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// Copyright 2020 The Dawn & Tint Authors
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#ifndef SRC_TINT_LANG_HLSL_WRITER_AST_PRINTER_AST_PRINTER_H_
#define SRC_TINT_LANG_HLSL_WRITER_AST_PRINTER_AST_PRINTER_H_
#include <string>
#include <tuple>
#include <unordered_map>
#include <unordered_set>
#include <utility>
#include "src/tint/api/common/binding_point.h"
#include "src/tint/api/options/array_length_from_uniform.h"
#include "src/tint/lang/core/builtin_value.h"
#include "src/tint/lang/hlsl/writer/ast_raise/decompose_memory_access.h"
#include "src/tint/lang/hlsl/writer/common/options.h"
#include "src/tint/lang/wgsl/program/program_builder.h"
#include "src/tint/utils/containers/scope_stack.h"
#include "src/tint/utils/generator/text_generator.h"
#include "src/tint/utils/math/hash.h"
// Forward declarations
namespace tint::sem {
class BuiltinFn;
class Call;
class ValueConstructor;
class ValueConversion;
} // namespace tint::sem
namespace tint::hlsl::writer {
/// The result of sanitizing a program for generation.
struct SanitizedResult {
/// Constructor
SanitizedResult();
/// Destructor
~SanitizedResult();
/// Move constructor
SanitizedResult(SanitizedResult&&);
/// The sanitized program.
Program program;
/// Indices into the array_length_from_uniform binding that are statically
/// used.
std::unordered_set<uint32_t> used_array_length_from_uniform_indices;
};
/// Sanitize a program in preparation for generating HLSL.
/// @param program the input program
/// @param options The HLSL generator options.
/// @returns the sanitized program and any supplementary information
SanitizedResult Sanitize(const Program& program, const Options& options);
/// Implementation class for HLSL generator
class ASTPrinter : public tint::TextGenerator {
public:
/// Constructor
/// @param program the program to generate
explicit ASTPrinter(const Program& program);
~ASTPrinter() override;
/// @returns true on successful generation; false otherwise
bool Generate();
/// Handles an index accessor expression
/// @param out the output stream
/// @param expr the expression to emit
/// @returns true if the index accessor was emitted
bool EmitIndexAccessor(StringStream& out, const ast::IndexAccessorExpression* expr);
/// Handles an assignment statement
/// @param stmt the statement to emit
/// @returns true if the statement was emitted successfully
bool EmitAssign(const ast::AssignmentStatement* stmt);
/// Handles generating a binary expression
/// @param out the output stream
/// @param expr the binary expression
/// @returns true if the expression was emitted, false otherwise
bool EmitBinary(StringStream& out, const ast::BinaryExpression* expr);
/// Handles generating a bitcast expression
/// @param out the output stream
/// @param expr the as expression
/// @returns true if the bitcast was emitted
bool EmitBitcast(StringStream& out, const ast::BitcastExpression* expr);
/// Emits a list of statements
/// @param stmts the statement list
/// @returns true if the statements were emitted successfully
bool EmitStatements(VectorRef<const ast::Statement*> stmts);
/// Emits a list of statements with an indentation
/// @param stmts the statement list
/// @returns true if the statements were emitted successfully
bool EmitStatementsWithIndent(VectorRef<const ast::Statement*> stmts);
/// Handles a block statement
/// @param stmt the statement to emit
/// @returns true if the statement was emitted successfully
bool EmitBlock(const ast::BlockStatement* stmt);
/// Handles a break statement
/// @param stmt the statement to emit
/// @returns true if the statement was emitted successfully
bool EmitBreak(const ast::BreakStatement* stmt);
/// Handles a break-if statement
/// @param stmt the statement to emit
/// @returns true if the statement was emitted successfully
bool EmitBreakIf(const ast::BreakIfStatement* stmt);
/// Handles generating a call expression
/// @param out the output stream
/// @param expr the call expression
/// @returns true if the call expression is emitted
bool EmitCall(StringStream& out, const ast::CallExpression* expr);
/// Handles generating a function call expression
/// @param out the output stream
/// @param call the call expression
/// @param function the function being called
/// @returns true if the expression is emitted
bool EmitFunctionCall(StringStream& out, const sem::Call* call, const sem::Function* function);
/// Handles generating a builtin call expression
/// @param out the output stream
