node_modules/eslint/lib/linter/code-path-analysis/code-path-analyzer.js - nifi-fds - Git at Google

 /**
  * @fileoverview A class of the code path analyzer.
  * @author Toru Nagashima
  */

 "use strict";

 //------------------------------------------------------------------------------
 // Requirements
 //------------------------------------------------------------------------------

 const assert = require("assert"),
     { breakableTypePattern } = require("../../shared/ast-utils"),
     CodePath = require("./code-path"),
     CodePathSegment = require("./code-path-segment"),
     IdGenerator = require("./id-generator"),
     debug = require("./debug-helpers");

 //------------------------------------------------------------------------------
 // Helpers
 //------------------------------------------------------------------------------

 /**
  * Checks whether or not a given node is a `case` node (not `default` node).
  * @param {ASTNode} node A `SwitchCase` node to check.
  * @returns {boolean} `true` if the node is a `case` node (not `default` node).
  */
 function isCaseNode(node) {
     return Boolean(node.test);
 }

 /**
  * Checks if a given node appears as the value of a PropertyDefinition node.
  * @param {ASTNode} node THe node to check.
  * @returns {boolean} `true` if the node is a PropertyDefinition value,
  *      false if not.
  */
 function isPropertyDefinitionValue(node) {
     const parent = node.parent;

     return parent && parent.type === "PropertyDefinition" && parent.value === node;
 }

 /**
  * Checks whether the given logical operator is taken into account for the code
  * path analysis.
  * @param {string} operator The operator found in the LogicalExpression node
  * @returns {boolean} `true` if the operator is "&&" or "||" or "??"
  */
 function isHandledLogicalOperator(operator) {
     return operator === "&&" || operator === "||" || operator === "??";
 }

 /**
  * Checks whether the given assignment operator is a logical assignment operator.
  * Logical assignments are taken into account for the code path analysis
  * because of their short-circuiting semantics.
  * @param {string} operator The operator found in the AssignmentExpression node
  * @returns {boolean} `true` if the operator is "&&=" or "||=" or "??="
  */
 function isLogicalAssignmentOperator(operator) {
     return operator === "&&=" || operator === "||=" || operator === "??=";
 }

 /**
  * Gets the label if the parent node of a given node is a LabeledStatement.
  * @param {ASTNode} node A node to get.
  * @returns {string|null} The label or `null`.
  */
 function getLabel(node) {
     if (node.parent.type === "LabeledStatement") {
         return node.parent.label.name;
     }
     return null;
 }

 /**
  * Checks whether or not a given logical expression node goes different path
  * between the `true` case and the `false` case.
  * @param {ASTNode} node A node to check.
  * @returns {boolean} `true` if the node is a test of a choice statement.
  */
 function isForkingByTrueOrFalse(node) {
     const parent = node.parent;

     switch (parent.type) {
         case "ConditionalExpression":
         case "IfStatement":
         case "WhileStatement":
         case "DoWhileStatement":
         case "ForStatement":
             return parent.test === node;

         case "LogicalExpression":
             return isHandledLogicalOperator(parent.operator);

         case "AssignmentExpression":
             return isLogicalAssignmentOperator(parent.operator);

         default:
             return false;
     }
 }

 /**
  * Gets the boolean value of a given literal node.
  *
  * This is used to detect infinity loops (e.g. `while (true) {}`).
  * Statements preceded by an infinity loop are unreachable if the loop didn't
  * have any `break` statement.
  * @param {ASTNode} node A node to get.
  * @returns {boolean|undefined} a boolean value if the node is a Literal node,
  *   otherwise `undefined`.
  */
 function getBooleanValueIfSimpleConstant(node) {
     if (node.type === "Literal") {
         return Boolean(node.value);
     }
     return void 0;
 }

 /**
  * Checks that a given identifier node is a reference or not.
  *
  * This is used to detect the first throwable node in a `try` block.
  * @param {ASTNode} node An Identifier node to check.
  * @returns {boolean} `true` if the node is a reference.
  */
 function isIdentifierReference(node) {
     const parent = node.parent;

     switch (parent.type) {
         case "LabeledStatement":
         case "BreakStatement":
         case "ContinueStatement":
         case "ArrayPattern":
         case "RestElement":
         case "ImportSpecifier":
         case "ImportDefaultSpecifier":
         case "ImportNamespaceSpecifier":
         case "CatchClause":
             return false;

         case "FunctionDeclaration":
         case "FunctionExpression":
         case "ArrowFunctionExpression":
         case "ClassDeclaration":
         case "ClassExpression":
         case "VariableDeclarator":
             return parent.id !== node;

         case "Property":
         case "PropertyDefinition":
         case "MethodDefinition":
             return (
                 parent.key !== node ||
                 parent.computed ||
                 parent.shorthand
             );

         case "AssignmentPattern":
             return parent.key !== node;

         default:
             return true;
     }
 }

 /**
  * Updates the current segment with the head segment.
  * This is similar to local branches and tracking branches of git.
  *
  * To separate the current and the head is in order to not make useless segments.
  *
  * In this process, both "onCodePathSegmentStart" and "onCodePathSegmentEnd"
  * events are fired.
  * @param {CodePathAnalyzer} analyzer The instance.
  * @param {ASTNode} node The current AST node.
  * @returns {void}
  */
 function forwardCurrentToHead(analyzer, node) {
     const codePath = analyzer.codePath;
     const state = CodePath.getState(codePath);
     const currentSegments = state.currentSegments;
     const headSegments = state.headSegments;
     const end = Math.max(currentSegments.length, headSegments.length);
     let i, currentSegment, headSegment;

