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jsx/include/jsx_scanner.hrl

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massive simplification of api, operation and internals. removes all demo modules temporarily
2011-08-31 18:52:01 -07:00
%% The MIT License
%% Copyright (c) 2010 Alisdair Sullivan <alisdairsullivan@yahoo.ca>
%% Permission is hereby granted, free of charge, to any person obtaining a copy
%% of this software and associated documentation files (the "Software"), to deal
%% in the Software without restriction, including without limitation the rights
%% to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
%% copies of the Software, and to permit persons to whom the Software is
%% furnished to do so, subject to the following conditions:
%% The above copyright notice and this permission notice shall be included in
%% all copies or substantial portions of the Software.
%% THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
%% IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
%% FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
%% AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
%% LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
%% OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
%% THE SOFTWARE.
%% whitespace
-define(space, 16#20).
-define(tab, 16#09).
-define(cr, 16#0D).
-define(newline, 16#0A).
%% object delimiters
-define(start_object, 16#7B).
-define(end_object, 16#7D).
%% array delimiters
-define(start_array, 16#5B).
-define(end_array, 16#5D).
%% kv seperator
-define(comma, 16#2C).
-define(quote, 16#22).
-define(colon, 16#3A).
%% string escape sequences
-define(escape, 16#5C).
-define(rsolidus, 16#5C).
-define(solidus, 16#2F).
-define(formfeed, 16#0C).
-define(backspace, 16#08).
-define(unicode, 16#75).
%% math
-define(zero, 16#30).
-define(decimalpoint, 16#2E).
-define(negative, 16#2D).
-define(positive, 16#2B).
%% some useful guards
-define(is_hex(Symbol),
(Symbol >= $a andalso Symbol =< $z); (Symbol >= $A andalso Symbol =< $Z);
(Symbol >= $0 andalso Symbol =< $9)
).
-define(is_nonzero(Symbol),
Symbol >= $1 andalso Symbol =< $9
).
-define(is_noncontrol(Symbol),
(Symbol >= ?space)
).
-define(is_whitespace(Symbol),
Symbol =:= ?space; Symbol =:= ?tab; Symbol =:= ?cr; Symbol =:= ?newline
).
%% error, incomplete and event macros
-ifndef(error).
-define(error(Args),
erlang:error(badarg, Args)
).
-endif.
-ifndef(incomplete).
-define(incomplete(State, Rest, T, Stack, Opts),
{ok, lists:reverse(T), fun(Stream) when is_binary(Stream) ->
State(<<Stream/binary, Rest/binary>>, [], Stack, Opts)
end
}
).
-define(incomplete(State, Rest, T, Stack, Opts, Acc),
{ok, T, fun(Stream) when is_binary(Stream) ->
State(<<Stream/binary, Rest/binary>>, [], Stack, Opts, Acc)
end
}
).
-endif.
-ifndef(event).
-define(event(Event, State, Rest, T, Stack, Opts),
State(Rest, Event ++ T, Stack, Opts)
).
-endif.
start(<<?start_object, Rest/binary>>, T, Stack, Opts) ->
?event([start_object], object, Rest, T, [key|Stack], Opts);
start(<<?start_array, Rest/binary>>, T, Stack, Opts) ->
?event([start_array], array, Rest, T, [array|Stack], Opts);
start(<<?quote, Rest/binary>>, T, Stack, Opts) ->
string(Rest, T, Stack, Opts, []);
start(<<$t, Rest/binary>>, T, Stack, Opts) ->
tr(Rest, T, Stack, Opts);
start(<<$f, Rest/binary>>, T, Stack, Opts) ->
fa(Rest, T, Stack, Opts);
start(<<$n, Rest/binary>>, T, Stack, Opts) ->
nu(Rest, T, Stack, Opts);
start(<<?negative, Rest/binary>>, T, Stack, Opts) ->
negative(Rest, T, Stack, Opts, "-");
start(<<?zero, Rest/binary>>, T, Stack, Opts) ->
zero(Rest, T, Stack, Opts, "0");
start(<<S/utf8, Rest/binary>>, T, Stack, Opts) when ?is_nonzero(S) ->
integer(Rest, T, Stack, Opts, [S]);
start(<<S, Rest/binary>>, T, Stack, Opts) when ?is_whitespace(S) ->
start(Rest, T, Stack, Opts);
start(<<>>, T, Stack, Opts) ->
?incomplete(start, <<>>, T, Stack, Opts);
start(Bin, T, Stack, Opts) ->
?error([Bin, T, Stack, Opts]).
