Core Erlang Wrap Up
This blog post wraps up the exploration of Core Erlang started in the previous two blog posts. The remaining default Core Erlang passes are described, followed by a look at how Core Erlang is represented internally in the compiler.
Here are the Core Erlang passes that will be run when using
OTP 21 RC1 or the master
branch in the git repository:
$ erlc +time core_wrapup.erl
Compiling "core_wrapup"
.
.
.
core : 0.000 s 15.7 kB
sys_core_fold : 0.000 s 9.0 kB
sys_core_alias : 0.000 s 9.0 kB
core_transforms : 0.000 s 9.0 kB
sys_core_bsm : 0.000 s 9.0 kB
sys_core_dsetel : 0.000 s 9.0 kB
.
.
.
We have covered core
and sys_core_fold
in the two previous
blog posts about Core Erlang.
The other Core Erlang passes #
sys_core_alias #
In the upcoming OTP 21 release, there is a new sys_core_alias
pass
contributed by José Valim.
The purpose of the pass is to avoid rebuilding terms that have been matched, such as in this example:
remove_even([{Key,Val}|T]) ->
case Val rem 2 =:= 0 of
true -> remove_even(T);
false -> [{Key,Val}|remove_even(T)]
end;
remove_even([]) -> [].
In the function head, the pattern {Key,Val}
binds two elements of a
tuple to the variables Key
and Val
, but the original tuple is not
captured. In the false
clause of the case
, a new tuple will be
constructed from Key
and Val
.
It is possible to avoid creating a new tuple by using the =
operator
to bind the complete tuple to a variable:
remove_even([{Key,Val}=Tuple|T]) ->
case Val rem 2 =:= 0 of
true -> remove_even(T);
false -> [Tuple|remove_even(T)]
end;
remove_even([]) -> [].
Essentially, the new sys_core_alias
pass does that transformation
automatically. Here is the Core Erlang code before applying this
optimization:
'remove_even'/1 =
fun (_0) ->
case _0 of
<[{Key,Val}|T]> when 'true' ->
let <_1> =
call
'erlang':'rem'(Val, 2)
in
case <> of
<>
when call 'erlang':'=:='(_1, 0) ->
apply 'remove_even'/1(T)
<> when 'true' ->
let <_2> =
apply 'remove_even'/1(T)
in
[{Key,Val}|_2] % BUILDING TUPLE
end
<[]> when 'true' ->
[]
<_4> when 'true' ->
primop 'match_fail'({'function_clause',_4})
end
Here is the code after running the sys_core_alias
pass:
'remove_even'/1 =
fun (_0) ->
case _0 of
<[_@r0 = {Key,Val}|T]> when 'true' ->
let <_1> =
call 'erlang':'rem'(Val, 2)
in
case <> of
<>
when call 'erlang':'=:='(_1, 0) ->
apply 'remove_even'/1(T)
<> when 'true' ->
let <_2> =
apply 'remove_even'/1(T)
in
[_@r0|_2] % REUSING EXISTING TUPLE
end
<[]> when 'true' ->
[]
<_4> when 'true' ->
primop 'match_fail'({'function_clause',_4})
end
core_transforms #
Similar to parse transforms, the core_transforms
pass makes it possible to
add compiler passes that transform the Core Erlang code without modifying
the compiler.
As an example, here is a simple core transform module:
-module(my_core_transform).
-export([core_transform/2]).
core_transform(Core, _Options) ->
Module = cerl:concrete(cerl:module_name(Core)),
io:format("Module name: ~p\n", [Module]),
io:format("Number of nodes in Core Erlang tree: ~p\n",
[cerl_trees:size(Core)]),
Core.
Before explaining the code, let’s see it in action:
$ erlc my_core_transform
$ erlc -pa . '+{core_transform,my_core_transform}' core_wrapup.erl
Module name: core_wrapup
Number of nodes in Core Erlang tree: 220
$
The {core_transform,Name}
option instructs the compiler to run a
core transformation. In this case, the core transform module is
my_core_transform
. After doing the standard optimizing passes,
the compiler will call my_core_transform:core_transform/2
, passing
the Core Erlang code as the first argument and the compiler options
as the second argument.
The first line in the core_transform/2
functions calls
cerl:module_name(Core)
to retrieve the module name. The return value
of cerl:module_name/1
is a record representing any literal term. To
retrieve the actual term (an atom in this case), cerl:concrete/1
is called.
In the second io:format/2
call, we call cerl_trees:size/1
to
count the number of nodes in the tree that represents the Core Erlang
code for the module.
This core transform does not do any real transforming, since the last line returns the Core Erlang code without any modifications.
sys_core_bsm #
sys_core_bsm
is the first of three passes that implement the delayed
sub binary optimization described in the Efficiency
Guide. sys_core_bsm
adds annotations that are
later used by v3_codegen
and beam_bsm
to optimize matching of
binaries.
sys_core_dsetel #
The sys_core_dsetel
pass will optimize chained or nested
applications of setelement/3
as in this example:
update_tuple(T0) ->
T = setelement(3, T0, y),
setelement(2, T, x).