     // Fires leaving events.
     for (i = 0; i < end; ++i) {
         currentSegment = currentSegments[i];
         headSegment = headSegments[i];

         if (currentSegment !== headSegment && currentSegment) {
             debug.dump(`onCodePathSegmentEnd ${currentSegment.id}`);

             if (currentSegment.reachable) {
                 analyzer.emitter.emit(
                     "onCodePathSegmentEnd",
                     currentSegment,
                     node
                 );
             }
         }
     }

     // Update state.
     state.currentSegments = headSegments;

     // Fires entering events.
     for (i = 0; i < end; ++i) {
         currentSegment = currentSegments[i];
         headSegment = headSegments[i];

         if (currentSegment !== headSegment && headSegment) {
             debug.dump(`onCodePathSegmentStart ${headSegment.id}`);

             CodePathSegment.markUsed(headSegment);
             if (headSegment.reachable) {
                 analyzer.emitter.emit(
                     "onCodePathSegmentStart",
                     headSegment,
                     node
                 );
             }
         }
     }

 }

 /**
  * Updates the current segment with empty.
  * This is called at the last of functions or the program.
  * @param {CodePathAnalyzer} analyzer The instance.
  * @param {ASTNode} node The current AST node.
  * @returns {void}
  */
 function leaveFromCurrentSegment(analyzer, node) {
     const state = CodePath.getState(analyzer.codePath);
     const currentSegments = state.currentSegments;

     for (let i = 0; i < currentSegments.length; ++i) {
         const currentSegment = currentSegments[i];

         debug.dump(`onCodePathSegmentEnd ${currentSegment.id}`);
         if (currentSegment.reachable) {
             analyzer.emitter.emit(
                 "onCodePathSegmentEnd",
                 currentSegment,
                 node
             );
         }
     }

     state.currentSegments = [];
 }

 /**
  * Updates the code path due to the position of a given node in the parent node
  * thereof.
  *
  * For example, if the node is `parent.consequent`, this creates a fork from the
  * current path.
  * @param {CodePathAnalyzer} analyzer The instance.
  * @param {ASTNode} node The current AST node.
  * @returns {void}
  */
 function preprocess(analyzer, node) {
     const codePath = analyzer.codePath;
     const state = CodePath.getState(codePath);
     const parent = node.parent;

     switch (parent.type) {

         // The `arguments.length == 0` case is in `postprocess` function.
         case "CallExpression":
             if (parent.optional === true && parent.arguments.length >= 1 && parent.arguments[0] === node) {
                 state.makeOptionalRight();
             }
             break;
         case "MemberExpression":
             if (parent.optional === true && parent.property === node) {
                 state.makeOptionalRight();
             }
             break;

         case "LogicalExpression":
             if (
                 parent.right === node &&
                 isHandledLogicalOperator(parent.operator)
             ) {
                 state.makeLogicalRight();
             }
             break;

         case "AssignmentExpression":
             if (
                 parent.right === node &&
                 isLogicalAssignmentOperator(parent.operator)
             ) {
                 state.makeLogicalRight();
             }
             break;

         case "ConditionalExpression":
         case "IfStatement":

             /*
              * Fork if this node is at `consequent`/`alternate`.
              * `popForkContext()` exists at `IfStatement:exit` and
              * `ConditionalExpression:exit`.
              */
             if (parent.consequent === node) {
                 state.makeIfConsequent();
             } else if (parent.alternate === node) {
                 state.makeIfAlternate();
             }
             break;

         case "SwitchCase":
             if (parent.consequent[0] === node) {
                 state.makeSwitchCaseBody(false, !parent.test);
             }
             break;

         case "TryStatement":
             if (parent.handler === node) {
                 state.makeCatchBlock();
             } else if (parent.finalizer === node) {
                 state.makeFinallyBlock();
             }
             break;

         case "WhileStatement":
             if (parent.test === node) {
                 state.makeWhileTest(getBooleanValueIfSimpleConstant(node));
             } else {
                 assert(parent.body === node);
                 state.makeWhileBody();
             }
             break;

         case "DoWhileStatement":
             if (parent.body === node) {
                 state.makeDoWhileBody();
             } else {
                 assert(parent.test === node);
                 state.makeDoWhileTest(getBooleanValueIfSimpleConstant(node));
             }
             break;

         case "ForStatement":
             if (parent.test === node) {
                 state.makeForTest(getBooleanValueIfSimpleConstant(node));
             } else if (parent.update === node) {
                 state.makeForUpdate();
             } else if (parent.body === node) {
                 state.makeForBody();
             }
             break;

         case "ForInStatement":
         case "ForOfStatement":
             if (parent.left === node) {
                 state.makeForInOfLeft();
             } else if (parent.right === node) {
                 state.makeForInOfRight();
             } else {
                 assert(parent.body === node);
                 state.makeForInOfBody();
             }
             break;

         case "AssignmentPattern":

             /*
              * Fork if this node is at `right`.
              * `left` is executed always, so it uses the current path.
              * `popForkContext()` exists at `AssignmentPattern:exit`.
              */
             if (parent.right === node) {
                 state.pushForkContext();
                 state.forkBypassPath();
                 state.forkPath();
             }
             break;

         default:
             break;
     }
 }

 /**
  * Updates the code path due to the type of a given node in entering.
  * @param {CodePathAnalyzer} analyzer The instance.
  * @param {ASTNode} node The current AST node.
  * @returns {void}
  */
 function processCodePathToEnter(analyzer, node) {
     let codePath = analyzer.codePath;
     let state = codePath && CodePath.getState(codePath);
     const parent = node.parent;

