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// Copyright 2020 The Tint Authors.
//
// 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 "src/type_determiner.h"
#include <algorithm>
#include <memory>
#include <utility>
#include <vector>
#include "src/ast/array_accessor_expression.h"
#include "src/ast/assignment_statement.h"
#include "src/ast/binary_expression.h"
#include "src/ast/bitcast_expression.h"
#include "src/ast/block_statement.h"
#include "src/ast/break_statement.h"
#include "src/ast/call_expression.h"
#include "src/ast/call_statement.h"
#include "src/ast/case_statement.h"
#include "src/ast/continue_statement.h"
#include "src/ast/discard_statement.h"
#include "src/ast/else_statement.h"
#include "src/ast/fallthrough_statement.h"
#include "src/ast/identifier_expression.h"
#include "src/ast/if_statement.h"
#include "src/ast/loop_statement.h"
#include "src/ast/member_accessor_expression.h"
#include "src/ast/return_statement.h"
#include "src/ast/scalar_constructor_expression.h"
#include "src/ast/switch_statement.h"
#include "src/ast/type_constructor_expression.h"
#include "src/ast/unary_op_expression.h"
#include "src/ast/variable_decl_statement.h"
#include "src/diagnostic/formatter.h"
#include "src/program_builder.h"
#include "src/semantic/call.h"
#include "src/semantic/expression.h"
#include "src/semantic/function.h"
#include "src/semantic/intrinsic.h"
#include "src/semantic/member_accessor_expression.h"
#include "src/semantic/statement.h"
#include "src/semantic/variable.h"
#include "src/type/array_type.h"
#include "src/type/bool_type.h"
#include "src/type/depth_texture_type.h"
#include "src/type/f32_type.h"
#include "src/type/i32_type.h"
#include "src/type/matrix_type.h"
#include "src/type/multisampled_texture_type.h"
#include "src/type/pointer_type.h"
#include "src/type/sampled_texture_type.h"
#include "src/type/storage_texture_type.h"
#include "src/type/struct_type.h"
#include "src/type/texture_type.h"
#include "src/type/u32_type.h"
#include "src/type/vector_type.h"
#include "src/type/void_type.h"
namespace tint {
namespace {
using IntrinsicType = tint::semantic::IntrinsicType;
// Helper class that temporarily assigns a value to a reference for the scope of
// the object. Once the ScopedAssignment is destructed, the original value is
// restored.
template <typename T>
class ScopedAssignment {
public:
ScopedAssignment(T& ref, T val) : ref_(ref) {
old_value_ = ref;
ref = val;
}
~ScopedAssignment() { ref_ = old_value_; }
private:
T& ref_;
T old_value_;
};
} // namespace
TypeDeterminer::TypeDeterminer(ProgramBuilder* builder)
: builder_(builder), intrinsic_table_(IntrinsicTable::Create()) {}
TypeDeterminer::~TypeDeterminer() = default;
void TypeDeterminer::set_referenced_from_function_if_needed(VariableInfo* var,
bool local) {
if (current_function_ == nullptr) {
return;
}
if (var->storage_class == ast::StorageClass::kNone ||
var->storage_class == ast::StorageClass::kFunction) {
return;
}
current_function_->referenced_module_vars.add(var);
if (local) {
current_function_->local_referenced_module_vars.add(var);
}
}
bool TypeDeterminer::Determine() {
bool result = DetermineInternal();
// Even if resolving failed, create all the semantic nodes for information we
// did generate.
CreateSemanticNodes();
return result;
}
bool TypeDeterminer::DetermineInternal() {
for (auto* var : builder_->AST().GlobalVariables()) {
variable_stack_.set_global(var->symbol(), CreateVariableInfo(var));
if (var->has_constructor()) {
if (!DetermineResultType(var->constructor())) {
return false;
}
}
}
if (!DetermineFunctions(builder_->AST().Functions())) {
return false;
}
return true;
}
bool TypeDeterminer::DetermineFunctions(const ast::FunctionList& funcs) {
for (auto* func : funcs) {
if (!DetermineFunction(func)) {
return false;
}
}
return true;
}
bool TypeDeterminer::DetermineFunction(ast::Function* func) {
auto* func_info = function_infos_.Create<FunctionInfo>(func);
ScopedAssignment<FunctionInfo*> sa(current_function_, func_info);
variable_stack_.push_scope();
for (auto* param : func->params()) {
variable_stack_.set(param->symbol(), CreateVariableInfo(param));
}
if (!DetermineStatements(func->body())) {
return false;
}
variable_stack_.pop_scope();
// Register the function information _after_ processing the statements. This
// allows us to catch a function calling itself when determining the call
// information as this function doesn't exist until it's finished.