/// @param call the call expression
/// @param builtin the builtin being called
/// @returns true if the expression is emitted
bool EmitBuiltinCall(StringStream& out, const sem::Call* call, const sem::BuiltinFn* builtin);
/// Handles generating a value conversion expression
/// @param out the output stream
/// @param call the call expression
/// @param conv the value conversion
/// @returns true if the expression is emitted
bool EmitValueConversion(StringStream& out,
const sem::Call* call,
const sem::ValueConversion* conv);
/// Handles generating a value constructor expression
/// @param out the output stream
/// @param call the call expression
/// @param ctor the value constructor
/// @returns true if the expression is emitted
bool EmitValueConstructor(StringStream& out,
const sem::Call* call,
const sem::ValueConstructor* ctor);
/// Handles generating a call expression to a
/// DecomposeMemoryAccess::Intrinsic for a uniform buffer
/// @param out the output stream
/// @param expr the call expression
/// @param intrinsic the DecomposeMemoryAccess::Intrinsic
/// @returns true if the call expression is emitted
bool EmitUniformBufferAccess(StringStream& out,
const ast::CallExpression* expr,
const DecomposeMemoryAccess::Intrinsic* intrinsic);
/// Handles generating a call expression to a
/// DecomposeMemoryAccess::Intrinsic for a storage buffer
/// @param out the output stream
/// @param expr the call expression
/// @param intrinsic the DecomposeMemoryAccess::Intrinsic
/// @returns true if the call expression is emitted
bool EmitStorageBufferAccess(StringStream& out,
const ast::CallExpression* expr,
const DecomposeMemoryAccess::Intrinsic* intrinsic);
/// Handles generating a barrier intrinsic call
/// @param out the output stream
/// @param builtin the semantic information for the barrier builtin
/// @returns true if the call expression is emitted
bool EmitBarrierCall(StringStream& out, const sem::BuiltinFn* builtin);
/// Handles generating an atomic intrinsic call for a storage buffer variable
/// @param out the output stream
/// @param expr the call expression
/// @param intrinsic the atomic intrinsic
/// @returns true if the call expression is emitted
bool EmitStorageAtomicCall(StringStream& out,
const ast::CallExpression* expr,
const DecomposeMemoryAccess::Intrinsic* intrinsic);
/// Handles generating the helper function for the atomic intrinsic function
/// @param func the function
/// @param intrinsic the atomic intrinsic
/// @returns true if the function is emitted
bool EmitStorageAtomicIntrinsic(const ast::Function* func,
const DecomposeMemoryAccess::Intrinsic* intrinsic);
/// Handles generating an atomic intrinsic call for a workgroup variable
/// @param out the output stream
/// @param expr the call expression
/// @param builtin the semantic information for the atomic builtin
/// @returns true if the call expression is emitted
bool EmitWorkgroupAtomicCall(StringStream& out,
const ast::CallExpression* expr,
const sem::BuiltinFn* builtin);
/// Handles generating a call to a texture function (`textureSample`,
/// `textureSampleGrad`, etc)
/// @param out the output stream
/// @param call the call expression
/// @param builtin the semantic information for the texture builtin
/// @returns true if the call expression is emitted
bool EmitTextureCall(StringStream& out, const sem::Call* call, const sem::BuiltinFn* builtin);
/// Handles generating a call to the `select()` builtin
/// @param out the output stream
/// @param expr the call expression
/// @returns true if the call expression is emitted
bool EmitSelectCall(StringStream& out, const ast::CallExpression* expr);
/// Handles generating a call to the `modf()` builtin
/// @param out the output stream
/// @param expr the call expression
/// @param builtin the semantic information for the builtin
/// @returns true if the call expression is emitted
bool EmitModfCall(StringStream& out,
const ast::CallExpression* expr,
const sem::BuiltinFn* builtin);
/// Handles generating a call to the `frexp()` builtin
/// @param out the output stream
/// @param expr the call expression
/// @param builtin the semantic information for the builtin
/// @returns true if the call expression is emitted
bool EmitFrexpCall(StringStream& out,
const ast::CallExpression* expr,
const sem::BuiltinFn* builtin);
/// Handles generating a call to the `degrees()` builtin
/// @param out the output stream
/// @param expr the call expression
/// @param builtin the semantic information for the builtin
/// @returns true if the call expression is emitted
