%%
%% %CopyrightBegin%
%%
%% Copyright Ericsson AB 1996-2019. All Rights Reserved.
%%
%% Licensed under the Apache License, Version 2.0 (the "License");
%% you may not use this file except in compliance with the License.
%% You may obtain a copy of the License at
%%
%% http://www.apache.org/licenses/LICENSE-2.0
%%
%% Unless required by applicable law or agreed to in writing, software
%% distributed under the License is distributed on an "AS IS" BASIS,
%% WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
%% See the License for the specific language governing permissions and
%% limitations under the License.
%%
%% %CopyrightEnd%
%%
-module(io_lib_pretty).
%%% Pretty printing Erlang terms
%%%
%%% In this module "print" means the formatted printing while "write"
%%% means just writing out onto one line.
-export([print/1,print/2,print/3,print/4,print/5,print/6]).
%% To be used by io_lib only.
-export([intermediate/6, write/1]).
%%%
%%% Exported functions
%%%
%% print(Term) -> [Chars]
%% print(Term, Column, LineLength, Depth) -> [Chars]
%% Depth = -1 gives unlimited print depth. Use io_lib:write for atomic terms.
-spec print(term()) -> io_lib:chars().
print(Term) ->
print(Term, 1, 80, -1).
%% print(Term, RecDefFun) -> [Chars]
%% print(Term, Depth, RecDefFun) -> [Chars]
%% RecDefFun = fun(Tag, NoFields) -> [FieldTag] | no
%% Used by the shell for printing records and for Unicode.
-type rec_print_fun() :: fun((Tag :: atom(), NFields :: non_neg_integer()) ->
'no' | [FieldName :: atom()]).
-type column() :: integer().
-type encoding() :: epp:source_encoding() | 'unicode'.
-type line_length() :: pos_integer().
-type depth() :: integer().
-type line_max_chars() :: integer().
-type chars_limit() :: integer().
-type chars() :: io_lib:chars().
-type option() :: {'chars_limit', chars_limit()}
| {'column', column()}
| {'depth', depth()}
| {'encoding', encoding()}
| {'line_length', line_length()}
| {'line_max_chars', line_max_chars()}
| {'record_print_fun', rec_print_fun()}
| {'strings', boolean()}.
-type options() :: [option()].
-spec print(term(), rec_print_fun()) -> chars();
(term(), options()) -> chars().
print(Term, Options) when is_list(Options) ->
Col = get_option(column, Options, 1),
Ll = get_option(line_length, Options, 80),
D = get_option(depth, Options, -1),
M = get_option(line_max_chars, Options, -1),
T = get_option(chars_limit, Options, -1),
RecDefFun = get_option(record_print_fun, Options, no_fun),
Encoding = get_option(encoding, Options, epp:default_encoding()),
Strings = get_option(strings, Options, true),
print(Term, Col, Ll, D, M, T, RecDefFun, Encoding, Strings);
print(Term, RecDefFun) ->
print(Term, -1, RecDefFun).
-spec print(term(), depth(), rec_print_fun()) -> chars().
print(Term, Depth, RecDefFun) ->
print(Term, 1, 80, Depth, RecDefFun).
-spec print(term(), column(), line_length(), depth()) -> chars().
print(Term, Col, Ll, D) ->
print(Term, Col, Ll, D, _M=-1, _T=-1, no_fun, latin1, true).
-spec print(term(), column(), line_length(), depth(), rec_print_fun()) ->
chars().
print(Term, Col, Ll, D, RecDefFun) ->
print(Term, Col, Ll, D, _M=-1, RecDefFun).
-spec print(term(), column(), line_length(), depth(), line_max_chars(),
rec_print_fun()) -> chars().
print(Term, Col, Ll, D, M, RecDefFun) ->
print(Term, Col, Ll, D, M, _T=-1, RecDefFun, latin1, true).
%% D = Depth, default -1 (infinite), or LINEMAX=30 when printing from shell
%% T = chars_limit, that is, maximal number of characters, default -1
%% Used together with D to limit the output. It is possible that
%% more than T characters are returned.
%% Col = current column, default 1
%% Ll = line length/~p field width, default 80
%% M = CHAR_MAX (-1 if no max, 60 when printing from shell)
print(_, _, _, 0, _M, _T, _RF, _Enc, _Str) -> "...";
print(_, _, _, _D, _M, 0, _RF, _Enc, _Str) -> "...";
print(Term, Col, Ll, D, M, T, RecDefFun, Enc, Str) when Col =< 0 ->
%% ensure Col is at least 1
print(Term, 1, Ll, D, M, T, RecDefFun, Enc, Str);
print(Atom, _Col, _Ll, _D, _M, _T, _RF, Enc, _Str) when is_atom(Atom) ->
write_atom(Atom, Enc);
print(Term, Col, Ll, D, M0, T, RecDefFun, Enc, Str) when is_tuple(Term);
is_list(Term);
is_map(Term);
is_bitstring(Term) ->
%% preprocess and compute total number of chars
{_, Len, _Dots, _} = If =
case T < 0 of
true -> print_length(Term, D, T, RecDefFun, Enc, Str);
false -> intermediate(Term, D, T, RecDefFun, Enc, Str)
end,
%% use Len as CHAR_MAX if M0 = -1
M = max_cs(M0, Len),
if
Ll =:= 0 ->
write(If);
Len < Ll - Col, Len =< M ->
%% write the whole thing on a single line when there is room
write(If);
true ->
%% compute the indentation TInd for tagged tuples and records
TInd = while_fail([-1, 4],
fun(I) -> cind(If, Col, Ll, M, I, 0, 0) end,
1),
pp(If, Col, Ll, M, TInd, indent(Col), 0, 0)
end;
print(Term, _Col, _Ll, _D, _M, _T, _RF, _Enc, _Str) ->
%% atomic data types (bignums, atoms, ...) are never truncated
io_lib:write(Term).
%%%
%%% Local functions
%%%
%% use M only if nonnegative, otherwise use Len as default value
max_cs(M, Len) when M < 0 ->
Len;
max_cs(M, _Len) ->
M.
-define(ATM(T), is_list(element(1, T))).
