break; |
| } |
| } |
| |
| auto* parent = sem->Parent(); |
| auto* loop = parent ? parent->As<sem::LoopStatement>() : nullptr; |
| if (loop) { |
| // We've reached the end of a loop body. If there is a continuing block, |
| // process it before ending the block so that any variables declared in the |
| // loop body are visible to the continuing block. |
| if (auto* continuing = |
| loop->Declaration()->As<ast::LoopStatement>()->continuing) { |
| auto& loop_body_behavior = sem->Behaviors(); |
| if (loop_body_behavior.Contains(sem::Behavior::kNext) || |
| loop_body_behavior.Contains(sem::Behavior::kContinue)) { |
| cf = ProcessStatement(cf, continuing); |
| } |
| } |
| } |
| |
| if (sem_.Get<sem::FunctionBlockStatement>(block)) { |
| // We've reached the end of the function body. |
| // Add edges from pointer parameter outputs to their current value. |
| for (auto& param : current_function_->parameters) { |
| if (param.ptr_output_contents) { |
| param.ptr_output_contents->AddEdge( |
| current_function_->variables.Get(param.sem)); |
| } |
| } |
| } |
| |
| scoped_assignments = std::move(current_function_->variables.Top()); |
| } |
| |
| // Propagate all variables assignments to the containing scope if the behavior is |
| // 'Next'. |
| auto& behaviors = sem->Behaviors(); |
| if (behaviors.Contains(sem::Behavior::kNext)) { |
| for (auto& var : scoped_assignments) { |
| current_function_->variables.Set(var.key, var.value); |
| } |
| } |
| |
| // Remove any variables declared in this scope from the set of in-scope variables. |
| for (auto decl : sem->Decls()) { |
| current_function_->local_var_decls.Remove(decl.value.variable); |
| } |
| |
| return cf; |
| }, |
| |
| [&](const ast::BreakStatement* brk) { |
| // Find the loop or switch statement that we are in. |
| auto* parent = sem_.Get(brk) |
| ->FindFirstParent<sem::SwitchStatement, sem::LoopStatement, |
| sem::ForLoopStatement, sem::WhileStatement>(); |
| |
| auto& info = current_function_->LoopSwitchInfoFor(parent); |
| |
| // Propagate variable values to the loop/switch exit nodes. |
| for (auto& var : current_function_->local_var_decls) { |
| // Skip variables that were declared inside this loop/switch. |
| if (auto* lv = var->As<sem::LocalVariable>(); |
| lv && |
| lv->Statement()->FindFirstParent([&](auto* s) { return s == parent; })) { |
| continue; |
| } |
| |
| // Add an edge from the variable exit node to its value at this point. |
| auto* exit_node = info.var_exit_nodes.GetOrAdd(var, [&] { |
| auto name = NameFor(var); |
| return CreateNode({name, "_value_", info.type, "_exit"}); |
| }); |
| exit_node->AddEdge(current_function_->variables.Get(var)); |
| } |
| |
| return cf; |
| }, |
| |
| [&](const ast::BreakIfStatement* brk) { |
| // This works very similar to the IfStatement uniformity below, execpt instead of |
| // processing the body, we directly inline the BreakStatement uniformity from |
| // above. |
| auto* sem = sem_.Get(brk); |
| |
| auto [_, v_cond] = ProcessExpression(cf, brk->condition); |
| |
| // Add a diagnostic node to capture the control flow change. |
| auto* v = CreateNode({"break_if_stmt"}, brk); |
| v->affects_control_flow = true; |
| v->AddEdge(v_cond); |
| |
| { |
| auto* parent = sem->FindFirstParent<sem::LoopStatement>(); |
| auto& info = current_function_->LoopSwitchInfoFor(parent); |
| |
| // Propagate variable values to the loop exit nodes. |
| for (auto& var : current_function_->local_var_decls) { |
| // Skip variables that were declared inside this loop. |
| if (auto* lv = var->As<sem::LocalVariable>(); |
| lv && lv->Statement()->FindFirstParent( |
| [&](auto* s) { return s == parent; })) { |
| continue; |
| } |
| |
| // Add an edge from the variable exit node to its value at this point. |
| auto* exit_node = info.var_exit_nodes.GetOrAdd(var, [&] { |
| auto name = NameFor(var); |
| return CreateNode({name, "_value_", info.type, "_exit"}); |
| }); |
| |
| exit_node->AddEdge(current_function_->variables.Get(var)); |
| } |
| } |
| |
| if (sem->Behaviors() != sem::Behaviors{sem::Behavior::kNext}) { |
| auto* cf_end = CreateNode({"break_if_CFend"}); |
| cf_end->AddEdge(v); |
| return cf_end; |
| } |
| return cf; |
| }, |
| |
| [&](const ast::CallStatement* c) { |
| auto [cf1, _] = ProcessCall(cf, c->expr); |
| return cf1; |
| }, |
| |
| [&](const ast::CompoundAssignmentStatement* c) { |
| // The compound assignment statement `a += b` is equivalent to: |
| // let p = &a; |
| // *p = *p + b; |
| |
| // Evaluate the LHS. |
| auto [cf1, l1, ident] = ProcessLValueExpression(cf, c->lhs); |
| |
| // Get the current value loaded from the LHS reference before evaluating the RHS. |
| auto* lhs_load = current_function_->variables.Get(ident); |
| |
| // Evaluate the RHS. |
| auto [cf2, v2] = ProcessExpression(cf1, c->rhs); |
| |
| // Create a node for the resulting value. |
| auto* result = CreateNode({"binary_expr_result"}); |
| result->AddEdge(v2); |
| if (lhs_load) { |
| result->AddEdge(lhs_load); |
| } |
| |
| // Update the variable node for the LHS variable. |
| l1->AddEdge(result); |
| current_function_->variables.Set(ident, l1); |
| |
| return cf2; |
| }, |
| |
| [&](const ast::ContinueStatement* c) { |
| // Find the loop statement that we are in. |
| auto* parent = sem_.Get(c) |
| ->FindFirstParent<sem::LoopStatement, sem::ForLoopStatement, |
| sem::WhileStatement>(); |
| auto& info = current_function_->LoopSwitchInfoFor(parent); |
| |
| // Propagate assignments to the loop input nodes. |
| for (auto v : info.var_in_nodes) { |
| auto* in_node = v.value; |
| auto* out_node = current_function_->variables.Get(v.key); |
| if (out_node != in_node) { |
| in_node->AddEdge(out_node); |
| } |
| } |
| return cf; |
| }, |
| |
| [&](const ast::DiscardStatement*) { return cf; }, |
| |
| [&](const ast::ForLoopStatement* f) { |
| auto* sem_loop = sem_.Get(f); |
| auto* cfx = CreateNode({"loop_start"}); |
| |
| // Insert the initializer before the loop. |
| auto* cf_init = cf; |
| if (f->initializer) { |
| cf_init = ProcessStatement(cf, f->initializer); |
| } |
| auto* cf_start = cf_init; |
| |
| auto& info = current_function_->LoopSwitchInfoFor(sem_loop); |
| info.type = "forloop"; |
| |
| // Create input nodes for any variables declared before this loop. |
| for (auto& v : current_function_->local_var_decls) { |
| auto* in_node = CreateNode({NameFor(v), "_value_forloop_in"}); |
| in_node->AddEdge(current_function_->variables.Get(v)); |
| info.var_in_nodes.Replace(v, in_node); |
| current_function_->variables.Set(v, in_node); |
| } |
| |