bool EmitDegreesCall(StringStream& out,
const ast::CallExpression* expr,
const sem::BuiltinFn* builtin);
/// Handles generating a call to the `radians()` builtin
/// @param out the output stream
/// @param expr the call expression
/// @param builtin the semantic information for the builtin
/// @returns true if the call expression is emitted
bool EmitRadiansCall(StringStream& out,
const ast::CallExpression* expr,
const sem::BuiltinFn* builtin);
/// Handles generating a call to the `sign()` builtin
/// @param out the output stream
/// @param call the call semantic node
/// @param builtin the semantic information for the builtin
/// @returns true if the call expression is emitted
bool EmitSignCall(StringStream& out, const sem::Call* call, const sem::BuiltinFn* builtin);
/// Handles generating a call to data packing builtin
/// @param out the output stream
/// @param expr the call expression
/// @param builtin the semantic information for the builtin
/// @returns true if the call expression is emitted
bool EmitDataPackingCall(StringStream& out,
const ast::CallExpression* expr,
const sem::BuiltinFn* builtin);
/// Handles generating a call to data unpacking builtin
/// @param out the output stream
/// @param expr the call expression
/// @param builtin the semantic information for the builtin
/// @returns true if the call expression is emitted
bool EmitDataUnpackingCall(StringStream& out,
const ast::CallExpression* expr,
const sem::BuiltinFn* builtin);
/// Handles generating a call to the `quantizeToF16()` intrinsic
/// @param out the output stream
/// @param expr the call expression
/// @param builtin the semantic information for the builtin
/// @returns true if the call expression is emitted
bool EmitQuantizeToF16Call(StringStream& out,
const ast::CallExpression* expr,
const sem::BuiltinFn* builtin);
/// Handles generating a call to the `trunc()` intrinsic
/// @param out the output stream
/// @param expr the call expression
/// @param builtin the semantic information for the builtin
/// @returns true if the call expression is emitted
bool EmitTruncCall(StringStream& out,
const ast::CallExpression* expr,
const sem::BuiltinFn* builtin);
/// Handles generating a call to the builtins defined in the language extension
/// `packed_4x8_integer_dot_product`.
/// @param out the output stream
/// @param expr the call expression
/// @param builtin the semantic information for the builtin
/// @returns true if the call expression is emitted
bool EmitPacked4x8IntegerDotProductBuiltinCall(StringStream& out,
const ast::CallExpression* expr,
const sem::BuiltinFn* builtin);
/// Handles generating a call to subgroup builtins.
/// @param out the output stream
/// @param expr the call expression
/// @param builtin the semantic information for the builtin
/// @returns true if the call expression is emitted
bool EmitSubgroupCall(StringStream& out,
const ast::CallExpression* expr,
const sem::BuiltinFn* builtin);
/// Handles a case statement
/// @param s the switch statement
/// @param case_idx the index of the switch case in the switch statement
/// @returns true if the statement was emitted successfully
bool EmitCase(const ast::SwitchStatement* s, size_t case_idx);
/// Handles generating a discard statement
/// @param stmt the discard statement
/// @returns true if the statement was successfully emitted
bool EmitDiscard(const ast::DiscardStatement* stmt);
/// Handles a continue statement
/// @param stmt the statement to emit
/// @returns true if the statement was emitted successfully
bool EmitContinue(const ast::ContinueStatement* stmt);
/// Handles generating an Expression
/// @param out the output stream
/// @param expr the expression
/// @returns true if the expression was emitted
bool EmitExpression(StringStream& out, const ast::Expression* expr);
/// Handles generating an Expression for texture or storage buffer call arguments. This is
/// specifically to work around a DXC bug around passing signed integer splatted constants as
/// args to these functions (see crbug.com/tint/1976)
/// @param out the output stream
/// @param expr the expression
/// @returns true if the expression was emitted
bool EmitTextureOrStorageBufferCallArgExpression(StringStream& out,
const ast::Expression* expr);
/// Handles generating a function
/// @param func the function to generate
/// @returns true if the function was emitted
bool EmitFunction(const ast::Function* func);
/// Handles emitting the function body if it discards to work around a FXC
/// compilation bug.