-define(ATM_PAIR(Pair),
?ATM(element(2, element(1, Pair))) % Key
andalso
?ATM(element(3, element(1, Pair)))). % Value
-define(ATM_FLD(Field), ?ATM(element(4, element(1, Field)))).
pp({_S,Len,_,_} = If, Col, Ll, M, _TInd, _Ind, LD, W)
when Len < Ll - Col - LD, Len + W + LD =< M ->
write(If);
pp({{list,L}, _Len, _, _}, Col, Ll, M, TInd, Ind, LD, W) ->
[$[, pp_list(L, Col + 1, Ll, M, TInd, indent(1, Ind), LD, $|, W + 1), $]];
pp({{tuple,true,L}, _Len, _, _}, Col, Ll, M, TInd, Ind, LD, W) ->
[${, pp_tag_tuple(L, Col, Ll, M, TInd, Ind, LD, W + 1), $}];
pp({{tuple,false,L}, _Len, _, _}, Col, Ll, M, TInd, Ind, LD, W) ->
[${, pp_list(L, Col + 1, Ll, M, TInd, indent(1, Ind), LD, $,, W + 1), $}];
pp({{map,Pairs}, _Len, _, _}, Col, Ll, M, TInd, Ind, LD, W) ->
[$#, ${, pp_map(Pairs, Col + 2, Ll, M, TInd, indent(2, Ind), LD, W + 1),
$}];
pp({{record,[{Name,NLen} | L]}, _Len, _, _}, Col, Ll, M, TInd, Ind, LD, W) ->
[Name, ${, pp_record(L, NLen, Col, Ll, M, TInd, Ind, LD, W + NLen+1), $}];
pp({{bin,S}, _Len, _, _}, Col, Ll, M, _TInd, Ind, LD, W) ->
pp_binary(S, Col + 2, Ll, M, indent(2, Ind), LD, W);
pp({S,_Len,_,_}, _Col, _Ll, _M, _TInd, _Ind, _LD, _W) ->
S.
%% Print a tagged tuple by indenting the rest of the elements
%% differently to the tag. Tuple has size >= 2.
pp_tag_tuple([{Tag,Tlen,_,_} | L], Col, Ll, M, TInd, Ind, LD, W) ->
%% this uses TInd
TagInd = Tlen + 2,
Tcol = Col + TagInd,
S = $,,
if
TInd > 0, TagInd > TInd ->
Col1 = Col + TInd,
Indent = indent(TInd, Ind),
[Tag|pp_tail(L, Col1, Tcol, Ll, M, TInd, Indent, LD, S, W+Tlen)];
true ->
Indent = indent(TagInd, Ind),
[Tag, S | pp_list(L, Tcol, Ll, M, TInd, Indent, LD, S, W+Tlen+1)]
end.
pp_map([], _Col, _Ll, _M, _TInd, _Ind, _LD, _W) ->
""; % cannot happen
pp_map({dots, _, _, _}, _Col, _Ll, _M, _TInd, _Ind, _LD, _W) ->
"..."; % cannot happen
pp_map([P | Ps], Col, Ll, M, TInd, Ind, LD, W) ->
{PS, PW} = pp_pair(P, Col, Ll, M, TInd, Ind, last_depth(Ps, LD), W),
[PS | pp_pairs_tail(Ps, Col, Col + PW, Ll, M, TInd, Ind, LD, PW)].
pp_pairs_tail([], _Col0, _Col, _Ll, _M, _TInd, _Ind, _LD, _W) ->
"";
pp_pairs_tail({dots, _, _, _}, _Col0, _Col, _M, _Ll, _TInd, _Ind, _LD, _W) ->
",...";
pp_pairs_tail([{_, Len, _, _}=P | Ps], Col0, Col, Ll, M, TInd, Ind, LD, W) ->
LD1 = last_depth(Ps, LD),
ELen = 1 + Len,
if
LD1 =:= 0, ELen + 1 < Ll - Col, W + ELen + 1 =< M, ?ATM_PAIR(P);
LD1 > 0, ELen < Ll - Col - LD1, W + ELen + LD1 =< M, ?ATM_PAIR(P) ->
[$,, write_pair(P) |
pp_pairs_tail(Ps, Col0, Col+ELen, Ll, M, TInd, Ind, LD, W+ELen)];
true ->
{PS, PW} = pp_pair(P, Col0, Ll, M, TInd, Ind, LD1, 0),
[$,, $\n, Ind, PS |
pp_pairs_tail(Ps, Col0, Col0 + PW, Ll, M, TInd, Ind, LD, PW)]
end.
pp_pair({_, Len, _, _}=Pair, Col, Ll, M, _TInd, _Ind, LD, W)
when Len < Ll - Col - LD, Len + W + LD =< M ->
{write_pair(Pair), if
?ATM_PAIR(Pair) ->
Len;
true ->
Ll % force nl
end};
pp_pair({{map_pair, K, V}, _Len, _, _}, Col0, Ll, M, TInd, Ind0, LD, W) ->
I = map_value_indent(TInd),
Ind = indent(I, Ind0),
{[pp(K, Col0, Ll, M, TInd, Ind0, LD, W), " =>\n",
Ind | pp(V, Col0 + I, Ll, M, TInd, Ind, LD, 0)], Ll}. % force nl
pp_record([], _Nlen, _Col, _Ll, _M, _TInd, _Ind, _LD, _W) ->
"";
pp_record({dots, _, _, _}, _Nlen, _Col, _Ll, _M, _TInd, _Ind, _LD, _W) ->
"...";
pp_record([F | Fs], Nlen, Col0, Ll, M, TInd, Ind0, LD, W0) ->
Nind = Nlen + 1,
{Col, Ind, S, W} = rec_indent(Nind, TInd, Col0, Ind0, W0),
{FS, FW} = pp_field(F, Col, Ll, M, TInd, Ind, last_depth(Fs, LD), W),
[S, FS | pp_fields_tail(Fs, Col, Col + FW, Ll, M, TInd, Ind, LD, W + FW)].
pp_fields_tail([], _Col0, _Col, _Ll, _M, _TInd, _Ind, _LD, _W) ->
"";
pp_fields_tail({dots, _, _ ,_}, _Col0, _Col, _M, _Ll, _TInd, _Ind, _LD, _W) ->
",...";
pp_fields_tail([{_, Len, _, _}=F | Fs], Col0, Col, Ll, M, TInd, Ind, LD, W) ->
LD1 = last_depth(Fs, LD),
ELen = 1 + Len,
if
LD1 =:= 0, ELen + 1 < Ll - Col, W + ELen + 1 =< M, ?ATM_FLD(F);
LD1 > 0, ELen < Ll - Col - LD1, W + ELen + LD1 =< M, ?ATM_FLD(F) ->
[$,, write_field(F) |
pp_fields_tail(Fs, Col0, Col+ELen, Ll, M, TInd, Ind, LD, W+ELen)];
true ->
{FS, FW} = pp_field(F, Col0, Ll, M, TInd, Ind, LD1, 0),
[$,, $\n, Ind, FS |
pp_fields_tail(Fs, Col0, Col0 + FW, Ll, M, TInd, Ind, LD, FW)]
end.
