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skia / skia / af8b7cb5ec9d92d4082a9e40a98069e8d49b87d9 / . / src / sksl / SkSLInliner.cpp
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/*
* Copyright 2020 Google LLC
*
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
#include "src/sksl/SkSLInliner.h"
#include "limits.h"
#include <memory>
#include <unordered_set>
#include "src/sksl/SkSLAnalysis.h"
#include "src/sksl/ir/SkSLBinaryExpression.h"
#include "src/sksl/ir/SkSLBoolLiteral.h"
#include "src/sksl/ir/SkSLBreakStatement.h"
#include "src/sksl/ir/SkSLConstructor.h"
#include "src/sksl/ir/SkSLContinueStatement.h"
#include "src/sksl/ir/SkSLDiscardStatement.h"
#include "src/sksl/ir/SkSLDoStatement.h"
#include "src/sksl/ir/SkSLEnum.h"
#include "src/sksl/ir/SkSLExpressionStatement.h"
#include "src/sksl/ir/SkSLExternalFunctionCall.h"
#include "src/sksl/ir/SkSLExternalValueReference.h"
#include "src/sksl/ir/SkSLField.h"
#include "src/sksl/ir/SkSLFieldAccess.h"
#include "src/sksl/ir/SkSLFloatLiteral.h"
#include "src/sksl/ir/SkSLForStatement.h"
#include "src/sksl/ir/SkSLFunctionCall.h"
#include "src/sksl/ir/SkSLFunctionDeclaration.h"
#include "src/sksl/ir/SkSLFunctionDefinition.h"
#include "src/sksl/ir/SkSLFunctionReference.h"
#include "src/sksl/ir/SkSLIfStatement.h"
#include "src/sksl/ir/SkSLIndexExpression.h"
#include "src/sksl/ir/SkSLInlineMarker.h"
#include "src/sksl/ir/SkSLIntLiteral.h"
#include "src/sksl/ir/SkSLInterfaceBlock.h"
#include "src/sksl/ir/SkSLLayout.h"
#include "src/sksl/ir/SkSLNop.h"
#include "src/sksl/ir/SkSLNullLiteral.h"
#include "src/sksl/ir/SkSLPostfixExpression.h"
#include "src/sksl/ir/SkSLPrefixExpression.h"
#include "src/sksl/ir/SkSLReturnStatement.h"
#include "src/sksl/ir/SkSLSetting.h"
#include "src/sksl/ir/SkSLSwitchCase.h"
#include "src/sksl/ir/SkSLSwitchStatement.h"
#include "src/sksl/ir/SkSLSwizzle.h"
#include "src/sksl/ir/SkSLTernaryExpression.h"
#include "src/sksl/ir/SkSLUnresolvedFunction.h"
#include "src/sksl/ir/SkSLVarDeclarations.h"
#include "src/sksl/ir/SkSLVarDeclarationsStatement.h"
#include "src/sksl/ir/SkSLVariable.h"
#include "src/sksl/ir/SkSLVariableReference.h"
#include "src/sksl/ir/SkSLWhileStatement.h"
namespace SkSL {
namespace {
static int count_all_returns(const FunctionDefinition& funcDef) {
class CountAllReturns : public ProgramVisitor {
public:
CountAllReturns(const FunctionDefinition& funcDef) {
this->visitProgramElement(funcDef);
}
bool visitStatement(const Statement& stmt) override {
switch (stmt.kind()) {
case Statement::Kind::kReturn:
++fNumReturns;
[[fallthrough]];
default:
return INHERITED::visitStatement(stmt);
}
}
int fNumReturns = 0;
using INHERITED = ProgramVisitor;
};
return CountAllReturns{funcDef}.fNumReturns;
}
static int count_returns_at_end_of_control_flow(const FunctionDefinition& funcDef) {
class CountReturnsAtEndOfControlFlow : public ProgramVisitor {
public:
CountReturnsAtEndOfControlFlow(const FunctionDefinition& funcDef) {
this->visitProgramElement(funcDef);
}
bool visitStatement(const Statement& stmt) override {
switch (stmt.kind()) {
case Statement::Kind::kBlock: {
// Check only the last statement of a block.
const auto& blockStmts = stmt.as<Block>().fStatements;
return (blockStmts.size() > 0) ? this->visitStatement(*blockStmts.back())
: false;
}
case Statement::Kind::kSwitch:
case Statement::Kind::kWhile:
case Statement::Kind::kDo:
case Statement::Kind::kFor:
// Don't introspect switches or loop structures at all.