/// @param func the function with the body to emit
/// @returns true if the function was emitted
bool EmitFunctionBodyWithDiscard(const ast::Function* func);
/// Handles emitting a global variable
/// @param global the global variable
/// @returns true on success
bool EmitGlobalVariable(const ast::Variable* global);
/// Handles emitting a global variable with the uniform address space
/// @param var the AST node for the 'var'
/// @param sem the semantic node for the 'var'
/// @returns true on success
bool EmitUniformVariable(const ast::Var* var, const sem::Variable* sem);
/// Handles emitting a global variable with the storage address space
/// @param var the AST node for the 'var'
/// @param sem the semantic node for the 'var'
/// @returns true on success
bool EmitStorageVariable(const ast::Var* var, const sem::Variable* sem);
/// Handles emitting a global variable with the handle address space
/// @param var the AST node for the 'var'
/// @param sem the semantic node for the 'var'
/// @returns true on success
bool EmitHandleVariable(const ast::Var* var, const sem::Variable* sem);
/// Handles emitting a global variable with the private address space
/// @param var the global variable
/// @returns true on success
bool EmitPrivateVariable(const sem::Variable* var);
/// Handles emitting a global variable with the workgroup address space
/// @param var the global variable
/// @returns true on success
bool EmitWorkgroupVariable(const sem::Variable* var);
/// Handles emitting the entry point function
/// @param func the entry point
/// @returns true if the entry point function was emitted
bool EmitEntryPointFunction(const ast::Function* func);
/// Handles an if statement
/// @param stmt the statement to emit
/// @returns true if the statement was successfully emitted
bool EmitIf(const ast::IfStatement* stmt);
/// Handles a constant value
/// @param out the output stream
/// @param constant the constant value to emit
/// @param is_variable_initializer true if the constant is used as the RHS of a variable
/// initializer
/// @returns true if the constant value was successfully emitted
bool EmitConstant(StringStream& out,
const core::constant::Value* constant,
bool is_variable_initializer);
/// Handles a literal
/// @param out the output stream
/// @param lit the literal to emit
/// @returns true if the literal was successfully emitted
bool EmitLiteral(StringStream& out, const ast::LiteralExpression* lit);
/// Handles a loop statement
/// @param stmt the statement to emit
/// @returns true if the statement was emitted
bool EmitLoop(const ast::LoopStatement* stmt);
/// Handles a for loop statement
/// @param stmt the statement to emit
/// @returns true if the statement was emitted
bool EmitForLoop(const ast::ForLoopStatement* stmt);
/// Handles a while statement
/// @param stmt the statement to emit
/// @returns true if the statement was emitted
bool EmitWhile(const ast::WhileStatement* stmt);
/// Handles generating an identifier expression
/// @param out the output stream
/// @param expr the identifier expression
/// @returns true if the identifeir was emitted
bool EmitIdentifier(StringStream& out, const ast::IdentifierExpression* expr);
/// Handles a member accessor expression
/// @param out the output stream
/// @param expr the member accessor expression
/// @returns true if the member accessor was emitted
bool EmitMemberAccessor(StringStream& out, const ast::MemberAccessorExpression* expr);
/// Handles return statements
/// @param stmt the statement to emit
/// @returns true if the statement was successfully emitted
bool EmitReturn(const ast::ReturnStatement* stmt);
/// Handles statement
/// @param stmt the statement to emit
/// @returns true if the statement was emitted
bool EmitStatement(const ast::Statement* stmt);
/// Handles generating a switch statement
/// @param stmt the statement to emit
/// @returns true if the statement was emitted
bool EmitSwitch(const ast::SwitchStatement* stmt);
// Handles generating a switch statement with only a default case
/// @param stmt the statement to emit
/// @returns true if the statement was emitted
bool EmitDefaultOnlySwitch(const ast::SwitchStatement* stmt);
/// Handles generating type
/// @param out the output stream
/// @param type the type to generate
/// @param address_space the address space of the variable
/// @param access the access control type of the variable
/// @param name the name of the variable, used for array emission.