pp_field({_, Len, _, _}=Fl, Col, Ll, M, _TInd, _Ind, LD, W)
when Len < Ll - Col - LD, Len + W + LD =< M ->
{write_field(Fl), if
?ATM_FLD(Fl) ->
Len;
true ->
Ll % force nl
end};
pp_field({{field, Name, NameL, F},_,_, _}, Col0, Ll, M, TInd, Ind0, LD, W0) ->
{Col, Ind, S, W} = rec_indent(NameL, TInd, Col0, Ind0, W0 + NameL),
Sep = case S of
[$\n | _] -> " =";
_ -> " = "
end,
{[Name, Sep, S | pp(F, Col, Ll, M, TInd, Ind, LD, W)], Ll}. % force nl
rec_indent(RInd, TInd, Col0, Ind0, W0) ->
%% this uses TInd
Nl = (TInd > 0) and (RInd > TInd),
DCol = case Nl of
true -> TInd;
false -> RInd
end,
Col = Col0 + DCol,
Ind = indent(DCol, Ind0),
S = case Nl of
true -> [$\n | Ind];
false -> ""
end,
W = case Nl of
true -> 0;
false -> W0
end,
{Col, Ind, S, W}.
pp_list({dots, _, _, _}, _Col0, _Ll, _M, _TInd, _Ind, _LD, _S, _W) ->
"...";
pp_list([E | Es], Col0, Ll, M, TInd, Ind, LD, S, W) ->
{ES, WE} = pp_element(E, Col0, Ll, M, TInd, Ind, last_depth(Es, LD), W),
[ES | pp_tail(Es, Col0, Col0 + WE, Ll, M, TInd, Ind, LD, S, W + WE)].
pp_tail([], _Col0, _Col, _Ll, _M, _TInd, _Ind, _LD, _S, _W) ->
[];
pp_tail([{_, Len, _, _}=E | Es], Col0, Col, Ll, M, TInd, Ind, LD, S, W) ->
LD1 = last_depth(Es, LD),
ELen = 1 + Len,
if
LD1 =:= 0, ELen + 1 < Ll - Col, W + ELen + 1 =< M, ?ATM(E);
LD1 > 0, ELen < Ll - Col - LD1, W + ELen + LD1 =< M, ?ATM(E) ->
[$,, write(E) |
pp_tail(Es, Col0, Col + ELen, Ll, M, TInd, Ind, LD, S, W+ELen)];
true ->
{ES, WE} = pp_element(E, Col0, Ll, M, TInd, Ind, LD1, 0),
[$,, $\n, Ind, ES |
pp_tail(Es, Col0, Col0 + WE, Ll, M, TInd, Ind, LD, S, WE)]
end;
pp_tail({dots, _, _, _}, _Col0, _Col, _Ll, _M, _TInd, _Ind, _LD, S, _W) ->
[S | "..."];
pp_tail({_, Len, _, _}=E, _Col0, Col, Ll, M, _TInd, _Ind, LD, S, W)
when Len + 1 < Ll - Col - (LD + 1),
Len + 1 + W + (LD + 1) =< M,
?ATM(E) ->
[S | write(E)];
pp_tail(E, Col0, _Col, Ll, M, TInd, Ind, LD, S, _W) ->
[S, $\n, Ind | pp(E, Col0, Ll, M, TInd, Ind, LD + 1, 0)].
pp_element({_, Len, _, _}=E, Col, Ll, M, _TInd, _Ind, LD, W)
when Len < Ll - Col - LD, Len + W + LD =< M, ?ATM(E) ->
{write(E), Len};
pp_element(E, Col, Ll, M, TInd, Ind, LD, W) ->
{pp(E, Col, Ll, M, TInd, Ind, LD, W), Ll}. % force nl
%% Reuse the list created by io_lib:write_binary()...
pp_binary([LT,LT,S,GT,GT], Col, Ll, M, Ind, LD, W) ->
N = erlang:max(8, erlang:min(Ll - Col, M - 4 - W) - LD),
[LT,LT,pp_binary(S, N, N, Ind),GT,GT].
pp_binary([BS, $, | S], N, N0, Ind) ->
Len = length(BS) + 1,
case N - Len of
N1 when N1 < 0 ->
[$\n, Ind, BS, $, | pp_binary(S, N0 - Len, N0, Ind)];
N1 ->
[BS, $, | pp_binary(S, N1, N0, Ind)]
end;
pp_binary([BS1, $:, BS2]=S, N, _N0, Ind)
when length(BS1) + length(BS2) + 1 > N ->
[$\n, Ind, S];
pp_binary(S, N, _N0, Ind) ->
case iolist_size(S) > N of
true ->
[$\n, Ind, S];
false ->
S
end.
%% write the whole thing on a single line
write({{tuple, _IsTagged, L}, _, _, _}) ->
[${, write_list(L, $,), $}];
write({{list, L}, _, _, _}) ->
[$[, write_list(L, $|), $]];
write({{map, Pairs}, _, _, _}) ->
[$#,${, write_list(Pairs, $,), $}];
write({{map_pair, _K, _V}, _, _, _}=Pair) ->
write_pair(Pair);
write({{record, [{Name,_} | L]}, _, _, _}) ->
[Name, ${, write_fields(L), $}];
write({{bin, S}, _, _, _}) ->
S;
write({S, _, _, _}) ->
S.
write_pair({{map_pair, K, V}, _, _, _}) ->
[write(K), " => ", write(V)].
write_fields([]) ->
"";
write_fields({dots, _, _, _}) ->
"...";
write_fields([F | Fs]) ->
[write_field(F) | write_fields_tail(Fs)].
write_fields_tail([]) ->
"";
write_fields_tail({dots, _, _, _}) ->
",...";
write_fields_tail([F | Fs]) ->
[$,, write_field(F) | write_fields_tail(Fs)].
write_field({{field, Name, _NameL, F}, _, _, _}) ->
[Name, " = " | write(F)].
write_list({dots, _, _, _}, _S) ->
"...";
write_list([E | Es], S) ->
[write(E) | write_tail(Es, S)].
write_tail([], _S) ->
[];
write_tail([E | Es], S) ->
[$,, write(E) | write_tail(Es, S)];
write_tail({dots, _, _, _}, S) ->
[S | "..."];
write_tail(E, S) ->
[S | write(E)].
-type more() :: fun((chars_limit(), DeltaDepth :: non_neg_integer()) ->
intermediate_format()).
-type if_list() :: maybe_improper_list(intermediate_format(),
{'dots', non_neg_integer(),
non_neg_integer(), more()}).
