protected Expression Visit(BinaryExpression expression)
{
// First, dispatch to resolve type of node at deeper level
Visit((Node)expression);
var leftType = expression.Left.TypeInference.TargetType;
var rightType = expression.Right.TypeInference.TargetType;
var returnType = expression.TypeInference.ExpectedType ?? expression.TypeInference.TargetType;
bool isNumericOperator = true;
switch (expression.Operator)
{
case BinaryOperator.LogicalAnd:
case BinaryOperator.LogicalOr:
isNumericOperator = false;
returnType = GetBinaryImplicitConversionType(expression.Span, leftType, rightType, true);
expression.TypeInference.TargetType = returnType;
break;
case BinaryOperator.Less:
case BinaryOperator.LessEqual:
case BinaryOperator.Greater:
case BinaryOperator.GreaterEqual:
case BinaryOperator.Equality:
case BinaryOperator.Inequality:
isNumericOperator = false;
returnType = GetBinaryImplicitConversionType(expression.Span, leftType, rightType, false);
TypeBase resultType = ScalarType.Bool;
if (returnType is VectorType)
{
resultType = new VectorType(ScalarType.Bool, ((VectorType)returnType).Dimension);
}
else if (returnType is MatrixType)
{
var matrixType = (MatrixType)returnType;
resultType = new MatrixType(ScalarType.Bool, matrixType.RowCount, matrixType.ColumnCount);
}
expression.TypeInference.TargetType = resultType;
break;
}
if (returnType != null)
{
if (returnType == ScalarType.Bool && isNumericOperator)
{
var typeToCheck = leftType ?? rightType;
if (typeToCheck != null)
return ConvertExpressionToBool(expression, typeToCheck);
}
}
if (!isNumericOperator || CastHelper.NeedConvertForBinary(leftType, returnType))
expression.Left = Cast(leftType, returnType, expression.Left);
if (!isNumericOperator || CastHelper.NeedConvertForBinary(rightType, returnType))
expression.Right = Cast(rightType, returnType, expression.Right);
return expression;
}
/// <summary>
/// Visits the specified type.
/// </summary>
/// <param name="type">the type.</param>
public override void Visit(VectorType type)
{
var finalTypeName = "Vector" + type.Dimension;
if (IsColorStatus)
{
if (type.Dimension == 3)
finalTypeName = "Color3";
else if (type.Dimension == 4)
finalTypeName = "Color4";
else
throw new NotSupportedException("Color attribute is only valid for float3/float4.");
}
Write(finalTypeName);
ProcessInitialValueStatus = true;
}
/// <inheritdoc/>
public bool Equals(VectorType other)
{
return base.Equals(other);
}
/// <summary>
/// Initializes a new instance of the <see cref="HlslGrammar"/> class.
