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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/tint/reader/wgsl/parser_impl.h"
#include <limits>
#include "src/tint/ast/array.h"
#include "src/tint/ast/assignment_statement.h"
#include "src/tint/ast/bitcast_expression.h"
#include "src/tint/ast/break_statement.h"
#include "src/tint/ast/call_statement.h"
#include "src/tint/ast/continue_statement.h"
#include "src/tint/ast/discard_statement.h"
#include "src/tint/ast/external_texture.h"
#include "src/tint/ast/fallthrough_statement.h"
#include "src/tint/ast/id_attribute.h"
#include "src/tint/ast/if_statement.h"
#include "src/tint/ast/increment_decrement_statement.h"
#include "src/tint/ast/invariant_attribute.h"
#include "src/tint/ast/loop_statement.h"
#include "src/tint/ast/return_statement.h"
#include "src/tint/ast/stage_attribute.h"
#include "src/tint/ast/switch_statement.h"
#include "src/tint/ast/type_name.h"
#include "src/tint/ast/unary_op_expression.h"
#include "src/tint/ast/variable_decl_statement.h"
#include "src/tint/ast/vector.h"
#include "src/tint/ast/workgroup_attribute.h"
#include "src/tint/reader/wgsl/lexer.h"
#include "src/tint/sem/depth_texture.h"
#include "src/tint/sem/external_texture.h"
#include "src/tint/sem/multisampled_texture.h"
#include "src/tint/sem/sampled_texture.h"
namespace tint::reader::wgsl {
namespace {
template <typename T>
using Expect = ParserImpl::Expect<T>;
template <typename T>
using Maybe = ParserImpl::Maybe<T>;
/// Controls the maximum number of times we'll call into the sync() and
/// unary_expression() functions from themselves. This is to guard against stack
/// overflow when there is an excessive number of blocks.
constexpr uint32_t kMaxParseDepth = 128;
/// The maximum number of tokens to look ahead to try and sync the
/// parser on error.
constexpr size_t const kMaxResynchronizeLookahead = 32;
const char kVertexStage[] = "vertex";
const char kFragmentStage[] = "fragment";
const char kComputeStage[] = "compute";
const char kReadAccess[] = "read";
const char kWriteAccess[] = "write";
const char kReadWriteAccess[] = "read_write";
ast::Builtin ident_to_builtin(std::string_view str) {
if (str == "position") {
return ast::Builtin::kPosition;
}
if (str == "vertex_index") {
return ast::Builtin::kVertexIndex;
}
if (str == "instance_index") {
return ast::Builtin::kInstanceIndex;
}
if (str == "front_facing") {
return ast::Builtin::kFrontFacing;
}
if (str == "frag_depth") {
return ast::Builtin::kFragDepth;
}
if (str == "local_invocation_id") {
return ast::Builtin::kLocalInvocationId;
}
if (str == "local_invocation_idx" || str == "local_invocation_index") {
return ast::Builtin::kLocalInvocationIndex;
}
if (str == "global_invocation_id") {
return ast::Builtin::kGlobalInvocationId;
}
if (str == "workgroup_id") {
return ast::Builtin::kWorkgroupId;
}
if (str == "num_workgroups") {
return ast::Builtin::kNumWorkgroups;
}
if (str == "sample_index") {
return ast::Builtin::kSampleIndex;
}
if (str == "sample_mask") {
return ast::Builtin::kSampleMask;
}
return ast::Builtin::kNone;
}
const char kBindingAttribute[] = "binding";
const char kBuiltinAttribute[] = "builtin";
const char kGroupAttribute[] = "group";
const char kIdAttribute[] = "id";
const char kInterpolateAttribute[] = "interpolate";
const char kInvariantAttribute[] = "invariant";
const char kLocationAttribute[] = "location";
const char kSizeAttribute[] = "size";
const char kAlignAttribute[] = "align";
const char kStageAttribute[] = "stage";
const char kWorkgroupSizeAttribute[] = "workgroup_size";
// https://gpuweb.github.io/gpuweb/wgsl.html#reserved-keywords
bool is_reserved(Token t) {
return t == "asm" || t == "bf16" || t == "const" || t == "do" || t == "enum" || t == "f64" ||
t == "handle" || t == "i8" || t == "i16" || t == "i64" || t == "mat" ||
t == "premerge" || t == "regardless" || t == "typedef" || t == "u8" || t == "u16" ||
t == "u64" || t == "unless" || t == "using" || t == "vec" || t == "void" || t == "while";
}
/// Enter-exit counters for block token types.
/// Used by sync_to() to skip over closing block tokens that were opened during
/// the forward scan.
struct BlockCounters {
int brace = 0; // { }
int bracket = 0; // [ ]
int paren = 0; // ( )
/// @return the current enter-exit depth for the given block token type. If
/// `t` is not a block token type, then 0 is always returned.
int consume(const Token& t) {
if (t.Is(Token::Type::kBraceLeft))
return brace++;
if (t.Is(Token::Type::kBraceRight))
return brace--;
if (t.Is(Token::Type::kBracketLeft))
return bracket++;
if (t.Is(Token::Type::kBracketRight))
return bracket--;
if (t.Is(Token::Type::kParenLeft))
return paren++;
if (t.Is(Token::Type::kParenRight))
return paren--;
return 0;
}
};
} // namespace
/// RAII helper that combines a Source on construction with the last token's
/// source when implicitly converted to `Source`.
class ParserImpl::MultiTokenSource {
public:
/// Constructor that starts with Source at the current peek position
/// @param parser the parser
explicit MultiTokenSource(ParserImpl* parser)
: MultiTokenSource(parser, parser->peek().source().Begin()) {}
/// Constructor that starts with the input `start` Source
/// @param parser the parser
/// @param start the start source of the range
MultiTokenSource(ParserImpl* parser, const Source& start) : parser_(parser), start_(start) {}
/// Implicit conversion to Source that returns the combined source from start
/// to the current last token's source.
operator Source() const {
Source end = parser_->last_token().source().End();
if (end < start_) {
end = start_;
}
return Source::Combine(start_, end);
}
private:
ParserImpl* parser_;
Source start_;
};
ParserImpl::TypedIdentifier::TypedIdentifier() = default;
ParserImpl::TypedIdentifier::TypedIdentifier(const TypedIdentifier&) = default;
ParserImpl::TypedIdentifier::TypedIdentifier(const ast::Type* type_in,
std::string name_in,
Source source_in)
: type(type_in), name(std::move(name_in)), source(std::move(source_in)) {}
ParserImpl::TypedIdentifier::~TypedIdentifier() = default;
ParserImpl::FunctionHeader::FunctionHeader() = default;
ParserImpl::FunctionHeader::FunctionHeader(const FunctionHeader&) = default;
ParserImpl::FunctionHeader::FunctionHeader(Source src,
std::string n,
ast::VariableList p,
const ast::Type* ret_ty,
ast::AttributeList ret_attrs)
: source(src), name(n), params(p), return_type(ret_ty), return_type_attributes(ret_attrs) {}
ParserImpl::FunctionHeader::~FunctionHeader() = default;
ParserImpl::FunctionHeader& ParserImpl::FunctionHeader::operator=(const FunctionHeader& rhs) =
default;
ParserImpl::VarDeclInfo::VarDeclInfo() = default;
ParserImpl::VarDeclInfo::VarDeclInfo(const VarDeclInfo&) = default;
ParserImpl::VarDeclInfo::VarDeclInfo(Source source_in,
std::string name_in,
ast::StorageClass storage_class_in,
ast::Access access_in,
const ast::Type* type_in)
: source(std::move(source_in)),
name(std::move(name_in)),
storage_class(storage_class_in),
access(access_in),
type(type_in) {}
ParserImpl::VarDeclInfo::~VarDeclInfo() = default;
ParserImpl::ParserImpl(Source::File const* file) : lexer_(std::make_unique<Lexer>(file)) {}
ParserImpl::~ParserImpl() = default;
ParserImpl::Failure::Errored ParserImpl::add_error(const Source& source,
std::string_view err,
std::string_view use) {
std::stringstream msg;
msg << err;
if (!use.empty()) {
msg << " for " << use;
}
add_error(source, msg.str());
return Failure::kErrored;
}
ParserImpl::Failure::Errored ParserImpl::add_error(const Token& t, const std::string& err) {
add_error(t.source(), err);
return Failure::kErrored;
}
ParserImpl::Failure::Errored ParserImpl::add_error(const Source& source, const std::string& err) {
if (silence_errors_ == 0) {
builder_.Diagnostics().add_error(diag::System::Reader, err, source);
}
return Failure::kErrored;
}
void ParserImpl::deprecated(const Source& source, const std::string& msg) {
builder_.Diagnostics().add_warning(diag::System::Reader,
"use of deprecated language feature: " + msg, source);
}
Token ParserImpl::next() {
if (!token_queue_.empty()) {
auto t = token_queue_.front();
token_queue_.pop_front();
last_token_ = t;
return last_token_;
}
last_token_ = lexer_->next();
return last_token_;
}
Token ParserImpl::peek(size_t idx) {
while (token_queue_.size() < (idx + 1)) {
token_queue_.push_back(lexer_->next());
}
return token_queue_[idx];
}
bool ParserImpl::peek_is(Token::Type tok, size_t idx) {
return peek(idx).Is(tok);
}
Token ParserImpl::last_token() const {
return last_token_;
}
bool ParserImpl::Parse() {
translation_unit();
return !has_error();
}
// translation_unit
// : enable_directive* global_decl* EOF
void ParserImpl::translation_unit() {
bool after_global_decl = false;
while (continue_parsing()) {
auto p = peek();
if (p.IsEof()) {
break;
}
auto ed = enable_directive();
if (ed.matched) {
if (after_global_decl) {
add_error(p, "enable directives must come before all global declarations");
}
} else if (ed.errored) {
// Found a invalid enable directive.
continue;
} else {
auto gd = global_decl();
if (gd.matched) {
after_global_decl = true;
}
if (!gd.matched && !gd.errored) {
add_error(p, "unexpected token");
}
}
if (builder_.Diagnostics().error_count() >= max_errors_) {
add_error(Source{{}, p.source().file},
"stopping after " + std::to_string(max_errors_) + " errors");
break;
}
}
}
// enable_directive
// : enable name SEMICLON
Maybe<bool> ParserImpl::enable_directive() {
auto decl = sync(Token::Type::kSemicolon, [&]() -> Maybe<bool> {
if (!match(Token::Type::kEnable)) {
return Failure::kNoMatch;
}
// Match the extension name.