symbol_to_function_[func->symbol()] = func_info;
function_to_info_.emplace(func, func_info);
return true;
}
bool TypeDeterminer::DetermineStatements(const ast::BlockStatement* stmts) {
for (auto* stmt : *stmts) {
if (auto* decl = stmt->As<ast::VariableDeclStatement>()) {
if (!ValidateVariableDeclStatement(decl)) {
return false;
}
}
if (!DetermineVariableStorageClass(stmt)) {
return false;
}
if (!DetermineResultType(stmt)) {
return false;
}
}
return true;
}
bool TypeDeterminer::DetermineVariableStorageClass(ast::Statement* stmt) {
auto* var_decl = stmt->As<ast::VariableDeclStatement>();
if (var_decl == nullptr) {
return true;
}
auto* var = var_decl->variable();
auto* info = CreateVariableInfo(var);
variable_to_info_.emplace(var, info);
// Nothing to do for const
if (var->is_const()) {
return true;
}
if (info->storage_class == ast::StorageClass::kFunction) {
return true;
}
if (info->storage_class != ast::StorageClass::kNone) {
diagnostics_.add_error("function variable has a non-function storage class",
stmt->source());
return false;
}
info->storage_class = ast::StorageClass::kFunction;
return true;
}
bool TypeDeterminer::DetermineResultType(ast::Statement* stmt) {
auto* sem_statement = builder_->create<semantic::Statement>(stmt);
ScopedAssignment<semantic::Statement*> sa(current_statement_, sem_statement);
if (auto* a = stmt->As<ast::AssignmentStatement>()) {
return DetermineResultType(a->lhs()) && DetermineResultType(a->rhs());
}
if (auto* b = stmt->As<ast::BlockStatement>()) {
return DetermineStatements(b);
}
if (stmt->Is<ast::BreakStatement>()) {
return true;
}
if (auto* c = stmt->As<ast::CallStatement>()) {
return DetermineResultType(c->expr());
}
if (auto* c = stmt->As<ast::CaseStatement>()) {
return DetermineStatements(c->body());
}
if (stmt->Is<ast::ContinueStatement>()) {
return true;
}
if (stmt->Is<ast::DiscardStatement>()) {
return true;
}
if (auto* e = stmt->As<ast::ElseStatement>()) {
return DetermineResultType(e->condition()) &&
DetermineStatements(e->body());
}
if (stmt->Is<ast::FallthroughStatement>()) {
return true;
}
if (auto* i = stmt->As<ast::IfStatement>()) {
if (!DetermineResultType(i->condition()) ||
!DetermineStatements(i->body())) {
return false;
}
for (auto* else_stmt : i->else_statements()) {
if (!DetermineResultType(else_stmt)) {
return false;
}
}
return true;
}
if (auto* l = stmt->As<ast::LoopStatement>()) {
return DetermineStatements(l->body()) &&
DetermineStatements(l->continuing());
}
if (auto* r = stmt->As<ast::ReturnStatement>()) {
return DetermineResultType(r->value());
}
if (auto* s = stmt->As<ast::SwitchStatement>()) {
if (!DetermineResultType(s->condition())) {
return false;
}
for (auto* case_stmt : s->body()) {
if (!DetermineResultType(case_stmt)) {
return false;
}
}
return true;
}
if (auto* v = stmt->As<ast::VariableDeclStatement>()) {
variable_stack_.set(v->variable()->symbol(),
variable_to_info_.at(v->variable()));
return DetermineResultType(v->variable()->constructor());
}
diagnostics_.add_error(
"unknown statement type for type determination: " + builder_->str(stmt),
stmt->source());
return false;
}
bool TypeDeterminer::DetermineResultType(const ast::ExpressionList& list) {
for (auto* expr : list) {
if (!DetermineResultType(expr)) {
return false;
}
}
return true;
}
bool TypeDeterminer::DetermineResultType(ast::Expression* expr) {
// This is blindly called above, so in some cases the expression won't exist.