     /**
      * Creates a new code path and trigger the onCodePathStart event
      * based on the currently selected node.
      * @param {string} origin The reason the code path was started.
      * @returns {void}
      */
     function startCodePath(origin) {
         if (codePath) {

             // Emits onCodePathSegmentStart events if updated.
             forwardCurrentToHead(analyzer, node);
             debug.dumpState(node, state, false);
         }

         // Create the code path of this scope.
         codePath = analyzer.codePath = new CodePath({
             id: analyzer.idGenerator.next(),
             origin,
             upper: codePath,
             onLooped: analyzer.onLooped
         });
         state = CodePath.getState(codePath);

         // Emits onCodePathStart events.
         debug.dump(`onCodePathStart ${codePath.id}`);
         analyzer.emitter.emit("onCodePathStart", codePath, node);
     }

     /*
      * Special case: The right side of class field initializer is considered
      * to be its own function, so we need to start a new code path in this
      * case.
      */
     if (isPropertyDefinitionValue(node)) {
         startCodePath("class-field-initializer");

         /*
          * Intentional fall through because `node` needs to also be
          * processed by the code below. For example, if we have:
          *
          * class Foo {
          *     a = () => {}
          * }
          *
          * In this case, we also need start a second code path.
          */

     }

     switch (node.type) {
         case "Program":
             startCodePath("program");
             break;

         case "FunctionDeclaration":
         case "FunctionExpression":
         case "ArrowFunctionExpression":
             startCodePath("function");
             break;

         case "StaticBlock":
             startCodePath("class-static-block");
             break;

         case "ChainExpression":
             state.pushChainContext();
             break;
         case "CallExpression":
             if (node.optional === true) {
                 state.makeOptionalNode();
             }
             break;
         case "MemberExpression":
             if (node.optional === true) {
                 state.makeOptionalNode();
             }
             break;

         case "LogicalExpression":
             if (isHandledLogicalOperator(node.operator)) {
                 state.pushChoiceContext(
                     node.operator,
                     isForkingByTrueOrFalse(node)
                 );
             }
             break;

         case "AssignmentExpression":
             if (isLogicalAssignmentOperator(node.operator)) {
                 state.pushChoiceContext(
                     node.operator.slice(0, -1), // removes `=` from the end
                     isForkingByTrueOrFalse(node)
                 );
             }
             break;

         case "ConditionalExpression":
         case "IfStatement":
             state.pushChoiceContext("test", false);
             break;

         case "SwitchStatement":
             state.pushSwitchContext(
                 node.cases.some(isCaseNode),
                 getLabel(node)
             );
             break;

         case "TryStatement":
             state.pushTryContext(Boolean(node.finalizer));
             break;

         case "SwitchCase":

             /*
              * Fork if this node is after the 2st node in `cases`.
              * It's similar to `else` blocks.
              * The next `test` node is processed in this path.
              */
             if (parent.discriminant !== node && parent.cases[0] !== node) {
                 state.forkPath();
             }
             break;

         case "WhileStatement":
         case "DoWhileStatement":
         case "ForStatement":
         case "ForInStatement":
         case "ForOfStatement":
             state.pushLoopContext(node.type, getLabel(node));
             break;

         case "LabeledStatement":
             if (!breakableTypePattern.test(node.body.type)) {
                 state.pushBreakContext(false, node.label.name);
             }
             break;

         default:
             break;
     }

     // Emits onCodePathSegmentStart events if updated.
     forwardCurrentToHead(analyzer, node);
     debug.dumpState(node, state, false);
 }

 /**
  * Updates the code path due to the type of a given node in leaving.
  * @param {CodePathAnalyzer} analyzer The instance.
  * @param {ASTNode} node The current AST node.
  * @returns {void}
  */
 function processCodePathToExit(analyzer, node) {

     const codePath = analyzer.codePath;
     const state = CodePath.getState(codePath);
     let dontForward = false;

     switch (node.type) {
         case "ChainExpression":
             state.popChainContext();
             break;

         case "IfStatement":
         case "ConditionalExpression":
             state.popChoiceContext();
             break;

         case "LogicalExpression":
             if (isHandledLogicalOperator(node.operator)) {
                 state.popChoiceContext();
             }
             break;

         case "AssignmentExpression":
             if (isLogicalAssignmentOperator(node.operator)) {
                 state.popChoiceContext();
             }
             break;

         case "SwitchStatement":
             state.popSwitchContext();
             break;

         case "SwitchCase":

