(function (global, factory) {
  typeof exports === 'object' && typeof module !== 'undefined' ? factory(exports) :
  typeof define === 'function' && define.amd ? define(['exports'], factory) :
  (global = global || self, factory((global.acorn = global.acorn || {}, global.acorn.walk = {})));
}(this, function (exports) { 'use strict';

  // AST walker module for Mozilla Parser API compatible trees

  // A simple walk is one where you simply specify callbacks to be
  // called on specific nodes. The last two arguments are optional. A
  // simple use would be
  //
  //     walk.simple(myTree, {
  //         Expression: function(node) { ... }
  //     });
  //
  // to do something with all expressions. All Parser API node types
  // can be used to identify node types, as well as Expression and
  // Statement, which denote categories of nodes.
  //
  // The base argument can be used to pass a custom (recursive)
  // walker, and state can be used to give this walked an initial
  // state.

  function simple(node, visitors, baseVisitor, state, override) {
    if (!baseVisitor) { baseVisitor = base
    ; }(function c(node, st, override) {
      var type = override || node.type, found = visitors[type];
      baseVisitor[type](node, st, c);
      if (found) { found(node, st); }
    })(node, state, override);
  }

  // An ancestor walk keeps an array of ancestor nodes (including the
  // current node) and passes them to the callback as third parameter
  // (and also as state parameter when no other state is present).
  function ancestor(node, visitors, baseVisitor, state) {
    var ancestors = [];
    if (!baseVisitor) { baseVisitor = base
    ; }(function c(node, st, override) {
      var type = override || node.type, found = visitors[type];
      var isNew = node !== ancestors[ancestors.length - 1];
      if (isNew) { ancestors.push(node); }
      baseVisitor[type](node, st, c);
      if (found) { found(node, st || ancestors, ancestors); }
      if (isNew) { ancestors.pop(); }
    })(node, state);
  }

  // A recursive walk is one where your functions override the default
  // walkers. They can modify and replace the state parameter that's
  // threaded through the walk, and can opt how and whether to walk
  // their child nodes (by calling their third argument on these
  // nodes).
  function recursive(node, state, funcs, baseVisitor, override) {
    var visitor = funcs ? make(funcs, baseVisitor || undefined) : baseVisitor
    ;(function c(node, st, override) {
      visitor[override || node.type](node, st, c);
    })(node, state, override);
  }

  function makeTest(test) {
    if (typeof test === "string")
      { return function (type) { return type === test; } }
    else if (!test)
      { return function () { return true; } }
    else
      { return test }
  }

  var Found = function Found(node, state) { this.node = node; this.state = state; };

  // A full walk triggers the callback on each node
  function full(node, callback, baseVisitor, state, override) {
    if (!baseVisitor) { baseVisitor = base
    ; }(function c(node, st, override) {
      var type = override || node.type;
      baseVisitor[type](node, st, c);
      if (!override) { callback(node, st, type); }
    })(node, state, override);
  }

  // An fullAncestor walk is like an ancestor walk, but triggers
  // the callback on each node
  function fullAncestor(node, callback, baseVisitor, state) {
    if (!baseVisitor) { baseVisitor = base; }
    var ancestors = []
    ;(function c(node, st, override) {
      var type = override || node.type;
      var isNew = node !== ancestors[ancestors.length - 1];
      if (isNew) { ancestors.push(node); }
      baseVisitor[type](node, st, c);
      if (!override) { callback(node, st || ancestors, ancestors, type); }
      if (isNew) { ancestors.pop(); }
    })(node, state);
  }

  // Find a node with a given start, end, and type (all are optional,
  // null can be used as wildcard). Returns a {node, state} object, or
  // undefined when it doesn't find a matching node.
  function findNodeAt(node, start, end, test, baseVisitor, state) {
    if (!baseVisitor) { baseVisitor = base; }
    test = makeTest(test);
    try {
      (function c(node, st, override) {
        var type = override || node.type;
        if ((start == null || node.start <= start) &&
            (end == null || node.end >= end))
          { baseVisitor[type](node, st, c); }
        if ((start == null || node.start === start) &&
            (end == null || node.end === end) &&
            test(type, node))
          { throw new Found(node, st) }
      })(node, state);
    } catch (e) {
      if (e instanceof Found) { return e }
      throw e
    }
  }

