%% %% %CopyrightBegin% %% %% Copyright Ericsson AB 1996-2013. All Rights Reserved. %% %% The contents of this file are subject to the Erlang Public License, %% Version 1.1, (the "License"); you may not use this file except in %% compliance with the License. You should have received a copy of the %% Erlang Public License along with this software. If not, it can be %% retrieved online at http://www.erlang.org/. %% %% Software distributed under the License is distributed on an "AS IS" %% basis, WITHOUT WARRANTY OF ANY KIND, either express or implied. See %% the License for the specific language governing rights and limitations %% under the License. %% %% %CopyrightEnd% %% -module(c). %% Utilities to use from shell. %% Avoid warning for local function error/2 clashing with autoimported BIF. -compile({no_auto_import,[error/2]}). -export([help/0,lc/1,c/1,c/2,nc/1,nc/2, nl/1,l/1,i/0,i/1,ni/0, y/1, y/2, lc_batch/0, lc_batch/1, i/3,pid/3,m/0,m/1, bt/1, q/0, erlangrc/0,erlangrc/1,bi/1, flush/0, regs/0, nregs/0,pwd/0,ls/0,ls/1,cd/1,memory/1,memory/0, xm/1]). -export([display_info/1]). -export([appcall/4]). -import(lists, [reverse/1,flatten/1,sublist/3,sort/1,keysort/2, concat/1,max/1,min/1,foreach/2,foldl/3,flatmap/2]). -import(io, [format/1, format/2]). %%----------------------------------------------------------------------- -spec help() -> 'ok'. help() -> io:put_chars(<<"bt(Pid) -- stack backtrace for a process\n" "c(File) -- compile and load code in \n" "cd(Dir) -- change working directory\n" "flush() -- flush any messages sent to the shell\n" "help() -- help info\n" "i() -- information about the system\n" "ni() -- information about the networked system\n" "i(X,Y,Z) -- information about pid \n" "l(Module) -- load or reload module\n" "lc([File]) -- compile a list of Erlang modules\n" "ls() -- list files in the current directory\n" "ls(Dir) -- list files in directory \n" "m() -- which modules are loaded\n" "m(Mod) -- information about module \n" "memory() -- memory allocation information\n" "memory(T) -- memory allocation information of type \n" "nc(File) -- compile and load code in on all nodes\n" "nl(Module) -- load module on all nodes\n" "pid(X,Y,Z) -- convert X,Y,Z to a Pid\n" "pwd() -- print working directory\n" "q() -- quit - shorthand for init:stop()\n" "regs() -- information about registered processes\n" "nregs() -- information about all registered processes\n" "xm(M) -- cross reference check a module\n" "y(File) -- generate a Yecc parser\n">>). %% c(FileName) %% Compile a file/module. -spec c(File) -> {'ok', Module} | 'error' when File :: file:name(), Module :: module(). c(File) -> c(File, []). -spec c(File, Options) -> {'ok', Module} | 'error' when File :: file:name(), Options :: [compile:option()], Module :: module(). c(File, Opts0) when is_list(Opts0) -> Opts = [report_errors,report_warnings|Opts0], case compile:file(File, Opts) of {ok,Mod} -> %Listing file. machine_load(Mod, File, Opts); {ok,Mod,_Ws} -> %Warnings maybe turned on. machine_load(Mod, File, Opts); Other -> %Errors go here Other end; c(File, Opt) -> c(File, [Opt]). %%% Obtain the 'outdir' option