/// </summary>
public HlslGrammar()
{
GrammarComments = "Hlsl version 5.0";
Term(string_literal_raw, TokenCategory.String, TokenType.StringLiteral);
Punc("::", TokenType.IdentifierSeparator);
// ------------------------------------------------------------------------------------
// Comments
// ------------------------------------------------------------------------------------
identifier_ns_list.Rule = MakePlusRule(identifier_ns_list, ToTerm("::"), identifier_raw);
identifier_dot_list.Rule = MakePlusRule(identifier_dot_list, ToTerm("."), identifier_raw);
identifier_ns.Rule = identifier_raw + "::" + identifier_ns_list;
identifier_dot.Rule = identifier_or_generic + ToTerm(".") + identifier_dot_list;
identifier_or_dot.Rule = identifier | identifier_dot;
identifier.Rule |= identifier_ns;
semi_opt.Rule = Empty | PreferShiftHere() + ";";
//Prepare term set for conflict resolution
_skipTokensInPreview.UnionWith(new[] { ToTerm("."), identifier_raw, ToTerm(","), ToTerm("::"), ToTerm("["), ToTerm("]"), float_literal, integer_literal });
var genericResolverHint = new GenericResolverHint(_skipTokensInPreview);
less_than.Rule = genericResolverHint + "<";
// ------------------------------------------------------------------------------------
// Types
// ------------------------------------------------------------------------------------
// String
string_literal.Rule = string_literal_raw.List();
string_literal_raw.AstNodeCreator = CreateStringRawLiteral;
// Add string to literals
literal.Rule |= string_literal;
float_qualifier.Rule = Keyword("unorm") | Keyword("snorm");
// scalars
var scalarTypes = new[] { ScalarType.Bool, ScalarType.Int, ScalarType.UInt, ScalarType.Float, ScalarType.Half, ScalarType.Double };
foreach (var scalarType in scalarTypes)
{
NonTerminal scalarTerm;
var localScalarType = scalarType;
if (scalarType == ScalarType.Float)
{
scalarTerm = new NonTerminal(
"float",
(context, node) =>
{
var dynamicFloatType = Ast<ScalarType>(node);
dynamicFloatType.Name = new Identifier(localScalarType.Name) { Span = SpanConverter.Convert(node.Span) };
dynamicFloatType.Type = localScalarType.Type;
dynamicFloatType.Qualifiers = Qualifier.None;
if (node.ChildNodes.Count == 2)
{
dynamicFloatType.Qualifiers = (Qualifier)node.ChildNodes[0].AstNode;
}
})
{
Rule = Keyword("float", true) | float_qualifier + Keyword("float", true)
};
}
else
{
scalarTerm = CreateScalarTerminal(scalarType);
}
if (scalars.Rule == null) scalars.Rule = scalarTerm;
else scalars.Rule |= scalarTerm;
}
// Buffer Rules
buffer_type.Rule = TypeName("Buffer") + less_than + simple_type_or_type_name + ">";
// Vectors Rules
vector_type.AstNodeCreator = CreateVectorAst;
vector_type.Rule = Keyword("vector") + less_than + scalars_or_typename + "," + number + ">";
vector_type_list.Rule = vector_type;
// Add all vector int1 int2 int3 int4... float1 float2 float3 float4... etc.
foreach (var scalarTypeIt in scalarTypes)
{
var scalarType = scalarTypeIt;
for (var dim = 1; dim <= 4; dim++)
{
var vectorTypeInstance = new VectorType(scalarTypeIt, dim);
var nonGenericType = vectorTypeInstance.ToNonGenericType();
var name = nonGenericType.Name.Text;
vector_type_list.Rule |= new NonTerminal(name,
(ctx, node) =>
{
var typeName = vectorTypeInstance.ToNonGenericType(SpanConverter.Convert(node.Span));
node.AstNode = typeName;
}) { Rule = Keyword(name) };
}
}
// Matrices
matrix_type_simple.Rule = Keyword("matrix");
matrix_type_simple.AstNodeCreator = (ctx, node) =>
{
var typeName = Ast<TypeName>(node);
typeName.Name = new Identifier("matrix") { Span = SpanConverter.Convert(node.Span) };
typeName.TypeInference.TargetType = new MatrixType(ScalarType.Float, 4, 4);
};
matrix_type.Rule = Keyword("matrix") + less_than + scalars_or_typename + "," + number + "," + number + ">";
matrix_type.AstNodeCreator = CreateMatrixAst;
matrix_type_list.Rule = matrix_type | matrix_type_simple;
// Add all matrix typedefs: int1x1 int1x2... float1x1 float1x2 float1x3 float1x4... etc.
