duckstation/dep/reshadefx/include/effect_expression.hpp

251 lines
8.9 KiB
C++

/*
* Copyright (C) 2014 Patrick Mours
* SPDX-License-Identifier: BSD-3-Clause
*/
#pragma once
#include "effect_token.hpp"
#include <cstdint>
namespace reshadefx
{
/// <summary>
/// Structure which encapsulates a parsed value type
/// </summary>
struct type
{
enum datatype : uint8_t
{
t_void,
t_bool,
t_min16int,
t_int,
t_min16uint,
t_uint,
t_min16float,
t_float,
t_string,
t_struct,
t_texture1d,
t_texture2d,
t_texture3d,
t_sampler1d_int,
t_sampler2d_int,
t_sampler3d_int,
t_sampler1d_uint,
t_sampler2d_uint,
t_sampler3d_uint,
t_sampler1d_float,
t_sampler2d_float,
t_sampler3d_float,
t_storage1d_int,
t_storage2d_int,
t_storage3d_int,
t_storage1d_uint,
t_storage2d_uint,
t_storage3d_uint,
t_storage1d_float,
t_storage2d_float,
t_storage3d_float,
t_function,
};
enum qualifier : uint32_t
{
q_extern = 1 << 0,
q_static = 1 << 1,
q_uniform = 1 << 2,
q_volatile = 1 << 3,
q_precise = 1 << 4,
q_groupshared = 1 << 14,
q_in = 1 << 5,
q_out = 1 << 6,
q_inout = q_in | q_out,
q_const = 1 << 8,
q_linear = 1 << 10,
q_noperspective = 1 << 11,
q_centroid = 1 << 12,
q_nointerpolation = 1 << 13,
};
/// <summary>
/// Gets the result type of an operation involving the two input types.
/// </summary>
static type merge(const type &lhs, const type &rhs);
/// <summary>
/// Calculates the ranking between two types which can be used to select the best matching function overload. The higher the rank, the better the match. A value of zero indicates that the types are not compatible.
/// </summary>
static unsigned int rank(const type &src, const type &dst);
/// <summary>
/// Returns a human-readable description of this type definition.
/// </summary>
std::string description() const;
bool has(qualifier x) const { return (qualifiers & x) == x; }
bool is_void() const { return base == t_void; }
bool is_boolean() const { return base == t_bool; }
bool is_numeric() const { return base >= t_bool && base <= t_float; }
bool is_integral() const { return (base >= t_bool && base <= t_uint) || (base >= t_sampler1d_int && base <= t_sampler3d_uint) || (base >= t_storage1d_int && base <= t_storage3d_uint); }
bool is_floating_point() const { return base == t_min16float || base == t_float || (base >= t_sampler1d_float && base <= t_sampler3d_float) || (base >= t_storage1d_float && base <= t_storage3d_float); }
bool is_signed() const { return base == t_min16int || base == t_int || (base >= t_sampler1d_int && base <= t_sampler3d_int) || (base >= t_storage1d_int && base <= t_storage3d_int) || is_floating_point(); }
bool is_unsigned() const { return base == t_min16uint || base == t_uint || (base >= t_sampler1d_uint && base <= t_sampler3d_uint) || (base >= t_storage1d_uint && base <= t_storage3d_uint); }
bool is_struct() const { return base == t_struct; }
bool is_object() const { return is_texture() || is_sampler() || is_storage(); }
bool is_texture() const { return base >= t_texture1d && base <= t_texture3d; }
bool is_sampler() const { return base >= t_sampler1d_int && base <= t_sampler3d_float; }
bool is_storage() const { return base >= t_storage1d_int && base <= t_storage3d_float; }
bool is_function() const { return base == t_function; }
bool is_array() const { return array_length != 0; }
bool is_scalar() const { return is_numeric() && !is_matrix() && !is_vector() && !is_array(); }
bool is_vector() const { return is_numeric() && rows > 1 && cols == 1; }
bool is_matrix() const { return is_numeric() && rows >= 1 && cols > 1; }
unsigned int precision() const { return base == t_min16int || base == t_min16uint || base == t_min16float ? 16 : 32; }
unsigned int components() const { return rows * cols; }
unsigned int texture_dimension() const { return base >= t_texture1d && base <= t_storage3d_float ? ((base - t_texture1d) % 3) + 1 : 0; }
friend inline bool operator==(const type &lhs, const type &rhs)
{
return lhs.base == rhs.base && lhs.rows == rhs.rows && lhs.cols == rhs.cols && lhs.array_length == rhs.array_length && lhs.definition == rhs.definition;
}
friend inline bool operator!=(const type &lhs, const type &rhs)
{
return !operator==(lhs, rhs);
}
// Underlying base type ('int', 'float', ...)
