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[Erlang 0109] From Elixir to Erlang Code
Elixir代码最终编译成为erlang代码,这个过程是怎样的?本文通过一个小测试做下探索.
编译一旦完成,你就看到了真相
Elixir代码组织方式一方面和Erlang一样才用非常扁平的代码模块结构,另一方面Elixir同时支持嵌套.Elixir比较方便的一点是可以在Elixir Shell中完成对模块的定义.看下面的方式:
iex> defmodule Math do ...> def sum(a, b) do ...> a + b ...> end ...> end iex> Math.sum(1, 2) 3
下面我们把代码放在m.ex模块中,模块的名字和代码文件的名字是可以不一样的,在编译之后文件夹中新增了一个Elixir.Math.beam的文件.换句话说,elixirc已经把m.ex文件编译成Elixir.Math.beam,按照Erlang对模块名称和文件名一致性的要求,我们可以在Erlang的Shell中验证一下:
[root@nimbus elixir]# elixirc m.ex [root@nimbus elixir]# ls Elixir.Math.beam m.ex [root@nimbus elixir]# erl Erlang R16B01 (erts-5.10.2) [source] [64-bit] [smp:2:2] [async-threads:10] [hipe] [kernel-poll:false] Eshell V5.10.2 (abort with ^G) 1> ‘Elixir.Math‘:sum(12,23). 35 2>
是不是和我们预期的一样?之前提到过多次从beam中还原源代码的方法,现在我们动手看下这个Elixir.Math.beam的Erlang代码是怎样的,输出我做了一下排版:
5> {ok,{_,[{abstract_code,{_,AC}}]}} = beam_lib:chunks("Elixir.Math",[abstract_code]). {ok,{‘Elixir.Math‘, [{abstract_code, {raw_abstract_v1, [{attribute,0,compile, {no_auto_import,[{bitsize,1},{apply,2}, {spawn,2}, {spawn_link,2}, {spawn_monitor,3}, {spawn_opt,2}, {spawn_opt,3}, {spawn,4}, {spawn_link,4}, {spawn_opt,4}, {spawn_opt,5}, {nodes,...}, {...}|...]}}, {attribute,1,file,{"/data2/elixir/m.ex",1}}, {attribute,1,module,‘Elixir.Math‘}, {attribute,1,export,[{‘__info__‘,1},{sum,2}]}, {function,0,‘__info__‘,1, [{clause,0, [{atom,0,functions}], [], [{cons,0,{...},...}]}, {clause,0,[{atom,0,macros}],[],[{nil,0}]}, {clause,0,[{atom,0,docs}],[],[{cons,...}]}, {clause,0,[{atom,0,...}],[],[{...}]}, {clause,0,[{atom,...}],[],[...]}, {clause,0,[{...}],[],...}]}, {function,2,sum,2, [{clause,2, [{var,2,a},{var,2,b}], [], [{op,3,...}]}]}]}}]}} 6> io:fwrite("~s~n", [erl_prettypr:format(erl_syntax:form_list(AC))]). -compile({no_auto_import, [{bitsize, 1}, {apply, 2}, {spawn, 2}, {spawn_link, 2}, {spawn_monitor, 3}, {spawn_opt, 2}, {spawn_opt, 3}, {spawn, 4}, {spawn_link, 4}, {spawn_opt, 4}, {spawn_opt, 5}, {nodes, 0}, {disconnect_node, 1}, {integer_to_list, 2}, {integer_to_binary, 2}, {max, 2}, {min, 2}, {port_control, 3}, {port_connect, 2}, {port_command, 2}, {port_command, 3}, {port_close, 1}, {spawn_monitor, 1}, {spawn, 1}, {load_module, 2}, {spawn_link, 1}, {binary_to_float, 1}, {float_to_binary, 2}, {float_to_binary, 1}, {list_to_integer, 2}, {integer_to_binary, 1}, {binary_to_integer, 2}, {binary_to_integer, 1}, {check_old_code, 1}, {binary_part, 3}, {binary_part, 2}, {binary_to_term, 2}, {binary_to_existing_atom, 2}, {binary_to_atom, 2}, {atom_to_binary, 2}, {bitstring_to_list, 1}, {list_to_bitstring, 1}, {bit_size, 1}, {byte_size, 1}, {tuple_size, 1}, {is_bitstring, 1}, {list_to_existing_atom, 1}, {iolist_to_binary, 1}, {iolist_size, 1}, {is_boolean, 1}, {is_record, 3}, {is_record, 2}, {is_function, 2}, {is_function, 1}, {is_binary, 1}, {is_reference, 1}, {is_port, 1}, {is_pid, 1}, {is_number, 1}, {is_integer, 1}, {is_float, 1}, {is_tuple, 1}, {is_list, 1}, {is_atom, 1}, {error, 2}, {error, 1}, {is_process_alive, 1}, {demonitor, 2}, {demonitor, 1}, {monitor, 2}, {whereis, 1}, {unregister, 1}, {unlink, 1}, {tuple_to_list, 1}, {trunc, 1}, {tl, 1}, {time, 0}, {throw, 1}, {term_to_binary, 2}, {term_to_binary, 1}, {statistics, 1}, {split_binary, 2}, {spawn_link, 3}, {spawn, 3}, {size, 1}, {setelement, 3}, {self, 0}, {round, 1}, {registered, 0}, {register, 2}, {put, 2}, {purge_module, 1}, {processes, 0}, {process_info, 2}, {process_info, 1}, {process_flag, 3}, {process_flag, 2}, {pre_loaded, 0}, {pid_to_list, 1}, {open_port, 2}, {now, 0}, {nodes, 1}, {node, 0}, {node, 1}, {monitor_node, 2}, {module_loaded, 1}, {make_ref, 0}, {list_to_tuple, 