| // Copyright (c) 2012, the Dart project authors. Please see the AUTHORS file |
| // for details. All rights reserved. Use of this source code is governed by a |
| // BSD-style license that can be found in the LICENSE file. |
| |
| part of js; |
| |
| class Printer implements NodeVisitor { |
| final bool shouldCompressOutput; |
| leg.Compiler compiler; |
| leg.CodeBuffer outBuffer; |
| int indentLevel = 0; |
| bool inForInit = false; |
| bool atStatementBegin = false; |
| final DanglingElseVisitor danglingElseVisitor; |
| final LocalNamer localNamer; |
| bool pendingSemicolon = false; |
| bool pendingSpace = false; |
| static final identifierCharacterRegExp = new RegExp(r'^[a-zA-Z_0-9$]'); |
| static final expressionContinuationRegExp = new RegExp(r'^[-+([]'); |
| |
| Printer(leg.Compiler compiler, { allowVariableMinification: true }) |
| : shouldCompressOutput = compiler.enableMinification, |
| this.compiler = compiler, |
| outBuffer = new leg.CodeBuffer(), |
| danglingElseVisitor = new DanglingElseVisitor(compiler), |
| localNamer = determineRenamer(compiler.enableMinification, |
| allowVariableMinification); |
| |
| static LocalNamer determineRenamer(bool shouldCompressOutput, |
| bool allowVariableMinification) { |
| return (shouldCompressOutput && allowVariableMinification) |
| ? new MinifyRenamer() : new IdentityNamer(); |
| } |
| |
| /// Always emit a newline, even under `enableMinification`. |
| void forceLine() { |
| out("\n"); |
| } |
| /// Emits a newline for readability. |
| void lineOut() { |
| if (!shouldCompressOutput) forceLine(); |
| } |
| void spaceOut() { |
| if (!shouldCompressOutput) out(" "); |
| } |
| |
| String lastAddedString = null; |
| int get lastCharCode { |
| if (lastAddedString == null) return 0; |
| assert(lastAddedString.length != ""); |
| return lastAddedString.codeUnitAt(lastAddedString.length - 1); |
| } |
| |
| void out(String str) { |
| if (str != "") { |
| if (pendingSemicolon) { |
| if (!shouldCompressOutput) { |
| outBuffer.add(";"); |
| } else if (str != "}") { |
| // We want to output newline instead of semicolon because it makes |
| // the raw stack traces much easier to read and it also makes line- |
| // based tools like diff work much better. JavaScript will |
| // automatically insert the semicolon at the newline if it means a |
| // parsing error is avoided, so we can only do this trick if the |
| // next line is not something that can be glued onto a valid |
| // expression to make a new valid expression. |
| if (expressionContinuationRegExp.hasMatch(str)) { |
| outBuffer.add(";"); |
| } else { |
| outBuffer.add("\n"); |
| } |
| } |
| } |
| if (pendingSpace && |
| (!shouldCompressOutput || identifierCharacterRegExp.hasMatch(str))) { |
| outBuffer.add(" "); |
| } |
| pendingSpace = false; |
| pendingSemicolon = false; |
| outBuffer.add(str); |
| lastAddedString = str; |
| } |
| } |
| |
| void outLn(String str) { |
| out(str); |
| lineOut(); |
| } |
| |
| void outSemicolonLn() { |
| if (shouldCompressOutput) { |
| pendingSemicolon = true; |
| } else { |
| out(";"); |
| forceLine(); |
| } |
| } |
| |
| void outIndent(String str) { indent(); out(str); } |
| void outIndentLn(String str) { indent(); outLn(str); } |
| void indent() { |
| if (!shouldCompressOutput) { |
| for (int i = 0; i < indentLevel; i++) out(" "); |
| } |
| } |
| |
| void recordSourcePosition(var position) { |
| if (position != null) { |
| outBuffer.setSourceLocation(position); |
| } |
| } |
| |
| visit(Node node) { |
| if (node.sourcePosition != null) outBuffer.beginMappedRange(); |
| recordSourcePosition(node.sourcePosition); |
| node.accept(this); |
| recordSourcePosition(node.endSourcePosition); |
| if (node.sourcePosition != null) outBuffer.endMappedRange(); |
| } |
| |
| visitCommaSeparated(List<Node> nodes, int hasRequiredType, |
| {bool newInForInit, bool newAtStatementBegin}) { |
| for (int i = 0; i < nodes.length; i++) { |
| if (i != 0) { |
| atStatementBegin = false; |
| out(","); |
| spaceOut(); |
| } |
