blob: 2d541a3b5339ea78a1ff21d84e8941a8ae1d678d [file] [log] [blame]
/*
* Copyright 2016 Google Inc.
*
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
#include "SkSLCompiler.h"
#include "SkSLCFGGenerator.h"
#include "SkSLGLSLCodeGenerator.h"
#include "SkSLIRGenerator.h"
#include "SkSLSPIRVCodeGenerator.h"
#include "ir/SkSLExpression.h"
#include "ir/SkSLExpressionStatement.h"
#include "ir/SkSLIntLiteral.h"
#include "ir/SkSLModifiersDeclaration.h"
#include "ir/SkSLNop.h"
#include "ir/SkSLSymbolTable.h"
#include "ir/SkSLTernaryExpression.h"
#include "ir/SkSLUnresolvedFunction.h"
#include "ir/SkSLVarDeclarations.h"
#ifdef SK_ENABLE_SPIRV_VALIDATION
#include "spirv-tools/libspirv.hpp"
#endif
#define STRINGIFY(x) #x
// include the built-in shader symbols as static strings
static const char* SKSL_INCLUDE =
#include "sksl.include"
;
static const char* SKSL_VERT_INCLUDE =
#include "sksl_vert.include"
;
static const char* SKSL_FRAG_INCLUDE =
#include "sksl_frag.include"
;
static const char* SKSL_GEOM_INCLUDE =
#include "sksl_geom.include"
;
namespace SkSL {
Compiler::Compiler()
: fErrorCount(0) {
auto types = std::shared_ptr<SymbolTable>(new SymbolTable(this));
auto symbols = std::shared_ptr<SymbolTable>(new SymbolTable(types, this));
fIRGenerator = new IRGenerator(&fContext, symbols, *this);
fTypes = types;
#define ADD_TYPE(t) types->addWithoutOwnership(fContext.f ## t ## _Type->fName, \
fContext.f ## t ## _Type.get())
ADD_TYPE(Void);
ADD_TYPE(Float);
ADD_TYPE(Vec2);
ADD_TYPE(Vec3);
ADD_TYPE(Vec4);
ADD_TYPE(Double);
ADD_TYPE(DVec2);
ADD_TYPE(DVec3);
ADD_TYPE(DVec4);
ADD_TYPE(Int);
ADD_TYPE(IVec2);
ADD_TYPE(IVec3);
ADD_TYPE(IVec4);
ADD_TYPE(UInt);
ADD_TYPE(UVec2);
ADD_TYPE(UVec3);
ADD_TYPE(UVec4);
ADD_TYPE(Bool);
ADD_TYPE(BVec2);
ADD_TYPE(BVec3);
ADD_TYPE(BVec4);
ADD_TYPE(Mat2x2);
types->addWithoutOwnership(String("mat2x2"), fContext.fMat2x2_Type.get());
ADD_TYPE(Mat2x3);
ADD_TYPE(Mat2x4);
ADD_TYPE(Mat3x2);
ADD_TYPE(Mat3x3);
types->addWithoutOwnership(String("mat3x3"), fContext.fMat3x3_Type.get());
ADD_TYPE(Mat3x4);
ADD_TYPE(Mat4x2);
ADD_TYPE(Mat4x3);
ADD_TYPE(Mat4x4);
types->addWithoutOwnership(String("mat4x4"), fContext.fMat4x4_Type.get());
ADD_TYPE(GenType);
ADD_TYPE(GenDType);
ADD_TYPE(GenIType);
ADD_TYPE(GenUType);
ADD_TYPE(GenBType);
ADD_TYPE(Mat);
ADD_TYPE(Vec);
ADD_TYPE(GVec);
ADD_TYPE(GVec2);
ADD_TYPE(GVec3);
ADD_TYPE(GVec4);
ADD_TYPE(DVec);
ADD_TYPE(IVec);
ADD_TYPE(UVec);
ADD_TYPE(BVec);
ADD_TYPE(Sampler1D);
ADD_TYPE(Sampler2D);
ADD_TYPE(Sampler3D);
ADD_TYPE(SamplerExternalOES);
ADD_TYPE(SamplerCube);
ADD_TYPE(Sampler2DRect);
ADD_TYPE(Sampler1DArray);
ADD_TYPE(Sampler2DArray);
ADD_TYPE(SamplerCubeArray);
ADD_TYPE(SamplerBuffer);
ADD_TYPE(Sampler2DMS);
ADD_TYPE(Sampler2DMSArray);
ADD_TYPE(ISampler2D);
ADD_TYPE(Image2D);
ADD_TYPE(IImage2D);
ADD_TYPE(SubpassInput);
ADD_TYPE(SubpassInputMS);
ADD_TYPE(GSampler1D);
ADD_TYPE(GSampler2D);
ADD_TYPE(GSampler3D);
ADD_TYPE(GSamplerCube);
ADD_TYPE(GSampler2DRect);
ADD_TYPE(GSampler1DArray);
ADD_TYPE(GSampler2DArray);
ADD_TYPE(GSamplerCubeArray);
ADD_TYPE(GSamplerBuffer);
ADD_TYPE(GSampler2DMS);
ADD_TYPE(GSampler2DMSArray);
ADD_TYPE(Sampler1DShadow);
ADD_TYPE(Sampler2DShadow);
ADD_TYPE(SamplerCubeShadow);
ADD_TYPE(Sampler2DRectShadow);
ADD_TYPE(Sampler1DArrayShadow);
ADD_TYPE(Sampler2DArrayShadow);
ADD_TYPE(SamplerCubeArrayShadow);
ADD_TYPE(GSampler2DArrayShadow);
ADD_TYPE(GSamplerCubeArrayShadow);
String skCapsName("sk_Caps");
Variable* skCaps = new Variable(Position(), Modifiers(), skCapsName,
*fContext.fSkCaps_Type, Variable::kGlobal_Storage);
fIRGenerator->fSymbolTable->add(skCapsName, std::unique_ptr<Symbol>(skCaps));
Modifiers::Flag ignored1;
std::vector<std::unique_ptr<ProgramElement>> ignored2;
fIRGenerator->convertProgram(String(SKSL_INCLUDE), *fTypes, &ignored1, &ignored2);
fIRGenerator->fSymbolTable->markAllFunctionsBuiltin();
ASSERT(!fErrorCount);
}
Compiler::~Compiler() {
delete fIRGenerator;
}
