glslang/hlsl/hlslGrammar.cpp
2016-06-04 11:46:33 -06:00

1074 lines
29 KiB
C++
Executable File

//
//Copyright (C) 2016 Google, Inc.
//
//All rights reserved.
//
//Redistribution and use in source and binary forms, with or without
//modification, are permitted provided that the following conditions
//are met:
//
// Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
//
// Redistributions in binary form must reproduce the above
// copyright notice, this list of conditions and the following
// disclaimer in the documentation and/or other materials provided
// with the distribution.
//
// Neither the name of Google, Inc., nor the names of its
// contributors may be used to endorse or promote products derived
// from this software without specific prior written permission.
//
//THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
//"AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
//LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
//FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
//COPYRIGHT HOLDERS OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
//INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
//BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
//LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
//CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
//LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
//ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
//POSSIBILITY OF SUCH DAMAGE.
//
//
// This is a set of mutually recursive methods implementing the HLSL grammar.
// Generally, each returns
// - through an argument: a type specifically appropriate to which rule it
// recognized
// - through the return value: true/false to indicate whether or not it
// recognized its rule
//
// As much as possible, only grammar recognition should happen in this file,
// with all other work being farmed out to hlslParseHelper.cpp, which in turn
// will build the AST.
//
// The next token, yet to be "accepted" is always sitting in 'token'.
// When a method says it accepts a rule, that means all tokens involved
// in the rule will have been consumed, and none left in 'token'.
//
#include "hlslTokens.h"
#include "hlslGrammar.h"
namespace glslang {
// Root entry point to this recursive decent parser.
// Return true if compilation unit was successfully accepted.
bool HlslGrammar::parse()
{
advanceToken();
return acceptCompilationUnit();
}
void HlslGrammar::expected(const char* syntax)
{
parseContext.error(token.loc, "Expected", syntax, "");
}
// Only process the next token if it is an identifier.
// Return true if it was an identifier.
bool HlslGrammar::acceptIdentifier(HlslToken& idToken)
{
if (peekTokenClass(EHTokIdentifier)) {
idToken = token;
advanceToken();
return true;
}
return false;
}
// compilationUnit
// : list of externalDeclaration
//
bool HlslGrammar::acceptCompilationUnit()
{
TIntermNode* unitNode = nullptr;
while (! peekTokenClass(EHTokNone)) {
// externalDeclaration
TIntermNode* declarationNode;
if (! acceptDeclaration(declarationNode))
return false;
// hook it up
unitNode = intermediate.growAggregate(unitNode, declarationNode);
}
// set root of AST
intermediate.setTreeRoot(unitNode);
return true;
}
// declaration
// : SEMICOLON
// : fully_specified_type SEMICOLON
// | fully_specified_type identifier SEMICOLON
// | fully_specified_type identifier = expression SEMICOLON
// | fully_specified_type identifier function_parameters SEMICOLON // function prototype
// | fully_specified_type identifier function_parameters COLON semantic compound_statement // function definition
//
// 'node' could get created if the declaration creates code, like an initializer
// or a function body.
//
bool HlslGrammar::acceptDeclaration(TIntermNode*& node)
{
node = nullptr;
// fully_specified_type
TType type;
if (! acceptFullySpecifiedType(type))
return false;
// identifier
HlslToken idToken;
if (acceptIdentifier(idToken)) {
// = expression
TIntermTyped* expressionNode = nullptr;
if (acceptTokenClass(EHTokAssign)) {
if (! acceptExpression(expressionNode)) {
expected("initializer");
return false;
}
}
// SEMICOLON
if (acceptTokenClass(EHTokSemicolon)) {
node = parseContext.declareVariable(idToken.loc, *idToken.string, type, 0, expressionNode);
return true;
}
// function_parameters
TFunction* function = new TFunction(idToken.string, type);
if (acceptFunctionParameters(*function)) {
// COLON semantic
acceptSemantic();
// compound_statement
if (peekTokenClass(EHTokLeftBrace))
return acceptFunctionDefinition(*function, node);
// SEMICOLON
if (acceptTokenClass(EHTokSemicolon))
return true;
return false;
}
}
// SEMICOLON
if (acceptTokenClass(EHTokSemicolon))
return true;
return true;
}
// fully_specified_type
// : type_specifier
// | type_qualifier type_specifier
//
bool HlslGrammar::acceptFullySpecifiedType(TType& type)
{
// type_qualifier
TQualifier qualifier;
qualifier.clear();
acceptQualifier(qualifier);
// type_specifier
if (! acceptType(type))
return false;
type.getQualifier() = qualifier;
return true;
}
// If token is a qualifier, return its token class and advance to the next
// qualifier. Otherwise, return false, and don't advance.