| visitNestedExpression(nodes[i], hasRequiredType, |
| newInForInit: newInForInit, |
| newAtStatementBegin: newAtStatementBegin); |
| } |
| } |
| |
| visitAll(List<Node> nodes) { |
| nodes.forEach(visit); |
| } |
| |
| visitProgram(Program program) { |
| visitAll(program.body); |
| } |
| |
| bool blockBody(Node body, {bool needsSeparation, bool needsNewline}) { |
| if (body is Block) { |
| spaceOut(); |
| blockOut(body, false, needsNewline); |
| return true; |
| } |
| if (shouldCompressOutput && needsSeparation) { |
| // If [shouldCompressOutput] is false, then the 'lineOut' will insert |
| // the separation. |
| out(" "); |
| } else { |
| lineOut(); |
| } |
| indentLevel++; |
| visit(body); |
| indentLevel--; |
| return false; |
| } |
| |
| void blockOutWithoutBraces(Node node) { |
| if (node is Block) { |
| node.statements.forEach(blockOutWithoutBraces); |
| } else { |
| visit(node); |
| } |
| } |
| |
| void blockOut(Block node, bool shouldIndent, bool needsNewline) { |
| if (shouldIndent) indent(); |
| out("{"); |
| lineOut(); |
| indentLevel++; |
| node.statements.forEach(blockOutWithoutBraces); |
| indentLevel--; |
| indent(); |
| out("}"); |
| if (needsNewline) lineOut(); |
| } |
| |
| visitBlock(Block block) { |
| blockOut(block, true, true); |
| } |
| |
| visitExpressionStatement(ExpressionStatement expressionStatement) { |
| indent(); |
| visitNestedExpression(expressionStatement.expression, EXPRESSION, |
| newInForInit: false, newAtStatementBegin: true); |
| outSemicolonLn(); |
| } |
| |
| visitEmptyStatement(EmptyStatement nop) { |
| outIndentLn(";"); |
| } |
| |
| void ifOut(If node, bool shouldIndent) { |
| Node then = node.then; |
| Node elsePart = node.otherwise; |
| bool hasElse = node.hasElse; |
| |
| // Handle dangling elses. |
| if (hasElse) { |
| bool needsBraces = node.then.accept(danglingElseVisitor); |
| if (needsBraces) { |
| then = new Block(<Statement>[then]); |
| } |
| } |
| if (shouldIndent) indent(); |
| out("if"); |
| spaceOut(); |
| out("("); |
| visitNestedExpression(node.condition, EXPRESSION, |
| newInForInit: false, newAtStatementBegin: false); |
| out(")"); |
| bool thenWasBlock = |
| blockBody(then, needsSeparation: false, needsNewline: !hasElse); |
| if (hasElse) { |
| if (thenWasBlock) { |
| spaceOut(); |
| } else { |
| indent(); |
| } |
| out("else"); |
| if (elsePart is If) { |
| pendingSpace = true; |
| ifOut(elsePart, false); |
| } else { |
| blockBody(elsePart, needsSeparation: true, needsNewline: true); |
| } |
| } |
| } |
| |
| visitIf(If node) { |
| ifOut(node, true); |
| } |
| |
| visitFor(For loop) { |
| outIndent("for"); |
| spaceOut(); |
| out("("); |
| if (loop.init != null) { |
| visitNestedExpression(loop.init, EXPRESSION, |
| newInForInit: true, newAtStatementBegin: false); |
| } |
| out(";"); |
| if (loop.condition != null) { |
| spaceOut(); |
| visitNestedExpression(loop.condition, EXPRESSION, |
| newInForInit: false, newAtStatementBegin: false); |
| } |
| out(";"); |
| if (loop.update != null) { |
| spaceOut(); |
| visitNestedExpression(loop.update, EXPRESSION, |
| newInForInit: false, newAtStatementBegin: false); |
| } |
| out(")"); |
| blockBody(loop.body, needsSeparation: false, needsNewline: true); |
| } |
| |
| visitForIn(ForIn loop) { |
| outIndent("for"); |
| spaceOut(); |
| out("("); |
| visitNestedExpression(loop.leftHandSide, EXPRESSION, |
| newInForInit: true, newAtStatementBegin: false); |
| out(" in"); |
| pendingSpace = true; |
| visitNestedExpression(loop.object, EXPRESSION, |
| newInForInit: false, newAtStatementBegin: false); |
| out(")"); |
| blockBody(loop.body, needsSeparation: false, needsNewline: true); |
| } |
| |
| visitWhile(While loop) { |
| outIndent("while"); |
| spaceOut(); |
| out("("); |
| visitNestedExpression(loop.condition, EXPRESSION, |
| newInForInit: false, newAtStatementBegin: false); |
| out(")"); |
| blockBody(loop.body, needsSeparation: false, needsNewline: true); |
| } |
| |
| visitDo(Do loop) { |
| outIndent("do"); |