object(<<?quote, Rest/binary>>, T, Stack, Opts) ->
string(Rest, T, Stack, Opts, []);
object(<<?end_object, Rest/binary>>, T, [key|Stack], Opts) ->
?event([end_object], maybe_done, Rest, T, Stack, Opts);
object(<<S, Rest/binary>>, T, Stack, Opts) when ?is_whitespace(S) ->
object(Rest, T, Stack, Opts);
object(<<>>, T, Stack, Opts) ->
?incomplete(object, <<>>, T, Stack, Opts);
object(Bin, T, Stack, Opts) ->
?error([Bin, T, Stack, Opts]).
array(<<?quote, Rest/binary>>, T, Stack, Opts) ->
string(Rest, T, Stack, Opts, []);
array(<<$t, Rest/binary>>, T, Stack, Opts) ->
tr(Rest, T, Stack, Opts);
array(<<$f, Rest/binary>>, T, Stack, Opts) ->
fa(Rest, T, Stack, Opts);
array(<<$n, Rest/binary>>, T, Stack, Opts) ->
nu(Rest, T, Stack, Opts);
array(<<?negative, Rest/binary>>, T, Stack, Opts) ->
negative(Rest, T, Stack, Opts, "-");
array(<<?zero, Rest/binary>>, T, Stack, Opts) ->
zero(Rest, T, Stack, Opts, "0");
array(<<S, Rest/binary>>, T, Stack, Opts) when ?is_nonzero(S) ->
integer(Rest, T, Stack, Opts, [S]);
array(<<?start_object, Rest/binary>>, T, Stack, Opts) ->
?event([start_object], object, Rest, T, [key|Stack], Opts);
array(<<?start_array, Rest/binary>>, T, Stack, Opts) ->
?event([start_array], array, Rest, T, [array|Stack], Opts);
array(<<?end_array, Rest/binary>>, T, [array|Stack], Opts) ->
maybe_done(Rest, [end_array] ++ T, Stack, Opts);
array(<<S, Rest/binary>>, T, Stack, Opts) when ?is_whitespace(S) ->
array(Rest, T, Stack, Opts);
array(<<>>, T, Stack, Opts) ->
?incomplete(array, <<>>, T, Stack, Opts);
array(Bin, T, Stack, Opts) ->
?error([Bin, T, Stack, Opts]).
value(<<?quote, Rest/binary>>, T, Stack, Opts) ->
string(Rest, T, Stack, Opts, []);
value(<<$t, Rest/binary>>, T, Stack, Opts) ->
tr(Rest, T, Stack, Opts);
value(<<$f, Rest/binary>>, T, Stack, Opts) ->
fa(Rest, T, Stack, Opts);
value(<<$n, Rest/binary>>, T, Stack, Opts) ->
nu(Rest, T, Stack, Opts);
value(<<?negative, Rest/binary>>, T, Stack, Opts) ->
negative(Rest, T, Stack, Opts, "-");
value(<<?zero, Rest/binary>>, T, Stack, Opts) ->
zero(Rest, T, Stack, Opts, "0");
value(<<S, Rest/binary>>, T, Stack, Opts) when ?is_nonzero(S) ->
integer(Rest, T, Stack, Opts, [S]);
value(<<?start_object, Rest/binary>>, T, Stack, Opts) ->
?event([start_object], object, Rest, T, [key|Stack], Opts);
value(<<?start_array, Rest/binary>>, T, Stack, Opts) ->
?event([start_array], array, Rest, T, [array|Stack], Opts);
value(<<S, Rest/binary>>, T, Stack, Opts) when ?is_whitespace(S) ->
value(Rest, T, Stack, Opts);
value(<<>>, T, Stack, Opts) ->
?incomplete(value, <<>>, T, Stack, Opts);
value(Bin, T, Stack, Opts) ->
?error([Bin, T, Stack, Opts]).
colon(<<?colon, Rest/binary>>, T, [key|Stack], Opts) ->
value(Rest, T, [object|Stack], Opts);
colon(<<S, Rest/binary>>, T, Stack, Opts) when ?is_whitespace(S) ->
colon(Rest, T, Stack, Opts);
colon(<<>>, T, Stack, Opts) ->
?incomplete(colon, <<>>, T, Stack, Opts);
colon(Bin, T, Stack, Opts) ->
?error([Bin, T, Stack, Opts]).
key(<<?quote, Rest/binary>>, T, Stack, Opts) ->
string(Rest, T, Stack, Opts, []);
key(<<S, Rest/binary>>, T, Stack, Opts) when ?is_whitespace(S) ->
key(Rest, T, Stack, Opts);
key(<<>>, T, Stack, Opts) ->
?incomplete(key, <<>>, T, Stack, Opts);
key(Bin, T, Stack, Opts) ->
?error([Bin, T, Stack, Opts]).