foreach (var scalarTypeIt in scalarTypes)
{
var scalarType = scalarTypeIt;
for (var dimX = 1; dimX <= 4; dimX++)
for (var dimY = 1; dimY <= 4; dimY++)
{
var matrixTypeInstance = new MatrixType(scalarTypeIt, dimY, dimX);
var nonGenericType = matrixTypeInstance.ToNonGenericType();
var name = nonGenericType.Name.Text;
// var typeName = new TypeName(name) { Alias = matrixTypeInstance };
matrix_type_list.Rule |= new NonTerminal(
name,
(ctx, node) =>
{
var typeName = matrixTypeInstance.ToNonGenericType(SpanConverter.Convert(node.Span));
node.AstNode = typeName;
}) { Rule = Keyword(name) };
}
}
// Sampler types
state_type.Rule = CreateRuleFromObjectTypes(
StateType.BlendState,
StateType.DepthStencilState,
StateType.RasterizerState,
SamplerStateType.SamplerState,
SamplerStateType.SamplerStateOld,
SamplerStateType.SamplerComparisonState);
sampler_type.Rule = CreateRuleFromObjectTypes(
SamplerType.Sampler,
SamplerType.Sampler1D,
SamplerType.Sampler2D,
SamplerType.Sampler3D,
SamplerType.SamplerCube);
sampler_type.AstNodeCreator = CreateTypeFromTokenAst<SamplerType>;
// Texture types
texture_type_profile_4.Rule = CreateRuleFromObjectTypes(
TextureType.Texture1D,
TextureType.Texture1DArray,
TextureType.Texture2D,
TextureType.Texture2DArray,
TextureType.Texture3D,
TextureType.TextureCube);
texture_type.Rule = Keyword("texture") | texture_type_profile_4;
// ByteAddressBuffer
byte_address_buffer.Rule = TypeName("ByteAddressBuffer") | TypeName("RWByteAddressBuffer");
// StructuredBuffer
structured_buffer_type.Rule = TypeName("AppendStructuredBuffer") | TypeName("ConsumeStructuredBuffer") | TypeName("RWStructuredBuffer") | TypeName("StructuredBuffer");
structured_buffer.Rule = structured_buffer_type + less_than + scalars_and_vectors + ">";
// RWTexture.*
texture_type_profile_5.Rule = TypeName("RWBuffer") | TypeName("RWTexture1D") | TypeName("RWTexture1DArray") | TypeName("RWTexture2D") | TypeName("RWTexture2DArray") | TypeName("RWTexture3D");
texture_generic_simple_type.Rule = texture_type_profile_4 + less_than + scalars_and_vectors + ">"
| texture_type_profile_5 + less_than + scalars_and_vectors + ">";
texture_dms_type_profile_5.Rule = TypeName("Texture2DMS") | TypeName("Texture2DMSArray");
texture_generic_dms_type.Rule = texture_dms_type_profile_5 + less_than + scalars_and_vectors + ">"
| texture_dms_type_profile_5 + less_than + scalars_and_vectors + "," + number + ">";
texture_generic_type.Rule = texture_generic_simple_type | texture_generic_dms_type;
// HullShader/DomainShader InputPatch/OutputPatch
patch_type.Rule = TypeName("InputPatch") | TypeName("OutputPatch");
patch_generic_type.Rule = patch_type + less_than + type + "," + number + ">";
texture_type_list.Rule = texture_type | texture_generic_type;
// Types used by the geometry shader
geometry_stream.Rule = line_stream | point_stream | triangle_stream | stream_output_object;
triangle_stream.Rule = TypeName("TriangleStream") + less_than + type + ">";
point_stream.Rule = TypeName("PointStream") + less_than + type + ">";
line_stream.Rule = TypeName("LineStream") + less_than + type + ">";
stream_output_object.Rule = TypeName("StreamOutputObject") + less_than + type + ">";
//// Shader object
//// shader_objects.Rule = ToTerm("VertexShader") | "PixelShader" | "GeometryShader";
string_type.Rule = Keyword("string");
// Add string to simple types
simple_type.Rule |= string_type;
// Add Object types
object_type.Rule |= buffer_type
| state_type
| texture_type_list
| byte_address_buffer
| structured_buffer
| patch_generic_type
| interface_specifier
| class_specifier
| geometry_stream;
////| shader_objects;
// Type name
typename_for_cast.Rule = identifier + new IdentifierResolverHint(true);