// add the definition created by assigning to the lvalue to the definition set
void Compiler::addDefinition(const Expression* lvalue, std::unique_ptr<Expression>* expr,
DefinitionMap* definitions) {
switch (lvalue->fKind) {
case Expression::kVariableReference_Kind: {
const Variable& var = ((VariableReference*) lvalue)->fVariable;
if (var.fStorage == Variable::kLocal_Storage) {
(*definitions)[&var] = expr;
}
break;
}
case Expression::kSwizzle_Kind:
// We consider the variable written to as long as at least some of its components have
// been written to. This will lead to some false negatives (we won't catch it if you
// write to foo.x and then read foo.y), but being stricter could lead to false positives
// (we write to foo.x, and then pass foo to a function which happens to only read foo.x,
// but since we pass foo as a whole it is flagged as an error) unless we perform a much
// more complicated whole-program analysis. This is probably good enough.
this->addDefinition(((Swizzle*) lvalue)->fBase.get(),
(std::unique_ptr<Expression>*) &fContext.fDefined_Expression,
definitions);
break;
case Expression::kIndex_Kind:
// see comments in Swizzle
this->addDefinition(((IndexExpression*) lvalue)->fBase.get(),
(std::unique_ptr<Expression>*) &fContext.fDefined_Expression,
definitions);
break;
case Expression::kFieldAccess_Kind:
// see comments in Swizzle
this->addDefinition(((FieldAccess*) lvalue)->fBase.get(),
(std::unique_ptr<Expression>*) &fContext.fDefined_Expression,
definitions);
break;
default:
// not an lvalue, can't happen
ASSERT(false);
}
}
// add local variables defined by this node to the set
void Compiler::addDefinitions(const BasicBlock::Node& node,
DefinitionMap* definitions) {
switch (node.fKind) {
case BasicBlock::Node::kExpression_Kind: {
ASSERT(node.expression());
const Expression* expr = (Expression*) node.expression()->get();
switch (expr->fKind) {
case Expression::kBinary_Kind: {
BinaryExpression* b = (BinaryExpression*) expr;
if (b->fOperator == Token::EQ) {
this->addDefinition(b->fLeft.get(), &b->fRight, definitions);
} else if (Token::IsAssignment(b->fOperator)) {
this->addDefinition(
b->fLeft.get(),
(std::unique_ptr<Expression>*) &fContext.fDefined_Expression,
definitions);
}
break;
}
case Expression::kPrefix_Kind: {
const PrefixExpression* p = (PrefixExpression*) expr;
if (p->fOperator == Token::MINUSMINUS || p->fOperator == Token::PLUSPLUS) {
this->addDefinition(
p->fOperand.get(),
(std::unique_ptr<Expression>*) &fContext.fDefined_Expression,
definitions);
}
break;
}
case Expression::kPostfix_Kind: {
const PostfixExpression* p = (PostfixExpression*) expr;
if (p->fOperator == Token::MINUSMINUS || p->fOperator == Token::PLUSPLUS) {
this->addDefinition(
p->fOperand.get(),
(std::unique_ptr<Expression>*) &fContext.fDefined_Expression,
definitions);
}
break;
}
case Expression::kVariableReference_Kind: {
const VariableReference* v = (VariableReference*) expr;
if (v->fRefKind != VariableReference::kRead_RefKind) {
this->addDefinition(
v,
(std::unique_ptr<Expression>*) &fContext.fDefined_Expression,
definitions);
}
}
default:
break;
}
break;
}
case BasicBlock::Node::kStatement_Kind: {
const Statement* stmt = (Statement*) node.statement()->get();
if (stmt->fKind == Statement::kVarDeclaration_Kind) {
VarDeclaration& vd = (VarDeclaration&) *stmt;
if (vd.fValue) {
(*definitions)[vd.fVar] = &vd.fValue;
}
}
break;
}
}
}
void Compiler::scanCFG(CFG* cfg, BlockId blockId, std::set<BlockId>* workList) {
BasicBlock& block = cfg->fBlocks[blockId];
// compute definitions after this block
DefinitionMap after = block.fBefore;
for (const BasicBlock::Node& n : block.fNodes) {
this->addDefinitions(n, &after);
}
// propagate definitions to exits
for (BlockId exitId : block.fExits) {
BasicBlock& exit = cfg->fBlocks[exitId];
for (const auto& pair : after) {
std::unique_ptr<Expression>* e1 = pair.second;
auto found = exit.fBefore.find(pair.first);
if (found == exit.fBefore.end()) {
// exit has no definition for it, just copy it