| if (blockBody(loop.body, needsSeparation: true, needsNewline: false)) { |
| spaceOut(); |
| } else { |
| indent(); |
| } |
| out("while"); |
| spaceOut(); |
| out("("); |
| visitNestedExpression(loop.condition, EXPRESSION, |
| newInForInit: false, newAtStatementBegin: false); |
| out(")"); |
| outSemicolonLn(); |
| } |
| |
| visitContinue(Continue node) { |
| if (node.targetLabel == null) { |
| outIndent("continue"); |
| } else { |
| outIndent("continue ${node.targetLabel}"); |
| } |
| outSemicolonLn(); |
| } |
| |
| visitBreak(Break node) { |
| if (node.targetLabel == null) { |
| outIndent("break"); |
| } else { |
| outIndent("break ${node.targetLabel}"); |
| } |
| outSemicolonLn(); |
| } |
| |
| visitReturn(Return node) { |
| if (node.value == null) { |
| outIndent("return"); |
| } else { |
| outIndent("return"); |
| pendingSpace = true; |
| visitNestedExpression(node.value, EXPRESSION, |
| newInForInit: false, newAtStatementBegin: false); |
| } |
| outSemicolonLn(); |
| } |
| |
| visitThrow(Throw node) { |
| outIndent("throw"); |
| pendingSpace = true; |
| visitNestedExpression(node.expression, EXPRESSION, |
| newInForInit: false, newAtStatementBegin: false); |
| outSemicolonLn(); |
| } |
| |
| visitTry(Try node) { |
| outIndent("try"); |
| blockBody(node.body, needsSeparation: true, needsNewline: false); |
| if (node.catchPart != null) { |
| visit(node.catchPart); |
| } |
| if (node.finallyPart != null) { |
| spaceOut(); |
| out("finally"); |
| blockBody(node.finallyPart, needsSeparation: true, needsNewline: true); |
| } else { |
| lineOut(); |
| } |
| } |
| |
| visitCatch(Catch node) { |
| spaceOut(); |
| out("catch"); |
| spaceOut(); |
| out("("); |
| visitNestedExpression(node.declaration, EXPRESSION, |
| newInForInit: false, newAtStatementBegin: false); |
| out(")"); |
| blockBody(node.body, needsSeparation: false, needsNewline: true); |
| } |
| |
| visitSwitch(Switch node) { |
| outIndent("switch"); |
| spaceOut(); |
| out("("); |
| visitNestedExpression(node.key, EXPRESSION, |
| newInForInit: false, newAtStatementBegin: false); |
| out(")"); |
| spaceOut(); |
| outLn("{"); |
| indentLevel++; |
| visitAll(node.cases); |
| indentLevel--; |
| outIndentLn("}"); |
| } |
| |
| visitCase(Case node) { |
| outIndent("case"); |
| pendingSpace = true; |
| visitNestedExpression(node.expression, EXPRESSION, |
| newInForInit: false, newAtStatementBegin: false); |
| outLn(":"); |
| if (!node.body.statements.isEmpty) { |
| indentLevel++; |
| blockOutWithoutBraces(node.body); |
| indentLevel--; |
| } |
| } |
| |
| visitDefault(Default node) { |
| outIndentLn("default:"); |
| if (!node.body.statements.isEmpty) { |
| indentLevel++; |
| blockOutWithoutBraces(node.body); |
| indentLevel--; |
| } |
| } |
| |
| visitLabeledStatement(LabeledStatement node) { |
| outIndent("${node.label}:"); |
| blockBody(node.body, needsSeparation: false, needsNewline: true); |
| } |
| |
| void functionOut(Fun fun, Node name, VarCollector vars) { |
| out("function"); |
| if (name != null) { |
| out(" "); |
| // Name must be a [Decl]. Therefore only test for primary expressions. |
| visitNestedExpression(name, PRIMARY, |
| newInForInit: false, newAtStatementBegin: false); |
| } |
| localNamer.enterScope(vars); |
| out("("); |
| if (fun.params != null) { |
| visitCommaSeparated(fun.params, PRIMARY, |
| newInForInit: false, newAtStatementBegin: false); |
| } |
| out(")"); |
| blockBody(fun.body, needsSeparation: false, needsNewline: false); |
| localNamer.leaveScope(); |
| } |
| |
| visitFunctionDeclaration(FunctionDeclaration declaration) { |
| VarCollector vars = new VarCollector(); |
| vars.visitFunctionDeclaration(declaration); |
| indent(); |
| functionOut(declaration.function, declaration.name, vars); |
| lineOut(); |
| } |
| |
| visitNestedExpression(Expression node, int requiredPrecedence, |
| {bool newInForInit, bool newAtStatementBegin}) { |
| bool needsParentheses = |
| // a - (b + c). |
| (requiredPrecedence != EXPRESSION && |
| node.precedenceLevel < requiredPrecedence) || |