void HlslGrammar::acceptQualifier(TQualifier& qualifier)
{
switch (peek()) {
case EHTokUniform:
qualifier.storage = EvqUniform;
break;
case EHTokConst:
qualifier.storage = EvqConst;
break;
default:
return;
}
advanceToken();
}
// If token is for a type, update 'type' with the type information,
// and return true and advance.
// Otherwise, return false, and don't advance
bool HlslGrammar::acceptType(TType& type)
{
if (! token.isType)
return false;
switch (peek()) {
case EHTokInt:
case EHTokInt1:
case EHTokDword:
new(&type) TType(EbtInt);
break;
case EHTokFloat:
new(&type) TType(EbtFloat);
break;
case EHTokFloat1:
new(&type) TType(EbtFloat);
type.makeVector();
break;
case EHTokFloat2:
new(&type) TType(EbtFloat, EvqTemporary, 2);
break;
case EHTokFloat3:
new(&type) TType(EbtFloat, EvqTemporary, 3);
break;
case EHTokFloat4:
new(&type) TType(EbtFloat, EvqTemporary, 4);
break;
case EHTokInt2:
new(&type) TType(EbtInt, EvqTemporary, 2);
break;
case EHTokInt3:
new(&type) TType(EbtInt, EvqTemporary, 3);
break;
case EHTokInt4:
new(&type) TType(EbtInt, EvqTemporary, 4);
break;
case EHTokBool2:
new(&type) TType(EbtBool, EvqTemporary, 2);
break;
case EHTokBool3:
new(&type) TType(EbtBool, EvqTemporary, 3);
break;
case EHTokBool4:
new(&type) TType(EbtBool, EvqTemporary, 4);
break;
case EHTokInt1x1:
new(&type) TType(EbtInt, EvqTemporary, 0, 1, 1);
break;
case EHTokInt1x2:
new(&type) TType(EbtInt, EvqTemporary, 0, 2, 1);
break;
case EHTokInt1x3:
new(&type) TType(EbtInt, EvqTemporary, 0, 3, 1);
break;
case EHTokInt1x4:
new(&type) TType(EbtInt, EvqTemporary, 0, 4, 1);
break;
case EHTokInt2x1:
new(&type) TType(EbtInt, EvqTemporary, 0, 1, 2);
break;
case EHTokInt2x2:
new(&type) TType(EbtInt, EvqTemporary, 0, 2, 2);
break;
case EHTokInt2x3:
new(&type) TType(EbtInt, EvqTemporary, 0, 3, 2);
break;
case EHTokInt2x4:
new(&type) TType(EbtInt, EvqTemporary, 0, 4, 2);
break;
case EHTokInt3x1:
new(&type) TType(EbtInt, EvqTemporary, 0, 1, 3);
break;
case EHTokInt3x2:
new(&type) TType(EbtInt, EvqTemporary, 0, 2, 3);
break;
case EHTokInt3x3:
new(&type) TType(EbtInt, EvqTemporary, 0, 3, 3);
break;
case EHTokInt3x4:
new(&type) TType(EbtInt, EvqTemporary, 0, 4, 3);
break;
case EHTokInt4x1:
new(&type) TType(EbtInt, EvqTemporary, 0, 1, 4);
break;
case EHTokInt4x2:
new(&type) TType(EbtInt, EvqTemporary, 0, 2, 4);
break;
case EHTokInt4x3:
new(&type) TType(EbtInt, EvqTemporary, 0, 3, 4);
break;
case EHTokInt4x4:
new(&type) TType(EbtInt, EvqTemporary, 0, 4, 4);
break;
case EHTokFloat1x1:
new(&type) TType(EbtFloat, EvqTemporary, 0, 1, 1);
break;
case EHTokFloat1x2:
new(&type) TType(EbtFloat, EvqTemporary, 0, 2, 1);
break;
case EHTokFloat1x3:
new(&type) TType(EbtFloat, EvqTemporary, 0, 3, 1);
break;
case EHTokFloat1x4:
new(&type) TType(EbtFloat, EvqTemporary, 0, 4, 1);
break;
case EHTokFloat2x1:
new(&type) TType(EbtFloat, EvqTemporary, 0, 1, 2);
break;
case EHTokFloat2x2:
new(&type) TType(EbtFloat, EvqTemporary, 0, 2, 2);
break;
case EHTokFloat2x3:
new(&type) TType(EbtFloat, EvqTemporary, 0, 3, 2);
break;
case EHTokFloat2x4:
new(&type) TType(EbtFloat, EvqTemporary, 0, 4, 2);
break;
case EHTokFloat3x1:
new(&type) TType(EbtFloat, EvqTemporary, 0, 1, 3);
break;
case EHTokFloat3x2:
new(&type) TType(EbtFloat, EvqTemporary, 0, 2, 3);
break;
case EHTokFloat3x3:
new(&type) TType(EbtFloat, EvqTemporary, 0, 3, 3);
break;
case EHTokFloat3x4:
new(&type) TType(EbtFloat, EvqTemporary, 0, 4, 3);
break;
case EHTokFloat4x1:
new(&type) TType(EbtFloat, EvqTemporary, 0, 1, 4);
break;
case EHTokFloat4x2:
new(&type) TType(EbtFloat, EvqTemporary, 0, 2, 4);
break;
case EHTokFloat4x3:
new(&type) TType(EbtFloat, EvqTemporary, 0, 3, 4);
break;
case EHTokFloat4x4:
new(&type) TType(EbtFloat, EvqTemporary, 0, 4, 4);
break;
case EHTokDouble1x1:
new(&type) TType(EbtDouble, EvqTemporary, 0, 1, 1);
break;
case EHTokDouble1x2:
new(&type) TType(EbtDouble, EvqTemporary, 0, 2, 1);
break;
case EHTokDouble1x3:
new(&type) TType(EbtDouble, EvqTemporary, 0, 3, 1);
break;
case EHTokDouble1x4:
new(&type) TType(EbtDouble, EvqTemporary, 0, 4, 1);
break;
case EHTokDouble2x1:
new(&type) TType(EbtDouble, EvqTemporary, 0, 1, 2);
break;
case EHTokDouble2x2:
new(&type) TType(EbtDouble, EvqTemporary, 0, 2, 2);
break;
case EHTokDouble2x3:
new(&type) TType(EbtDouble, EvqTemporary, 0, 3, 2);
break;
case EHTokDouble2x4:
new(&type) TType(EbtDouble, EvqTemporary, 0, 4, 2);
break;
case EHTokDouble3x1:
new(&type) TType(EbtDouble, EvqTemporary, 0, 1, 3);
break;
case EHTokDouble3x2:
new(&type) TType(EbtDouble, EvqTemporary, 0, 2, 3);
break;
case EHTokDouble3x3:
new(&type) TType(EbtDouble, EvqTemporary, 0, 3, 3);
break;
case EHTokDouble3x4:
new(&type) TType(EbtDouble, EvqTemporary, 0, 4, 3);
break;
case EHTokDouble4x1:
new(&type) TType(EbtDouble, EvqTemporary, 0, 1, 4);
break;
case EHTokDouble4x2:
new(&type) TType(EbtDouble, EvqTemporary, 0, 2, 4);
break;
case EHTokDouble4x3:
new(&type) TType(EbtDouble, EvqTemporary, 0, 3, 4);
break;
case EHTokDouble4x4:
new(&type) TType(EbtDouble, EvqTemporary, 0, 4, 4);
break;
default:
return false;
}
advanceToken();
return true;
}
// function_parameters
// : LEFT_PAREN parameter_declaration COMMA parameter_declaration ... RIGHT_PAREN
//
bool HlslGrammar::acceptFunctionParameters(TFunction& function)
{
// LEFT_PAREN
if (! acceptTokenClass(EHTokLeftParen))
return false;
do {
// parameter_declaration
if (! acceptParameterDeclaration(function))
break;
// COMMA
if (! acceptTokenClass(EHTokComma))
break;
} while (true);
// RIGHT_PAREN
if (! acceptTokenClass(EHTokRightParen)) {
expected("right parenthesis");
return false;
}
return true;
}
// parameter_declaration
// : fully_specified_type
// | fully_specified_type identifier
//
bool HlslGrammar::acceptParameterDeclaration(TFunction& function)
{
// fully_specified_type
TType* type = new TType;
if (! acceptFullySpecifiedType(*type))
return false;
// identifier
HlslToken idToken;
acceptIdentifier(idToken);
TParameter param = { idToken.string, type };
function.addParameter(param);
return true;
}
// Do the work to create the function definition in addition to
// parsing the body (compound_statement).