from the argument. Return "." if no %%% such option was given. -spec outdir([compile:option()]) -> file:filename(). outdir([]) -> "."; outdir([Opt|Rest]) -> case Opt of {outdir, D} -> D; _ -> outdir(Rest) end. %%% We have compiled File with options Opts. Find out where the %%% output file went to, and load it. machine_load(Mod, File, Opts) -> Dir = outdir(Opts), File2 = filename:join(Dir, filename:basename(File, ".erl")), case compile:output_generated(Opts) of true -> Base = atom_to_list(Mod), case filename:basename(File, ".erl") of Base -> code:purge(Mod), check_load(code:load_abs(File2,Mod), Mod); _OtherMod -> format("** Module name '~p' does not match file name '~tp' **~n", [Mod,File]), {error, badfile} end; false -> format("** Warning: No object file created - nothing loaded **~n", []), ok end. %%% This function previously warned if the loaded module was %%% loaded from some other place than current directory. %%% Now, loading from other than current directory is supposed to work. %%% so this function does nothing special. check_load({error, _R} = Error, _) -> Error; check_load(_, Mod) -> {ok, Mod}. %% Compile a list of modules %% enables the nice unix shell cmd %% erl -s c lc f1 f2 f3 @d c1=v1 @c2 @i IDir @o ODir -s erlang halt %% to compile files f1.erl , f2.erl ....... from a unix shell %% with constant c2 defined, c1=v1 (v1 must be a term!), include dir %% IDir, outdir ODir. -spec lc(Files) -> 'ok' | 'error' when Files :: [File :: erl_compile:cmd_line_arg()]. lc(Args) -> case catch split(Args, [], []) of error -> error; {Opts, Files} -> COpts = [report_errors, report_warnings | reverse(Opts)], foreach(fun(File) -> compile:file(File, COpts) end, reverse(Files)) end. %%% lc_batch/1 works like lc/1, but halts afterwards, with appropriate %%% exit code. This is meant to be called by "erl -compile". -spec lc_batch() -> no_return(). lc_batch() -> io:format("Error: no files to compile~n"), halt(1). -spec lc_batch([erl_compile:cmd_line_arg()]) -> no_return(). lc_batch(Args) -> try split(Args, [], []) of {Opts, Files} -> COpts = [report_errors, report_warnings | reverse(Opts)], Res = [compile:file(File, COpts) || File <- reverse(Files)], case lists:member(error, Res) of true -> halt(1); false -> halt(0) end catch throw:error -> halt(1) end. split(['@i', Dir | T], Opts, Files) -> split(T, [{i, atom_to_list(Dir)} | Opts], Files); split(['@o', Dir | T], Opts, Files) -> split(T, [{outdir, atom_to_list(Dir)} | Opts], Files); split(['@d', Def | T], Opts, Files) -> split(T, [split_def(atom_to_list(Def), []) | Opts], Files); split([File | T], Opts, Files) -> split(T, Opts, [File | Files]); split([], Opts, Files) -> {Opts, Files}. split_def([$= | T], Res) -> {d, list_to_atom(reverse(Res)),make_term(T)}; split_def([H | T], Res) -> split_def(T, [H | Res]); split_def([], Res) -> {d, list_to_atom(reverse(Res))}. make_term(Str) -> case erl_scan:string(Str) of {ok, Tokens, _} -> case erl_parse:parse_term(Tokens ++ [{dot, 1}]) of {ok, Term} -> Term; {error, {_,_,Reason}} -> io:format("~ts: ~ts~n", [Reason, Str]), throw(error) end; {error, {_,_,Reason}, _} -> io:format("~ts: ~ts~n", [Reason, Str]), throw(error) end. -spec nc(File) -> {'ok', Module} | 'error' when File :: file:name(), Module :: module(). nc(File) -> nc(File, []). -spec nc(File, Options) -> {'ok', Module} | 'error' when File :: file:name(), Options :: [Option] | Option, Option:: compile:option(), Module :: module(). nc(File, Opts0) when is_list(Opts0) -> Opts = Opts0 ++ [report_errors, report_warnings], case compile:file(File, Opts) of {ok,Mod} -> Dir = outdir(Opts), Obj = filename:basename(File, ".erl") ++ code:objfile_extension(), Fname = filename:join(Dir, Obj), case file:read_file(Fname) of {ok,Bin} -> rpc:eval_everywhere(code,load_binary,[Mod,Fname,Bin]), {ok,Mod}; Other -> Other end; Other -> %Errors go here Other end; nc(File, Opt) when is_atom(Opt) -> nc(File, [Opt]). %% l(Mod) %% Reload module Mod from file of same name -spec l(Module) -> code:load_ret() when Module :: module(). l(Mod) -> code:purge(Mod), code:load_file(Mod). %% Network version of l/1 -spec nl(Module) -> abcast | error when Module :: module(). nl(Mod) -> case code:get_object_code(Mod) of {_Module, Bin, Fname} -> rpc:eval_everywhere(code, load_binary, [Mod, Fname, Bin]); Other -> Other end. -spec i() -> 'ok'. i() -> i(processes()). -spec ni() -> 'ok'. ni() -> i(all_procs()). -spec i([pid()]) -> 'ok'. i(Ps) -> i(Ps, length(Ps)). -spec i([pid()], non_neg_integer()) -> 'ok'. i(Ps, N) when N =< 100 -> iformat("Pid", "Initial Call", "Heap", "Reds", "Msgs"), iformat("Registered", "Current Function", "Stack", "", ""), {R,M,H,S} = foldl(fun(Pid, {R0,M0,H0,S0}) -> {A,B,C,D} = display_info(Pid), {R0+A,M0+B,H0+C,S0+D} end, {0,0,0,0}, Ps), iformat("Total", "", w(H), w(R), w(M)), iformat("", "", w(S), "", ""); i(Ps, N) -> iformat("Pid", "Initial Call", "Heap", "Reds", "Msgs"), iformat("Registered", "Current Function", "Stack", "", ""), paged_i(Ps, {0,0,0,0}, N, 50). paged_i([], {R,M,H,S}, _, _) -> iformat("Total", "", w(H), w(R), w(M)), iformat("", "", w(S), "", ""); paged_i(Ps, Acc, N, Page) -> {Pids, Rest, N1} = if N > Page -> {L1,L2} = lists:split(Page, Ps), {L1,L2,N-Page}; true -> {Ps, [], 0} end, NewAcc = foldl(fun(Pid, {R,M,H,S}) -> {A,B,C,D} = display_info(Pid), {R+A,M+B,H+C,S+D} end, Acc, Pids), case Rest of [_|_] -> choice(fun() -> paged_i(Rest, NewAcc, N1, Page) end); [] -> paged_i([], NewAcc, 0, Page) end. choice(F) -> case get_line('(c)ontinue (q)uit -->', "c\n") of "c\n" -> F(); "q\n" -> quit; _ -> choice(F) end. get_line(P, Default) -> case line_string(io:get_line(P)) of "\n" -> Default; L -> L end. %% If the standard input is set to binary mode %% convert it to a list so we can properly match. line_string(Binary) when is_binary(Binary) -> unicode:characters_to_list(Binary); line_string(Other) -> Other. mfa_string(Fun) when is_function(Fun) -> {module,M} = erlang:fun_info(Fun, module), {name,F} = erlang:fun_info(Fun, name), {arity,A} = erlang:fun_info(Fun, arity), mfa_string({M,F,A}); mfa_string({M,F,A}) -> io_lib:format("~w:~w/~w", [M,F,A]); mfa_string(X) -> w(X). display_info(Pid) -> case pinfo(Pid) of undefined -> {0,0,0,0}; Info -> Call = initial_call(Info), Curr = case fetch(current_function, Info) of {Mod,F,Args} when is_list(Args) -> {Mod,F,length(Args)}; Other -> Other end, Reds = fetch(reductions, Info), LM = length(fetch(messages, Info)), HS = fetch(heap_size, Info), SS = fetch(stack_size, Info), iformat(w(Pid), mfa_string(Call), w(HS), w(Reds), w(LM)), iformat(case fetch(registered_name, Info) of 0 -> ""; X -> w(X) end, mfa_string(Curr), w(SS), "", ""), {Reds, LM, HS, SS} end. %% We have to do some assumptions about the initial call. %% If the initial call is proc_lib:init_p/3,5 we can find more information %% calling the function proc_lib:initial_call/1. initial_call(Info) -> case fetch(initial_call, Info) of {proc_lib, init_p, _} -> proc_lib:translate_initial_call(Info); ICall -> ICall end. iformat(A1, A2, A3, A4, A5) -> format("~-21s ~-33s ~8s ~8s ~4s~n", [A1,A2,A3,A4,A5]). all_procs() -> case is_alive() of true -> flatmap(fun (N) -> rpc:call(N,erlang,processes,[]) end, [node()|nodes()]); false -> processes() end. pinfo(Pid) -> case is_alive() of true -> rpc:call(node(Pid), erlang, process_info, [Pid]); false -> process_info(Pid) end. fetch(Key, Info) -> case lists:keyfind(Key, 1, Info) of {_, Val} -> Val; false -> 0 end. -spec pid(X, Y, Z) -> pid() when X :: non_neg_integer(), Y :: non_neg_integer(), Z :: non_neg_integer(). pid(X, Y, Z) -> list_to_pid("<" ++ integer_to_list(X) ++ "." ++ integer_to_list(Y) ++ "." ++ integer_to_list(Z) ++ ">"). -spec i(X, Y, Z) -> [{atom(), term()}] when X :: non_neg_integer(), Y :: non_neg_integer(), Z :: non_neg_integer(). i(X, Y, Z) -> pinfo(pid(X, Y, Z)). -spec q() -> no_return(). q() -> init:stop(). -spec bt(Pid) -> 'ok' | 'undefined' when Pid :: pid(). bt(Pid) -> case catch erlang:process_display(Pid, backtrace) of {'EXIT', _} -> undefined; _ -> ok end. -spec m() -> 'ok'. m() -> mformat("Module", "File"), foreach(fun ({Mod,File}) -> mformat(Mod, File) end, sort(code:all_loaded())). mformat(A1, A2) -> format("~-20s ~s\n", [A1,A2]). %% erlangrc(Home) %% Try to run a ".erlang" file, first in the current directory %% else in home directory. erlangrc() -> case init:get_argument(home) of {ok,[[Home]]} -> erlangrc([Home]); _ -> f_p_e(["."], ".erlang") end. erlangrc([Home]) -> f_p_e([".",Home], ".erlang"). error(Fmt, Args) -> error_logger:error_msg(Fmt, Args). f_p_e(P, F) -> case file:path_eval(P, F) of {error, enoent} = Enoent -> Enoent; {error, E={Line, _Mod, _Term}} -> error("file:path_eval(~tp,~tp): error on line ~p: ~ts~n", [P, F, Line, file:format_error(E)]), ok; {error, E} -> error("file:path_eval(~tp,~tp): ~ts~n", [P, F, file:format_error(E)]), ok; Other -> Other end. bi(I) -> case erlang:system_info(I) of X when is_binary(X) -> io:put_chars(binary_to_list(X)); X when is_list(X) -> io:put_chars(X); X -> format("~w", [X]) end. %% %% Short and nice form of module info %% -spec m(Module) -> 'ok' when Module :: module(). m(M) -> L = M:module_info(), {exports,E} = lists:keyfind(exports, 1, L), Time = get_compile_time(L), COpts = get_compile_options(L), format("Module ~w compiled: ",[M]), print_time(Time), format("Compiler options: ~p~n", [COpts]), print_object_file(M), format("Exports: ~n",[]), print_exports(keysort(1, E)). print_object_file(Mod) -> case code:is_loaded(Mod) of {file,File} -> format("Object file: ~ts\n", [File]); _ -> ignore end. get_compile_time(L) -> case get_compile_info(L, time) of {ok,Val} -> Val; error -> notime end. get_compile_options(L) -> case get_compile_info(L, options) of {ok,Val} -> Val; error -> [] end. get_compile_info(L, Tag) -> case lists:keyfind(compile, 1, L) of {compile, I} -> case lists:keyfind(Tag, 1, I) of {Tag, Val} -> {ok,Val}; false -> error end; false -> error end. print_exports(X) when length(X) > 16 -> split_print_exports(X); print_exports([]) -> ok; print_exports([{F, A} |Tail]) -> format(" ~w/~w~n",[F, A]), print_exports(Tail). split_print_exports(L) -> Len = length(L), Mid = Len div 2, L1 = sublist(L, 1, Mid), L2 = sublist(L, Mid +1, Len - Mid + 1), split_print_exports(L1, L2). split_print_exports([], [{F, A}|T]) -> Str = " ", format("~-30s~w/~w~n", [Str, F, A]), split_print_exports([], T); split_print_exports([{F1, A1}|T1], [{F2, A2} | T2]) -> Str = flatten(io_lib:format("~w/~w", [F1, A1])), format("~-30s~w/~w~n", [Str, F2, A2]), split_print_exports(T1, T2); split_print_exports([], []) -> ok. print_time({Year,Month,Day,Hour,Min,_Secs}) -> format("Date: ~s ~w ~w, ", [month(Month),Day,Year]), format("Time: ~.2.0w.~.2.0w~n", [Hour,Min]); print_time(notime) -> format("No compile time info available~n",[]). month(1) -> "January"; month(2) -> "February"; month(3) -> "March"; month(4) -> "April"; month(5) -> "May"; month(6) -> "June"; month(7) -> "July"; month(8) -> "August"; month(9) -> "September"; month(10) -> "October"; month(11) -> "November"; month(12) -> "December". %% Just because we can't eval receive statements... -spec flush() -> 'ok'. flush() -> receive X -> case lists:keyfind(encoding, 1, io:getopts()) of {encoding,unicode} -> format("Shell got ~tp~n",[X]); _ -> format("Shell got ~p~n",[X]) end, flush() after 0 -> ok end. %% Print formatted info about all registered names in the system -spec nregs() -> 'ok'. nregs() -> foreach(fun (N) -> print_node_regs(N) end, all_regs()). -spec regs() -> 'ok'. regs() -> print_node_regs({node(),registered()}). all_regs() -> case is_alive() of true -> [{N,rpc:call(N, erlang, registered, [])} || N <- [node()|nodes()]]; false -> [{node(),registered()}] end. print_node_regs({N, List}) when is_list(List) -> {Pids,Ports,_Dead} = pids_and_ports(N, sort(List), [], [], []), %% print process info format("~n** Registered procs on node ~w **~n",[N]), procformat("Name", "Pid", "Initial Call", "Reds", "Msgs"), foreach(fun({Name,PI,Pid}) -> procline(Name, PI, Pid) end, Pids), %% print port info format("~n** Registered ports on node ~w **~n",[N]), portformat("Name", "Id", "Command"), foreach(fun({Name,PI,Id}) -> portline(Name, PI, Id) end, Ports). pids_and_ports(_, [], Pids, Ports, Dead) -> {reverse(Pids),reverse(Ports),reverse(Dead)}; pids_and_ports(Node, [Name|Names], Pids, Ports, Dead) -> case pwhereis(Node, Name) of Pid when is_pid(Pid) -> pids_and_ports(Node, Names, [{Name,pinfo(Pid),Pid}|Pids], Ports, Dead); Id when is_port(Id) -> pids_and_ports(Node, Names, Pids, [{Name,portinfo(Id),Id}|Ports], Dead); undefined -> pids_and_ports(Node, Names, Pids, Ports, [Name|Dead]) end. pwhereis(Node, Name) -> case is_alive() of true -> rpc:call(Node, erlang, whereis, [Name]); false -> whereis(Name) end. portinfo(Id) -> case is_alive() of true -> [ rpc:call(node(Id), erlang, port_info, [Id,name]) ]; false -> [ erlang:port_info(Id, name) ] end. procline(Name, Info, Pid) -> Call = initial_call(Info), Reds = fetch(reductions, Info), LM = length(fetch(messages, Info)), procformat(io_lib:format("~w",[Name]), io_lib:format("~w",[Pid]), io_lib:format("~s",[mfa_string(Call)]), integer_to_list(Reds), integer_to_list(LM)). procformat(Name, Pid, Call, Reds, LM) -> format("~-21s ~-12s ~-25s ~12s ~4s~n", [Name,Pid,Call,Reds,LM]). portline(Name, Info, Id) -> Cmd = fetch(name, Info), portformat(io_lib:format("~w",[Name]), erlang:port_to_list(Id), Cmd). portformat(Name, Id, Cmd) -> format("~-21s ~-15s ~-40s~n", [Name,Id,Cmd]). %% pwd() %% cd(Directory) %% These are just wrappers around the file:get/set_cwd functions. -spec pwd() -> 'ok'. pwd() -> case file:get_cwd() of {ok, Str} -> ok = io:format("~ts\n", [Str]); {error, _} -> ok = io:format("Cannot determine current directory\n") end. -spec cd(Dir) -> 'ok' when Dir :: file:name(). cd(Dir) -> _ = file:set_cwd(Dir), pwd(). %% ls() %% ls(Directory) %% The strategy is to print in fixed width files. -spec ls() -> 'ok'. ls() -> ls("."). -spec ls(Dir) -> 'ok' when Dir :: file:name(). ls(Dir) -> case file:list_dir(Dir) of {ok, Entries} -> ls_print(sort(Entries)); {error, enotdir} -> ls_print([Dir]); {error, Error} -> format("~s\n", [file:format_error(Error)]) end. ls_print([]) -> ok; ls_print(L) -> Width = min([max(lengths(L, [])), 40]) + 5, ls_print(L, Width, 0). ls_print(X, Width, Len) when Width + Len >= 80 -> io:nl(), ls_print(X, Width, 0); ls_print([H|T], Width, Len) -> io:format("~-*ts",[Width,H]), ls_print(T, Width, Len+Width); ls_print([], _, _) -> io:nl(). lengths([H|T], L) -> lengths(T, [length(H)|L]); lengths([], L) -> L. w(X) -> io_lib:write(X). %% %% memory/[0,1] %% -spec memory() -> [{Type, Size}] when Type :: atom(), Size :: non_neg_integer(). memory() -> erlang:memory(). -spec memory(Type) -> Size when Type :: atom(), Size :: non_neg_integer() ; (Types) -> [{Type, Size}] when Types :: [Type], Type :: atom(), Size :: non_neg_integer(). memory(TypeSpec) -> erlang:memory(TypeSpec). %% %% Cross Reference Check %% %%-spec xm(module() | file:filename()) -> xref:m/1 return xm(M) -> appcall(tools, xref, m, [M]). %% %% Call yecc %% %%-spec y(file:name()) -> yecc:file/2 return y(File) -> y(File, []). %%-spec y(file:name(), [yecc:option()]) -> yecc:file/2 return y(File, Opts) -> appcall(parsetools, yecc, file, [File, Opts]). %% %% Avoid creating strong components in xref and dialyzer by making calls %% from helper functions to other applications indirect. %% appcall(App, M, F, Args) -> try apply(M, F, Args) catch error:undef -> case erlang:get_stacktrace() of [{M,F,Args,_}|_] -> Arity = length(Args), io:format("Call to ~w:~w/~w in application ~w failed.\n", [M,F,Arity,App]); Stk -> erlang:raise(error, undef, Stk) end end.