-type intermediate_format() ::
{chars()
| {'bin', chars()}
| 'dots'
| {'field', Name :: chars(), NameLen :: non_neg_integer(),
intermediate_format()}
| {'list', if_list()}
| {'map', if_list()}
| {'map_pair', K :: intermediate_format(),
V :: intermediate_format()}
| {'record', [{Name :: chars(), NameLen :: non_neg_integer()}
| if_list()]}
| {'tuple', IsTagged :: boolean(), if_list()},
Len :: non_neg_integer(),
NumOfDots :: non_neg_integer(),
More :: more() | 'no_more'
}.
-spec intermediate(term(), depth(), pos_integer(), rec_print_fun(),
encoding(), boolean()) -> intermediate_format().
intermediate(Term, D, T, RF, Enc, Str) when T > 0 ->
D0 = 1,
If = print_length(Term, D0, T, RF, Enc, Str),
case If of
{_, Len, Dots, _} when Dots =:= 0; Len > T; D =:= 1 ->
If;
_ ->
find_upper(If, Term, T, D0, 2, D, RF, Enc, Str)
end.
find_upper(Lower, Term, T, Dl, Dd, D, RF, Enc, Str) ->
Dd2 = Dd * 2,
D1 = case D < 0 of
true -> Dl + Dd2;
false -> min(Dl + Dd2, D)
end,
If = expand(Lower, T, D1 - Dl),
case If of
{_, _, _Dots=0, _} -> % even if Len > T
If;
{_, _Len=T, _, _} -> % increasing the depth is meaningless
If;
{_, Len, _, _} when Len < T, D1 < D orelse D < 0 ->
find_upper(If, Term, T, D1, Dd2, D, RF, Enc, Str);
_ ->
search_depth(Lower, If, Term, T, Dl, D1, RF, Enc, Str)
end.
%% Lower has NumOfDots > 0 and Len =< T.
%% Upper has NumOfDots > 0 and Len > T.
search_depth(Lower, Upper, _Term, T, Dl, Du, _RF, _Enc, _Str)
when Du - Dl =:= 1 ->
%% The returned intermediate format has Len >= T.
case Lower of
{_, T, _, _} ->
Lower;
_ ->
Upper
end;
search_depth(Lower, Upper, Term, T, Dl, Du, RF, Enc, Str) ->
D1 = (Dl + Du) div 2,
If = expand(Lower, T, D1 - Dl),
case If of
{_, Len, _, _} when Len > T ->
%% Len can be greater than Upper's length.
%% This is a bit expensive since the work to
%% crate Upper is wasted. It is the price
%% to pay to get a more balanced output.
search_depth(Lower, If, Term, T, Dl, D1, RF, Enc, Str);
_ ->
search_depth(If, Upper, Term, T, D1, Du, RF, Enc, Str)
end.
%% The depth (D) is used for extracting and counting the characters to
%% print. The structure is kept so that the returned intermediate
%% format can be formatted. The separators (list, tuple, record, map) are
%% counted but need to be added later.
%% D =/= 0
print_length([], _D, _T, _RF, _Enc, _Str) ->
{"[]", 2, 0, no_more};
print_length({}, _D, _T, _RF, _Enc, _Str) ->
{"{}", 2, 0, no_more};
print_length(#{}=M, _D, _T, _RF, _Enc, _Str) when map_size(M) =:= 0 ->
{"#{}", 3, 0, no_more};
print_length(Atom, _D, _T, _RF, Enc, _Str) when is_atom(Atom) ->
S = write_atom(Atom, Enc),
{S, io_lib:chars_length(S), 0, no_more};
print_length(List, D, T, RF, Enc, Str) when is_list(List) ->
%% only flat lists are "printable"
case Str andalso printable_list(List, D, T, Enc) of
true ->
%% print as string, escaping double-quotes in the list
S = write_string(List, Enc),
{S, io_lib:chars_length(S), 0, no_more};
{true, Prefix} ->
%% Truncated lists when T < 0 could break some existing code.
S = write_string(Prefix, Enc),
%% NumOfDots = 0 to avoid looping--increasing the depth
%% does not make Prefix longer.
{[S | "..."], 3 + io_lib:chars_length(S), 0, no_more};
false ->
case print_length_list(List, D, T, RF, Enc, Str) of
{What, Len, Dots, _More} when Dots > 0 ->
More = fun(T1, Dd) ->
?FUNCTION_NAME(List, D+Dd, T1, RF, Enc, Str)
end,
{What, Len, Dots, More};
If ->
If
end
end;
print_length(Fun, _D, _T, _RF, _Enc, _Str) when is_function(Fun) ->
S = io_lib:write(Fun),
{S, iolist_size(S), 0, no_more};
print_length(R, D, T, RF, Enc, Str) when is_atom(element(1, R)),
is_function(RF) ->
case RF(element(1, R), tuple_size(R) - 1) of
no ->
print_length_tuple(R, D, T, RF, Enc, Str);
RDefs ->
print_length_record(R, D, T, RF, RDefs, Enc, Str)
end;
print_length(Tuple, D, T, RF, Enc, Str) when is_tuple(Tuple) ->
print_length_tuple(Tuple, D, T, RF, Enc, Str);
print_length(Map, D, T, RF, Enc, Str) when is_map(Map) ->
print_length_map(Map, D, T, RF, Enc, Str);
print_length(<<>>, _D, _T, _RF, _Enc, _Str) ->
{"<<>>", 4, 0, no_more};
print_length(<<_/bitstring>> = Bin, 1, _T, RF, Enc, Str) ->
More = fun(T1, Dd) -> ?FUNCTION_NAME(Bin, 1+Dd, T1, RF, Enc, Str) end,
{"<<...>>", 7, 3, More};
print_length(<<_/bitstring>> = Bin, D, T, RF, Enc, Str) ->
D1 = D - 1,
case
Str andalso
(bit_size(Bin) rem 8) =:= 0 andalso
printable_bin0(Bin, D1, tsub(T, 6), Enc)
of
{true, List} when is_list(List) ->
S = io_lib:write_string(List, $"), %"
{[$<,$<,S,$>,$>], 4 + length(S), 0, no_more};
{false, List} when is_list(List) ->
S = io_lib:write_string(List, $"), %"
{[$<,$<,S,"/utf8>>"], 9 + io_lib:chars_length(S), 0, no_more};
{true, true, Prefix} ->
S = io_lib:write_string(Prefix, $"), %"
More = fun(T1, Dd) ->
?FUNCTION_NAME(Bin, D+Dd, T1, RF, Enc, Str)
end,
{[$<,$<,S|"...>>"], 7 + length(S), 3, More};
{false, true, Prefix} ->
S = io_lib:write_string(Prefix, $"), %"
More = fun(T1, Dd) ->
?FUNCTION_NAME(Bin, D+Dd, T1, RF, Enc, Str)
end,
{[$<,$<,S|"/utf8...>>"], 12 + io_lib:chars_length(S), 3, More};
false ->
case io_lib:write_binary(Bin, D, T) of
{S, <<>>} ->
{{bin, S}, iolist_size(S), 0, no_more};
{S, _Rest} ->
More = fun(T1, Dd) ->
?FUNCTION_NAME(Bin, D+Dd, T1, RF, Enc, Str)
end,
{{bin, S}, iolist_size(S), 3, More}
end
end;
print_length(Term, _D, _T, _RF, _Enc, _Str) ->
S = io_lib:write(Term),
%% S can contain unicode, so iolist_size(S) cannot be used here
{S, io_lib:chars_length(S), 0, no_more}.