bool HlslGrammar::acceptFunctionDefinition(TFunction& function, TIntermNode*& node)
{
TFunction* functionDeclarator = parseContext.handleFunctionDeclarator(token.loc, function, false /* not prototype */);
// This does a symbol table push
node = parseContext.handleFunctionDefinition(token.loc, *functionDeclarator);
// compound_statement
TIntermNode* functionBody = nullptr;
if (acceptCompoundStatement(functionBody)) {
node = intermediate.growAggregate(node, functionBody);
intermediate.setAggregateOperator(node, EOpFunction, functionDeclarator->getType(), token.loc);
node->getAsAggregate()->setName(functionDeclarator->getMangledName().c_str());
parseContext.symbolTable.pop(nullptr);
return true;
}
return false;
}
// The top-level full expression recognizer.
//
// expression
// : assignment_expression COMMA assignment_expression COMMA assignment_expression ...
//
bool HlslGrammar::acceptExpression(TIntermTyped*& node)
{
node = nullptr;
// assignment_expression
if (! acceptAssignmentExpression(node))
return false;
if (! peekTokenClass(EHTokComma))
return true;
do {
// ... COMMA
TSourceLoc loc = token.loc;
advanceToken();
// ... assignment_expression
TIntermTyped* rightNode = nullptr;
if (! acceptAssignmentExpression(rightNode)) {
expected("assignment expression");
return false;
}
node = intermediate.addComma(node, rightNode, loc);
if (! peekTokenClass(EHTokComma))
return true;
} while (true);
}
// Accept an assignment expression, where assignment operations
// associate right-to-left. This is, it is implicit, for example
//
// a op (b op (c op d))
//
// assigment_expression
// : binary_expression op binary_expression op binary_expression ...
//
bool HlslGrammar::acceptAssignmentExpression(TIntermTyped*& node)
{
if (! acceptBinaryExpression(node, PlLogicalOr))
return false;
TOperator assignOp = HlslOpMap::assignment(peek());
if (assignOp == EOpNull)
return true;
// ... op
TSourceLoc loc = token.loc;
advanceToken();
// ... binary_expression
// But, done by recursing this function, which automatically
// gets the right-to-left associativity.
TIntermTyped* rightNode = nullptr;
if (! acceptAssignmentExpression(rightNode)) {
expected("assignment expression");
return false;
}
node = intermediate.addAssign(assignOp, node, rightNode, loc);
if (! peekTokenClass(EHTokComma))
return true;
return true;
}
// Accept a binary expression, for binary operations that
// associate left-to-right. This is, it is implicit, for example
//
// ((a op b) op c) op d
//
// binary_expression
// : expression op expression op expression ...
//
// where 'expression' is the next higher level in precedence.