workList->insert(exitId);
exit.fBefore[pair.first] = e1;
} else {
// exit has a (possibly different) value already defined
std::unique_ptr<Expression>* e2 = exit.fBefore[pair.first];
if (e1 != e2) {
// definition has changed, merge and add exit block to worklist
workList->insert(exitId);
if (e1 && e2) {
exit.fBefore[pair.first] =
(std::unique_ptr<Expression>*) &fContext.fDefined_Expression;
} else {
exit.fBefore[pair.first] = nullptr;
}
}
}
}
}
}
// returns a map which maps all local variables in the function to null, indicating that their value
// is initially unknown
static DefinitionMap compute_start_state(const CFG& cfg) {
DefinitionMap result;
for (const auto& block : cfg.fBlocks) {
for (const auto& node : block.fNodes) {
if (node.fKind == BasicBlock::Node::kStatement_Kind) {
ASSERT(node.statement());
const Statement* s = node.statement()->get();
if (s->fKind == Statement::kVarDeclarations_Kind) {
const VarDeclarationsStatement* vd = (const VarDeclarationsStatement*) s;
for (const auto& decl : vd->fDeclaration->fVars) {
result[((VarDeclaration&) *decl).fVar] = nullptr;
}
}
}
}
}
return result;
}
/**
* Returns true if assigning to this lvalue has no effect.
*/
static bool is_dead(const Expression& lvalue) {
switch (lvalue.fKind) {
case Expression::kVariableReference_Kind:
return ((VariableReference&) lvalue).fVariable.dead();
case Expression::kSwizzle_Kind:
return is_dead(*((Swizzle&) lvalue).fBase);
case Expression::kFieldAccess_Kind:
return is_dead(*((FieldAccess&) lvalue).fBase);
case Expression::kIndex_Kind: {
const IndexExpression& idx = (IndexExpression&) lvalue;
return is_dead(*idx.fBase) && !idx.fIndex->hasSideEffects();
}
default:
ABORT("invalid lvalue: %s\n", lvalue.description().c_str());
}
}
/**
* Returns true if this is an assignment which can be collapsed down to just the right hand side due
* to a dead target and lack of side effects on the left hand side.
*/
static bool dead_assignment(const BinaryExpression& b) {
if (!Token::IsAssignment(b.fOperator)) {
return false;
}
return is_dead(*b.fLeft);
}
void Compiler::computeDataFlow(CFG* cfg) {
cfg->fBlocks[cfg->fStart].fBefore = compute_start_state(*cfg);
std::set<BlockId> workList;
for (BlockId i = 0; i < cfg->fBlocks.size(); i++) {
workList.insert(i);
}
while (workList.size()) {
BlockId next = *workList.begin();
workList.erase(workList.begin());
this->scanCFG(cfg, next, &workList);
}
}
/**
* Attempts to replace the expression pointed to by iter with a new one (in both the CFG and the
* IR). If the expression can be cleanly removed, returns true and updates the iterator to point to
* the newly-inserted element. Otherwise updates only the IR and returns false (and the CFG will
* need to be regenerated).
*/
bool try_replace_expression(BasicBlock* b,
std::vector<BasicBlock::Node>::iterator* iter,
std::unique_ptr<Expression>* newExpression) {
std::unique_ptr<Expression>* target = (*iter)->expression();
if (!b->tryRemoveExpression(iter)) {
*target = std::move(*newExpression);
return false;
}
*target = std::move(*newExpression);
return b->tryInsertExpression(iter, target);
}
/**
* Returns true if the expression is a constant numeric literal with the specified value, or a
* constant vector with all elements equal to the specified value.
*/
bool is_constant(const Expression& expr, double value) {
switch (expr.fKind) {
case Expression::kIntLiteral_Kind:
return ((IntLiteral&) expr).fValue == value;
case Expression::kFloatLiteral_Kind:
return ((FloatLiteral&) expr).fValue == value;
case Expression::kConstructor_Kind: {
Constructor& c = (Constructor&) expr;
if (c.fType.kind() == Type::kVector_Kind && c.isConstant()) {
for (int i = 0; i < c.fType.columns(); ++i) {
if (!is_constant(c.getVecComponent(i), value)) {
return false;
}
}
return true;
}
return false;
}
default:
return false;
}
}
/**
* Collapses the binary expression pointed to by iter down to just the right side (in both the IR
* and CFG structures).
