View Source cerl_clauses (compiler v8.5.1)
Utility functions for Core Erlang case/receive clauses.
Note
The documentation of the public interface for the Erlang compiler can be found in module
compile
.This module is an internal part of the compiler. Its API is not guaranteed to remain compatible between releases.
Syntax trees are defined in the module cerl
.
Summary
Functions
Returns true
if any of the abstract clauses in the list is a catch-all,
otherwise false
.
Tries to reduce a guard expression to a single constant value, if possible.
Returns true
if an abstract clause is a catch-all, otherwise false
.
Matches a pattern against an expression.
Like match/2
, but matching a sequence of patterns against a
sequence of expressions.
Equivalent to reduce(Cs, []).
Selects a single clause, if possible, or otherwise reduces the list of selectable clauses.
Types
Functions
Returns true
if any of the abstract clauses in the list is a catch-all,
otherwise false
.
See is_catchall/1
for details.
Note: each node in Clauses
must have type clause
.
See also: is_catchall/1
.
Tries to reduce a guard expression to a single constant value, if possible.
The returned value is {value, Term}
if the guard expression Expr
always yields the constant value Term
, and is otherwise none
.
Note that although guard expressions should only yield boolean values, this
function does not guarantee that Term
is either true
or false
. Also note
that only simple constructs like let-expressions are examined recursively;
general constant folding is not performed.
See also: is_catchall/1
.
-spec is_catchall(Clause :: cerl:c_clause()) -> boolean().
Returns true
if an abstract clause is a catch-all, otherwise false
.
A clause is a catch-all if all its patterns are variables, and its
guard expression always evaluates to true
;
cf. eval_guard/1
.
Note: Clause
must have type clause
.
See also: any_catchall/1
, eval_guard/1
.
Matches a pattern against an expression.
The returned value is none
if a match is impossible, {true, Bindings}
if Pattern
definitely matches Expr
, and {false, Bindings}
if a match is not definite, but cannot be excluded.
Bindings
is then a list of pairs {Var, SubExpr}
, associating each
variable in the pattern with either the corresponding subexpression of
Expr
, or with the atom any
if no matching subexpression
exists. (Recall that variables may not be repeated in a Core Erlang
pattern.) The list of bindings is given in innermost-first order; this
should only be of interest if Pattern
contains one or more alias
patterns. If the returned value is {true, []}
, it implies that the
pattern and the expression are syntactically identical.
Instead of a syntax tree, the atom any
can be passed for Expr
(or, more
generally, be used for any subtree of Expr
, in as much the abstract syntax
tree implementation allows it); this means that it cannot be decided whether the
pattern will match or not, and the corresponding variable bindings will all map
to any
. The typical use is for producing bindings for receive
clauses.
Note: Binary-syntax patterns are never structurally matched against binary-syntax expressions by this function.
Examples:
- Matching a pattern "
{X, Y}
" against the expression "{foo, f(Z)}
" yields{true, Bindings}
whereBindings
associates "X
" with the subtree "foo
" and "Y
" with the subtree "f(Z)
". - Matching pattern "
{X, {bar, Y}}
" against expression "{foo, f(Z)}
" yields{false, Bindings}
whereBindings
associates "X
" with the subtree "foo
" and "Y
" withany
(because it is not known if "{foo, Y}
" might match the run-time value of "f(Z)
" or not). - Matching pattern "
{foo, bar}
" against expression "{foo, f()}
" yields{false, []}
, telling us that there might be a match, but we cannot deduce any bindings. - Matching
{foo, X = {bar, Y}}
against expression "{foo, {bar, baz}}
" yields{true, Bindings}
whereBindings
associates "Y
" with "baz
", and "X
" with "{bar, baz}
". - Matching a pattern "
{X, Y}
" againstany
yields{false, Bindings}
whereBindings
associates both "X
" and "Y
" withany
.
Like match/2
, but matching a sequence of patterns against a
sequence of expressions.
Passing an empty list for Exprs
is equivalent to passing a list of
any
atoms of the same length as Patterns
.
See also: match/2
.
-spec reduce([cerl:c_clause()]) -> {true, {cerl:c_clause(), bindings()}} | {false, [cerl:c_clause()]}.
Equivalent to reduce(Cs, []).
-spec reduce(Clauses :: [cerl:c_clause()], Exprs :: [expr()]) -> {true, {cerl:c_clause(), bindings()}} | {false, [cerl:c_clause()]}.
Selects a single clause, if possible, or otherwise reduces the list of selectable clauses.
The input is a list Clauses
of abstract clauses (i.e.,
syntax trees of type clause
), and a list of switch expressions Exprs
. The
function tries to uniquely select a single clause or discard unselectable
clauses, with respect to the switch expressions. All abstract clauses in the
list must have the same number of patterns. If Exprs
is not the empty list, it
must have the same length as the number of patterns in each clause; see
match_list/2
for details.
A clause can only be selected if its guard expression always yields the atom
true
, and a clause whose guard expression always yields the atom false
can
never be selected. Other guard expressions are considered to have unknown value;
cf. eval_guard/1
.
If a particular clause can be selected, the function returns
{true, {Clause, Bindings}}
, where Clause
is the selected clause and
Bindings
is a list of pairs {Var, SubExpr}
associating the variables
occurring in the patterns of Clause
with the corresponding subexpressions in
Exprs
. The list of bindings is given in innermost-first order; see the
match/2
function for details.
If no clause could be definitely selected, the function returns
{false, NewClauses}
, where NewClauses
is the list of entries in Clauses
that remain after eliminating unselectable clauses, preserving the relative
order.
See also: eval_guard/1
, match/2
, match_list/2
.