if (!expr) {
return true;
}
if (TypeOf(expr)) {
return true; // Already resolved
}
if (auto* a = expr->As<ast::ArrayAccessorExpression>()) {
return DetermineArrayAccessor(a);
}
if (auto* b = expr->As<ast::BinaryExpression>()) {
return DetermineBinary(b);
}
if (auto* b = expr->As<ast::BitcastExpression>()) {
return DetermineBitcast(b);
}
if (auto* c = expr->As<ast::CallExpression>()) {
return DetermineCall(c);
}
if (auto* c = expr->As<ast::ConstructorExpression>()) {
return DetermineConstructor(c);
}
if (auto* i = expr->As<ast::IdentifierExpression>()) {
return DetermineIdentifier(i);
}
if (auto* m = expr->As<ast::MemberAccessorExpression>()) {
return DetermineMemberAccessor(m);
}
if (auto* u = expr->As<ast::UnaryOpExpression>()) {
return DetermineUnaryOp(u);
}
diagnostics_.add_error("unknown expression for type determination",
expr->source());
return false;
}
bool TypeDeterminer::DetermineArrayAccessor(
ast::ArrayAccessorExpression* expr) {
if (!DetermineResultType(expr->array())) {
return false;
}
if (!DetermineResultType(expr->idx_expr())) {
return false;
}
auto* res = TypeOf(expr->array());
auto* parent_type = res->UnwrapAll();
type::Type* ret = nullptr;
if (auto* arr = parent_type->As<type::Array>()) {
ret = arr->type();
} else if (auto* vec = parent_type->As<type::Vector>()) {
ret = vec->type();
} else if (auto* mat = parent_type->As<type::Matrix>()) {
ret = builder_->create<type::Vector>(mat->type(), mat->rows());
} else {
diagnostics_.add_error("invalid parent type (" + parent_type->type_name() +
") in array accessor",
expr->source());
return false;
}
// If we're extracting from a pointer, we return a pointer.
if (auto* ptr = res->As<type::Pointer>()) {
ret = builder_->create<type::Pointer>(ret, ptr->storage_class());
} else if (auto* arr = parent_type->As<type::Array>()) {
if (!arr->type()->is_scalar()) {
// If we extract a non-scalar from an array then we also get a pointer. We
// will generate a Function storage class variable to store this
// into.
ret = builder_->create<type::Pointer>(ret, ast::StorageClass::kFunction);
}
}
SetType(expr, ret);
return true;
}
bool TypeDeterminer::DetermineBitcast(ast::BitcastExpression* expr) {
if (!DetermineResultType(expr->expr())) {
return false;
}
SetType(expr, expr->type());
return true;
}
bool TypeDeterminer::DetermineCall(ast::CallExpression* call) {
if (!DetermineResultType(call->params())) {
return false;
}
// The expression has to be an identifier as you can't store function pointers
// but, if it isn't we'll just use the normal result determination to be on
// the safe side.
auto* ident = call->func()->As<ast::IdentifierExpression>();
if (!ident) {
diagnostics_.add_error("call target is not an identifier", call->source());
return false;
}
auto name = builder_->Symbols().NameFor(ident->symbol());
auto intrinsic_type = MatchIntrinsicType(name);
if (intrinsic_type != IntrinsicType::kNone) {
if (!DetermineIntrinsicCall(call, intrinsic_type)) {
return false;
}
} else {
if (current_function_) {
auto callee_func_it = symbol_to_function_.find(ident->symbol());
if (callee_func_it == symbol_to_function_.end()) {
if (current_function_->declaration->symbol() == ident->symbol()) {
diagnostics_.add_error("recursion is not permitted. '" + name +
"' attempted to call itself.",
call->source());
} else {
diagnostics_.add_error(
"v-0006: unable to find called function: " + name,
call->source());
}
return false;
}
auto* callee_func = callee_func_it->second;
// Note: Requires called functions to be resolved first.
