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/*
* Copyright 2020 Google LLC
*
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
#ifndef SKSL_DSL_CORE
#define SKSL_DSL_CORE
#include "include/private/SkSLProgramKind.h"
#include "include/private/SkTArray.h"
#include "include/sksl/DSLBlock.h"
#include "include/sksl/DSLCase.h"
#include "include/sksl/DSLErrorHandling.h"
#include "include/sksl/DSLExpression.h"
#include "include/sksl/DSLFunction.h"
#include "include/sksl/DSLStatement.h"
#include "include/sksl/DSLType.h"
#include "include/sksl/DSLVar.h"
#include "include/sksl/DSLWrapper.h"
namespace SkSL {
class Compiler;
namespace dsl {
// When users import the DSL namespace via `using namespace SkSL::dsl`, we want the SwizzleComponent
// Type enum to come into scope as well, so `Swizzle(var, X, Y, ONE)` can work as expected.
// `namespace SkSL::SwizzleComponent` contains only an `enum Type`; this `using namespace` directive
// shouldn't pollute the SkSL::dsl namespace with anything else.
using namespace SkSL::SwizzleComponent;
enum DSLFlag {
kNo_Flag = 0,
kMangle_Flag = 1 << 0,
kOptimize_Flag = 1 << 1,
kValidate_Flag = 1 << 2,
kMarkVarsDeclared_Flag = 1 << 3,
};
constexpr int kDefaultDSLFlags = kMangle_Flag | kOptimize_Flag | kValidate_Flag;
/**
* Starts DSL output on the current thread using the specified compiler. This must be called
* prior to any other DSL functions.
*/
void Start(SkSL::Compiler* compiler, SkSL::ProgramKind kind = SkSL::ProgramKind::kFragment,
int flags = kDefaultDSLFlags);
/**
* Signals the end of DSL output. This must be called sometime between a call to Start() and the
* termination of the thread.
*/
void End();
/**
* Installs an ErrorHandler which will be notified of any errors that occur during DSL calls. If
* no ErrorHandler is installed, any errors will be fatal.
*/
void SetErrorHandler(ErrorHandler* errorHandler);
DSLVar sk_FragColor();
DSLVar sk_FragCoord();
/**
* break;
*/
DSLStatement Break();
/**
* continue;
*/
DSLStatement Continue();
/**
* Creates a variable declaration statement.
*/
DSLStatement Declare(DSLVar& var, PositionInfo pos = PositionInfo());
/**
* Declares a global variable.
*/
void DeclareGlobal(DSLVar& var, PositionInfo pos = PositionInfo());
/**
* default: statements
*/
template<class... Statements>
DSLCase Default(Statements... statements) {
return DSLCase(DSLExpression(), std::move(statements)...);
}
/**
* discard;
*/
DSLStatement Discard();
/**
* do stmt; while (test);
*/
DSLStatement Do(DSLStatement stmt, DSLExpression test, PositionInfo pos = PositionInfo());
/**
* for (initializer; test; next) stmt;
*/
DSLStatement For(DSLStatement initializer, DSLExpression test, DSLExpression next,
DSLStatement stmt, PositionInfo pos = PositionInfo());
/**
* if (test) ifTrue; [else ifFalse;]
*/
DSLStatement If(DSLExpression test, DSLStatement ifTrue, DSLStatement ifFalse = DSLStatement(),
PositionInfo pos = PositionInfo());
/**
* return [value];
*/
DSLStatement Return(DSLExpression value = DSLExpression(), PositionInfo pos = PositionInfo());
/**
* test ? ifTrue : ifFalse
*/
DSLExpression Select(DSLExpression test, DSLExpression ifTrue, DSLExpression ifFalse,
PositionInfo info = PositionInfo());
DSLStatement StaticIf(DSLExpression test, DSLStatement ifTrue,