print_length_map(Map, 1, _T, RF, Enc, Str) ->
More = fun(T1, Dd) -> ?FUNCTION_NAME(Map, 1+Dd, T1, RF, Enc, Str) end,
{"#{...}", 6, 3, More};
print_length_map(Map, D, T, RF, Enc, Str) when is_map(Map) ->
Next = maps:next(maps:iterator(Map)),
PairsS = print_length_map_pairs(Next, D, D - 1, tsub(T, 3), RF, Enc, Str),
{Len, Dots} = list_length(PairsS, 3, 0),
{{map, PairsS}, Len, Dots, no_more}.
print_length_map_pairs(none, _D, _D0, _T, _RF, _Enc, _Str) ->
[];
print_length_map_pairs(Term, D, D0, T, RF, Enc, Str) when D =:= 1; T =:= 0->
More = fun(T1, Dd) ->
?FUNCTION_NAME(Term, D+Dd, D0, T1, RF, Enc, Str)
end,
{dots, 3, 3, More};
print_length_map_pairs({K, V, Iter}, D, D0, T, RF, Enc, Str) ->
Pair1 = print_length_map_pair(K, V, D0, tsub(T, 1), RF, Enc, Str),
{_, Len1, _, _} = Pair1,
Next = maps:next(Iter),
[Pair1 |
print_length_map_pairs(Next, D - 1, D0, tsub(T, Len1+1), RF, Enc, Str)].
print_length_map_pair(K, V, D, T, RF, Enc, Str) ->
{_, KL, KD, _} = P1 = print_length(K, D, T, RF, Enc, Str),
KL1 = KL + 4,
{_, VL, VD, _} = P2 = print_length(V, D, tsub(T, KL1), RF, Enc, Str),
{{map_pair, P1, P2}, KL1 + VL, KD + VD, no_more}.
print_length_tuple(Tuple, 1, _T, RF, Enc, Str) ->
More = fun(T1, Dd) -> ?FUNCTION_NAME(Tuple, 1+Dd, T1, RF, Enc, Str) end,
{"{...}", 5, 3, More};
print_length_tuple(Tuple, D, T, RF, Enc, Str) ->
L = print_length_tuple1(Tuple, 1, D, tsub(T, 2), RF, Enc, Str),
IsTagged = is_atom(element(1, Tuple)) and (tuple_size(Tuple) > 1),
{Len, Dots} = list_length(L, 2, 0),
{{tuple,IsTagged,L}, Len, Dots, no_more}.
print_length_tuple1(Tuple, I, _D, _T, _RF, _Enc, _Str)
when I > tuple_size(Tuple) ->
[];
print_length_tuple1(Tuple, I, D, T, RF, Enc, Str) when D =:= 1; T =:= 0->
More = fun(T1, Dd) -> ?FUNCTION_NAME(Tuple, I, D+Dd, T1, RF, Enc, Str) end,
{dots, 3, 3, More};
print_length_tuple1(Tuple, I, D, T, RF, Enc, Str) ->
E = element(I, Tuple),
T1 = tsub(T, 1),
{_, Len1, _, _} = Elem1 = print_length(E, D - 1, T1, RF, Enc, Str),
T2 = tsub(T1, Len1),
[Elem1 | print_length_tuple1(Tuple, I + 1, D - 1, T2, RF, Enc, Str)].
print_length_record(Tuple, 1, _T, RF, RDefs, Enc, Str) ->
More = fun(T1, Dd) ->
?FUNCTION_NAME(Tuple, 1+Dd, T1, RF, RDefs, Enc, Str)
end,
{"{...}", 5, 3, More};
print_length_record(Tuple, D, T, RF, RDefs, Enc, Str) ->
Name = [$# | write_atom(element(1, Tuple), Enc)],
NameL = io_lib:chars_length(Name),
T1 = tsub(T, NameL+2),
L = print_length_fields(RDefs, D - 1, T1, Tuple, 2, RF, Enc, Str),
{Len, Dots} = list_length(L, NameL + 2, 0),
{{record, [{Name,NameL} | L]}, Len, Dots, no_more}.
print_length_fields([], _D, _T, Tuple, I, _RF, _Enc, _Str)
when I > tuple_size(Tuple) ->
[];
print_length_fields(Term, D, T, Tuple, I, RF, Enc, Str)
when D =:= 1; T =:= 0 ->
More = fun(T1, Dd) ->
?FUNCTION_NAME(Term, D+Dd, T1, Tuple, I, RF, Enc, Str)
end,
{dots, 3, 3, More};
print_length_fields([Def | Defs], D, T, Tuple, I, RF, Enc, Str) ->
E = element(I, Tuple),
T1 = tsub(T, 1),
Field1 = print_length_field(Def, D - 1, T1, E, RF, Enc, Str),
{_, Len1, _, _} = Field1,
T2 = tsub(T1, Len1),
[Field1 |
print_length_fields(Defs, D - 1, T2, Tuple, I + 1, RF, Enc, Str)].
print_length_field(Def, D, T, E, RF, Enc, Str) ->
Name = write_atom(Def, Enc),
NameL = io_lib:chars_length(Name) + 3,
{_, Len, Dots, _} =
Field = print_length(E, D, tsub(T, NameL), RF, Enc, Str),
{{field, Name, NameL, Field}, NameL + Len, Dots, no_more}.
print_length_list(List, D, T, RF, Enc, Str) ->
L = print_length_list1(List, D, tsub(T, 2), RF, Enc, Str),
{Len, Dots} = list_length(L, 2, 0),
{{list, L}, Len, Dots, no_more}.