| // Insert the condition at the start of the loop body. |
| if (f->condition) { |
| auto [cf_cond, v] = ProcessExpression(cfx, f->condition); |
| auto* cf_condition_end = CreateNode({"for_condition_CFend"}, f); |
| cf_condition_end->affects_control_flow = true; |
| cf_condition_end->AddEdge(v); |
| cf_start = cf_condition_end; |
| |
| // Propagate assignments to the loop exit nodes. |
| for (auto& var : current_function_->local_var_decls) { |
| auto* exit_node = info.var_exit_nodes.GetOrAdd(var, [&] { |
| auto name = NameFor(var); |
| return CreateNode({name, "_value_", info.type, "_exit"}); |
| }); |
| exit_node->AddEdge(current_function_->variables.Get(var)); |
| } |
| } |
| auto* cf1 = ProcessStatement(cf_start, f->body); |
| |
| // Insert the continuing statement at the end of the loop body. |
| if (f->continuing) { |
| auto* cf2 = ProcessStatement(cf1, f->continuing); |
| cfx->AddEdge(cf2); |
| } else { |
| cfx->AddEdge(cf1); |
| } |
| cfx->AddEdge(cf); |
| |
| // Add edges from variable loop input nodes to their values at the end of the loop. |
| for (auto& v : info.var_in_nodes) { |
| auto* in_node = v.value; |
| auto* out_node = current_function_->variables.Get(v.key); |
| if (out_node != in_node) { |
| in_node->AddEdge(out_node); |
| } |
| } |
| |
| // Set each variable's exit node as its value in the outer scope. |
| for (auto& v : info.var_exit_nodes) { |
| current_function_->variables.Set(v.key, v.value); |
| } |
| |
| if (f->initializer) { |
| // Remove variables declared in the for-loop initializer from the current scope. |
| if (auto* decl = f->initializer->As<ast::VariableDeclStatement>()) { |
| current_function_->local_var_decls.Remove(sem_.Get(decl->variable)); |
| } |
| } |
| |
| current_function_->RemoveLoopSwitchInfoFor(sem_loop); |
| |
| if (sem_loop->Behaviors() == sem::Behaviors{sem::Behavior::kNext}) { |
| return cf; |
| } else { |
| return cfx; |
| } |
| }, |
| |
| [&](const ast::WhileStatement* w) { |
| auto* sem_loop = sem_.Get(w); |
| auto* cfx = CreateNode({"loop_start"}); |
| |
| auto* cf_start = cf; |
| |
| auto& info = current_function_->LoopSwitchInfoFor(sem_loop); |
| info.type = "whileloop"; |
| |
| // Create input nodes for any variables declared before this loop. |
| for (auto& v : current_function_->local_var_decls) { |
| auto* in_node = CreateNode({NameFor(v), "_value_forloop_in"}); |
| in_node->AddEdge(current_function_->variables.Get(v)); |
| info.var_in_nodes.Replace(v, in_node); |
| current_function_->variables.Set(v, in_node); |
| } |
| |
| // Insert the condition at the start of the loop body. |
| { |
| auto [cf_cond, v] = ProcessExpression(cfx, w->condition); |
| auto* cf_condition_end = CreateNode({"while_condition_CFend"}, w); |
| cf_condition_end->affects_control_flow = true; |
| cf_condition_end->AddEdge(v); |
| cf_start = cf_condition_end; |
| } |
| |
| // Propagate assignments to the loop exit nodes. |
| for (auto& var : current_function_->local_var_decls) { |
| auto* exit_node = info.var_exit_nodes.GetOrAdd(var, [&] { |
| auto name = NameFor(var); |
| return CreateNode({name, "_value_", info.type, "_exit"}); |
| }); |
| exit_node->AddEdge(current_function_->variables.Get(var)); |
| } |
| auto* cf1 = ProcessStatement(cf_start, w->body); |
| cfx->AddEdge(cf1); |
| cfx->AddEdge(cf); |
| |
| // Add edges from variable loop input nodes to their values at the end of the loop. |
| for (auto v : info.var_in_nodes) { |
| auto* in_node = v.value; |
| auto* out_node = current_function_->variables.Get(v.key); |
| if (out_node != in_node) { |
| in_node->AddEdge(out_node); |
| } |
| } |
| |
| // Set each variable's exit node as its value in the outer scope. |
| for (auto v : info.var_exit_nodes) { |
| current_function_->variables.Set(v.key, v.value); |
| } |
| |
| current_function_->RemoveLoopSwitchInfoFor(sem_loop); |
| |
| if (sem_loop->Behaviors() == sem::Behaviors{sem::Behavior::kNext}) { |
| return cf; |
| } else { |
| return cfx; |
| } |
| }, |
| |
| [&](const ast::IfStatement* i) { |
| auto* sem_if = sem_.Get(i); |
| auto [_, v_cond] = ProcessExpression(cf, i->condition); |
| |
| // Add a diagnostic node to capture the control flow change. |
| auto* v = CreateNode({"if_stmt"}, i); |
| v->affects_control_flow = true; |
| v->AddEdge(v_cond); |
| |
| Hashmap<const sem::Variable*, Node*, 4> true_vars; |
| Hashmap<const sem::Variable*, Node*, 4> false_vars; |
| |
| // Helper to process a statement with a new scope for variable assignments. |
| // Populates `assigned_vars` with new nodes for any variables that are assigned in |
| // this statement. |
| auto process_in_scope = |
| [&](Node* cf_in, const ast::Statement* s, |
| Hashmap<const sem::Variable*, Node*, 4>& assigned_vars) { |
| // Push a new scope for variable assignments. |
| current_function_->variables.Push(); |
| |
| // Process the statement. |
| auto* cf_out = ProcessStatement(cf_in, s); |
| |
| assigned_vars = current_function_->variables.Top(); |
| |
| // Pop the scope and return. |
| current_function_->variables.Pop(); |
| return cf_out; |
| }; |
| |
| auto* cf1 = process_in_scope(v, i->body, true_vars); |
| |
| bool true_has_next = sem_.Get(i->body)->Behaviors().Contains(sem::Behavior::kNext); |
| bool false_has_next = true; |
| |
| Node* cf2 = nullptr; |
| if (i->else_statement) { |
| cf2 = process_in_scope(v, i->else_statement, false_vars); |
| |
| false_has_next = |
| sem_.Get(i->else_statement)->Behaviors().Contains(sem::Behavior::kNext); |
| } |
| |
| // Update values for any variables assigned in the if or else blocks. |
| for (auto& var : current_function_->local_var_decls) { |
| // Skip variables not assigned in either block. |
| if (!true_vars.Contains(var) && !false_vars.Contains(var)) { |
| continue; |
| } |
| |
| // Create an exit node for the variable. |
| auto* out_node = CreateNode({NameFor(var), "_value_if_exit"}); |
| |
| // Add edges to the assigned value or the initial value. |
| // Only add edges if the behavior for that block contains 'Next'. |
| if (true_has_next) { |
| if (true_vars.Contains(var)) { |
| out_node->AddEdge(*true_vars.Get(var)); |
| } else { |
| out_node->AddEdge(current_function_->variables.Get(var)); |
| } |
| } |
| if (false_has_next) { |
| if (false_vars.Contains(var)) { |
| out_node->AddEdge(*false_vars.Get(var)); |
| } else { |
| out_node->AddEdge(current_function_->variables.Get(var)); |
| } |
| } |
| |
| current_function_->variables.Set(var, out_node); |
| } |
| |
| if (sem_if->Behaviors() != sem::Behaviors{sem::Behavior::kNext}) { |
| auto* cf_end = CreateNode({"if_CFend"}); |