Expect<std::string> name = {""};
auto t = peek();
if (t.IsIdentifier()) {
synchronized_ = true;
next();
name = {t.to_str(), t.source()};
} else if (t.Is(Token::Type::kF16)) {
// `f16` is a valid extension name and also a keyword
synchronized_ = true;
next();
name = {"f16", t.source()};
} else if (handle_error(t)) {
// The token might itself be an error.
return Failure::kErrored;
} else {
// Failed to match an extension name.
synchronized_ = false;
return add_error(t.source(), "invalid extension name");
}
if (!expect("enable directive", Token::Type::kSemicolon)) {
return Failure::kErrored;
}
auto extension = ast::ParseExtension(name.value);
if (extension == ast::Extension::kNone) {
return add_error(name.source, "unsupported extension: '" + name.value + "'");
}
builder_.AST().AddEnable(create<ast::Enable>(name.source, extension));
return true;
});
if (decl.errored) {
return Failure::kErrored;
}
if (decl.matched) {
return true;
}
return Failure::kNoMatch;
}
// global_decl
// : SEMICOLON
// | global_variable_decl SEMICLON
// | global_constant_decl SEMICOLON
// | type_alias SEMICOLON
// | struct_decl
// | function_decl
Maybe<bool> ParserImpl::global_decl() {
if (match(Token::Type::kSemicolon) || match(Token::Type::kEOF))
return true;
bool errored = false;
auto attrs = attribute_list();
if (attrs.errored)
errored = true;
if (!continue_parsing())
return Failure::kErrored;
auto decl = sync(Token::Type::kSemicolon, [&]() -> Maybe<bool> {
auto gv = global_variable_decl(attrs.value);
if (gv.errored)
return Failure::kErrored;
if (gv.matched) {
if (!expect("variable declaration", Token::Type::kSemicolon))
return Failure::kErrored;
builder_.AST().AddGlobalVariable(gv.value);
return true;
}
auto gc = global_constant_decl(attrs.value);
if (gc.errored)
return Failure::kErrored;
if (gc.matched) {
if (!expect("let declaration", Token::Type::kSemicolon))
return Failure::kErrored;
builder_.AST().AddGlobalVariable(gc.value);
return true;
}
auto ta = type_alias();
if (ta.errored)
return Failure::kErrored;
if (ta.matched) {
if (!expect("type alias", Token::Type::kSemicolon))
return Failure::kErrored;
builder_.AST().AddTypeDecl(ta.value);
return true;
}
auto str = struct_decl();
if (str.errored)
return Failure::kErrored;
if (str.matched) {
builder_.AST().AddTypeDecl(str.value);
return true;
}
return Failure::kNoMatch;
});
if (decl.errored) {
errored = true;
}
if (decl.matched) {
return expect_attributes_consumed(attrs.value);
}
auto func = function_decl(attrs.value);
if (func.errored) {
errored = true;
}
if (func.matched) {
builder_.AST().AddFunction(func.value);
return true;
}
if (errored) {
return Failure::kErrored;
}
// Invalid syntax found - try and determine the best error message
// We have attributes parsed, but nothing to consume them?
if (attrs.value.size() > 0) {
return add_error(next(), "expected declaration after attributes");
}
// We have a statement outside of a function?
auto t = peek();
auto stat = without_error([&] { return statement(); });
if (stat.matched) {
// Attempt to jump to the next '}' - the function might have just been
// missing an opening line.
sync_to(Token::Type::kBraceRight, true);
return add_error(t, "statement found outside of function body");
}
if (!stat.errored) {
// No match, no error - the parser might not have progressed.
// Ensure we always make _some_ forward progress.
next();
}
// The token might itself be an error.
if (handle_error(t)) {
return Failure::kErrored;
}
// Exhausted all attempts to make sense of where we're at.
// Return a no-match
return Failure::kNoMatch;
}
// global_variable_decl
// : variable_attribute_list* variable_decl
// | variable_attribute_list* variable_decl EQUAL const_expr
Maybe<const ast::Variable*> ParserImpl::global_variable_decl(ast::AttributeList& attrs) {
auto decl = variable_decl();
if (decl.errored)
return Failure::kErrored;
if (!decl.matched)
return Failure::kNoMatch;
const ast::Expression* constructor = nullptr;
if (match(Token::Type::kEqual)) {
auto expr = expect_const_expr();
if (expr.errored)
return Failure::kErrored;
constructor = expr.value;
}
return create<ast::Variable>(decl->source, // source
builder_.Symbols().Register(decl->name), // symbol
decl->storage_class, // storage class
decl->access, // access control
decl->type, // type
false, // is_const
false, // is_overridable
constructor, // constructor
std::move(attrs)); // attributes
}
// global_constant_decl :
// | LET (ident | variable_ident_decl) global_const_initializer
// | attribute* override (ident | variable_ident_decl) (equal expression)?
// global_const_initializer
// : EQUAL const_expr
Maybe<const ast::Variable*> ParserImpl::global_constant_decl(ast::AttributeList& attrs) {
bool is_overridable = false;
const char* use = nullptr;
if (match(Token::Type::kLet)) {
use = "let declaration";
} else if (match(Token::Type::kOverride)) {
use = "override declaration";
is_overridable = true;
} else {
return Failure::kNoMatch;
}
auto decl = expect_variable_ident_decl(use, /* allow_inferred = */ true);
if (decl.errored)
return Failure::kErrored;
const ast::Expression* initializer = nullptr;
if (match(Token::Type::kEqual)) {
auto init = expect_const_expr();
if (init.errored) {
return Failure::kErrored;
}
initializer = std::move(init.value);
}
return create<ast::Variable>(decl->source, // source
builder_.Symbols().Register(decl->name), // symbol
ast::StorageClass::kNone, // storage class
ast::Access::kUndefined, // access control
decl->type, // type
true, // is_const
is_overridable, // is_overridable
initializer, // constructor
std::move(attrs)); // attributes
}
// variable_decl
// : VAR variable_qualifier? variable_ident_decl
Maybe<ParserImpl::VarDeclInfo> ParserImpl::variable_decl(bool allow_inferred) {
Source source;
if (!match(Token::Type::kVar, &source))
return Failure::kNoMatch;
VariableQualifier vq;
auto explicit_vq = variable_qualifier();
if (explicit_vq.errored)
return Failure::kErrored;
if (explicit_vq.matched) {
vq = explicit_vq.value;
}
auto decl = expect_variable_ident_decl("variable declaration", allow_inferred);
if (decl.errored)
return Failure::kErrored;
return VarDeclInfo{decl->source, decl->name, vq.storage_class, vq.access, decl->type};
}
// texture_samplers
// : sampler
// | depth_texture
// | sampled_texture LESS_THAN type_decl GREATER_THAN
// | multisampled_texture LESS_THAN type_decl GREATER_THAN
// | storage_texture LESS_THAN texel_format
// COMMA access GREATER_THAN
Maybe<const ast::Type*> ParserImpl::texture_samplers() {
auto type = sampler();
if (type.matched)
return type;
type = depth_texture();
if (type.matched)
return type;
type = external_texture();
if (type.matched)
return type.value;
auto source_range = make_source_range();
auto dim = sampled_texture();
if (dim.matched) {
const char* use = "sampled texture type";
auto subtype = expect_lt_gt_block(use, [&] { return expect_type(use); });
if (subtype.errored)
return Failure::kErrored;
return builder_.ty.sampled_texture(source_range, dim.value, subtype.value);
}
auto ms_dim = multisampled_texture();
if (ms_dim.matched) {
const char* use = "multisampled texture type";
auto subtype = expect_lt_gt_block(use, [&] { return expect_type(use); });
if (subtype.errored)
return Failure::kErrored;
return builder_.ty.multisampled_texture(source_range, ms_dim.value, subtype.value);
}
auto storage = storage_texture();
if (storage.matched) {
const char* use = "storage texture type";
using StorageTextureInfo = std::pair<tint::ast::TexelFormat, tint::ast::Access>;
auto params = expect_lt_gt_block(use, [&]() -> Expect<StorageTextureInfo> {
auto format = expect_texel_format(use);
if (format.errored) {
return Failure::kErrored;
}
if (!expect("access control", Token::Type::kComma)) {
return Failure::kErrored;
}
auto access = expect_access("access control");
if (access.errored) {
return Failure::kErrored;
}
return std::make_pair(format.value, access.value);
});
if (params.errored) {
return Failure::kErrored;
}
return builder_.ty.storage_texture(source_range, storage.value, params->first,
params->second);
}
return Failure::kNoMatch;
}
// sampler
// : SAMPLER
// | SAMPLER_COMPARISON
Maybe<const ast::Type*> ParserImpl::sampler() {
Source source;
if (match(Token::Type::kSampler, &source))
return builder_.ty.sampler(source, ast::SamplerKind::kSampler);
if (match(Token::Type::kComparisonSampler, &source))
return builder_.ty.sampler(source, ast::SamplerKind::kComparisonSampler);
return Failure::kNoMatch;
}
// sampled_texture
// : TEXTURE_SAMPLED_1D
// | TEXTURE_SAMPLED_2D
// | TEXTURE_SAMPLED_2D_ARRAY
// | TEXTURE_SAMPLED_3D
// | TEXTURE_SAMPLED_CUBE
// | TEXTURE_SAMPLED_CUBE_ARRAY
Maybe<const ast::TextureDimension> ParserImpl::sampled_texture() {
if (match(Token::Type::kTextureSampled1d))
return ast::TextureDimension::k1d;
if (match(Token::Type::kTextureSampled2d))
return ast::TextureDimension::k2d;
if (match(Token::Type::kTextureSampled2dArray))
return ast::TextureDimension::k2dArray;
if (match(Token::Type::kTextureSampled3d))
return ast::TextureDimension::k3d;
if (match(Token::Type::kTextureSampledCube))
return ast::TextureDimension::kCube;
if (match(Token::Type::kTextureSampledCubeArray))
return ast::TextureDimension::kCubeArray;
return Failure::kNoMatch;
}
// external_texture
// : TEXTURE_EXTERNAL
Maybe<const ast::Type*> ParserImpl::external_texture() {
Source source;
if (match(Token::Type::kTextureExternal, &source)) {
return builder_.ty.external_texture(source);
}
return Failure::kNoMatch;
}
// multisampled_texture
// : TEXTURE_MULTISAMPLED_2D
Maybe<const ast::TextureDimension> ParserImpl::multisampled_texture() {
if (match(Token::Type::kTextureMultisampled2d))
return ast::TextureDimension::k2d;
return Failure::kNoMatch;
}
// storage_texture
// : TEXTURE_STORAGE_1D
// | TEXTURE_STORAGE_2D
// | TEXTURE_STORAGE_2D_ARRAY
// | TEXTURE_STORAGE_3D
Maybe<const ast::TextureDimension> ParserImpl::storage_texture() {
if (match(Token::Type::kTextureStorage1d))
return ast::TextureDimension::k1d;
if (match(Token::Type::kTextureStorage2d))
return ast::TextureDimension::k2d;
if (match(Token::Type::kTextureStorage2dArray))
return ast::TextureDimension::k2dArray;
if (match(Token::Type::kTextureStorage3d))
return ast::TextureDimension::k3d;
return Failure::kNoMatch;
}
// depth_texture
// : TEXTURE_DEPTH_2D
// | TEXTURE_DEPTH_2D_ARRAY
// | TEXTURE_DEPTH_CUBE
// | TEXTURE_DEPTH_CUBE_ARRAY
// | TEXTURE_DEPTH_MULTISAMPLED_2D
Maybe<const ast::Type*> ParserImpl::depth_texture() {
Source source;
if (match(Token::Type::kTextureDepth2d, &source)) {
return builder_.ty.depth_texture(source, ast::TextureDimension::k2d);
}
if (match(Token::Type::kTextureDepth2dArray, &source)) {
return builder_.ty.depth_texture(source, ast::TextureDimension::k2dArray);
}
if (match(Token::Type::kTextureDepthCube, &source)) {
return builder_.ty.depth_texture(source, ast::TextureDimension::kCube);
}
if (match(Token::Type::kTextureDepthCubeArray, &source)) {