return false;
case Statement::Kind::kReturn:
++fNumReturns;
[[fallthrough]];
default:
return INHERITED::visitStatement(stmt);
}
}
int fNumReturns = 0;
using INHERITED = ProgramVisitor;
};
return CountReturnsAtEndOfControlFlow{funcDef}.fNumReturns;
}
static int count_returns_in_breakable_constructs(const FunctionDefinition& funcDef) {
class CountReturnsInBreakableConstructs : public ProgramVisitor {
public:
CountReturnsInBreakableConstructs(const FunctionDefinition& funcDef) {
this->visitProgramElement(funcDef);
}
bool visitStatement(const Statement& stmt) override {
switch (stmt.kind()) {
case Statement::Kind::kSwitch:
case Statement::Kind::kWhile:
case Statement::Kind::kDo:
case Statement::Kind::kFor: {
++fInsideBreakableConstruct;
bool result = INHERITED::visitStatement(stmt);
--fInsideBreakableConstruct;
return result;
}
case Statement::Kind::kReturn:
fNumReturns += (fInsideBreakableConstruct > 0) ? 1 : 0;
[[fallthrough]];
default:
return INHERITED::visitStatement(stmt);
}
}
int fNumReturns = 0;
int fInsideBreakableConstruct = 0;
using INHERITED = ProgramVisitor;
};
return CountReturnsInBreakableConstructs{funcDef}.fNumReturns;
}
static bool has_early_return(const FunctionDefinition& funcDef) {
int returnCount = count_all_returns(funcDef);
if (returnCount == 0) {
return false;
}
int returnsAtEndOfControlFlow = count_returns_at_end_of_control_flow(funcDef);
return returnCount > returnsAtEndOfControlFlow;
}
static bool contains_recursive_call(const FunctionDeclaration& funcDecl) {
class ContainsRecursiveCall : public ProgramVisitor {
public:
bool visit(const FunctionDeclaration& funcDecl) {
fFuncDecl = &funcDecl;
return funcDecl.fDefinition ? this->visitProgramElement(*funcDecl.fDefinition)
: false;
}
bool visitExpression(const Expression& expr) override {
if (expr.is<FunctionCall>() && expr.as<FunctionCall>().fFunction.matches(*fFuncDecl)) {
return true;
}
return INHERITED::visitExpression(expr);
}
bool visitStatement(const Statement& stmt) override {
if (stmt.is<InlineMarker>() && stmt.as<InlineMarker>().fFuncDecl->matches(*fFuncDecl)) {
return true;
}
return INHERITED::visitStatement(stmt);
}
const FunctionDeclaration* fFuncDecl;
using INHERITED = ProgramVisitor;
};
return ContainsRecursiveCall{}.visit(funcDecl);
}
static void ensure_scoped_blocks(Block* inlinedBody, Statement* parentStmt) {
if (parentStmt && (parentStmt->is<IfStatement>() || parentStmt->is<ForStatement>() ||
parentStmt->is<DoStatement>() || parentStmt->is<WhileStatement>())) {
// Occasionally, IR generation can lead to Blocks containing multiple statements, but no
// scope. If this block is used as the statement for a do/for/if/while, this isn't actually
// possible to represent textually; a scope must be added for the generated code to match
// the intent. In the case of Blocks nested inside other Blocks, we add the scope to the
// outermost block if needed. Zero-statement blocks have similar issues--if we don't
// represent the Block textually somehow, we run the risk of accidentally absorbing the
// following statement into our loop--so we also add a scope to these.
for (Block* nestedBlock = inlinedBody;; ) {
if (nestedBlock->fIsScope) {
// We found an explicit scope; all is well.
return;
}
if (nestedBlock->fStatements.size() != 1) {
// We found a block with multiple (or zero) statements, but no scope? Let's add a
// scope to the outermost block.
inlinedBody->fIsScope = true;
return;
}
if (!nestedBlock->fStatements[0]->is<Block>()) {
// This block has exactly one thing inside, and it's not another block. No need to
// scope it.
return;
}
// We have to go deeper.
nestedBlock = &nestedBlock->fStatements[0]->as<Block>();
}
}
}
static const Type* copy_if_needed(const Type* src, SymbolTable& symbolTable) {
if (src->typeKind() == Type::TypeKind::kArray) {
return symbolTable.takeOwnershipOfSymbol(std::make_unique<Type>(*src));
}
return src;
}
static Statement* find_parent_statement(const std::vector<std::unique_ptr<Statement>*>& stmtStack) {
SkASSERT(!stmtStack.empty());
// Walk the statement stack from back to front, ignoring the last element (which is the
// enclosing statement).
auto iter = stmtStack.rbegin();
++iter;
// Anything counts as a parent statement other than a scopeless Block.
for (; iter != stmtStack.rend(); ++iter) {
Statement* stmt = (*iter)->get();
if (!stmt->is<Block>() || stmt->as<Block>().fIsScope) {
return stmt;
}
}
// There wasn't any parent statement to be found.
return nullptr;
}
} // namespace
void Inliner::reset(const Context& context, const Program::Settings& settings) {
fContext = &context;
fSettings = &settings;
fInlineVarCounter = 0;
}
String Inliner::uniqueNameForInlineVar(const String& baseName, SymbolTable* symbolTable) {
// If the base name starts with an underscore, like "_coords", we can't append another
// underscore, because OpenGL disallows two consecutive underscores anywhere in the string. But
// in the general case, using the underscore as a splitter reads nicely enough that it's worth
// putting in this special case.
const char* splitter = baseName.startsWith("_") ? "" : "_";
// Append a unique numeric prefix to avoid name overlap. Check the symbol table to make sure
// we're not reusing an existing name. (Note that within a single compilation pass, this check
// isn't fully comprehensive, as code isn't always generated in top-to-bottom order.)
