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erl_syntax_lib

MODULE

erl_syntax_lib

MODULE SUMMARY

Support library for abstract Erlang syntax trees.

DESCRIPTION

Support library for abstract Erlang syntax trees.

This module contains utility functions for working with the abstract data type defined in the module erl_syntax.

DATA TYPES

ordset(T) = ordset(T) (see module //stdlib/ordsets)
syntaxTree() = syntaxTree() (see module erl_syntax)

An abstract syntax tree. See the erl_syntax module for details.

EXPORTS

analyze_application(Node::syntaxTree()) -> FunctionName | Arity

Types:

FunctionName = {atom(), Arity} | {ModuleName, FunctionName}
Arity = integer()
ModuleName = atom()

Returns the name of a called function. The result is a representation of the name of the applied function F/A, if Node represents a function application "<em>F</em>(<em>X_1</em>, ..., <em>X_A</em>)". If the function is not explicitly named (i.e., F is given by some expression), only the arity A is returned.

The evaluation throws syntax_error if Node does not represent a well-formed application expression.

See also: analyze_function_name/1.

analyze_attribute(Node::syntaxTree()) -> preprocessor | {atom(), atom()}

Analyzes an attribute node. If Node represents a preprocessor directive, the atom preprocessor is returned. Otherwise, if Node represents a module attribute "-<em>Name</em>...", a tuple {Name, Info} is returned, where Info depends on Name, as follows:

{module, Info}

where Info = analyze_module_attribute(Node).

{export, Info}

where Info = analyze_export_attribute(Node).

{import, Info}

where Info = analyze_import_attribute(Node).

{file, Info}

where Info = analyze_file_attribute(Node).

{record, Info}

where Info = analyze_record_attribute(Node).

{Name, Info}

where {Name, Info} = analyze_wild_attribute(Node).

The evaluation throws syntax_error if Node does not represent a well-formed module attribute.

See also: analyze_export_attribute/1, analyze_file_attribute/1, analyze_import_attribute/1, analyze_module_attribute/1, analyze_record_attribute/1, analyze_wild_attribute/1.

analyze_export_attribute(Node::syntaxTree()) -> [FunctionName]

Types:

FunctionName = atom() | {atom(), integer()} | {ModuleName, FunctionName}
ModuleName = atom()

Returns the list of function names declared by an export attribute. We do not guarantee that each name occurs at most once in the list. The order of listing is not defined.

The evaluation throws syntax_error if Node does not represent a well-formed export attribute.

See also: analyze_attribute/1.

analyze_file_attribute(Node::syntaxTree()) -> {string(), integer()}

Returns the file name and line number of a file attribute. The result is the pair {File, Line} if Node represents "-file(File, Line).".

The evaluation throws syntax_error if Node does not represent a well-formed file attribute.

See also: analyze_attribute/1.

analyze_form(Node::syntaxTree()) -> {atom(), term()} | atom()

Analyzes a "source code form" node. If Node is a "form" type (cf. erl_syntax:is_form/1), the returned value is a tuple {Type, Info} where Type is the node type and Info depends on Type, as follows:

{attribute, Info}

where Info = analyze_attribute(Node).

{error_marker, Info}

where Info = erl_syntax:error_marker_info(Node).

{function, Info}

where Info = analyze_function(Node).

{rule, Info}

where Info = analyze_rule(Node).

{warning_marker, Info}

where Info = erl_syntax:warning_marker_info(Node).

For other types of forms, only the node type is returned.

The evaluation throws syntax_error if Node is not well-formed.

See also: analyze_attribute/1, analyze_function/1, analyze_rule/1, erl_syntax:error_marker_info/1, erl_syntax:is_form/1, erl_syntax:warning_marker_info/1.

analyze_forms(Forms) -> [{Key, term()}]

Types:

Forms = syntaxTree() | [syntaxTree()]
Key = attributes | errors | exports | functions | imports | module | records | rules | warnings

Analyzes a sequence of "program forms". The given Forms may be a single syntax tree of type form_list, or a list of "program form" syntax trees. The returned value is a list of pairs {Key, Info}, where each value of Key occurs at most once in the list; the absence of a particular key indicates that there is no well-defined value for that key.