1}, {list_to_pid, 1}, {list_to_integer, 1}, {list_to_float, 1}, {list_to_binary, 1}, {list_to_atom, 1}, {link, 1}, {length, 1}, {is_alive, 0}, {integer_to_list, 1}, {hd, 1}, {halt, 2}, {halt, 1}, {halt, 0}, {group_leader, 2}, {group_leader, 0}, {get_keys, 1}, {get, 1}, {get, 0}, {garbage_collect, 1}, {garbage_collect, 0}, {float_to_list, 2}, {float_to_list, 1}, {float, 1}, {exit, 2}, {exit, 1}, {erase, 1}, {erase, 0}, {element, 2}, {delete_module, 1}, {date, 0}, {check_process_code, 2}, {binary_to_term, 1}, {binary_to_list, 3}, {binary_to_list, 1}, {atom_to_list, 1}, {apply, 3}, {abs, 1}]}). -file("/data2/elixir/m.ex", 1). -module(‘Elixir.Math‘). -export([‘__info__‘/1, sum/2]). ‘__info__‘(functions) -> [{sum, 2}]; ‘__info__‘(macros) -> []; ‘__info__‘(docs) -> [{{sum, 2}, 2, def, [{a, [{line, 2}], nil}, {b, [{line, 2}], nil}], nil}]; ‘__info__‘(moduledoc) -> {1, nil}; ‘__info__‘(module) -> ‘Elixir.Math‘; ‘__info__‘(atom) -> module_info(atom). sum(a, b) -> a + b. ok 7>
如何编译的?
下面我们探究一下Elixir编译的过程,切入点当然是elixirc,打开这个脚本:
可以看到完成了一些环境变量解析之后,最终是调用了elixir
exec "$SCRIPT_PATH"/elixir +compile "$@"
OK,我们继续跟进elixir,经过一番参数检查,变量解析后,最后执行的命令类似下面:
erl -pa "$SCRIPT_PATH"/../lib/*/ebin -noshell -s elixir start_cli -extra +compile
简单回顾一下erlang 运行时环境启动的参数,erl的参数分三种:加号+后面跟的是 emulator flags,单连字符"-"后面跟的是flags,init进程会完成这些参数的解析; -extra 后面跟的内容都会被当做是plain arguments. http://erlang.org/doc/man/erl.html
% erl +W w -sname arnie +R 9 -s my_init -extra +bertie (arnie@host)1> init:get_argument(sname). {ok,[["arnie"]]} (arnie@host)2> init:get_plain_arguments(). ["+bertie"]
Here +W w and +R 9 are emulator flags. -s my_init is an init flag, interpreted by init. -sname arnie is a user flag, stored by init. It is read by Kernel and will cause the Erlang runtime system to become distributed. Finally, everything after -extra (that is, +bertie) is considered as plain arguments.
% erl -myflag 1 1> init:get_argument(myflag). {ok,[["1"]]} 2> init:get_plain_arguments(). []
Here the user flag -myflag 1 is passed to and stored by the init process. It is a user defined flag, presumably used by some user defined application.
书归正传,elixir代码里面给我们后续跟进的线索"-s elixir start_cli",废话少说,打开文件:
https://github.com/elixir-lang/elixir/blob/master/lib/elixir/src/elixir.erl
%% Boot and process given options. Invoked by Elixir‘s script. start_cli() -> application:start(?MODULE), ‘Elixir.Kernel.CLI‘:main(init:get_plain_arguments()).
ok,下面我们手工完成m.ex文件的编译过程(为了方便执行你可以去/elixir/lib/elixir/ebin文件夹),我们分两步1.启动elixir 2.调用编译函数 ‘Elixir.Kernel.CLI‘:main(["+compile","m.ex"]).之所以要启动elixir,是为了完成类似code_server的职责.
[root@nimbus ebin]# erl Erlang R16B01 (erts-5.10.2) [source] [64-bit] [smp:2:2] [async-threads:10] [hipe] [kernel-poll:false] Eshell V5.10.2 (abort with ^G) 1> application:start(elixir). ok 2> ‘Elixir.Kernel.CLI‘:main(["+compile","m.ex"]).
检查文件夹中的文件,是不是已经编译好了.
{ok,"今天就到这里."}
如果你要继续跟进代码,你可以看到:
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 | @doc "" " This is the API invoked by Elixir boot process. "" " def main(argv) do argv = lc arg inlist argv, do : String.from_char_list!(arg) { config, argv } = process_argv(argv, Kernel.CLI.Config. new ) System.argv(argv) run fn -> command_results = Enum.map(Enum.reverse(config.commands), &process_command(&1, config)) command_errors = lc { :error, msg } inlist command_results, do : msg errors = Enum.reverse(config.errors) ++ command_errors if errors != [] do Enum.each(errors, &IO.puts(:stderr, &1)) System.halt(1) end end, config.halt end |
1 2 3 | defp process_argv([ "+compile" |t], config) do process_compiler t, config end |
最后,于"金蝉脱壳"上映之际小图一张
[Erlang 0109] From Elixir to Erlang Code
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