return builder_.ty.depth_texture(source, ast::TextureDimension::kCubeArray);
}
if (match(Token::Type::kTextureDepthMultisampled2d, &source)) {
return builder_.ty.depth_multisampled_texture(source, ast::TextureDimension::k2d);
}
return Failure::kNoMatch;
}
// texel_format
// : 'rgba8unorm'
// | 'rgba8snorm'
// | 'rgba8uint'
// | 'rgba8sint'
// | 'rgba16uint'
// | 'rgba16sint'
// | 'rgba16float'
// | 'r32uint'
// | 'r32sint'
// | 'r32float'
// | 'rg32uint'
// | 'rg32sint'
// | 'rg32float'
// | 'rgba32uint'
// | 'rgba32sint'
// | 'rgba32float'
Expect<ast::TexelFormat> ParserImpl::expect_texel_format(std::string_view use) {
auto t = next();
if (t == "rgba8unorm") {
return ast::TexelFormat::kRgba8Unorm;
}
if (t == "rgba8snorm") {
return ast::TexelFormat::kRgba8Snorm;
}
if (t == "rgba8uint") {
return ast::TexelFormat::kRgba8Uint;
}
if (t == "rgba8sint") {
return ast::TexelFormat::kRgba8Sint;
}
if (t == "rgba16uint") {
return ast::TexelFormat::kRgba16Uint;
}
if (t == "rgba16sint") {
return ast::TexelFormat::kRgba16Sint;
}
if (t == "rgba16float") {
return ast::TexelFormat::kRgba16Float;
}
if (t == "r32uint") {
return ast::TexelFormat::kR32Uint;
}
if (t == "r32sint") {
return ast::TexelFormat::kR32Sint;
}
if (t == "r32float") {
return ast::TexelFormat::kR32Float;
}
if (t == "rg32uint") {
return ast::TexelFormat::kRg32Uint;
}
if (t == "rg32sint") {
return ast::TexelFormat::kRg32Sint;
}
if (t == "rg32float") {
return ast::TexelFormat::kRg32Float;
}
if (t == "rgba32uint") {
return ast::TexelFormat::kRgba32Uint;
}
if (t == "rgba32sint") {
return ast::TexelFormat::kRgba32Sint;
}
if (t == "rgba32float") {
return ast::TexelFormat::kRgba32Float;
}
return add_error(t.source(), "invalid format", use);
}
// variable_ident_decl
// : IDENT COLON type_decl
Expect<ParserImpl::TypedIdentifier> ParserImpl::expect_variable_ident_decl(std::string_view use,
bool allow_inferred) {
auto ident = expect_ident(use);
if (ident.errored)
return Failure::kErrored;
if (allow_inferred && !peek_is(Token::Type::kColon)) {
return TypedIdentifier{nullptr, ident.value, ident.source};
}
if (!expect(use, Token::Type::kColon))
return Failure::kErrored;
auto t = peek();
auto type = type_decl();
if (type.errored)
return Failure::kErrored;
if (!type.matched)
return add_error(t.source(), "invalid type", use);
return TypedIdentifier{type.value, ident.value, ident.source};
}
Expect<ast::Access> ParserImpl::expect_access(std::string_view use) {
auto ident = expect_ident(use);
if (ident.errored)
return Failure::kErrored;
if (ident.value == kReadAccess)
return {ast::Access::kRead, ident.source};
if (ident.value == kWriteAccess)
return {ast::Access::kWrite, ident.source};
if (ident.value == kReadWriteAccess)
return {ast::Access::kReadWrite, ident.source};
return add_error(ident.source, "invalid value for access control");
}
// variable_qualifier
// : LESS_THAN storage_class (COMMA access_mode)? GREATER_THAN
Maybe<ParserImpl::VariableQualifier> ParserImpl::variable_qualifier() {
if (!peek_is(Token::Type::kLessThan)) {
return Failure::kNoMatch;
}
auto* use = "variable declaration";
auto vq = expect_lt_gt_block(use, [&]() -> Expect<VariableQualifier> {
auto source = make_source_range();
auto sc = expect_storage_class(use);
if (sc.errored) {
return Failure::kErrored;
}
if (match(Token::Type::kComma)) {
auto ac = expect_access(use);
if (ac.errored) {
return Failure::kErrored;
}
return VariableQualifier{sc.value, ac.value};
}
return Expect<VariableQualifier>{VariableQualifier{sc.value, ast::Access::kUndefined},
source};
});
if (vq.errored) {
return Failure::kErrored;
}
return vq;
}
// type_alias
// : TYPE IDENT EQUAL type_decl
Maybe<const ast::Alias*> ParserImpl::type_alias() {
if (!peek_is(Token::Type::kType))
return Failure::kNoMatch;
auto t = next();
const char* use = "type alias";
auto name = expect_ident(use);
if (name.errored)
return Failure::kErrored;
if (!expect(use, Token::Type::kEqual))
return Failure::kErrored;
auto type = type_decl();
if (type.errored)
return Failure::kErrored;
if (!type.matched)
return add_error(peek(), "invalid type alias");
return builder_.ty.alias(make_source_range_from(t.source()), name.value, type.value);
}
// type_decl
// : IDENTIFIER
// | BOOL
// | FLOAT32
// | INT32
// | UINT32
// | VEC2 LESS_THAN type_decl GREATER_THAN
// | VEC3 LESS_THAN type_decl GREATER_THAN
// | VEC4 LESS_THAN type_decl GREATER_THAN
// | PTR LESS_THAN storage_class, type_decl (COMMA access_mode)? GREATER_THAN
// | array_attribute_list* ARRAY LESS_THAN type_decl COMMA
// INT_LITERAL GREATER_THAN
// | array_attribute_list* ARRAY LESS_THAN type_decl
// GREATER_THAN
// | MAT2x2 LESS_THAN type_decl GREATER_THAN
// | MAT2x3 LESS_THAN type_decl GREATER_THAN
// | MAT2x4 LESS_THAN type_decl GREATER_THAN
// | MAT3x2 LESS_THAN type_decl GREATER_THAN
// | MAT3x3 LESS_THAN type_decl GREATER_THAN
// | MAT3x4 LESS_THAN type_decl GREATER_THAN
// | MAT4x2 LESS_THAN type_decl GREATER_THAN
// | MAT4x3 LESS_THAN type_decl GREATER_THAN
// | MAT4x4 LESS_THAN type_decl GREATER_THAN
// | texture_samplers
Maybe<const ast::Type*> ParserImpl::type_decl() {
auto t = peek();
Source source;
if (match(Token::Type::kIdentifier, &source)) {
return builder_.create<ast::TypeName>(source, builder_.Symbols().Register(t.to_str()));
}
if (match(Token::Type::kBool, &source))
return builder_.ty.bool_(source);
if (match(Token::Type::kF16, &source))
return builder_.ty.f16(source);
if (match(Token::Type::kF32, &source))
return builder_.ty.f32(source);
if (match(Token::Type::kI32, &source))
return builder_.ty.i32(source);
if (match(Token::Type::kU32, &source))
return builder_.ty.u32(source);
if (t.IsVector()) {
next(); // Consume the peek
return expect_type_decl_vector(t);
}
if (match(Token::Type::kPtr)) {
return expect_type_decl_pointer(t);
}
if (match(Token::Type::kAtomic)) {
return expect_type_decl_atomic(t);
}
if (match(Token::Type::kArray, &source)) {
return expect_type_decl_array(t);
}
if (t.IsMatrix()) {
next(); // Consume the peek
return expect_type_decl_matrix(t);
}
auto texture_or_sampler = texture_samplers();
if (texture_or_sampler.errored)
return Failure::kErrored;
if (texture_or_sampler.matched)
return texture_or_sampler;
return Failure::kNoMatch;
}
Expect<const ast::Type*> ParserImpl::expect_type(std::string_view use) {
auto type = type_decl();
if (type.errored)
return Failure::kErrored;
if (!type.matched)
return add_error(peek().source(), "invalid type", use);
return type.value;
}
Expect<const ast::Type*> ParserImpl::expect_type_decl_pointer(Token t) {
const char* use = "ptr declaration";
auto storage_class = ast::StorageClass::kNone;
auto access = ast::Access::kUndefined;
auto subtype = expect_lt_gt_block(use, [&]() -> Expect<const ast::Type*> {
auto sc = expect_storage_class(use);
if (sc.errored) {
return Failure::kErrored;
}
storage_class = sc.value;
if (!expect(use, Token::Type::kComma)) {
return Failure::kErrored;
}
auto type = expect_type(use);
if (type.errored) {
return Failure::kErrored;
}
if (match(Token::Type::kComma)) {
auto ac = expect_access("access control");
if (ac.errored) {
return Failure::kErrored;
}
access = ac.value;
}
return type.value;
});
if (subtype.errored) {
return Failure::kErrored;
}
return builder_.ty.pointer(make_source_range_from(t.source()), subtype.value, storage_class,
access);
}
Expect<const ast::Type*> ParserImpl::expect_type_decl_atomic(Token t) {
const char* use = "atomic declaration";
auto subtype = expect_lt_gt_block(use, [&] { return expect_type(use); });
if (subtype.errored) {
return Failure::kErrored;
}
return builder_.ty.atomic(make_source_range_from(t.source()), subtype.value);
}
Expect<const ast::Type*> ParserImpl::expect_type_decl_vector(Token t) {
uint32_t count = 2;
if (t.Is(Token::Type::kVec3)) {
count = 3;
} else if (t.Is(Token::Type::kVec4)) {
count = 4;
}
const ast::Type* subtype = nullptr;
if (peek_is(Token::Type::kLessThan)) {
const char* use = "vector";
auto ty = expect_lt_gt_block(use, [&] { return expect_type(use); });
if (ty.errored) {
return Failure::kErrored;
}
subtype = ty.value;
}
return builder_.ty.vec(make_source_range_from(t.source()), subtype, count);
}
Expect<const ast::Type*> ParserImpl::expect_type_decl_array(Token t) {
const char* use = "array declaration";
const ast::Expression* size = nullptr;
auto subtype = expect_lt_gt_block(use, [&]() -> Expect<const ast::Type*> {
auto type = expect_type(use);
if (type.errored)
return Failure::kErrored;
if (match(Token::Type::kComma)) {
auto expr = primary_expression();
if (expr.errored) {
return Failure::kErrored;
} else if (!expr.matched) {
return add_error(peek(), "expected array size expression");
}
size = std::move(expr.value);
}
return type.value;
});
if (subtype.errored) {
return Failure::kErrored;
}
return builder_.ty.array(make_source_range_from(t.source()), subtype.value, size);
}
Expect<const ast::Type*> ParserImpl::expect_type_decl_matrix(Token t) {
uint32_t rows = 2;
uint32_t columns = 2;
if (t.IsMat3xN()) {
columns = 3;
} else if (t.IsMat4xN()) {
columns = 4;
}
if (t.IsMatNx3()) {
rows = 3;
} else if (t.IsMatNx4()) {
rows = 4;
}
const ast::Type* subtype = nullptr;
if (peek_is(Token::Type::kLessThan)) {
const char* use = "matrix";
auto ty = expect_lt_gt_block(use, [&] { return expect_type(use); });
if (ty.errored) {
return Failure::kErrored;
}
subtype = ty.value;
}
return builder_.ty.mat(make_source_range_from(t.source()), subtype, columns, rows);
}
// storage_class
// : INPUT
// | OUTPUT
// | UNIFORM
// | WORKGROUP
// | STORAGE
// | PRIVATE
// | FUNCTION
Expect<ast::StorageClass> ParserImpl::expect_storage_class(std::string_view use) {
auto source = peek().source();
if (match(Token::Type::kUniform))
return {ast::StorageClass::kUniform, source};
if (match(Token::Type::kWorkgroup))
return {ast::StorageClass::kWorkgroup, source};
if (match(Token::Type::kStorage))
return {ast::StorageClass::kStorage, source};
if (match(Token::Type::kPrivate))
return {ast::StorageClass::kPrivate, source};
if (match(Token::Type::kFunction))
return {ast::StorageClass::kFunction, source};
return add_error(source, "invalid storage class", use);
}
// struct_decl
// : STRUCT IDENT struct_body_decl
Maybe<const ast::Struct*> ParserImpl::struct_decl() {
auto t = peek();
auto source = t.source();
if (!match(Token::Type::kStruct))
return Failure::kNoMatch;
auto name = expect_ident("struct declaration");
if (name.errored)
return Failure::kErrored;
auto body = expect_struct_body_decl();
if (body.errored)
return Failure::kErrored;
auto sym = builder_.Symbols().Register(name.value);
return create<ast::Struct>(source, sym, std::move(body.value), ast::AttributeList{});
}
// struct_body_decl
// : BRACE_LEFT (struct_member COMMA)* struct_member COMMA? BRACE_RIGHT
Expect<ast::StructMemberList> ParserImpl::expect_struct_body_decl() {
return expect_brace_block("struct declaration", [&]() -> Expect<ast::StructMemberList> {
ast::StructMemberList members;
bool errored = false;
while (continue_parsing()) {
// Check for the end of the list.