Each entry in the resulting list contains the following corresponding information about the program forms:

{attributes, Attributes}
  • Attributes = [{atom(), term()}]

Attributes is a list of pairs representing the names and corresponding values of all so-called "wild" attributes (as e.g. "-compile(...)") occurring in Forms (cf. analyze_wild_attribute/1). We do not guarantee that each name occurs at most once in the list. The order of listing is not defined.

{errors, Errors}
  • Errors = [term()]

Errors is the list of error descriptors of all error_marker nodes that occur in Forms. The order of listing is not defined.

{exports, Exports}
  • Exports = [FunctionName]

  • FunctionName = atom() | {atom(), integer()} | {ModuleName, FunctionName}

  • ModuleName = atom()

Exports is a list of representations of those function names that are listed by export declaration attributes in Forms (cf. analyze_export_attribute/1). We do not guarantee that each name occurs at most once in the list. The order of listing is not defined.

{functions, Functions}
  • Functions = [{atom(), integer()}]

Functions is a list of the names of the functions that are defined in Forms (cf. analyze_function/1). We do not guarantee that each name occurs at most once in the list. The order of listing is not defined.

{imports, Imports}
  • Imports = [{Module, Names}]

  • Module = atom()

  • Names = [FunctionName]

  • FunctionName = atom() | {atom(), integer()} | {ModuleName, FunctionName}

  • ModuleName = atom()

Imports is a list of pairs representing those module names and corresponding function names that are listed by import declaration attributes in Forms (cf. analyze_import_attribute/1), where each Module occurs at most once in Imports. We do not guarantee that each name occurs at most once in the lists of function names. The order of listing is not defined.

{module, ModuleName}
  • ModuleName = atom()

ModuleName is the name declared by a module attribute in Forms. If no module name is defined in Forms, the result will contain no entry for the module key. If multiple module name declarations should occur, all but the first will be ignored.

{records, Records}
  • Records = [{atom(), Fields}]

  • Fields = [{atom(), Default}]

  • Default = none | syntaxTree()

Records is a list of pairs representing the names and corresponding field declarations of all record declaration attributes occurring in Forms. For fields declared without a default value, the corresponding value for Default is the atom none (cf. analyze_record_attribute/1). We do not guarantee that each record name occurs at most once in the list. The order of listing is not defined.

{rules, Rules}
  • Rules = [{atom(), integer()}]

Rules is a list of the names of the rules that are defined in Forms (cf. analyze_rule/1). We do not guarantee that each name occurs at most once in the list. The order of listing is not defined.

{warnings, Warnings}
  • Warnings = [term()]

Warnings is the list of error descriptors of all warning_marker nodes that occur in Forms. The order of listing is not defined.

The evaluation throws syntax_error if an ill-formed Erlang construct is encountered.

See also: analyze_export_attribute/1, analyze_function/1, analyze_import_attribute/1, analyze_record_attribute/1, analyze_rule/1, analyze_wild_attribute/1, erl_syntax:error_marker_info/1, erl_syntax:warning_marker_info/1.

analyze_function(Node::syntaxTree()) -> {atom(), integer()}

Returns the name and arity of a function definition. The result is a pair {Name, A} if Node represents a function definition "Name(<em>P_1</em>, ..., <em>P_A</em>) -> ...".

The evaluation throws syntax_error if Node does not represent a well-formed function definition.

See also: analyze_rule/1.

analyze_function_name(Node::syntaxTree()) -> FunctionName

Types:

FunctionName = atom() | {atom(), integer()} | {ModuleName, FunctionName}
ModuleName = atom()

Returns the function name represented by a syntax tree. If Node represents a function name, such as "foo/1" or "bloggs:fred/2", a uniform representation of that name is returned. Different nestings of arity and module name qualifiers in the syntax tree does not affect the result.

The evaluation throws syntax_error if Node does not represent a well-formed function name.

analyze_implicit_fun(Node::syntaxTree()) -> FunctionName

Types:

FunctionName = atom() | {atom(), integer()} | {ModuleName, FunctionName}
ModuleName = atom()

Returns the name of an implicit fun expression "fun <em>F</em>". The result is a representation of the function name F. (Cf. analyze_function_name/1.)