| cf_end->AddEdge(cf1); |
| if (cf2) { |
| cf_end->AddEdge(cf2); |
| } |
| return cf_end; |
| } |
| return cf; |
| }, |
| |
| [&](const ast::IncrementDecrementStatement* i) { |
| // The increment/decrement statement `i++` is equivalent to `i = i + 1`. |
| |
| // Evaluate the LHS. |
| auto [cf1, l1, ident] = ProcessLValueExpression(cf, i->lhs); |
| |
| // Get the current value loaded from the LHS reference. |
| auto* lhs_load = current_function_->variables.Get(ident); |
| |
| // Create a node for the resulting value. |
| auto* result = CreateNode({"incdec_result"}); |
| result->AddEdge(cf1); |
| if (lhs_load) { |
| result->AddEdge(lhs_load); |
| } |
| |
| // Update the variable node for the LHS variable. |
| l1->AddEdge(result); |
| current_function_->variables.Set(ident, l1); |
| |
| return cf1; |
| }, |
| |
| [&](const ast::LoopStatement* l) { |
| auto* sem_loop = sem_.Get(l); |
| auto* cfx = CreateNode({"loop_start"}); |
| |
| auto& info = current_function_->LoopSwitchInfoFor(sem_loop); |
| info.type = "loop"; |
| |
| // Create input nodes for any variables declared before this loop. |
| for (auto& v : current_function_->local_var_decls) { |
| auto name = NameFor(v); |
| auto* in_node = CreateNode({name, "_value_loop_in"}, v->Declaration()); |
| in_node->AddEdge(current_function_->variables.Get(v)); |
| info.var_in_nodes.Replace(v, in_node); |
| current_function_->variables.Set(v, in_node); |
| } |
| |
| // Note: The continuing block is processed as a special case at the end of |
| // processing the loop body BlockStatement. This is so that variable declarations |
| // inside the loop body are visible to the continuing statement. |
| auto* cf1 = ProcessStatement(cfx, l->body); |
| cfx->AddEdge(cf1); |
| cfx->AddEdge(cf); |
| |
| // Add edges from variable loop input nodes to their values at the end of the loop. |
| for (auto v : info.var_in_nodes) { |
| auto* in_node = v.value; |
| auto* out_node = current_function_->variables.Get(v.key); |
| if (out_node != in_node) { |
| in_node->AddEdge(out_node); |
| } |
| } |
| |
| // Set each variable's exit node as its value in the outer scope. |
| for (auto v : info.var_exit_nodes) { |
| current_function_->variables.Set(v.key, v.value); |
| } |
| |
| current_function_->RemoveLoopSwitchInfoFor(sem_loop); |
| |
| if (sem_loop->Behaviors() == sem::Behaviors{sem::Behavior::kNext}) { |
| return cf; |
| } else { |
| return cfx; |
| } |
| }, |
| |
| [&](const ast::ReturnStatement* r) { |
| Node* cf_ret; |
| if (r->value) { |
| auto [cf1, v] = ProcessExpression(cf, r->value); |
| current_function_->value_return->AddEdge(v); |
| cf_ret = cf1; |
| } else { |
| TINT_ASSERT(cf != nullptr); |
| cf_ret = cf; |
| } |
| |
| // Add edges from each pointer parameter output to its current value. |
| for (auto& param : current_function_->parameters) { |
| if (param.ptr_output_contents) { |
| param.ptr_output_contents->AddEdge( |
| current_function_->variables.Get(param.sem)); |
| } |
| } |
| |
| return cf_ret; |
| }, |
| |
| [&](const ast::SwitchStatement* s) { |
| auto* sem_switch = sem_.Get(s); |
| auto [cfx, v_cond] = ProcessExpression(cf, s->condition); |
| |
| // Add a diagnostic node to capture the control flow change. |
| auto* v = CreateNode({"switch_stmt"}, s); |
| v->affects_control_flow = true; |
| v->AddEdge(v_cond); |
| |
| Node* cf_end = nullptr; |
| if (sem_switch->Behaviors() != sem::Behaviors{sem::Behavior::kNext}) { |
| cf_end = CreateNode({"switch_CFend"}); |
| } |
| |
| auto& info = current_function_->LoopSwitchInfoFor(sem_switch); |
| info.type = "switch"; |
| |
| auto* cf_n = v; |
| for (auto* c : s->body) { |
| auto* sem_case = sem_.Get(c); |
| |
| current_function_->variables.Push(); |
| cf_n = ProcessStatement(v, c->body); |
| |
| if (cf_end) { |
| cf_end->AddEdge(cf_n); |
| } |
| |
| if (sem_case->Behaviors().Contains(sem::Behavior::kNext)) { |
| // Propagate variable values to the switch exit nodes. |
| for (auto& var : current_function_->local_var_decls) { |
| // Skip variables that were declared inside the switch. |
| if (auto* lv = var->As<sem::LocalVariable>(); |
| lv && lv->Statement()->FindFirstParent( |
| [&](auto* st) { return st == sem_switch; })) { |
| continue; |
| } |
| |
| // Add an edge from the variable exit node to its new value. |
| auto* exit_node = info.var_exit_nodes.GetOrAdd(var, [&] { |
| auto name = NameFor(var); |
| return CreateNode({name, "_value_", info.type, "_exit"}); |
| }); |
| exit_node->AddEdge(current_function_->variables.Get(var)); |
| } |
| } |
| current_function_->variables.Pop(); |
| } |
| |
| // Update nodes for any variables assigned in the switch statement. |
| for (auto var : info.var_exit_nodes) { |
| current_function_->variables.Set(var.key, var.value); |
| } |
| |
| return cf_end ? cf_end : cf; |
| }, |
| |
| [&](const ast::VariableDeclStatement* decl) { |
| Node* node; |
| auto* sem_var = sem_.Get(decl->variable); |
| if (decl->variable->initializer) { |
| auto [cf1, v] = ProcessExpression(cf, decl->variable->initializer); |
| cf = cf1; |
| node = v; |
| |
| // Store if lhs is a partial pointer |
| if (sem_var->Type()->Is<core::type::Pointer>()) { |
| auto* init = sem_.Get(decl->variable->initializer); |
| if (auto* unary_init = init->Declaration()->As<ast::UnaryOpExpression>()) { |
| auto* e = UnwrapIndirectAndAddressOfChain(unary_init); |
| if (e->Is<ast::AccessorExpression>()) { |
| current_function_->partial_ptrs.Add(sem_var); |
| } |
| } |
| } |
| } else { |
| node = cf; |
| } |
| current_function_->variables.Set(sem_var, node); |
| |
| if (decl->variable->Is<ast::Var>()) { |
| current_function_->local_var_decls.Add( |
| sem_.Get<sem::LocalVariable>(decl->variable)); |
| } |
| |
| return cf; |
| }, |
| |
| [&](const ast::ConstAssert*) { |
| return cf; // No impact on uniformity |
| }, |
| |
| TINT_ICE_ON_NO_MATCH); |
| } |
| |
| /// Process an identifier expression. |
| /// @param cf the input control flow node |
| /// @param ident the identifier expression to process |
| /// @param load_rule true if the load rule is being invoked on this identifier |
| /// @returns a pair of (control flow node, value node) |
| std::pair<Node*, Node*> ProcessIdentExpression(Node* cf, |
| const ast::IdentifierExpression* ident, |
| bool load_rule = false) { |
| // Helper to check if the entry point attribute of `obj` indicates non-uniformity. |
| auto has_nonuniform_entry_point_attribute = [&](auto* obj) { |
| // Only the num_workgroups and workgroup_id builtins are uniform. |
| if (auto* builtin_attr = ast::GetAttribute<ast::BuiltinAttribute>(obj->attributes)) { |
