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/*
 * Copyright 2009 The Closure Compiler Authors.
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
 * You may obtain a copy of the License at
 *
 *     http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */

package com.google.javascript.jscomp;

import static com.google.common.base.Preconditions.checkState;

import com.google.common.annotations.VisibleForTesting;
import com.google.common.base.Preconditions;
import com.google.javascript.jscomp.AbstractCompiler.LifeCycleStage;
import com.google.javascript.jscomp.OptimizeCalls.ReferenceMap;
import com.google.javascript.rhino.IR;
import com.google.javascript.rhino.Node;
import java.util.ArrayList;
import java.util.BitSet;
import java.util.List;
import java.util.Map.Entry;
import javax.annotation.Nullable;

/**
 * Optimize function calls and function signatures.
 *
 * 
    *
  • Removes optional parameters if no caller specifies it as argument.
  • *
  • Removes arguments at call site to function that ignores the parameter.
  • *
  • Inline a parameter if the function is always called with that constant.
  • *
* * @author [email protected] (John Lenz) */ class OptimizeParameters implements CompilerPass, OptimizeCalls.CallGraphCompilerPass { private final AbstractCompiler compiler; private Scope globalScope; OptimizeParameters(AbstractCompiler compiler) { this.compiler = compiler; } @Override @VisibleForTesting public void process(Node externs, Node root) { checkState(compiler.getLifeCycleStage() == LifeCycleStage.NORMALIZED); ReferenceMap refMap = OptimizeCalls.buildPropAndGlobalNameReferenceMap( compiler, externs, root); process(externs, root, refMap); } @Override public void process(Node externs, Node root, ReferenceMap refMap) { this.globalScope = refMap.getGlobalScope(); // Find all function nodes whose callers ignore the return values. List> toOptimize = new ArrayList<>(); for (Entry> entry : refMap.getNameReferences()) { String key = entry.getKey(); ArrayList refs = entry.getValue(); if (isCandidate(key, refs)) { toOptimize.add(refs); } } for (Entry> entry : refMap.getPropReferences()) { String key = entry.getKey(); ArrayList refs = entry.getValue(); if (isCandidate(key, refs)) { toOptimize.add(refs); } } // NOTE: The optimization that are perform must be careful to keep the // ReferenceMap in a consistent state. They should be careful to not // remove or add global references without update the reference map. // While adding references to the map is O(1), removing references // O(n) where (n) is the number of references. // // So the most transformative pass should be last. So: // // - Removing parameters not provided by any call-site only // moves the name and default values from the parameter list to the // functions' bodies, so no updates are needed if the same node // are reused. // // - Moving parameters that are provided the same value by every // call-site to the function bodies, is currently limited to cases // where there are only one function definition, so no updates // are needed if the same nodes are reused. // // - Removing parameters that are unreferenced from call-sites, may // remove references, as it is run last. for (ArrayList refs : toOptimize) { tryEliminateOptionalArgs(refs); } for (ArrayList refs : toOptimize) { tryEliminateConstantArgs(refs); } // tryEliminateUnusedArgs may mutate UnusedParameterOptimizer optimizer = new UnusedParameterOptimizer(); for (ArrayList refs : toOptimize) { optimizer.tryEliminateUnusedArgs(refs); } optimizer.applyChanges(); } class UnusedParameterOptimizer { final List toRemove = new ArrayList<>(); final List toReplaceWithZero = new ArrayList<>(); /** * Attempt to eliminate unused parameters by removing them from both the call sites * and the function definitions. * * An unused first parameter: * function foo(a, b) {use(b);} * foo(1,2); * foo(1,3) * becomes * function foo(b) {use(b);} * foo(2); * foo(3); * * @param refs A list of references to the symbol (name or property) as vetted by * #isCandidate. */ void tryEliminateUnusedArgs(ArrayList refs) { // An argument is unused if its position is greater than the number of declared parameters // or if it marked as unused. List fns = ReferenceMap.getFunctionNodes(refs); Preconditions.checkState(!fns.isEmpty()); // Examine all function definitions that are ever assigned to the symbol to determine: // 1. Which formal parameter positions are used by at least one of the definitions? // 2. What is the largest number of formal parameters across all of the functions? // 3. The lowest formal parameter position that contains a rest parameter that is used. // e.g. // foo = function(used0, unused1, ...usedRest) {} // foo = function(unused0, ...unusedRest) {} // In this case maxFormalsCount = 3, lowestUsedRest = 2, and used = { 0, 2 } int maxFormalsCount = 0; int lowestUsedRest = Integer.MAX_VALUE; BitSet used = new BitSet(); for (Node fn : fns) { Node paramList = NodeUtil.getFunctionParameters(fn); int index = -1; for (Node c = paramList.getFirstChild(); c != null; c = c.getNext()) { index++; if (!c.isUnusedParameter()) { used.set(index); if (c.isRest()) { lowestUsedRest = Math.min(lowestUsedRest, index); if (lowestUsedRest == 0) { // don't bother doing anything more, all the parameters are used. return; } } } } maxFormalsCount = Math.max(maxFormalsCount, index + 1); } // every argument slot after the earliest rest is used if (lowestUsedRest < maxFormalsCount) { used.set(lowestUsedRest, maxFormalsCount); } BitSet unused = ((BitSet) used.clone()); unused.flip(0, maxFormalsCount); // If was a used "rest" declaration, there are no trailing parameters to remove, so // bail out now if there are no unused formals. if (lowestUsedRest < maxFormalsCount && unused.cardinality() == 0) { return; } // NOTE: RemoveUnusedCode removes any trailing unused formals, so we don't need to // do for that case. BitSet unremovable = ((BitSet) used.clone()); // A parameter is removable from a call-site if the parameter value // has no side-effects. If all call-sites can be updated, the // parameter can be removed from the function definitions. // Regardless, the side-effect free values can still be replaced // with a simpler expression. // 3 values determine the range of removable parameters: // the number of formal parameters, the unused parameters bitset, // and the position of a used rest parameter (if any). // - If the parameter index is higher >= the "rest", it // is not a candidate, otherwise if it is in bitset or // the greater than the declared formals. // To be removed, the candidate must be side-effect free. // If not all candidates can be removed, the removable // candidates are still removed if there are no following parameters. // If there are following parameters the removable candidates are // replaced with a literal zero instead. // Build a list of parameters to remove int lowestSpread = Integer.MAX_VALUE; for (Node n : refs) { if (ReferenceMap.isCallOrNewTarget(n)) { Node param = ReferenceMap.getFirstArgumentForCallOrNewOrDotCall(n); int paramIndex = 0; while (param != null) { if (paramIndex >= maxFormalsCount) { break; } if (param.isSpread()) { lowestSpread = Math.min(lowestSpread, paramIndex); break; } if (!unremovable.get(paramIndex) && NodeUtil.mayHaveSideEffects(param, compiler)) { unremovable.set(paramIndex); } param = param.getNext(); paramIndex++; } } } // Although, a spread prevents the removal of it and all following used slots, it doesn't // prevent the replacement of unused values from other call sites if (lowestSpread < maxFormalsCount) { unremovable.set(lowestSpread, maxFormalsCount); } // Only remove trailing parameters if there isn't a rest arguments in any of the // definition sites. int removeAllAfterIndex = Integer.MAX_VALUE; if (lowestUsedRest == Integer.MAX_VALUE) { removeAllAfterIndex = maxFormalsCount - 1; } for (Node n : refs) { if (ReferenceMap.isCallOrNewTarget(n) && !alreadyRemoved(n)) { Node arg = ReferenceMap.getFirstArgumentForCallOrNewOrDotCall(n); recordRemovalCallArguments( lowestUsedRest, removeAllAfterIndex, unused, unremovable, arg, 0); } } for (Node fn : fns) { Node paramList = NodeUtil.getFunctionParameters(fn); Node param = paramList.getFirstChild(); removeUnusedFunctionParameters(unremovable, param, 0); } } // Either firstRestIndex will be MAX_VALUE or removeAllAfterIndex will be MAX_VALUE void recordRemovalCallArguments( int firstRestIndex, int removeAllAfterIndex, BitSet unused, BitSet unremovable, Node arg, int index) { if (arg == null) { return; } if (index > removeAllAfterIndex) { removeArgAndFollowing(arg); return; } if (arg.isSpread()) { // There is no meaningful "index" after a spread. return; } recordRemovalCallArguments( firstRestIndex, removeAllAfterIndex, unused, unremovable, arg.getNext(), index + 1); if (index < firstRestIndex && unused.get(index)) { if (!NodeUtil.mayHaveSideEffects(arg, compiler)) { if (unremovable.get(index)) { if (!arg.isNumber() || arg.getDouble() != 0) { toReplaceWithZero.add(arg); } } else { toRemove.add(arg); } } } } void removeArgAndFollowing(Node arg) { if (arg != null) { removeArgAndFollowing(arg.getNext()); if (!NodeUtil.mayHaveSideEffects(arg, compiler)) { toRemove.add(arg); } } } void removeUnusedFunctionParameters(BitSet unremovable, Node param, int index) { if (param != null) { removeUnusedFunctionParameters(unremovable, param.getNext(), index + 1); if (!unremovable.get(index)) { checkState(param.isName()); // update for ES6 // params are not otherwise referenceable. compiler.reportChangeToEnclosingScope(param); param.detach(); } } } /** * Applies optimizations to all previously marked nodes. */ public void applyChanges() { for (Node n : toRemove) { // Don't remove any nodes twice since doing so would violate change reporting constraints. if (alreadyRemoved(n)) { continue; } compiler.reportChangeToEnclosingScope(n); n.detach(); NodeUtil.markFunctionsDeleted(n, compiler); } for (Node n : toReplaceWithZero) { Preconditions.checkState(!n.isNumber() || n.getDouble() != 0.0); // Don't remove any nodes twice since doing so would violate change reporting constraints. if (alreadyRemoved(n)) { continue; } compiler.reportChangeToEnclosingScope(n); n.replaceWith(IR.number(0).srcref(n)); NodeUtil.markFunctionsDeleted(n, compiler); } } } private static boolean alreadyRemoved(Node n) { Node parent = n.getParent(); while (parent != null) { n = parent; parent = n.getParent(); } return !n.isRoot(); } /** * This reference set is a candidate for parameter-moving if: * - if all call sites are known (no aliasing) * - if all definition sites are known (the possible values are known functions) * - there is at least one definition */ private boolean isCandidate(String name, ArrayList refs) { if (!OptimizeCalls.mayBeOptimizableName(compiler, name)) { return false; } boolean seenCandidateDefiniton = false; boolean seenCandidateUse = false; for (Node n : refs) { // TODO(johnlenz): Determine what to do about ".constructor" references. // Currently classes that are super classes or have superclasses aren't optimized // // if (parent.isCall() && n != parent.getFirstChild() && isClassDefiningCall(parent)) { // continue; // } else if (ReferenceMap.isCallOrNewTarget(n)) { // TODO(johnlenz): filter .apply when we support it seenCandidateUse = true; } else if (isCandidateDefinition(n)) { seenCandidateDefiniton = true; } else { // If this isn't an non-aliasing reference (typeof, instanceof, etc) // then there is nothing that can be done. if (!OptimizeCalls.isAllowedReference(n)) { // TODO(johnlenz): allow extends clauses. return false; } } } return seenCandidateDefiniton && seenCandidateUse; } private boolean