skia2/tests/SkSLDSLTest.cpp
Ethan Nicholas ab0a13d9d9 Removed the final remnants of IRGenerator
This completes the long process of moving all of IRGenerator's code and
data into better homes and finally kills the class altogether. There is
a lot of #include churn here due to poor header hygiene in the past;
IRGenerator.h included a ton of stuff and almost everything included
IRGenerator, allowing us to inadvertently be sloppy with our includes.

Change-Id: I70d854e57dec7bd9a311b72f9f72d978d354da98
Reviewed-on: https://skia-review.googlesource.com/c/skia/+/459936
Reviewed-by: John Stiles <johnstiles@google.com>
Commit-Queue: Ethan Nicholas <ethannicholas@google.com>
2021-10-19 13:17:01 +00:00

2182 lines
76 KiB
C++

/*
* Copyright 2020 Google LLC
*
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
#include "include/private/SkSLIRNode.h"
#include "include/sksl/DSL.h"
#include "include/sksl/DSLRuntimeEffects.h"
#include "src/gpu/GrDirectContextPriv.h"
#include "src/gpu/GrGpu.h"
#include "src/sksl/SkSLCompiler.h"
#include "src/sksl/SkSLThreadContext.h"
#include "src/sksl/dsl/priv/DSLWriter.h"
#include "src/sksl/ir/SkSLBlock.h"
#include "src/sksl/ir/SkSLVariable.h"
#include "tests/Test.h"
#include <limits>
using namespace SkSL::dsl;
SkSL::ProgramSettings default_settings() {
SkSL::ProgramSettings result;
result.fDSLMarkVarsDeclared = true;
result.fDSLMangling = false;
return result;
}
SkSL::ProgramSettings no_mark_vars_declared() {
SkSL::ProgramSettings result = default_settings();
result.fDSLMarkVarsDeclared = false;
return result;
}
/**
* In addition to issuing an automatic Start() and End(), disables mangling and optionally
* auto-declares variables during its lifetime. Variable auto-declaration simplifies testing so we
* don't have to sprinkle all the tests with a bunch of Declare(foo).release() calls just to avoid
* errors, especially given that some of the variables have options that make them an error to
* actually declare.
*/
class AutoDSLContext {
public:
AutoDSLContext(GrGpu* gpu, SkSL::ProgramSettings settings = default_settings(),
SkSL::ProgramKind kind = SkSL::ProgramKind::kFragment) {
Start(gpu->shaderCompiler(), kind, settings);
}
~AutoDSLContext() {
End();
}
};
class ExpectError : public SkSL::ErrorReporter {
public:
ExpectError(skiatest::Reporter* reporter, const char* msg)
: fMsg(msg)
, fReporter(reporter)
, fOldReporter(&GetErrorReporter()) {
SetErrorReporter(this);
}
~ExpectError() override {
REPORTER_ASSERT(fReporter, !fMsg,
"Error mismatch: expected:\n%s\nbut no error occurred\n", fMsg);
SetErrorReporter(fOldReporter);
}
void handleError(skstd::string_view msg, SkSL::PositionInfo pos) override {
REPORTER_ASSERT(fReporter, fMsg, "Received unexpected extra error: %.*s\n",
(int)msg.length(), msg.data());
REPORTER_ASSERT(fReporter, !fMsg || msg == fMsg,
"Error mismatch: expected:\n%s\nbut received:\n%.*s", fMsg, (int)msg.length(),
msg.data());
fMsg = nullptr;
}
private:
const char* fMsg;
skiatest::Reporter* fReporter;
ErrorReporter* fOldReporter;
};
static bool whitespace_insensitive_compare(const char* a, const char* b) {
for (;;) {
while (isspace(*a)) {
++a;
}
while (isspace(*b)) {
++b;
}
if (*a != *b) {
return false;
}
if (*a == 0) {
return true;
}
++a;
++b;
}
}
// for use from SkSLDSLOnlyTest.cpp
void StartDSL(const sk_gpu_test::ContextInfo ctxInfo) {
Start(ctxInfo.directContext()->priv().getGpu()->shaderCompiler());
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLStartup, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Expression e1 = 1;
REPORTER_ASSERT(r, e1.release()->description() == "1");
Expression e2 = 1.0;
REPORTER_ASSERT(r, e2.release()->description() == "1.0");
Expression e3 = true;
REPORTER_ASSERT(r, e3.release()->description() == "true");
Var a(kInt_Type, "a");
Expression e4 = a;
REPORTER_ASSERT(r, e4.release()->description() == "a");
REPORTER_ASSERT(r, whitespace_insensitive_compare("", ""));
REPORTER_ASSERT(r, !whitespace_insensitive_compare("", "a"));
REPORTER_ASSERT(r, !whitespace_insensitive_compare("a", ""));
REPORTER_ASSERT(r, whitespace_insensitive_compare("a", "a"));
REPORTER_ASSERT(r, whitespace_insensitive_compare("abc", "abc"));
REPORTER_ASSERT(r, whitespace_insensitive_compare("abc", " abc "));
REPORTER_ASSERT(r, whitespace_insensitive_compare("a b c ", "\n\n\nabc"));
REPORTER_ASSERT(r, !whitespace_insensitive_compare("a b c d", "\n\n\nabc"));
}
static SkSL::String stringize(DSLStatement& stmt) { return stmt.release()->description(); }
static SkSL::String stringize(DSLPossibleStatement& stmt) { return stmt.release()->description(); }
static SkSL::String stringize(DSLExpression& expr) { return expr.release()->description(); }
static SkSL::String stringize(DSLPossibleExpression& expr) { return expr.release()->description(); }
static SkSL::String stringize(DSLBlock& blck) { return blck.release()->description(); }
static SkSL::String stringize(SkSL::IRNode& node) { return node.description(); }
static SkSL::String stringize(SkSL::Program& program) { return program.description(); }
template <typename T>
static void expect_equal(skiatest::Reporter* r, int lineNumber, T& input, const char* expected) {
SkSL::String actual = stringize(input);
if (!whitespace_insensitive_compare(expected, actual.c_str())) {
ERRORF(r, "(Failed on line %d)\nExpected: %s\n Actual: %s\n",
lineNumber, expected, actual.c_str());
}
}
template <typename T>
static void expect_equal(skiatest::Reporter* r, int lineNumber, T&& dsl, const char* expected) {
// This overload allows temporary values to be passed to expect_equal.
return expect_equal(r, lineNumber, dsl, expected);
}
#define EXPECT_EQUAL(a, b) expect_equal(r, __LINE__, (a), (b))
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLFlags, r, ctxInfo) {
{
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu(), no_mark_vars_declared());
EXPECT_EQUAL(All(GreaterThan(Float4(1), Float4(0))), "true");
Var x(kInt_Type, "x");
EXPECT_EQUAL(Declare(x), "int x;");
}
{
SkSL::ProgramSettings settings;
settings.fOptimize = false;
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu(), settings,
SkSL::ProgramKind::kFragment);
EXPECT_EQUAL(All(GreaterThan(Float4(1), Float4(0))),
"all(greaterThan(float4(1.0), float4(0.0)))");
}
{
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu(), SkSL::ProgramSettings());
Var x(kInt_Type, "x");
EXPECT_EQUAL(Declare(x), "int _0_x;");
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLFloat, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Expression e1 = Float(std::numeric_limits<float>::max());
REPORTER_ASSERT(r, atof(e1.release()->description().c_str()) ==
std::numeric_limits<float>::max());
Expression e2 = Float(std::numeric_limits<float>::min());
REPORTER_ASSERT(r, atof(e2.release()->description().c_str()) ==
std::numeric_limits<float>::min());
EXPECT_EQUAL(Float2(0),
"float2(0.0)");
EXPECT_EQUAL(Float2(-0.5, 1),
"float2(-0.5, 1.0)");
EXPECT_EQUAL(Float3(0.75),
"float3(0.75)");
EXPECT_EQUAL(Float3(Float2(0, 1), -2),
"float3(0.0, 1.0, -2.0)");
EXPECT_EQUAL(Float3(0, 1, 2),
"float3(0.0, 1.0, 2.0)");
EXPECT_EQUAL(Float4(0),
"float4(0.0)");
EXPECT_EQUAL(Float4(Float2(0, 1), Float2(2, 3)),
"float4(0.0, 1.0, 2.0, 3.0)");
EXPECT_EQUAL(Float4(0, 1, Float2(2, 3)),
"float4(0.0, 1.0, 2.0, 3.0)");
EXPECT_EQUAL(Float4(0, 1, 2, 3),
"float4(0.0, 1.0, 2.0, 3.0)");
DSLVar x(kFloat_Type, "x");
EXPECT_EQUAL(x = 1.0, "(x = 1.0)");
EXPECT_EQUAL(x = 1.0f, "(x = 1.0)");
DSLVar y(kFloat2_Type, "y");
EXPECT_EQUAL(y.x() = 1.0, "(y.x = 1.0)");
EXPECT_EQUAL(y.x() = 1.0f, "(y.x = 1.0)");
{
ExpectError error(r, "floating point value is infinite");
Float(std::numeric_limits<float>::infinity()).release();
}
{
ExpectError error(r, "floating point value is NaN");
Float(std::numeric_limits<float>::quiet_NaN()).release();
}
{
ExpectError error(r, "'float4' is not a valid parameter to 'float2' constructor; use '.xy' "
"instead");
Float2(Float4(1)).release();
}
{
ExpectError error(r, "invalid arguments to 'float4' constructor (expected 4 scalars, but "
"found 3)");
Float4(Float3(1)).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLHalf, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Expression e1 = Half(std::numeric_limits<float>::max());