| auto builtin = b.Sem().Get(builtin_attr)->Value(); |
| if (builtin == core::BuiltinValue::kNumWorkgroups || |
| builtin == core::BuiltinValue::kWorkgroupId) { |
| return false; |
| } |
| } |
| return true; |
| }; |
| |
| auto* node = CreateNode({NameFor(ident), "_ident_expr"}, ident); |
| auto* sem_ident = sem_.GetVal(ident); |
| TINT_ASSERT(sem_ident); |
| auto* var_user = sem_ident->Unwrap()->As<sem::VariableUser>(); |
| auto* sem = var_user->Variable(); |
| return Switch( |
| sem, |
| |
| [&](const sem::Parameter* param) { |
| auto* user_func = param->Owner()->As<sem::Function>(); |
| if (user_func && user_func->Declaration()->IsEntryPoint()) { |
| if (auto* str = param->Type()->As<sem::Struct>()) { |
| // We consider the whole struct to be non-uniform if any one of its members |
| // is non-uniform. |
| bool uniform = true; |
| for (auto* member : str->Members()) { |
| if (has_nonuniform_entry_point_attribute(member->Declaration())) { |
| uniform = false; |
| } |
| } |
| node->AddEdge(uniform ? cf : current_function_->may_be_non_uniform); |
| return std::make_pair(cf, node); |
| } else { |
| if (has_nonuniform_entry_point_attribute(param->Declaration())) { |
| node->AddEdge(current_function_->may_be_non_uniform); |
| } else { |
| node->AddEdge(cf); |
| } |
| return std::make_pair(cf, node); |
| } |
| } else { |
| node->AddEdge(cf); |
| |
| auto* current_value = current_function_->variables.Get(param); |
| if (auto* ptr = param->Type()->As<core::type::Pointer>()) { |
| if (load_rule) { |
| if (ptr->AddressSpace() == core::AddressSpace::kFunction || |
| ptr->Access() == core::Access::kRead) { |
| // We are loading from a pointer to a function-scope variable or an |
| // immutable module-scope variable, so add an edge to its contents. |
| node->AddEdge(current_value); |
| } else { |
| // We are loading from a pointer to a mutable module-scope variable, |
| // which always has non-uniform contents. |
| node->AddEdge(current_function_->may_be_non_uniform); |
| } |
| } else { |
| // This is a pointer parameter that we are not loading from, so add an |
| // edge to the pointer value itself. |
| node->AddEdge(current_function_->parameters[param->Index()].value); |
| } |
| } else { |
| // The parameter is a value, so add an edge to it. |
| node->AddEdge(current_value); |
| } |
| |
| return std::make_pair(cf, node); |
| } |
| }, |
| |
| [&](const sem::GlobalVariable* global) { |
| // Loads from global read-write variables may be non-uniform. |
| if (global->Declaration()->Is<ast::Var>() && |
| global->Access() != core::Access::kRead && load_rule) { |
| node->AddEdge(current_function_->may_be_non_uniform); |
| } else { |
| node->AddEdge(cf); |
| } |
| return std::make_pair(cf, node); |
| }, |
| |
| [&](const sem::LocalVariable* local) { |
| node->AddEdge(cf); |
| |
| auto* local_value = current_function_->variables.Get(local); |
| if (local->Type()->Is<core::type::Pointer>()) { |
| if (load_rule) { |
| // We are loading from the pointer, so add an edge to its contents. |
| auto* root = var_user->RootIdentifier(); |
| if (root->Is<sem::GlobalVariable>()) { |
| if (root->Access() != core::Access::kRead) { |
| // The contents of a mutable global variable is always non-uniform. |
| node->AddEdge(current_function_->may_be_non_uniform); |
| } |
| } else { |
| node->AddEdge(current_function_->variables.Get(root)); |
| } |
| |
| // The uniformity of the contents also depends on the uniformity of the |
| // pointer itself. For a pointer captured in a let declaration, this will |
| // come from the value node of that declaration. |
| node->AddEdge(local_value); |
| } else { |
| // The variable is a pointer that we are not loading from, so add an edge to |
| // the pointer value itself. |
| node->AddEdge(local_value); |
| } |
| } else if (local->Type()->Is<core::type::Reference>()) { |
| if (load_rule) { |
| // We are loading from the reference, so add an edge to its contents. |
| node->AddEdge(local_value); |
| } else { |
| // References to local variables (i.e. var declarations) are always uniform, |
| // so no other edges needed. |
| } |
| } else { |
| // The identifier is a value declaration, so add an edge to it. |
| node->AddEdge(local_value); |
| } |
| |
| return std::make_pair(cf, node); |
| }, |
| |
| TINT_ICE_ON_NO_MATCH); |
| } |
| |
| /// Process an expression. |
| /// @param cf the input control flow node |
| /// @param expr the expression to process |
| /// @param load_rule true if the load rule is being invoked on this expression |
| /// @returns a pair of (control flow node, value node) |
| std::pair<Node*, Node*> ProcessExpression(Node* cf, |
| const ast::Expression* expr, |
| bool load_rule = false) { |
| if (sem_.Get<sem::Load>(expr)) { |
| // Set the load-rule flag to indicate that identifier expressions in this sub-tree |
| // should add edges to the contents of the variables that they refer to. |
| load_rule = true; |
| } |
| |
| return Switch( |
| expr, |
| |
| [&](const ast::BinaryExpression* e) { |
| if (e->IsLogical()) { |
| // Short-circuiting binary operators are a special case. |
| auto [cf1, v1] = ProcessExpression(cf, e->lhs); |
| |
| // Add a diagnostic node to capture the control flow change. |
| auto* v1_cf = CreateNode({"short_circuit_op"}, e); |
| v1_cf->affects_control_flow = true; |
| v1_cf->AddEdge(v1); |
| |
| auto [cf2, v2] = ProcessExpression(v1_cf, e->rhs); |
| return std::pair<Node*, Node*>(cf, v2); |
| } else { |
| auto [cf1, v1] = ProcessExpression(cf, e->lhs); |
| auto [cf2, v2] = ProcessExpression(cf1, e->rhs); |
| auto* result = CreateNode({"binary_expr_result"}, e); |
| result->AddEdge(v1); |
| result->AddEdge(v2); |
| return std::pair<Node*, Node*>(cf2, result); |
| } |
| }, |
| |
| [&](const ast::CallExpression* c) { return ProcessCall(cf, c); }, |
| |
| [&](const ast::IdentifierExpression* i) { |
| return ProcessIdentExpression(cf, i, load_rule); |
| }, |
| |
| [&](const ast::IndexAccessorExpression* i) { |
| auto [cf1, v1] = ProcessExpression(cf, i->object, load_rule); |
| auto [cf2, v2] = ProcessExpression(cf1, i->index); |
| auto* result = CreateNode({"index_accessor_result"}); |
| result->AddEdge(v1); |
| result->AddEdge(v2); |
| return std::pair<Node*, Node*>(cf2, result); |
| }, |
| |
| [&](const ast::LiteralExpression*) { return std::make_pair(cf, cf); }, |
| |
| [&](const ast::MemberAccessorExpression* m) { |
| return ProcessExpression(cf, m->object, load_rule); |
| }, |
| |
| [&](const ast::UnaryOpExpression* u) { |
| return ProcessExpression(cf, u->expr, load_rule); |