*/
void delete_left(BasicBlock* b,
std::vector<BasicBlock::Node>::iterator* iter,
bool* outUpdated,
bool* outNeedsRescan) {
*outUpdated = true;
std::unique_ptr<Expression>* target = (*iter)->expression();
ASSERT((*target)->fKind == Expression::kBinary_Kind);
BinaryExpression& bin = (BinaryExpression&) **target;
bool result;
if (bin.fOperator == Token::EQ) {
result = b->tryRemoveLValueBefore(iter, bin.fLeft.get());
} else {
result = b->tryRemoveExpressionBefore(iter, bin.fLeft.get());
}
*target = std::move(bin.fRight);
if (!result) {
*outNeedsRescan = true;
return;
}
if (*iter == b->fNodes.begin()) {
*outNeedsRescan = true;
return;
}
--(*iter);
if ((*iter)->fKind != BasicBlock::Node::kExpression_Kind ||
(*iter)->expression() != &bin.fRight) {
*outNeedsRescan = true;
return;
}
*iter = b->fNodes.erase(*iter);
ASSERT((*iter)->expression() == target);
}
/**
* Collapses the binary expression pointed to by iter down to just the left side (in both the IR and
* CFG structures).
*/
void delete_right(BasicBlock* b,
std::vector<BasicBlock::Node>::iterator* iter,
bool* outUpdated,
bool* outNeedsRescan) {
*outUpdated = true;
std::unique_ptr<Expression>* target = (*iter)->expression();
ASSERT((*target)->fKind == Expression::kBinary_Kind);
BinaryExpression& bin = (BinaryExpression&) **target;
if (!b->tryRemoveExpressionBefore(iter, bin.fRight.get())) {
*target = std::move(bin.fLeft);
*outNeedsRescan = true;
return;
}
*target = std::move(bin.fLeft);
if (*iter == b->fNodes.begin()) {
*outNeedsRescan = true;
return;
}
--(*iter);
if (((*iter)->fKind != BasicBlock::Node::kExpression_Kind ||
(*iter)->expression() != &bin.fLeft)) {
*outNeedsRescan = true;
return;
}
*iter = b->fNodes.erase(*iter);
ASSERT((*iter)->expression() == target);
}
/**
* Constructs the specified type using a single argument.
*/
static std::unique_ptr<Expression> construct(const Type& type, std::unique_ptr<Expression> v) {
std::vector<std::unique_ptr<Expression>> args;
args.push_back(std::move(v));
auto result = std::unique_ptr<Expression>(new Constructor(Position(), type, std::move(args)));
return result;
}
/**
* Used in the implementations of vectorize_left and vectorize_right. Given a vector type and an
* expression x, deletes the expression pointed to by iter and replaces it with <type>(x).
*/
static void vectorize(BasicBlock* b,
std::vector<BasicBlock::Node>::iterator* iter,
const Type& type,
std::unique_ptr<Expression>* otherExpression,
bool* outUpdated,
bool* outNeedsRescan) {
ASSERT((*(*iter)->expression())->fKind == Expression::kBinary_Kind);
ASSERT(type.kind() == Type::kVector_Kind);
ASSERT((*otherExpression)->fType.kind() == Type::kScalar_Kind);
*outUpdated = true;
std::unique_ptr<Expression>* target = (*iter)->expression();
if (!b->tryRemoveExpression(iter)) {
*target = construct(type, std::move(*otherExpression));
*outNeedsRescan = true;
} else {
*target = construct(type, std::move(*otherExpression));
if (!b->tryInsertExpression(iter, target)) {
*outNeedsRescan = true;
}
}
}
/**
* Given a binary expression of the form x <op> vec<n>(y), deletes the right side and vectorizes the
* left to yield vec<n>(x).
*/
static void vectorize_left(BasicBlock* b,
std::vector<BasicBlock::Node>::iterator* iter,
bool* outUpdated,
bool* outNeedsRescan) {
BinaryExpression& bin = (BinaryExpression&) **(*iter)->expression();
vectorize(b, iter, bin.fRight->fType, &bin.fLeft, outUpdated, outNeedsRescan);
}
/**
* Given a binary expression of the form vec<n>(x) <op> y, deletes the left side and vectorizes the
* right to yield vec<n>(y).