| // for (a = (x in o); ... ; ... ) { ... } |
| (newInForInit && node is Binary && (node as Binary).op == "in") || |
| // (function() { ... })(). |
| // ({a: 2, b: 3}.toString()). |
| (newAtStatementBegin && (node is NamedFunction || |
| node is Fun || |
| node is ObjectInitializer)); |
| if (needsParentheses) { |
| inForInit = false; |
| atStatementBegin = false; |
| out("("); |
| visit(node); |
| out(")"); |
| } else { |
| inForInit = newInForInit; |
| atStatementBegin = newAtStatementBegin; |
| visit(node); |
| } |
| } |
| |
| visitVariableDeclarationList(VariableDeclarationList list) { |
| out("var "); |
| visitCommaSeparated(list.declarations, ASSIGNMENT, |
| newInForInit: inForInit, newAtStatementBegin: false); |
| } |
| |
| visitSequence(Sequence sequence) { |
| // Note that we only require that the entries are expressions and not |
| // assignments. This means that nested sequences are not put into |
| // parenthesis. |
| visitCommaSeparated(sequence.expressions, EXPRESSION, |
| newInForInit: false, |
| newAtStatementBegin: atStatementBegin); |
| } |
| |
| visitAssignment(Assignment assignment) { |
| visitNestedExpression(assignment.leftHandSide, LEFT_HAND_SIDE, |
| newInForInit: inForInit, |
| newAtStatementBegin: atStatementBegin); |
| if (assignment.value != null) { |
| spaceOut(); |
| String op = assignment.op; |
| if (op != null) out(op); |
| out("="); |
| spaceOut(); |
| visitNestedExpression(assignment.value, ASSIGNMENT, |
| newInForInit: inForInit, |
| newAtStatementBegin: false); |
| } |
| } |
| |
| visitVariableInitialization(VariableInitialization initialization) { |
| visitAssignment(initialization); |
| } |
| |
| visitConditional(Conditional cond) { |
| visitNestedExpression(cond.condition, LOGICAL_OR, |
| newInForInit: inForInit, |
| newAtStatementBegin: atStatementBegin); |
| spaceOut(); |
| out("?"); |
| spaceOut(); |
| // The then part is allowed to have an 'in'. |
| visitNestedExpression(cond.then, ASSIGNMENT, |
| newInForInit: false, newAtStatementBegin: false); |
| spaceOut(); |
| out(":"); |
| spaceOut(); |
| visitNestedExpression(cond.otherwise, ASSIGNMENT, |
| newInForInit: inForInit, newAtStatementBegin: false); |
| } |
| |
| visitNew(New node) { |
| out("new "); |
| visitNestedExpression(node.target, CALL, |
| newInForInit: inForInit, newAtStatementBegin: false); |
| out("("); |
| visitCommaSeparated(node.arguments, ASSIGNMENT, |
| newInForInit: false, newAtStatementBegin: false); |
| out(")"); |
| } |
| |
| visitCall(Call call) { |
| visitNestedExpression(call.target, LEFT_HAND_SIDE, |
| newInForInit: inForInit, |
| newAtStatementBegin: atStatementBegin); |
| out("("); |
| visitCommaSeparated(call.arguments, ASSIGNMENT, |
| newInForInit: false, newAtStatementBegin: false); |
| out(")"); |
| } |
| |
| visitBinary(Binary binary) { |
| Expression left = binary.left; |
| Expression right = binary.right; |
| String op = binary.op; |
| int leftPrecedenceRequirement; |
| int rightPrecedenceRequirement; |
| switch (op) { |
| case "||": |
| leftPrecedenceRequirement = LOGICAL_OR; |
| // x || (y || z) <=> (x || y) || z. |
| rightPrecedenceRequirement = LOGICAL_OR; |
| break; |
| case "&&": |
| leftPrecedenceRequirement = LOGICAL_AND; |
| // x && (y && z) <=> (x && y) && z. |
| rightPrecedenceRequirement = LOGICAL_AND; |
| break; |
| case "|": |
| leftPrecedenceRequirement = BIT_OR; |
| // x | (y | z) <=> (x | y) | z. |
| rightPrecedenceRequirement = BIT_OR; |
| break; |
| case "^": |
| leftPrecedenceRequirement = BIT_XOR; |
| // x ^ (y ^ z) <=> (x ^ y) ^ z. |
| rightPrecedenceRequirement = BIT_XOR; |
| break; |
| case "&": |
| leftPrecedenceRequirement = BIT_AND; |
| // x & (y & z) <=> (x & y) & z. |
| rightPrecedenceRequirement = BIT_AND; |
| break; |
| case "==": |
| case "!=": |
| case "===": |
| case "!==": |
| leftPrecedenceRequirement = EQUALITY; |
| rightPrecedenceRequirement = RELATIONAL; |
| break; |
| case "<": |
| case ">": |
| case "<=": |
| case ">=": |
| case "instanceof": |
| case "in": |