//
bool HlslGrammar::acceptBinaryExpression(TIntermTyped*& node, PrecedenceLevel precedenceLevel)
{
if (precedenceLevel > PlMul)
return acceptUnaryExpression(node);
// assignment_expression
if (! acceptBinaryExpression(node, (PrecedenceLevel)(precedenceLevel + 1)))
return false;
TOperator op = HlslOpMap::binary(peek());
PrecedenceLevel tokenLevel = HlslOpMap::precedenceLevel(op);
if (tokenLevel < precedenceLevel)
return true;
do {
// ... op
TSourceLoc loc = token.loc;
advanceToken();
// ... expression
TIntermTyped* rightNode = nullptr;
if (! acceptBinaryExpression(rightNode, (PrecedenceLevel)(precedenceLevel + 1))) {
expected("expression");
return false;
}
node = intermediate.addBinaryMath(op, node, rightNode, loc);
if (! peekTokenClass(EHTokComma))
return true;
} while (true);
}
// unary_expression
// : (type) unary_expression
// | + unary_expression
// | - unary_expression
// | ! unary_expression
// | ~ unary_expression
// | ++ unary_expression
// | -- unary_expression
// | postfix_expression
//
bool HlslGrammar::acceptUnaryExpression(TIntermTyped*& node)
{
// (type) unary_expression
// Have to look two steps ahead, because this could be, e.g., a
// postfix_expression instead, since that also starts with at "(".
if (acceptTokenClass(EHTokLeftParen)) {
TType castType;
if (acceptType(castType)) {
if (! acceptTokenClass(EHTokRightParen)) {
expected("right parenthesis");
return false;
}
// We've matched "(type)" now, get the expression to cast
TSourceLoc loc = token.loc;
if (! acceptUnaryExpression(node))
return false;
// Hook it up like a constructor
TFunction* constructorFunction = parseContext.handleConstructorCall(loc, castType);
if (constructorFunction == nullptr) {
expected("type that can be constructed");
return false;
}
TIntermTyped* arguments = nullptr;
parseContext.handleFunctionArgument(constructorFunction, arguments, node);
node = parseContext.handleFunctionCall(loc, constructorFunction, arguments);
return true;
} else {
// This isn't a type cast, but it still started "(", so if it is a
// unary expression, it can only be a postfix_expression, so try that.
// Back it up first.
recedeToken();
return acceptPostfixExpression(node);
}
}
// peek for "op unary_expression"
TOperator unaryOp = HlslOpMap::preUnary(peek());
// postfix_expression (if no unary operator)
if (unaryOp == EOpNull)
return acceptPostfixExpression(node);
// op unary_expression
TSourceLoc loc = token.loc;
advanceToken();
if (! acceptUnaryExpression(node))
return false;
// + is a no-op
if (unaryOp == EOpAdd)
return true;
node = intermediate.addUnaryMath(unaryOp, node, loc);
return node != nullptr;
}
// postfix_expression
// : LEFT_PAREN expression RIGHT_PAREN
// | literal
// | constructor
// | identifier
// | function_call
// | postfix_expression LEFT_BRACKET integer_expression RIGHT_BRACKET
// | postfix_expression DOT IDENTIFIER
// | postfix_expression INC_OP
// | postfix_expression DEC_OP
//
bool HlslGrammar::acceptPostfixExpression(TIntermTyped*& node)
{
// Not implemented as self-recursive:
// The logical "right recursion" is done with an loop at the end
// idToken will pick up either a variable or a function name in a function call
HlslToken idToken;
// Find something before the postfix operations, as they can't operate
// on nothing. So, no "return true", they fall through, only "return false".
if (acceptTokenClass(EHTokLeftParen)) {
// LEFT_PAREN expression RIGHT_PAREN
if (! acceptExpression(node)) {
expected("expression");
return false;
}
if (! acceptTokenClass(EHTokRightParen)) {
expected("right parenthesis");
return false;
}
} else if (acceptLiteral(node)) {
// literal (nothing else to do yet), go on to the
} else if (acceptConstructor(node)) {
// constructor (nothing else to do yet)
} else if (acceptIdentifier(idToken)) {
// identifier or function_call name
if (! peekTokenClass(EHTokLeftParen)) {
node = parseContext.handleVariable(idToken.loc, idToken.symbol, token.string);
} else if (acceptFunctionCall(idToken, node)) {
// function_call (nothing else to do yet)
} else {
expected("function call arguments");
return false;
}
} else {
// nothing found, can't post operate
return false;
}
// Something was found, chain as many postfix operations as exist.