*/
static void vectorize_right(BasicBlock* b,
std::vector<BasicBlock::Node>::iterator* iter,
bool* outUpdated,
bool* outNeedsRescan) {
BinaryExpression& bin = (BinaryExpression&) **(*iter)->expression();
vectorize(b, iter, bin.fLeft->fType, &bin.fRight, outUpdated, outNeedsRescan);
}
// Mark that an expression which we were writing to is no longer being written to
void clear_write(const Expression& expr) {
switch (expr.fKind) {
case Expression::kVariableReference_Kind: {
((VariableReference&) expr).setRefKind(VariableReference::kRead_RefKind);
break;
}
case Expression::kFieldAccess_Kind:
clear_write(*((FieldAccess&) expr).fBase);
break;
case Expression::kSwizzle_Kind:
clear_write(*((Swizzle&) expr).fBase);
break;
case Expression::kIndex_Kind:
clear_write(*((IndexExpression&) expr).fBase);
break;
default:
ABORT("shouldn't be writing to this kind of expression\n");
break;
}
}
void Compiler::simplifyExpression(DefinitionMap& definitions,
BasicBlock& b,
std::vector<BasicBlock::Node>::iterator* iter,
std::unordered_set<const Variable*>* undefinedVariables,
bool* outUpdated,
bool* outNeedsRescan) {
Expression* expr = (*iter)->expression()->get();
ASSERT(expr);
if ((*iter)->fConstantPropagation) {
std::unique_ptr<Expression> optimized = expr->constantPropagate(*fIRGenerator, definitions);
if (optimized) {
*outUpdated = true;
if (!try_replace_expression(&b, iter, &optimized)) {
*outNeedsRescan = true;
return;
}
ASSERT((*iter)->fKind == BasicBlock::Node::kExpression_Kind);
expr = (*iter)->expression()->get();
}
}
switch (expr->fKind) {
case Expression::kVariableReference_Kind: {
const Variable& var = ((VariableReference*) expr)->fVariable;
if (var.fStorage == Variable::kLocal_Storage && !definitions[&var] &&
(*undefinedVariables).find(&var) == (*undefinedVariables).end()) {
(*undefinedVariables).insert(&var);
this->error(expr->fPosition,
"'" + var.fName + "' has not been assigned");
}
break;
}
case Expression::kTernary_Kind: {
TernaryExpression* t = (TernaryExpression*) expr;
if (t->fTest->fKind == Expression::kBoolLiteral_Kind) {
// ternary has a constant test, replace it with either the true or
// false branch
if (((BoolLiteral&) *t->fTest).fValue) {
(*iter)->setExpression(std::move(t->fIfTrue));
} else {
(*iter)->setExpression(std::move(t->fIfFalse));
}
*outUpdated = true;
*outNeedsRescan = true;
}
break;
}
case Expression::kBinary_Kind: {
BinaryExpression* bin = (BinaryExpression*) expr;
if (dead_assignment(*bin)) {
delete_left(&b, iter, outUpdated, outNeedsRescan);
break;
}
// collapse useless expressions like x * 1 or x + 0
if (((bin->fLeft->fType.kind() != Type::kScalar_Kind) &&
(bin->fLeft->fType.kind() != Type::kVector_Kind)) ||
((bin->fRight->fType.kind() != Type::kScalar_Kind) &&
(bin->fRight->fType.kind() != Type::kVector_Kind))) {
break;
}
switch (bin->fOperator) {
case Token::STAR:
if (is_constant(*bin->fLeft, 1)) {
if (bin->fLeft->fType.kind() == Type::kVector_Kind &&
bin->fRight->fType.kind() == Type::kScalar_Kind) {
// vec4(1) * x -> vec4(x)
vectorize_right(&b, iter, outUpdated, outNeedsRescan);
} else {
// 1 * x -> x
// 1 * vec4(x) -> vec4(x)
// vec4(1) * vec4(x) -> vec4(x)
delete_left(&b, iter, outUpdated, outNeedsRescan);
}
}
else if (is_constant(*bin->fLeft, 0)) {
if (bin->fLeft->fType.kind() == Type::kScalar_Kind &&
bin->fRight->fType.kind() == Type::kVector_Kind) {
// 0 * vec4(x) -> vec4(0)
vectorize_left(&b, iter, outUpdated, outNeedsRescan);
} else {
// 0 * x -> 0
// vec4(0) * x -> vec4(0)
// vec4(0) * vec4(x) -> vec4(0)
delete_right(&b, iter, outUpdated, outNeedsRescan);
}
}
else if (is_constant(*bin->fRight, 1)) {
if (bin->fLeft->fType.kind() == Type::kScalar_Kind &&
bin->fRight->fType.kind() == Type::kVector_Kind) {
// x * vec4(1) -> vec4(x)
vectorize_left(&b, iter, outUpdated, outNeedsRescan);
} else {
// x * 1 -> x
// vec4(x) * 1 -> vec4(x)
// vec4(x) * vec4(1) -> vec4(x)
delete_right(&b, iter, outUpdated, outNeedsRescan);