| leftPrecedenceRequirement = RELATIONAL; |
| rightPrecedenceRequirement = SHIFT; |
| break; |
| case ">>": |
| case "<<": |
| case ">>>": |
| leftPrecedenceRequirement = SHIFT; |
| rightPrecedenceRequirement = ADDITIVE; |
| break; |
| case "+": |
| case "-": |
| leftPrecedenceRequirement = ADDITIVE; |
| // We cannot remove parenthesis for "+" because |
| // x + (y + z) <!=> (x + y) + z: |
| // Example: |
| // "a" + (1 + 2) => "a3"; |
| // ("a" + 1) + 2 => "a12"; |
| rightPrecedenceRequirement = MULTIPLICATIVE; |
| break; |
| case "*": |
| case "/": |
| case "%": |
| leftPrecedenceRequirement = MULTIPLICATIVE; |
| // We cannot remove parenthesis for "*" because of precision issues. |
| rightPrecedenceRequirement = UNARY; |
| break; |
| default: |
| compiler.internalError("Forgot operator: $op"); |
| } |
| |
| visitNestedExpression(left, leftPrecedenceRequirement, |
| newInForInit: inForInit, |
| newAtStatementBegin: atStatementBegin); |
| |
| if (op == "in" || op == "instanceof") { |
| // There are cases where the space is not required but without further |
| // analysis we cannot know. |
| out(" "); |
| out(op); |
| out(" "); |
| } else { |
| spaceOut(); |
| out(op); |
| spaceOut(); |
| } |
| visitNestedExpression(right, rightPrecedenceRequirement, |
| newInForInit: inForInit, |
| newAtStatementBegin: false); |
| } |
| |
| visitPrefix(Prefix unary) { |
| String op = unary.op; |
| switch (op) { |
| case "delete": |
| case "void": |
| case "typeof": |
| // There are cases where the space is not required but without further |
| // analysis we cannot know. |
| out(op); |
| out(" "); |
| break; |
| case "+": |
| case "++": |
| if (lastCharCode == charCodes.$PLUS) out(" "); |
| out(op); |
| break; |
| case "-": |
| case "--": |
| if (lastCharCode == charCodes.$MINUS) out(" "); |
| out(op); |
| break; |
| default: |
| out(op); |
| } |
| visitNestedExpression(unary.argument, UNARY, |
| newInForInit: inForInit, newAtStatementBegin: false); |
| } |
| |
| visitPostfix(Postfix postfix) { |
| visitNestedExpression(postfix.argument, LEFT_HAND_SIDE, |
| newInForInit: inForInit, |
| newAtStatementBegin: atStatementBegin); |
| out(postfix.op); |
| } |
| |
| visitVariableUse(VariableUse ref) { |
| out(localNamer.getName(ref.name)); |
| } |
| |
| visitThis(This node) { |
| out("this"); |
| } |
| |
| visitVariableDeclaration(VariableDeclaration decl) { |
| out(localNamer.getName(decl.name)); |
| } |
| |
| visitParameter(Parameter param) { |
| out(localNamer.getName(param.name)); |
| } |
| |
| bool isDigit(int charCode) { |
| return charCodes.$0 <= charCode && charCode <= charCodes.$9; |
| } |
| |
| bool isValidJavaScriptId(String field) { |
| if (field.length < 3) return false; |
| // Ignore the leading and trailing string-delimiter. |
| for (int i = 1; i < field.length - 1; i++) { |
| // TODO(floitsch): allow more characters. |
| int charCode = field.codeUnitAt(i); |
| if (!(charCodes.$a <= charCode && charCode <= charCodes.$z || |
| charCodes.$A <= charCode && charCode <= charCodes.$Z || |
| charCode == charCodes.$$ || |
| charCode == charCodes.$_ || |
| i != 1 && isDigit(charCode))) { |
| return false; |
| } |
| } |
| // TODO(floitsch): normally we should also check that the field is not a |
| // reserved word. We don't generate fields with reserved word names except |
| // for 'super'. |
| if (field == '"super"') return false; |
| return true; |
| } |
| |
| visitAccess(PropertyAccess access) { |
| visitNestedExpression(access.receiver, CALL, |
| newInForInit: inForInit, |
| newAtStatementBegin: atStatementBegin); |
| Node selector = access.selector; |
| if (selector is LiteralString) { |
| LiteralString selectorString = selector; |
| String fieldWithQuotes = selectorString.value; |
| if (isValidJavaScriptId(fieldWithQuotes)) { |
| if (access.receiver is LiteralNumber) out(" "); |
| out("."); |
| out(fieldWithQuotes.substring(1, fieldWithQuotes.length - 1)); |
| return; |
| } |
| } |
| out("["); |
| visitNestedExpression(selector, EXPRESSION, |
| newInForInit: false, newAtStatementBegin: false); |