| }, |
| |
| TINT_ICE_ON_NO_MATCH); |
| } |
| |
| /// @param u unary expression with op == kIndirection |
| /// @returns true if `u` is an indirection unary expression that ultimately dereferences a |
| /// partial pointer, false otherwise. |
| bool IsDerefOfPartialPointer(const ast::UnaryOpExpression* u) { |
| TINT_ASSERT(u->op == core::UnaryOp::kIndirection); |
| |
| // To determine if we're dereferencing a partial pointer, unwrap *& |
| // chains; if the final expression is an identifier, see if it's a |
| // partial pointer. If it's not an identifier, then it must be an |
| // index/member accessor expression, and thus a partial pointer. |
| auto* e = UnwrapIndirectAndAddressOfChain(u); |
| if (auto* var_user = sem_.Get<sem::VariableUser>(e)) { |
| if (current_function_->partial_ptrs.Contains(var_user->Variable())) { |
| return true; |
| } |
| } else { |
| TINT_ASSERT(e->Is<ast::AccessorExpression>()); |
| return true; |
| } |
| return false; |
| } |
| |
| /// LValue holds the Nodes returned by ProcessLValueExpression() |
| struct LValue { |
| /// The control-flow node for an LValue expression |
| Node* cf = nullptr; |
| |
| /// The new value node for an LValue expression |
| Node* new_val = nullptr; |
| |
| /// The root identifier for an LValue expression. |
| const sem::Variable* root_identifier = nullptr; |
| }; |
| |
| /// Process an LValue expression. |
| /// @param cf the input control flow node |
| /// @param expr the expression to process |
| /// @param is_dereferencing `true` if we are dereferencing a pointer |
| /// @param is_partial_reference `true` if we are referencing a subset of a variable |
| /// @returns a tuple of (control flow node, variable node, root identifier) |
| LValue ProcessLValueExpression(Node* cf, |
| const ast::Expression* expr, |
| bool is_dereferencing = false, |
| bool is_partial_reference = false) { |
| return Switch( |
| expr, |
| |
| [&](const ast::IdentifierExpression* i) { |
| auto* sem = sem_.GetVal(i)->UnwrapLoad()->As<sem::VariableUser>(); |
| auto result = Switch( |
| sem->Variable(), |
| [&](const sem::GlobalVariable*) { |
| // Pointers cannot be stored in module-scope variables, so we should never |
| // be dereferencing here. |
| TINT_ASSERT(!is_dereferencing); |
| |
| return LValue{cf, current_function_->may_be_non_uniform, nullptr}; |
| }, |
| [&](const sem::LocalVariable* local) { |
| Node* value = nullptr; |
| const sem::Variable* root_ident = local; |
| if (is_dereferencing) { |
| // If we are dereferencing then we must have a pointer, and the only |
| // declaration that can hold a pointer is a `let`. |
| TINT_ASSERT(local->Declaration()->Is<ast::Let>() && |
| local->Type()->Is<core::type::Pointer>()); |
| |
| // Determine the root identifier for the contents of the pointer. |
| root_ident = local->Initializer()->RootIdentifier(); |
| |
| // Create a new value node for the contents of the pointer. |
| value = CreateNode({NameFor(root_ident), "_contents"}); |
| |
| // The uniformity of the value depends on the pointer itself. |
| value->AddEdge(current_function_->variables.Get(local)); |
| } else { |
| // Create a new value node for this variable. |
| value = CreateNode({NameFor(i), "_lvalue"}); |
| } |
| |
| return LValue{cf, value, root_ident}; |
| }, |
| [&](const sem::Parameter* param) { |
| // Parameters can only be LValues when we are dereferencing a pointer. |
| TINT_ASSERT(is_dereferencing && param->Type()->Is<core::type::Pointer>()); |
| |
| // Create a new value node for the contents of the pointer. |
| auto* value = CreateNode({NameFor(i), "_contents"}); |
| |
| // The uniformity of the value depends on the pointer itself. |
| value->AddEdge(current_function_->parameters[param->Index()].value); |
| |
| return LValue{cf, value, param}; |
| }, |
| [&](Default) { |
| TINT_ICE() << "unknown lvalue identifier expression type: " |
| << std::string(sem->Variable()->TypeInfo().name); |
| return LValue{}; |
| }); |
| |
| // If the identifier is part of an expression that is a partial reference to a |
| // variable (e.g. index or member access), we link back to the variable's previous |
| // value. If the previous value was non-uniform, a partial assignment will not make |
| // it uniform. |
| auto* old_value = current_function_->variables.Get(result.root_identifier); |
| if (is_partial_reference && old_value) { |
| result.new_val->AddEdge(old_value); |
| } |
| |
| return result; |
| }, |
| |
| [&](const ast::IndexAccessorExpression* i) { |
| // If the source object is a pointer, there is an implicit dereference due to the |
| // pointer_composite_access language feature. |
| is_dereferencing = |
| is_dereferencing || sem_.GetVal(i->object)->Type()->Is<core::type::Pointer>(); |
| |
| auto [cf1, l1, root_ident] = |
| ProcessLValueExpression(cf, i->object, is_dereferencing, |
| /*is_partial_reference*/ true); |
| auto [cf2, v2] = ProcessExpression(cf1, i->index); |
| l1->AddEdge(v2); |
| return LValue{cf2, l1, root_ident}; |
| }, |
| |
| [&](const ast::MemberAccessorExpression* m) { |
| // If the source object is a pointer, there is an implicit dereference due to the |
| // pointer_composite_access language feature. |
| is_dereferencing = |
| is_dereferencing || sem_.GetVal(m->object)->Type()->Is<core::type::Pointer>(); |
| |
| return ProcessLValueExpression(cf, m->object, is_dereferencing, |
| /*is_partial_reference*/ true); |
| }, |
| |
| [&](const ast::UnaryOpExpression* u) { |
| if (u->op == core::UnaryOp::kIndirection) { |
| return ProcessLValueExpression( |
| cf, u->expr, |
| /* is_dereferencing */ true, |
| /* is_partial_reference */ is_partial_reference || |
| IsDerefOfPartialPointer(u)); |
| } |
| return ProcessLValueExpression(cf, u->expr, |
| /* is_dereferencing */ false, |
| /* is_partial_reference */ is_partial_reference); |
| }, |
| |
| TINT_ICE_ON_NO_MATCH); |
| } |
| |
| /// Process a function call expression. |
| /// @param cf the input control flow node |
| /// @param call the function call to process |
| /// @returns a pair of (control flow node, value node) |
| std::pair<Node*, Node*> ProcessCall(Node* cf, const ast::CallExpression* call) { |
| std::string name = NameFor(call->target); |
| |
| // Process call arguments |
| Node* cf_last_arg = cf; |
| Vector<Node*, 8> args; |
| Vector<Node*, 8> ptrarg_contents; |
| ptrarg_contents.Resize(call->args.Length()); |
| for (size_t i = 0; i < call->args.Length(); i++) { |
| auto [cf_i, arg_i] = ProcessExpression(cf_last_arg, call->args[i]); |
| |
| // Capture the index of this argument in a new node. |