isCandidateDefinition(Node n) { Node parent = n.getParent(); if (parent.isFunction() && NodeUtil.isFunctionDeclaration(parent)) { return allDefinitionsAreCandidateFunctions(parent); } else if (ReferenceMap.isSimpleAssignmentTarget(n)) { if (allDefinitionsAreCandidateFunctions(parent.getLastChild())) { return true; } } else if (n.isName() && n.hasChildren()) { if (allDefinitionsAreCandidateFunctions(n.getFirstChild())) { return true; } } else if (isClassMemberDefinition(n)) { return true; } return false; } private boolean isClassMemberDefinition(Node n) { return n.isMemberFunctionDef() && n.getParent().isClassMembers(); } private static boolean allDefinitionsAreCandidateFunctions(Node n) { switch (n.getToken()) { case FUNCTION: // Named function expression can refer to themselves, // "arguments" can refer to all parameters or their count, // so they are not candidates. return !NodeUtil.isNamedFunctionExpression(n) && !NodeUtil.doesFunctionReferenceOwnArgumentsObject(n); case CAST: case COMMA: return allDefinitionsAreCandidateFunctions(n.getLastChild()); case HOOK: return allDefinitionsAreCandidateFunctions(n.getSecondChild()) && allDefinitionsAreCandidateFunctions(n.getLastChild()); case OR: case AND: return allDefinitionsAreCandidateFunctions(n.getFirstChild()) && allDefinitionsAreCandidateFunctions(n.getLastChild()); default: return false; } } /** * Removes any optional parameters if no callers specifies it as an argument. */ private void tryEliminateOptionalArgs(ArrayList refs) { // Count the maximum number of arguments passed into this function all // all points of the program. int maxArgs = -1; for (Node n : refs) { if (ReferenceMap.isCallOrNewTarget(n)) { int numArgs = 0; Node firstArg = ReferenceMap.getFirstArgumentForCallOrNewOrDotCall(n); for (Node c = firstArg; c != null; c = c.getNext()) { numArgs++; if (c.isSpread()) { // Bail: with spread we must assume all parameters are used, don't waste // any more time. return; } } if (numArgs > maxArgs) { maxArgs = numArgs; } } } for (Node fn : ReferenceMap.getFunctionNodes(refs)) { eliminateParamsAfter(fn, maxArgs); } } /** * Eliminate parameters if they are always constant. * * function foo(a, b) {...} * foo(1,2); * foo(1,3) * becomes * function foo(b) { var a = 1 ... } * foo(2); * foo(3); * * @param refs A list of references to the symbol (name or property) as vetted by * #isCandidate. */ private void tryEliminateConstantArgs(ArrayList refs) { List parameters = findFixedArguments(refs); if (parameters == null) { return; } List fns = ReferenceMap.getFunctionNodes(refs); if (fns.size() > 1) { // TODO(johnlenz): support moving simple constants. // This requires cloning the tree and avoiding adding additional calls/definitions that will // invalidate the reference map return; } // Only one definition is currently supported. Node fn = fns.get(0); boolean continueLooking = adjustForConstraints(fn, parameters); if (!continueLooking) { return; } // Found something to do, move the values from the call sites to the function definitions. for (Node n : refs) { if (ReferenceMap.isCallOrNewTarget(n) && !alreadyRemoved(n)) { optimizeCallSite(parameters, n); } } optimizeFunctionDefinition(parameters, fn); } /** * @param refs A list of references to the symbol (name or property) as vetted by * #isCandidate. * @return A list of Parameter objects, in the declaration order, which represent potentially * movable values fixed values from all call sites or null if there are no candidate values. */ private List findFixedArguments(ArrayList refs) { List parameters = new ArrayList<>(); boolean firstCall = true; // Build a list of parameters to remove boolean continueLooking = false; for (Node n : refs) { if (ReferenceMap.isCallOrNewTarget(n)) { Node call = n.getParent(); Node firstDotCallParam = call.getFirstChild(); // Normally, we ignore the first parameter to a .call expression (the 