| out("]"); |
| } |
| |
| visitNamedFunction(NamedFunction namedFunction) { |
| VarCollector vars = new VarCollector(); |
| vars.visitNamedFunction(namedFunction); |
| functionOut(namedFunction.function, namedFunction.name, vars); |
| } |
| |
| visitFun(Fun fun) { |
| VarCollector vars = new VarCollector(); |
| vars.visitFun(fun); |
| functionOut(fun, null, vars); |
| } |
| |
| visitLiteralBool(LiteralBool node) { |
| out(node.value ? "true" : "false"); |
| } |
| |
| visitLiteralString(LiteralString node) { |
| out(node.value); |
| } |
| |
| visitLiteralNumber(LiteralNumber node) { |
| int charCode = node.value.codeUnitAt(0); |
| if (charCode == charCodes.$MINUS && lastCharCode == charCodes.$MINUS) { |
| out(" "); |
| } |
| out(node.value); |
| } |
| |
| visitLiteralNull(LiteralNull node) { |
| out("null"); |
| } |
| |
| visitArrayInitializer(ArrayInitializer node) { |
| out("["); |
| List<ArrayElement> elements = node.elements; |
| int elementIndex = 0; |
| for (int i = 0; i < node.length; i++) { |
| if (elementIndex < elements.length && |
| elements[elementIndex].index == i) { |
| visitNestedExpression(elements[elementIndex].value, ASSIGNMENT, |
| newInForInit: false, newAtStatementBegin: false); |
| elementIndex++; |
| // We can avoid a trailing "," if there was an element just before. So |
| // `[1]` and `[1,]` are the same, but `[,]` and `[]` are not. |
| if (i != node.length - 1) { |
| out(","); |
| spaceOut(); |
| } |
| } else { |
| out(","); |
| } |
| } |
| out("]"); |
| } |
| |
| visitArrayElement(ArrayElement node) { |
| throw "Unreachable"; |
| } |
| |
| visitObjectInitializer(ObjectInitializer node) { |
| // Print all the properties on one line until we see a function-valued |
| // property. Ideally, we would use a proper pretty-printer to make the |
| // decision based on layout. |
| bool onePerLine = false; |
| List<Property> properties = node.properties; |
| out("{"); |
| ++indentLevel; |
| for (int i = 0; i < properties.length; i++) { |
| Expression value = properties[i].value; |
| if (value is Fun || value is NamedFunction) onePerLine = true; |
| if (i != 0) { |
| out(","); |
| if (!onePerLine) spaceOut(); |
| } |
| if (onePerLine) { |
| forceLine(); |
| indent(); |
| } |
| visitProperty(properties[i]); |
| } |
| --indentLevel; |
| if (onePerLine) lineOut(); |
| out("}"); |
| } |
| |
| visitProperty(Property node) { |
| if (node.name is LiteralString) { |
| LiteralString nameString = node.name; |
| String name = nameString.value; |
| if (isValidJavaScriptId(name)) { |
| out(name.substring(1, name.length - 1)); |
| } else { |
| out(name); |
| } |
| } else { |
| assert(node.name is LiteralNumber); |
| LiteralNumber nameNumber = node.name; |
| out(nameNumber.value); |
| } |
| out(":"); |
| spaceOut(); |
| visitNestedExpression(node.value, ASSIGNMENT, |
| newInForInit: false, newAtStatementBegin: false); |
| } |
| |
| visitRegExpLiteral(RegExpLiteral node) { |
| out(node.pattern); |
| } |
| |
| visitLiteralExpression(LiteralExpression node) { |
| String template = node.template; |
| List<Expression> inputs = node.inputs; |
| |
| List<String> parts = template.split('#'); |
| if (parts.length != inputs.length + 1) { |
| compiler.internalError('Wrong number of arguments for JS: $template'); |
| } |
| // Code that uses JS must take care of operator precedences, and |
| // put parenthesis if needed. |
| out(parts[0]); |
| for (int i = 0; i < inputs.length; i++) { |
| visit(inputs[i]); |
| out(parts[i + 1]); |
| } |
| } |
| |
| visitLiteralStatement(LiteralStatement node) { |
| outLn(node.code); |
| } |
| |
| void visitComment(Comment node) { |
| if (shouldCompressOutput) return; |
| String comment = node.comment.trim(); |
| if (comment.isEmpty) return; |
| for (var line in comment.split('\n')) { |
| if (comment.startsWith('//')) { |
| outIndentLn(line.trim()); |
| } else { |
| outIndentLn('// ${line.trim()}'); |
| } |
| } |
| } |
| } |
| |
| |
| class OrderedSet<T> { |
| final Set<T> set; |
| final List<T> list; |