String uniqueName;
for (;;) {
uniqueName = String::printf("_%d%s%s", fInlineVarCounter++, splitter, baseName.c_str());
StringFragment frag{uniqueName.data(), uniqueName.length()};
if ((*symbolTable)[frag] == nullptr) {
break;
}
}
return uniqueName;
}
std::unique_ptr<Expression> Inliner::inlineExpression(int offset,
VariableRewriteMap* varMap,
const Expression& expression) {
auto expr = [&](const std::unique_ptr<Expression>& e) -> std::unique_ptr<Expression> {
if (e) {
return this->inlineExpression(offset, varMap, *e);
}
return nullptr;
};
auto argList = [&](const std::vector<std::unique_ptr<Expression>>& originalArgs)
-> std::vector<std::unique_ptr<Expression>> {
std::vector<std::unique_ptr<Expression>> args;
args.reserve(originalArgs.size());
for (const std::unique_ptr<Expression>& arg : originalArgs) {
args.push_back(expr(arg));
}
return args;
};
switch (expression.kind()) {
case Expression::Kind::kBinary: {
const BinaryExpression& b = expression.as<BinaryExpression>();
return std::make_unique<BinaryExpression>(offset,
expr(b.fLeft),
b.fOperator,
expr(b.fRight),
&b.type());
}
case Expression::Kind::kBoolLiteral:
case Expression::Kind::kIntLiteral:
case Expression::Kind::kFloatLiteral:
case Expression::Kind::kNullLiteral:
return expression.clone();
case Expression::Kind::kConstructor: {
const Constructor& constructor = expression.as<Constructor>();
return std::make_unique<Constructor>(offset, &constructor.type(),
argList(constructor.fArguments));
}
case Expression::Kind::kExternalFunctionCall: {
const ExternalFunctionCall& externalCall = expression.as<ExternalFunctionCall>();
return std::make_unique<ExternalFunctionCall>(offset, &externalCall.type(),
externalCall.fFunction,
argList(externalCall.fArguments));
}
case Expression::Kind::kExternalValue:
return expression.clone();
case Expression::Kind::kFieldAccess: {
const FieldAccess& f = expression.as<FieldAccess>();
return std::make_unique<FieldAccess>(expr(f.fBase), f.fFieldIndex, f.fOwnerKind);
}
case Expression::Kind::kFunctionCall: {
const FunctionCall& funcCall = expression.as<FunctionCall>();
return std::make_unique<FunctionCall>(offset, &funcCall.type(), funcCall.fFunction,
argList(funcCall.fArguments));
}
case Expression::Kind::kFunctionReference:
return expression.clone();
case Expression::Kind::kIndex: {
const IndexExpression& idx = expression.as<IndexExpression>();
return std::make_unique<IndexExpression>(*fContext, expr(idx.fBase), expr(idx.fIndex));
}
case Expression::Kind::kPrefix: {
const PrefixExpression& p = expression.as<PrefixExpression>();
return std::make_unique<PrefixExpression>(p.fOperator, expr(p.fOperand));
}
case Expression::Kind::kPostfix: {
const PostfixExpression& p = expression.as<PostfixExpression>();
return std::make_unique<PostfixExpression>(expr(p.fOperand), p.fOperator);
}
case Expression::Kind::kSetting:
return expression.clone();
case Expression::Kind::kSwizzle: {
const Swizzle& s = expression.as<Swizzle>();
return std::make_unique<Swizzle>(*fContext, expr(s.fBase), s.fComponents);
}
case Expression::Kind::kTernary: {
const TernaryExpression& t = expression.as<TernaryExpression>();
return std::make_unique<TernaryExpression>(offset, expr(t.fTest),
expr(t.fIfTrue), expr(t.fIfFalse));
}
case Expression::Kind::kTypeReference:
return expression.clone();
case Expression::Kind::kVariableReference: {
const VariableReference& v = expression.as<VariableReference>();
auto found = varMap->find(&v.fVariable);
if (found != varMap->end()) {
return std::make_unique<VariableReference>(offset, *found->second, v.fRefKind);
}
return v.clone();
}
default:
SkASSERT(false);
return nullptr;
}
}
std::unique_ptr<Statement> Inliner::inlineStatement(int offset,
VariableRewriteMap* varMap,
SymbolTable* symbolTableForStatement,
const Variable* returnVar,
bool haveEarlyReturns,
const Statement& statement) {
auto stmt = [&](const std::unique_ptr<Statement>& s) -> std::unique_ptr<Statement> {
if (s) {
return this->inlineStatement(offset, varMap, symbolTableForStatement, returnVar,
haveEarlyReturns, *s);
}
return nullptr;
};
auto stmts = [&](const std::vector<std::unique_ptr<Statement>>& ss) {
std::vector<std::unique_ptr<Statement>> result;
for (const auto& s : ss) {
result.push_back(stmt(s));
}
return result;
};
auto expr = [&](const std::unique_ptr<Expression>& e) -> std::unique_ptr<Expression> {
if (e) {
return this->inlineExpression(offset, varMap, *e);
}
return nullptr;
};
switch (statement.kind()) {
case Statement::Kind::kBlock: {
const Block& b = statement.as<Block>();
return std::make_unique<Block>(offset, stmts(b.fStatements), b.fSymbols, b.fIsScope);
}
case Statement::Kind::kBreak:
case Statement::Kind::kContinue:
case Statement::Kind::kDiscard:
return statement.clone();
case Statement::Kind::kDo: {
const DoStatement& d = statement.as<DoStatement>();
return std::make_unique<DoStatement>(offset, stmt(d.fStatement), expr(d.fTest));
}
case Statement::Kind::kExpression: {
const ExpressionStatement& e = statement.as<ExpressionStatement>();
return std::make_unique<ExpressionStatement>(expr(e.fExpression));
}
case Statement::Kind::kFor: {
const ForStatement& f = statement.as<ForStatement>();
// need to ensure initializer is evaluated first so that we've already remapped its
// declarations by the time we evaluate test & next
std::unique_ptr<Statement> initializer = stmt(f.fInitializer);