do {
TSourceLoc loc = token.loc;
TOperator postOp = HlslOpMap::postUnary(peek());
// Consume only a valid post-unary operator, otherwise we are done.
switch (postOp) {
case EOpIndexDirectStruct:
case EOpIndexIndirect:
case EOpPostIncrement:
case EOpPostDecrement:
advanceToken();
break;
default:
return true;
}
// We have a valid post-unary operator, process it.
switch (postOp) {
case EOpIndexDirectStruct:
// todo
break;
case EOpIndexIndirect:
{
TIntermTyped* indexNode = nullptr;
if (! acceptExpression(indexNode) ||
! peekTokenClass(EHTokRightBracket)) {
expected("expression followed by ']'");
return false;
}
// todo: node = intermediate.addBinaryMath(
}
case EOpPostIncrement:
case EOpPostDecrement:
node = intermediate.addUnaryMath(postOp, node, loc);
break;
default:
assert(0);
break;
}
} while (true);
}
// constructor
// : type argument_list
//
bool HlslGrammar::acceptConstructor(TIntermTyped*& node)
{
// type
TType type;
if (acceptType(type)) {
TFunction* constructorFunction = parseContext.handleConstructorCall(token.loc, type);
if (constructorFunction == nullptr)
return false;
// arguments
TIntermTyped* arguments = nullptr;
if (! acceptArguments(constructorFunction, arguments)) {
expected("constructor arguments");
return false;
}
// hook it up
node = parseContext.handleFunctionCall(arguments->getLoc(), constructorFunction, arguments);
return true;
}
return false;
}
// The function_call identifier was already recognized, and passed in as idToken.
//
// function_call
// : [idToken] arguments
//
bool HlslGrammar::acceptFunctionCall(HlslToken idToken, TIntermTyped*& node)
{
// arguments
TFunction* function = new TFunction(idToken.string, TType(EbtVoid));
TIntermTyped* arguments = nullptr;
if (! acceptArguments(function, arguments))
return false;
node = parseContext.handleFunctionCall(idToken.loc, function, arguments);
return true;
}
// arguments
// : LEFT_PAREN expression COMMA expression COMMA ... RIGHT_PAREN
//
// The arguments are pushed onto the 'function' argument list and
// onto the 'arguments' aggregate.
//
bool HlslGrammar::acceptArguments(TFunction* function, TIntermTyped*& arguments)
{
// LEFT_PAREN
if (! acceptTokenClass(EHTokLeftParen))
return false;
do {
// expression
TIntermTyped* arg;
if (! acceptAssignmentExpression(arg))
break;
// hook it up
parseContext.handleFunctionArgument(function, arguments, arg);
// COMMA
if (! acceptTokenClass(EHTokComma))
break;
} while (true);
// RIGHT_PAREN
if (! acceptTokenClass(EHTokRightParen)) {
expected("right parenthesis");
return false;
}
return true;
}
bool HlslGrammar::acceptLiteral(TIntermTyped*& node)
{
switch (token.tokenClass) {
case EHTokIntConstant:
node = intermediate.addConstantUnion(token.i, token.loc, true);
break;
case EHTokFloatConstant:
node = intermediate.addConstantUnion(token.d, EbtFloat, token.loc, true);
break;
case EHTokDoubleConstant:
node = intermediate.addConstantUnion(token.d, EbtDouble, token.loc, true);
break;
case EHTokBoolConstant:
node = intermediate.addConstantUnion(token.b, token.loc, true);
break;
default:
return false;
}
advanceToken();
return true;
}
// compound_statement
// : LEFT_CURLY statement statement ... RIGHT_CURLY
//
bool HlslGrammar::acceptCompoundStatement(TIntermNode*& retStatement)
{
TIntermAggregate* compoundStatement = nullptr;
// LEFT_CURLY
if (! acceptTokenClass(EHTokLeftBrace))
return false;
// statement statement ...