// This is currently guaranteed as functions must be declared before use.
current_function_->transitive_calls.add(callee_func);
for (auto* transitive_call : callee_func->transitive_calls) {
current_function_->transitive_calls.add(transitive_call);
}
// We inherit any referenced variables from the callee.
for (auto* var : callee_func->referenced_module_vars) {
set_referenced_from_function_if_needed(var, false);
}
}
auto iter = symbol_to_function_.find(ident->symbol());
if (iter == symbol_to_function_.end()) {
diagnostics_.add_error(
"v-0005: function must be declared before use: '" + name + "'",
call->source());
return false;
}
auto* function = iter->second;
function_calls_.emplace(call,
FunctionCallInfo{function, current_statement_});
SetType(call, function->declaration->return_type());
}
return true;
}
bool TypeDeterminer::DetermineIntrinsicCall(
ast::CallExpression* call,
semantic::IntrinsicType intrinsic_type) {
std::vector<type::Type*> arg_tys;
arg_tys.reserve(call->params().size());
for (auto* expr : call->params()) {
arg_tys.emplace_back(TypeOf(expr));
}
auto result = intrinsic_table_->Lookup(*builder_, intrinsic_type, arg_tys,
call->source());
if (!result.intrinsic) {
// Intrinsic lookup failed.
diagnostics_.add(result.diagnostics);
// TODO(bclayton): https://crbug.com/tint/487
// The Validator expects intrinsic signature mismatches to still produce
// type information. The rules for what the Validator expects are rather
// bespoke. Try to match what the Validator expects. As the Validator's
// checks on intrinsics is now almost entirely covered by the
// IntrinsicTable, we should remove the Validator checks on intrinsic
// signatures and remove these hacks.
semantic::ParameterList parameters;
parameters.reserve(arg_tys.size());
for (auto* arg : arg_tys) {
parameters.emplace_back(semantic::Parameter{arg});
}
type::Type* ret_ty = nullptr;
switch (intrinsic_type) {
case IntrinsicType::kCross:
ret_ty = builder_->ty.vec3<ProgramBuilder::f32>();
break;
case IntrinsicType::kDeterminant:
ret_ty = builder_->create<type::F32>();
break;
case IntrinsicType::kArrayLength:
ret_ty = builder_->create<type::U32>();
break;
default:
ret_ty = arg_tys.empty() ? builder_->ty.void_() : arg_tys[0];
break;
}
auto* intrinsic = builder_->create<semantic::Intrinsic>(intrinsic_type,
ret_ty, parameters);
builder_->Sem().Add(call, builder_->create<semantic::Call>(
call, intrinsic, current_statement_));
SetType(call, ret_ty);
return false;
}
builder_->Sem().Add(call, builder_->create<semantic::Call>(
call, result.intrinsic, current_statement_));
SetType(call, result.intrinsic->ReturnType());
return true;
}
bool TypeDeterminer::DetermineConstructor(ast::ConstructorExpression* expr) {
if (auto* ty = expr->As<ast::TypeConstructorExpression>()) {
for (auto* value : ty->values()) {
if (!DetermineResultType(value)) {
return false;
}
}
SetType(expr, ty->type());
} else {
SetType(expr,
expr->As<ast::ScalarConstructorExpression>()->literal()->type());
}
return true;
}
bool TypeDeterminer::DetermineIdentifier(ast::IdentifierExpression* expr) {
auto symbol = expr->symbol();
VariableInfo* var;
if (variable_stack_.get(symbol, &var)) {
// A constant is the type, but a variable is always a pointer so synthesize
// the pointer around the variable type.