%% string has an additional parameter, an accumulator (Acc) used to hold the
%% intermediate representation of the string being parsed. using a list of
%% integers representing unicode codepoints is faster than constructing
%% binaries, there's a branch kicking around which proves it
%% string uses partial_utf/1 to cease parsing when invalid encodings are
%% encountered rather than just checking remaining binary size like other
%% states to eliminate certain incomplete states
%% when parsing strings, the naive detection of partial codepoints is
%% insufficient. this incredibly anal function should detect all badly formed
%% utf sequences
partial_utf(<<>>) -> true;
partial_utf(<<X>>) when X >= 16#c2, X =< 16#df -> true;
partial_utf(<<X, Rest/binary>>) when X >= 16#e0, X =< 16#ef ->
case Rest of
<<>> -> true
; <<Y>> when Y >= 16#80, Y =< 16#bf -> true
; _ -> false
end;
partial_utf(<<X, Rest/binary>>) when X >= 16#f0, X =< 16#f4 ->
case Rest of
<<>> -> true
; <<Y>> when Y >= 16#80, Y =< 16#bf -> true
; <<Y, Z>> when Y >= 16#80, Y =< 16#bf, Z >= 16#80, Z =< 16#bf -> true
; _ -> false
end;
partial_utf(_) -> false.
string(<<?quote, Rest/binary>>, T, [key|_] = Stack, Opts, Acc) ->
?event([{key, lists:reverse(Acc)}], colon, Rest, T, Stack, Opts);
string(<<?quote, Rest/binary>>, T, Stack, Opts, Acc) ->
?event([{string, lists:reverse(Acc)}], maybe_done, Rest, T, Stack, Opts);
string(<<?rsolidus, Rest/binary>>, T, Stack, Opts, Acc) ->
escape(Rest, T, Stack, Opts, Acc);
%% things get dumb here. erlang doesn't properly restrict unicode non-characters
%% so you can't trust the codepoints it returns always
%% the range 32..16#fdcf is safe, so allow that
string(<<S/utf8, Rest/binary>>, T, Stack, Opts, Acc)
when ?is_noncontrol(S), S < 16#fdd0 ->
string(Rest, T, Stack, Opts, [S] ++ Acc);
%% the range 16#fdf0..16#fffd is also safe
string(<<S/utf8, Rest/binary>>, T, Stack, Opts, Acc)
when S > 16#fdef, S < 16#fffe ->
string(Rest, T, Stack, Opts, [S] ++ Acc);
%% yes, i think it's insane too
string(<<S/utf8, Rest/binary>>, T, Stack, Opts, Acc)
when S > 16#ffff andalso
S =/= 16#1fffe andalso S =/= 16#1ffff andalso
S =/= 16#2fffe andalso S =/= 16#2ffff andalso
S =/= 16#3fffe andalso S =/= 16#3ffff andalso
S =/= 16#4fffe andalso S =/= 16#4ffff andalso
S =/= 16#5fffe andalso S =/= 16#5ffff andalso
S =/= 16#6fffe andalso S =/= 16#6ffff andalso
S =/= 16#7fffe andalso S =/= 16#7ffff andalso
S =/= 16#8fffe andalso S =/= 16#8ffff andalso
S =/= 16#9fffe andalso S =/= 16#9ffff andalso
S =/= 16#afffe andalso S =/= 16#affff andalso
S =/= 16#bfffe andalso S =/= 16#bffff andalso
S =/= 16#cfffe andalso S =/= 16#cffff andalso
S =/= 16#dfffe andalso S =/= 16#dffff andalso
S =/= 16#efffe andalso S =/= 16#effff andalso
S =/= 16#ffffe andalso S =/= 16#fffff andalso
S =/= 16#10fffe andalso S =/= 16#10ffff ->
string(Rest, T, Stack, Opts, [S] ++ Acc);
string(Bin, T, Stack, Opts, Acc) ->
case partial_utf(Bin) of
true -> ?incomplete(string, Bin, T, Stack, Opts, Acc)
; false ->
case Opts#opts.loose_unicode of
true -> noncharacter(Bin, T, Stack, Opts, Acc)
; false -> ?error([Bin, T, Stack, Opts, Acc])
end
end.