Translated to Core Erlang it looks like this:
'update_tuple'/1 =
fun (_0) ->
let <T> =
call 'erlang':'setelement'(3, _0, 'y')
in
call 'erlang':'setelement'(2, T, 'x')
The sys_core_dsetel
pass replaces the second call to setelement/3
with the primop dsetelement/3
, which destructively updates a tuple:
'update_tuple'/1 =
fun (_0) ->
let <T> =
call 'erlang':'setelement'(3, _0, 'y')
in do
primop 'dsetelement'(2, T, 'x')
T
do
evaluates two expressions in sequence, ignoring the value of the
first expression. It is used here because the primop dsetelement/3
updates its tuple argument without returning a value.
The sys_core_dsetel
pass is intentionally run as the very last
Core Erlang pass. Doing other optimizations might render the optimization
unsafe. For example, there must not occur a garbage collection between
the call to setelement/3
and dsetelement/3
.
Why is this optimization useful? Surely a sequence of setelement/3
calls must be rare?
Consider this function that updates two elements in a record:
-record(rec, {a,b,c,d,e,f,g,h}).
update_record(R) ->
R#rec{a=x,b=y}.
In a previous blog post we saw that the -E
option
will produce an .E
file with the code after records have been translated
to tuple operations:
$ erlc -E core_wrapup.erl
Here is the code for update_record/1
after record translation:
update_record(R) ->
begin
rec0 = R,
case rec0 of
{rec,_,_,_,_,_,_,_,_} ->
setelement(2, setelement(3, rec0, y), x);
_ ->
error({badrecord,rec})
end
end.
After verifying that R
is indeed a record of the correct type (that is,
that the size and first element of the tuple are correct), nested calls
to setelement/3
is used to update two elements of the tuple.
The optimized Core Erlang code for update_record/1
will look like
this:
'update_record'/1 =
fun (_0) ->
case _0 of
<{'rec',_5,_6,_7,_8,_9,_10,_11,_12}> when 'true' ->
let <_2> =
call 'erlang':'setelement'(3, _0, 'y')
in do primop 'dsetelement'(2, _2, 'x')
_2
<_13> when 'true' ->
call 'erlang':'error'({'badrecord','rec'})
end
The representation of Core Erlang code #
So far we have looked at the external (pretty-printed) representation of Core Erlang. Before leaving Core Erlang, we will take a brief look at the internal representation of Core Erlang that the compiler uses.
There are two three ways to work with Core Erlang within an
optimizer pass:
-
Using the API functions in the
cerl
module -
Using the
c_*
records defined incore_parse.hrl
-
Mixing use of records with use of the API functions
Using the cerl module and friends #
The cerl
module provides API functions to construct, deconstruct, update,
and query each of the constructs in Core Erlang.
Here are some examples:
-
cerl:c_var(Name)
constructs the Core Erlang representation of a variable with the nameName
. -
cerl:is_c_var(Core)
returnstrue
if theCore
represents a Core Erlang variable, andfalse
otherwise. -
cerl:var_name(Core)
returns the name of a variable (and crashes ifCore
does not represent a Core Erlang variable).
There are also the cerl_trees
and cerl_clauses
modules that provide
useful utility functions for manipulating Core Erlang code.
Using the records #
In core_parse.hrl
, there is one record for each kind of Core Erlang
construct. All record names start with the prefix c_
.
For example, the record #c_var{}
represents a variable, the record
#c_call{}
the call
expression, the record c_tuple{}
a tuple, and
so on.
As a complete example, we can rewrite our previous core transform
to use record matching instead of cerl
to retrieve the module name:
-module(my_core_transform).
-export([core_transform/2]).
-include_lib("compiler/src/core_parse.hrl").
core_transform(Core, _Options) ->
#c_module{name=#c_literal{val=Module}} = Core,
io:format("Module name: ~p\n", [Module]),
io:format("Number of nodes in Core Erlang tree: ~p\n",
[cerl_trees:size(Core)]),
Core.
Mixing the cerl
API with records #
The cerl
module internally use the records in core_parse.hrl
, so
the two approaches can be mixed. For example, sys_core_fold
mostly
use the records, but sometimes uses cerl
when it is more convenient.
Wrapping up the wrap up #
It seems that there is enough material for several more blog posts about Core Erlang. For instance, I haven’t even mentioned the inliners (not a typo, there are two inliners). That means that there might be more blog posts about Core Erlang in the future.
But in the very near future, it is time to explore the compiler passes
that follow Core Erlang, and perhaps answer the eternal question about
the v3_
prefix. Was there ever a v2_kernel
(spoiler: yes) or a
v1_kernel
(spoiler: no)?