             /*
              * This is the same as the process at the 1st `consequent` node in
              * `preprocess` function.
              * Must do if this `consequent` is empty.
              */
             if (node.consequent.length === 0) {
                 state.makeSwitchCaseBody(true, !node.test);
             }
             if (state.forkContext.reachable) {
                 dontForward = true;
             }
             break;

         case "TryStatement":
             state.popTryContext();
             break;

         case "BreakStatement":
             forwardCurrentToHead(analyzer, node);
             state.makeBreak(node.label && node.label.name);
             dontForward = true;
             break;

         case "ContinueStatement":
             forwardCurrentToHead(analyzer, node);
             state.makeContinue(node.label && node.label.name);
             dontForward = true;
             break;

         case "ReturnStatement":
             forwardCurrentToHead(analyzer, node);
             state.makeReturn();
             dontForward = true;
             break;

         case "ThrowStatement":
             forwardCurrentToHead(analyzer, node);
             state.makeThrow();
             dontForward = true;
             break;

         case "Identifier":
             if (isIdentifierReference(node)) {
                 state.makeFirstThrowablePathInTryBlock();
                 dontForward = true;
             }
             break;

         case "CallExpression":
         case "ImportExpression":
         case "MemberExpression":
         case "NewExpression":
         case "YieldExpression":
             state.makeFirstThrowablePathInTryBlock();
             break;

         case "WhileStatement":
         case "DoWhileStatement":
         case "ForStatement":
         case "ForInStatement":
         case "ForOfStatement":
             state.popLoopContext();
             break;

         case "AssignmentPattern":
             state.popForkContext();
             break;

         case "LabeledStatement":
             if (!breakableTypePattern.test(node.body.type)) {
                 state.popBreakContext();
             }
             break;

         default:
             break;
     }

     // Emits onCodePathSegmentStart events if updated.
     if (!dontForward) {
         forwardCurrentToHead(analyzer, node);
     }
     debug.dumpState(node, state, true);
 }

 /**
  * Updates the code path to finalize the current code path.
  * @param {CodePathAnalyzer} analyzer The instance.
  * @param {ASTNode} node The current AST node.
  * @returns {void}
  */
 function postprocess(analyzer, node) {

     /**
      * Ends the code path for the current node.
      * @returns {void}
      */
     function endCodePath() {
         let codePath = analyzer.codePath;

         // Mark the current path as the final node.
         CodePath.getState(codePath).makeFinal();

         // Emits onCodePathSegmentEnd event of the current segments.
         leaveFromCurrentSegment(analyzer, node);

         // Emits onCodePathEnd event of this code path.
         debug.dump(`onCodePathEnd ${codePath.id}`);
         analyzer.emitter.emit("onCodePathEnd", codePath, node);
         debug.dumpDot(codePath);

         codePath = analyzer.codePath = analyzer.codePath.upper;
         if (codePath) {
             debug.dumpState(node, CodePath.getState(codePath), true);
         }

     }

     switch (node.type) {
         case "Program":
         case "FunctionDeclaration":
         case "FunctionExpression":
         case "ArrowFunctionExpression":
         case "StaticBlock": {
             endCodePath();
             break;
         }

         // The `arguments.length >= 1` case is in `preprocess` function.
         case "CallExpression":
             if (node.optional === true && node.arguments.length === 0) {
                 CodePath.getState(analyzer.codePath).makeOptionalRight();
             }
             break;

         default:
             break;
     }

     /*
      * Special case: The right side of class field initializer is considered
      * to be its own function, so we need to end a code path in this
      * case.
      *
      * We need to check after the other checks in order to close the
      * code paths in the correct order for code like this:
      *
      *
      * class Foo {
      *     a = () => {}
      * }
      *
      * In this case, The ArrowFunctionExpression code path is closed first
      * and then we need to close the code path for the PropertyDefinition
      * value.
      */
     if (isPropertyDefinitionValue(node)) {
         endCodePath();
     }
 }

 //------------------------------------------------------------------------------
 // Public Interface
 //------------------------------------------------------------------------------

 /**
  * The class to analyze code paths.
  * This class implements the EventGenerator interface.
  */
 class CodePathAnalyzer {

     /**
      * @param {EventGenerator} eventGenerator An event generator to wrap.
      */
     constructor(eventGenerator) {
         this.original = eventGenerator;
         this.emitter = eventGenerator.emitter;
         this.codePath = null;
         this.idGenerator = new IdGenerator("s");
         this.currentNode = null;
         this.onLooped = this.onLooped.bind(this);
     }

     /**
      * Does the process to enter a given AST node.
      * This updates state of analysis and calls `enterNode` of the wrapped.
      * @param {ASTNode} node A node which is entering.
      * @returns {void}
      */
     enterNode(node) {
         this.currentNode = node;

         // Updates the code path due to node's position in its parent node.
         if (node.parent) {
             preprocess(this, node);
         }

         /*
          * Updates the code path.
          * And emits onCodePathStart/onCodePathSegmentStart events.
          */
         processCodePathToEnter(this, node);

         // Emits node events.
         this.original.enterNode(node);

         this.currentNode = null;
     }

     /**
      * Does the process to leave a given AST node.
      * This updates state of analysis and calls `leaveNode` of the wrapped.
      * @param {ASTNode} node A node which is leaving.
      * @returns {void}
      */
     leaveNode(node) {
         this.currentNode = node;

         /*
          * Updates the code path.
          * And emits onCodePathStart/onCodePathSegmentStart events.
          */
         processCodePathToExit(this, node);

         // Emits node events.
         this.original.leaveNode(node);

         // Emits the last onCodePathStart/onCodePathSegmentStart events.
         postprocess(this, node);

         this.currentNode = null;
     }

     /**
      * This is called on a code path looped.
      * Then this raises a looped event.
      * @param {CodePathSegment} fromSegment A segment of prev.
      * @param {CodePathSegment} toSegment A segment of next.
      * @returns {void}
      */
     onLooped(fromSegment, toSegment) {
         if (fromSegment.reachable && toSegment.reachable) {
             debug.dump(`onCodePathSegmentLoop ${fromSegment.id} -> ${toSegment.id}`);
             this.emitter.emit(
                 "onCodePathSegmentLoop",
                 fromSegment,
                 toSegment,
                 this.currentNode
             );
         }
     }
 }

 module.exports = CodePathAnalyzer;
	/**
	* @fileoverview A class of the code path analyzer.
	* @author Toru Nagashima
	*/