if (var->declaration->is_const()) {
SetType(expr, var->declaration->type());
} else if (var->declaration->type()->Is<type::Pointer>()) {
SetType(expr, var->declaration->type());
} else {
SetType(expr, builder_->create<type::Pointer>(var->declaration->type(),
var->storage_class));
}
var->users.push_back(expr);
set_referenced_from_function_if_needed(var, true);
return true;
}
auto iter = symbol_to_function_.find(symbol);
if (iter != symbol_to_function_.end()) {
diagnostics_.add_error("missing '(' for function call",
expr->source().End());
return false;
}
std::string name = builder_->Symbols().NameFor(symbol);
if (MatchIntrinsicType(name) != IntrinsicType::kNone) {
diagnostics_.add_error("missing '(' for intrinsic call",
expr->source().End());
return false;
}
diagnostics_.add_error(
"v-0006: identifier must be declared before use: " + name,
expr->source());
return false;
}
IntrinsicType TypeDeterminer::MatchIntrinsicType(const std::string& name) {
if (name == "abs") {
return IntrinsicType::kAbs;
} else if (name == "acos") {
return IntrinsicType::kAcos;
} else if (name == "all") {
return IntrinsicType::kAll;
} else if (name == "any") {
return IntrinsicType::kAny;
} else if (name == "arrayLength") {
return IntrinsicType::kArrayLength;
} else if (name == "asin") {
return IntrinsicType::kAsin;
} else if (name == "atan") {
return IntrinsicType::kAtan;
} else if (name == "atan2") {
return IntrinsicType::kAtan2;
} else if (name == "ceil") {
return IntrinsicType::kCeil;
} else if (name == "clamp") {
return IntrinsicType::kClamp;
} else if (name == "cos") {
return IntrinsicType::kCos;
} else if (name == "cosh") {
return IntrinsicType::kCosh;
} else if (name == "countOneBits") {
return IntrinsicType::kCountOneBits;
} else if (name == "cross") {
return IntrinsicType::kCross;
} else if (name == "determinant") {
return IntrinsicType::kDeterminant;
} else if (name == "distance") {
return IntrinsicType::kDistance;
} else if (name == "dot") {
return IntrinsicType::kDot;
} else if (name == "dpdx") {
return IntrinsicType::kDpdx;
} else if (name == "dpdxCoarse") {
return IntrinsicType::kDpdxCoarse;
} else if (name == "dpdxFine") {
return IntrinsicType::kDpdxFine;
} else if (name == "dpdy") {
return IntrinsicType::kDpdy;
} else if (name == "dpdyCoarse") {
return IntrinsicType::kDpdyCoarse;
} else if (name == "dpdyFine") {
return IntrinsicType::kDpdyFine;
} else if (name == "exp") {
return IntrinsicType::kExp;
} else if (name == "exp2") {
return IntrinsicType::kExp2;
} else if (name == "faceForward") {
return IntrinsicType::kFaceForward;
} else if (name == "floor") {
return IntrinsicType::kFloor;
} else if (name == "fma") {
return IntrinsicType::kFma;
} else if (name == "fract") {
return IntrinsicType::kFract;
} else if (name == "frexp") {
return IntrinsicType::kFrexp;
} else if (name == "fwidth") {
return IntrinsicType::kFwidth;
} else if (name == "fwidthCoarse") {
return IntrinsicType::kFwidthCoarse;
} else if (name == "fwidthFine") {
return IntrinsicType::kFwidthFine;
} else if (name == "inverseSqrt") {
return IntrinsicType::kInverseSqrt;
} else if (name == "isFinite") {
return IntrinsicType::kIsFinite;
} else if (name == "isInf") {
return IntrinsicType::kIsInf;
} else if (name == "isNan") {
return IntrinsicType::kIsNan;
} else if (name == "isNormal") {
return IntrinsicType::kIsNormal;
} else if (name == "ldexp") {
return IntrinsicType::kLdexp;
} else if (name == "length") {
return IntrinsicType::kLength;
} else if (name == "log") {
return IntrinsicType::kLog;
} else if (name == "log2") {
return IntrinsicType::kLog2;
} else if (name == "max") {
return IntrinsicType::kMax;
} else if (name == "min") {
return IntrinsicType::kMin;
} else if (name == "mix") {
return IntrinsicType::kMix;
} else if (name == "modf") {
return IntrinsicType::kModf;
} else if (name == "normalize") {
return IntrinsicType::kNormalize;
} else if (name == "pack4x8snorm") {
return IntrinsicType::kPack4x8Snorm;
} else if (name == "pack4x8unorm") {
return IntrinsicType::kPack4x8Unorm;
} else if (name == "pack2x16snorm") {
return IntrinsicType::kPack2x16Snorm;
} else if (name == "pack2x16unorm") {
return IntrinsicType::kPack2x16Unorm;
} else if (name == "pack2x16float") {
return IntrinsicType::kPack2x16Float;