auto t = peek();
if (!t.IsIdentifier() && !t.Is(Token::Type::kAttr)) {
break;
}
auto member = expect_struct_member();
if (member.errored) {
errored = true;
if (!sync_to(Token::Type::kComma, /* consume: */ false)) {
return Failure::kErrored;
}
} else {
members.push_back(member.value);
}
// TODO(crbug.com/tint/1475): Remove support for semicolons.
if (auto sc = peek(); sc.Is(Token::Type::kSemicolon)) {
deprecated(sc.source(), "struct members should be separated with commas");
next();
continue;
}
if (!match(Token::Type::kComma))
break;
}
if (errored) {
return Failure::kErrored;
}
return members;
});
}
// struct_member
// : attribute* variable_ident_decl
Expect<ast::StructMember*> ParserImpl::expect_struct_member() {
auto attrs = attribute_list();
if (attrs.errored) {
return Failure::kErrored;
}
auto decl = expect_variable_ident_decl("struct member");
if (decl.errored)
return Failure::kErrored;
return create<ast::StructMember>(decl->source, builder_.Symbols().Register(decl->name),
decl->type, std::move(attrs.value));
}
// function_decl
// : function_header body_stmt
Maybe<const ast::Function*> ParserImpl::function_decl(ast::AttributeList& attrs) {
auto header = function_header();
if (header.errored) {
if (sync_to(Token::Type::kBraceLeft, /* consume: */ false)) {
// There were errors in the function header, but the parser has managed to
// resynchronize with the opening brace. As there's no outer
// synchronization token for function declarations, attempt to parse the
// function body. The AST isn't used as we've already errored, but this
// catches any errors inside the body, and can help keep the parser in
// sync.
expect_body_stmt();
}
return Failure::kErrored;
}
if (!header.matched)
return Failure::kNoMatch;
bool errored = false;
auto body = expect_body_stmt();
if (body.errored)
errored = true;
if (errored)
return Failure::kErrored;
return create<ast::Function>(header->source, builder_.Symbols().Register(header->name),
header->params, header->return_type, body.value, attrs,
header->return_type_attributes);
}
// function_header
// : FN IDENT PAREN_LEFT param_list PAREN_RIGHT return_type_decl_optional
// return_type_decl_optional
// :
// | ARROW attribute_list* type_decl
Maybe<ParserImpl::FunctionHeader> ParserImpl::function_header() {
Source source;
if (!match(Token::Type::kFn, &source)) {
return Failure::kNoMatch;
}
const char* use = "function declaration";
bool errored = false;
auto name = expect_ident(use);
if (name.errored) {
errored = true;
if (!sync_to(Token::Type::kParenLeft, /* consume: */ false)) {
return Failure::kErrored;
}
}
auto params = expect_paren_block(use, [&] { return expect_param_list(); });
if (params.errored) {
errored = true;
if (!synchronized_) {
return Failure::kErrored;
}
}
const ast::Type* return_type = nullptr;
ast::AttributeList return_attributes;
if (match(Token::Type::kArrow)) {
auto attrs = attribute_list();
if (attrs.errored) {
return Failure::kErrored;
}
return_attributes = attrs.value;
auto type = type_decl();
if (type.errored) {
errored = true;
} else if (!type.matched) {
return add_error(peek(), "unable to determine function return type");
} else {
return_type = type.value;
}
} else {
return_type = builder_.ty.void_();
}
if (errored) {
return Failure::kErrored;
}
return FunctionHeader{source, name.value, std::move(params.value), return_type,
std::move(return_attributes)};
}
// param_list
// :
// | (param COMMA)* param COMMA?
Expect<ast::VariableList> ParserImpl::expect_param_list() {
ast::VariableList ret;
while (continue_parsing()) {
// Check for the end of the list.
auto t = peek();
if (!t.IsIdentifier() && !t.Is(Token::Type::kAttr)) {
break;
}
auto param = expect_param();
if (param.errored)
return Failure::kErrored;
ret.push_back(param.value);
if (!match(Token::Type::kComma))
break;
}
return ret;
}
// param
// : attribute_list* variable_ident_decl
Expect<ast::Variable*> ParserImpl::expect_param() {
auto attrs = attribute_list();
auto decl = expect_variable_ident_decl("parameter");
if (decl.errored)
return Failure::kErrored;
auto* var = create<ast::Variable>(decl->source, // source
builder_.Symbols().Register(decl->name), // symbol
ast::StorageClass::kNone, // storage class
ast::Access::kUndefined, // access control
decl->type, // type
true, // is_const
false, // is_overridable
nullptr, // constructor
std::move(attrs.value)); // attributes
// Formal parameters are treated like a const declaration where the
// initializer value is provided by the call's argument. The key point is
// that it's not updatable after initially set. This is unlike C or GLSL
// which treat formal parameters like local variables that can be updated.
return var;
}
// pipeline_stage
// : VERTEX
// | FRAGMENT
// | COMPUTE
Expect<ast::PipelineStage> ParserImpl::expect_pipeline_stage() {
auto t = peek();
if (t == kVertexStage) {
next(); // Consume the peek
return {ast::PipelineStage::kVertex, t.source()};
}
if (t == kFragmentStage) {
next(); // Consume the peek
return {ast::PipelineStage::kFragment, t.source()};
}
if (t == kComputeStage) {
next(); // Consume the peek
return {ast::PipelineStage::kCompute, t.source()};
}
return add_error(peek(), "invalid value for stage attribute");
}
Expect<ast::Builtin> ParserImpl::expect_builtin() {
auto ident = expect_ident("builtin");
if (ident.errored)
return Failure::kErrored;
ast::Builtin builtin = ident_to_builtin(ident.value);
if (builtin == ast::Builtin::kNone)
return add_error(ident.source, "invalid value for builtin attribute");
return {builtin, ident.source};
}
// body_stmt
// : BRACE_LEFT statements BRACE_RIGHT
Expect<ast::BlockStatement*> ParserImpl::expect_body_stmt() {
return expect_brace_block("", [&]() -> Expect<ast::BlockStatement*> {
auto stmts = expect_statements();
if (stmts.errored)
return Failure::kErrored;
return create<ast::BlockStatement>(Source{}, stmts.value);
});
}
// paren_rhs_stmt
// : PAREN_LEFT logical_or_expression PAREN_RIGHT
Expect<const ast::Expression*> ParserImpl::expect_paren_rhs_stmt() {
return expect_paren_block("", [&]() -> Expect<const ast::Expression*> {
auto expr = logical_or_expression();
if (expr.errored)
return Failure::kErrored;
if (!expr.matched)
return add_error(peek(), "unable to parse expression");
return expr.value;
});
}
// statements
// : statement*
Expect<ast::StatementList> ParserImpl::expect_statements() {
bool errored = false;
ast::StatementList stmts;
while (continue_parsing()) {
auto stmt = statement();
if (stmt.errored) {
errored = true;
} else if (stmt.matched) {
stmts.emplace_back(stmt.value);
} else {
break;
}
}
if (errored)
return Failure::kErrored;
return stmts;
}
// statement
// : SEMICOLON
// | body_stmt?
// | if_stmt
// | switch_stmt
// | loop_stmt
// | for_stmt
// | non_block_statement
// : return_stmt SEMICOLON
// | func_call_stmt SEMICOLON
// | variable_stmt SEMICOLON
// | break_stmt SEMICOLON
// | continue_stmt SEMICOLON
// | DISCARD SEMICOLON
// | assignment_stmt SEMICOLON
// | increment_stmt SEMICOLON
// | decrement_stmt SEMICOLON
Maybe<const ast::Statement*> ParserImpl::statement() {
while (match(Token::Type::kSemicolon)) {
// Skip empty statements
}
// Non-block statments that error can resynchronize on semicolon.
auto stmt = sync(Token::Type::kSemicolon, [&] { return non_block_statement(); });
if (stmt.errored)
return Failure::kErrored;
if (stmt.matched)
return stmt;
auto stmt_if = if_stmt();
if (stmt_if.errored)
return Failure::kErrored;
if (stmt_if.matched)
return stmt_if.value;
auto sw = switch_stmt();
if (sw.errored)
return Failure::kErrored;
if (sw.matched)
return sw.value;
auto loop = loop_stmt();
if (loop.errored)
return Failure::kErrored;
if (loop.matched)
return loop.value;
auto stmt_for = for_stmt();
if (stmt_for.errored)
return Failure::kErrored;
if (stmt_for.matched)
return stmt_for.value;
if (peek_is(Token::Type::kBraceLeft)) {
auto body = expect_body_stmt();
if (body.errored)
return Failure::kErrored;
return body.value;
}
return Failure::kNoMatch;
}
// statement (continued)
// : return_stmt SEMICOLON
// | func_call_stmt SEMICOLON
// | variable_stmt SEMICOLON
// | break_stmt SEMICOLON
// | continue_stmt SEMICOLON
// | DISCARD SEMICOLON
// | assignment_stmt SEMICOLON
// | increment_stmt SEMICOLON
// | decrement_stmt SEMICOLON
Maybe<const ast::Statement*> ParserImpl::non_block_statement() {
auto stmt = [&]() -> Maybe<const ast::Statement*> {
auto ret_stmt = return_stmt();
if (ret_stmt.errored)
return Failure::kErrored;
if (ret_stmt.matched)
return ret_stmt.value;
auto func = func_call_stmt();
if (func.errored)
return Failure::kErrored;
if (func.matched)
return func.value;
auto var = variable_stmt();
if (var.errored)
return Failure::kErrored;
if (var.matched)
return var.value;
auto b = break_stmt();
if (b.errored)
return Failure::kErrored;
if (b.matched)
return b.value;
auto cont = continue_stmt();
if (cont.errored)
return Failure::kErrored;
if (cont.matched)
return cont.value;
auto assign = assignment_stmt();
if (assign.errored)
return Failure::kErrored;
if (assign.matched)
return assign.value;
Source source;
if (match(Token::Type::kDiscard, &source))
return create<ast::DiscardStatement>(source);
return Failure::kNoMatch;
}();
if (stmt.matched && !expect(stmt->Name(), Token::Type::kSemicolon))
return Failure::kErrored;
return stmt;
}
// return_stmt
// : RETURN logical_or_expression?
Maybe<const ast::ReturnStatement*> ParserImpl::return_stmt() {
Source source;
if (!match(Token::Type::kReturn, &source))
return Failure::kNoMatch;
if (peek_is(Token::Type::kSemicolon))
return create<ast::ReturnStatement>(source, nullptr);
auto expr = logical_or_expression();
if (expr.errored)
return Failure::kErrored;
// TODO(bclayton): Check matched?
return create<ast::ReturnStatement>(source, expr.value);
}
// variable_stmt
// : variable_decl
// | variable_decl EQUAL logical_or_expression
// | CONST variable_ident_decl EQUAL logical_or_expression
Maybe<const ast::VariableDeclStatement*> ParserImpl::variable_stmt() {
if (match(Token::Type::kLet)) {
auto decl = expect_variable_ident_decl("let declaration",
/*allow_inferred = */ true);
if (decl.errored)
return Failure::kErrored;
if (!expect("let declaration", Token::Type::kEqual))
return Failure::kErrored;
auto constructor = logical_or_expression();
if (constructor.errored)
return Failure::kErrored;
if (!constructor.matched)
return add_error(peek(), "missing constructor for let declaration");
auto* var = create<ast::Variable>(decl->source, // source
builder_.Symbols().Register(decl->name), // symbol
ast::StorageClass::kNone, // storage class
ast::Access::kUndefined, // access control
decl->type, // type
true, // is_const
false, // is_overridable
constructor.value, // constructor
ast::AttributeList{}); // attributes
return create<ast::VariableDeclStatement>(decl->source, var);
}
auto decl = variable_decl(/*allow_inferred = */ true);
if (decl.errored)
return Failure::kErrored;
if (!decl.matched)
return Failure::kNoMatch;
const ast::Expression* constructor = nullptr;
if (match(Token::Type::kEqual)) {
auto constructor_expr = logical_or_expression();
if (constructor_expr.errored)
return Failure::kErrored;
if (!constructor_expr.matched)
return add_error(peek(), "missing constructor for variable declaration");
constructor = constructor_expr.value;
}
auto* var = create<ast::Variable>(decl->source, // source
builder_.Symbols().Register(decl->name), // symbol
decl->storage_class, // storage class
decl->access, // access control
decl->type, // type
false, // is_const
false, // is_overridable
constructor, // constructor
ast::AttributeList{}); // attributes
return create<ast::VariableDeclStatement>(var->source, var);
}
// if_stmt
// : IF expression compound_stmt ( ELSE else_stmt ) ?