	"use strict";

	//------------------------------------------------------------------------------
	// Requirements
	//------------------------------------------------------------------------------

	const assert = require("assert"),
	{ breakableTypePattern } = require("../../shared/ast-utils"),
	CodePath = require("./code-path"),
	CodePathSegment = require("./code-path-segment"),
	IdGenerator = require("./id-generator"),
	debug = require("./debug-helpers");

	//------------------------------------------------------------------------------
	// Helpers
	//------------------------------------------------------------------------------

	/**
	* Checks whether or not a given node is a `case` node (not `default` node).
	* @param {ASTNode} node A `SwitchCase` node to check.
	* @returns {boolean} `true` if the node is a `case` node (not `default` node).
	*/
	function isCaseNode(node) {
	return Boolean(node.test);
	}

	/**
	* Checks if a given node appears as the value of a PropertyDefinition node.
	* @param {ASTNode} node THe node to check.
	* @returns {boolean} `true` if the node is a PropertyDefinition value,
	* false if not.
	*/
	function isPropertyDefinitionValue(node) {
	const parent = node.parent;

	return parent && parent.type === "PropertyDefinition" && parent.value === node;
	}

	/**
	* Checks whether the given logical operator is taken into account for the code
	* path analysis.
	* @param {string} operator The operator found in the LogicalExpression node
	* @returns {boolean} `true` if the operator is "&&" or "\|\|" or "??"
	*/
	function isHandledLogicalOperator(operator) {
	return operator === "&&" \|\| operator === "\|\|" \|\| operator === "??";
	}

	/**
	* Checks whether the given assignment operator is a logical assignment operator.
	* Logical assignments are taken into account for the code path analysis
	* because of their short-circuiting semantics.
	* @param {string} operator The operator found in the AssignmentExpression node
	* @returns {boolean} `true` if the operator is "&&=" or "\|\|=" or "??="
	*/
	function isLogicalAssignmentOperator(operator) {
	return operator === "&&=" \|\| operator === "\|\|=" \|\| operator === "??=";
	}

	/**
	* Gets the label if the parent node of a given node is a LabeledStatement.
	* @param {ASTNode} node A node to get.
	* @returns {string\|null} The label or `null`.
	*/
	function getLabel(node) {
	if (node.parent.type === "LabeledStatement") {
	return node.parent.label.name;
	}
	return null;
	}

	/**
	* Checks whether or not a given logical expression node goes different path
	* between the `true` case and the `false` case.
	* @param {ASTNode} node A node to check.
	* @returns {boolean} `true` if the node is a test of a choice statement.
	*/
	function isForkingByTrueOrFalse(node) {
	const parent = node.parent;

	switch (parent.type) {
	case "ConditionalExpression":
	case "IfStatement":
	case "WhileStatement":
	case "DoWhileStatement":
	case "ForStatement":
	return parent.test === node;

	case "LogicalExpression":
	return isHandledLogicalOperator(parent.operator);

	case "AssignmentExpression":
	return isLogicalAssignmentOperator(parent.operator);

	default:
	return false;
	}
	}

	/**
	* Gets the boolean value of a given literal node.
	*
	* This is used to detect infinity loops (e.g. `while (true) {}`).
	* Statements preceded by an infinity loop are unreachable if the loop didn't
	* have any `break` statement.
	* @param {ASTNode} node A node to get.
	* @returns {boolean\|undefined} a boolean value if the node is a Literal node,
	* otherwise `undefined`.
	*/
	function getBooleanValueIfSimpleConstant(node) {
	if (node.type === "Literal") {
	return Boolean(node.value);
	}
	return void 0;
	}

	/**
	* Checks that a given identifier node is a reference or not.
	*
	* This is used to detect the first throwable node in a `try` block.
	* @param {ASTNode} node An Identifier node to check.
	* @returns {boolean} `true` if the node is a reference.
	*/
	function isIdentifierReference(node) {
	const parent = node.parent;

	switch (parent.type) {
	case "LabeledStatement":
	case "BreakStatement":
	case "ContinueStatement":
	case "ArrayPattern":
	case "RestElement":
	case "ImportSpecifier":
	case "ImportDefaultSpecifier":
	case "ImportNamespaceSpecifier":
	case "CatchClause":
	return false;

	case "FunctionDeclaration":
	case "FunctionExpression":
	case "ArrowFunctionExpression":
	case "ClassDeclaration":
	case "ClassExpression":
	case "VariableDeclarator":
	return parent.id !== node;

	case "Property":
	case "PropertyDefinition":
	case "MethodDefinition":
	return (
	parent.key !== node \|\|
	parent.computed \|\|
	parent.shorthand
	);

	case "AssignmentPattern":
	return parent.key !== node;

	default:
	return true;
	}
	}

	/**
	* Updates the current segment with the head segment.
	* This is similar to local branches and tracking branches of git.
	*
	* To separate the current and the head is in order to not make useless segments.
	*
	* In this process, both "onCodePathSegmentStart" and "onCodePathSegmentEnd"
	* events are fired.
	* @param {CodePathAnalyzer} analyzer The instance.
	* @param {ASTNode} node The current AST node.
	* @returns {void}
	*/
	function forwardCurrentToHead(analyzer, node) {
	const codePath = analyzer.codePath;
	const state = CodePath.getState(codePath);
	const currentSegments = state.currentSegments;
	const headSegments = state.headSegments;
	const end = Math.max(currentSegments.length, headSegments.length);
	let i, currentSegment, headSegment;