identifier_generic_parameter_list.Rule = MakePlusRule(identifier_generic_parameter_list, ToTerm(","), identifier_sub_generic);
identifier_sub_generic.Rule = identifier_or_generic;
identifier_sub_generic.AstNodeCreator = CreateIdentifierSubGenericAst;
//identifier_generic.Rule = identifier + new IdentifierResolverHint(true) + "<" + identifier_generic_parameter_list + ">";
identifier_generic.Rule = identifier + new GenericResolverHint(_skipTokensInPreview) + "<" + identifier_generic_parameter_list + ">";
identifier_or_generic.Rule = identifier + new IdentifierResolverHint(true)
| identifier_generic + this.ReduceHere();
type_generic.Rule = identifier_or_generic;
// Type used for cast (use valuetype)
type_for_cast.Rule = typename_for_cast
| value_type;
// ------------------------------------------------------------------------------------
// Expressions
// ------------------------------------------------------------------------------------
// Add special variable allowed as variable name and keyword
identifier_extended.Rule |= Keyword("sample") | Keyword("point");
// postfix_expression
postfix_expression.Rule |= compile_expression
| asm_expression
| state_expression;
compile_expression.Rule = Keyword("compile") + identifier + method_invoke_expression_simple;
// Match an asm block: asm { ... }
asm_expression.Rule = asm_block;
KeyTerms.Add(asm_block.Name, asm_block);
state_expression.Rule = state_type + state_initializer;
// Add cast_expression
cast_expression_raw.Rule = "(" + type_for_cast + rank_specifier.ListOpt() + ")" + cast_expression;
cast_expression.Rule |= cast_expression_raw;
// Syntax is for example: texture = <g_textureref>;
identifier_special_reference_expression.Rule = less_than + indexable_identifier + ">";
identifier_keyword.Rule = Keyword("texture");
simple_assignment_expression_statement.Rule |= indexable_identifier + assignment_operator + identifier_special_reference_expression + ";"
| identifier_keyword + assignment_operator + identifier_special_reference_expression + ";"
| identifier_keyword + assignment_operator + expression + ";";
state_initializer.Rule = "{" + simple_assignment_expression_statement.ListOpt() + "}";
// ------------------------------------------------------------------------------------
// Attribute modifiers
// ------------------------------------------------------------------------------------
attribute_qualifier_pre.Rule = attribute_list_opt;
attribute_list_opt.Rule = MakeStarRule(attribute_list_opt, null, attribute_modifier);
attribute_modifier.Rule = "[" + identifier + "]"
| "[" + identifier + "(" + literal_list.Opt() + ")" + "]";
// ------------------------------------------------------------------------------------
// Variable modifiers
// ------------------------------------------------------------------------------------
// storageClass = Storage_Class + Type_Modifier
storage_qualifier.Rule |= Keyword("extern") | Keyword("nointerpolation") | Keyword("precise") | Keyword("shared") | Keyword("groupshared") | Keyword("static") | Keyword("volatile")
| Keyword("row_major") | Keyword("column_major") | Keyword("linear") | Keyword("centroid") | Keyword("noperspective") | Keyword("sample") | Keyword("unsigned")
| Keyword("inline");
semantic.Rule = ToTerm(":") + identifier;
packoffset.Rule = ToTerm(":") + Keyword("packoffset") + "(" + identifier_or_dot + ")";
register.Rule = ToTerm(":") + Keyword("register") + "(" + indexable_identifier + ")"
| ToTerm(":") + Keyword("register") + "(" + identifier + "," + indexable_identifier + ")";
variable_declarator_qualifier_post_hlsl.Rule = Empty
| semantic
| semantic + packoffset + register.ListOpt()
| semantic + register.List()
| packoffset + register.ListOpt()
| register.List();
variable_declarator_qualifier_post.Rule = variable_declarator_qualifier_post_hlsl;