} else if (name == "pow") {
return IntrinsicType::kPow;
} else if (name == "reflect") {
return IntrinsicType::kReflect;
} else if (name == "reverseBits") {
return IntrinsicType::kReverseBits;
} else if (name == "round") {
return IntrinsicType::kRound;
} else if (name == "select") {
return IntrinsicType::kSelect;
} else if (name == "sign") {
return IntrinsicType::kSign;
} else if (name == "sin") {
return IntrinsicType::kSin;
} else if (name == "sinh") {
return IntrinsicType::kSinh;
} else if (name == "smoothStep") {
return IntrinsicType::kSmoothStep;
} else if (name == "sqrt") {
return IntrinsicType::kSqrt;
} else if (name == "step") {
return IntrinsicType::kStep;
} else if (name == "tan") {
return IntrinsicType::kTan;
} else if (name == "tanh") {
return IntrinsicType::kTanh;
} else if (name == "textureDimensions") {
return IntrinsicType::kTextureDimensions;
} else if (name == "textureNumLayers") {
return IntrinsicType::kTextureNumLayers;
} else if (name == "textureNumLevels") {
return IntrinsicType::kTextureNumLevels;
} else if (name == "textureNumSamples") {
return IntrinsicType::kTextureNumSamples;
} else if (name == "textureLoad") {
return IntrinsicType::kTextureLoad;
} else if (name == "textureStore") {
return IntrinsicType::kTextureStore;
} else if (name == "textureSample") {
return IntrinsicType::kTextureSample;
} else if (name == "textureSampleBias") {
return IntrinsicType::kTextureSampleBias;
} else if (name == "textureSampleCompare") {
return IntrinsicType::kTextureSampleCompare;
} else if (name == "textureSampleGrad") {
return IntrinsicType::kTextureSampleGrad;
} else if (name == "textureSampleLevel") {
return IntrinsicType::kTextureSampleLevel;
} else if (name == "trunc") {
return IntrinsicType::kTrunc;
} else if (name == "unpack4x8snorm") {
return IntrinsicType::kUnpack4x8Snorm;
} else if (name == "unpack4x8unorm") {
return IntrinsicType::kUnpack4x8Unorm;
} else if (name == "unpack2x16snorm") {
return IntrinsicType::kUnpack2x16Snorm;
} else if (name == "unpack2x16unorm") {
return IntrinsicType::kUnpack2x16Unorm;
} else if (name == "unpack2x16float") {
return IntrinsicType::kUnpack2x16Float;
}
return IntrinsicType::kNone;
}
bool TypeDeterminer::DetermineMemberAccessor(
ast::MemberAccessorExpression* expr) {
if (!DetermineResultType(expr->structure())) {
return false;
}
auto* res = TypeOf(expr->structure());
auto* data_type = res->UnwrapPtrIfNeeded()->UnwrapIfNeeded();
type::Type* ret = nullptr;
std::vector<uint32_t> swizzle;
if (auto* ty = data_type->As<type::Struct>()) {
auto* strct = ty->impl();
auto symbol = expr->member()->symbol();
for (auto* member : strct->members()) {
if (member->symbol() == symbol) {
ret = member->type();
break;
}
}
if (ret == nullptr) {
diagnostics_.add_error(
"struct member " + builder_->Symbols().NameFor(symbol) + " not found",
expr->source());
return false;
}
// If we're extracting from a pointer, we return a pointer.
if (auto* ptr = res->As<type::Pointer>()) {
ret = builder_->create<type::Pointer>(ret, ptr->storage_class());
}
} else if (auto* vec = data_type->As<type::Vector>()) {
std::string str = builder_->Symbols().NameFor(expr->member()->symbol());
auto size = str.size();
swizzle.reserve(str.size());
for (auto c : str) {
switch (c) {
case 'x':
case 'r':
swizzle.emplace_back(0);
break;
case 'y':
case 'g':
swizzle.emplace_back(1);
break;
case 'z':
case 'b':
swizzle.emplace_back(2);
break;
case 'w':
case 'a':
swizzle.emplace_back(3);
break;
default:
diagnostics_.add_error(
"invalid vector swizzle character",
expr->member()->source().Begin() + swizzle.size());
return false;
}
}
if (size < 1 || size > 4) {
diagnostics_.add_error("invalid vector swizzle size",
expr->member()->source());
return false;
}
// All characters are valid, check if they're being mixed
auto is_rgba = [](char c) {
return c == 'r' || c == 'g' || c == 'b' || c == 'a';
};
auto is_xyzw = [](char c) {
return c == 'x' || c == 'y' || c == 'z' || c == 'w';
};
if (!std::all_of(str.begin(), str.end(), is_rgba) &&
!std::all_of(str.begin(), str.end(), is_xyzw)) {
diagnostics_.add_error(
"invalid mixing of vector swizzle characters rgba with xyzw",
expr->member()->source());
return false;
}
if (size == 1) {
// A single element swizzle is just the type of the vector.