	// Fires leaving events.
	for (i = 0; i < end; ++i) {
	currentSegment = currentSegments[i];
	headSegment = headSegments[i];

	if (currentSegment !== headSegment && currentSegment) {
	debug.dump(`onCodePathSegmentEnd ${currentSegment.id}`);

	if (currentSegment.reachable) {
	analyzer.emitter.emit(
	"onCodePathSegmentEnd",
	currentSegment,
	node
	);
	}
	}
	}

	// Update state.
	state.currentSegments = headSegments;

	// Fires entering events.
	for (i = 0; i < end; ++i) {
	currentSegment = currentSegments[i];
	headSegment = headSegments[i];

	if (currentSegment !== headSegment && headSegment) {
	debug.dump(`onCodePathSegmentStart ${headSegment.id}`);

	CodePathSegment.markUsed(headSegment);
	if (headSegment.reachable) {
	analyzer.emitter.emit(
	"onCodePathSegmentStart",
	headSegment,
	node
	);
	}
	}
	}

	}

	/**
	* Updates the current segment with empty.
	* This is called at the last of functions or the program.
	* @param {CodePathAnalyzer} analyzer The instance.
	* @param {ASTNode} node The current AST node.
	* @returns {void}
	*/
	function leaveFromCurrentSegment(analyzer, node) {
	const state = CodePath.getState(analyzer.codePath);
	const currentSegments = state.currentSegments;

	for (let i = 0; i < currentSegments.length; ++i) {
	const currentSegment = currentSegments[i];

	debug.dump(`onCodePathSegmentEnd ${currentSegment.id}`);
	if (currentSegment.reachable) {
	analyzer.emitter.emit(
	"onCodePathSegmentEnd",
	currentSegment,
	node
	);
	}
	}

	state.currentSegments = [];
	}

	/**
	* Updates the code path due to the position of a given node in the parent node
	* thereof.
	*
	* For example, if the node is `parent.consequent`, this creates a fork from the
	* current path.
	* @param {CodePathAnalyzer} analyzer The instance.
	* @param {ASTNode} node The current AST node.
	* @returns {void}
	*/
	function preprocess(analyzer, node) {
	const codePath = analyzer.codePath;
	const state = CodePath.getState(codePath);
	const parent = node.parent;

	switch (parent.type) {

	// The `arguments.length == 0` case is in `postprocess` function.
	case "CallExpression":
	if (parent.optional === true && parent.arguments.length >= 1 && parent.arguments[0] === node) {
	state.makeOptionalRight();
	}
	break;
	case "MemberExpression":
	if (parent.optional === true && parent.property === node) {
	state.makeOptionalRight();
	}
	break;

	case "LogicalExpression":
	if (
	parent.right === node &&
	isHandledLogicalOperator(parent.operator)
	) {
	state.makeLogicalRight();
	}
	break;

	case "AssignmentExpression":
	if (
	parent.right === node &&
	isLogicalAssignmentOperator(parent.operator)
	) {
	state.makeLogicalRight();
	}
	break;

	case "ConditionalExpression":
	case "IfStatement":

	/*
	* Fork if this node is at `consequent`/`alternate`.
	* `popForkContext()` exists at `IfStatement:exit` and
	* `ConditionalExpression:exit`.
	*/
	if (parent.consequent === node) {
	state.makeIfConsequent();
	} else if (parent.alternate === node) {
	state.makeIfAlternate();
	}
	break;

	case "SwitchCase":
	if (parent.consequent[0] === node) {
	state.makeSwitchCaseBody(false, !parent.test);
	}
	break;

	case "TryStatement":
	if (parent.handler === node) {
	state.makeCatchBlock();
	} else if (parent.finalizer === node) {
	state.makeFinallyBlock();
	}
	break;

	case "WhileStatement":
	if (parent.test === node) {
	state.makeWhileTest(getBooleanValueIfSimpleConstant(node));
	} else {
	assert(parent.body === node);
	state.makeWhileBody();
	}
	break;

	case "DoWhileStatement":
	if (parent.body === node) {
	state.makeDoWhileBody();
	} else {
	assert(parent.test === node);
	state.makeDoWhileTest(getBooleanValueIfSimpleConstant(node));
	}
	break;

	case "ForStatement":
	if (parent.test === node) {
	state.makeForTest(getBooleanValueIfSimpleConstant(node));
	} else if (parent.update === node) {
	state.makeForUpdate();
	} else if (parent.body === node) {
	state.makeForBody();
	}
	break;

	case "ForInStatement":
	case "ForOfStatement":
	if (parent.left === node) {
	state.makeForInOfLeft();
	} else if (parent.right === node) {
	state.makeForInOfRight();
	} else {
	assert(parent.body === node);
	state.makeForInOfBody();
	}
	break;

	case "AssignmentPattern":

	/*
	* Fork if this node is at `right`.
	* `left` is executed always, so it uses the current path.
	* `popForkContext()` exists at `AssignmentPattern:exit`.
	*/
	if (parent.right === node) {
	state.pushForkContext();
	state.forkBypassPath();
	state.forkPath();
	}
	break;

	default:
	break;
	}
	}

	/**
	* Updates the code path due to the type of a given node in entering.
	* @param {CodePathAnalyzer} analyzer The instance.
	* @param {ASTNode} node The current AST node.
	* @returns {void}
	*/
	function processCodePathToEnter(analyzer, node) {
	let codePath = analyzer.codePath;
	let state = codePath && CodePath.getState(codePath);
	const parent = node.parent;