| // Note: This is an additional node that isn't described in the specification, for the |
| // purpose of providing diagnostic information. |
| Node* arg_node = CreateNode({name, "_arg_", std::to_string(i)}, call); |
| arg_node->type = Node::kFunctionCallArgumentValue; |
| arg_node->arg_index = static_cast<uint32_t>(i); |
| arg_node->AddEdge(arg_i); |
| |
| // For pointer arguments, create an additional node to represent the contents of that |
| // pointer prior to the function call. |
| auto* sem_arg = sem_.GetVal(call->args[i]); |
| if (sem_arg->Type()->Is<core::type::Pointer>()) { |
| auto* arg_contents = |
| CreateNode({name, "_ptrarg_", std::to_string(i), "_contents"}, call); |
| arg_contents->type = Node::kFunctionCallArgumentContents; |
| arg_contents->arg_index = static_cast<uint32_t>(i); |
| |
| auto* root = sem_arg->RootIdentifier(); |
| if (root->Is<sem::GlobalVariable>()) { |
| if (root->Access() != core::Access::kRead) { |
| // The contents of a mutable global variable is always non-uniform. |
| arg_contents->AddEdge(current_function_->may_be_non_uniform); |
| } |
| } else { |
| arg_contents->AddEdge(current_function_->variables.Get(root)); |
| } |
| arg_contents->AddEdge(arg_node); |
| ptrarg_contents[i] = arg_contents; |
| } |
| |
| cf_last_arg = cf_i; |
| args.Push(arg_node); |
| } |
| |
| // Note: This is an additional node that isn't described in the specification, for the |
| // purpose of providing diagnostic information. |
| Node* call_node = CreateNode({name, "_call"}, call); |
| call_node->AddEdge(cf_last_arg); |
| |
| Node* result = CreateNode({name, "_return_value"}, call); |
| result->type = Node::kFunctionCallReturnValue; |
| Node* cf_after = CreateNode({"CF_after_", name}, call); |
| |
| auto default_severity = kUniformityFailuresAsError ? wgsl::DiagnosticSeverity::kError |
| : wgsl::DiagnosticSeverity::kWarning; |
| |
| // Get tags for the callee. |
| CallSiteTag callsite_tag = {CallSiteTag::CallSiteNoRestriction}; |
| FunctionTag function_tag = NoRestriction; |
| auto* sem = SemCall(call); |
| const FunctionInfo* func_info = nullptr; |
| Switch( |
| sem->Target(), |
| [&](const sem::BuiltinFn* builtin) { |
| // Most builtins have no restrictions. The exceptions are barriers, derivatives, |
| // some texture sampling builtins, and atomics. |
| if (builtin->IsBarrier()) { |
| callsite_tag = {CallSiteTag::CallSiteRequiredToBeUniform, default_severity}; |
| } else if (builtin->Fn() == wgsl::BuiltinFn::kWorkgroupUniformLoad) { |
| callsite_tag = {CallSiteTag::CallSiteRequiredToBeUniform, default_severity}; |
| } else if (builtin->IsDerivative() || |
| builtin->Fn() == wgsl::BuiltinFn::kTextureSample || |
| builtin->Fn() == wgsl::BuiltinFn::kTextureSampleBias || |
| builtin->Fn() == wgsl::BuiltinFn::kTextureSampleCompare) { |
| // Get the severity of derivative uniformity violations in this context. |
| auto severity = sem_.DiagnosticSeverity( |
| call, wgsl::CoreDiagnosticRule::kDerivativeUniformity); |
| if (severity != wgsl::DiagnosticSeverity::kOff) { |
| callsite_tag = {CallSiteTag::CallSiteRequiredToBeUniform, severity}; |
| } |
| function_tag = ReturnValueMayBeNonUniform; |
| } else if (builtin->IsAtomic()) { |
| callsite_tag = {CallSiteTag::CallSiteNoRestriction}; |
| function_tag = ReturnValueMayBeNonUniform; |
| } else if (builtin->Fn() == wgsl::BuiltinFn::kTextureLoad) { |
| // Loading from a read-write storage texture may produce a non-uniform value. |
| auto* storage = |
| builtin->Parameters()[0]->Type()->As<core::type::StorageTexture>(); |
| if (storage && storage->access() == core::Access::kReadWrite) { |
| callsite_tag = {CallSiteTag::CallSiteNoRestriction}; |
| function_tag = ReturnValueMayBeNonUniform; |
| } |
| } |
| }, |
| [&](const sem::Function* func) { |
| // We must have already analyzed the user-defined function since we process |
| // functions in dependency order. |
| auto info = functions_.Get(func->Declaration()); |
| TINT_ASSERT(info); |
| callsite_tag = info->callsite_tag; |
| function_tag = info->function_tag; |
| func_info = info.value; |
| }, |
| [&](const sem::ValueConstructor*) { |
| callsite_tag = {CallSiteTag::CallSiteNoRestriction}; |
| function_tag = NoRestriction; |
| }, |
| [&](const sem::ValueConversion*) { |
| callsite_tag = {CallSiteTag::CallSiteNoRestriction}; |
| function_tag = NoRestriction; |
| }, // |
| TINT_ICE_ON_NO_MATCH); |
| |
| cf_after->AddEdge(call_node); |
| |
| if (function_tag == ReturnValueMayBeNonUniform) { |
| result->AddEdge(current_function_->may_be_non_uniform); |
| } |
| |
| result->AddEdge(cf_after); |
| |
| // For each argument, add edges based on parameter tags. |
| for (size_t i = 0; i < args.Length(); i++) { |
| if (func_info) { |
| auto& param_info = func_info->parameters[i]; |
| |
| // Capture the direct uniformity requirements. |
| switch (param_info.tag_direct.tag) { |
| case ParameterTag::ParameterValueRequiredToBeUniform: |
| current_function_->RequiredToBeUniform(param_info.tag_direct.severity) |
| ->AddEdge(args[i]); |
| break; |
| case ParameterTag::ParameterContentsRequiredToBeUniform: { |
| current_function_->RequiredToBeUniform(param_info.tag_direct.severity) |
| ->AddEdge(ptrarg_contents[i]); |
| break; |
| } |
| case ParameterTag::ParameterNoRestriction: |
| break; |
| } |
| // Capture the effects of this parameter on the return value. |
| switch (param_info.tag_retval.tag) { |
| case ParameterTag::ParameterValueRequiredToBeUniform: |
| result->AddEdge(args[i]); |
| break; |
| case ParameterTag::ParameterContentsRequiredToBeUniform: { |
| result->AddEdge(ptrarg_contents[i]); |
| break; |
| } |
| case ParameterTag::ParameterNoRestriction: |
| break; |
| } |
| |
| // Capture the effects of other call parameters on the contents of this parameter |
| // after the call returns. |
| auto* sem_arg = sem_.GetVal(call->args[i]); |
| if (sem_arg->Type()->Is<core::type::Pointer>()) { |
| auto* ptr_result = |
| CreateNode({name, "_ptrarg_", std::to_string(i), "_result"}, call); |
| ptr_result->type = Node::kFunctionCallPointerArgumentResult; |
| ptr_result->arg_index = static_cast<uint32_t>(i); |
| if (param_info.pointer_may_become_non_uniform) { |
| ptr_result->AddEdge(current_function_->may_be_non_uniform); |
| } else { |
| // Add edge to the call to catch when it's called in non-uniform control |
| // flow. |
| ptr_result->AddEdge(call_node); |
| |
| // Add edges from the resulting pointer value to any other arguments that |
| // feed it. We distinguish between requirements on the source arguments |