DSLStatement ifFalse = DSLStatement(), PositionInfo pos = PositionInfo());
DSLPossibleStatement StaticSwitch(DSLExpression value, SkTArray<DSLCase> cases);
/**
* @switch (value) { cases }
*/
template<class... Cases>
DSLPossibleStatement StaticSwitch(DSLExpression value, Cases... cases) {
SkTArray<DSLCase> caseArray;
caseArray.reserve_back(sizeof...(cases));
(caseArray.push_back(std::move(cases)), ...);
return StaticSwitch(std::move(value), std::move(caseArray));
}
DSLPossibleStatement Switch(DSLExpression value, SkTArray<DSLCase> cases);
/**
* switch (value) { cases }
*/
template<class... Cases>
DSLPossibleStatement Switch(DSLExpression value, Cases... cases) {
SkTArray<DSLCase> caseArray;
caseArray.reserve_back(sizeof...(cases));
(caseArray.push_back(std::move(cases)), ...);
return Switch(std::move(value), std::move(caseArray));
}
/**
* while (test) stmt;
*/
DSLStatement While(DSLExpression test, DSLStatement stmt, PositionInfo info = PositionInfo());
/**
* expression.xyz1
*/
DSLExpression Swizzle(DSLExpression base,
SkSL::SwizzleComponent::Type a,
PositionInfo pos = PositionInfo());
DSLExpression Swizzle(DSLExpression base,
SkSL::SwizzleComponent::Type a,
SkSL::SwizzleComponent::Type b,
PositionInfo pos = PositionInfo());
DSLExpression Swizzle(DSLExpression base,
SkSL::SwizzleComponent::Type a,
SkSL::SwizzleComponent::Type b,
SkSL::SwizzleComponent::Type c,
PositionInfo pos = PositionInfo());
DSLExpression Swizzle(DSLExpression base,
SkSL::SwizzleComponent::Type a,
SkSL::SwizzleComponent::Type b,
SkSL::SwizzleComponent::Type c,
SkSL::SwizzleComponent::Type d,
PositionInfo pos = PositionInfo());
/**
* Returns the absolute value of x. If x is a vector, operates componentwise.
*/
DSLExpression Abs(DSLExpression x, PositionInfo pos = PositionInfo());
/**
* Returns true if all of the components of boolean vector x are true.
*/
DSLExpression All(DSLExpression x, PositionInfo pos = PositionInfo());
/**
* Returns true if any of the components of boolean vector x are true.
*/
DSLExpression Any(DSLExpression x, PositionInfo pos = PositionInfo());
/**
* Returns the arctangent of y over x. Operates componentwise on vectors.
*/
DSLExpression Atan(DSLExpression y_over_x, PositionInfo pos = PositionInfo());
DSLExpression Atan(DSLExpression y, DSLExpression x, PositionInfo pos = PositionInfo());
/**
* Returns x rounded towards positive infinity. If x is a vector, operates componentwise.
*/
DSLExpression Ceil(DSLExpression x, PositionInfo pos = PositionInfo());
/**
* Returns x clamped to between min and max. If x is a vector, operates componentwise.
*/
DSLExpression Clamp(DSLExpression x, DSLExpression min, DSLExpression max,
PositionInfo pos = PositionInfo());
/**
* Returns the cosine of x. If x is a vector, operates componentwise.
*/
DSLExpression Cos(DSLExpression x, PositionInfo pos = PositionInfo());
/**
* Returns the cross product of x and y.
*/
DSLExpression Cross(DSLExpression x, DSLExpression y, PositionInfo pos = PositionInfo());
/**
* Returns x converted from radians to degrees. If x is a vector, operates componentwise.
*/
DSLExpression Degrees(DSLExpression x, PositionInfo pos = PositionInfo());
/**
* Returns the distance between x and y.
*/
DSLExpression Distance(DSLExpression x, DSLExpression y, PositionInfo pos = PositionInfo());
/**
* Returns the dot product of x and y.