return std::make_unique<ForStatement>(offset, std::move(initializer), expr(f.fTest),
expr(f.fNext), stmt(f.fStatement), f.fSymbols);
}
case Statement::Kind::kIf: {
const IfStatement& i = statement.as<IfStatement>();
return std::make_unique<IfStatement>(offset, i.fIsStatic, expr(i.fTest),
stmt(i.fIfTrue), stmt(i.fIfFalse));
}
case Statement::Kind::kInlineMarker:
case Statement::Kind::kNop:
return statement.clone();
case Statement::Kind::kReturn: {
const ReturnStatement& r = statement.as<ReturnStatement>();
if (r.fExpression) {
auto assignment = std::make_unique<ExpressionStatement>(
std::make_unique<BinaryExpression>(
offset,
std::make_unique<VariableReference>(offset, *returnVar,
VariableReference::kWrite_RefKind),
Token::Kind::TK_EQ,
expr(r.fExpression),
&returnVar->type()));
if (haveEarlyReturns) {
std::vector<std::unique_ptr<Statement>> block;
block.push_back(std::move(assignment));
block.emplace_back(new BreakStatement(offset));
return std::make_unique<Block>(offset, std::move(block), /*symbols=*/nullptr,
/*isScope=*/true);
} else {
return std::move(assignment);
}
} else {
if (haveEarlyReturns) {
return std::make_unique<BreakStatement>(offset);
} else {
return std::make_unique<Nop>();
}
}
}
case Statement::Kind::kSwitch: {
const SwitchStatement& ss = statement.as<SwitchStatement>();
std::vector<std::unique_ptr<SwitchCase>> cases;
for (const auto& sc : ss.fCases) {
cases.emplace_back(new SwitchCase(offset, expr(sc->fValue),
stmts(sc->fStatements)));
}
return std::make_unique<SwitchStatement>(offset, ss.fIsStatic, expr(ss.fValue),
std::move(cases), ss.fSymbols);
}
case Statement::Kind::kVarDeclaration: {
const VarDeclaration& decl = statement.as<VarDeclaration>();
std::vector<std::unique_ptr<Expression>> sizes;
for (const auto& size : decl.fSizes) {
sizes.push_back(expr(size));
}
std::unique_ptr<Expression> initialValue = expr(decl.fValue);
const Variable* old = decl.fVar;
// We assign unique names to inlined variables--scopes hide most of the problems in this
// regard, but see `InlinerAvoidsVariableNameOverlap` for a counterexample where unique
// names are important.
auto name = std::make_unique<String>(
this->uniqueNameForInlineVar(String(old->fName), symbolTableForStatement));
const String* namePtr = symbolTableForStatement->takeOwnershipOfString(std::move(name));
const Type* typePtr = copy_if_needed(&old->type(), *symbolTableForStatement);
const Variable* clone = symbolTableForStatement->takeOwnershipOfSymbol(
std::make_unique<Variable>(offset,
old->fModifiers,
namePtr->c_str(),
typePtr,
old->fStorage,
initialValue.get()));
(*varMap)[old] = clone;
return std::make_unique<VarDeclaration>(clone, std::move(sizes),
std::move(initialValue));
}
case Statement::Kind::kVarDeclarations: {
const VarDeclarations& decls = *statement.as<VarDeclarationsStatement>().fDeclaration;
std::vector<std::unique_ptr<VarDeclaration>> vars;
for (const auto& var : decls.fVars) {
vars.emplace_back(&stmt(var).release()->as<VarDeclaration>());
}
const Type* typePtr = copy_if_needed(&decls.fBaseType, *symbolTableForStatement);
return std::unique_ptr<Statement>(new VarDeclarationsStatement(
std::make_unique<VarDeclarations>(offset, typePtr, std::move(vars))));
}
case Statement::Kind::kWhile: {
const WhileStatement& w = statement.as<WhileStatement>();
return std::make_unique<WhileStatement>(offset, expr(w.fTest), stmt(w.fStatement));
}
default:
SkASSERT(false);
return nullptr;
}
}
Inliner::InlinedCall Inliner::inlineCall(FunctionCall* call,
SymbolTable* symbolTableForCall) {
// Inlining is more complicated here than in a typical compiler, because we have to have a
// high-level IR and can't just drop statements into the middle of an expression or even use
// gotos.
//
// Since we can't insert statements into an expression, we run the inline function as extra
// statements before the statement we're currently processing, relying on a lack of execution
// order guarantees. Since we can't use gotos (which are normally used to replace return
// statements), we wrap the whole function in a loop and use break statements to jump to the
// end.
SkASSERT(fSettings);
SkASSERT(fContext);
SkASSERT(call);
SkASSERT(this->isSafeToInline(*call, /*inlineThreshold=*/INT_MAX));
std::vector<std::unique_ptr<Expression>>& arguments = call->fArguments;
const int offset = call->fOffset;
const FunctionDefinition& function = *call->fFunction.fDefinition;
const bool hasEarlyReturn = has_early_return(function);
InlinedCall inlinedCall;
inlinedCall.fInlinedBody = std::make_unique<Block>(offset,
std::vector<std::unique_ptr<Statement>>{},
/*symbols=*/nullptr,
/*isScope=*/false);
std::vector<std::unique_ptr<Statement>>& inlinedBody = inlinedCall.fInlinedBody->fStatements;
inlinedBody.reserve(1 + // Inline marker
1 + // Result variable
arguments.size() + // Function arguments (passing in)
arguments.size() + // Function arguments (copy out-parameters back)
1); // Inlined code (either as a Block or do-while loop)
inlinedBody.push_back(std::make_unique<InlineMarker>(call->fFunction));
auto makeInlineVar = [&](const String& baseName, const Type* type, Modifiers modifiers,
std::unique_ptr<Expression>* initialValue) -> const Variable* {
// $floatLiteral or $intLiteral aren't real types that we can use for scratch variables, so
// replace them if they ever appear here. If this happens, we likely forgot to coerce a type
// somewhere during compilation.