The evaluation throws syntax_error if Node does not represent a well-formed implicit fun.

See also: analyze_function_name/1.

analyze_import_attribute(Node::syntaxTree()) -> {atom(), [FunctionName]} | atom()

Types:

FunctionName = atom() | {atom(), integer()} | {ModuleName, FunctionName}
ModuleName = atom()

Returns the module name and (if present) list of function names declared by an import attribute. The returned value is an atom Module or a pair {Module, Names}, where Names is a list of function names declared as imported from the module named by Module. We do not guarantee that each name occurs at most once in Names. The order of listing is not defined.

The evaluation throws syntax_error if Node does not represent a well-formed import attribute.

See also: analyze_attribute/1.

analyze_module_attribute(Node::syntaxTree()) -> Name::atom() | {Name::atom(), Variables::[atom()]}

Returns the module name and possible parameters declared by a module attribute. If the attribute is a plain module declaration such as -module(name), the result is the module name. If the attribute is a parameterized module declaration, the result is a tuple containing the module name and a list of the parameter variable names.

The evaluation throws syntax_error if Node does not represent a well-formed module attribute.

See also: analyze_attribute/1.

analyze_record_attribute(Node::syntaxTree()) -> {atom(), Fields}

Types:

Fields = [{atom(), none | syntaxTree()}]

Returns the name and the list of fields of a record declaration attribute. The result is a pair {Name, Fields}, if Node represents "-record(Name, {...}).", where Fields is a list of pairs {Label, Default} for each field "Label" or "Label = <em>Default</em>" in the declaration, listed in left-to-right order. If the field has no default-value declaration, the value for Default will be the atom none. We do not guarantee that each label occurs at most one in the list.

The evaluation throws syntax_error if Node does not represent a well-formed record declaration attribute.

See also: analyze_attribute/1, analyze_record_field/1.

analyze_record_expr(Node::syntaxTree()) -> {atom(), Info} | atom()

Types:

Info = {atom(), [{atom(), Value}]} | {atom(), atom()} | atom()
Value = none | syntaxTree()

Returns the record name and field name/names of a record expression. If Node has type record_expr, record_index_expr or record_access, a pair {Type, Info} is returned, otherwise an atom Type is returned. Type is the node type of Node, and Info depends on Type, as follows:

record_expr:

{atom(), [{atom(), Value}]}

record_access:

{atom(), atom()} | atom()

record_index_expr:

{atom(), atom()}

For a record_expr node, Info represents the record name and the list of descriptors for the involved fields, listed in the order they appear. (See analyze_record_field/1 for details on the field descriptors). For a record_access node, Info represents the record name and the field name (or if the record name is not included, only the field name; this is allowed only in Mnemosyne-query syntax). For a record_index_expr node, Info represents the record name and the name field name.

The evaluation throws syntax_error if Node represents a record expression that is not well-formed.

See also: analyze_record_attribute/1, analyze_record_field/1.

analyze_record_field(Node::syntaxTree()) -> {atom(), Value}

Types:

Value = none | syntaxTree()

Returns the label and value-expression of a record field specifier. The result is a pair {Label, Value}, if Node represents "Label = <em>Value</em>" or "Label", where in the first case, Value is a syntax tree, and in the second case Value is none.

The evaluation throws syntax_error if Node does not represent a well-formed record field specifier.

See also: analyze_record_attribute/1, analyze_record_expr/1.

analyze_rule(Node::syntaxTree()) -> {atom(), integer()}

Returns the name and arity of a Mnemosyne rule. The result is a pair {Name, A} if Node represents a rule "Name(<em>P_1</em>, ..., <em>P_A</em>) :- ...".

The evaluation throws syntax_error if Node does not represent a well-formed Mnemosyne rule.

See also: analyze_function/1.

analyze_wild_attribute(Node::syntaxTree()) -> {atom(), term()}

Returns the name and value of a "wild" attribute. The result is the pair {Name, Value}, if Node represents "-Name(Value)".

Note that no checking is done whether Name is a reserved attribute name such as module or export: it is assumed that the attribute is "wild".

The evaluation throws syntax_error if Node does not represent a well-formed wild attribute.