// else_stmt
// : body_stmt
// | if_stmt
Maybe<const ast::IfStatement*> ParserImpl::if_stmt() {
// Parse if-else chains iteratively instead of recursively, to avoid
// stack-overflow for long chains of if-else statements.
struct IfInfo {
Source source;
const ast::Expression* condition;
const ast::BlockStatement* body;
};
// Parse an if statement, capturing the source, condition, and body statement.
auto parse_if = [&]() -> Maybe<IfInfo> {
Source source;
if (!match(Token::Type::kIf, &source)) {
return Failure::kNoMatch;
}
auto condition = logical_or_expression();
if (condition.errored) {
return Failure::kErrored;
}
if (!condition.matched) {
return add_error(peek(), "unable to parse condition expression");
}
auto body = expect_body_stmt();
if (body.errored) {
return Failure::kErrored;
}
return IfInfo{source, condition.value, body.value};
};
std::vector<IfInfo> statements;
// Parse the first if statement.
auto first_if = parse_if();
if (first_if.errored) {
return Failure::kErrored;
} else if (!first_if.matched) {
return Failure::kNoMatch;
}
statements.push_back(first_if.value);
// Parse the components of every "else {if}" in the chain.
const ast::Statement* last_stmt = nullptr;
while (continue_parsing()) {
if (!match(Token::Type::kElse)) {
break;
}
// Try to parse an "else if".
auto else_if = parse_if();
if (else_if.errored) {
return Failure::kErrored;
} else if (else_if.matched) {
statements.push_back(else_if.value);
continue;
}
// If it wasn't an "else if", it must just be an "else".
auto else_body = expect_body_stmt();
if (else_body.errored) {
return Failure::kErrored;
}
last_stmt = else_body.value;
break;
}
// Now walk back through the statements to create their AST nodes.
for (auto itr = statements.rbegin(); itr != statements.rend(); itr++) {
last_stmt = create<ast::IfStatement>(itr->source, itr->condition, itr->body, last_stmt);
}
return last_stmt->As<ast::IfStatement>();
}
// switch_stmt
// : SWITCH paren_rhs_stmt BRACKET_LEFT switch_body+ BRACKET_RIGHT
Maybe<const ast::SwitchStatement*> ParserImpl::switch_stmt() {
Source source;
if (!match(Token::Type::kSwitch, &source))
return Failure::kNoMatch;
auto condition = logical_or_expression();
if (condition.errored)
return Failure::kErrored;
if (!condition.matched) {
return add_error(peek(), "unable to parse selector expression");
}
auto body = expect_brace_block("switch statement", [&]() -> Expect<ast::CaseStatementList> {
bool errored = false;
ast::CaseStatementList list;
while (continue_parsing()) {
auto stmt = switch_body();
if (stmt.errored) {
errored = true;
continue;
}
if (!stmt.matched)
break;
list.push_back(stmt.value);
}
if (errored)
return Failure::kErrored;
return list;
});
if (body.errored)
return Failure::kErrored;
return create<ast::SwitchStatement>(source, condition.value, body.value);
}
// switch_body
// : CASE case_selectors COLON? BRACKET_LEFT case_body BRACKET_RIGHT
// | DEFAULT COLON? BRACKET_LEFT case_body BRACKET_RIGHT
Maybe<const ast::CaseStatement*> ParserImpl::switch_body() {
if (!peek_is(Token::Type::kCase) && !peek_is(Token::Type::kDefault))
return Failure::kNoMatch;
auto t = next();
auto source = t.source();
ast::CaseSelectorList selector_list;
if (t.Is(Token::Type::kCase)) {
auto selectors = expect_case_selectors();
if (selectors.errored)
return Failure::kErrored;
selector_list = std::move(selectors.value);
}
// Consume the optional colon if present.
match(Token::Type::kColon);
const char* use = "case statement";
auto body = expect_brace_block(use, [&] { return case_body(); });
if (body.errored)
return Failure::kErrored;
if (!body.matched)
return add_error(body.source, "expected case body");
return create<ast::CaseStatement>(source, selector_list, body.value);
}
// case_selectors
// : const_literal (COMMA const_literal)* COMMA?
Expect<ast::CaseSelectorList> ParserImpl::expect_case_selectors() {
ast::CaseSelectorList selectors;
while (continue_parsing()) {
auto cond = const_literal();
if (cond.errored) {
return Failure::kErrored;
} else if (!cond.matched) {
break;
} else if (!cond->Is<ast::IntLiteralExpression>()) {
return add_error(cond.value->source, "invalid case selector must be an integer value");
}
selectors.push_back(cond.value->As<ast::IntLiteralExpression>());
if (!match(Token::Type::kComma)) {
break;
}
}
if (selectors.empty())
return add_error(peek(), "unable to parse case selectors");
return selectors;
}
// case_body
// :
// | statement case_body
// | FALLTHROUGH SEMICOLON
Maybe<const ast::BlockStatement*> ParserImpl::case_body() {
ast::StatementList stmts;
while (continue_parsing()) {
Source source;
if (match(Token::Type::kFallthrough, &source)) {
if (!expect("fallthrough statement", Token::Type::kSemicolon))
return Failure::kErrored;
stmts.emplace_back(create<ast::FallthroughStatement>(source));
break;
}
auto stmt = statement();
if (stmt.errored)
return Failure::kErrored;
if (!stmt.matched)
break;
stmts.emplace_back(stmt.value);
}
return create<ast::BlockStatement>(Source{}, stmts);
}
// loop_stmt
// : LOOP BRACKET_LEFT statements continuing_stmt? BRACKET_RIGHT
Maybe<const ast::LoopStatement*> ParserImpl::loop_stmt() {
Source source;
if (!match(Token::Type::kLoop, &source))
return Failure::kNoMatch;
return expect_brace_block("loop", [&]() -> Maybe<const ast::LoopStatement*> {
auto stmts = expect_statements();
if (stmts.errored)
return Failure::kErrored;
auto continuing = continuing_stmt();
if (continuing.errored)
return Failure::kErrored;
auto* body = create<ast::BlockStatement>(source, stmts.value);
return create<ast::LoopStatement>(source, body, continuing.value);
});
}
ForHeader::ForHeader(const ast::Statement* init,
const ast::Expression* cond,
const ast::Statement* cont)
: initializer(init), condition(cond), continuing(cont) {}
ForHeader::~ForHeader() = default;
// (variable_stmt | increment_stmt | decrement_stmt | assignment_stmt |
// func_call_stmt)?
Maybe<const ast::Statement*> ParserImpl::for_header_initializer() {
auto call = func_call_stmt();
if (call.errored)
return Failure::kErrored;
if (call.matched)
return call.value;
auto var = variable_stmt();
if (var.errored)
return Failure::kErrored;
if (var.matched)
return var.value;
auto assign = assignment_stmt();
if (assign.errored)
return Failure::kErrored;
if (assign.matched)
return assign.value;
return Failure::kNoMatch;
}
// (increment_stmt | decrement_stmt | assignment_stmt | func_call_stmt)?
Maybe<const ast::Statement*> ParserImpl::for_header_continuing() {
auto call_stmt = func_call_stmt();
if (call_stmt.errored)
return Failure::kErrored;
if (call_stmt.matched)
return call_stmt.value;
auto assign = assignment_stmt();
if (assign.errored)
return Failure::kErrored;
if (assign.matched)
return assign.value;
return Failure::kNoMatch;
}
// for_header
// : (variable_stmt | assignment_stmt | func_call_stmt)?
// SEMICOLON
// logical_or_expression? SEMICOLON
// (assignment_stmt | func_call_stmt)?
Expect<std::unique_ptr<ForHeader>> ParserImpl::expect_for_header() {
auto initializer = for_header_initializer();
if (initializer.errored)
return Failure::kErrored;
if (!expect("initializer in for loop", Token::Type::kSemicolon))
return Failure::kErrored;
auto condition = logical_or_expression();
if (condition.errored)
return Failure::kErrored;
if (!expect("condition in for loop", Token::Type::kSemicolon))
return Failure::kErrored;
auto continuing = for_header_continuing();
if (continuing.errored)
return Failure::kErrored;
return std::make_unique<ForHeader>(initializer.value, condition.value, continuing.value);
}
// for_statement
// : FOR PAREN_LEFT for_header PAREN_RIGHT BRACE_LEFT statements BRACE_RIGHT
Maybe<const ast::ForLoopStatement*> ParserImpl::for_stmt() {
Source source;
if (!match(Token::Type::kFor, &source))
return Failure::kNoMatch;
auto header = expect_paren_block("for loop", [&] { return expect_for_header(); });
if (header.errored)
return Failure::kErrored;
auto stmts = expect_brace_block("for loop", [&] { return expect_statements(); });
if (stmts.errored)
return Failure::kErrored;
return create<ast::ForLoopStatement>(source, header->initializer, header->condition,
header->continuing,
create<ast::BlockStatement>(stmts.value));
}
// func_call_stmt
// : IDENT argument_expression_list
Maybe<const ast::CallStatement*> ParserImpl::func_call_stmt() {
auto t = peek();
auto t2 = peek(1);
if (!t.IsIdentifier() || !t2.Is(Token::Type::kParenLeft))
return Failure::kNoMatch;
next(); // Consume the first peek
auto source = t.source();
auto name = t.to_str();
auto params = expect_argument_expression_list("function call");
if (params.errored)
return Failure::kErrored;
return create<ast::CallStatement>(
source,
create<ast::CallExpression>(
source, create<ast::IdentifierExpression>(source, builder_.Symbols().Register(name)),
std::move(params.value)));
}
// break_stmt
// : BREAK
Maybe<const ast::BreakStatement*> ParserImpl::break_stmt() {
Source source;
if (!match(Token::Type::kBreak, &source))
return Failure::kNoMatch;
return create<ast::BreakStatement>(source);
}
// continue_stmt
// : CONTINUE
Maybe<const ast::ContinueStatement*> ParserImpl::continue_stmt() {
Source source;
if (!match(Token::Type::kContinue, &source))
return Failure::kNoMatch;
return create<ast::ContinueStatement>(source);
}
// continuing_stmt
// : CONTINUING body_stmt
Maybe<const ast::BlockStatement*> ParserImpl::continuing_stmt() {
if (!match(Token::Type::kContinuing))
return create<ast::BlockStatement>(Source{}, ast::StatementList{});
return expect_body_stmt();
}
// primary_expression
// : IDENT argument_expression_list?