%% we don't need to guard against partial utf here, because it's already taken
%% care of in string. theoretically, the last clause of noncharacter/4 is
%% unreachable
%% non-characters erlang doesn't recognize as non-characters, idiotically
noncharacter(<<S/utf8, Rest/binary>>, T, Stack, Opts, Acc)
when ?is_noncontrol(S) ->
string(Rest, T, Stack, Opts, [16#fffd] ++ Acc);
%% u+fffe and u+ffff
noncharacter(<<239, 191, X, Rest/binary>>, T, Stack, Opts, Acc)
when X == 190; X == 191 ->
string(Rest, T, Stack, Opts, [16#fffd] ++ Acc);
%% surrogates
noncharacter(<<237, X, _, Rest/binary>>, T, Stack, Opts, Acc) when X >= 160 ->
string(Rest, T, Stack, Opts, [16#fffd] ++ Acc);
noncharacter(Bin, T, Stack, Opts, Acc) ->
?error([Bin, T, Stack, Opts, Acc]).
escape(<<$b, Rest/binary>>, T, Stack, Opts, Acc) ->
string(Rest, T, Stack, Opts, "\b" ++ Acc);
escape(<<$f, Rest/binary>>, T, Stack, Opts, Acc) ->
string(Rest, T, Stack, Opts, "\f" ++ Acc);
escape(<<$n, Rest/binary>>, T, Stack, Opts, Acc) ->
string(Rest, T, Stack, Opts, "\n" ++ Acc);
escape(<<$r, Rest/binary>>, T, Stack, Opts, Acc) ->
string(Rest, T, Stack, Opts, "\r" ++ Acc);
escape(<<$t, Rest/binary>>, T, Stack, Opts, Acc) ->
string(Rest, T, Stack, Opts, "\t" ++ Acc);
escape(<<$u, Rest/binary>>, T, Stack, Opts, Acc) ->
escaped_unicode(Rest, T, Stack, Opts, {[], Acc});
escape(<<S, Rest/binary>>, T, Stack, Opts, Acc)
when S =:= ?quote; S =:= ?solidus; S =:= ?rsolidus ->
string(Rest, T, Stack, Opts, [S] ++ Acc);
escape(<<>>, T, Stack, Opts, Acc) ->
?incomplete(escape, <<>>, T, Stack, Opts, Acc);
escape(Bin, T, Stack, Opts, Acc) ->
?error([Bin, T, Stack, Opts, Acc]).
%% this code is ugly and unfortunate, but so is json's handling of escaped
%% unicode codepoint sequences.
escaped_unicode(<<D, Rest/binary>>, T, Stack, Opts, {[C, B, A], String})
when ?is_hex(D) ->
case erlang:list_to_integer([A, B, C, D], 16) of
%% high surrogate, we need a low surrogate next
X when X >= 16#d800, X =< 16#dbff ->
low_surrogate(Rest, T, Stack, Opts, {X, String})
%% non-characters, you're not allowed to exchange these
; X when X == 16#fffe; X == 16#ffff; X >= 16#fdd0, X =< 16#fdef ->
case Opts#opts.loose_unicode of
true ->
string(Rest, T, Stack, Opts, [16#fffd] ++ String)
; false ->
?error([<<D, Rest/binary>>, T, Stack, Opts, {[C, B, A], String}])
end
%% allowing interchange of null bytes allows attackers to forge
%% malicious streams
; X when X == 16#0000 ->
case Opts#opts.loose_unicode of
true ->
string(Rest, T, Stack, Opts, [16#fffd] ++ String)
; false ->
?error([<<D, Rest/binary>>, T, Stack, Opts, {[C, B, A], String}])
end
%% anything else
; X ->
string(Rest, T, Stack, Opts, [X] ++ String)
end;
escaped_unicode(<<S, Rest/binary>>, T, Stack, Opts, {Acc, String})
when ?is_hex(S) ->
escaped_unicode(Rest, T, Stack, Opts, {[S] ++ Acc, String});
escaped_unicode(<<>>, T, Stack, Opts, Acc) ->
?incomplete(escaped_unicode, <<>>, T, Stack, Opts, Acc);
escaped_unicode(Bin, T, Stack, Opts, Acc) ->
?error([Bin, T, Stack, Opts, Acc]).