  // Find the innermost node of a given type that contains the given
  // position. Interface similar to findNodeAt.
  function findNodeAround(node, pos, test, baseVisitor, state) {
    test = makeTest(test);
    if (!baseVisitor) { baseVisitor = base; }
    try {
      (function c(node, st, override) {
        var type = override || node.type;
        if (node.start > pos || node.end < pos) { return }
        baseVisitor[type](node, st, c);
        if (test(type, node)) { throw new Found(node, st) }
      })(node, state);
    } catch (e) {
      if (e instanceof Found) { return e }
      throw e
    }
  }

  // Find the outermost matching node after a given position.
  function findNodeAfter(node, pos, test, baseVisitor, state) {
    test = makeTest(test);
    if (!baseVisitor) { baseVisitor = base; }
    try {
      (function c(node, st, override) {
        if (node.end < pos) { return }
        var type = override || node.type;
        if (node.start >= pos && test(type, node)) { throw new Found(node, st) }
        baseVisitor[type](node, st, c);
      })(node, state);
    } catch (e) {
      if (e instanceof Found) { return e }
      throw e
    }
  }

  // Find the outermost matching node before a given position.
  function findNodeBefore(node, pos, test, baseVisitor, state) {
    test = makeTest(test);
    if (!baseVisitor) { baseVisitor = base; }
    var max
    ;(function c(node, st, override) {
      if (node.start > pos) { return }
      var type = override || node.type;
      if (node.end <= pos && (!max || max.node.end < node.end) && test(type, node))
        { max = new Found(node, st); }
      baseVisitor[type](node, st, c);
    })(node, state);
    return max
  }

  // Fallback to an Object.create polyfill for older environments.
  var create = Object.create || function(proto) {
    function Ctor() {}
    Ctor.prototype = proto;
    return new Ctor
  };

  // Used to create a custom walker. Will fill in all missing node
  // type properties with the defaults.
  function make(funcs, baseVisitor) {
    var visitor = create(baseVisitor || base);
    for (var type in funcs) { visitor[type] = funcs[type]; }
    return visitor
  }

  function skipThrough(node, st, c) { c(node, st); }
  function ignore(_node, _st, _c) {}

  // Node walkers.

  var base = {};

  base.Program = base.BlockStatement = function (node, st, c) {
    for (var i = 0, list = node.body; i < list.length; i += 1)
      {
      var stmt = list[i];

      c(stmt, st, "Statement");
    }
  };
  base.Statement = skipThrough;
  base.EmptyStatement = ignore;
  base.ExpressionStatement = base.ParenthesizedExpression =
    function (node, st, c) { return c(node.expression, st, "Expression"); };
  base.IfStatement = function (node, st, c) {
    c(node.test, st, "Expression");
    c(node.consequent, st, "Statement");
    if (node.alternate) { c(node.alternate, st, "Statement"); }
  };
  base.LabeledStatement = function (node, st, c) { return c(node.body, st, "Statement"); };
  base.BreakStatement = base.ContinueStatement = ignore;
  base.WithStatement = function (node, st, c) {
    c(node.object, st, "Expression");
    c(node.body, st, "Statement");
  };
  base.SwitchStatement = function (node, st, c) {
    c(node.discriminant, st, "Expression");
    for (var i$1 = 0, list$1 = node.cases; i$1 < list$1.length; i$1 += 1) {
      var cs = list$1[i$1];

      if (cs.test) { c(cs.test, st, "Expression"); }
      for (var i = 0, list = cs.consequent; i < list.length; i += 1)
        {
        var cons = list[i];

        c(cons, st, "Statement");
      }
    }
  };
  base.SwitchCase = function (node, st, c) {
    if (node.test) { c(node.test, st, "Expression"); }
    for (var i = 0, list = node.consequent; i < list.length; i += 1)
      {
      var cons = list[i];