/// @param name_printed (optional) if not nullptr and an array was printed
/// then the boolean is set to true.
/// @returns true if the type is emitted
bool EmitType(StringStream& out,
const core::type::Type* type,
core::AddressSpace address_space,
core::Access access,
const std::string& name,
bool* name_printed = nullptr);
/// Handles generating type and name
/// @param out the output stream
/// @param type the type to generate
/// @param address_space the address space of the variable
/// @param access the access control type of the variable
/// @param name the name to emit
/// @returns true if the type is emitted
bool EmitTypeAndName(StringStream& out,
const core::type::Type* type,
core::AddressSpace address_space,
core::Access access,
const std::string& name);
/// Handles generating a structure declaration. If the structure has already been emitted, then
/// this function will simply return `true` without emitting anything.
/// @param buffer the text buffer that the type declaration will be written to
/// @param ty the struct to generate
/// @returns true if the struct is emitted
bool EmitStructType(TextBuffer* buffer, const core::type::Struct* ty);
/// Handles a unary op expression
/// @param out the output stream
/// @param expr the expression to emit
/// @returns true if the expression was emitted
bool EmitUnaryOp(StringStream& out, const ast::UnaryOpExpression* expr);
/// Emits `value` for the given type
/// @param out the output stream
/// @param type the type to emit the value for
/// @param value the value to emit
/// @returns true if the value was successfully emitted.
bool EmitValue(StringStream& out, const core::type::Type* type, int value);
/// Emits the zero value for the given type
/// @param out the output stream
/// @param type the type to emit the value for
/// @returns true if the zero value was successfully emitted.
bool EmitZeroValue(StringStream& out, const core::type::Type* type);
/// Handles generating a 'var' declaration
/// @param var the variable to generate
/// @returns true if the variable was emitted
bool EmitVar(const ast::Var* var);
/// Handles generating a 'let' declaration
/// @param let the variable to generate
/// @returns true if the variable was emitted
bool EmitLet(const ast::Let* let);
/// Emits call to a helper vector assignment function for the input assignment
/// statement and vector type. This is used to work around FXC issues where
/// assignments to vectors with dynamic indices cause compilation failures.
/// @param stmt assignment statement that corresponds to a vector assignment
/// via an accessor expression
/// @param vec the vector type being assigned to
/// @returns true on success
bool EmitDynamicVectorAssignment(const ast::AssignmentStatement* stmt,
const core::type::Vector* vec);
/// Emits call to a helper matrix assignment function for the input assignment
/// statement and matrix type. This is used to work around FXC issues where
/// assignment of a vector to a matrix with a dynamic index causes compilation
/// failures.
/// @param stmt assignment statement that corresponds to a matrix assignment
/// via an accessor expression
/// @param mat the matrix type being assigned to
/// @returns true on success
bool EmitDynamicMatrixVectorAssignment(const ast::AssignmentStatement* stmt,
const core::type::Matrix* mat);
/// Emits call to a helper matrix assignment function for the input assignment
/// statement and matrix type. This is used to work around FXC issues where
/// assignment of a scalar to a matrix with at least one dynamic index causes
/// compilation failures.