low_surrogate(<<?rsolidus, Rest/binary>>, T, Stack, Opts, Acc) ->
low_surrogate_u(Rest, T, Stack, Opts, Acc);
%% not an escaped codepoint, our high codepoint is illegal. dispatch back to
%% string to handle
low_surrogate(<<S, Rest/binary>> = Bin, T, Stack, Opts, {High, String}) ->
case Opts#opts.loose_unicode of
true ->
string(Bin, T, Stack, Opts, [16#fffd] ++ String)
; false ->
?error([<<S, Rest/binary>>, T, Stack, Opts, {High, String}])
end;
low_surrogate(<<>>, T, Stack, Opts, Acc) ->
?incomplete(low_surrogate, <<>>, T, Stack, Opts, Acc);
low_surrogate(Bin, T, Stack, Opts, Acc) ->
?error([Bin, T, Stack, Opts, Acc]).
low_surrogate_u(<<$u, Rest/binary>>, T, Stack, Opts, {High, String}) ->
low_surrogate_v(Rest, T, Stack, Opts, {[], High, String});
%% not a low surrogate, dispatch back to string to handle, including the
%% rsolidus we parsed previously
low_surrogate_u(<<S, Rest/binary>> = Bin, T, Stack, Opts, {High, String}) ->
case Opts#opts.loose_unicode of
true ->
string(<<?rsolidus, Bin/binary>>,
T,
Stack,
Opts,
[16#fffd] ++ String
)
; false ->
?error([<<S, Rest/binary>>, T, Stack, Opts, {High, String}])
end;
low_surrogate_u(<<>>, T, Stack, Opts, Acc) ->
?incomplete(low_surrogate_u, <<>>, T, Stack, Opts, Acc);
low_surrogate_u(Bin, T, Stack, Opts, Acc) ->
?error([Bin, T, Stack, Opts, Acc]).
low_surrogate_v(<<D, Rest/binary>>, T, Stack, Opts, {[C, B, A], High, String})
when ?is_hex(D) ->
case erlang:list_to_integer([A, B, C, D], 16) of
X when X >= 16#dc00, X =< 16#dfff ->
V = surrogate_to_codepoint(High, X),
case V rem 16#10000 of Y when Y == 16#fffe; Y == 16#ffff ->
case Opts#opts.loose_unicode of
true ->
string(Rest, T, Stack, Opts, [16#fffd] ++ String)
; false ->
?error([<<D, Rest/binary>>, T, Stack, Opts, {[C, B, A], High, String}])
end
; _ ->
string(Rest, T, Stack, Opts, [V] ++ String)
end
%% not a low surrogate, bad bad bad
; _ ->
case Opts#opts.loose_unicode of
true ->
string(Rest, T, Stack, Opts, [16#fffd, 16#fffd] ++ String)
; false ->
?error([<<D, Rest/binary>>, T, Stack, Opts, {[C, B, A], High, String}])
end
end;
low_surrogate_v(<<S, Rest/binary>>, T, Stack, Opts, {Low, High, String})
when ?is_hex(S) ->
low_surrogate_v(Rest, T, Stack, Opts, {[S] ++ Low, High, String});
low_surrogate_v(<<>>, T, Stack, Opts, Acc) ->
?incomplete(low_surrogate_v, <<>>, T, Stack, Opts, Acc);
low_surrogate_v(Bin, T, Stack, Opts, Acc) ->
?error([Bin, T, Stack, Opts, Acc]).
%% stole this from the unicode spec
surrogate_to_codepoint(High, Low) ->
(High - 16#d800) * 16#400 + (Low - 16#dc00) + 16#10000.