      c(cons, st, "Statement");
    }
  };
  base.ReturnStatement = base.YieldExpression = base.AwaitExpression = function (node, st, c) {
    if (node.argument) { c(node.argument, st, "Expression"); }
  };
  base.ThrowStatement = base.SpreadElement =
    function (node, st, c) { return c(node.argument, st, "Expression"); };
  base.TryStatement = function (node, st, c) {
    c(node.block, st, "Statement");
    if (node.handler) { c(node.handler, st); }
    if (node.finalizer) { c(node.finalizer, st, "Statement"); }
  };
  base.CatchClause = function (node, st, c) {
    if (node.param) { c(node.param, st, "Pattern"); }
    c(node.body, st, "Statement");
  };
  base.WhileStatement = base.DoWhileStatement = function (node, st, c) {
    c(node.test, st, "Expression");
    c(node.body, st, "Statement");
  };
  base.ForStatement = function (node, st, c) {
    if (node.init) { c(node.init, st, "ForInit"); }
    if (node.test) { c(node.test, st, "Expression"); }
    if (node.update) { c(node.update, st, "Expression"); }
    c(node.body, st, "Statement");
  };
  base.ForInStatement = base.ForOfStatement = function (node, st, c) {
    c(node.left, st, "ForInit");
    c(node.right, st, "Expression");
    c(node.body, st, "Statement");
  };
  base.ForInit = function (node, st, c) {
    if (node.type === "VariableDeclaration") { c(node, st); }
    else { c(node, st, "Expression"); }
  };
  base.DebuggerStatement = ignore;

  base.FunctionDeclaration = function (node, st, c) { return c(node, st, "Function"); };
  base.VariableDeclaration = function (node, st, c) {
    for (var i = 0, list = node.declarations; i < list.length; i += 1)
      {
      var decl = list[i];

      c(decl, st);
    }
  };
  base.VariableDeclarator = function (node, st, c) {
    c(node.id, st, "Pattern");
    if (node.init) { c(node.init, st, "Expression"); }
  };

  base.Function = function (node, st, c) {
    if (node.id) { c(node.id, st, "Pattern"); }
    for (var i = 0, list = node.params; i < list.length; i += 1)
      {
      var param = list[i];

      c(param, st, "Pattern");
    }
    c(node.body, st, node.expression ? "Expression" : "Statement");
  };

  base.Pattern = function (node, st, c) {
    if (node.type === "Identifier")
      { c(node, st, "VariablePattern"); }
    else if (node.type === "MemberExpression")
      { c(node, st, "MemberPattern"); }
    else
      { c(node, st); }
  };
  base.VariablePattern = ignore;
  base.MemberPattern = skipThrough;
  base.RestElement = function (node, st, c) { return c(node.argument, st, "Pattern"); };
  base.ArrayPattern = function (node, st, c) {
    for (var i = 0, list = node.elements; i < list.length; i += 1) {
      var elt = list[i];

      if (elt) { c(elt, st, "Pattern"); }
    }
  };
  base.ObjectPattern = function (node, st, c) {
    for (var i = 0, list = node.properties; i < list.length; i += 1) {
      var prop = list[i];

      if (prop.type === "Property") {
        if (prop.computed) { c(prop.key, st, "Expression"); }
        c(prop.value, st, "Pattern");
      } else if (prop.type === "RestElement") {
        c(prop.argument, st, "Pattern");
      }
    }
  };

  base.Expression = skipThrough;
  base.ThisExpression = base.Super = base.MetaProperty = ignore;
  base.ArrayExpression = function (node, st, c) {
    for (var i = 0, list = node.elements; i < list.length; i += 1) {
      var elt = list[i];

      if (elt) { c(elt, st, "Expression"); }
    }
  };
  base.ObjectExpression = function (node, st, c) {
    for (var i = 0, list = node.properties; i < list.length; i += 1)
      {
      var prop = list[i];