print_length_list1([], _D, _T, _RF, _Enc, _Str) ->
[];
print_length_list1(Term, D, T, RF, Enc, Str) when D =:= 1; T =:= 0->
More = fun(T1, Dd) -> ?FUNCTION_NAME(Term, D+Dd, T1, RF, Enc, Str) end,
{dots, 3, 3, More};
print_length_list1([E | Es], D, T, RF, Enc, Str) ->
{_, Len1, _, _} = Elem1 = print_length(E, D - 1, tsub(T, 1), RF, Enc, Str),
[Elem1 | print_length_list1(Es, D - 1, tsub(T, Len1 + 1), RF, Enc, Str)];
print_length_list1(E, D, T, RF, Enc, Str) ->
print_length(E, D - 1, T, RF, Enc, Str).
list_length([], Acc, DotsAcc) ->
{Acc, DotsAcc};
list_length([{_, Len, Dots, _} | Es], Acc, DotsAcc) ->
list_length_tail(Es, Acc + Len, DotsAcc + Dots);
list_length({_, Len, Dots, _}, Acc, DotsAcc) ->
{Acc + Len, DotsAcc + Dots}.
list_length_tail([], Acc, DotsAcc) ->
{Acc, DotsAcc};
list_length_tail([{_, Len, Dots, _} | Es], Acc, DotsAcc) ->
list_length_tail(Es, Acc + 1 + Len, DotsAcc + Dots);
list_length_tail({_, Len, Dots, _}, Acc, DotsAcc) ->
{Acc + 1 + Len, DotsAcc + Dots}.
%% ?CHARS printable characters has depth 1.
-define(CHARS, 4).
%% only flat lists are "printable"
printable_list(_L, 1, _T, _Enc) ->
false;
printable_list(L, _D, T, latin1) when T < 0 ->
io_lib:printable_latin1_list(L);
printable_list(L, _D, T, latin1) when T >= 0 ->
N = tsub(T, 2),
case printable_latin1_list(L, N) of
all ->
true;
0 ->
{L1, _} = lists:split(N, L),
{true, L1};
_NC ->
false
end;
printable_list(L, _D, T, _Unicode) when T >= 0 ->
N = tsub(T, 2),
%% Be careful not to traverse more of L than necessary.
try string:slice(L, 0, N) of
"" ->
false;
Prefix ->
case is_flat(L, lists:flatlength(Prefix)) of
true ->
case string:equal(Prefix, L) of
true ->
io_lib:printable_list(L);
false ->
io_lib:printable_list(Prefix)
andalso {true, Prefix}
end;
false ->
false
end
catch _:_ -> false
end;
printable_list(L, _D, T, _Uni) when T < 0->
io_lib:printable_list(L).
is_flat(_L, 0) ->
true;
is_flat([C|Cs], N) when is_integer(C) ->
is_flat(Cs, N - 1);
is_flat(_, _N) ->
false.
printable_bin0(Bin, D, T, Enc) ->
Len = case D >= 0 of
true ->
%% Use byte_size() also if Enc =/= latin1.
DChars = erlang:min(?CHARS * D, byte_size(Bin)),
case T >= 0 of
true ->
erlang:min(T, DChars);
false ->
DChars
end;
false when T < 0 ->
byte_size(Bin);
false when T >= 0 -> % cannot happen
T
end,
printable_bin(Bin, Len, D, Enc).
printable_bin(_Bin, 0, _D, _Enc) ->
false;
printable_bin(Bin, Len, D, latin1) ->
N = erlang:min(20, Len),
L = binary_to_list(Bin, 1, N),
case printable_latin1_list(L, N) of
all when N =:= byte_size(Bin) ->
{true, L};
all when N =:= Len -> % N < byte_size(Bin)
{true, true, L};
all ->
case printable_bin1(Bin, 1 + N, Len - N) of
0 when byte_size(Bin) =:= Len ->
{true, binary_to_list(Bin)};
NC when D > 0, Len - NC >= D ->
{true, true, binary_to_list(Bin, 1, Len - NC)};
NC when is_integer(NC) ->
false
end;
NC when is_integer(NC), D > 0, N - NC >= D ->
{true, true, binary_to_list(Bin, 1, N - NC)};
NC when is_integer(NC) ->
false
end;
printable_bin(Bin, Len, D, _Uni) ->
case valid_utf8(Bin,Len) of
true ->
case printable_unicode(Bin, Len, [], io:printable_range()) of
{_, <<>>, L} ->
{byte_size(Bin) =:= length(L), L};
{NC, Bin1, L} when D > 0, Len - NC >= D ->
{byte_size(Bin)-byte_size(Bin1) =:= length(L), true, L};
{_NC, _Bin, _L} ->
false
end;
false ->
printable_bin(Bin, Len, D, latin1)
end.
printable_bin1(_Bin, _Start, 0) ->
0;
printable_bin1(Bin, Start, Len) ->
N = erlang:min(10000, Len),
L = binary_to_list(Bin, Start, Start + N - 1),
case printable_latin1_list(L, N) of
all ->
printable_bin1(Bin, Start + N, Len - N);
NC when is_integer(NC) ->
Len - (N - NC)
end.
%% -> all | integer() >=0. Adopted from io_lib.erl.
printable_latin1_list([_ | _], 0) -> 0;
printable_latin1_list([C | Cs], N) when C >= $\s, C =< $~ ->
printable_latin1_list(Cs, N - 1);
printable_latin1_list([C | Cs], N) when C >= $\240, C =< $\377 ->
printable_latin1_list(Cs, N - 1);
printable_latin1_list([$\n | Cs], N) -> printable_latin1_list(Cs, N - 1);
printable_latin1_list([$\r | Cs], N) -> printable_latin1_list(Cs, N - 1);
printable_latin1_list([$\t | Cs], N) -> printable_latin1_list(Cs, N - 1);
printable_latin1_list([$\v | Cs], N) -> printable_latin1_list(Cs, N - 1);
printable_latin1_list([$\b | Cs], N) -> printable_latin1_list(Cs, N - 1);
printable_latin1_list([$\f | Cs], N) -> printable_latin1_list(Cs, N - 1);
printable_latin1_list([$\e | Cs], N) -> printable_latin1_list(Cs, N - 1);
printable_latin1_list([], _) -> all;
printable_latin1_list(_, N) -> N.
valid_utf8(<<>>,_) ->
true;
valid_utf8(_,0) ->
true;
valid_utf8(<<_/utf8, R/binary>>,N) ->
valid_utf8(R,N-1);
valid_utf8(_,_) ->
false.
printable_unicode(<<C/utf8, R/binary>>=Bin, I, L, Range) when I > 0 ->
case printable_char(C,Range) of
true ->
printable_unicode(R, I - 1, [C | L],Range);
false ->
{I, Bin, lists:reverse(L)}
end;
printable_unicode(Bin, I, L,_) ->
{I, Bin, lists:reverse(L)}.