*/
DSLExpression Dot(DSLExpression x, DSLExpression y, PositionInfo pos = PositionInfo());
/**
* Returns a boolean vector indicating whether components of x are equal to the corresponding
* components of y.
*/
DSLExpression Equal(DSLExpression x, DSLExpression y, PositionInfo pos = PositionInfo());
/**
* Returns e^x. If x is a vector, operates componentwise.
*/
DSLExpression Exp(DSLExpression x, PositionInfo pos = PositionInfo());
/**
* Returns 2^x. If x is a vector, operates componentwise.
*/
DSLExpression Exp2(DSLExpression x, PositionInfo pos = PositionInfo());
/**
* If dot(i, nref) >= 0, returns n, otherwise returns -n.
*/
DSLExpression Faceforward(DSLExpression n, DSLExpression i, DSLExpression nref,
PositionInfo pos = PositionInfo());
/**
* Returns x rounded towards negative infinity. If x is a vector, operates componentwise.
*/
DSLExpression Floor(DSLExpression x, PositionInfo pos = PositionInfo());
/**
* Returns the fractional part of x. If x is a vector, operates componentwise.
*/
DSLExpression Fract(DSLExpression x, PositionInfo pos = PositionInfo());
/**
* Returns a boolean vector indicating whether components of x are greater than the corresponding
* components of y.
*/
DSLExpression GreaterThan(DSLExpression x, DSLExpression y, PositionInfo pos = PositionInfo());
/**
* Returns a boolean vector indicating whether components of x are greater than or equal to the
* corresponding components of y.
*/
DSLExpression GreaterThanEqual(DSLExpression x, DSLExpression y, PositionInfo pos = PositionInfo());
/**
* Returns the 1/sqrt(x). If x is a vector, operates componentwise.
*/
DSLExpression Inversesqrt(DSLExpression x, PositionInfo pos = PositionInfo());
/**
* Returns the inverse of the matrix x.
*/
DSLExpression Inverse(DSLExpression x, PositionInfo pos = PositionInfo());
/**
* Returns the length of the vector x.
*/
DSLExpression Length(DSLExpression x, PositionInfo pos = PositionInfo());
/**
* Returns a boolean vector indicating whether components of x are less than the corresponding
* components of y.
*/
DSLExpression LessThan(DSLExpression x, DSLExpression y, PositionInfo pos = PositionInfo());
/**
* Returns a boolean vector indicating whether components of x are less than or equal to the
* corresponding components of y.
*/
DSLExpression LessThanEqual(DSLExpression x, DSLExpression y, PositionInfo pos = PositionInfo());
/**
* Returns the log base e of x. If x is a vector, operates componentwise.
*/
DSLExpression Log(DSLExpression x, PositionInfo pos = PositionInfo());
/**
* Returns the log base 2 of x. If x is a vector, operates componentwise.
*/
DSLExpression Log2(DSLExpression x, PositionInfo pos = PositionInfo());
/**
* Returns the larger (closer to positive infinity) of x and y. If x is a vector, operates
* componentwise. y may be either a vector of the same dimensions as x, or a scalar.
*/
DSLExpression Max(DSLExpression x, DSLExpression y, PositionInfo pos = PositionInfo());
/**
* Returns the smaller (closer to negative infinity) of x and y. If x is a vector, operates
* componentwise. y may be either a vector of the same dimensions as x, or a scalar.
*/
DSLExpression Min(DSLExpression x, DSLExpression y, PositionInfo pos = PositionInfo());
/**
* Returns a linear intepolation between x and y at position a, where a=0 results in x and a=1
* results in y. If x and y are vectors, operates componentwise. a may be either a vector of the
* same dimensions as x and y, or a scalar.
*/
DSLExpression Mix(DSLExpression x, DSLExpression y, DSLExpression a,
PositionInfo pos = PositionInfo());
/**
* Returns x modulo y. If x is a vector, operates componentwise. y may be either a vector of the
* same dimensions as x, or a scalar.