REPORTER_ASSERT(r,
atof(e1.release()->description().c_str()) == std::numeric_limits<float>::max());
Expression e2 = Half(std::numeric_limits<float>::min());
REPORTER_ASSERT(r,
atof(e2.release()->description().c_str()) == std::numeric_limits<float>::min());
EXPECT_EQUAL(Half2(0),
"half2(0.0)");
EXPECT_EQUAL(Half2(-0.5, 1),
"half2(-0.5, 1.0)");
EXPECT_EQUAL(Half3(0.75),
"half3(0.75)");
EXPECT_EQUAL(Half3(Half2(0, 1), -2),
"half3(0.0, 1.0, -2.0)");
EXPECT_EQUAL(Half3(0, 1, 2),
"half3(0.0, 1.0, 2.0)");
EXPECT_EQUAL(Half4(0),
"half4(0.0)");
EXPECT_EQUAL(Half4(Half2(0, 1), Half2(2, 3)),
"half4(0.0, 1.0, 2.0, 3.0)");
EXPECT_EQUAL(Half4(0, 1, Half2(2, 3)),
"half4(0.0, 1.0, 2.0, 3.0)");
EXPECT_EQUAL(Half4(0, 1, 2, 3),
"half4(0.0, 1.0, 2.0, 3.0)");
{
ExpectError error(r, "floating point value is infinite");
Half(std::numeric_limits<float>::infinity()).release();
}
{
ExpectError error(r, "floating point value is NaN");
Half(std::numeric_limits<float>::quiet_NaN()).release();
}
{
ExpectError error(r, "'half4' is not a valid parameter to 'half2' constructor; use '.xy' "
"instead");
Half2(Half4(1)).release();
}
{
ExpectError error(r, "invalid arguments to 'half4' constructor (expected 4 scalars, but "
"found 3)");
Half4(Half3(1)).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLInt, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
EXPECT_EQUAL(Int(std::numeric_limits<int32_t>::max()),
"2147483647");
EXPECT_EQUAL(Int2(std::numeric_limits<int32_t>::min()),
"int2(-2147483648)");
EXPECT_EQUAL(Int2(0, 1),
"int2(0, 1)");
EXPECT_EQUAL(Int3(0),
"int3(0)");
EXPECT_EQUAL(Int3(Int2(0, 1), -2),
"int3(0, 1, -2)");
EXPECT_EQUAL(Int3(0, 1, 2),
"int3(0, 1, 2)");
EXPECT_EQUAL(Int4(0),
"int4(0)");
EXPECT_EQUAL(Int4(Int2(0, 1), Int2(2, 3)),
"int4(0, 1, 2, 3)");
EXPECT_EQUAL(Int4(0, 1, Int2(2, 3)),
"int4(0, 1, 2, 3)");
EXPECT_EQUAL(Int4(0, 1, 2, 3),
"int4(0, 1, 2, 3)");
{
ExpectError error(r, "'int4' is not a valid parameter to 'int2' constructor; use '.xy' "
"instead");
Int2(Int4(1)).release();
}
{
ExpectError error(r, "invalid arguments to 'int4' constructor (expected 4 scalars, but "
"found 3)");
Int4(Int3(1)).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLUInt, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
EXPECT_EQUAL(UInt(std::numeric_limits<uint32_t>::max()),
"4294967295");
EXPECT_EQUAL(UInt2(std::numeric_limits<uint32_t>::min()),
"uint2(0)");
EXPECT_EQUAL(UInt2(0, 1),
"uint2(0, 1)");
EXPECT_EQUAL(UInt3(0),
"uint3(0)");
EXPECT_EQUAL(UInt3(UInt2(0, 1), -2),
"uint3(0, 1, -2)");
EXPECT_EQUAL(UInt3(0, 1, 2),
"uint3(0, 1, 2)");
EXPECT_EQUAL(UInt4(0),
"uint4(0)");
EXPECT_EQUAL(UInt4(UInt2(0, 1), UInt2(2, 3)),
"uint4(0, 1, 2, 3)");
EXPECT_EQUAL(UInt4(0, 1, UInt2(2, 3)),
"uint4(0, 1, 2, 3)");
EXPECT_EQUAL(UInt4(0, 1, 2, 3),
"uint4(0, 1, 2, 3)");
{
ExpectError error(r, "'uint4' is not a valid parameter to 'uint2' constructor; use '.xy' "
"instead");
UInt2(UInt4(1)).release();
}
{
ExpectError error(r, "invalid arguments to 'uint4' constructor (expected 4 scalars, but "
"found 3)");
UInt4(UInt3(1)).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLShort, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
EXPECT_EQUAL(Short(std::numeric_limits<int16_t>::max()),
"32767");
EXPECT_EQUAL(Short2(std::numeric_limits<int16_t>::min()),
"short2(-32768)");
EXPECT_EQUAL(Short2(0, 1),
"short2(0, 1)");
EXPECT_EQUAL(Short3(0),
"short3(0)");
EXPECT_EQUAL(Short3(Short2(0, 1), -2),
"short3(0, 1, -2)");
EXPECT_EQUAL(Short3(0, 1, 2),
"short3(0, 1, 2)");
EXPECT_EQUAL(Short4(0),
"short4(0)");
EXPECT_EQUAL(Short4(Short2(0, 1), Short2(2, 3)),
"short4(0, 1, 2, 3)");
EXPECT_EQUAL(Short4(0, 1, Short2(2, 3)),
"short4(0, 1, 2, 3)");
EXPECT_EQUAL(Short4(0, 1, 2, 3),
"short4(0, 1, 2, 3)");
{
ExpectError error(r, "'short4' is not a valid parameter to 'short2' constructor; use '.xy' "
"instead");
Short2(Short4(1)).release();
}
{
ExpectError error(r, "invalid arguments to 'short4' constructor (expected 4 scalars, but "
"found 3)");
Short4(Short3(1)).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLUShort, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
EXPECT_EQUAL(UShort(std::numeric_limits<uint16_t>::max()),
"65535");
EXPECT_EQUAL(UShort2(std::numeric_limits<uint16_t>::min()),
"ushort2(0)");
EXPECT_EQUAL(UShort2(0, 1),
"ushort2(0, 1)");
EXPECT_EQUAL(UShort3(0),
"ushort3(0)");
EXPECT_EQUAL(UShort3(UShort2(0, 1), -2),
"ushort3(0, 1, -2)");
EXPECT_EQUAL(UShort3(0, 1, 2),
"ushort3(0, 1, 2)");
EXPECT_EQUAL(UShort4(0),
"ushort4(0)");
EXPECT_EQUAL(UShort4(UShort2(0, 1), UShort2(2, 3)),
"ushort4(0, 1, 2, 3)");
EXPECT_EQUAL(UShort4(0, 1, UShort2(2, 3)),
"ushort4(0, 1, 2, 3)");
EXPECT_EQUAL(UShort4(0, 1, 2, 3),
"ushort4(0, 1, 2, 3)");
{
ExpectError error(r, "'ushort4' is not a valid parameter to 'ushort2' constructor; use "
"'.xy' instead");
UShort2(UShort4(1)).release();
}
{
ExpectError error(r, "invalid arguments to 'ushort4' constructor (expected 4 scalars, but "
"found 3)");
UShort4(UShort3(1)).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLBool, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
EXPECT_EQUAL(Bool2(false),
"bool2(false)");
EXPECT_EQUAL(Bool2(false, true),
"bool2(false, true)");
EXPECT_EQUAL(Bool3(false),
"bool3(false)");
EXPECT_EQUAL(Bool3(Bool2(false, true), false),
"bool3(false, true, false)");
EXPECT_EQUAL(Bool3(false, true, false),
"bool3(false, true, false)");
EXPECT_EQUAL(Bool4(false),
"bool4(false)");
EXPECT_EQUAL(Bool4(Bool2(false, true), Bool2(false, true)),
"bool4(false, true, false, true)");
EXPECT_EQUAL(Bool4(false, true, Bool2(false, true)),
"bool4(false, true, false, true)");
EXPECT_EQUAL(Bool4(false, true, false, true),
"bool4(false, true, false, true)");
{
ExpectError error(r, "'bool4' is not a valid parameter to 'bool2' constructor; use '.xy' "
"instead");
Bool2(Bool4(true)).release();
}
{
ExpectError error(r, "invalid arguments to 'bool4' constructor (expected 4 scalars, but "
"found 3)");
Bool4(Bool3(true)).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLType, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
REPORTER_ASSERT(r, DSLType(kBool_Type).isBoolean());
REPORTER_ASSERT(r, !DSLType(kBool_Type).isNumber());
REPORTER_ASSERT(r, !DSLType(kBool_Type).isFloat());
REPORTER_ASSERT(r, !DSLType(kBool_Type).isSigned());
REPORTER_ASSERT(r, !DSLType(kBool_Type).isUnsigned());
REPORTER_ASSERT(r, !DSLType(kBool_Type).isInteger());
REPORTER_ASSERT(r, DSLType(kBool_Type).isScalar());
REPORTER_ASSERT(r, !DSLType(kBool_Type).isVector());
REPORTER_ASSERT(r, !DSLType(kBool_Type).isMatrix());
REPORTER_ASSERT(r, !DSLType(kBool_Type).isArray());
REPORTER_ASSERT(r, !DSLType(kBool_Type).isStruct());
REPORTER_ASSERT(r, !DSLType(kInt_Type).isBoolean());
REPORTER_ASSERT(r, DSLType(kInt_Type).isNumber());
REPORTER_ASSERT(r, !DSLType(kInt_Type).isFloat());
REPORTER_ASSERT(r, DSLType(kInt_Type).isSigned());
REPORTER_ASSERT(r, !DSLType(kInt_Type).isUnsigned());
REPORTER_ASSERT(r, DSLType(kInt_Type).isInteger());
REPORTER_ASSERT(r, DSLType(kInt_Type).isScalar());
REPORTER_ASSERT(r, !DSLType(kInt_Type).isVector());
REPORTER_ASSERT(r, !DSLType(kInt_Type).isMatrix());
REPORTER_ASSERT(r, !DSLType(kInt_Type).isArray());
REPORTER_ASSERT(r, !DSLType(kInt_Type).isStruct());
REPORTER_ASSERT(r, !DSLType(kUInt_Type).isBoolean());
REPORTER_ASSERT(r, DSLType(kUInt_Type).isNumber());
REPORTER_ASSERT(r, !DSLType(kUInt_Type).isFloat());
REPORTER_ASSERT(r, !DSLType(kUInt_Type).isSigned());
REPORTER_ASSERT(r, DSLType(kUInt_Type).isUnsigned());
REPORTER_ASSERT(r, DSLType(kUInt_Type).isInteger());
REPORTER_ASSERT(r, DSLType(kUInt_Type).isScalar());
REPORTER_ASSERT(r, !DSLType(kUInt_Type).isVector());
REPORTER_ASSERT(r, !DSLType(kUInt_Type).isMatrix());
REPORTER_ASSERT(r, !DSLType(kUInt_Type).isArray());
REPORTER_ASSERT(r, !DSLType(kUInt_Type).isStruct());
REPORTER_ASSERT(r, !DSLType(kFloat_Type).isBoolean());
REPORTER_ASSERT(r, DSLType(kFloat_Type).isNumber());
REPORTER_ASSERT(r, DSLType(kFloat_Type).isFloat());
REPORTER_ASSERT(r, !DSLType(kFloat_Type).isSigned());
REPORTER_ASSERT(r, !DSLType(kFloat_Type).isUnsigned());
REPORTER_ASSERT(r, !DSLType(kFloat_Type).isInteger());
REPORTER_ASSERT(r, DSLType(kFloat_Type).isScalar());
REPORTER_ASSERT(r, !DSLType(kFloat_Type).isVector());