	/**
	* Creates a new code path and trigger the onCodePathStart event
	* based on the currently selected node.
	* @param {string} origin The reason the code path was started.
	* @returns {void}
	*/
	function startCodePath(origin) {
	if (codePath) {

	// Emits onCodePathSegmentStart events if updated.
	forwardCurrentToHead(analyzer, node);
	debug.dumpState(node, state, false);
	}

	// Create the code path of this scope.
	codePath = analyzer.codePath = new CodePath({
	id: analyzer.idGenerator.next(),
	origin,
	upper: codePath,
	onLooped: analyzer.onLooped
	});
	state = CodePath.getState(codePath);

	// Emits onCodePathStart events.
	debug.dump(`onCodePathStart ${codePath.id}`);
	analyzer.emitter.emit("onCodePathStart", codePath, node);
	}

	/*
	* Special case: The right side of class field initializer is considered
	* to be its own function, so we need to start a new code path in this
	* case.
	*/
	if (isPropertyDefinitionValue(node)) {
	startCodePath("class-field-initializer");

	/*
	* Intentional fall through because `node` needs to also be
	* processed by the code below. For example, if we have:
	*
	* class Foo {
	* a = () => {}
	* }
	*
	* In this case, we also need start a second code path.
	*/

	}

	switch (node.type) {
	case "Program":
	startCodePath("program");
	break;

	case "FunctionDeclaration":
	case "FunctionExpression":
	case "ArrowFunctionExpression":
	startCodePath("function");
	break;

	case "StaticBlock":
	startCodePath("class-static-block");
	break;

	case "ChainExpression":
	state.pushChainContext();
	break;
	case "CallExpression":
	if (node.optional === true) {
	state.makeOptionalNode();
	}
	break;
	case "MemberExpression":
	if (node.optional === true) {
	state.makeOptionalNode();
	}
	break;

	case "LogicalExpression":
	if (isHandledLogicalOperator(node.operator)) {
	state.pushChoiceContext(
	node.operator,
	isForkingByTrueOrFalse(node)
	);
	}
	break;

	case "AssignmentExpression":
	if (isLogicalAssignmentOperator(node.operator)) {
	state.pushChoiceContext(
	node.operator.slice(0, -1), // removes `=` from the end
	isForkingByTrueOrFalse(node)
	);
	}
	break;

	case "ConditionalExpression":
	case "IfStatement":
	state.pushChoiceContext("test", false);
	break;

	case "SwitchStatement":
	state.pushSwitchContext(
	node.cases.some(isCaseNode),
	getLabel(node)
	);
	break;

	case "TryStatement":
	state.pushTryContext(Boolean(node.finalizer));
	break;

	case "SwitchCase":

	/*
	* Fork if this node is after the 2st node in `cases`.
	* It's similar to `else` blocks.
	* The next `test` node is processed in this path.
	*/
	if (parent.discriminant !== node && parent.cases[0] !== node) {
	state.forkPath();
	}
	break;

	case "WhileStatement":
	case "DoWhileStatement":
	case "ForStatement":
	case "ForInStatement":
	case "ForOfStatement":
	state.pushLoopContext(node.type, getLabel(node));
	break;

	case "LabeledStatement":
	if (!breakableTypePattern.test(node.body.type)) {
	state.pushBreakContext(false, node.label.name);
	}
	break;

	default:
	break;
	}

	// Emits onCodePathSegmentStart events if updated.
	forwardCurrentToHead(analyzer, node);
	debug.dumpState(node, state, false);
	}

	/**
	* Updates the code path due to the type of a given node in leaving.
	* @param {CodePathAnalyzer} analyzer The instance.
	* @param {ASTNode} node The current AST node.
	* @returns {void}
	*/
	function processCodePathToExit(analyzer, node) {

	const codePath = analyzer.codePath;
	const state = CodePath.getState(codePath);
	let dontForward = false;

	switch (node.type) {
	case "ChainExpression":
	state.popChainContext();
	break;

	case "IfStatement":
	case "ConditionalExpression":
	state.popChoiceContext();
	break;

	case "LogicalExpression":
	if (isHandledLogicalOperator(node.operator)) {
	state.popChoiceContext();
	}
	break;

	case "AssignmentExpression":
	if (isLogicalAssignmentOperator(node.operator)) {
	state.popChoiceContext();
	}
	break;

	case "SwitchStatement":
	state.popSwitchContext();
	break;

	case "SwitchCase":

	/*
	* This is the same as the process at the 1st `consequent` node in
	* `preprocess` function.
	* Must do if this `consequent` is empty.
	*/
	if (node.consequent.length === 0) {
	state.makeSwitchCaseBody(true, !node.test);
	}
	if (state.forkContext.reachable) {
	dontForward = true;
	}
	break;

	case "TryStatement":
	state.popTryContext();
	break;

	case "BreakStatement":
	forwardCurrentToHead(analyzer, node);
	state.makeBreak(node.label && node.label.name);
	dontForward = true;
	break;

	case "ContinueStatement":
	forwardCurrentToHead(analyzer, node);
	state.makeContinue(node.label && node.label.name);
	dontForward = true;
	break;

	case "ReturnStatement":
	forwardCurrentToHead(analyzer, node);
	state.makeReturn();
	dontForward = true;
	break;