/// @param stmt assignment statement that corresponds to a matrix assignment
/// via an accessor expression
/// @param mat the matrix type being assigned to
/// @returns true on success
bool EmitDynamicMatrixScalarAssignment(const ast::AssignmentStatement* stmt,
const core::type::Matrix* mat);
/// Handles generating a builtin method name
/// @param builtin the semantic info for the builtin
/// @returns the name or "" if not valid
std::string generate_builtin_name(const sem::BuiltinFn* builtin);
/// Converts a builtin to an attribute name
/// @param builtin the builtin to convert
/// @returns the string name of the builtin or blank on error
std::string builtin_to_attribute(core::BuiltinValue builtin) const;
/// Converts interpolation attributes to a HLSL modifiers
/// @param type the interpolation type
/// @param sampling the interpolation sampling
/// @returns the string name of the attribute or blank on error
std::string interpolation_to_modifiers(core::InterpolationType type,
core::InterpolationSampling sampling) const;
private:
enum class VarType { kIn, kOut };
struct EntryPointData {
std::string struct_name;
std::string var_name;
};
struct DMAIntrinsic {
DecomposeMemoryAccess::Intrinsic::Op op;
DecomposeMemoryAccess::Intrinsic::DataType type;
bool operator==(const DMAIntrinsic& rhs) const { return op == rhs.op && type == rhs.type; }
/// Hasher is a std::hash function for DMAIntrinsic
struct Hasher {
/// @param i the DMAIntrinsic to hash
/// @returns the hash of `i`
inline std::size_t operator()(const DMAIntrinsic& i) const {
return Hash(i.op, i.type);
}
};
};
/// The map key for two semantic types.
using BinaryType =
tint::UnorderedKeyWrapper<std::tuple<const core::type::Type*, const core::type::Type*>>;
/// CallBuiltinHelper will call the builtin helper function, creating it
/// if it hasn't been built already. If the builtin needs to be built then
/// CallBuiltinHelper will generate the function signature and will call
/// `build` to emit the body of the function.
/// @param out the output stream
/// @param call the call expression
/// @param builtin the semantic information for the builtin
/// @param build a function with the signature:
/// `bool(TextBuffer* buffer, const std::vector<std::string>& params)`
/// Where:
/// `buffer` is the body of the generated function
/// `params` is the name of all the generated function parameters
/// @returns true if the call expression is emitted
template <typename F>
bool CallBuiltinHelper(StringStream& out,
const ast::CallExpression* call,
const sem::BuiltinFn* builtin,
F&& build);
/// @param s the structure
/// @returns the name of the structure, taking special care of builtin structures that start
/// with double underscores. If the structure is a builtin, then the returned name will be a
/// unique name without the leading underscores.
std::string StructName(const core::type::Struct* s);
/// @return a new, unique identifier with the given prefix.
/// @param prefix optional prefix to apply to the generated identifier. If empty "tint_symbol"
/// will be used.
std::string UniqueIdentifier(const std::string& prefix = "");
/// Alias for builder_.TypeOf(ptr)
template <typename T>
auto TypeOf(T* ptr) {
return builder_.TypeOf(ptr);
}
ProgramBuilder builder_;
/// Helper functions emitted at the top of the output
TextBuffer helpers_;
/// Map of builtin structure to unique generated name
std::unordered_map<const core::type::Struct*, std::string> builtin_struct_names_;
std::function<bool()> emit_continuing_;
std::unordered_map<const core::type::Matrix*, std::string> matrix_scalar_inits_;
std::unordered_map<const sem::BuiltinFn*, std::string> builtins_;
// Polyfill functions for bitcast expression, BinaryType indicates the source type and the
// destination type.
std::unordered_map<BinaryType, std::string> bitcast_funcs_;
std::unordered_map<const core::type::Vector*, std::string> dynamic_vector_write_;
std::unordered_map<const core::type::Matrix*, std::string> dynamic_matrix_vector_write_;
std::unordered_map<const core::type::Matrix*, std::string> dynamic_matrix_scalar_write_;
std::unordered_map<const core::type::Type*, std::string> value_or_one_if_zero_;
std::unordered_set<const core::type::Struct*> emitted_structs_;
// The line index in current_buffer_ of the current global declaration / function.
size_t global_insertion_point_ = 0;
};
} // namespace tint::hlsl::writer
#endif // SRC_TINT_LANG_HLSL_WRITER_AST_PRINTER_AST_PRINTER_H_