'this' value) // but if it is a spread, we know nothing about any of the parameters, so bail out now. if (firstDotCallParam.isSpread()) { continueLooking = false; break; } Node cur = ReferenceMap.getFirstArgumentForCallOrNewOrDotCall(n); if (firstCall) { // Use the first call to construct a list of parameter values of the // function. continueLooking = buildInitialParameterList(parameters, cur); firstCall = false; } else { // All the rest must match continueLooking = findFixedParameters(parameters, cur); } if (!continueLooking) { break; } } } return (continueLooking) ? parameters : null; } /** * Adjust the provided Parameter objects value created by #findFixedArguments for "rest" value * and side-effects which might prevent the motion of the parameters from the call sites to the * function body. * * @param parameters A list of Parameter objects summarizing all the call-sites and * whether any of the parameters are fixed. * @return Whether there are any movable parameters. */ private static boolean adjustForConstraints(Node fn, List parameters) { Node paramList = NodeUtil.getFunctionParameters(fn); Node lastFormal = paramList.getLastChild(); int restIndex = Integer.MAX_VALUE; int lastNonRestFormal = paramList.getChildCount() - 1; Node formal = lastFormal; if (lastFormal != null && lastFormal.isRest()) { restIndex = lastNonRestFormal; lastNonRestFormal--; formal = formal.getPrevious(); } // A parameter with side-effects can move if there are no following parameters // that can be affected. // A parameter can be moved if it can't be side-effected (a literal), // or there are no following side-effects, that aren't moved. boolean anyMovable = false; boolean seenUnmovableSideEffects = false; boolean seenUnmoveableSideEffected = false; boolean allRestValueRemovable = true; for (int i = parameters.size() - 1; i >= 0; i--) { Parameter current = parameters.get(i); // back-off for default values whose default value maybe needed. // TODO(johnlenz): handle used default if (i <= lastNonRestFormal) { if (formal.isDefaultValue() && current.mayBeUndefined) { current.shouldRemove = false; } formal = formal.getPrevious(); } // Preserve side-effect ordering, don't move this parameter if: // * the current parameter has side-effects and a following // parameters that will not be move can be effected. // * the current parameter can be effected and a following // parameter that will not be moved has side-effects if (current.shouldRemove && ((seenUnmovableSideEffects && current.canBeSideEffected()) || (seenUnmoveableSideEffected && current.hasSideEffects()))) { current.shouldRemove = false; } // If any values that are part of the rest cannot be moved to the function body, // then all the rest values must remain at the callsite. if (i >= restIndex) { if (allRestValueRemovable) { if (!current.shouldRemove) { anyMovable = false; allRestValueRemovable = false; // revisit the trailing params and remark them now that we know they are unremovable. for (int j = i + 1; j < parameters.size(); j++) { Parameter p = parameters.get(0); p.shouldRemove = false; if (p.canBeSideEffected) { seenUnmoveableSideEffected = true; } if (p.hasSideEffects) { seenUnmovableSideEffects = true; } } } } else { current.shouldRemove = false; } } if (current.shouldRemove) { anyMovable = true; } else { if (current.canBeSideEffected) { seenUnmoveableSideEffected = true; } if (current.hasSideEffects) { seenUnmovableSideEffects = true; } } } return anyMovable; } /** * Determine which parameters use the same expression. * @return Whether any parameter was found that can be updated. */ private boolean findFixedParameters(List parameters, Node cur) { boolean anyMovable = false; int index = 0; while (cur != null) { Parameter p; if (index >= parameters.size()) { p = new Parameter(cur, false); parameters.add(p); setParameterSideEffectInfo(p, cur); } else { p = parameters.get(index); if (p.shouldRemove()) { Node value = p.getArg(); if (!cur.isEquivalentTo(value)) { p.setShouldRemove(false); } else { anyMovable = true; } } } cur = cur.getNext(); index++; } for (; index < parameters.size(); index++) { parameters.get(index).setShouldRemove(false); } return anyMovable; } /** * @return Whether any parameter was movable. */ private boolean buildInitialParameterList(List parameters, Node cur) { boolean anyMovable = false; while (cur != null) { if (cur.isSpread()) { break; } boolean movable = isMovableValue(cur, globalScope); Parameter p = new Parameter(cur, movable); setParameterSideEffectInfo(p, cur); parameters.add(p); if (movable) { anyMovable = true; } cur = cur.getNext(); } return anyMovable; } private void setParameterSideEffectInfo(Parameter p, Node value) { p.setHasSideEffects(NodeUtil.mayHaveSideEffects(value, compiler)); p.setCanBeSideEffected(NodeUtil.canBeSideEffected(value)); p.setMayBeUndefined(NodeUtil.mayBeUndefined(value)); } /** * @return Whether the expression can be safely moved to another function * in another scope. */ private static boolean isMovableValue(Node n, Scope globalScope) { // Things that can change value or are inaccessible can't be moved, these // are "this", "arguments", local names, and functions that capture local // values. switch (n.getToken()) { case THIS: return false; case FUNCTION: // Don't move function closures. // TODO(johnlenz): Closure that only contain global reference can be // moved. return false; case NAME: if (n.getString().equals("arguments")) { return false; } else { Var v = globalScope.getVar(n.getString()); if (v == null) { return false; } } break; default: break; } for (Node c = n.getFirstChild(); c != null; c = c.getNext()) { if (!isMovableValue(c, globalScope)) { return false; } } return true; } private void optimizeFunctionDefinition(List parameters, Node fn) { Node paramList = NodeUtil.getFunctionParameters(fn); Node maybeRest = paramList.getLastChild(); int lastParameter = parameters.size() - 1; if (maybeRest != null && maybeRest.isRest()) { int restIndex = paramList.getChildCount() - 1; // If the rest parameter is removable they all are. if (parameters.size() < restIndex || (restIndex < parameters.size() && parameters.get(restIndex).shouldRemove())) { Node value = IR.arraylit().srcref(maybeRest); for (int i = restIndex; i < parameters.size(); i++) { Parameter parameter = parameters.get(i); checkState(parameter.shouldRemove()); value.addChildToBack(parameters.get(i).getArg()); } maybeRest.detach(); Node lhs = maybeRest.removeFirstChild(); addRestVariableToFunction(fn, lhs, value); } // process the rest. lastParameter = Math.min(parameters.size() - 1, restIndex - 1); } for (int i = lastParameter; i >= 0; i--) { Parameter parameter = parameters.get(i); if (parameter.shouldRemove()) { Node formalParam = NodeUtil.getArgumentForFunction(fn, i); if (formalParam != null) { formalParam.detach(); if (formalParam.isDefaultValue()) { // Drop the default value as we should only get here if the default value isn't going // to be used. checkState(!parameter.mayBeUndefined); formalParam = formalParam.getFirstChild().detach(); } } addVariableToFunction(fn, formalParam, parameters.get(i).getArg()); } } } private void optimizeCallSite(List parameters, Node target) { Node call = ReferenceMap.getCallOrNewNodeForTarget(target); boolean mayMutateArgs = call.mayMutateArguments(); boolean mayMutateGlobalsOrThrow = call.mayMutateGlobalStateOrThrow(); for (int index = parameters.size() - 1; index >= 0; index--) { Parameter p = parameters.get(index); if (p.shouldRemove()) { eliminateCallTargetArgAt(target, index); if (mayMutateArgs && !mayMutateGlobalsOrThrow // We want to cover both global-state arguments, and // expressions that might throw exceptions. // We're deliberately conservative here b/c it's // difficult to test all the edge cases. && !NodeUtil.isImmutableValue(p.getArg())) { mayMutateGlobalsOrThrow = true; call.setSideEffectFlags( new Node.SideEffectFlags(call.getSideEffectFlags()).setMutatesGlobalState()); } } } } /** * Simple container class that keeps tracks of a parameter and whether it * should be removed. */ private static class Parameter { private final Node arg; private boolean shouldRemove; private boolean hasSideEffects; private boolean canBeSideEffected; private boolean mayBeUndefined; public Parameter(Node arg, boolean shouldRemove) { this.shouldRemove = shouldRemove; this.arg = arg; } public Node getArg() { return arg; } public boolean shouldRemove() { return shouldRemove; } public void setShouldRemove(boolean value) { shouldRemove = value; } public void setHasSideEffects(boolean hasSideEffects) { this.hasSideEffects = hasSideEffects; } public boolean hasSideEffects() { return hasSideEffects; } public void setCanBeSideEffected(boolean canBeSideEffected) { this.canBeSideEffected = canBeSideEffected; } public boolean canBeSideEffected() { return canBeSideEffected; } public void setMayBeUndefined(boolean mayBeUndefined) { this.mayBeUndefined = mayBeUndefined; } public boolean mayBeUndefined() { return mayBeUndefined; } } private void addRestVariableToFunction(Node function, Node lhs, Node value) { checkState(lhs.getParent() == null); addVariableToFunction(function, lhs, value); } /** * Adds a variable to the top of a function block. * @param function A function node. * @param lhs The lhs expression. * @param value The initial value of the variable. */ private void addVariableToFunction(Node function, @Nullable Node lhs, Node value) { checkState(value.getParent() == null); checkState(lhs == null || lhs.getParent() == null); Node block = NodeUtil.getFunctionBody(function); Node stmt; if (lhs != null) { stmt = NodeUtil.newVarNode(lhs, value); } else { stmt = IR.exprResult(value).useSourceInfoFrom(value); } // Insert the statement at the beginning of the function body, but after any // existing function declarations so that the tree stays normalized. Node insertionPoint = block.getFirstChild(); while (insertionPoint != null && insertionPoint.isFunction()) { insertionPoint = insertionPoint.getNext(); } if (insertionPoint == null) { block.addChildToBack(stmt); } else { block.addChildBefore(stmt, insertionPoint); } compiler.reportChangeToEnclosingScope(stmt); } /** * Removes all formal parameters starting at argIndex. */ private void eliminateParamsAfter(Node fnNode, int argIndex) { Node formalArgPtr = NodeUtil.getFunctionParameters(fnNode).getFirstChild(); while (argIndex != 0 && formalArgPtr != null) { formalArgPtr = formalArgPtr.getNext(); argIndex--; } eliminateParamsAfter(fnNode, formalArgPtr); } private void eliminateParamsAfter(Node fnNode, Node formal) { if (formal != null) { // Keep the args in the same order, do the last first. eliminateParamsAfter(fnNode, formal.getNext()); formal.detach(); Node stmt; if (formal.isRest()) { checkState(formal.getNext() == null); stmt = NodeUtil.newVarNode(formal.getFirstChild().detach(), IR.arraylit().srcref(formal)); } else { if (formal.isDefaultValue()) { Node lhs = formal.getFirstChild().detach(); Node value = formal.getLastChild().detach(); stmt = NodeUtil.newVarNode(lhs, value); } else { stmt = IR.var(formal).useSourceInfoIfMissingFrom(formal); } } fnNode.getLastChild().addChildToFront(stmt); compiler.reportChangeToEnclosingScope(stmt); } } /** * Eliminates the parameter from a function call. * @param definitionFinder The definition and use sites index. * @param p * @param call The function call node * @param argIndex The index of the argument to remove. */ private void eliminateCallTargetArgAt(Node ref, int argIndex) { Node callArgNode = ReferenceMap.getArgumentForCallOrNewOrDotCall(ref, argIndex); if (callArgNode != null) { NodeUtil.deleteNode(callArgNode, compiler); } } }




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