REPORTER_ASSERT(r, !DSLType(kFloat_Type).isMatrix());
REPORTER_ASSERT(r, !DSLType(kFloat_Type).isArray());
REPORTER_ASSERT(r, !DSLType(kFloat_Type).isStruct());
REPORTER_ASSERT(r, !DSLType(kFloat2_Type).isBoolean());
REPORTER_ASSERT(r, !DSLType(kFloat2_Type).isNumber());
REPORTER_ASSERT(r, !DSLType(kFloat2_Type).isFloat());
REPORTER_ASSERT(r, !DSLType(kFloat2_Type).isSigned());
REPORTER_ASSERT(r, !DSLType(kFloat2_Type).isUnsigned());
REPORTER_ASSERT(r, !DSLType(kFloat2_Type).isInteger());
REPORTER_ASSERT(r, !DSLType(kFloat2_Type).isScalar());
REPORTER_ASSERT(r, DSLType(kFloat2_Type).isVector());
REPORTER_ASSERT(r, !DSLType(kFloat2_Type).isMatrix());
REPORTER_ASSERT(r, !DSLType(kFloat2_Type).isArray());
REPORTER_ASSERT(r, !DSLType(kFloat2_Type).isStruct());
REPORTER_ASSERT(r, !DSLType(kHalf2x2_Type).isBoolean());
REPORTER_ASSERT(r, !DSLType(kHalf2x2_Type).isNumber());
REPORTER_ASSERT(r, !DSLType(kHalf2x2_Type).isFloat());
REPORTER_ASSERT(r, !DSLType(kHalf2x2_Type).isSigned());
REPORTER_ASSERT(r, !DSLType(kHalf2x2_Type).isUnsigned());
REPORTER_ASSERT(r, !DSLType(kHalf2x2_Type).isInteger());
REPORTER_ASSERT(r, !DSLType(kHalf2x2_Type).isScalar());
REPORTER_ASSERT(r, !DSLType(kHalf2x2_Type).isVector());
REPORTER_ASSERT(r, DSLType(kHalf2x2_Type).isMatrix());
REPORTER_ASSERT(r, !DSLType(kHalf2x2_Type).isArray());
REPORTER_ASSERT(r, !DSLType(kHalf2x2_Type).isStruct());
REPORTER_ASSERT(r, !DSLType(Array(kFloat_Type, 2)).isBoolean());
REPORTER_ASSERT(r, !DSLType(Array(kFloat_Type, 2)).isNumber());
REPORTER_ASSERT(r, !DSLType(Array(kFloat_Type, 2)).isFloat());
REPORTER_ASSERT(r, !DSLType(Array(kFloat_Type, 2)).isSigned());
REPORTER_ASSERT(r, !DSLType(Array(kFloat_Type, 2)).isUnsigned());
REPORTER_ASSERT(r, !DSLType(Array(kFloat_Type, 2)).isInteger());
REPORTER_ASSERT(r, !DSLType(Array(kFloat_Type, 2)).isScalar());
REPORTER_ASSERT(r, !DSLType(Array(kFloat_Type, 2)).isVector());
REPORTER_ASSERT(r, !DSLType(Array(kFloat_Type, 2)).isMatrix());
REPORTER_ASSERT(r, DSLType(Array(kFloat_Type, 2)).isArray());
REPORTER_ASSERT(r, !DSLType(Array(kFloat_Type, 2)).isStruct());
Var x(kFloat_Type);
DSLExpression e = x + 1;
REPORTER_ASSERT(r, e.type().isFloat());
e.release();
{
ExpectError error(r, "array size must be positive");
Array(kFloat_Type, -1);
}
{
ExpectError error(r, "multi-dimensional arrays are not supported");
Array(Array(kFloat_Type, 2), 2);
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLMatrices, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Var f22(kFloat2x2_Type, "f22");
EXPECT_EQUAL(f22 = Float2x2(1), "(f22 = float2x2(1.0))");
Var f32(kFloat3x2_Type, "f32");
EXPECT_EQUAL(f32 = Float3x2(1, 2, 3, 4, 5, 6),
"(f32 = float3x2(1.0, 2.0, 3.0, 4.0, 5.0, 6.0))");
Var f42(kFloat4x2_Type, "f42");
EXPECT_EQUAL(f42 = Float4x2(Float4(1, 2, 3, 4), 5, 6, 7, 8),
"(f42 = float4x2(1.0, 2.0, 3.0, 4.0, 5.0, 6.0, 7.0, 8.0))");
Var f23(kFloat2x3_Type, "f23");
EXPECT_EQUAL(f23 = Float2x3(1, Float2(2, 3), 4, Float2(5, 6)),
"(f23 = float2x3(1.0, 2.0, 3.0, 4.0, 5.0, 6.0))");
Var f33(kFloat3x3_Type, "f33");
EXPECT_EQUAL(f33 = Float3x3(Float3(1, 2, 3), 4, Float2(5, 6), 7, 8, 9),
"(f33 = float3x3(1.0, 2.0, 3.0, 4.0, 5.0, 6.0, 7.0, 8.0, 9.0))");
Var f43(kFloat4x3_Type, "f43");
EXPECT_EQUAL(f43 = Float4x3(Float4(1, 2, 3, 4), Float4(5, 6, 7, 8), Float4(9, 10, 11, 12)),
"(f43 = float4x3(1.0, 2.0, 3.0, 4.0, 5.0, 6.0, 7.0, 8.0, 9.0, 10.0, 11.0, 12.0))");
Var f24(kFloat2x4_Type, "f24");
EXPECT_EQUAL(f24 = Float2x4(1, 2, 3, 4, 5, 6, 7, 8),
"(f24 = float2x4(1.0, 2.0, 3.0, 4.0, 5.0, 6.0, 7.0, 8.0))");
Var f34(kFloat3x4_Type, "f34");
EXPECT_EQUAL(f34 = Float3x4(1, 2, 3, 4, 5, 6, 7, 8, 9, Float3(10, 11, 12)),
"(f34 = float3x4(1.0, 2.0, 3.0, 4.0, 5.0, 6.0, 7.0, 8.0, 9.0, 10.0, 11.0, 12.0))");
Var f44(kFloat4x4_Type, "f44");
EXPECT_EQUAL(f44 = Float4x4(1), "(f44 = float4x4(1.0))");
Var h22(kHalf2x2_Type, "h22");
EXPECT_EQUAL(h22 = Half2x2(1), "(h22 = half2x2(1.0))");
Var h32(kHalf3x2_Type, "h32");
EXPECT_EQUAL(h32 = Half3x2(1, 2, 3, 4, 5, 6),
"(h32 = half3x2(1.0, 2.0, 3.0, 4.0, 5.0, 6.0))");
Var h42(kHalf4x2_Type, "h42");
EXPECT_EQUAL(h42 = Half4x2(Half4(1, 2, 3, 4), 5, 6, 7, 8),
"(h42 = half4x2(1.0, 2.0, 3.0, 4.0, 5.0, 6.0, 7.0, 8.0))");
Var h23(kHalf2x3_Type, "h23");
EXPECT_EQUAL(h23 = Half2x3(1, Half2(2, 3), 4, Half2(5, 6)),
"(h23 = half2x3(1.0, 2.0, 3.0, 4.0, 5.0, 6.0))");
Var h33(kHalf3x3_Type, "h33");
EXPECT_EQUAL(h33 = Half3x3(Half3(1, 2, 3), 4, Half2(5, 6), 7, 8, 9),
"(h33 = half3x3(1.0, 2.0, 3.0, 4.0, 5.0, 6.0, 7.0, 8.0, 9.0))");
Var h43(kHalf4x3_Type, "h43");
EXPECT_EQUAL(h43 = Half4x3(Half4(1, 2, 3, 4), Half4(5, 6, 7, 8), Half4(9, 10, 11, 12)),
"(h43 = half4x3(1.0, 2.0, 3.0, 4.0, 5.0, 6.0, 7.0, 8.0, 9.0, 10.0, 11.0, 12.0))");
Var h24(kHalf2x4_Type, "h24");
EXPECT_EQUAL(h24 = Half2x4(1, 2, 3, 4, 5, 6, 7, 8),
"(h24 = half2x4(1.0, 2.0, 3.0, 4.0, 5.0, 6.0, 7.0, 8.0))");
Var h34(kHalf3x4_Type, "h34");
EXPECT_EQUAL(h34 = Half3x4(1, 2, 3, 4, 5, 6, 7, 8, 9, Half3(10, 11, 12)),
"(h34 = half3x4(1.0, 2.0, 3.0, 4.0, 5.0, 6.0, 7.0, 8.0, 9.0, 10.0, 11.0, 12.0))");
Var h44(kHalf4x4_Type, "h44");
EXPECT_EQUAL(h44 = Half4x4(1), "(h44 = half4x4(1.0))");
EXPECT_EQUAL(f22 * 2, "(f22 * 2.0)");
EXPECT_EQUAL(f22 == Float2x2(1), "(f22 == float2x2(1.0))");
EXPECT_EQUAL(h42[0][1], "h42[0].y");
EXPECT_EQUAL(f43 * Float4(0), "(f43 * float4(0.0))");
EXPECT_EQUAL(h23 * 2, "(h23 * 2.0)");
EXPECT_EQUAL(Inverse(f44), "inverse(f44)");
{
ExpectError error(r, "invalid arguments to 'float3x3' constructor (expected 9 scalars, but "
"found 2)");
DSLExpression(Float3x3(Float2(1))).release();
}
{
ExpectError error(r, "invalid arguments to 'half2x2' constructor (expected 4 scalars, but "
"found 5)");
DSLExpression(Half2x2(1, 2, 3, 4, 5)).release();
}
{
ExpectError error(r, "type mismatch: '*' cannot operate on 'float4x3', 'float3'");
DSLExpression(f43 * Float3(1)).release();
}
{
ExpectError error(r, "type mismatch: '=' cannot operate on 'float4x3', 'float3x3'");
DSLExpression(f43 = f33).release();
}
{
ExpectError error(r, "type mismatch: '=' cannot operate on 'half2x2', 'float2x2'");
DSLExpression(h22 = f22).release();
}
{
ExpectError error(r, "no match for inverse(float4x3)");
DSLExpression(Inverse(f43)).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLPlus, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Var a(kFloat_Type, "a"), b(kFloat_Type, "b");
EXPECT_EQUAL(a + b,
"(a + b)");
EXPECT_EQUAL(a + 1,
"(a + 1.0)");
EXPECT_EQUAL(0.5 + a + -99,
"((0.5 + a) + -99.0)");
EXPECT_EQUAL(a += b + 1,
"(a += (b + 1.0))");
EXPECT_EQUAL(+a,
"a");
EXPECT_EQUAL(+(a + b),
"(a + b)");
{
ExpectError error(r, "type mismatch: '+' cannot operate on 'bool2', 'float'");
DSLExpression((Bool2(true) + a)).release();
}
{
ExpectError error(r, "type mismatch: '+=' cannot operate on 'float', 'bool2'");
DSLExpression((a += Bool2(true))).release();
}
{
ExpectError error(r, "cannot assign to this expression");
DSLExpression((1.0 += a)).release();
}
{
ExpectError error(r, "'+' cannot operate on 'bool'");
Var c(kBool_Type);
DSLExpression(+c).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLMinus, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Var a(kInt_Type, "a"), b(kInt_Type, "b");
EXPECT_EQUAL(a - b,
"(a - b)");
EXPECT_EQUAL(a - 1,
"(a - 1)");
EXPECT_EQUAL(2 - a - b,
"((2 - a) - b)");
EXPECT_EQUAL(a -= b + 1,
"(a -= (b + 1))");
EXPECT_EQUAL(-a,
"-a");
EXPECT_EQUAL(-(a - b),
"-(a - b)");
{
ExpectError error(r, "type mismatch: '-' cannot operate on 'bool2', 'int'");
DSLExpression(Bool2(true) - a).release();
}
{
ExpectError error(r, "type mismatch: '-=' cannot operate on 'int', 'bool2'");
DSLExpression(a -= Bool2(true)).release();
}
{
ExpectError error(r, "cannot assign to this expression");
DSLExpression(1.0 -= a).release();
}
{
ExpectError error(r, "'-' cannot operate on 'bool'");
Var c(kBool_Type);
DSLExpression(-c).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLMultiply, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Var a(kFloat_Type, "a"), b(kFloat_Type, "b");
EXPECT_EQUAL(a * b,
"(a * b)");
EXPECT_EQUAL(a * 2,
"(a * 2.0)");
EXPECT_EQUAL(0.5 * a * -99,
"((0.5 * a) * -99.0)");
EXPECT_EQUAL(a *= b + 1,
"(a *= (b + 1.0))");
{
ExpectError error(r, "type mismatch: '*' cannot operate on 'bool2', 'float'");