printable_char($\n,_) -> true;
printable_char($\r,_) -> true;
printable_char($\t,_) -> true;
printable_char($\v,_) -> true;
printable_char($\b,_) -> true;
printable_char($\f,_) -> true;
printable_char($\e,_) -> true;
printable_char(C,latin1) ->
C >= $\s andalso C =< $~ orelse
C >= 16#A0 andalso C =< 16#FF;
printable_char(C,unicode) ->
C >= $\s andalso C =< $~ orelse
C >= 16#A0 andalso C < 16#D800 orelse
C > 16#DFFF andalso C < 16#FFFE orelse
C > 16#FFFF andalso C =< 16#10FFFF.
write_atom(A, latin1) ->
io_lib:write_atom_as_latin1(A);
write_atom(A, _Uni) ->
io_lib:write_atom(A).
write_string(S, latin1) ->
io_lib:write_latin1_string(S, $"); %"
write_string(S, _Uni) ->
io_lib:write_string(S, $"). %"
expand({_, _, _Dots=0, no_more} = If, _T, _Dd) -> If;
%% expand({{list,L}, _Len, _, no_more}, T, Dd) ->
%% {NL, NLen, NDots} = expand_list(L, T, Dd, 2),
%% {{list,NL}, NLen, NDots, no_more};
expand({{tuple,IsTagged,L}, _Len, _, no_more}, T, Dd) ->
{NL, NLen, NDots} = expand_list(L, T, Dd, 2),
{{tuple,IsTagged,NL}, NLen, NDots, no_more};
expand({{map, Pairs}, _Len, _, no_more}, T, Dd) ->
{NPairs, NLen, NDots} = expand_list(Pairs, T, Dd, 3),
{{map, NPairs}, NLen, NDots, no_more};
expand({{map_pair, K, V}, _Len, _, no_more}, T, Dd) ->
{_, KL, KD, _} = P1 = expand(K, tsub(T, 1), Dd),
KL1 = KL + 4,
{_, VL, VD, _} = P2 = expand(V, tsub(T, KL1), Dd),
{{map_pair, P1, P2}, KL1 + VL, KD + VD, no_more};
expand({{record, [{Name,NameL} | L]}, _Len, _, no_more}, T, Dd) ->
{NL, NLen, NDots} = expand_list(L, T, Dd, NameL + 2),
{{record, [{Name,NameL} | NL]}, NLen, NDots, no_more};
expand({{field, Name, NameL, Field}, _Len, _, no_more}, T, Dd) ->
F = {_S, L, Dots, _} = expand(Field, tsub(T, NameL), Dd),
{{field, Name, NameL, F}, NameL + L, Dots, no_more};
expand({_, _, _, More}, T, Dd) ->
More(T, Dd).
expand_list(Ifs, T, Dd, L0) ->
L = expand_list(Ifs, tsub(T, L0), Dd),
{Len, Dots} = list_length(L, L0, 0),
{L, Len, Dots}.
expand_list([], _T, _Dd) ->
[];
expand_list([If | Ifs], T, Dd) ->
{_, Len1, _, _} = Elem1 = expand(If, tsub(T, 1), Dd),
[Elem1 | expand_list(Ifs, tsub(T, Len1 + 1), Dd)];
expand_list({_, _, _, More}, T, Dd) ->
More(T, Dd).
%% Make sure T does not change sign.
tsub(T, _) when T < 0 -> T;
tsub(T, E) when T >= E -> T - E;
tsub(_, _) -> 0.
%% Throw 'no_good' if the indentation exceeds half the line length
%% unless there is room for M characters on the line.
cind({_S, Len, _, _}, Col, Ll, M, Ind, LD, W) when Len < Ll - Col - LD,
Len + W + LD =< M ->
Ind;
cind({{list,L}, _Len, _, _}, Col, Ll, M, Ind, LD, W) ->
cind_list(L, Col + 1, Ll, M, Ind, LD, W + 1);
cind({{tuple,true,L}, _Len, _ ,_}, Col, Ll, M, Ind, LD, W) ->
cind_tag_tuple(L, Col, Ll, M, Ind, LD, W + 1);
cind({{tuple,false,L}, _Len, _, _}, Col, Ll, M, Ind, LD, W) ->
cind_list(L, Col + 1, Ll, M, Ind, LD, W + 1);
cind({{map,Pairs}, _Len, _, _}, Col, Ll, M, Ind, LD, W) ->
cind_map(Pairs, Col + 2, Ll, M, Ind, LD, W + 2);
cind({{record,[{_Name,NLen} | L]}, _Len, _, _}, Col, Ll, M, Ind, LD, W) ->
cind_record(L, NLen, Col, Ll, M, Ind, LD, W + NLen + 1);
cind({{bin,_S}, _Len, _, _}, _Col, _Ll, _M, Ind, _LD, _W) ->
Ind;
cind({_S,_Len,_,_}, _Col, _Ll, _M, Ind, _LD, _W) ->
Ind.
cind_tag_tuple([{_Tag,Tlen,_,_} | L], Col, Ll, M, Ind, LD, W) ->
TagInd = Tlen + 2,
Tcol = Col + TagInd,
if
Ind > 0, TagInd > Ind ->
Col1 = Col + Ind,
if
M + Col1 =< Ll; Col1 =< Ll div 2 ->
cind_tail(L, Col1, Tcol, Ll, M, Ind, LD, W + Tlen);
true ->
throw(no_good)
end;
M + Tcol < Ll; Tcol < Ll div 2 ->
cind_list(L, Tcol, Ll, M, Ind, LD, W + Tlen + 1);
true ->
throw(no_good)
end.
cind_map([P | Ps], Col, Ll, M, Ind, LD, W) ->
PW = cind_pair(P, Col, Ll, M, Ind, last_depth(Ps, LD), W),
cind_pairs_tail(Ps, Col, Col + PW, Ll, M, Ind, LD, W + PW);
cind_map(_, _Col, _Ll, _M, Ind, _LD, _W) ->
Ind. % cannot happen
cind_pairs_tail([{_, Len, _, _} = P | Ps], Col0, Col, Ll, M, Ind, LD, W) ->
LD1 = last_depth(Ps, LD),
ELen = 1 + Len,
if
LD1 =:= 0, ELen + 1 < Ll - Col, W + ELen + 1 =< M, ?ATM_PAIR(P);
LD1 > 0, ELen < Ll - Col - LD1, W + ELen + LD1 =< M, ?ATM_PAIR(P) ->
cind_pairs_tail(Ps, Col0, Col + ELen, Ll, M, Ind, LD, W + ELen);
true ->
PW = cind_pair(P, Col0, Ll, M, Ind, LD1, 0),
cind_pairs_tail(Ps, Col0, Col0 + PW, Ll, M, Ind, LD, PW)
end;
cind_pairs_tail(_, _Col0, _Col, _Ll, _M, Ind, _LD, _W) ->
Ind.