| // value versus its contents for pointer arguments. |
| for (auto* source : param_info.ptr_output_source_param_values) { |
| ptr_result->AddEdge(args[source->Index()]); |
| } |
| for (auto* source : param_info.ptr_output_source_param_contents) { |
| ptr_result->AddEdge(ptrarg_contents[source->Index()]); |
| } |
| } |
| |
| // Update the current stored value for this pointer argument. |
| auto* root_ident = sem_arg->RootIdentifier(); |
| TINT_ASSERT(root_ident); |
| current_function_->variables.Set(root_ident, ptr_result); |
| } |
| } else { |
| auto* builtin = sem->Target()->As<sem::BuiltinFn>(); |
| if (builtin && builtin->Fn() == wgsl::BuiltinFn::kWorkgroupUniformLoad) { |
| // The workgroupUniformLoad builtin requires its parameter to be uniform. |
| current_function_->RequiredToBeUniform(default_severity)->AddEdge(args[i]); |
| } else { |
| // All other builtin function parameters are RequiredToBeUniformForReturnValue, |
| // as are parameters for value constructors and value conversions. |
| result->AddEdge(args[i]); |
| } |
| } |
| } |
| |
| // Add the callsite requirement last. |
| // We traverse edges in reverse order, so this makes the callsite requirement take highest |
| // priority when reporting violations. |
| if (callsite_tag.tag == CallSiteTag::CallSiteRequiredToBeUniform) { |
| current_function_->RequiredToBeUniform(callsite_tag.severity)->AddEdge(call_node); |
| } |
| |
| return {cf_after, result}; |
| } |
| |
| /// Traverse a graph starting at `source`, inserting all visited nodes into `reachable` and |
| /// recording which node they were reached from. |
| /// @param source the starting node |
| /// @param reachable the set of reachable nodes to populate, if required |
| void Traverse(Node* source, UniqueVector<Node*, 4>* reachable = nullptr) { |
| Vector<Node*, 8> to_visit{source}; |
| |
| while (!to_visit.IsEmpty()) { |
| auto* node = to_visit.Back(); |
| to_visit.Pop(); |
| |
| if (reachable) { |
| reachable->Add(node); |
| } |
| for (auto* to : node->edges) { |
| if (to->visited_from == nullptr) { |
| to->visited_from = node; |
| to_visit.Push(to); |
| } |
| } |
| } |
| } |
| |
| /// Trace back along a path from `start` until finding a node that matches a predicate. |
| /// @param start the starting node |
| /// @param pred the predicate function |
| /// @returns the first node found that matches the predicate, or nullptr |
| template <typename F> |
| Node* TraceBackAlongPathUntil(Node* start, F&& pred) { |
| auto* current = start; |
| while (current) { |
| if (pred(current)) { |
| break; |
| } |
| current = current->visited_from; |
| } |
| return current; |
| } |
| |
| /// Recursively descend through the function called by `call` and the functions that it calls in |
| /// order to find a call to a builtin function that requires uniformity with the given severity. |
| const ast::CallExpression* FindBuiltinThatRequiresUniformity( |
| const ast::CallExpression* call, |
| wgsl::DiagnosticSeverity severity) { |
| auto* target = SemCall(call)->Target(); |
| if (target->Is<sem::BuiltinFn>()) { |
| // This is a call to a builtin, so we must be done. |
| return call; |
| } else if (auto* user = target->As<sem::Function>()) { |
| // This is a call to a user-defined function, so inspect the functions called by that |
| // function and look for one whose node has an edge from the RequiredToBeUniform node. |
| auto target_info = functions_.Get(user->Declaration()); |
| for (auto* call_node : target_info->RequiredToBeUniform(severity)->edges) { |
| if (call_node->type == Node::kRegular) { |
| auto* child_call = call_node->ast->As<ast::CallExpression>(); |
| return FindBuiltinThatRequiresUniformity(child_call, severity); |
| } |
| } |
| TINT_UNREACHABLE() << "unable to find child call with uniformity requirement"; |
| } else { |
| TINT_UNREACHABLE() << "unexpected call expression type"; |
| } |
| return nullptr; |
| } |
| |
| /// Add diagnostic notes to show where control flow became non-uniform on the way to a node. |
| /// @param function the function being analyzed |
| /// @param required_to_be_uniform the node to traverse from |
| /// @param may_be_non_uniform the node to traverse to |
| void ShowControlFlowDivergence(FunctionInfo& function, |
| Node* required_to_be_uniform, |
| Node* may_be_non_uniform) { |
| // Traverse the graph to generate a path from the node to the source of non-uniformity. |
| function.ResetVisited(); |
| Traverse(required_to_be_uniform); |
| |
| // Get the source of the non-uniform value. |
| auto* non_uniform_source = may_be_non_uniform->visited_from; |
| TINT_ASSERT(non_uniform_source); |
| |
| // Show where the non-uniform value results in non-uniform control flow. |
| auto* control_flow = TraceBackAlongPathUntil( |
| non_uniform_source, [](Node* node) { return node->affects_control_flow; }); |
| if (control_flow) { |
| diagnostics_.AddNote(diag::System::Resolver, control_flow->ast->source) |
| << "control flow depends on possibly non-uniform value"; |
| // TODO(jrprice): There are cases where the function with uniformity requirements is not |
| // actually inside this control flow construct, for example: |
| // - A conditional interrupt (e.g. break), with a barrier elsewhere in the loop |
| // - A conditional assignment to a variable, which is later used to guard a barrier |
| // In these cases, the diagnostics are not entirely accurate as they may not highlight |
| // the actual cause of divergence. |
| } |
| |
| ShowSourceOfNonUniformity(non_uniform_source); |
| } |
| |
| /// Add a diagnostic note to show the origin of a non-uniform value. |
| /// @param non_uniform_source the node that represents a non-uniform value |
| void ShowSourceOfNonUniformity(Node* non_uniform_source) { |
| TINT_ASSERT(non_uniform_source); |
| |
| auto var_type = [&](const sem::Variable* var) { |
| switch (var->AddressSpace()) { |
| case core::AddressSpace::kStorage: |
| return "read_write storage buffer "; |
| case core::AddressSpace::kWorkgroup: |
| return "workgroup storage variable "; |
| case core::AddressSpace::kPrivate: |
| return "module-scope private variable "; |
| default: |
| return ""; |
| } |
| }; |
| auto param_type = [&](const sem::Parameter* param) { |
| if (ast::HasAttribute<ast::BuiltinAttribute>(param->Declaration()->attributes)) { |
| return "builtin "; |
| } else if (ast::HasAttribute<ast::LocationAttribute>( |
| param->Declaration()->attributes)) { |
| return "user-defined input "; |
| } else { |
| return "parameter "; |
| } |
| }; |
| |
| // Show the source of the non-uniform value. |