DSLExpression(Bool2(true) * a).release();
}
{
ExpectError error(r, "type mismatch: '*=' cannot operate on 'float', 'bool2'");
DSLExpression(a *= Bool2(true)).release();
}
{
ExpectError error(r, "cannot assign to this expression");
DSLExpression(1.0 *= a).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLDivide, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Var a(kFloat_Type, "a"), b(kFloat_Type, "b");
EXPECT_EQUAL(a / b,
"(a / b)");
EXPECT_EQUAL(a / 2,
"(a / 2.0)");
EXPECT_EQUAL(0.5 / a / -99,
"((0.5 / a) / -99.0)");
EXPECT_EQUAL(b / (a - 1),
"(b / (a - 1.0))");
EXPECT_EQUAL(a /= b + 1,
"(a /= (b + 1.0))");
{
ExpectError error(r, "type mismatch: '/' cannot operate on 'bool2', 'float'");
DSLExpression(Bool2(true) / a).release();
}
{
ExpectError error(r, "type mismatch: '/=' cannot operate on 'float', 'bool2'");
DSLExpression(a /= Bool2(true)).release();
}
{
ExpectError error(r, "cannot assign to this expression");
DSLExpression(1.0 /= a).release();
}
{
ExpectError error(r, "division by zero");
DSLExpression(a /= 0).release();
}
{
Var c(kFloat2_Type, "c");
ExpectError error(r, "division by zero");
DSLExpression(c /= Float2(Float(0), 1)).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLMod, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Var a(kInt_Type, "a"), b(kInt_Type, "b");
Expression e1 = a % b;
EXPECT_EQUAL(e1, "(a % b)");
Expression e2 = a % 2;
EXPECT_EQUAL(e2, "(a % 2)");
Expression e3 = 10 % a % -99;
EXPECT_EQUAL(e3, "((10 % a) % -99)");
Expression e4 = a %= b + 1;
EXPECT_EQUAL(e4, "(a %= (b + 1))");
{
ExpectError error(r, "type mismatch: '%' cannot operate on 'bool2', 'int'");
DSLExpression(Bool2(true) % a).release();
}
{
ExpectError error(r, "type mismatch: '%=' cannot operate on 'int', 'bool2'");
DSLExpression(a %= Bool2(true)).release();
}
{
ExpectError error(r, "cannot assign to this expression");
DSLExpression(1 %= a).release();
}
{
ExpectError error(r, "division by zero");
DSLExpression(a %= 0).release();
}
{
Var c(kInt2_Type, "c");
ExpectError error(r, "division by zero");
DSLExpression(c %= Int2(Int(0), 1)).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLShl, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Var a(kInt_Type, "a"), b(kInt_Type, "b");
Expression e1 = a << b;
EXPECT_EQUAL(e1, "(a << b)");
Expression e2 = a << 1;
EXPECT_EQUAL(e2, "(a << 1)");
Expression e3 = 1 << a << 2;
EXPECT_EQUAL(e3, "((1 << a) << 2)");
Expression e4 = a <<= b + 1;
EXPECT_EQUAL(e4, "(a <<= (b + 1))");
{
ExpectError error(r, "type mismatch: '<<' cannot operate on 'bool2', 'int'");
DSLExpression(Bool2(true) << a).release();
}
{
ExpectError error(r, "type mismatch: '<<=' cannot operate on 'int', 'bool2'");
DSLExpression(a <<= Bool2(true)).release();
}
{
ExpectError error(r, "cannot assign to this expression");
DSLExpression(1 <<= a).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLShr, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Var a(kInt_Type, "a"), b(kInt_Type, "b");
Expression e1 = a >> b;
EXPECT_EQUAL(e1, "(a >> b)");
Expression e2 = a >> 1;
EXPECT_EQUAL(e2, "(a >> 1)");
Expression e3 = 1 >> a >> 2;
EXPECT_EQUAL(e3, "((1 >> a) >> 2)");
Expression e4 = a >>= b + 1;
EXPECT_EQUAL(e4, "(a >>= (b + 1))");
{
ExpectError error(r, "type mismatch: '>>' cannot operate on 'bool2', 'int'");
DSLExpression(Bool2(true) >> a).release();
}
{
ExpectError error(r, "type mismatch: '>>=' cannot operate on 'int', 'bool2'");
DSLExpression(a >>= Bool2(true)).release();
}
{
ExpectError error(r, "cannot assign to this expression");
DSLExpression(1 >>= a).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLBitwiseAnd, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Var a(kInt_Type, "a"), b(kInt_Type, "b");
Expression e1 = a & b;
EXPECT_EQUAL(e1, "(a & b)");
Expression e2 = a & 1;
EXPECT_EQUAL(e2, "(a & 1)");
Expression e3 = 1 & a & 2;
EXPECT_EQUAL(e3, "((1 & a) & 2)");
Expression e4 = a &= b + 1;
EXPECT_EQUAL(e4, "(a &= (b + 1))");
{
ExpectError error(r, "type mismatch: '&' cannot operate on 'bool2', 'int'");
DSLExpression(Bool2(true) & a).release();
}
{
ExpectError error(r, "type mismatch: '&=' cannot operate on 'int', 'bool2'");
DSLExpression(a &= Bool2(true)).release();
}
{
ExpectError error(r, "cannot assign to this expression");
DSLExpression(1 &= a).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLBitwiseOr, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Var a(kInt_Type, "a"), b(kInt_Type, "b");
Expression e1 = a | b;
EXPECT_EQUAL(e1, "(a | b)");
Expression e2 = a | 1;
EXPECT_EQUAL(e2, "(a | 1)");
Expression e3 = 1 | a | 2;
EXPECT_EQUAL(e3, "((1 | a) | 2)");
Expression e4 = a |= b + 1;
EXPECT_EQUAL(e4, "(a |= (b + 1))");
{
ExpectError error(r, "type mismatch: '|' cannot operate on 'bool2', 'int'");
DSLExpression(Bool2(true) | a).release();
}
{
ExpectError error(r, "type mismatch: '|=' cannot operate on 'int', 'bool2'");
DSLExpression(a |= Bool2(true)).release();
}
{
ExpectError error(r, "cannot assign to this expression");
DSLExpression(1 |= a).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLBitwiseXor, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Var a(kInt_Type, "a"), b(kInt_Type, "b");
Expression e1 = a ^ b;
EXPECT_EQUAL(e1, "(a ^ b)");
Expression e2 = a ^ 1;
EXPECT_EQUAL(e2, "(a ^ 1)");
Expression e3 = 1 ^ a ^ 2;
EXPECT_EQUAL(e3, "((1 ^ a) ^ 2)");
Expression e4 = a ^= b + 1;
EXPECT_EQUAL(e4, "(a ^= (b + 1))");
{
ExpectError error(r, "type mismatch: '^' cannot operate on 'bool2', 'int'");
DSLExpression(Bool2(true) ^ a).release();
}
{
ExpectError error(r, "type mismatch: '^=' cannot operate on 'int', 'bool2'");
DSLExpression(a ^= Bool2(true)).release();
}
{
ExpectError error(r, "cannot assign to this expression");
DSLExpression(1 ^= a).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLLogicalAnd, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Var a(kBool_Type, "a"), b(kBool_Type, "b");
Expression e1 = a && b;
EXPECT_EQUAL(e1, "(a && b)");
Expression e2 = a && true && b;
EXPECT_EQUAL(e2, "(a && b)");
Expression e3 = a && false && b;
EXPECT_EQUAL(e3, "false");
{
ExpectError error(r, "type mismatch: '&&' cannot operate on 'bool', 'int'");
DSLExpression(a && 5).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLLogicalOr, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Var a(kBool_Type, "a"), b(kBool_Type, "b");
Expression e1 = a || b;
EXPECT_EQUAL(e1, "(a || b)");
Expression e2 = a || true || b;
EXPECT_EQUAL(e2, "true");
Expression e3 = a || false || b;
EXPECT_EQUAL(e3, "(a || b)");
{
ExpectError error(r, "type mismatch: '||' cannot operate on 'bool', 'int'");
DSLExpression(a || 5).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLLogicalXor, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Var a(kBool_Type, "a"), b(kBool_Type, "b");
Expression e1 = LogicalXor(a, b);
EXPECT_EQUAL(e1, "(a ^^ b)");
{
ExpectError error(r, "type mismatch: '^^' cannot operate on 'bool', 'int'");
DSLExpression(LogicalXor(a, 5)).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLComma, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Var a(kInt_Type, "a"), b(kInt_Type, "b");
Expression e1 = (a += b, b);
EXPECT_EQUAL(e1, "((a += b) , b)");
Expression e2 = (a += b, b += b, Int2(a));
EXPECT_EQUAL(e2, "(((a += b) , (b += b)) , int2(a))");
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLEqual, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Var a(kInt_Type, "a"), b(kInt_Type, "b");
Expression e1 = a == b;
EXPECT_EQUAL(e1, "(a == b)");
Expression e2 = a == 5;
EXPECT_EQUAL(e2, "(a == 5)");
{
ExpectError error(r, "type mismatch: '==' cannot operate on 'int', 'bool2'");
DSLExpression(a == Bool2(true)).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLNotEqual, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Var a(kInt_Type, "a"), b(kInt_Type, "b");
Expression e1 = a != b;
EXPECT_EQUAL(e1, "(a != b)");
Expression e2 = a != 5;
EXPECT_EQUAL(e2, "(a != 5)");
{
ExpectError error(r, "type mismatch: '!=' cannot operate on 'int', 'bool2'");
DSLExpression(a != Bool2(true)).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLGreaterThan, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Var a(kInt_Type, "a"), b(kInt_Type, "b");
Expression e1 = a > b;