%% like strings, numbers are collected in an intermediate accumulator before
%% being emitted to the callback handler
negative(<<$0, Rest/binary>>, T, Stack, Opts, Acc) ->
zero(Rest, T, Stack, Opts, "0" ++ Acc);
negative(<<S, Rest/binary>>, T, Stack, Opts, Acc) when ?is_nonzero(S) ->
integer(Rest, T, Stack, Opts, [S] ++ Acc);
negative(<<>>, T, Stack, Opts, Acc) ->
?incomplete(negative, <<>>, T, Stack, Opts, Acc);
negative(Bin, T, Stack, Opts, Acc) ->
?error([Bin, T, Stack, Opts, Acc]).
zero(<<?end_object, Rest/binary>>, T, [object|Stack], Opts, Acc) ->
?event([end_object, format_number(Acc)], maybe_done, Rest, T, Stack, Opts);
zero(<<?end_array, Rest/binary>>, T, [array|Stack], Opts, Acc) ->
?event([end_array, format_number(Acc)], maybe_done, Rest, T, Stack, Opts);
zero(<<?comma, Rest/binary>>, T, [object|Stack], Opts, Acc) ->
?event([format_number(Acc)], key, Rest, T, [key|Stack], Opts);
zero(<<?comma, Rest/binary>>, T, [array|_] = Stack, Opts, Acc) ->
?event([format_number(Acc)], value, Rest, T, Stack, Opts);
zero(<<?decimalpoint, Rest/binary>>, T, Stack, Opts, Acc) ->
initial_decimal(Rest, T, Stack, Opts, {Acc, []});
zero(<<S, Rest/binary>>, T, Stack, Opts, Acc) when ?is_whitespace(S) ->
?event([format_number(Acc)], maybe_done, Rest, T, Stack, Opts);
zero(<<>>, T, Stack, Opts, Acc) ->
?incomplete(zero, <<>>, T, Stack, Opts, Acc);
zero(Bin, T, Stack, Opts, Acc) ->
?error([Bin, T, Stack, Opts, Acc]).
integer(<<S, Rest/binary>>, T, Stack, Opts, Acc) when ?is_nonzero(S) ->
integer(Rest, T, Stack, Opts, [S] ++ Acc);
integer(<<?end_object, Rest/binary>>, T, [object|Stack], Opts, Acc) ->
?event([end_object, format_number(Acc)], maybe_done, Rest, T, Stack, Opts);
integer(<<?end_array, Rest/binary>>, T, [array|Stack], Opts, Acc) ->
?event([end_array, format_number(Acc)], maybe_done, Rest, T, Stack, Opts);
integer(<<?comma, Rest/binary>>, T, [object|Stack], Opts, Acc) ->
?event([format_number(Acc)], key, Rest, T, [key|Stack], Opts);
integer(<<?comma, Rest/binary>>, T, [array|_] = Stack, Opts, Acc) ->
?event([format_number(Acc)], value, Rest, T, Stack, Opts);
integer(<<?decimalpoint, Rest/binary>>, T, Stack, Opts, Acc) ->
initial_decimal(Rest, T, Stack, Opts, {Acc, []});
integer(<<?zero, Rest/binary>>, T, Stack, Opts, Acc) ->
integer(Rest, T, Stack, Opts, [?zero] ++ Acc);
integer(<<S, Rest/binary>>, T, Stack, Opts, Acc) when S =:= $e; S =:= $E ->
e(Rest, T, Stack, Opts, {Acc, [], []});
integer(<<S, Rest/binary>>, T, Stack, Opts, Acc) when ?is_whitespace(S) ->
?event([format_number(Acc)], maybe_done, Rest, T, Stack, Opts);
integer(<<>>, T, Stack, Opts, Acc) ->
?incomplete(integer, <<>>, T, Stack, Opts, Acc);
integer(Bin, T, Stack, Opts, Acc) ->
?error([Bin, T, Stack, Opts, Acc]).
initial_decimal(<<S, Rest/binary>>, T, Stack, Opts, {Int, Frac})
when S =:= ?zero; ?is_nonzero(S) ->
decimal(Rest, T, Stack, Opts, {Int, [S] ++ Frac});
initial_decimal(<<>>, T, Stack, Opts, Acc) ->
?incomplete(initial_decimal, <<>>, T, Stack, Opts, Acc);
initial_decimal(Bin, T, Stack, Opts, Acc) ->
?error([Bin, T, Stack, Opts, Acc]).