| |
| OrderedSet() : set = new Set<T>(), list = <T>[]; |
| |
| void add(T x) { |
| if (!set.contains(x)) { |
| set.add(x); |
| list.add(x); |
| } |
| } |
| |
| void forEach(void fun(T x)) { |
| list.forEach(fun); |
| } |
| } |
| |
| // Collects all the var declarations in the function. We need to do this in a |
| // separate pass because JS vars are lifted to the top of the function. |
| class VarCollector extends BaseVisitor { |
| bool nested; |
| final OrderedSet<String> vars; |
| final OrderedSet<String> params; |
| |
| VarCollector() : nested = false, |
| vars = new OrderedSet<String>(), |
| params = new OrderedSet<String>(); |
| |
| void forEachVar(void fn(String v)) => vars.forEach(fn); |
| void forEachParam(void fn(String p)) => params.forEach(fn); |
| |
| void collectVarsInFunction(Fun fun) { |
| if (!nested) { |
| nested = true; |
| if (fun.params != null) { |
| for (int i = 0; i < fun.params.length; i++) { |
| params.add(fun.params[i].name); |
| } |
| } |
| visitBlock(fun.body); |
| nested = false; |
| } |
| } |
| |
| void visitFunctionDeclaration(FunctionDeclaration declaration) { |
| // Note that we don't bother collecting the name of the function. |
| collectVarsInFunction(declaration.function); |
| } |
| |
| void visitNamedFunction(NamedFunction namedFunction) { |
| // Note that we don't bother collecting the name of the function. |
| collectVarsInFunction(namedFunction.function); |
| } |
| |
| void visitFun(Fun fun) { |
| collectVarsInFunction(fun); |
| } |
| |
| void visitThis(This node) {} |
| |
| void visitVariableDeclaration(VariableDeclaration decl) { |
| vars.add(decl.name); |
| } |
| } |
| |
| |
| /** |
| * Returns true, if the given node must be wrapped into braces when used |
| * as then-statement in an [If] that has an else branch. |
| */ |
| class DanglingElseVisitor extends BaseVisitor<bool> { |
| leg.Compiler compiler; |
| |
| DanglingElseVisitor(this.compiler); |
| |
| bool visitProgram(Program node) => false; |
| |
| bool visitNode(Statement node) { |
| compiler.internalError("Forgot node: $node"); |
| } |
| |
| bool visitBlock(Block node) => false; |
| bool visitExpressionStatement(ExpressionStatement node) => false; |
| bool visitEmptyStatement(EmptyStatement node) => false; |
| bool visitIf(If node) { |
| if (!node.hasElse) return true; |
| return node.otherwise.accept(this); |
| } |
| bool visitFor(For node) => node.body.accept(this); |
| bool visitForIn(ForIn node) => node.body.accept(this); |
| bool visitWhile(While node) => node.body.accept(this); |
| bool visitDo(Do node) => false; |
| bool visitContinue(Continue node) => false; |
| bool visitBreak(Break node) => false; |
| bool visitReturn(Return node) => false; |
| bool visitThrow(Throw node) => false; |
| bool visitTry(Try node) { |
| if (node.finallyPart != null) { |
| return node.finallyPart.accept(this); |
| } else { |
| return node.catchPart.accept(this); |
| } |
| } |
| bool visitCatch(Catch node) => node.body.accept(this); |
| bool visitSwitch(Switch node) => false; |
| bool visitCase(Case node) => false; |
| bool visitDefault(Default node) => false; |
| bool visitFunctionDeclaration(FunctionDeclaration node) => false; |
| bool visitLabeledStatement(LabeledStatement node) |
| => node.body.accept(this); |
| bool visitLiteralStatement(LiteralStatement node) => true; |
| |
| bool visitExpression(Expression node) => false; |
| } |
| |
| |
| leg.CodeBuffer prettyPrint(Node node, leg.Compiler compiler, |
| { allowVariableMinification: true }) { |
| Printer printer = |
| new Printer(compiler, |
| allowVariableMinification: allowVariableMinification); |
| printer.visit(node); |
| return printer.outBuffer; |
| } |
| |
| |
| abstract class LocalNamer { |
| String getName(String oldName); |
| String declareVariable(String oldName); |
| String declareParameter(String oldName); |
| void enterScope(VarCollector vars); |
| void leaveScope(); |
| } |
| |
| |
| class IdentityNamer implements LocalNamer { |
| String getName(String oldName) => oldName; |