EXPECT_EQUAL(e1, "(a > b)");
Expression e2 = a > 5;
EXPECT_EQUAL(e2, "(a > 5)");
{
ExpectError error(r, "type mismatch: '>' cannot operate on 'int', 'bool2'");
DSLExpression(a > Bool2(true)).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLGreaterThanOrEqual, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Var a(kInt_Type, "a"), b(kInt_Type, "b");
Expression e1 = a >= b;
EXPECT_EQUAL(e1, "(a >= b)");
Expression e2 = a >= 5;
EXPECT_EQUAL(e2, "(a >= 5)");
{
ExpectError error(r, "type mismatch: '>=' cannot operate on 'int', 'bool2'");
DSLExpression(a >= Bool2(true)).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLLessThan, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Var a(kInt_Type, "a"), b(kInt_Type, "b");
Expression e1 = a < b;
EXPECT_EQUAL(e1, "(a < b)");
Expression e2 = a < 5;
EXPECT_EQUAL(e2, "(a < 5)");
{
ExpectError error(r, "type mismatch: '<' cannot operate on 'int', 'bool2'");
DSLExpression(a < Bool2(true)).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLLessThanOrEqual, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Var a(kInt_Type, "a"), b(kInt_Type, "b");
Expression e1 = a <= b;
EXPECT_EQUAL(e1, "(a <= b)");
Expression e2 = a <= 5;
EXPECT_EQUAL(e2, "(a <= 5)");
{
ExpectError error(r, "type mismatch: '<=' cannot operate on 'int', 'bool2'");
DSLExpression(a <= Bool2(true)).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLLogicalNot, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Var a(kInt_Type, "a"), b(kInt_Type, "b");
Expression e1 = !(a <= b);
EXPECT_EQUAL(e1, "!(a <= b)");
{
ExpectError error(r, "'!' cannot operate on 'int'");
DSLExpression(!a).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLBitwiseNot, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Var a(kInt_Type, "a"), b(kBool_Type, "b");
Expression e1 = ~a;
EXPECT_EQUAL(e1, "~a");
{
ExpectError error(r, "'~' cannot operate on 'bool'");
DSLExpression(~b).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLIncrement, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Var a(kInt_Type, "a"), b(kBool_Type, "b");
Expression e1 = ++a;
EXPECT_EQUAL(e1, "++a");
Expression e2 = a++;
EXPECT_EQUAL(e2, "a++");
{
ExpectError error(r, "'++' cannot operate on 'bool'");
DSLExpression(++b).release();
}
{
ExpectError error(r, "'++' cannot operate on 'bool'");
DSLExpression(b++).release();
}
{
ExpectError error(r, "cannot assign to this expression");
DSLExpression(++(a + 1)).release();
}
{
ExpectError error(r, "cannot assign to this expression");
DSLExpression((a + 1)++).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLDecrement, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Var a(kInt_Type, "a"), b(kBool_Type, "b");
Expression e1 = --a;
EXPECT_EQUAL(e1, "--a");
Expression e2 = a--;
EXPECT_EQUAL(e2, "a--");
{
ExpectError error(r, "'--' cannot operate on 'bool'");
DSLExpression(--b).release();
}
{
ExpectError error(r, "'--' cannot operate on 'bool'");
DSLExpression(b--).release();
}
{
ExpectError error(r, "cannot assign to this expression");
DSLExpression(--(a + 1)).release();
}
{
ExpectError error(r, "cannot assign to this expression");
DSLExpression((a + 1)--).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLCall, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
{
DSLExpression sqrt(SkSL::ThreadContext::Compiler().convertIdentifier(/*line=*/-1, "sqrt"));
SkTArray<DSLWrapper<DSLExpression>> args;
args.emplace_back(16);
EXPECT_EQUAL(sqrt(std::move(args)), "4.0"); // sqrt(16) gets optimized to 4
}
{
DSLExpression pow(SkSL::ThreadContext::Compiler().convertIdentifier(/*line=*/-1, "pow"));
DSLVar a(kFloat_Type, "a");
DSLVar b(kFloat_Type, "b");
SkTArray<DSLWrapper<DSLExpression>> args;
args.emplace_back(a);
args.emplace_back(b);
EXPECT_EQUAL(pow(std::move(args)), "pow(a, b)");
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLBlock, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu(), no_mark_vars_declared());
EXPECT_EQUAL(Block(), "{ }");
Var a(kInt_Type, "a", 1), b(kInt_Type, "b", 2);
EXPECT_EQUAL(Block(Declare(a), Declare(b), a = b), "{ int a = 1; int b = 2; (a = b); }");
EXPECT_EQUAL((If(a > 0, --a), ++b), "if ((a > 0)) --a; ++b;");
SkTArray<DSLStatement> statements;
statements.push_back(a = 0);
statements.push_back(++a);
EXPECT_EQUAL(Block(std::move(statements)), "{ (a = 0); ++a; }");
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLBreak, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu(), no_mark_vars_declared());
Var i(kInt_Type, "i", 0);
DSLFunction(kVoid_Type, "success").define(
For(Declare(i), i < 10, ++i, Block(
If(i > 5, Break())
))
);
REPORTER_ASSERT(r, SkSL::ThreadContext::ProgramElements().size() == 1);
EXPECT_EQUAL(*SkSL::ThreadContext::ProgramElements()[0],
"void success() { for (int i = 0; (i < 10); ++i) { if ((i > 5)) break; } }");
{
ExpectError error(r, "break statement must be inside a loop or switch");
DSLFunction(kVoid_Type, "fail").define(
Break()
);
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLContinue, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu(), no_mark_vars_declared());
Var i(kInt_Type, "i", 0);
DSLFunction(kVoid_Type, "success").define(
For(Declare(i), i < 10, ++i, Block(
If(i < 5, Continue())
))
);
REPORTER_ASSERT(r, SkSL::ThreadContext::ProgramElements().size() == 1);
EXPECT_EQUAL(*SkSL::ThreadContext::ProgramElements()[0],
"void success() { for (int i = 0; (i < 10); ++i) { if ((i < 5)) continue; } }");
{
ExpectError error(r, "continue statement must be inside a loop");
DSLFunction(kVoid_Type, "fail").define(
Continue()
);
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLDeclare, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu(), no_mark_vars_declared());
{
Var a(kHalf4_Type, "a"), b(kHalf4_Type, "b", Half4(1));
EXPECT_EQUAL(Declare(a), "half4 a;");
EXPECT_EQUAL(Declare(b), "half4 b = half4(1.0);");
}
{
DSLWriter::Reset();
SkTArray<Var> vars;
vars.push_back(Var(kBool_Type, "a", true));
vars.push_back(Var(kFloat_Type, "b"));
EXPECT_EQUAL(Declare(vars), "bool a = true; float b;");
}
{
DSLWriter::Reset();
REPORTER_ASSERT(r, SkSL::ThreadContext::ProgramElements().empty());
GlobalVar a(kHalf4_Type, "a"), b(kHalf4_Type, "b", Half4(1));
Declare(a);
Declare(b);
REPORTER_ASSERT(r, SkSL::ThreadContext::ProgramElements().size() == 2);
EXPECT_EQUAL(*SkSL::ThreadContext::ProgramElements()[0], "half4 a;");
EXPECT_EQUAL(*SkSL::ThreadContext::ProgramElements()[1], "half4 b = half4(1.0);");
}
{
DSLWriter::Reset();
REPORTER_ASSERT(r, SkSL::ThreadContext::ProgramElements().empty());
SkTArray<GlobalVar> vars;
vars.push_back(GlobalVar(kHalf4_Type, "a"));
vars.push_back(GlobalVar(kHalf4_Type, "b", Half4(1)));
Declare(vars);
REPORTER_ASSERT(r, SkSL::ThreadContext::ProgramElements().size() == 2);
EXPECT_EQUAL(*SkSL::ThreadContext::ProgramElements()[0], "half4 a;");
EXPECT_EQUAL(*SkSL::ThreadContext::ProgramElements()[1], "half4 b = half4(1.0);");
}
{
DSLWriter::Reset();
Var a(kHalf4_Type, "a", 1);
ExpectError error(r, "expected 'half4', but found 'int'");
Declare(a).release();
}
{
DSLWriter::Reset();
Var a(kInt_Type, "a");
Declare(a).release();
ExpectError error(r, "variable has already been declared");
Declare(a).release();
}
{
DSLWriter::Reset();
Var a(kUniform_Modifier, kInt_Type, "a");
ExpectError error(r, "'uniform' is not permitted here");
Declare(a).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLDeclareGlobal, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu(), no_mark_vars_declared());
DSLGlobalVar x(kInt_Type, "x", 0);
Declare(x);
DSLGlobalVar y(kUniform_Modifier, kFloat2_Type, "y");
Declare(y);
REPORTER_ASSERT(r, SkSL::ThreadContext::ProgramElements().size() == 2);
EXPECT_EQUAL(*SkSL::ThreadContext::ProgramElements()[0], "int x = 0;");
EXPECT_EQUAL(*SkSL::ThreadContext::ProgramElements()[1], "uniform float2 y;");
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLDiscard, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Var x(kFloat_Type, "x", 1);
EXPECT_EQUAL(If(Sqrt(x) > 0, Discard()), "if ((sqrt(x) > 0.0)) discard;");
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLDo, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Statement x = Do(Block(), true);
EXPECT_EQUAL(x, "do {} while (true);");