      c(prop, st);
    }
  };
  base.FunctionExpression = base.ArrowFunctionExpression = base.FunctionDeclaration;
  base.SequenceExpression = function (node, st, c) {
    for (var i = 0, list = node.expressions; i < list.length; i += 1)
      {
      var expr = list[i];

      c(expr, st, "Expression");
    }
  };
  base.TemplateLiteral = function (node, st, c) {
    for (var i = 0, list = node.quasis; i < list.length; i += 1)
      {
      var quasi = list[i];

      c(quasi, st);
    }

    for (var i$1 = 0, list$1 = node.expressions; i$1 < list$1.length; i$1 += 1)
      {
      var expr = list$1[i$1];

      c(expr, st, "Expression");
    }
  };
  base.TemplateElement = ignore;
  base.UnaryExpression = base.UpdateExpression = function (node, st, c) {
    c(node.argument, st, "Expression");
  };
  base.BinaryExpression = base.LogicalExpression = function (node, st, c) {
    c(node.left, st, "Expression");
    c(node.right, st, "Expression");
  };
  base.AssignmentExpression = base.AssignmentPattern = function (node, st, c) {
    c(node.left, st, "Pattern");
    c(node.right, st, "Expression");
  };
  base.ConditionalExpression = function (node, st, c) {
    c(node.test, st, "Expression");
    c(node.consequent, st, "Expression");
    c(node.alternate, st, "Expression");
  };
  base.NewExpression = base.CallExpression = function (node, st, c) {
    c(node.callee, st, "Expression");
    if (node.arguments)
      { for (var i = 0, list = node.arguments; i < list.length; i += 1)
        {
          var arg = list[i];

          c(arg, st, "Expression");
        } }
  };
  base.MemberExpression = function (node, st, c) {
    c(node.object, st, "Expression");
    if (node.computed) { c(node.property, st, "Expression"); }
  };
  base.ExportNamedDeclaration = base.ExportDefaultDeclaration = function (node, st, c) {
    if (node.declaration)
      { c(node.declaration, st, node.type === "ExportNamedDeclaration" || node.declaration.id ? "Statement" : "Expression"); }
    if (node.source) { c(node.source, st, "Expression"); }
  };
  base.ExportAllDeclaration = function (node, st, c) {
    c(node.source, st, "Expression");
  };
  base.ImportDeclaration = function (node, st, c) {
    for (var i = 0, list = node.specifiers; i < list.length; i += 1)
      {
      var spec = list[i];

      c(spec, st);
    }
    c(node.source, st, "Expression");
  };
  base.ImportSpecifier = base.ImportDefaultSpecifier = base.ImportNamespaceSpecifier = base.Identifier = base.Literal = base.Import = ignore;

  base.TaggedTemplateExpression = function (node, st, c) {
    c(node.tag, st, "Expression");
    c(node.quasi, st, "Expression");
  };
  base.ClassDeclaration = base.ClassExpression = function (node, st, c) { return c(node, st, "Class"); };
  base.Class = function (node, st, c) {
    if (node.id) { c(node.id, st, "Pattern"); }
    if (node.superClass) { c(node.superClass, st, "Expression"); }
    c(node.body, st);
  };
  base.ClassBody = function (node, st, c) {
    for (var i = 0, list = node.body; i < list.length; i += 1)
      {
      var elt = list[i];

      c(elt, st);
    }
  };
  base.MethodDefinition = base.Property = function (node, st, c) {
    if (node.computed) { c(node.key, st, "Expression"); }
    c(node.value, st, "Expression");
  };

  exports.ancestor = ancestor;
  exports.base = base;
  exports.findNodeAfter = findNodeAfter;
  exports.findNodeAround = findNodeAround;
  exports.findNodeAt = findNodeAt;
  exports.findNodeBefore = findNodeBefore;
  exports.full = full;
  exports.fullAncestor = fullAncestor;
  exports.make = make;
  exports.recursive = recursive;
  exports.simple = simple;

  Object.defineProperty(exports, '__esModule', { value: true });

}));