ret = vec->type();
// If we're extracting from a pointer, we return a pointer.
if (auto* ptr = res->As<type::Pointer>()) {
ret = builder_->create<type::Pointer>(ret, ptr->storage_class());
}
} else {
// The vector will have a number of components equal to the length of
// the swizzle. This assumes the validator will check that the swizzle
// is correct.
ret = builder_->create<type::Vector>(vec->type(),
static_cast<uint32_t>(size));
}
} else {
diagnostics_.add_error(
"invalid use of member accessor on a non-vector/non-struct " +
data_type->type_name(),
expr->source());
return false;
}
builder_->Sem().Add(expr,
builder_->create<semantic::MemberAccessorExpression>(
expr, ret, current_statement_, std::move(swizzle)));
SetType(expr, ret);
return true;
}
bool TypeDeterminer::DetermineBinary(ast::BinaryExpression* expr) {
if (!DetermineResultType(expr->lhs()) || !DetermineResultType(expr->rhs())) {
return false;
}
// Result type matches first parameter type
if (expr->IsAnd() || expr->IsOr() || expr->IsXor() || expr->IsShiftLeft() ||
expr->IsShiftRight() || expr->IsAdd() || expr->IsSubtract() ||
expr->IsDivide() || expr->IsModulo()) {
SetType(expr, TypeOf(expr->lhs())->UnwrapPtrIfNeeded());
return true;
}
// Result type is a scalar or vector of boolean type
if (expr->IsLogicalAnd() || expr->IsLogicalOr() || expr->IsEqual() ||
expr->IsNotEqual() || expr->IsLessThan() || expr->IsGreaterThan() ||
expr->IsLessThanEqual() || expr->IsGreaterThanEqual()) {
auto* bool_type = builder_->create<type::Bool>();
auto* param_type = TypeOf(expr->lhs())->UnwrapPtrIfNeeded();
type::Type* result_type = bool_type;
if (auto* vec = param_type->As<type::Vector>()) {
result_type = builder_->create<type::Vector>(bool_type, vec->size());
}
SetType(expr, result_type);
return true;
}
if (expr->IsMultiply()) {
auto* lhs_type = TypeOf(expr->lhs())->UnwrapPtrIfNeeded();
auto* rhs_type = TypeOf(expr->rhs())->UnwrapPtrIfNeeded();
// Note, the ordering here matters. The later checks depend on the prior
// checks having been done.
auto* lhs_mat = lhs_type->As<type::Matrix>();
auto* rhs_mat = rhs_type->As<type::Matrix>();
auto* lhs_vec = lhs_type->As<type::Vector>();
auto* rhs_vec = rhs_type->As<type::Vector>();
type::Type* result_type;
if (lhs_mat && rhs_mat) {
result_type = builder_->create<type::Matrix>(
lhs_mat->type(), lhs_mat->rows(), rhs_mat->columns());
} else if (lhs_mat && rhs_vec) {
result_type =
builder_->create<type::Vector>(lhs_mat->type(), lhs_mat->rows());
} else if (lhs_vec && rhs_mat) {
result_type =
builder_->create<type::Vector>(rhs_mat->type(), rhs_mat->columns());
} else if (lhs_mat) {
// matrix * scalar
result_type = lhs_type;
} else if (rhs_mat) {
// scalar * matrix
result_type = rhs_type;
} else if (lhs_vec && rhs_vec) {
result_type = lhs_type;
} else if (lhs_vec) {
// Vector * scalar
result_type = lhs_type;
} else if (rhs_vec) {
// Scalar * vector
result_type = rhs_type;
} else {
// Scalar * Scalar
result_type = lhs_type;
}
SetType(expr, result_type);
return true;
}
diagnostics_.add_error("Unknown binary expression", expr->source());
return false;
}
bool TypeDeterminer::DetermineUnaryOp(ast::UnaryOpExpression* expr) {
// Result type matches the parameter type.