Var a(kFloat_Type, "a"), b(kFloat_Type, "b");
Statement y = Do(Block(a++, --b), a != b);
EXPECT_EQUAL(y, "do { a++; --b; } while ((a != b));");
{
ExpectError error(r, "expected 'bool', but found 'int'");
Do(Block(), 7).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLFor, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu(), no_mark_vars_declared());
EXPECT_EQUAL(For(Statement(), Expression(), Expression(), Block()),
"for (;;) {}");
Var i(kInt_Type, "i", 0);
EXPECT_EQUAL(For(Declare(i), i < 10, ++i, i += 5),
"for (int i = 0; (i < 10); ++i) (i += 5);");
Var j(kInt_Type, "j", 0);
Var k(kInt_Type, "k", 10);
EXPECT_EQUAL(For((Declare(j), Declare(k)), j < k, ++j, Block()), R"(
{
int j = 0;
int k = 10;
for (; (j < k); ++j) {}
}
)");
{
ExpectError error(r, "expected 'bool', but found 'int'");
For(i = 0, i + 10, ++i, i += 5).release();
}
{
ExpectError error(r, "invalid for loop initializer");
For(If(i == 0, i = 1), i < 10, ++i, i += 5).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLFunction, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu(), no_mark_vars_declared());
Parameter coords(kFloat2_Type, "coords");
DSLFunction(kVoid_Type, "main", coords).define(
sk_FragColor() = Half4(coords, 0, 1)
);
REPORTER_ASSERT(r, SkSL::ThreadContext::ProgramElements().size() == 1);
EXPECT_EQUAL(*SkSL::ThreadContext::ProgramElements()[0],
"void main(float2 coords) { (sk_FragColor = half4(half2(coords), 0.0, 1.0)); }");
{
DSLWriter::Reset();
DSLParameter x(kFloat_Type, "x");
DSLFunction sqr(kFloat_Type, "sqr", x);
sqr.define(
Return(x * x)
);
EXPECT_EQUAL(sqr(sk_FragCoord().x()), "sqr(sk_FragCoord.x)");
REPORTER_ASSERT(r, SkSL::ThreadContext::ProgramElements().size() == 1);
EXPECT_EQUAL(*SkSL::ThreadContext::ProgramElements()[0],
"float sqr(float x) { return (x * x); }");
}
{
DSLWriter::Reset();
DSLParameter x(kFloat2_Type, "x");
DSLParameter y(kFloat2_Type, "y");
DSLFunction dot(kFloat2_Type, "dot", x, y);
dot.define(
Return(x * x + y * y)
);
EXPECT_EQUAL(dot(Float2(1.0f, 2.0f), Float2(3.0f, 4.0f)),
"dot(float2(1.0, 2.0), float2(3.0, 4.0))");
REPORTER_ASSERT(r, SkSL::ThreadContext::ProgramElements().size() == 1);
EXPECT_EQUAL(*SkSL::ThreadContext::ProgramElements()[0],
"float2 dot(float2 x, float2 y) { return ((x * x) + (y * y)); }");
}
{
DSLWriter::Reset();
DSLParameter x(kFloat_Type, "x");
DSLParameter y(kFloat_Type, "y");
DSLFunction pair(kFloat2_Type, "pair", x, y);
pair.define(
Return(Float2(x, y))
);
Var varArg1(kFloat_Type, "varArg1");
Var varArg2(kFloat_Type, "varArg2");
DSLWriter::MarkDeclared(varArg1);
DSLWriter::MarkDeclared(varArg2);
EXPECT_EQUAL(pair(varArg1, varArg2), "pair(varArg1, varArg2)");
}
{
ExpectError error(r, "expected 'float', but found 'bool'");
DSLWriter::Reset();
DSLFunction(kFloat_Type, "broken").define(
Return(true)
);
}
{
ExpectError error(r, "expected function to return 'float'");
DSLWriter::Reset();
DSLFunction(kFloat_Type, "broken").define(
Return()
);
}
{
ExpectError error(r, "function 'broken' can exit without returning a value");
DSLWriter::Reset();
Var x(kFloat_Type, "x", 0);
DSLFunction(kFloat_Type, "broken").define(
Declare(x),
If(x == 1, Return(x))
);
}
{
ExpectError error(r, "may not return a value from a void function");
DSLWriter::Reset();
DSLFunction(kVoid_Type, "broken").define(
Return(0)
);
}
{
ExpectError error(r, "function 'broken' can exit without returning a value");
DSLWriter::Reset();
DSLFunction(kFloat_Type, "broken").define(
);
}
{
ExpectError error(r, "parameter has already been used in another function");
DSLWriter::Reset();
DSLParameter p(kFloat_Type);
DSLFunction(kVoid_Type, "ok", p).define(
);
DSLFunction(kVoid_Type, "broken", p).define(
);
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLIf, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Var a(kFloat_Type, "a"), b(kFloat_Type, "b");
Statement x = If(a > b, a -= b);
EXPECT_EQUAL(x, "if ((a > b)) (a -= b);");
Statement y = If(a > b, a -= b, b -= a);
EXPECT_EQUAL(y, "if ((a > b)) (a -= b); else (b -= a);");
Statement z = StaticIf(a > b, a -= b, b -= a);
EXPECT_EQUAL(z, "@if ((a > b)) (a -= b); else (b -= a);");
{
ExpectError error(r, "expected 'bool', but found 'float'");
If(a + b, a -= b).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLInterfaceBlock, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
DSLGlobalVar intf = InterfaceBlock(kUniform_Modifier, "InterfaceBlock1",
{ Field(kFloat_Type, "a"), Field(kInt_Type, "b") });
REPORTER_ASSERT(r, SkSL::ThreadContext::ProgramElements().size() == 1);
EXPECT_EQUAL(*SkSL::ThreadContext::ProgramElements().back(),
"uniform InterfaceBlock1 { float a; int b; };");
EXPECT_EQUAL(intf.field("a"), "InterfaceBlock1.a");
DSLGlobalVar intf2 = InterfaceBlock(kUniform_Modifier, "InterfaceBlock2",
{ Field(kFloat2_Type, "x"), Field(kHalf2x2_Type, "y") },
"blockVar");
REPORTER_ASSERT(r, SkSL::ThreadContext::ProgramElements().size() == 2);
EXPECT_EQUAL(*SkSL::ThreadContext::ProgramElements().back(),
"uniform InterfaceBlock2 { float2 x; half2x2 y; } blockVar;");
EXPECT_EQUAL(intf2.field("x"), "blockVar.x");
DSLGlobalVar intf3 = InterfaceBlock(kUniform_Modifier, "InterfaceBlock3",
{ Field(kFloat_Type, "z") },"arrayVar", 4);
REPORTER_ASSERT(r, SkSL::ThreadContext::ProgramElements().size() == 3);
EXPECT_EQUAL(*SkSL::ThreadContext::ProgramElements().back(),
"uniform InterfaceBlock3 { float z; } arrayVar[4];");
EXPECT_EQUAL(intf3[1].field("z"), "arrayVar[1].z");
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLReturn, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Statement x = Return();
EXPECT_EQUAL(x, "return;");
Statement y = Return(true);
EXPECT_EQUAL(y, "return true;");
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLSelect, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Var a(kInt_Type, "a");
Expression x = Select(a > 0, 1, -1);
EXPECT_EQUAL(x, "((a > 0) ? 1 : -1)");
{
ExpectError error(r, "expected 'bool', but found 'int'");
Select(a, 1, -1).release();
}
{
ExpectError error(r, "ternary operator result mismatch: 'float2', 'float3'");
Select(a > 0, Float2(1), Float3(1)).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLSwitch, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Var a(kFloat_Type, "a"), b(kInt_Type, "b");
SkTArray<DSLStatement> caseStatements;
caseStatements.push_back(a = 1);
caseStatements.push_back(Continue());
Statement x = Switch(b,
Case(0, a = 0, Break()),
Case(1, std::move(caseStatements)),
Case(2, a = 2 /*Fallthrough*/),
Default(Discard())
);
EXPECT_EQUAL(x, R"(
switch (b) {
case 0: (a = 0.0); break;
case 1: (a = 1.0); continue;
case 2: (a = 2.0);
default: discard;
}
)");
Statement y = StaticSwitch(b,
Case(0, a = 0, Break()),
Case(1, a = 1, Continue()),
Case(2, a = 2 /*Fallthrough*/),
Default(Discard())
);
EXPECT_EQUAL(y, R"(
@switch (b) {
case 0: (a = 0.0); break;
case 1: (a = 1.0); continue;
case 2: (a = 2.0);
default: discard;
}
)");
EXPECT_EQUAL(Switch(b),
"switch (b) {}");
EXPECT_EQUAL(Switch(b, Default(), Case(0), Case(1)),
"switch (b) { default: case 0: case 1: }");
{
ExpectError error(r, "duplicate case value '0'");
DSLStatement(Switch(0, Case(0), Case(0))).release();
}
{
ExpectError error(r, "duplicate default case");
DSLStatement(Switch(0, Default(a = 0), Default(a = 1))).release();
}
{
ExpectError error(r, "case value must be a constant integer");
Var c(kInt_Type);
DSLStatement(Switch(0, Case(c))).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLSwizzle, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Var a(kFloat4_Type, "a");
EXPECT_EQUAL(a.x(),
"a.x");
EXPECT_EQUAL(a.y(),
"a.y");
EXPECT_EQUAL(a.z(),
"a.z");
EXPECT_EQUAL(a.w(),
"a.w");
EXPECT_EQUAL(a.r(),
"a.x");
EXPECT_EQUAL(a.g(),
"a.y");
EXPECT_EQUAL(a.b(),
"a.z");
EXPECT_EQUAL(a.a(),
"a.w");
EXPECT_EQUAL(Swizzle(a, R),
"a.x");
EXPECT_EQUAL(Swizzle(a, ZERO, G),
"float2(0.0, a.y)");
EXPECT_EQUAL(Swizzle(a, B, G, G),
"a.zyy");
EXPECT_EQUAL(Swizzle(a, R, G, B, ONE),
"float4(a.xyz, 1.0)");
EXPECT_EQUAL(Swizzle(a, B, G, R, ONE).r(),
"a.z");
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLVarSwap, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu(), no_mark_vars_declared());
// We should be able to convert `a` into a proper var by swapping it, even from within a scope.