	case "ThrowStatement":
	forwardCurrentToHead(analyzer, node);
	state.makeThrow();
	dontForward = true;
	break;

	case "Identifier":
	if (isIdentifierReference(node)) {
	state.makeFirstThrowablePathInTryBlock();
	dontForward = true;
	}
	break;

	case "CallExpression":
	case "ImportExpression":
	case "MemberExpression":
	case "NewExpression":
	case "YieldExpression":
	state.makeFirstThrowablePathInTryBlock();
	break;

	case "WhileStatement":
	case "DoWhileStatement":
	case "ForStatement":
	case "ForInStatement":
	case "ForOfStatement":
	state.popLoopContext();
	break;

	case "AssignmentPattern":
	state.popForkContext();
	break;

	case "LabeledStatement":
	if (!breakableTypePattern.test(node.body.type)) {
	state.popBreakContext();
	}
	break;

	default:
	break;
	}

	// Emits onCodePathSegmentStart events if updated.
	if (!dontForward) {
	forwardCurrentToHead(analyzer, node);
	}
	debug.dumpState(node, state, true);
	}

	/**
	* Updates the code path to finalize the current code path.
	* @param {CodePathAnalyzer} analyzer The instance.
	* @param {ASTNode} node The current AST node.
	* @returns {void}
	*/
	function postprocess(analyzer, node) {

	/**
	* Ends the code path for the current node.
	* @returns {void}
	*/
	function endCodePath() {
	let codePath = analyzer.codePath;

	// Mark the current path as the final node.
	CodePath.getState(codePath).makeFinal();

	// Emits onCodePathSegmentEnd event of the current segments.
	leaveFromCurrentSegment(analyzer, node);

	// Emits onCodePathEnd event of this code path.
	debug.dump(`onCodePathEnd ${codePath.id}`);
	analyzer.emitter.emit("onCodePathEnd", codePath, node);
	debug.dumpDot(codePath);

	codePath = analyzer.codePath = analyzer.codePath.upper;
	if (codePath) {
	debug.dumpState(node, CodePath.getState(codePath), true);
	}

	}

	switch (node.type) {
	case "Program":
	case "FunctionDeclaration":
	case "FunctionExpression":
	case "ArrowFunctionExpression":
	case "StaticBlock": {
	endCodePath();
	break;
	}

	// The `arguments.length >= 1` case is in `preprocess` function.
	case "CallExpression":
	if (node.optional === true && node.arguments.length === 0) {
	CodePath.getState(analyzer.codePath).makeOptionalRight();
	}
	break;

	default:
	break;
	}

	/*
	* Special case: The right side of class field initializer is considered
	* to be its own function, so we need to end a code path in this
	* case.
	*
	* We need to check after the other checks in order to close the
	* code paths in the correct order for code like this:
	*
	*
	* class Foo {
	* a = () => {}
	* }
	*
	* In this case, The ArrowFunctionExpression code path is closed first
	* and then we need to close the code path for the PropertyDefinition
	* value.
	*/
	if (isPropertyDefinitionValue(node)) {
	endCodePath();
	}
	}

	//------------------------------------------------------------------------------
	// Public Interface
	//------------------------------------------------------------------------------

	/**
	* The class to analyze code paths.
	* This class implements the EventGenerator interface.
	*/
	class CodePathAnalyzer {

	/**
	* @param {EventGenerator} eventGenerator An event generator to wrap.
	*/
	constructor(eventGenerator) {
	this.original = eventGenerator;
	this.emitter = eventGenerator.emitter;
	this.codePath = null;
	this.idGenerator = new IdGenerator("s");
	this.currentNode = null;
	this.onLooped = this.onLooped.bind(this);
	}

	/**
	* Does the process to enter a given AST node.
	* This updates state of analysis and calls `enterNode` of the wrapped.
	* @param {ASTNode} node A node which is entering.
	* @returns {void}
	*/
	enterNode(node) {
	this.currentNode = node;

	// Updates the code path due to node's position in its parent node.
	if (node.parent) {
	preprocess(this, node);
	}

	/*
	* Updates the code path.
	* And emits onCodePathStart/onCodePathSegmentStart events.
	*/
	processCodePathToEnter(this, node);

	// Emits node events.
	this.original.enterNode(node);

	this.currentNode = null;
	}

	/**
	* Does the process to leave a given AST node.
	* This updates state of analysis and calls `leaveNode` of the wrapped.
	* @param {ASTNode} node A node which is leaving.
	* @returns {void}
	*/
	leaveNode(node) {
	this.currentNode = node;

	/*
	* Updates the code path.
	* And emits onCodePathStart/onCodePathSegmentStart events.
	*/
	processCodePathToExit(this, node);

	// Emits node events.
	this.original.leaveNode(node);

	// Emits the last onCodePathStart/onCodePathSegmentStart events.
	postprocess(this, node);

	this.currentNode = null;
	}

	/**
	* This is called on a code path looped.
	* Then this raises a looped event.
	* @param {CodePathSegment} fromSegment A segment of prev.
	* @param {CodePathSegment} toSegment A segment of next.
	* @returns {void}
	*/
	onLooped(fromSegment, toSegment) {
	if (fromSegment.reachable && toSegment.reachable) {
	debug.dump(`onCodePathSegmentLoop ${fromSegment.id} -> ${toSegment.id}`);
	this.emitter.emit(
	"onCodePathSegmentLoop",
	fromSegment,
	toSegment,
	this.currentNode
	);
	}
	}
	}

	module.exports = CodePathAnalyzer;