cind_pair({{map_pair, _Key, _Value}, Len, _, _}=Pair, Col, Ll, M, _Ind, LD, W)
when Len < Ll - Col - LD, Len + W + LD =< M ->
if
?ATM_PAIR(Pair) ->
Len;
true ->
Ll
end;
cind_pair({{map_pair, K, V}, _Len, _, _}, Col0, Ll, M, Ind, LD, W0) ->
cind(K, Col0, Ll, M, Ind, LD, W0),
I = map_value_indent(Ind),
cind(V, Col0 + I, Ll, M, Ind, LD, 0),
Ll.
map_value_indent(TInd) ->
case TInd > 0 of
true ->
TInd;
false ->
4
end.
cind_record([F | Fs], Nlen, Col0, Ll, M, Ind, LD, W0) ->
Nind = Nlen + 1,
{Col, W} = cind_rec(Nind, Col0, Ll, M, Ind, W0),
FW = cind_field(F, Col, Ll, M, Ind, last_depth(Fs, LD), W),
cind_fields_tail(Fs, Col, Col + FW, Ll, M, Ind, LD, W + FW);
cind_record(_, _Nlen, _Col, _Ll, _M, Ind, _LD, _W) ->
Ind.
cind_fields_tail([{_, Len, _, _} = F | Fs], Col0, Col, Ll, M, Ind, LD, W) ->
LD1 = last_depth(Fs, LD),
ELen = 1 + Len,
if
LD1 =:= 0, ELen + 1 < Ll - Col, W + ELen + 1 =< M, ?ATM_FLD(F);
LD1 > 0, ELen < Ll - Col - LD1, W + ELen + LD1 =< M, ?ATM_FLD(F) ->
cind_fields_tail(Fs, Col0, Col + ELen, Ll, M, Ind, LD, W + ELen);
true ->
FW = cind_field(F, Col0, Ll, M, Ind, LD1, 0),
cind_fields_tail(Fs, Col0, Col + FW, Ll, M, Ind, LD, FW)
end;
cind_fields_tail(_, _Col0, _Col, _Ll, _M, Ind, _LD, _W) ->
Ind.
cind_field({{field, _N, _NL, _F}, Len, _, _}=Fl, Col, Ll, M, _Ind, LD, W)
when Len < Ll - Col - LD, Len + W + LD =< M ->
if
?ATM_FLD(Fl) ->
Len;
true ->
Ll
end;
cind_field({{field, _Name, NameL, F},_Len,_,_}, Col0, Ll, M, Ind, LD, W0) ->
{Col, W} = cind_rec(NameL, Col0, Ll, M, Ind, W0 + NameL),
cind(F, Col, Ll, M, Ind, LD, W),
Ll.
cind_rec(RInd, Col0, Ll, M, Ind, W0) ->
Nl = (Ind > 0) and (RInd > Ind),
DCol = case Nl of
true -> Ind;
false -> RInd
end,
Col = Col0 + DCol,
if
M + Col =< Ll; Col =< Ll div 2 ->
W = case Nl of
true -> 0;
false -> W0
end,
{Col, W};
true ->
throw(no_good)
end.
cind_list({dots, _, _, _}, _Col0, _Ll, _M, Ind, _LD, _W) ->
Ind;
cind_list([E | Es], Col0, Ll, M, Ind, LD, W) ->
WE = cind_element(E, Col0, Ll, M, Ind, last_depth(Es, LD), W),
cind_tail(Es, Col0, Col0 + WE, Ll, M, Ind, LD, W + WE).
cind_tail([], _Col0, _Col, _Ll, _M, Ind, _LD, _W) ->
Ind;
cind_tail([{_, Len, _, _} = E | Es], Col0, Col, Ll, M, Ind, LD, W) ->
LD1 = last_depth(Es, LD),
ELen = 1 + Len,
if
LD1 =:= 0, ELen + 1 < Ll - Col, W + ELen + 1 =< M, ?ATM(E);
LD1 > 0, ELen < Ll - Col - LD1, W + ELen + LD1 =< M, ?ATM(E) ->
cind_tail(Es, Col0, Col + ELen, Ll, M, Ind, LD, W + ELen);
true ->
WE = cind_element(E, Col0, Ll, M, Ind, LD1, 0),
cind_tail(Es, Col0, Col0 + WE, Ll, M, Ind, LD, WE)
end;
cind_tail({dots, _, _, _}, _Col0, _Col, _Ll, _M, Ind, _LD, _W) ->
Ind;
cind_tail({_, Len, _, _}=E, _Col0, Col, Ll, M, Ind, LD, W)
when Len + 1 < Ll - Col - (LD + 1),
Len + 1 + W + (LD + 1) =< M,
?ATM(E) ->
Ind;
cind_tail(E, _Col0, Col, Ll, M, Ind, LD, _W) ->
cind(E, Col, Ll, M, Ind, LD + 1, 0).
cind_element({_, Len, _, _}=E, Col, Ll, M, _Ind, LD, W)
when Len < Ll - Col - LD, Len + W + LD =< M, ?ATM(E) ->
Len;
cind_element(E, Col, Ll, M, Ind, LD, W) ->
cind(E, Col, Ll, M, Ind, LD, W),
Ll.
last_depth([_ | _], _LD) ->
0;
last_depth(_, LD) ->
LD + 1.
while_fail([], _F, V) ->
V;
while_fail([A | As], F, V) ->
try F(A) catch _ -> while_fail(As, F, V) end.
%% make a string of N spaces
indent(N) when is_integer(N), N > 0 ->
chars($\s, N-1).
%% prepend N spaces onto Ind
indent(1, Ind) -> % Optimization of common case
[$\s | Ind];
indent(4, Ind) -> % Optimization of common case
S2 = [$\s, $\s],
[S2, S2 | Ind];
indent(N, Ind) when is_integer(N), N > 0 ->
[chars($\s, N) | Ind].
%% A deep version of string:chars/2
chars(_C, 0) ->
[];
chars(C, 2) ->
[C, C];
chars(C, 3) ->
[C, C, C];
chars(C, N) when (N band 1) =:= 0 ->
S = chars(C, N bsr 1),
[S | S];
chars(C, N) ->
S = chars(C, N bsr 1),
[C, S | S].
get_option(Key, TupleList, Default) ->
case lists:keyfind(Key, 1, TupleList) of
false -> Default;
{Key, Value} -> Value;
_ -> Default
end.