Var a;
if (true)
{
Var(kInt_Type, "a").swap(a);
}
EXPECT_EQUAL(Statement(Block(Declare(a), a = 123)),
"{ int a; (a = 123); }");
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLWhile, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Statement x = While(true, Block());
EXPECT_EQUAL(x, "for (; true;) {}");
Var a(kFloat_Type, "a"), b(kFloat_Type, "b");
Statement y = While(a != b, Block(a++, --b));
EXPECT_EQUAL(y, "for (; (a != b);) { a++; --b; }");
{
ExpectError error(r, "expected 'bool', but found 'int'");
While(7, Block()).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLIndex, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Var a(Array(kInt_Type, 5), "a"), b(kInt_Type, "b");
EXPECT_EQUAL(a[0], "a[0]");
EXPECT_EQUAL(a[b], "a[b]");
{
ExpectError error(r, "expected 'int', but found 'bool'");
a[true].release();
}
{
ExpectError error(r, "expected array, but found 'int'");
b[0].release();
}
{
ExpectError error(r, "index -1 out of range for 'int[5]'");
a[-1].release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLBuiltins, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
// There is a Fract type on Mac which can conflict with our Fract builtin
using SkSL::dsl::Fract;
Var a(kHalf4_Type, "a"), b(kHalf4_Type, "b"), c(kHalf4_Type, "c");
Var h3(kHalf3_Type, "h3");
Var b4(kBool4_Type, "b4");
EXPECT_EQUAL(Abs(a), "abs(a)");
EXPECT_EQUAL(All(b4), "all(b4)");
EXPECT_EQUAL(Any(b4), "any(b4)");
EXPECT_EQUAL(Atan(a), "atan(a)");
EXPECT_EQUAL(Atan(a, b), "atan(a, b)");
EXPECT_EQUAL(Ceil(a), "ceil(a)");
EXPECT_EQUAL(Clamp(a, 0, 1), "clamp(a, 0.0, 1.0)");
EXPECT_EQUAL(Cos(a), "cos(a)");
EXPECT_EQUAL(Cross(h3, h3), "cross(h3, h3)");
EXPECT_EQUAL(Degrees(a), "degrees(a)");
EXPECT_EQUAL(Distance(a, b), "distance(a, b)");
EXPECT_EQUAL(Dot(a, b), "dot(a, b)");
EXPECT_EQUAL(Equal(a, b), "equal(a, b)");
EXPECT_EQUAL(Exp(a), "exp(a)");
EXPECT_EQUAL(Exp2(a), "exp2(a)");
EXPECT_EQUAL(Faceforward(a, b, c), "faceforward(a, b, c)");
EXPECT_EQUAL(Floor(a), "floor(a)");
EXPECT_EQUAL(Fract(a), "fract(a)");
EXPECT_EQUAL(GreaterThan(a, b), "greaterThan(a, b)");
EXPECT_EQUAL(GreaterThanEqual(a, b), "greaterThanEqual(a, b)");
EXPECT_EQUAL(Inversesqrt(a), "inversesqrt(a)");
EXPECT_EQUAL(LessThan(a, b), "lessThan(a, b)");
EXPECT_EQUAL(LessThanEqual(a, b), "lessThanEqual(a, b)");
EXPECT_EQUAL(Length(a), "length(a)");
EXPECT_EQUAL(Log(a), "log(a)");
EXPECT_EQUAL(Log2(a), "log2(a)");
EXPECT_EQUAL(Max(a, b), "max(a, b)");
EXPECT_EQUAL(Min(a, b), "min(a, b)");
EXPECT_EQUAL(Mix(a, b, c), "mix(a, b, c)");
EXPECT_EQUAL(Mod(a, b), "mod(a, b)");
EXPECT_EQUAL(Normalize(a), "normalize(a)");
EXPECT_EQUAL(NotEqual(a, b), "notEqual(a, b)");
EXPECT_EQUAL(Pow(a, b), "pow(a, b)");
EXPECT_EQUAL(Radians(a), "radians(a)");
EXPECT_EQUAL(Reflect(a, b), "reflect(a, b)");
EXPECT_EQUAL(Refract(a, b, 1), "refract(a, b, 1.0)");
EXPECT_EQUAL(Round(a), "round(a)");
EXPECT_EQUAL(Saturate(a), "saturate(a)");
EXPECT_EQUAL(Sign(a), "sign(a)");
EXPECT_EQUAL(Sin(a), "sin(a)");
EXPECT_EQUAL(Smoothstep(a, b, c), "smoothstep(a, b, c)");
EXPECT_EQUAL(Sqrt(a), "sqrt(a)");
EXPECT_EQUAL(Step(a, b), "step(a, b)");
EXPECT_EQUAL(Tan(a), "tan(a)");
EXPECT_EQUAL(Unpremul(a), "unpremul(a)");
// these calls all go through the normal channels, so it ought to be sufficient to prove that
// one of them reports errors correctly
{
ExpectError error(r, "no match for ceil(bool)");
Ceil(a == b).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLModifiers, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu(), no_mark_vars_declared());
Var v1(kConst_Modifier, kInt_Type, "v1", 0);
Statement d1 = Declare(v1);
EXPECT_EQUAL(d1, "const int v1 = 0;");
// Most modifiers require an appropriate context to be legal. We can't yet give them that
// context, so we can't as yet Declare() variables with these modifiers.
// TODO: better tests when able
Var v2(kIn_Modifier, kInt_Type, "v2");
REPORTER_ASSERT(r, v2.modifiers().flags() == SkSL::Modifiers::kIn_Flag);
DSLWriter::MarkDeclared(v2);
Var v3(kOut_Modifier, kInt_Type, "v3");
REPORTER_ASSERT(r, v3.modifiers().flags() == SkSL::Modifiers::kOut_Flag);
DSLWriter::MarkDeclared(v3);
Var v4(kFlat_Modifier, kInt_Type, "v4");
REPORTER_ASSERT(r, v4.modifiers().flags() == SkSL::Modifiers::kFlat_Flag);
DSLWriter::MarkDeclared(v4);
Var v5(kNoPerspective_Modifier, kInt_Type, "v5");
REPORTER_ASSERT(r, v5.modifiers().flags() == SkSL::Modifiers::kNoPerspective_Flag);
DSLWriter::MarkDeclared(v5);
Var v6(kIn_Modifier | kOut_Modifier, kInt_Type, "v6");
REPORTER_ASSERT(r, v6.modifiers().flags() == (SkSL::Modifiers::kIn_Flag |
SkSL::Modifiers::kOut_Flag));
DSLWriter::MarkDeclared(v6);
Var v7(kInOut_Modifier, kInt_Type, "v7");
REPORTER_ASSERT(r, v7.modifiers().flags() == (SkSL::Modifiers::kIn_Flag |
SkSL::Modifiers::kOut_Flag));
DSLWriter::MarkDeclared(v7);
Var v8(kUniform_Modifier, kInt_Type, "v8");
REPORTER_ASSERT(r, v8.modifiers().flags() == SkSL::Modifiers::kUniform_Flag);
DSLWriter::MarkDeclared(v8);
// Uniforms do not need to be explicitly declared
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLLayout, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu(), no_mark_vars_declared());
Var v1(DSLModifiers(DSLLayout().location(1).set(2).binding(3).offset(4).index(5).builtin(6)
.inputAttachmentIndex(7),
kConst_Modifier), kInt_Type, "v1", 0);
EXPECT_EQUAL(Declare(v1), "layout (location = 1, offset = 4, binding = 3, index = 5, set = 2, "
"builtin = 6, input_attachment_index = 7) const int v1 = 0;");
Var v2(DSLLayout().originUpperLeft(), kFloat2_Type, "v2");
EXPECT_EQUAL(Declare(v2), "layout (origin_upper_left) float2 v2;");
Var v4(DSLLayout().pushConstant(), kBool_Type, "v4");
EXPECT_EQUAL(Declare(v4), "layout (push_constant) bool v4;");
Var v5(DSLLayout().blendSupportAllEquations(), kHalf4_Type, "v5");
EXPECT_EQUAL(Declare(v5), "layout (blend_support_all_equations) half4 v5;");
{
ExpectError error(r, "'srgb_unpremul' is only permitted in runtime effects");
DSLGlobalVar v(DSLModifiers(DSLLayout().srgbUnpremul(), kUniform_Modifier), kHalf4_Type,
"v");
Declare(v);
}
{
ExpectError error(r, "layout qualifier 'location' appears more than once");
DSLLayout().location(1).location(2);
}
{
ExpectError error(r, "layout qualifier 'set' appears more than once");
DSLLayout().set(1).set(2);
}
{
ExpectError error(r, "layout qualifier 'binding' appears more than once");
DSLLayout().binding(1).binding(2);
}
{
ExpectError error(r, "layout qualifier 'offset' appears more than once");
DSLLayout().offset(1).offset(2);
}
{
ExpectError error(r, "layout qualifier 'index' appears more than once");
DSLLayout().index(1).index(2);
}
{
ExpectError error(r, "layout qualifier 'builtin' appears more than once");
DSLLayout().builtin(1).builtin(2);
}
{
ExpectError error(r, "layout qualifier 'input_attachment_index' appears more than once");
DSLLayout().inputAttachmentIndex(1).inputAttachmentIndex(2);
}
{
ExpectError error(r, "layout qualifier 'origin_upper_left' appears more than once");
DSLLayout().originUpperLeft().originUpperLeft();
}
{
ExpectError error(r, "layout qualifier 'push_constant' appears more than once");
DSLLayout().pushConstant().pushConstant();
}
{
ExpectError error(r, "layout qualifier 'blend_support_all_equations' appears more than "
"once");
DSLLayout().blendSupportAllEquations().blendSupportAllEquations();
}
{
ExpectError error(r, "layout qualifier 'srgb_unpremul' appears more than once");
DSLLayout().srgbUnpremul().srgbUnpremul();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLSampleShader, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu(), default_settings(),
SkSL::ProgramKind::kRuntimeShader);
DSLGlobalVar shader(kUniform_Modifier, kShader_Type, "child");
DSLGlobalVar notShader(kUniform_Modifier, kFloat_Type, "x");
EXPECT_EQUAL(shader.eval(Float2(0, 0)), "child.eval(float2(0.0, 0.0))");