See also: analyze_attribute/1.

annotate_bindings(Tree::syntaxTree()) -> syntaxTree()

Adds or updates annotations on nodes in a syntax tree. Equivalent to annotate_bindings(Tree, Bindings) where the top-level environment Bindings is taken from the annotation {env, Bindings} on the root node of Tree. An exception is thrown if no such annotation should exist.

See also: annotate_bindings/2.

annotate_bindings(Tree::syntaxTree(), Bindings::ordset(atom())) -> syntaxTree()

Adds or updates annotations on nodes in a syntax tree. Bindings specifies the set of bound variables in the environment of the top level node. The following annotations are affected:

  • {env, Vars}, representing the input environment of the subtree.

  • {bound, Vars}, representing the variables that are bound in the subtree.

  • {free, Vars}, representing the free variables in the subtree.

Bindings and Vars are ordered-set lists (cf. module ordsets) of atoms representing variable names.

See also: ordsets(3), annotate_bindings/1.

fold(F::Function, Start::term(), Tree::syntaxTree()) -> term()

Types:

Function = (syntaxTree(), term()) -> term()

Folds a function over all nodes of a syntax tree. The result is the value of Function(X1, Function(X2, ... Function(Xn, Start) ... )), where [X1, X2, ..., Xn] are the nodes of Tree in a post-order traversal.

See also: fold_subtrees/3, foldl_listlist/3.

fold_subtrees(F::Function, Start::term(), Tree::syntaxTree()) -> term()

Types:

Function = (syntaxTree(), term()) -> term()

Folds a function over the immediate subtrees of a syntax tree. This is similar to fold/3, but only on the immediate subtrees of Tree, in left-to-right order; it does not include the root node of Tree.

See also: fold/3.

foldl_listlist(F::Function, Start::term(), Ls::[[term()]]) -> term()

Types:

Function = (term(), term()) -> term()

Like lists:foldl/3, but over a list of lists.

See also: lists:foldl/3, fold/3.

function_name_expansions(Names::[Name]) -> [{ShortName, Name}]

Types:

Name = ShortName | {atom(), Name}
ShortName = atom() | {atom(), integer()}

Creates a mapping from corresponding short names to full function names. Names are represented by nested tuples of atoms and integers (cf. analyze_function_name/1). The result is a list containing a pair {ShortName, Name} for each element Name in the given list, where the corresponding ShortName is the rightmost-innermost part of Name. The list thus represents a finite mapping from unqualified names to the corresponding qualified names.

Note: the resulting list can contain more than one tuple {ShortName, Name} for the same ShortName, possibly with different values for Name, depending on the given list.

See also: analyze_function_name/1.

is_fail_expr(Tree::syntaxTree()) -> boolean()

Returns true if Tree represents an expression which never terminates normally. Note that the reverse does not apply. Currently, the detected cases are calls to exit/1, throw/1, erlang:error/1 and erlang:error/2.

See also: erlang:error/1, erlang:error/2, erlang:exit/1, erlang:throw/1.

limit(Tree, Depth) -> syntaxTree()

Equivalent to limit(Tree, Depth, Text) using the text "..." as default replacement.

See also: limit/3, erl_syntax:text/1.

limit(Tree::syntaxTree(), Depth::integer(), Node::syntaxTree()) -> syntaxTree()

Limits a syntax tree to a specified depth. Replaces all non-leaf subtrees in Tree at the given Depth by Node. If Depth is negative, the result is always Node, even if Tree has no subtrees.

When a group of subtrees (as e.g., the argument list of an application node) is at the specified depth, and there are two or more subtrees in the group, these will be collectively replaced by Node even if they are leaf nodes. Groups of subtrees that are above the specified depth will be limited in size, as if each subsequent tree in the group were one level deeper than the previous. E.g., if Tree represents a list of integers "[1, 2, 3, 4, 5, 6, 7, 8, 9, 10]", the result of limit(Tree, 5) will represent [1, 2, 3, 4, ...].

The resulting syntax tree is typically only useful for pretty-printing or similar visual formatting.

See also: limit/2.

map(F::Function, Tree::syntaxTree()) -> syntaxTree()

Types:

Function = (syntaxTree()) -> syntaxTree()

Applies a function to each node of a syntax tree. The result of each application replaces the corresponding original node. The order of traversal is bottom-up.