| String declareVariable(String oldName) => oldName; |
| String declareParameter(String oldName) => oldName; |
| void enterScope(VarCollector vars) {} |
| void leaveScope() {} |
| } |
| |
| |
| class MinifyRenamer implements LocalNamer { |
| final List<Map<String, String>> maps = []; |
| final List<int> parameterNumberStack = []; |
| final List<int> variableNumberStack = []; |
| int parameterNumber = 0; |
| int variableNumber = 0; |
| |
| MinifyRenamer(); |
| |
| void enterScope(VarCollector vars) { |
| maps.add(new Map<String, String>()); |
| variableNumberStack.add(variableNumber); |
| parameterNumberStack.add(parameterNumber); |
| vars.forEachVar(declareVariable); |
| vars.forEachParam(declareParameter); |
| } |
| |
| void leaveScope() { |
| maps.removeLast(); |
| variableNumber = variableNumberStack.removeLast(); |
| parameterNumber = parameterNumberStack.removeLast(); |
| } |
| |
| String getName(String oldName) { |
| // Go from inner scope to outer looking for mapping of name. |
| for (int i = maps.length - 1; i >= 0; i--) { |
| var map = maps[i]; |
| var replacement = map[oldName]; |
| if (replacement != null) return replacement; |
| } |
| return oldName; |
| } |
| |
| static const LOWER_CASE_LETTERS = 26; |
| static const LETTERS = 52; |
| static const DIGITS = 10; |
| |
| static int nthLetter(int n) { |
| return (n < LOWER_CASE_LETTERS) ? |
| charCodes.$a + n : |
| charCodes.$A + n - LOWER_CASE_LETTERS; |
| } |
| |
| // Parameters go from a to z and variables go from z to a. This makes each |
| // argument list and each top-of-function var declaration look similar and |
| // helps gzip compress the file. If we have more than 26 arguments and |
| // variables then we meet somewhere in the middle of the alphabet. After |
| // that we give up trying to be nice to the compression algorithm and just |
| // use the same namespace for arguments and variables, starting with A, and |
| // moving on to a0, a1, etc. |
| String declareVariable(String oldName) { |
| var newName; |
| if (variableNumber + parameterNumber < LOWER_CASE_LETTERS) { |
| // Variables start from z and go backwards, for better gzipability. |
| newName = getNameNumber(oldName, LOWER_CASE_LETTERS - 1 - variableNumber); |
| } else { |
| // After 26 variables and parameters we allocate them in the same order. |
| newName = getNameNumber(oldName, variableNumber + parameterNumber); |
| } |
| variableNumber++; |
| return newName; |
| } |
| |
| String declareParameter(String oldName) { |
| var newName; |
| if (variableNumber + parameterNumber < LOWER_CASE_LETTERS) { |
| newName = getNameNumber(oldName, parameterNumber); |
| } else { |
| newName = getNameNumber(oldName, variableNumber + parameterNumber); |
| } |
| parameterNumber++; |
| return newName; |
| } |
| |
| String getNameNumber(String oldName, int n) { |
| if (maps.isEmpty) return oldName; |
| |
| String newName; |
| if (n < LETTERS) { |
| // Start naming variables a, b, c, ..., z, A, B, C, ..., Z. |
| newName = new String.fromCharCodes([nthLetter(n)]); |
| } else { |
| // Then name variables a0, a1, a2, ..., a9, b0, b1, ..., Z9, aa0, aa1, ... |
| // For all functions with fewer than 500 locals this is just as compact |
| // as using aa, ab, etc. but avoids clashes with keywords. |
| n -= LETTERS; |
| int digit = n % DIGITS; |
| n ~/= DIGITS; |
| int alphaChars = 1; |
| int nameSpaceSize = LETTERS; |
| // Find out whether we should use the 1-character namespace (size 52), the |
| // 2-character namespace (size 52*52), etc. |
| while (n >= nameSpaceSize) { |
| n -= nameSpaceSize; |
| alphaChars++; |
| nameSpaceSize *= LETTERS; |
| } |
| var codes = <int>[]; |
| for (var i = 0; i < alphaChars; i++) { |
| nameSpaceSize ~/= LETTERS; |
| codes.add(nthLetter((n ~/ nameSpaceSize) % LETTERS)); |
| } |
| codes.add(charCodes.$0 + digit); |
| newName = new String.fromCharCodes(codes); |
| } |
| assert(new RegExp(r'[a-zA-Z][a-zA-Z0-9]*').hasMatch(newName)); |
| maps.last[oldName] = newName; |
| return newName; |
| } |
| } |