// | type_decl argument_expression_list
// | const_literal
// | paren_rhs_stmt
// | BITCAST LESS_THAN type_decl GREATER_THAN paren_rhs_stmt
Maybe<const ast::Expression*> ParserImpl::primary_expression() {
auto t = peek();
auto source = t.source();
auto lit = const_literal();
if (lit.errored) {
return Failure::kErrored;
}
if (lit.matched) {
return lit.value;
}
if (t.Is(Token::Type::kParenLeft)) {
auto paren = expect_paren_rhs_stmt();
if (paren.errored) {
return Failure::kErrored;
}
return paren.value;
}
if (match(Token::Type::kBitcast)) {
const char* use = "bitcast expression";
auto type = expect_lt_gt_block(use, [&] { return expect_type(use); });
if (type.errored)
return Failure::kErrored;
auto params = expect_paren_rhs_stmt();
if (params.errored)
return Failure::kErrored;
return create<ast::BitcastExpression>(source, type.value, params.value);
}
if (t.IsIdentifier()) {
next();
auto* ident =
create<ast::IdentifierExpression>(t.source(), builder_.Symbols().Register(t.to_str()));
if (peek_is(Token::Type::kParenLeft)) {
auto params = expect_argument_expression_list("function call");
if (params.errored)
return Failure::kErrored;
return create<ast::CallExpression>(source, ident, std::move(params.value));
}
return ident;
}
auto type = type_decl();
if (type.errored)
return Failure::kErrored;
if (type.matched) {
auto params = expect_argument_expression_list("type constructor");
if (params.errored)
return Failure::kErrored;
return builder_.Construct(source, type.value, std::move(params.value));
}
return Failure::kNoMatch;
}
// postfix_expression
// :
// | BRACE_LEFT logical_or_expression BRACE_RIGHT postfix_expr
// | PERIOD IDENTIFIER postfix_expr
Maybe<const ast::Expression*> ParserImpl::postfix_expression(const ast::Expression* prefix) {
Source source;
while (continue_parsing()) {
if (match(Token::Type::kBracketLeft, &source)) {
auto res = sync(Token::Type::kBracketRight, [&]() -> Maybe<const ast::Expression*> {
auto param = logical_or_expression();
if (param.errored)
return Failure::kErrored;
if (!param.matched) {
return add_error(peek(), "unable to parse expression inside []");
}
if (!expect("index accessor", Token::Type::kBracketRight)) {
return Failure::kErrored;
}
return create<ast::IndexAccessorExpression>(source, prefix, param.value);
});
if (res.errored) {
return res;
}
prefix = res.value;
continue;
}
if (match(Token::Type::kPeriod)) {
auto ident = expect_ident("member accessor");
if (ident.errored) {
return Failure::kErrored;
}
prefix = create<ast::MemberAccessorExpression>(
ident.source, prefix,
create<ast::IdentifierExpression>(ident.source,
builder_.Symbols().Register(ident.value)));
continue;
}
return prefix;
}
return Failure::kErrored;
}
// singular_expression
// : primary_expression postfix_expr
Maybe<const ast::Expression*> ParserImpl::singular_expression() {
auto prefix = primary_expression();
if (prefix.errored)
return Failure::kErrored;
if (!prefix.matched)
return Failure::kNoMatch;
return postfix_expression(prefix.value);
}
// argument_expression_list
// : PAREN_LEFT ((logical_or_expression COMMA)* logical_or_expression COMMA?)?
// PAREN_RIGHT
Expect<ast::ExpressionList> ParserImpl::expect_argument_expression_list(std::string_view use) {
return expect_paren_block(use, [&]() -> Expect<ast::ExpressionList> {
ast::ExpressionList ret;
while (continue_parsing()) {
auto arg = logical_or_expression();
if (arg.errored) {
return Failure::kErrored;
} else if (!arg.matched) {
break;
}
ret.push_back(arg.value);
if (!match(Token::Type::kComma)) {
break;
}
}
return ret;
});
}
// unary_expression
// : singular_expression
// | MINUS unary_expression
// | BANG unary_expression
// | TILDE unary_expression
// | STAR unary_expression
// | AND unary_expression
Maybe<const ast::Expression*> ParserImpl::unary_expression() {
auto t = peek();
if (match(Token::Type::kPlusPlus) || match(Token::Type::kMinusMinus)) {
add_error(t.source(),
"prefix increment and decrement operators are reserved for a "
"future WGSL version");
return Failure::kErrored;
}
ast::UnaryOp op;
if (match(Token::Type::kMinus)) {
op = ast::UnaryOp::kNegation;
} else if (match(Token::Type::kBang)) {
op = ast::UnaryOp::kNot;
} else if (match(Token::Type::kTilde)) {
op = ast::UnaryOp::kComplement;
} else if (match(Token::Type::kStar)) {
op = ast::UnaryOp::kIndirection;
} else if (match(Token::Type::kAnd)) {
op = ast::UnaryOp::kAddressOf;
} else {
return singular_expression();
}
if (parse_depth_ >= kMaxParseDepth) {
// We've hit a maximum parser recursive depth.
// We can't call into unary_expression() as we might stack overflow.
// Instead, report an error
add_error(peek(), "maximum parser recursive depth reached");
return Failure::kErrored;
}
++parse_depth_;
auto expr = unary_expression();
--parse_depth_;
if (expr.errored) {
return Failure::kErrored;
}
if (!expr.matched) {
return add_error(
peek(), "unable to parse right side of " + std::string(t.to_name()) + " expression");
}
return create<ast::UnaryOpExpression>(t.source(), op, expr.value);
}
// multiplicative_expr
// :
// | STAR unary_expression multiplicative_expr
// | FORWARD_SLASH unary_expression multiplicative_expr
// | MODULO unary_expression multiplicative_expr
Expect<const ast::Expression*> ParserImpl::expect_multiplicative_expr(const ast::Expression* lhs) {
while (continue_parsing()) {
ast::BinaryOp op = ast::BinaryOp::kNone;
if (peek_is(Token::Type::kStar))
op = ast::BinaryOp::kMultiply;
else if (peek_is(Token::Type::kForwardSlash))
op = ast::BinaryOp::kDivide;
else if (peek_is(Token::Type::kMod))
op = ast::BinaryOp::kModulo;
else
return lhs;
auto t = next();
auto source = t.source();
auto name = t.to_name();
auto rhs = unary_expression();
if (rhs.errored)
return Failure::kErrored;
if (!rhs.matched) {
return add_error(peek(),
"unable to parse right side of " + std::string(name) + " expression");
}
lhs = create<ast::BinaryExpression>(source, op, lhs, rhs.value);
}
return Failure::kErrored;
}
// multiplicative_expression
// : unary_expression multiplicative_expr
Maybe<const ast::Expression*> ParserImpl::multiplicative_expression() {
auto lhs = unary_expression();
if (lhs.errored)
return Failure::kErrored;
if (!lhs.matched)
return Failure::kNoMatch;
return expect_multiplicative_expr(lhs.value);
}
// additive_expr
// :
// | PLUS multiplicative_expression additive_expr
// | MINUS multiplicative_expression additive_expr
Expect<const ast::Expression*> ParserImpl::expect_additive_expr(const ast::Expression* lhs) {
while (continue_parsing()) {
ast::BinaryOp op = ast::BinaryOp::kNone;
if (peek_is(Token::Type::kPlus))
op = ast::BinaryOp::kAdd;
else if (peek_is(Token::Type::kMinus))
op = ast::BinaryOp::kSubtract;
else
return lhs;
auto t = next();
auto source = t.source();
auto rhs = multiplicative_expression();
if (rhs.errored)
return Failure::kErrored;
if (!rhs.matched)
return add_error(peek(), "unable to parse right side of + expression");
lhs = create<ast::BinaryExpression>(source, op, lhs, rhs.value);
}
return Failure::kErrored;
}
// additive_expression
// : multiplicative_expression additive_expr
Maybe<const ast::Expression*> ParserImpl::additive_expression() {
auto lhs = multiplicative_expression();
if (lhs.errored)
return Failure::kErrored;
if (!lhs.matched)
return Failure::kNoMatch;
return expect_additive_expr(lhs.value);
}
// shift_expr
// :
// | SHIFT_LEFT additive_expression shift_expr
// | SHIFT_RIGHT additive_expression shift_expr
Expect<const ast::Expression*> ParserImpl::expect_shift_expr(const ast::Expression* lhs) {
while (continue_parsing()) {
auto* name = "";
ast::BinaryOp op = ast::BinaryOp::kNone;
if (peek_is(Token::Type::kShiftLeft)) {
op = ast::BinaryOp::kShiftLeft;
name = "<<";
} else if (peek_is(Token::Type::kShiftRight)) {
op = ast::BinaryOp::kShiftRight;
name = ">>";
} else {
return lhs;
}
auto t = next();
auto source = t.source();
auto rhs = additive_expression();
if (rhs.errored)
return Failure::kErrored;
if (!rhs.matched) {
return add_error(peek(),
std::string("unable to parse right side of ") + name + " expression");
}
return lhs = create<ast::BinaryExpression>(source, op, lhs, rhs.value);
}
return Failure::kErrored;
}
// shift_expression
// : additive_expression shift_expr
Maybe<const ast::Expression*> ParserImpl::shift_expression() {
auto lhs = additive_expression();
if (lhs.errored)
return Failure::kErrored;
if (!lhs.matched)
return Failure::kNoMatch;
return expect_shift_expr(lhs.value);
}
// relational_expr
// :
// | LESS_THAN shift_expression relational_expr
// | GREATER_THAN shift_expression relational_expr
// | LESS_THAN_EQUAL shift_expression relational_expr
// | GREATER_THAN_EQUAL shift_expression relational_expr
Expect<const ast::Expression*> ParserImpl::expect_relational_expr(const ast::Expression* lhs) {
while (continue_parsing()) {
ast::BinaryOp op = ast::BinaryOp::kNone;
if (peek_is(Token::Type::kLessThan))
op = ast::BinaryOp::kLessThan;
else if (peek_is(Token::Type::kGreaterThan))
op = ast::BinaryOp::kGreaterThan;
else if (peek_is(Token::Type::kLessThanEqual))
op = ast::BinaryOp::kLessThanEqual;
else if (peek_is(Token::Type::kGreaterThanEqual))
op = ast::BinaryOp::kGreaterThanEqual;
else
return lhs;
auto t = next();
auto source = t.source();
auto name = t.to_name();
auto rhs = shift_expression();
if (rhs.errored)
return Failure::kErrored;
if (!rhs.matched) {
return add_error(peek(),
"unable to parse right side of " + std::string(name) + " expression");
}
lhs = create<ast::BinaryExpression>(source, op, lhs, rhs.value);
}
return Failure::kErrored;
}
// relational_expression
// : shift_expression relational_expr
Maybe<const ast::Expression*> ParserImpl::relational_expression() {
auto lhs = shift_expression();
if (lhs.errored)
return Failure::kErrored;
if (!lhs.matched)
return Failure::kNoMatch;
return expect_relational_expr(lhs.value);
}
// equality_expr
// :
// | EQUAL_EQUAL relational_expression equality_expr
// | NOT_EQUAL relational_expression equality_expr
Expect<const ast::Expression*> ParserImpl::expect_equality_expr(const ast::Expression* lhs) {
while (continue_parsing()) {
ast::BinaryOp op = ast::BinaryOp::kNone;
if (peek_is(Token::Type::kEqualEqual))
op = ast::BinaryOp::kEqual;
else if (peek_is(Token::Type::kNotEqual))
op = ast::BinaryOp::kNotEqual;
else
return lhs;
auto t = next();
auto source = t.source();
auto name = t.to_name();
auto rhs = relational_expression();
if (rhs.errored)
return Failure::kErrored;
if (!rhs.matched) {
return add_error(peek(),
"unable to parse right side of " + std::string(name) + " expression");
}