{
ExpectError error(r, "no match for shader::eval(half4)");
shader.eval(Half4(1)).release();
}
{
ExpectError error(r, "type does not support method calls");
notShader.eval(Half4(1)).release();
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLStruct, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu(), no_mark_vars_declared());
DSLType simpleStruct = Struct("SimpleStruct",
Field(kFloat_Type, "x"),
Field(kBool_Type, "b"),
Field(Array(kFloat_Type, 3), "a")
);
DSLVar result(simpleStruct, "result");
DSLFunction(simpleStruct, "returnStruct").define(
Declare(result),
result.field("x") = 123,
result.field("b") = result.field("x") > 0,
result.field("a")[0] = result.field("x"),
Return(result)
);
REPORTER_ASSERT(r, SkSL::ThreadContext::ProgramElements().size() == 2);
EXPECT_EQUAL(*SkSL::ThreadContext::ProgramElements()[0],
"struct SimpleStruct { float x; bool b; float[3] a; };");
EXPECT_EQUAL(*SkSL::ThreadContext::ProgramElements()[1],
"SimpleStruct returnStruct() { SimpleStruct result; (result.x = 123.0);"
"(result.b = (result.x > 0.0)); (result.a[0] = result.x); return result; }");
Struct("NestedStruct",
Field(kInt_Type, "x"),
Field(simpleStruct, "simple")
);
REPORTER_ASSERT(r, SkSL::ThreadContext::ProgramElements().size() == 3);
EXPECT_EQUAL(*SkSL::ThreadContext::ProgramElements()[2],
"struct NestedStruct { int x; SimpleStruct simple; };");
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLWrapper, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
std::vector<Wrapper<DSLExpression>> exprs;
exprs.push_back(DSLExpression(1));
exprs.emplace_back(2.0);
EXPECT_EQUAL(std::move(*exprs[0]), "1");
EXPECT_EQUAL(std::move(*exprs[1]), "2.0");
std::vector<Wrapper<DSLVar>> vars;
vars.emplace_back(DSLVar(kInt_Type, "x"));
REPORTER_ASSERT(r, DSLWriter::Var(*vars[0])->name() == "x");
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLRTAdjust, r, ctxInfo) {
{
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu(), no_mark_vars_declared(),
SkSL::ProgramKind::kVertex);
DSLGlobalVar rtAdjust(kUniform_Modifier, kFloat4_Type, "sk_RTAdjust");
Declare(rtAdjust);
DSLFunction(kVoid_Type, "main").define(
sk_Position() = Half4(0)
);
REPORTER_ASSERT(r, SkSL::ThreadContext::ProgramElements().size() == 2);
EXPECT_EQUAL(*SkSL::ThreadContext::ProgramElements()[1],
"void main() {"
"(sk_PerVertex.sk_Position = float4(0.0));"
"(sk_PerVertex.sk_Position = float4(((sk_PerVertex.sk_Position.xy * sk_RTAdjust.xz) + "
"(sk_PerVertex.sk_Position.ww * sk_RTAdjust.yw)), 0.0, sk_PerVertex.sk_Position.w));"
"}");
}
{
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu(), no_mark_vars_declared(),
SkSL::ProgramKind::kVertex);
REPORTER_ASSERT(r, !SkSL::ThreadContext::RTAdjustState().fInterfaceBlock);
DSLGlobalVar intf = InterfaceBlock(kUniform_Modifier, "uniforms",
{ Field(kInt_Type, "unused"),
Field(kFloat4_Type, "sk_RTAdjust") });
REPORTER_ASSERT(r, SkSL::ThreadContext::RTAdjustState().fInterfaceBlock);
REPORTER_ASSERT(r, SkSL::ThreadContext::RTAdjustState().fFieldIndex == 1);
}
{
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu(), no_mark_vars_declared(),
SkSL::ProgramKind::kVertex);
ExpectError error(r, "sk_RTAdjust must have type 'float4'");
InterfaceBlock(kUniform_Modifier, "uniforms",
{ Field(kInt_Type, "unused"), Field(kHalf4_Type, "sk_RTAdjust") });
}
{
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu(), no_mark_vars_declared(),
SkSL::ProgramKind::kVertex);
ExpectError error(r, "symbol 'sk_RTAdjust' was already defined");
InterfaceBlock(kUniform_Modifier, "uniforms1",
{ Field(kInt_Type, "unused1"), Field(kFloat4_Type, "sk_RTAdjust") });
InterfaceBlock(kUniform_Modifier, "uniforms2",
{ Field(kInt_Type, "unused2"), Field(kFloat4_Type, "sk_RTAdjust") });
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLInlining, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu(), no_mark_vars_declared());
DSLParameter x(kFloat_Type, "x");
DSLFunction sqr(kFloat_Type, "sqr", x);
sqr.define(
Return(x * x)
);
DSLFunction(kVoid_Type, "main").define(
sk_FragColor() = (sqr(2), Half4(sqr(3)))
);
const char* source = "source test";
std::unique_ptr<SkSL::Program> program = ReleaseProgram(std::make_unique<SkSL::String>(source));
EXPECT_EQUAL(*program,
"layout(location = 0, index = 0, builtin = 10001) out half4 sk_FragColor;"
"layout(builtin = 17)in bool sk_Clockwise;"
"void main() {"
"/* inlined: sqr */;"
"/* inlined: sqr */;"
"(sk_FragColor = (4.0 , half4(half(9.0))));"
"}");
REPORTER_ASSERT(r, *program->fSource == source);
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLReleaseUnused, r, ctxInfo) {
SkSL::ProgramSettings settings = default_settings();
settings.fAssertDSLObjectsReleased = false;
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu(), settings);
If(Sqrt(1) > 0, Discard());
// Ensure that we can safely destroy statements and expressions despite being unused while
// settings.fAssertDSLObjectsReleased is disabled.
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLPrototypes, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu(), no_mark_vars_declared());
{
DSLParameter x(kFloat_Type, "x");
DSLFunction sqr(kFloat_Type, "sqr", x);
REPORTER_ASSERT(r, SkSL::ThreadContext::ProgramElements().size() == 1);
EXPECT_EQUAL(*SkSL::ThreadContext::ProgramElements()[0], "float sqr(float x);");
sqr.define(
Return(x * x)
);
REPORTER_ASSERT(r, SkSL::ThreadContext::ProgramElements().size() == 1);
EXPECT_EQUAL(*SkSL::ThreadContext::ProgramElements()[0],
"float sqr(float x) { return (x * x); }");
}
{
DSLWriter::Reset();
DSLParameter x(kFloat_Type, "x");
DSLFunction sqr(kFloat_Type, "sqr", x);
REPORTER_ASSERT(r, SkSL::ThreadContext::ProgramElements().size() == 1);
EXPECT_EQUAL(*SkSL::ThreadContext::ProgramElements()[0], "float sqr(float x);");
DSLFunction(kVoid_Type, "main").define(sqr(5));
REPORTER_ASSERT(r, SkSL::ThreadContext::ProgramElements().size() == 2);
EXPECT_EQUAL(*SkSL::ThreadContext::ProgramElements()[0], "float sqr(float x);");
EXPECT_EQUAL(*SkSL::ThreadContext::ProgramElements()[1], "void main() { sqr(5.0); }");
sqr.define(
Return(x * x)
);
REPORTER_ASSERT(r, SkSL::ThreadContext::ProgramElements().size() == 3);
EXPECT_EQUAL(*SkSL::ThreadContext::ProgramElements()[2],
"float sqr(float x) { return (x * x); }");
const char* source = "source test";
std::unique_ptr<SkSL::Program> p = ReleaseProgram(std::make_unique<SkSL::String>(source));
EXPECT_EQUAL(*p,
"layout (builtin = 17) in bool sk_Clockwise;"
"float sqr(float x);"
"void main() {"
"/* inlined: sqr */;"
"25.0;"
"}");
}
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLExtension, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
AddExtension("test_extension");
REPORTER_ASSERT(r, SkSL::ThreadContext::ProgramElements().size() == 1);
EXPECT_EQUAL(*SkSL::ThreadContext::ProgramElements()[0], "#extension test_extension : enable");
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLModifiersDeclaration, r, ctxInfo) {
AutoDSLContext context(ctxInfo.directContext()->priv().getGpu());
Declare(Modifiers(Layout().blendSupportAllEquations(), kOut_Modifier));
REPORTER_ASSERT(r, SkSL::ThreadContext::ProgramElements().size() == 1);
EXPECT_EQUAL(*SkSL::ThreadContext::ProgramElements()[0],
"layout(blend_support_all_equations) out;");
}
DEF_GPUTEST_FOR_MOCK_CONTEXT(DSLES3Types, r, ctxInfo) {
StartRuntimeShader(ctxInfo.directContext()->priv().getGpu()->shaderCompiler());
{
ExpectError error(r, "type 'uint' is not supported");
Var u(kUInt_Type, "u");
}
{
ExpectError error(r, "type 'float3x2' is not supported");
Float3x2(1).release();
}
{
ExpectError error(r, "type 'uint' is not supported");
Var u(kUInt_Type, "u");
}
{
ExpectError error(r, "type '$genType' is private");
Var g(DSLType("$genType"), "g");
}
Parameter p(kFloat2_Type, "p");
Function(kHalf4_Type, "main", p).define(
Return(Half4(0))
);
EndRuntimeShader();
}