if (!DetermineResultType(expr->expr())) {
return false;
}
auto* result_type = TypeOf(expr->expr())->UnwrapPtrIfNeeded();
SetType(expr, result_type);
return true;
}
bool TypeDeterminer::ValidateVariableDeclStatement(
const ast::VariableDeclStatement* stmt) {
auto* ctor = stmt->variable()->constructor();
if (!ctor) {
return true;
}
if (auto* sce = ctor->As<ast::ScalarConstructorExpression>()) {
auto* lhs_type = stmt->variable()->type()->UnwrapAliasIfNeeded();
auto* rhs_type = sce->literal()->type()->UnwrapAliasIfNeeded();
if (lhs_type != rhs_type) {
diagnostics_.add_error(
"constructor expression type does not match variable type",
stmt->source());
return false;
}
}
return true;
}
TypeDeterminer::VariableInfo* TypeDeterminer::CreateVariableInfo(
ast::Variable* var) {
auto* info = variable_infos_.Create(var);
variable_to_info_.emplace(var, info);
return info;
}
type::Type* TypeDeterminer::TypeOf(ast::Expression* expr) {
auto it = expr_info_.find(expr);
if (it != expr_info_.end()) {
return it->second.type;
}
return nullptr;
}
void TypeDeterminer::SetType(ast::Expression* expr, type::Type* type) {
assert(expr_info_.count(expr) == 0);
expr_info_.emplace(expr, ExpressionInfo{type, current_statement_});
}
void TypeDeterminer::CreateSemanticNodes() const {
auto& sem = builder_->Sem();
// Collate all the 'ancestor_entry_points' - this is a map of function symbol
// to all the entry points that transitively call the function.
std::unordered_map<Symbol, std::vector<Symbol>> ancestor_entry_points;
for (auto* func : builder_->AST().Functions()) {
auto it = function_to_info_.find(func);
if (it == function_to_info_.end()) {
continue; // Type determination has likely errored. Process what we can.
}
auto* info = it->second;
if (!func->IsEntryPoint()) {
continue;
}
for (auto* call : info->transitive_calls) {
auto& vec = ancestor_entry_points[call->declaration->symbol()];
vec.emplace_back(func->symbol());
}
}
// Create semantic nodes for all ast::Variables
for (auto it : variable_to_info_) {
auto* var = it.first;
auto* info = it.second;
std::vector<const semantic::Expression*> users;
for (auto* user : info->users) {
// Create semantic node for the identifier expression if necessary
auto* sem_expr = sem.Get(user);
if (sem_expr == nullptr) {
auto* type = expr_info_.at(user).type;
auto* stmt = expr_info_.at(user).statement;
sem_expr = builder_->create<semantic::Expression>(user, type, stmt);
sem.Add(user, sem_expr);
}
users.push_back(sem_expr);
}
sem.Add(var, builder_->create<semantic::Variable>(var, info->storage_class,
std::move(users)));
}
auto remap_vars = [&sem](const std::vector<VariableInfo*>& in) {
std::vector<const semantic::Variable*> out;
out.reserve(in.size());
for (auto* info : in) {
out.emplace_back(sem.Get(info->declaration));
}
return out;
};
// Create semantic nodes for all ast::Functions
std::unordered_map<FunctionInfo*, semantic::Function*> func_info_to_sem_func;
for (auto it : function_to_info_) {
auto* func = it.first;
auto* info = it.second;
auto* sem_func = builder_->create<semantic::Function>(
info->declaration, remap_vars(info->referenced_module_vars),
remap_vars(info->local_referenced_module_vars),
ancestor_entry_points[func->symbol()]);
func_info_to_sem_func.emplace(info, sem_func);
sem.Add(func, sem_func);
}
// Create semantic nodes for all ast::CallExpressions
for (auto it : function_calls_) {
auto* call = it.first;
auto info = it.second;
auto* sem_func = func_info_to_sem_func.at(info.function);
sem.Add(call,
builder_->create<semantic::Call>(call, sem_func, info.statement));
}
// Create semantic nodes for all remaining expression types
for (auto it : expr_info_) {
auto* expr = it.first;
auto& info = it.second;
if (sem.Get(expr)) {
// Expression has already been assigned a semantic node
continue;
}
sem.Add(expr, builder_->create<semantic::Expression>(expr, info.type,
info.statement));
}
}
TypeDeterminer::VariableInfo::VariableInfo(ast::Variable* decl)
: declaration(decl), storage_class(decl->declared_storage_class()) {}
TypeDeterminer::VariableInfo::~VariableInfo() = default;
TypeDeterminer::FunctionInfo::FunctionInfo(ast::Function* decl)
: declaration(decl) {}
TypeDeterminer::FunctionInfo::~FunctionInfo() = default;
} // namespace tint