// ------------------------------------------------------------------------------------
// Declarations
// ------------------------------------------------------------------------------------
// Add typedef and constant buffer resource
declaration.Rule |= typedef_declaration
| constant_buffer_resource;
indexable_identifier_declarator_list.Rule = MakePlusRule(indexable_identifier_declarator_list, ToTerm(","), indexable_identifier_declarator);
// typedef [const] Type Name[Index];
typedef_declaration.Rule = Keyword("typedef") + type + indexable_identifier_declarator_list + ";"
| Keyword("typedef") + storage_qualifier + type + indexable_identifier_declarator_list + ";";
annotations.Rule = less_than + variable_declaration_raw.ListOpt() + ">";
annotations_opt.Rule = Empty | annotations;
// todo: add annotations_opt to variable_declarator qualifier post
// Add annotations to variable declarator
variable_declarator_raw.Rule += annotations_opt;
// Add special
variable_declarator.Rule |= variable_declarator_raw + state_initializer
| variable_declarator_raw + state_array_initializer;
state_initializer_list.Rule = MakePlusRule(state_initializer_list, ToTerm(","), state_initializer);
state_array_initializer.Rule = "{" + state_initializer_list + "}"
| "{" + state_initializer_list + "," + "}";
// interface definition
interface_specifier.Rule = Keyword("interface") + identifier_or_generic + "{" + method_declaration.ListOpt() + "}";
// class definition
class_specifier.Rule = Keyword("class") + identifier_or_generic + class_base_type + "{" + scope_declaration.ListOpt() + "}";
class_base_type_list.Rule = MakePlusRule(class_base_type_list, ToTerm(","), type_generic);
class_base_type.Rule = (ToTerm(":") + class_base_type_list).Opt();
// buffer definition
constant_buffer_resource_type.Rule = Keyword("cbuffer") | Keyword("tbuffer");
constant_buffer_resource.Rule = attribute_qualifier_pre + constant_buffer_resource_type + identifier.Opt() + register.Opt() + "{" + declaration.ListOpt() + "}" + semi_opt;
semantic_list_opt.Rule = semantic.ListOpt();
// Method
method_qualifier_post.Rule = semantic_list_opt;
method_operator_identifier.Rule = Keyword("operator") + "[" + "]"
| Keyword("operator") + "[" + "]" + "[" + "]";
method_special_identifier.Rule = identifier_extended + "." + method_operator_identifier | method_operator_identifier;
method_declarator.Rule |= method_special_identifier + "(" + parameter_list + ")";
parameter_qualifier.Rule = storage_qualifier | Keyword("in") | Keyword("out") | Keyword("inout") | Keyword("point") | Keyword("line") | Keyword("lineadj") | Keyword("triangle") | Keyword("triangleadj");
parameter_qualifier.AstNodeCreator = CreateParameterQualifier;
parameter_qualifier_pre_list_opt.Rule = parameter_qualifier.ListOpt();
parameter_qualifier_pre.Rule = parameter_qualifier_pre_list_opt;
// Make parameter_qualifier_pre transient as there is nothing else to parse then parameter_qualifier_pre_list_opt
parameter_qualifier_pre.Flags = TermFlags.IsTransient | TermFlags.NoAstNode;
parameter_qualifier_post.Rule = semantic_list_opt
| "=" + initializer + semantic_list_opt;
parameter_qualifier_post.AstNodeCreator = CreateParameterQualifierPost;
// ------------------------------------------------------------------------------------
// Technique/pass
// ------------------------------------------------------------------------------------
// technique
technique_keyword.Rule = Keyword("technique") | Keyword("Technique") | Keyword("technique10") | Keyword("Technique10") | Keyword("technique11") | Keyword("Technique11");
technique_definition.Rule = attribute_qualifier_pre + technique_keyword + identifier.Opt() + annotations_opt + "{" + pass_definition.List() + "}" + semi_opt;