| Switch( |
| non_uniform_source->ast, |
| [&](const ast::IdentifierExpression* ident) { |
| auto* var = sem_.GetVal(ident)->UnwrapLoad()->As<sem::VariableUser>()->Variable(); |
| if (auto* param = var->As<sem::Parameter>()) { |
| auto* func = param->Owner()->As<sem::Function>(); |
| diagnostics_.AddNote(diag::System::Resolver, ident->source) |
| << param_type(param) << "'" << NameFor(ident) << "' of '" << NameFor(func) |
| << "' may be non-uniform"; |
| } else { |
| diagnostics_.AddNote(diag::System::Resolver, ident->source) |
| << "reading from " << var_type(var) << "'" << NameFor(ident) |
| << "' may result in a non-uniform value"; |
| } |
| }, |
| [&](const ast::Variable* v) { |
| auto* var = sem_.Get(v); |
| diagnostics_.AddNote(diag::System::Resolver, v->source) |
| << "reading from " << var_type(var) << "'" << NameFor(v) |
| << "' may result in a non-uniform value"; |
| }, |
| [&](const ast::CallExpression* c) { |
| auto target_name = NameFor(c->target); |
| switch (non_uniform_source->type) { |
| case Node::kFunctionCallReturnValue: { |
| diagnostics_.AddNote(diag::System::Resolver, c->source) |
| << "return value of '" + target_name + "' may be non-uniform"; |
| break; |
| } |
| case Node::kFunctionCallArgumentContents: { |
| auto* arg = c->args[non_uniform_source->arg_index]; |
| auto* var = sem_.GetVal(arg)->RootIdentifier(); |
| diagnostics_.AddNote(diag::System::Resolver, var->Declaration()->source) |
| << "reading from " << var_type(var) << "'" << NameFor(var) |
| << "' may result in a non-uniform value"; |
| break; |
| } |
| case Node::kFunctionCallArgumentValue: { |
| auto* arg = c->args[non_uniform_source->arg_index]; |
| // TODO(jrprice): Which output? (return value vs another pointer argument). |
| diagnostics_.AddNote(diag::System::Resolver, arg->source) |
| << "passing non-uniform pointer to '" << target_name |
| << "' may produce a non-uniform output"; |
| break; |
| } |
| case Node::kFunctionCallPointerArgumentResult: { |
| diagnostics_.AddNote(diag::System::Resolver, |
| c->args[non_uniform_source->arg_index]->source) |
| << "contents of pointer may become non-uniform after calling '" |
| << target_name << "'"; |
| break; |
| } |
| default: { |
| TINT_ICE() << "unhandled source of non-uniformity"; |
| break; |
| } |
| } |
| }, |
| [&](const ast::Expression* e) { |
| diagnostics_.AddNote(diag::System::Resolver, e->source) |
| << "result of expression may be non-uniform"; |
| }, // |
| TINT_ICE_ON_NO_MATCH); |
| } |
| |
| /// Generate a diagnostic message for a uniformity issue. |
| /// @param function the function that the diagnostic is being produced for |
| /// @param source_node the node that has caused a uniformity issue in `function` |
| /// @param severity the severity of the diagnostic |
| void MakeError(FunctionInfo& function, Node* source_node, wgsl::DiagnosticSeverity severity) { |
| // Helper to produce a diagnostic message, as a note or with the global failure severity. |
| auto report = [&](Source source, std::string msg, bool note) { |
| diag::Diagnostic error{}; |
| error.severity = note ? diag::Severity::Note : wgsl::ToSeverity(severity); |
| error.system = diag::System::Resolver; |
| error.source = source; |
| error.message = msg; |
| diagnostics_.Add(std::move(error)); |
| }; |
| |
| // Traverse the graph to generate a path from RequiredToBeUniform to the source node. |
| function.ResetVisited(); |
| Traverse(function.RequiredToBeUniform(severity)); |
| TINT_ASSERT(source_node->visited_from); |
| |
| // Find a node that is required to be uniform that has a path to the source node. |
| auto* cause = TraceBackAlongPathUntil(source_node, [&](Node* node) { |
| return node->visited_from == function.RequiredToBeUniform(severity); |
| }); |
| |
| // The node will always have a corresponding call expression. |
| auto* call = cause->ast->As<ast::CallExpression>(); |
| TINT_ASSERT(call); |
| auto* target = SemCall(call)->Target(); |
| auto func_name = NameFor(call->target); |
| |
| if (cause->type == Node::kFunctionCallArgumentValue || |
| cause->type == Node::kFunctionCallArgumentContents) { |
| bool is_value = (cause->type == Node::kFunctionCallArgumentValue); |
| |
| auto* user_func = target->As<sem::Function>(); |
| if (user_func) { |
| // Recurse into the called function to show the reason for the requirement. |
| auto next_function = functions_.Get(user_func->Declaration()); |
| auto& param_info = next_function->parameters[cause->arg_index]; |
| MakeError(*next_function, |
| is_value ? param_info.value : param_info.ptr_input_contents, severity); |
| } |
| |
| // Show the place where the non-uniform argument was passed. |
| // If this is a builtin, this will be the trigger location for the failure. |
| StringStream ss; |
| ss << "possibly non-uniform value passed" << (is_value ? "" : " via pointer") |
| << " here"; |
| report(call->args[cause->arg_index]->source, ss.str(), /* note */ user_func != nullptr); |
| |
| // Show the origin of non-uniformity for the value or data that is being passed. |
| ShowSourceOfNonUniformity(source_node->visited_from); |
| } else { |
| auto* builtin_call = FindBuiltinThatRequiresUniformity(call, severity); |
| { |
| // Show a builtin was reachable from this call (which may be the call itself). |
| // This will be the trigger location for the failure. |
| StringStream ss; |
| ss << "'" << NameFor(builtin_call->target) |
| << "' must only be called from uniform control flow"; |
| report(builtin_call->source, ss.str(), /* note */ false); |
| } |
| |
| if (builtin_call != call) { |
| // The call was to a user function, so show that call too. |
| StringStream ss; |
| ss << "called "; |
| if (target->As<sem::Function>() != SemCall(builtin_call)->Stmt()->Function()) { |
| ss << "indirectly "; |
| } |
| ss << "by '" << func_name << "' from '" << function.name << "'"; |
| report(call->source, ss.str(), /* note */ true); |
| } |
| |
| // Show the point at which control-flow depends on a non-uniform value. |
| ShowControlFlowDivergence(function, cause, source_node); |
| } |
| } |
| |
| // Helper for obtaining the sem::Call node for the ast::CallExpression |
| const sem::Call* SemCall(const ast::CallExpression* expr) const { |
| return sem_.Get(expr)->UnwrapMaterialize()->As<sem::Call>(); |
| } |
| }; |
| |
| } // namespace |
| |
| bool AnalyzeUniformity(ProgramBuilder& builder, const DependencyGraph& dependency_graph) { |
| UniformityGraph graph(builder); |
| return graph.Build(dependency_graph); |
| } |
| |
| } // namespace tint::resolver |