}
}
else if (is_constant(*bin->fRight, 0)) {
if (bin->fLeft->fType.kind() == Type::kVector_Kind &&
bin->fRight->fType.kind() == Type::kScalar_Kind) {
// vec4(x) * 0 -> vec4(0)
vectorize_right(&b, iter, outUpdated, outNeedsRescan);
} else {
// x * 0 -> 0
// x * vec4(0) -> vec4(0)
// vec4(x) * vec4(0) -> vec4(0)
delete_left(&b, iter, outUpdated, outNeedsRescan);
}
}
break;
case Token::PLUS:
if (is_constant(*bin->fLeft, 0)) {
if (bin->fLeft->fType.kind() == Type::kVector_Kind &&
bin->fRight->fType.kind() == Type::kScalar_Kind) {
// vec4(0) + x -> vec4(x)
vectorize_right(&b, iter, outUpdated, outNeedsRescan);
} else {
// 0 + x -> x
// 0 + vec4(x) -> vec4(x)
// vec4(0) + vec4(x) -> vec4(x)
delete_left(&b, iter, outUpdated, outNeedsRescan);
}
} else if (is_constant(*bin->fRight, 0)) {
if (bin->fLeft->fType.kind() == Type::kScalar_Kind &&
bin->fRight->fType.kind() == Type::kVector_Kind) {
// x + vec4(0) -> vec4(x)
vectorize_left(&b, iter, outUpdated, outNeedsRescan);
} else {
// x + 0 -> x
// vec4(x) + 0 -> vec4(x)
// vec4(x) + vec4(0) -> vec4(x)
delete_right(&b, iter, outUpdated, outNeedsRescan);
}
}
break;
case Token::MINUS:
if (is_constant(*bin->fRight, 0)) {
if (bin->fLeft->fType.kind() == Type::kScalar_Kind &&
bin->fRight->fType.kind() == Type::kVector_Kind) {
// x - vec4(0) -> vec4(x)
vectorize_left(&b, iter, outUpdated, outNeedsRescan);
} else {
// x - 0 -> x
// vec4(x) - 0 -> vec4(x)
// vec4(x) - vec4(0) -> vec4(x)
delete_right(&b, iter, outUpdated, outNeedsRescan);
}
}
break;
case Token::SLASH:
if (is_constant(*bin->fRight, 1)) {
if (bin->fLeft->fType.kind() == Type::kScalar_Kind &&
bin->fRight->fType.kind() == Type::kVector_Kind) {
// x / vec4(1) -> vec4(x)
vectorize_left(&b, iter, outUpdated, outNeedsRescan);
} else {
// x / 1 -> x
// vec4(x) / 1 -> vec4(x)
// vec4(x) / vec4(1) -> vec4(x)
delete_right(&b, iter, outUpdated, outNeedsRescan);
}
} else if (is_constant(*bin->fLeft, 0)) {
if (bin->fLeft->fType.kind() == Type::kScalar_Kind &&
bin->fRight->fType.kind() == Type::kVector_Kind) {
// 0 / vec4(x) -> vec4(0)
vectorize_left(&b, iter, outUpdated, outNeedsRescan);
} else {
// 0 / x -> 0
// vec4(0) / x -> vec4(0)
// vec4(0) / vec4(x) -> vec4(0)
delete_right(&b, iter, outUpdated, outNeedsRescan);
}
}
break;
case Token::PLUSEQ:
if (is_constant(*bin->fRight, 0)) {
clear_write(*bin->fLeft);
delete_right(&b, iter, outUpdated, outNeedsRescan);
}
break;
case Token::MINUSEQ:
if (is_constant(*bin->fRight, 0)) {
clear_write(*bin->fLeft);
delete_right(&b, iter, outUpdated, outNeedsRescan);
}
break;
case Token::STAREQ:
if (is_constant(*bin->fRight, 1)) {
clear_write(*bin->fLeft);
delete_right(&b, iter, outUpdated, outNeedsRescan);
}
break;
case Token::SLASHEQ:
if (is_constant(*bin->fRight, 1)) {
clear_write(*bin->fLeft);
delete_right(&b, iter, outUpdated, outNeedsRescan);
}
break;
default:
break;
}
}
default:
break;
}
}
// returns true if this statement could potentially execute a break at the current level (we ignore
// nested loops and switches, since any breaks inside of them will merely break the loop / switch)
static bool contains_break(Statement& s) {
switch (s.fKind) {
case Statement::kBlock_Kind:
for (const auto& sub : ((Block&) s).fStatements) {
if (contains_break(*sub)) {
return true;
}
}
return false;
case Statement::kBreak_Kind:
return true;
case Statement::kIf_Kind: {
const IfStatement& i = (IfStatement&) s;
return contains_break(*i.fIfTrue) || (i.fIfFalse && contains_break(*i.fIfFalse));
}
default:
return false;
}
}
// Returns a block containing all of the statements that will be run if the given case matches
// (which, owing to the statements being owned by unique_ptrs, means the switch itself will be
// broken by this call and must then be discarded).
// Returns null (and leaves the switch unmodified) if no such simple reduction is possible, such as
// when break statements appear inside conditionals.