TIntermNode* statement = nullptr;
while (acceptStatement(statement)) {
// hook it up
compoundStatement = intermediate.growAggregate(compoundStatement, statement);
}
if (compoundStatement)
compoundStatement->setOperator(EOpSequence);
retStatement = compoundStatement;
// RIGHT_CURLY
return acceptTokenClass(EHTokRightBrace);
}
// statement
// : attributes attributed_statement
//
// attributed_statement
// : compound_statement
// | SEMICOLON
// | expression SEMICOLON
// | declaration_statement
// | selection_statement
// | switch_statement
// | case_label
// | iteration_statement
// | jump_statement
//
bool HlslGrammar::acceptStatement(TIntermNode*& statement)
{
statement = nullptr;
// attributes
acceptAttributes();
// attributed_statement
switch (peek()) {
case EHTokLeftBrace:
return acceptCompoundStatement(statement);
case EHTokIf:
return acceptSelectionStatement(statement);
case EHTokSwitch:
return acceptSwitchStatement(statement);
case EHTokFor:
case EHTokDo:
case EHTokWhile:
return acceptIterationStatement(statement);
case EHTokContinue:
case EHTokBreak:
case EHTokDiscard:
case EHTokReturn:
return acceptJumpStatement(statement);
case EHTokCase:
return acceptCaseLabel(statement);
case EHTokSemicolon:
return acceptTokenClass(EHTokSemicolon);
case EHTokRightBrace:
// Performance: not strictly necessary, but stops a bunch of hunting early,
// and is how sequences of statements end.
return false;
default:
{
// declaration
if (acceptDeclaration(statement))
return true;
// expression
TIntermTyped* node;
if (acceptExpression(node))
statement = node;
else
return false;
// SEMICOLON (following an expression)
if (! acceptTokenClass(EHTokSemicolon)) {
expected("semicolon");
return false;
}
}
}
return true;
}
// attributes
// : list of zero or more of: LEFT_BRACKET attribute RIGHT_BRACKET
//
// attribute:
// : UNROLL
// | UNROLL LEFT_PAREN literal RIGHT_PAREN
// | FASTOPT
// | ALLOW_UAV_CONDITION
// | BRANCH
// | FLATTEN
// | FORCECASE
// | CALL
//
void HlslGrammar::acceptAttributes()
{
// TODO
}
bool HlslGrammar::acceptSelectionStatement(TIntermNode*& statement)
{
return false;
}
bool HlslGrammar::acceptSwitchStatement(TIntermNode*& statement)
{
return false;
}
bool HlslGrammar::acceptIterationStatement(TIntermNode*& statement)
{
return false;
}
// jump_statement
// : CONTINUE SEMICOLON
// | BREAK SEMICOLON
// | DISCARD SEMICOLON
// | RETURN SEMICOLON
// | RETURN expression SEMICOLON
//
bool HlslGrammar::acceptJumpStatement(TIntermNode*& statement)
{
switch (peek()) {
case EHTokContinue:
case EHTokBreak:
case EHTokDiscard:
// TODO
return false;
case EHTokReturn:
// return
if (acceptTokenClass(EHTokReturn)) {
// expression
TIntermTyped* node;
if (acceptExpression(node)) {
// hook it up
statement = intermediate.addBranch(EOpReturn, node, token.loc);
} else
statement = intermediate.addBranch(EOpReturn, token.loc);
// SEMICOLON
if (! acceptTokenClass(EHTokSemicolon)) {
expected("semicolon");
return false;
}
return true;
}
default:
return false;
}
}
bool HlslGrammar::acceptCaseLabel(TIntermNode*& statement)
{
return false;
}
// COLON semantic
bool HlslGrammar::acceptSemantic()
{
// COLON
if (acceptTokenClass(EHTokColon)) {
// semantic
HlslToken idToken;
if (! acceptIdentifier(idToken)) {
expected("semantic");
return false;
}
}
return true;
}
} // end namespace glslang