datatype base = t_void;
// Number of rows if this is a vector type
unsigned int rows = 0;
// Number of columns if this is a matrix type
unsigned int cols = 0;
// Bit mask of all the qualifiers decorating the type
unsigned int qualifiers = 0;
// Negative if an unsized array, otherwise the number of elements if this is an array type
int array_length = 0;
// ID of the matching struct if this is a struct type
uint32_t definition = 0;
};
/// <summary>
/// Structure which encapsulates a parsed constant value
/// </summary>
struct constant
{
union
{
float as_float[16];
int32_t as_int[16];
uint32_t as_uint[16];
};
// Optional string associated with this constant
std::string string_data;
// Optional additional elements if this is an array constant
std::vector<constant> array_data;
};
/// <summary>
/// Structures which keeps track of the access chain of an expression
/// </summary>
struct expression
{
struct operation
{
enum op_type
{
op_cast,
op_member,
op_dynamic_index,
op_constant_index,
op_swizzle,
};
op_type op;
reshadefx::type from, to;
uint32_t index = 0;
signed char swizzle[4] = {};
};
uint32_t base = 0;
reshadefx::type type = {};
reshadefx::constant constant = {};
bool is_lvalue = false;
bool is_constant = false;
reshadefx::location location;
std::vector<operation> chain;
/// <summary>
/// Initializes the expression to a l-value.
/// </summary>
/// <param name="loc">Code location of the expression.</param>
/// <param name="base">SSA ID of the l-value.</param>
/// <param name="type">Value type of the expression result.</param>
void reset_to_lvalue(const reshadefx::location &loc, uint32_t base, const reshadefx::type &type);
/// <summary>
/// Initializes the expression to a r-value.
/// </summary>
/// <param name="loc">Code location of the expression.</param>
/// <param name="base">SSA ID of the r-value.</param>
/// <param name="type">Value type of the expression result.</param>
void reset_to_rvalue(const reshadefx::location &loc, uint32_t base, const reshadefx::type &type);
/// <summary>
/// Initializes the expression to a constant value.
/// </summary>
/// <param name="loc">Code location of the constant expression.</param>
/// <param name="data">Constant value to initialize to.</param>
void reset_to_rvalue_constant(const reshadefx::location &loc, bool data);
void reset_to_rvalue_constant(const reshadefx::location &loc, float data);
void reset_to_rvalue_constant(const reshadefx::location &loc, int32_t data);
void reset_to_rvalue_constant(const reshadefx::location &loc, uint32_t data);
void reset_to_rvalue_constant(const reshadefx::location &loc, std::string data);
void reset_to_rvalue_constant(const reshadefx::location &loc, reshadefx::constant data, const reshadefx::type &type);
/// <summary>
/// Adds a cast operation to the current access chain.
/// </summary>
/// <param name="type">Type to cast the expression to.</param>
void add_cast_operation(const reshadefx::type &type);
/// <summary>
/// Adds a structure member lookup to the current access chain.
/// </summary>
/// <param name="index">Index of the member to dereference.</param>
/// <param name="type">Value type of the member.</param>
void add_member_access(unsigned int index, const reshadefx::type &type);
/// <summary>
/// Adds an index operation to the current access chain.
/// </summary>
/// <param name="index_expression">SSA ID of the indexing value.</param>
void add_dynamic_index_access(uint32_t index_expression);
/// <summary>
/// Adds an constant index operation to the current access chain.
/// </summary>
/// <param name="index">Constant indexing value.</param>
void add_constant_index_access(unsigned int index);
/// <summary>
/// Adds a swizzle operation to the current access chain.
/// </summary>
/// <param name="swizzle">Swizzle for each component. -1 = unused, 0 = x, 1 = y, 2 = z, 3 = w.</param>
/// <param name="length">Number of components in the swizzle. The maximum is 4.</param>
void add_swizzle_access(const signed char swizzle[4], unsigned int length);
/// <summary>
/// Applies an unary operation to this constant expression.
/// </summary>
/// <param name="op">Unary operator to apply.</param>
bool evaluate_constant_expression(reshadefx::tokenid op);
/// <summary>
/// Applies a binary operation to this constant expression.
/// </summary>
/// <param name="op">Binary operator to apply.</param>
/// <param name="rhs">Constant value to use as right-hand side of the binary operation.</param>
bool evaluate_constant_expression(reshadefx::tokenid op, const reshadefx::constant &rhs);
};
}