static std::unique_ptr<Statement> block_for_case(SwitchStatement* s, SwitchCase* c) {
bool capturing = false;
std::vector<std::unique_ptr<Statement>*> statementPtrs;
for (const auto& current : s->fCases) {
if (current.get() == c) {
capturing = true;
}
if (capturing) {
for (auto& stmt : current->fStatements) {
if (stmt->fKind == Statement::kBreak_Kind) {
capturing = false;
break;
}
if (contains_break(*stmt)) {
return nullptr;
}
statementPtrs.push_back(&stmt);
}
if (!capturing) {
break;
}
}
}
std::vector<std::unique_ptr<Statement>> statements;
for (const auto& s : statementPtrs) {
statements.push_back(std::move(*s));
}
return std::unique_ptr<Statement>(new Block(Position(), std::move(statements)));
}
void Compiler::simplifyStatement(DefinitionMap& definitions,
BasicBlock& b,
std::vector<BasicBlock::Node>::iterator* iter,
std::unordered_set<const Variable*>* undefinedVariables,
bool* outUpdated,
bool* outNeedsRescan) {
Statement* stmt = (*iter)->statement()->get();
switch (stmt->fKind) {
case Statement::kVarDeclaration_Kind: {
const auto& varDecl = (VarDeclaration&) *stmt;
if (varDecl.fVar->dead() &&
(!varDecl.fValue ||
!varDecl.fValue->hasSideEffects())) {
if (varDecl.fValue) {
ASSERT((*iter)->statement()->get() == stmt);
if (!b.tryRemoveExpressionBefore(iter, varDecl.fValue.get())) {
*outNeedsRescan = true;
}
}
(*iter)->setStatement(std::unique_ptr<Statement>(new Nop()));
*outUpdated = true;
}
break;
}
case Statement::kIf_Kind: {
IfStatement& i = (IfStatement&) *stmt;
if (i.fTest->fKind == Expression::kBoolLiteral_Kind) {
// constant if, collapse down to a single branch
if (((BoolLiteral&) *i.fTest).fValue) {
ASSERT(i.fIfTrue);
(*iter)->setStatement(std::move(i.fIfTrue));
} else {
if (i.fIfFalse) {
(*iter)->setStatement(std::move(i.fIfFalse));
} else {
(*iter)->setStatement(std::unique_ptr<Statement>(new Nop()));
}
}
*outUpdated = true;
*outNeedsRescan = true;
break;
}
if (i.fIfFalse && i.fIfFalse->isEmpty()) {
// else block doesn't do anything, remove it
i.fIfFalse.reset();
*outUpdated = true;
*outNeedsRescan = true;
}
if (!i.fIfFalse && i.fIfTrue->isEmpty()) {
// if block doesn't do anything, no else block
if (i.fTest->hasSideEffects()) {
// test has side effects, keep it
(*iter)->setStatement(std::unique_ptr<Statement>(
new ExpressionStatement(std::move(i.fTest))));
} else {
// no if, no else, no test side effects, kill the whole if
// statement
(*iter)->setStatement(std::unique_ptr<Statement>(new Nop()));
}
*outUpdated = true;
*outNeedsRescan = true;
}
break;
}
case Statement::kSwitch_Kind: {
SwitchStatement& s = (SwitchStatement&) *stmt;
if (s.fValue->isConstant()) {
// switch is constant, replace it with the case that matches
bool found = false;
SwitchCase* defaultCase = nullptr;
for (const auto& c : s.fCases) {
if (!c->fValue) {
defaultCase = c.get();
continue;
}
ASSERT(c->fValue->fKind == s.fValue->fKind);
found = c->fValue->compareConstant(fContext, *s.fValue);
if (found) {
std::unique_ptr<Statement> newBlock = block_for_case(&s, c.get());
if (newBlock) {
(*iter)->setStatement(std::move(newBlock));
break;
} else {
if (s.fIsStatic) {
this->error(s.fPosition,
"static switch contains non-static conditional break");
s.fIsStatic = false;
}
return; // can't simplify
}
}
}
if (!found) {
// no matching case. use default if it exists, or kill the whole thing
if (defaultCase) {
std::unique_ptr<Statement> newBlock = block_for_case(&s, defaultCase);
if (newBlock) {
(*iter)->setStatement(std::move(newBlock));
} else {
if (s.fIsStatic) {
this->error(s.fPosition,
"static switch contains non-static conditional break");
s.fIsStatic = false;
}
return; // can't simplify
}
} else {
(*iter)->setStatement(std::unique_ptr<Statement>(new Nop()));
}
}
*outUpdated = true;
*outNeedsRescan = true;
}
break;
}
case Statement::kExpression_Kind: {
ExpressionStatement& e = (ExpressionStatement&) *stmt;
ASSERT((*iter)->statement()->get() == &e);
if (!e.fExpression->hasSideEffects()) {
// Expression statement with no side effects, kill it
if (!b.tryRemoveExpressionBefore(iter, e.fExpression.get())) {
*outNeedsRescan = true;
}
ASSERT((*iter)->statement()->get() == stmt);
(*iter)->setStatement(std::unique_ptr<Statement>(new Nop()));
*outUpdated = true;
}
break;
}
default:
break;
}
}
void Compiler::scanCFG(FunctionDefinition& f) {
CFG cfg = CFGGenerator().getCFG(f);
this->computeDataFlow(&cfg);
// check for unreachable code
for (size_t i = 0; i < cfg.fBlocks.size(); i++) {
if (i != cfg.fStart && !cfg.fBlocks[i].fEntrances.size() &&
cfg.fBlocks[i].fNodes.size()) {
Position p;
switch (cfg.fBlocks[i].fNodes[0].fKind) {
case BasicBlock::Node::kStatement_Kind:
p = (*cfg.fBlocks[i].fNodes[0].statement())->fPosition;
break;
case BasicBlock::Node::kExpression_Kind:
p = (*cfg.fBlocks[i].fNodes[0].expression())->fPosition;
break;
}
this->error(p, String("unreachable"));
}
}
if (fErrorCount) {