if (type == fContext->fFloatLiteral_Type.get()) {
SkDEBUGFAIL("found a $floatLiteral type while inlining");
type = fContext->fFloat_Type.get();
} else if (type == fContext->fIntLiteral_Type.get()) {
SkDEBUGFAIL("found an $intLiteral type while inlining");
type = fContext->fInt_Type.get();
}
// Provide our new variable with a unique name, and add it to our symbol table.
String uniqueName = this->uniqueNameForInlineVar(baseName, symbolTableForCall);
const String* namePtr = symbolTableForCall->takeOwnershipOfString(
std::make_unique<String>(std::move(uniqueName)));
StringFragment nameFrag{namePtr->c_str(), namePtr->length()};
// Add our new variable to the symbol table.
auto newVar = std::make_unique<Variable>(/*offset=*/-1, Modifiers(), nameFrag, type,
Variable::kLocal_Storage, initialValue->get());
const Variable* variableSymbol = symbolTableForCall->add(nameFrag, std::move(newVar));
// Prepare the variable declaration (taking extra care with `out` params to not clobber any
// initial value).
std::vector<std::unique_ptr<VarDeclaration>> variables;
if (initialValue && (modifiers.fFlags & Modifiers::kOut_Flag)) {
variables.push_back(std::make_unique<VarDeclaration>(
variableSymbol, /*sizes=*/std::vector<std::unique_ptr<Expression>>{},
(*initialValue)->clone()));
} else {
variables.push_back(std::make_unique<VarDeclaration>(
variableSymbol, /*sizes=*/std::vector<std::unique_ptr<Expression>>{},
std::move(*initialValue)));
}
// Add the new variable-declaration statement to our block of extra statements.
inlinedBody.push_back(std::make_unique<VarDeclarationsStatement>(
std::make_unique<VarDeclarations>(offset, type, std::move(variables))));
return variableSymbol;
};
// Create a variable to hold the result in the extra statements (excepting void).
const Variable* resultVar = nullptr;
if (function.fDeclaration.fReturnType != *fContext->fVoid_Type) {
std::unique_ptr<Expression> noInitialValue;
resultVar = makeInlineVar(String(function.fDeclaration.fName),
&function.fDeclaration.fReturnType, Modifiers{}, &noInitialValue);
}
// Create variables in the extra statements to hold the arguments, and assign the arguments to
// them.
VariableRewriteMap varMap;
for (int i = 0; i < (int) arguments.size(); ++i) {
const Variable* param = function.fDeclaration.fParameters[i];
if (arguments[i]->is<VariableReference>()) {
// The argument is just a variable, so we only need to copy it if it's an out parameter
// or it's written to within the function.
if ((param->fModifiers.fFlags & Modifiers::kOut_Flag) ||
!Analysis::StatementWritesToVariable(*function.fBody, *param)) {
varMap[param] = &arguments[i]->as<VariableReference>().fVariable;
continue;
}
}
varMap[param] = makeInlineVar(String(param->fName), &arguments[i]->type(),
param->fModifiers, &arguments[i]);
}
const Block& body = function.fBody->as<Block>();
auto inlineBlock = std::make_unique<Block>(offset, std::vector<std::unique_ptr<Statement>>{});
inlineBlock->fStatements.reserve(body.fStatements.size());
for (const std::unique_ptr<Statement>& stmt : body.fStatements) {
inlineBlock->fStatements.push_back(this->inlineStatement(
offset, &varMap, symbolTableForCall, resultVar, hasEarlyReturn, *stmt));
}
if (hasEarlyReturn) {
// Since we output to backends that don't have a goto statement (which would normally be
// used to perform an early return), we fake it by wrapping the function in a
// do { } while (false); and then use break statements to jump to the end in order to
// emulate a goto.
inlinedBody.push_back(std::make_unique<DoStatement>(
/*offset=*/-1,
std::move(inlineBlock),
std::make_unique<BoolLiteral>(*fContext, offset, /*value=*/false)));
} else {
// No early returns, so we can just dump the code in. We still need to keep the block so we
// don't get name conflicts with locals.
inlinedBody.push_back(std::move(inlineBlock));
}
// Copy the values of `out` parameters into their destinations.
for (size_t i = 0; i < arguments.size(); ++i) {
const Variable* p = function.fDeclaration.fParameters[i];
if (p->fModifiers.fFlags & Modifiers::kOut_Flag) {
SkASSERT(varMap.find(p) != varMap.end());
if (arguments[i]->kind() == Expression::Kind::kVariableReference &&
&arguments[i]->as<VariableReference>().fVariable == varMap[p]) {
// We didn't create a temporary for this parameter, so there's nothing to copy back
// out.
continue;
}
auto varRef = std::make_unique<VariableReference>(offset, *varMap[p]);
inlinedBody.push_back(std::make_unique<ExpressionStatement>(
std::make_unique<BinaryExpression>(offset,
arguments[i]->clone(),
Token::Kind::TK_EQ,
std::move(varRef),
&arguments[i]->type())));
}
}
if (function.fDeclaration.fReturnType != *fContext->fVoid_Type) {
// Return a reference to the result variable as our replacement expression.