See also: map_subtrees/2.

map_subtrees(F::Function, Tree::syntaxTree()) -> syntaxTree()

Types:

Function = (Tree) -> Tree1

Applies a function to each immediate subtree of a syntax tree. The result of each application replaces the corresponding original node.

See also: map/2.

mapfold(F::Function, Start::term(), Tree::syntaxTree()) -> {syntaxTree(), term()}

Types:

Function = (syntaxTree(), term()) -> {syntaxTree(), term()}

Combines map and fold in a single operation. This is similar to map/2, but also propagates an extra value from each application of the Function to the next, while doing a post-order traversal of the tree like fold/3. The value Start is passed to the first function application, and the final result is the result of the last application.

See also: fold/3, map/2.

mapfold_subtrees(F::Function, Start::term(), Tree::syntaxTree()) -> {syntaxTree(), term()}

Types:

Function = (syntaxTree(), term()) -> {syntaxTree(), term()}

Does a mapfold operation over the immediate subtrees of a syntax tree. This is similar to mapfold/3, but only on the immediate subtrees of Tree, in left-to-right order; it does not include the root node of Tree.

See also: mapfold/3.

mapfoldl_listlist(F::Function, S::State, Ls::[[term()]]) -> {[[term()]], term()}

Types:

Function = (term(), term()) -> {term(), term()}

Like lists:mapfoldl/3, but over a list of lists. The list of lists in the result has the same structure as the given list of lists.

new_variable_name(Used::set(atom())) -> atom()

Returns an atom which is not already in the set Used. This is equivalent to new_variable_name(Function, Used), where Function maps a given integer N to the atom whose name consists of "V" followed by the numeral for N.

See also: new_variable_name/2.

new_variable_name(F::Function, Used::set(atom())) -> atom()

Types:

Function = (integer()) -> atom()

Returns a user-named atom which is not already in the set Used. The atom is generated by applying the given Function to a generated integer. Integers are generated using an algorithm which tries to keep the names randomly distributed within a reasonably small range relative to the number of elements in the set.

This function uses the module random to generate new keys. The seed it uses may be initialized by calling random:seed/0 or random:seed/3 before this function is first called.

See also: random(3), sets(3), new_variable_name/1.

new_variable_names(N::integer(), Used::set(atom())) -> [atom()]

Like new_variable_name/1, but generates a list of N new names.

See also: new_variable_name/1.

new_variable_names(N::integer(), F::Function, Used::set(atom())) -> [atom()]

Types:

Function = (integer()) -> atom()

Like new_variable_name/2, but generates a list of N new names.

See also: new_variable_name/2.

strip_comments(Tree::syntaxTree()) -> syntaxTree()

Removes all comments from all nodes of a syntax tree. All other attributes (such as position information) remain unchanged. Standalone comments in form lists are removed; any other standalone comments are changed into null-comments (no text, no indentation).

to_comment(Tree) -> syntaxTree()

Equivalent to to_comment(Tree, "% ").

to_comment(Tree::syntaxTree(), Prefix::string()) -> syntaxTree()

Equivalent to to_comment(Tree, Prefix, F) for a default formatting function F. The default F simply calls erl_prettypr:format/1.

See also: to_comment/3, erl_prettypr:format/1.

to_comment(Tree::syntaxTree(), Prefix::string(), F::Printer) -> syntaxTree()

Types:

Printer = (syntaxTree()) -> string()

Transforms a syntax tree into an abstract comment. The lines of the comment contain the text for Node, as produced by the given Printer function. Each line of the comment is prefixed by the string Prefix (this does not include the initial "%" character of the comment line).

For example, the result of to_comment(erl_syntax:abstract([a,b,c])) represents

          %% [a,b,c]

(cf. to_comment/1).

Note: the text returned by the formatting function will be split automatically into separate comment lines at each line break. No extra work is needed.

See also: to_comment/1, to_comment/2.

variables(Tree::syntaxTree()) -> set(atom())

Types:

set(T) (see module //stdlib/sets)

Returns the names of variables occurring in a syntax tree, The result is a set of variable names represented by atoms. Macro names are not included.

See also: sets(3).

Richard Carlsson richardc@it.uu.se