lhs = create<ast::BinaryExpression>(source, op, lhs, rhs.value);
}
return Failure::kErrored;
}
// equality_expression
// : relational_expression equality_expr
Maybe<const ast::Expression*> ParserImpl::equality_expression() {
auto lhs = relational_expression();
if (lhs.errored)
return Failure::kErrored;
if (!lhs.matched)
return Failure::kNoMatch;
return expect_equality_expr(lhs.value);
}
// and_expr
// :
// | AND equality_expression and_expr
Expect<const ast::Expression*> ParserImpl::expect_and_expr(const ast::Expression* lhs) {
while (continue_parsing()) {
if (!peek_is(Token::Type::kAnd)) {
return lhs;
}
auto t = next();
auto source = t.source();
auto rhs = equality_expression();
if (rhs.errored)
return Failure::kErrored;
if (!rhs.matched)
return add_error(peek(), "unable to parse right side of & expression");
lhs = create<ast::BinaryExpression>(source, ast::BinaryOp::kAnd, lhs, rhs.value);
}
return Failure::kErrored;
}
// and_expression
// : equality_expression and_expr
Maybe<const ast::Expression*> ParserImpl::and_expression() {
auto lhs = equality_expression();
if (lhs.errored)
return Failure::kErrored;
if (!lhs.matched)
return Failure::kNoMatch;
return expect_and_expr(lhs.value);
}
// exclusive_or_expr
// :
// | XOR and_expression exclusive_or_expr
Expect<const ast::Expression*> ParserImpl::expect_exclusive_or_expr(const ast::Expression* lhs) {
while (continue_parsing()) {
Source source;
if (!match(Token::Type::kXor, &source))
return lhs;
auto rhs = and_expression();
if (rhs.errored)
return Failure::kErrored;
if (!rhs.matched)
return add_error(peek(), "unable to parse right side of ^ expression");
lhs = create<ast::BinaryExpression>(source, ast::BinaryOp::kXor, lhs, rhs.value);
}
return Failure::kErrored;
}
// exclusive_or_expression
// : and_expression exclusive_or_expr
Maybe<const ast::Expression*> ParserImpl::exclusive_or_expression() {
auto lhs = and_expression();
if (lhs.errored)
return Failure::kErrored;
if (!lhs.matched)
return Failure::kNoMatch;
return expect_exclusive_or_expr(lhs.value);
}
// inclusive_or_expr
// :
// | OR exclusive_or_expression inclusive_or_expr
Expect<const ast::Expression*> ParserImpl::expect_inclusive_or_expr(const ast::Expression* lhs) {
while (continue_parsing()) {
Source source;
if (!match(Token::Type::kOr, &source))
return lhs;
auto rhs = exclusive_or_expression();
if (rhs.errored)
return Failure::kErrored;
if (!rhs.matched)
return add_error(peek(), "unable to parse right side of | expression");
lhs = create<ast::BinaryExpression>(source, ast::BinaryOp::kOr, lhs, rhs.value);
}
return Failure::kErrored;
}
// inclusive_or_expression
// : exclusive_or_expression inclusive_or_expr
Maybe<const ast::Expression*> ParserImpl::inclusive_or_expression() {
auto lhs = exclusive_or_expression();
if (lhs.errored)
return Failure::kErrored;
if (!lhs.matched)
return Failure::kNoMatch;
return expect_inclusive_or_expr(lhs.value);
}
// logical_and_expr
// :
// | AND_AND inclusive_or_expression logical_and_expr
Expect<const ast::Expression*> ParserImpl::expect_logical_and_expr(const ast::Expression* lhs) {
while (continue_parsing()) {
if (!peek_is(Token::Type::kAndAnd)) {
return lhs;
}
auto t = next();
auto source = t.source();
auto rhs = inclusive_or_expression();
if (rhs.errored)
return Failure::kErrored;
if (!rhs.matched)
return add_error(peek(), "unable to parse right side of && expression");
lhs = create<ast::BinaryExpression>(source, ast::BinaryOp::kLogicalAnd, lhs, rhs.value);
}
return Failure::kErrored;
}
// logical_and_expression
// : inclusive_or_expression logical_and_expr
Maybe<const ast::Expression*> ParserImpl::logical_and_expression() {
auto lhs = inclusive_or_expression();
if (lhs.errored)
return Failure::kErrored;
if (!lhs.matched)
return Failure::kNoMatch;
return expect_logical_and_expr(lhs.value);
}
// logical_or_expr
// :
// | OR_OR logical_and_expression logical_or_expr
Expect<const ast::Expression*> ParserImpl::expect_logical_or_expr(const ast::Expression* lhs) {
while (continue_parsing()) {
Source source;
if (!match(Token::Type::kOrOr, &source))
return lhs;
auto rhs = logical_and_expression();
if (rhs.errored)
return Failure::kErrored;
if (!rhs.matched)
return add_error(peek(), "unable to parse right side of || expression");
lhs = create<ast::BinaryExpression>(source, ast::BinaryOp::kLogicalOr, lhs, rhs.value);
}
return Failure::kErrored;
}
// logical_or_expression
// : logical_and_expression logical_or_expr
Maybe<const ast::Expression*> ParserImpl::logical_or_expression() {
auto lhs = logical_and_expression();
if (lhs.errored)
return Failure::kErrored;
if (!lhs.matched)
return Failure::kNoMatch;
return expect_logical_or_expr(lhs.value);
}
// compound_assignment_operator:
// | plus_equal
// | minus_equal
// | times_equal
// | division_equal
// | modulo_equal
// | and_equal
// | or_equal
// | xor_equal
Maybe<ast::BinaryOp> ParserImpl::compound_assignment_operator() {
ast::BinaryOp compound_op = ast::BinaryOp::kNone;
if (peek_is(Token::Type::kPlusEqual)) {
compound_op = ast::BinaryOp::kAdd;
} else if (peek_is(Token::Type::kMinusEqual)) {
compound_op = ast::BinaryOp::kSubtract;
} else if (peek_is(Token::Type::kTimesEqual)) {
compound_op = ast::BinaryOp::kMultiply;
} else if (peek_is(Token::Type::kDivisionEqual)) {
compound_op = ast::BinaryOp::kDivide;
} else if (peek_is(Token::Type::kModuloEqual)) {
compound_op = ast::BinaryOp::kModulo;
} else if (peek_is(Token::Type::kAndEqual)) {
compound_op = ast::BinaryOp::kAnd;
} else if (peek_is(Token::Type::kOrEqual)) {
compound_op = ast::BinaryOp::kOr;
} else if (peek_is(Token::Type::kXorEqual)) {
compound_op = ast::BinaryOp::kXor;
}
if (compound_op != ast::BinaryOp::kNone) {
next();
return compound_op;
}
return Failure::kNoMatch;
}
// assignment_stmt
// | lhs_expression ( equal | compound_assignment_operator ) expression
// | underscore equal expression
// increment_stmt
// | lhs_expression PLUS_PLUS
// decrement_stmt
// | lhs_expression MINUS_MINUS
Maybe<const ast::Statement*> ParserImpl::assignment_stmt() {
auto t = peek();
auto source = t.source();
// tint:295 - Test for `ident COLON` - this is invalid grammar, and without
// special casing will error as "missing = for assignment", which is less
// helpful than this error message:
if (peek_is(Token::Type::kIdentifier) && peek_is(Token::Type::kColon, 1)) {
return add_error(peek(0).source(), "expected 'var' for variable declaration");
}
auto lhs = unary_expression();
if (lhs.errored) {
return Failure::kErrored;
}
if (!lhs.matched) {
if (!match(Token::Type::kUnderscore, &source)) {
return Failure::kNoMatch;
}
lhs = create<ast::PhonyExpression>(source);
}
// Handle increment and decrement statements.
// We do this here because the parsing of the LHS expression overlaps with
// the assignment statement, and we cannot tell which we are parsing until we
// hit the ++/--/= token.
if (match(Token::Type::kPlusPlus)) {
return create<ast::IncrementDecrementStatement>(source, lhs.value, true);
} else if (match(Token::Type::kMinusMinus)) {
return create<ast::IncrementDecrementStatement>(source, lhs.value, false);
}
auto compound_op = compound_assignment_operator();
if (compound_op.errored) {
return Failure::kErrored;
}
if (!compound_op.matched) {
if (!expect("assignment", Token::Type::kEqual)) {
return Failure::kErrored;
}
}
auto rhs = logical_or_expression();
if (rhs.errored) {
return Failure::kErrored;
}
if (!rhs.matched) {
return add_error(peek(), "unable to parse right side of assignment");
}
if (compound_op.value != ast::BinaryOp::kNone) {
return create<ast::CompoundAssignmentStatement>(source, lhs.value, rhs.value,
compound_op.value);
} else {
return create<ast::AssignmentStatement>(source, lhs.value, rhs.value);
}
}
// const_literal
// : INT_LITERAL
// | FLOAT_LITERAL
// | TRUE
// | FALSE
Maybe<const ast::LiteralExpression*> ParserImpl::const_literal() {
auto t = peek();
if (match(Token::Type::kIntLiteral)) {
return create<ast::IntLiteralExpression>(t.source(), t.to_i64(),
ast::IntLiteralExpression::Suffix::kNone);
}
if (match(Token::Type::kIntLiteral_I)) {
return create<ast::IntLiteralExpression>(t.source(), t.to_i64(),
ast::IntLiteralExpression::Suffix::kI);
}
if (match(Token::Type::kIntLiteral_U)) {
return create<ast::IntLiteralExpression>(t.source(), t.to_i64(),
ast::IntLiteralExpression::Suffix::kU);
}
if (match(Token::Type::kFloatLiteral)) {
return create<ast::FloatLiteralExpression>(t.source(), t.to_f64(),
ast::FloatLiteralExpression::Suffix::kNone);
}
if (match(Token::Type::kFloatLiteral_F)) {
return create<ast::FloatLiteralExpression>(t.source(), t.to_f64(),
ast::FloatLiteralExpression::Suffix::kF);
}
if (match(Token::Type::kTrue)) {
return create<ast::BoolLiteralExpression>(t.source(), true);
}
if (match(Token::Type::kFalse)) {
return create<ast::BoolLiteralExpression>(t.source(), false);
}
if (handle_error(t)) {
return Failure::kErrored;
}
return Failure::kNoMatch;
}
// const_expr
// : type_decl PAREN_LEFT ((const_expr COMMA)? const_expr COMMA?)? PAREN_RIGHT
// | const_literal
Expect<const ast::Expression*> ParserImpl::expect_const_expr() {
auto t = peek();
auto source = t.source();
if (t.IsLiteral()) {
auto lit = const_literal();
if (lit.errored) {
return Failure::kErrored;
}
if (!lit.matched) {
return add_error(peek(), "unable to parse constant literal");
}
return lit.value;
}
if (peek_is(Token::Type::kParenLeft, 1) || peek_is(Token::Type::kLessThan, 1)) {
auto type = expect_type("const_expr");
if (type.errored) {
return Failure::kErrored;
}
auto params = expect_paren_block("type constructor", [&]() -> Expect<ast::ExpressionList> {
ast::ExpressionList list;
while (continue_parsing()) {
if (peek_is(Token::Type::kParenRight)) {
break;
}
auto arg = expect_const_expr();
if (arg.errored) {
return Failure::kErrored;
}
list.emplace_back(arg.value);
if (!match(Token::Type::kComma)) {
break;
}
}
return list;
});
if (params.errored)
return Failure::kErrored;
return builder_.Construct(source, type.value, params.value);
}
return add_error(peek(), "unable to parse const_expr");
}
Maybe<ast::AttributeList> ParserImpl::attribute_list() {
bool errored = false;
ast::AttributeList attrs;
while (continue_parsing()) {
if (match(Token::Type::kAttr)) {
if (auto attr = expect_attribute(); attr.errored) {
errored = true;
} else {
attrs.emplace_back(attr.value);
}
} else {
break;
}
}
if (errored)
return Failure::kErrored;
if (attrs.empty())
return Failure::kNoMatch;
return attrs;
}
Expect<const ast::Attribute*> ParserImpl::expect_attribute() {
auto t = peek();
auto attr = attribute();
if (attr.errored)