return;
}
// check for dead code & undefined variables, perform constant propagation
std::unordered_set<const Variable*> undefinedVariables;
bool updated;
bool needsRescan = false;
do {
if (needsRescan) {
cfg = CFGGenerator().getCFG(f);
this->computeDataFlow(&cfg);
needsRescan = false;
}
updated = false;
for (BasicBlock& b : cfg.fBlocks) {
DefinitionMap definitions = b.fBefore;
for (auto iter = b.fNodes.begin(); iter != b.fNodes.end() && !needsRescan; ++iter) {
if (iter->fKind == BasicBlock::Node::kExpression_Kind) {
this->simplifyExpression(definitions, b, &iter, &undefinedVariables, &updated,
&needsRescan);
} else {
this->simplifyStatement(definitions, b, &iter, &undefinedVariables, &updated,
&needsRescan);
}
if (needsRescan) {
break;
}
this->addDefinitions(*iter, &definitions);
}
}
} while (updated);
ASSERT(!needsRescan);
// verify static ifs & switches
for (BasicBlock& b : cfg.fBlocks) {
DefinitionMap definitions = b.fBefore;
for (auto iter = b.fNodes.begin(); iter != b.fNodes.end() && !needsRescan; ++iter) {
if (iter->fKind == BasicBlock::Node::kStatement_Kind) {
const Statement& s = **iter->statement();
switch (s.fKind) {
case Statement::kIf_Kind:
if (((const IfStatement&) s).fIsStatic) {
this->error(s.fPosition, "static if has non-static test");
}
break;
case Statement::kSwitch_Kind:
if (((const SwitchStatement&) s).fIsStatic) {
this->error(s.fPosition, "static switch has non-static test");
}
break;
default:
break;
}
}
}
}
// check for missing return
if (f.fDeclaration.fReturnType != *fContext.fVoid_Type) {
if (cfg.fBlocks[cfg.fExit].fEntrances.size()) {
this->error(f.fPosition, String("function can exit without returning a value"));
}
}
}
std::unique_ptr<Program> Compiler::convertProgram(Program::Kind kind, String text,
const Program::Settings& settings) {
fErrorText = "";
fErrorCount = 0;
fIRGenerator->start(&settings);
std::vector<std::unique_ptr<ProgramElement>> elements;
Modifiers::Flag ignored;
switch (kind) {
case Program::kVertex_Kind:
fIRGenerator->convertProgram(String(SKSL_VERT_INCLUDE), *fTypes, &ignored, &elements);
break;
case Program::kFragment_Kind:
fIRGenerator->convertProgram(String(SKSL_FRAG_INCLUDE), *fTypes, &ignored, &elements);
break;
case Program::kGeometry_Kind:
fIRGenerator->convertProgram(String(SKSL_GEOM_INCLUDE), *fTypes, &ignored, &elements);
break;
}
fIRGenerator->fSymbolTable->markAllFunctionsBuiltin();
Modifiers::Flag defaultPrecision;
fIRGenerator->convertProgram(text, *fTypes, &defaultPrecision, &elements);
if (!fErrorCount) {
for (auto& element : elements) {
if (element->fKind == ProgramElement::kFunction_Kind) {
this->scanCFG((FunctionDefinition&) *element);
}
}
}
auto result = std::unique_ptr<Program>(new Program(kind, settings, defaultPrecision, &fContext,
std::move(elements),
fIRGenerator->fSymbolTable,
fIRGenerator->fInputs));
fIRGenerator->finish();
this->writeErrorCount();
if (fErrorCount) {
return nullptr;
}
return result;
}
bool Compiler::toSPIRV(const Program& program, OutputStream& out) {
#ifdef SK_ENABLE_SPIRV_VALIDATION
StringStream buffer;
SPIRVCodeGenerator cg(&fContext, &program, this, &buffer);
bool result = cg.generateCode();
if (result) {
spvtools::SpirvTools tools(SPV_ENV_VULKAN_1_0);
ASSERT(0 == buffer.size() % 4);
auto dumpmsg = [](spv_message_level_t, const char*, const spv_position_t&, const char* m) {
SkDebugf("SPIR-V validation error: %s\n", m);
};
tools.SetMessageConsumer(dumpmsg);
// Verify that the SPIR-V we produced is valid. If this assert fails, check the logs prior
// to the failure to see the validation errors.
ASSERT_RESULT(tools.Validate((const uint32_t*) buffer.data(), buffer.size() / 4));
out.write(buffer.data(), buffer.size());
}
#else
SPIRVCodeGenerator cg(&fContext, &program, this, &out);
bool result = cg.generateCode();
#endif
this->writeErrorCount();
return result;
}
bool Compiler::toSPIRV(const Program& program, String* out) {
StringStream buffer;
bool result = this->toSPIRV(program, buffer);
if (result) {
*out = String(buffer.data(), buffer.size());
}
return result;
}
bool Compiler::toGLSL(const Program& program, OutputStream& out) {
GLSLCodeGenerator cg(&fContext, &program, this, &out);
bool result = cg.generateCode();
this->writeErrorCount();
return result;
}
bool Compiler::toGLSL(const Program& program, String* out) {
StringStream buffer;
bool result = this->toGLSL(program, buffer);
if (result) {
*out = String(buffer.data(), buffer.size());
}
return result;
}
void Compiler::error(Position position, String msg) {
fErrorCount++;
fErrorText += "error: " + position.description() + ": " + msg.c_str() + "\n";
}
String Compiler::errorText() {
String result = fErrorText;
return result;
}
void Compiler::writeErrorCount() {
if (fErrorCount) {
fErrorText += to_string(fErrorCount) + " error";
if (fErrorCount > 1) {
fErrorText += "s";
}
fErrorText += "\n";
}
}
} // namespace