// pass
pass_keyword.Rule = Keyword("pass") | Keyword("Pass");
pass_statement.Rule = method_invoke_expression_simple + ";"
| simple_assignment_expression_statement;
pass_definition.Rule = attribute_qualifier_pre + pass_keyword + identifier.Opt() + annotations_opt + "{" + pass_statement.ListOpt() + "}" + semi_opt;
// ------------------------------------------------------------------------------------
// Top Level
// ------------------------------------------------------------------------------------
// Add the technique to the top level
toplevel_declaration.Rule |= technique_definition;
/*
//// ------------------------------------------------------------------------------------
//// Paradox Grammar
//// ------------------------------------------------------------------------------------
//var identifier_csharp = new NonTerminal("identifier_csharp");
//var group = new NonTerminal("group");
//var using_statement = new NonTerminal("using_statement");
//group.Rule = "group" + identifier + "{" + scope_declaration.ListOpt() + "}";
//identifier_csharp.Rule = MakePlusRule(identifier_csharp, ToTerm("."), identifier);
//using_statement.Rule = "using" + identifier + "=" + identifier_csharp + ";"
// | "using" + identifier_csharp + ";";
//scope_declaration.Rule |= using_statement;
//toplevel_declaration.Rule |= group;
*/
// ------------------------------------------------------------------------------------
// Globals
// ------------------------------------------------------------------------------------
// LanguageFlags = LanguageFlags.NewLineBeforeEOF;
LanguageFlags |= LanguageFlags.CreateAst;
}
/// <summary>
/// Finds the member type reference.
/// </summary>
/// <param name="vectorType">Type of the vector.</param>
/// <param name="memberReference">The member reference.</param>
protected virtual void FindMemberTypeReference(VectorType vectorType, MemberReferenceExpression memberReference)
{
var scalarType = vectorType.Type.ResolveType();
var components = memberReference.Member.Text;
if (components.Length <= 4 && (
components.All(x => x == 'x' || x == 'y' || x == 'z' || x == 'w') ||
components.All(x => x == 'r' || x == 'g' || x == 'b' || x == 'a') ||
components.All(x => x == 's' || x == 't' || x == 'u' || x == 'v')
))
{
memberReference.TypeInference.TargetType = components.Length == 1 ? scalarType : new VectorType((ScalarType)scalarType, components.Length);
}
}
/// <summary>
/// Find the type of the expression
/// </summary>
/// <param name="indexerExpression">the indexer expression</param>
protected virtual void ProcessIndexerExpression(IndexerExpression indexerExpression)
{
TypeBase type = null;
var targetType = indexerExpression.Target.TypeInference.TargetType;
if (targetType is ArrayType)
{
var arrayType = (ArrayType)targetType;
if (arrayType.Dimensions.Count == 1)
{
type = arrayType.Type.ResolveType();
}
else
{
var dimensions = new List<Expression>(arrayType.Dimensions);
dimensions.RemoveAt(0);
type = new ArrayType(arrayType.Type, dimensions.ToArray());
}
}
else if (targetType is VectorType)
{
type = ((VectorType)targetType).Type.ResolveType();
}
else if (targetType is MatrixType)
{
type = new VectorType((ScalarType)((MatrixType)targetType).Type.ResolveType(), ((MatrixType)targetType).ColumnCount);
}
else if (targetType is ClassType)
{
// This is for buffers<type>, especially in compute shaders
// TODO: check all the cases
var classType = (ClassType)targetType;
if (classType.GenericArguments.Count > 0)
type = classType.GenericArguments[0];
}
indexerExpression.TypeInference.TargetType = type;
if (type == null)
Error(MessageCode.ErrorIndexerType, indexerExpression.Span, indexerExpression);
}
/// <inheritdoc/>
public bool Equals(VectorType other)
{
return(base.Equals(other));
}