return Failure::kErrored;
if (attr.matched)
return attr.value;
return add_error(t, "expected attribute");
}
Maybe<const ast::Attribute*> ParserImpl::attribute() {
using Result = Maybe<const ast::Attribute*>;
auto t = next();
if (!t.IsIdentifier()) {
return Failure::kNoMatch;
}
if (t == kLocationAttribute) {
const char* use = "location attribute";
return expect_paren_block(use, [&]() -> Result {
auto val = expect_positive_sint(use);
if (val.errored)
return Failure::kErrored;
return create<ast::LocationAttribute>(t.source(), val.value);
});
}
if (t == kBindingAttribute) {
const char* use = "binding attribute";
return expect_paren_block(use, [&]() -> Result {
auto val = expect_positive_sint(use);
if (val.errored)
return Failure::kErrored;
return create<ast::BindingAttribute>(t.source(), val.value);
});
}
if (t == kGroupAttribute) {
const char* use = "group attribute";
return expect_paren_block(use, [&]() -> Result {
auto val = expect_positive_sint(use);
if (val.errored)
return Failure::kErrored;
return create<ast::GroupAttribute>(t.source(), val.value);
});
}
if (t == kInterpolateAttribute) {
return expect_paren_block("interpolate attribute", [&]() -> Result {
ast::InterpolationType type;
ast::InterpolationSampling sampling = ast::InterpolationSampling::kNone;
auto type_tok = next();
if (type_tok == "perspective") {
type = ast::InterpolationType::kPerspective;
} else if (type_tok == "linear") {
type = ast::InterpolationType::kLinear;
} else if (type_tok == "flat") {
type = ast::InterpolationType::kFlat;
} else {
return add_error(type_tok, "invalid interpolation type");
}
if (match(Token::Type::kComma)) {
auto sampling_tok = next();
if (sampling_tok == "center") {
sampling = ast::InterpolationSampling::kCenter;
} else if (sampling_tok == "centroid") {
sampling = ast::InterpolationSampling::kCentroid;
} else if (sampling_tok == "sample") {
sampling = ast::InterpolationSampling::kSample;
} else {
return add_error(sampling_tok, "invalid interpolation sampling");
}
}
return create<ast::InterpolateAttribute>(t.source(), type, sampling);
});
}
if (t == kInvariantAttribute) {
return create<ast::InvariantAttribute>(t.source());
}
if (t == kBuiltinAttribute) {
return expect_paren_block("builtin attribute", [&]() -> Result {
auto builtin = expect_builtin();
if (builtin.errored)
return Failure::kErrored;
return create<ast::BuiltinAttribute>(t.source(), builtin.value);
});
}
if (t == kWorkgroupSizeAttribute) {
return expect_paren_block("workgroup_size attribute", [&]() -> Result {
const ast::Expression* x = nullptr;
const ast::Expression* y = nullptr;
const ast::Expression* z = nullptr;
auto expr = primary_expression();
if (expr.errored) {
return Failure::kErrored;
} else if (!expr.matched) {
return add_error(peek(), "expected workgroup_size x parameter");
}
x = std::move(expr.value);
if (match(Token::Type::kComma)) {
expr = primary_expression();
if (expr.errored) {
return Failure::kErrored;
} else if (!expr.matched) {
return add_error(peek(), "expected workgroup_size y parameter");
}
y = std::move(expr.value);
if (match(Token::Type::kComma)) {
expr = primary_expression();
if (expr.errored) {
return Failure::kErrored;
} else if (!expr.matched) {
return add_error(peek(), "expected workgroup_size z parameter");
}
z = std::move(expr.value);
}
}
return create<ast::WorkgroupAttribute>(t.source(), x, y, z);
});
}
if (t == kStageAttribute) {
return expect_paren_block("stage attribute", [&]() -> Result {
auto stage = expect_pipeline_stage();
if (stage.errored)
return Failure::kErrored;
return create<ast::StageAttribute>(t.source(), stage.value);
});
}
if (t == kSizeAttribute) {
const char* use = "size attribute";
return expect_paren_block(use, [&]() -> Result {
auto val = expect_positive_sint(use);
if (val.errored)
return Failure::kErrored;
return create<ast::StructMemberSizeAttribute>(t.source(), val.value);
});
}
if (t == kAlignAttribute) {
const char* use = "align attribute";
return expect_paren_block(use, [&]() -> Result {
auto val = expect_positive_sint(use);
if (val.errored)
return Failure::kErrored;
return create<ast::StructMemberAlignAttribute>(t.source(), val.value);
});
}
if (t == kIdAttribute) {
const char* use = "id attribute";
return expect_paren_block(use, [&]() -> Result {
auto val = expect_positive_sint(use);
if (val.errored)
return Failure::kErrored;
return create<ast::IdAttribute>(t.source(), val.value);
});
}
return Failure::kNoMatch;
}
bool ParserImpl::expect_attributes_consumed(ast::AttributeList& in) {
if (in.empty()) {
return true;
}
add_error(in[0]->source, "unexpected attributes");
return false;
}
bool ParserImpl::match(Token::Type tok, Source* source /*= nullptr*/) {
auto t = peek();
if (source != nullptr)
*source = t.source();
if (t.Is(tok)) {
next();
return true;
}
return false;
}
bool ParserImpl::expect(std::string_view use, Token::Type tok) {
auto t = peek();
if (t.Is(tok)) {
next();
synchronized_ = true;
return true;
}
// Special case to split `>>` and `>=` tokens if we are looking for a `>`.
if (tok == Token::Type::kGreaterThan &&
(t.Is(Token::Type::kShiftRight) || t.Is(Token::Type::kGreaterThanEqual))) {
next();
// Push the second character to the token queue.
auto source = t.source();
source.range.begin.column++;
if (t.Is(Token::Type::kShiftRight)) {
token_queue_.push_front(Token(Token::Type::kGreaterThan, source));
} else if (t.Is(Token::Type::kGreaterThanEqual)) {
token_queue_.push_front(Token(Token::Type::kEqual, source));
}
synchronized_ = true;
return true;
}
// Error cases
synchronized_ = false;
if (handle_error(t)) {
return false;
}
std::stringstream err;
err << "expected '" << Token::TypeToName(tok) << "'";
if (!use.empty()) {
err << " for " << use;
}
add_error(t, err.str());
return false;
}
Expect<int32_t> ParserImpl::expect_sint(std::string_view use) {
auto t = peek();
if (!t.Is(Token::Type::kIntLiteral) && !t.Is(Token::Type::kIntLiteral_I)) {
return add_error(t.source(), "expected signed integer literal", use);
}
int64_t val = t.to_i64();
if ((val > std::numeric_limits<int32_t>::max()) ||
(val < std::numeric_limits<int32_t>::min())) {
// TODO(crbug.com/tint/1504): Test this when abstract int is implemented
return add_error(t.source(), "value overflows i32", use);
}
next();
return {static_cast<int32_t>(t.to_i64()), t.source()};
}
Expect<uint32_t> ParserImpl::expect_positive_sint(std::string_view use) {
auto sint = expect_sint(use);
if (sint.errored)
return Failure::kErrored;
if (sint.value < 0)
return add_error(sint.source, std::string(use) + " must be positive");
return {static_cast<uint32_t>(sint.value), sint.source};
}
Expect<uint32_t> ParserImpl::expect_nonzero_positive_sint(std::string_view use) {
auto sint = expect_sint(use);
if (sint.errored)
return Failure::kErrored;
if (sint.value <= 0)
return add_error(sint.source, std::string(use) + " must be greater than 0");
return {static_cast<uint32_t>(sint.value), sint.source};
}
Expect<std::string> ParserImpl::expect_ident(std::string_view use) {
auto t = peek();
if (t.IsIdentifier()) {
synchronized_ = true;
next();
if (is_reserved(t)) {
return add_error(t.source(), "'" + t.to_str() + "' is a reserved keyword");
}
return {t.to_str(), t.source()};
}
if (handle_error(t)) {
return Failure::kErrored;
}
synchronized_ = false;
return add_error(t.source(), "expected identifier", use);
}
template <typename F, typename T>
T ParserImpl::expect_block(Token::Type start, Token::Type end, std::string_view use, F&& body) {
if (!expect(use, start)) {
return Failure::kErrored;
}
return sync(end, [&]() -> T {
auto res = body();
if (res.errored)
return Failure::kErrored;
if (!expect(use, end))
return Failure::kErrored;
return res;
});
}
template <typename F, typename T>
T ParserImpl::expect_paren_block(std::string_view use, F&& body) {
return expect_block(Token::Type::kParenLeft, Token::Type::kParenRight, use,
std::forward<F>(body));
}
template <typename F, typename T>
T ParserImpl::expect_brace_block(std::string_view use, F&& body) {
return expect_block(Token::Type::kBraceLeft, Token::Type::kBraceRight, use,
std::forward<F>(body));
}
template <typename F, typename T>
T ParserImpl::expect_lt_gt_block(std::string_view use, F&& body) {
return expect_block(Token::Type::kLessThan, Token::Type::kGreaterThan, use,
std::forward<F>(body));
}
template <typename F, typename T>
T ParserImpl::sync(Token::Type tok, F&& body) {
if (parse_depth_ >= kMaxParseDepth) {
// We've hit a maximum parser recursive depth.
// We can't call into body() as we might stack overflow.
// Instead, report an error...
add_error(peek(), "maximum parser recursive depth reached");
// ...and try to resynchronize. If we cannot resynchronize to `tok` then
// synchronized_ is set to false, and the parser knows that forward progress
// is not being made.
sync_to(tok, /* consume: */ true);
return Failure::kErrored;
}
sync_tokens_.push_back(tok);
++parse_depth_;
auto result = body();
--parse_depth_;
if (sync_tokens_.back() != tok) {
TINT_ICE(Reader, builder_.Diagnostics()) << "sync_tokens is out of sync";
}
sync_tokens_.pop_back();
if (result.errored) {
sync_to(tok, /* consume: */ true);
}
return result;
}
bool ParserImpl::sync_to(Token::Type tok, bool consume) {
// Clear the synchronized state - gets set to true again on success.
synchronized_ = false;
BlockCounters counters;
for (size_t i = 0; i < kMaxResynchronizeLookahead; i++) {
auto t = peek(i);
if (counters.consume(t) > 0) {
continue; // Nested block
}
if (!t.Is(tok) && !is_sync_token(t)) {
continue; // Not a synchronization point
}
// Synchronization point found.
// Skip any tokens we don't understand, bringing us to just before the
// resync point.
while (i-- > 0) {
next();
}
// Is this synchronization token |tok|?
if (t.Is(tok)) {
if (consume) {
next();
}
synchronized_ = true;
return true;
}
break;
}
return false;
}
bool ParserImpl::is_sync_token(const Token& t) const {
for (auto r : sync_tokens_) {
if (t.Is(r)) {
return true;
}
}
return false;
}
bool ParserImpl::handle_error(const Token& t) {
// The token might itself be an error.
if (t.IsError()) {
synchronized_ = false;
add_error(t.source(), t.to_str());
return true;
}
return false;
}
template <typename F, typename T>
T ParserImpl::without_error(F&& body) {
silence_errors_++;
auto result = body();
silence_errors_--;
return result;
}
ParserImpl::MultiTokenSource ParserImpl::make_source_range() {
return MultiTokenSource(this);
}
ParserImpl::MultiTokenSource ParserImpl::make_source_range_from(const Source& start) {
return MultiTokenSource(this, start);
}
} // namespace tint::reader::wgsl