*/
DSLExpression Mod(DSLExpression x, DSLExpression y, PositionInfo pos = PositionInfo());
/**
* Returns the vector x normalized to a length of 1.
*/
DSLExpression Normalize(DSLExpression x, PositionInfo pos = PositionInfo());
/**
* Returns a boolean vector indicating whether components of x are not equal to the corresponding
* components of y.
*/
DSLExpression NotEqual(DSLExpression x, DSLExpression y, PositionInfo pos = PositionInfo());
/**
* Returns x raised to the power y. If x is a vector, operates componentwise. y may be either a
* vector of the same dimensions as x, or a scalar.
*/
DSLExpression Pow(DSLExpression x, DSLExpression y, PositionInfo pos = PositionInfo());
/**
* Returns x converted from degrees to radians. If x is a vector, operates componentwise.
*/
DSLExpression Radians(DSLExpression x, PositionInfo pos = PositionInfo());
/**
* Returns i reflected from a surface with normal n.
*/
DSLExpression Reflect(DSLExpression i, DSLExpression n, PositionInfo pos = PositionInfo());
/**
* Returns i refracted across a surface with normal n and ratio of indices of refraction eta.
*/
DSLExpression Refract(DSLExpression i, DSLExpression n, DSLExpression eta,
PositionInfo pos = PositionInfo());
/**
* Samples the child processor at the current coordinates.
*/
DSLExpression Sample(DSLExpression fp, PositionInfo pos = PositionInfo());
/**
* Implements the following functions:
* half4 sample(fragmentProcessor fp, float2 coords);
* half4 sample(fragmentProcessor fp, half4 input);
*/
DSLExpression Sample(DSLExpression target, DSLExpression x, PositionInfo pos = PositionInfo());
/**
* Implements the following functions:
* half4 sample(fragmentProcessor fp, float2 coords, half4 input);
*/
DSLExpression Sample(DSLExpression childProcessor, DSLExpression x, DSLExpression y,
PositionInfo pos = PositionInfo());
/**
* Returns x clamped to the range [0, 1]. If x is a vector, operates componentwise.
*/
DSLExpression Saturate(DSLExpression x, PositionInfo pos = PositionInfo());
/**
* Returns -1, 0, or 1 depending on whether x is negative, zero, or positive, respectively. If x is
* a vector, operates componentwise.
*/
DSLExpression Sign(DSLExpression x, PositionInfo pos = PositionInfo());
/**
* Returns the sine of x. If x is a vector, operates componentwise.
*/
DSLExpression Sin(DSLExpression x, PositionInfo pos = PositionInfo());
/**
* Returns a smooth interpolation between 0 (at x=edge1) and 1 (at x=edge2). If x is a vector,
* operates componentwise. edge1 and edge2 may either be both vectors of the same dimensions as x or
* scalars.
*/
DSLExpression Smoothstep(DSLExpression edge1, DSLExpression edge2, DSLExpression x,
PositionInfo pos = PositionInfo());
/**
* Returns the square root of x. If x is a vector, operates componentwise.
*/
DSLExpression Sqrt(DSLExpression x, PositionInfo pos = PositionInfo());
/**
* Returns 0 if x < edge or 1 if x >= edge. If x is a vector, operates componentwise. edge may be
* either a vector of the same dimensions as x, or a scalar.
*/
DSLExpression Step(DSLExpression edge, DSLExpression x, PositionInfo pos = PositionInfo());
/**
* Returns the tangent of x. If x is a vector, operates componentwise.
*/
DSLExpression Tan(DSLExpression x, PositionInfo pos = PositionInfo());
/**
* Returns x converted from premultipled to unpremultiplied alpha.
*/
DSLExpression Unpremul(DSLExpression x, PositionInfo pos = PositionInfo());
} // namespace dsl
} // namespace SkSL
#endif