inlinedCall.fReplacementExpr = std::make_unique<VariableReference>(offset, *resultVar);
} else {
// It's a void function, so it doesn't actually result in anything, but we have to return
// something non-null as a standin.
inlinedCall.fReplacementExpr = std::make_unique<BoolLiteral>(*fContext, offset,
/*value=*/false);
}
return inlinedCall;
}
bool Inliner::isSafeToInline(const FunctionCall& functionCall, int inlineThreshold) {
SkASSERT(fSettings);
if (functionCall.fFunction.fDefinition == nullptr) {
// Can't inline something if we don't actually have its definition.
return false;
}
const FunctionDefinition& functionDef = *functionCall.fFunction.fDefinition;
if (inlineThreshold < INT_MAX) {
if (!(functionDef.fDeclaration.fModifiers.fFlags & Modifiers::kInline_Flag) &&
Analysis::NodeCount(functionDef) >= inlineThreshold) {
// The function exceeds our maximum inline size and is not flagged 'inline'.
return false;
}
}
if (!fSettings->fCaps || !fSettings->fCaps->canUseDoLoops()) {
// We don't have do-while loops. We use do-while loops to simulate early returns, so we
// can't inline functions that have an early return.
bool hasEarlyReturn = has_early_return(functionDef);
// If we didn't detect an early return, there shouldn't be any returns in breakable
// constructs either.
SkASSERT(hasEarlyReturn || count_returns_in_breakable_constructs(functionDef) == 0);
return !hasEarlyReturn;
}
// We have do-while loops, but we don't have any mechanism to simulate early returns within a
// breakable construct (switch/for/do/while), so we can't inline if there's a return inside one.
bool hasReturnInBreakableConstruct = (count_returns_in_breakable_constructs(functionDef) > 0);
// If we detected returns in breakable constructs, we should also detect an early return.
SkASSERT(!hasReturnInBreakableConstruct || has_early_return(functionDef));
return !hasReturnInBreakableConstruct;
}
bool Inliner::analyze(Program& program) {
// A candidate function for inlining, containing everything that `inlineCall` needs.
struct InlineCandidate {
SymbolTable* fSymbols; // the SymbolTable of the candidate
Statement* fParentStmt; // the parent Statement of the enclosing stmt
std::unique_ptr<Statement>* fEnclosingStmt; // the Statement containing the candidate
std::unique_ptr<Expression>* fCandidateExpr; // the candidate FunctionCall to be inlined
};
// This is structured much like a ProgramVisitor, but does not actually use ProgramVisitor.
// The analyzer needs to keep track of the `unique_ptr<T>*` of statements and expressions so
// that they can later be replaced, and ProgramVisitor does not provide this; it only provides a
// `const T&`.
class InlineCandidateAnalyzer {
public:
// A list of all the inlining candidates we found during analysis.
std::vector<InlineCandidate> fInlineCandidates;
// A stack of the symbol tables; since most nodes don't have one, expected to be shallower
// than the enclosing-statement stack.
std::vector<SymbolTable*> fSymbolTableStack;
// A stack of "enclosing" statements--these would be suitable for the inliner to use for
// adding new instructions. Not all statements are suitable (e.g. a for-loop's initializer).
// The inliner might replace a statement with a block containing the statement.
std::vector<std::unique_ptr<Statement>*> fEnclosingStmtStack;
void visit(Program& program) {
fSymbolTableStack.push_back(program.fSymbols.get());
for (ProgramElement& pe : program) {
this->visitProgramElement(&pe);
}
fSymbolTableStack.pop_back();
}
void visitProgramElement(ProgramElement* pe) {
switch (pe->kind()) {
case ProgramElement::Kind::kFunction: {
FunctionDefinition& funcDef = pe->as<FunctionDefinition>();
this->visitStatement(&funcDef.fBody);
break;
}
default:
// The inliner can't operate outside of a function's scope.
break;
}
}
void visitStatement(std::unique_ptr<Statement>* stmt,
bool isViableAsEnclosingStatement = true) {
if (!*stmt) {
return;
}
size_t oldEnclosingStmtStackSize = fEnclosingStmtStack.size();
size_t oldSymbolStackSize = fSymbolTableStack.size();
if (isViableAsEnclosingStatement) {
fEnclosingStmtStack.push_back(stmt);
}
switch ((*stmt)->kind()) {
case Statement::Kind::kBreak:
case Statement::Kind::kContinue:
case Statement::Kind::kDiscard:
case Statement::Kind::kInlineMarker:
case Statement::Kind::kNop:
break;
case Statement::Kind::kBlock: {
Block& block = (*stmt)->as<Block>();
if (block.fSymbols) {
fSymbolTableStack.push_back(block.fSymbols.get());
}
for (std::unique_ptr<Statement>& blockStmt : block.fStatements) {
this->visitStatement(&blockStmt);
}
break;
}
case Statement::Kind::kDo: {
DoStatement& doStmt = (*stmt)->as<DoStatement>();
// The loop body is a candidate for inlining.
this->visitStatement(&doStmt.fStatement);
// The inliner isn't smart enough to inline the test-expression for a do-while
// loop at this time. There are two limitations:
// - We would need to insert the inlined-body block at the very end of the do-
// statement's inner fStatement. We don't support that today, but it's doable.
// - We cannot inline the test expression if the loop uses `continue` anywhere;
// that would skip over the inlined block that evaluates the test expression.
// There isn't a good fix for this--any workaround would be more complex than
// the cost of a function call. However, loops that don't use `continue` would
// still be viable candidates for inlining.
break;
}
case Statement::Kind::kExpression: {
ExpressionStatement& expr = (*stmt)->as<ExpressionStatement>();
this->visitExpression(&expr.fExpression);
break;
}
case Statement::Kind::kFor: {
ForStatement& forStmt = (*stmt)->as<ForStatement>();
if (forStmt.fSymbols) {
fSymbolTableStack.push_back(forStmt.fSymbols.get());
}
// The initializer and loop body are candidates for inlining.
this->visitStatement(&forStmt.fInitializer,
/*isViableAsEnclosingStatement=*/false);
this->visitStatement(&forStmt.fStatement);
// The inliner isn't smart enough to inline the test- or increment-expressions
// of a for loop loop at this time. There are a handful of limitations:
// - We would need to insert the test-expression block at the very beginning of
// the for-loop's inner fStatement, and the increment-expression block at the
// very end. We don't support that today, but it's doable.
// - The for-loop's built-in test-expression would need to be dropped entirely,
// and the loop would be halted via a break statement at the end of the
// inlined test-expression. This is again something we don't support today,
// but it could be implemented.
// - We cannot inline the increment-expression if the loop uses `continue`
// anywhere; that would skip over the inlined block that evaluates the
// increment expression. There isn't a good fix for this--any workaround would
// be more complex than the cost of a function call. However, loops that don't
// use `continue` would still be viable candidates for increment-expression
// inlining.
break;
}
case Statement::Kind::kIf: {
IfStatement& ifStmt = (*stmt)->as<IfStatement>();
this->visitExpression(&ifStmt.fTest);
this->visitStatement(&ifStmt.fIfTrue);
this->visitStatement(&ifStmt.fIfFalse);
break;
}
case Statement::Kind::kReturn: {
ReturnStatement& returnStmt = (*stmt)->as<ReturnStatement>();
this->visitExpression(&returnStmt.fExpression);
break;
}
case Statement::Kind::kSwitch: {
SwitchStatement& switchStmt = (*stmt)->as<SwitchStatement>();
if (switchStmt.fSymbols) {
fSymbolTableStack.push_back(switchStmt.fSymbols.get());
}
this->visitExpression(&switchStmt.fValue);
for (std::unique_ptr<SwitchCase>& switchCase : switchStmt.fCases) {
// The switch-case's fValue cannot be a FunctionCall; skip it.
for (std::unique_ptr<Statement>& caseBlock : switchCase->fStatements) {
this->visitStatement(&caseBlock);
}
}
break;
}
case Statement::Kind::kVarDeclaration: {
VarDeclaration& varDeclStmt = (*stmt)->as<VarDeclaration>();
// Don't need to scan the declaration's sizes; those are always IntLiterals.
this->visitExpression(&varDeclStmt.fValue);
break;
}
case Statement::Kind::kVarDeclarations: {
VarDeclarationsStatement& varDecls = (*stmt)->as<VarDeclarationsStatement>();
for (std::unique_ptr<Statement>& varDecl : varDecls.fDeclaration->fVars) {
this->visitStatement(&varDecl, /*isViableAsEnclosingStatement=*/false);
}
break;
}
case Statement::Kind::kWhile: {
WhileStatement& whileStmt = (*stmt)->as<WhileStatement>();
// The loop body is a candidate for inlining.
this->visitStatement(&whileStmt.fStatement);
// The inliner isn't smart enough to inline the test-expression for a while
// loop at this time. There are two limitations:
// - We would need to insert the inlined-body block at the very beginning of the
// while loop's inner fStatement. We don't support that today, but it's
// doable.
// - The while-loop's built-in test-expression would need to be replaced with a
// `true` BoolLiteral, and the loop would be halted via a break statement at
// the end of the inlined test-expression. This is again something we don't
// support today, but it could be implemented.
break;
}
default:
SkUNREACHABLE;
}
// Pop our symbol and enclosing-statement stacks.
fSymbolTableStack.resize(oldSymbolStackSize);
fEnclosingStmtStack.resize(oldEnclosingStmtStackSize);
}
void visitExpression(std::unique_ptr<Expression>* expr) {
if (!*expr) {
return;
}
switch ((*expr)->kind()) {
case Expression::Kind::kBoolLiteral:
case Expression::Kind::kDefined:
case Expression::Kind::kExternalValue:
case Expression::Kind::kFieldAccess:
case Expression::Kind::kFloatLiteral:
case Expression::Kind::kFunctionReference:
case Expression::Kind::kIntLiteral:
case Expression::Kind::kNullLiteral:
case Expression::Kind::kSetting:
case Expression::Kind::kTypeReference:
case Expression::Kind::kVariableReference:
// Nothing to scan here.
break;
case Expression::Kind::kBinary: {
BinaryExpression& binaryExpr = (*expr)->as<BinaryExpression>();
this->visitExpression(&binaryExpr.fLeft);
// Logical-and and logical-or binary expressions do not inline the right side,
// because that would invalidate short-circuiting. That is, when evaluating
// expressions like these:
// (false && x()) // always false
// (true || y()) // always true
// It is illegal for side-effects from x() or y() to occur. The simplest way to
// enforce that rule is to avoid inlining the right side entirely. However, it
// is safe for other types of binary expression to inline both sides.
bool shortCircuitable = (binaryExpr.fOperator == Token::Kind::TK_LOGICALAND ||
binaryExpr.fOperator == Token::Kind::TK_LOGICALOR);
if (!shortCircuitable) {
this->visitExpression(&binaryExpr.fRight);
}
break;
}
case Expression::Kind::kConstructor: {
Constructor& constructorExpr = (*expr)->as<Constructor>();
for (std::unique_ptr<Expression>& arg : constructorExpr.fArguments) {
this->visitExpression(&arg);
}
break;
}
case Expression::Kind::kExternalFunctionCall: {
ExternalFunctionCall& funcCallExpr = (*expr)->as<ExternalFunctionCall>();
for (std::unique_ptr<Expression>& arg : funcCallExpr.fArguments) {
this->visitExpression(&arg);
}
break;
}
case Expression::Kind::kFunctionCall: {
FunctionCall& funcCallExpr = (*expr)->as<FunctionCall>();
for (std::unique_ptr<Expression>& arg : funcCallExpr.fArguments) {
this->visitExpression(&arg);
}
this->addInlineCandidate(expr);
break;
}
case Expression::Kind::kIndex:{
IndexExpression& indexExpr = (*expr)->as<IndexExpression>();
this->visitExpression(&indexExpr.fBase);
this->visitExpression(&indexExpr.fIndex);
break;
}
case Expression::Kind::kPostfix: {
PostfixExpression& postfixExpr = (*expr)->as<PostfixExpression>();
this->visitExpression(&postfixExpr.fOperand);
break;
}
case Expression::Kind::kPrefix: {
PrefixExpression& prefixExpr = (*expr)->as<PrefixExpression>();
this->visitExpression(&prefixExpr.fOperand);
break;
}
case Expression::Kind::kSwizzle: {
Swizzle& swizzleExpr = (*expr)->as<Swizzle>();
this->visitExpression(&swizzleExpr.fBase);
break;
}
case Expression::Kind::kTernary: {
TernaryExpression& ternaryExpr = (*expr)->as<TernaryExpression>();
// The test expression is a candidate for inlining.
this->visitExpression(&ternaryExpr.fTest);
// The true- and false-expressions cannot be inlined, because we are only
// allowed to evaluate one side.
break;
}
default:
SkUNREACHABLE;
}
}
void addInlineCandidate(std::unique_ptr<Expression>* candidate) {
fInlineCandidates.push_back(InlineCandidate{fSymbolTableStack.back(),
find_parent_statement(fEnclosingStmtStack),
fEnclosingStmtStack.back(),
candidate});
}
};
InlineCandidateAnalyzer analyzer;
analyzer.visit(program);
// For each of our candidate function-call sites, check if it is actually safe to inline.
// Memoize our results so we don't check a function more than once.
std::unordered_map<const FunctionDeclaration*, bool> inlinableMap; // <function, safe-to-inline>
for (const InlineCandidate& candidate : analyzer.fInlineCandidates) {
const FunctionCall& funcCall = (*candidate.fCandidateExpr)->as<FunctionCall>();
const FunctionDeclaration* funcDecl = &funcCall.fFunction;
if (inlinableMap.find(funcDecl) == inlinableMap.end()) {
// We do not perform inlining on recursive calls to avoid an infinite death spiral of
// inlining.
int inlineThreshold = (funcDecl->fCallCount.load() > 1) ? fSettings->fInlineThreshold
: INT_MAX;
inlinableMap[funcDecl] = this->isSafeToInline(funcCall, inlineThreshold) &&
!contains_recursive_call(*funcDecl);
}
}
// Inline the candidates where we've determined that it's safe to do so.
std::unordered_set<const std::unique_ptr<Statement>*> enclosingStmtSet;
bool madeChanges = false;
for (const InlineCandidate& candidate : analyzer.fInlineCandidates) {
FunctionCall& funcCall = (*candidate.fCandidateExpr)->as<FunctionCall>();
const FunctionDeclaration* funcDecl = &funcCall.fFunction;
// If we determined that this candidate was not actually inlinable, skip it.
if (!inlinableMap[funcDecl]) {
continue;
}
// Inlining two expressions using the same enclosing statement in the same inlining pass
// does not work properly. If this happens, skip it; we'll get it in the next pass.
auto [unusedIter, inserted] = enclosingStmtSet.insert(candidate.fEnclosingStmt);
if (!inserted) {
continue;
}
// Convert the function call to its inlined equivalent.
InlinedCall inlinedCall = this->inlineCall(&funcCall, candidate.fSymbols);
if (inlinedCall.fInlinedBody) {
// Ensure that the inlined body has a scope if it needs one.
ensure_scoped_blocks(inlinedCall.fInlinedBody.get(), candidate.fParentStmt);
// Move the enclosing statement to the end of the unscoped Block containing the inlined
// function, then replace the enclosing statement with that Block.
// Before:
// fInlinedBody = Block{ stmt1, stmt2, stmt3 }
// fEnclosingStmt = stmt4
// After:
// fInlinedBody = null
// fEnclosingStmt = Block{ stmt1, stmt2, stmt3, stmt4 }
inlinedCall.fInlinedBody->fStatements.push_back(std::move(*candidate.fEnclosingStmt));
*candidate.fEnclosingStmt = std::move(inlinedCall.fInlinedBody);
}
// Replace the candidate function call with our replacement expression.
*candidate.fCandidateExpr = std::move(inlinedCall.fReplacementExpr);
madeChanges = true;
// Note that nothing was destroyed except for the FunctionCall. All other nodes should
// remain valid.
}
return madeChanges;
}
} // namespace SkSL