decimal(<<S, Rest/binary>>, T, Stack, Opts, {Int, Frac})
when S=:= ?zero; ?is_nonzero(S) ->
decimal(Rest, T, Stack, Opts, {Int, [S] ++ Frac});
decimal(<<?end_object, Rest/binary>>, T, [object|Stack], Opts, Acc) ->
?event([end_object, format_number(Acc)], maybe_done, Rest, T, Stack, Opts);
decimal(<<?end_array, Rest/binary>>, T, [array|Stack], Opts, Acc) ->
?event([end_array, format_number(Acc)], maybe_done, Rest, T, Stack, Opts);
decimal(<<?comma, Rest/binary>>, T, [object|Stack], Opts, Acc) ->
?event([format_number(Acc)], key, Rest, T, [key|Stack], Opts);
decimal(<<?comma, Rest/binary>>, T, [array|_] = Stack, Opts, Acc) ->
?event([format_number(Acc)], value, Rest, T, Stack, Opts);
decimal(<<S, Rest/binary>>, T, Stack, Opts, {Int, Frac})
when S =:= $e; S =:= $E ->
e(Rest, T, Stack, Opts, {Int, Frac, []});
decimal(<<S, Rest/binary>>, T, Stack, Opts, Acc) when ?is_whitespace(S) ->
?event([format_number(Acc)], maybe_done, Rest, T, Stack, Opts);
decimal(<<>>, T, Stack, Opts, Acc) ->
?incomplete(decimal, <<>>, T, Stack, Opts, Acc);
decimal(Bin, T, Stack, Opts, Acc) ->
?error([Bin, T, Stack, Opts, Acc]).
e(<<S, Rest/binary>>, T, Stack, Opts, {Int, Frac, Exp})
when S =:= ?zero; ?is_nonzero(S) ->
exp(Rest, T, Stack, Opts, {Int, Frac, [S] ++ Exp});
e(<<S, Rest/binary>>, T, Stack, Opts, {Int, Frac, Exp})
when S =:= ?positive; S =:= ?negative ->
ex(Rest, T, Stack, Opts, {Int, Frac, [S] ++ Exp});
e(<<>>, T, Stack, Opts, Acc) ->
?incomplete(e, <<>>, T, Stack, Opts, Acc);
e(Bin, T, Stack, Opts, Acc) ->
?error([Bin, T, Stack, Opts, Acc]).
ex(<<S, Rest/binary>>, T, Stack, Opts, {Int, Frac, Exp})
when S =:= ?zero; ?is_nonzero(S) ->
exp(Rest, T, Stack, Opts, {Int, Frac, [S] ++ Exp});
ex(<<>>, T, Stack, Opts, Acc) ->
?incomplete(ex, <<>>, T, Stack, Opts, Acc);
ex(Bin, T, Stack, Opts, Acc) ->
?error([Bin, T, Stack, Opts, Acc]).
exp(<<S, Rest/binary>>, T, Stack, Opts, {Int, Frac, Exp})
when S =:= ?zero; ?is_nonzero(S) ->
exp(Rest, T, Stack, Opts, {Int, Frac, [S] ++ Exp});
exp(<<?end_object, Rest/binary>>, T, [object|Stack], Opts, Acc) ->
?event([end_object, format_number(Acc)], maybe_done, Rest, T, Stack, Opts);
exp(<<?end_array, Rest/binary>>, T, [array|Stack], Opts, Acc) ->
?event([end_array, format_number(Acc)], maybe_done, Rest, T, Stack, Opts);
exp(<<?comma, Rest/binary>>, T, [object|Stack], Opts, Acc) ->
?event([format_number(Acc)], key, Rest, T, [key|Stack], Opts);
exp(<<?comma, Rest/binary>>, T, [array|_] = Stack, Opts, Acc) ->
?event([format_number(Acc)], value, Rest, T, Stack, Opts);
exp(<<S, Rest/binary>>, T, Stack, Opts, Acc) when ?is_whitespace(S) ->
?event([format_number(Acc)], maybe_done, Rest, T, Stack, Opts);
exp(<<>>, T, Stack, Opts, Acc) ->
?incomplete(exp, <<>>, T, Stack, Opts, Acc);
exp(Bin, T, Stack, Opts, Acc) ->
?error([Bin, T, Stack, Opts, Acc]).
format_number(Int) when is_list(Int) ->
{integer, list_to_integer(lists:reverse(Int))};
format_number({Int, Frac}) ->
{float, list_to_float(lists:reverse(Frac ++ "." ++ Int))};
format_number({Int, [], Exp}) ->
{float, list_to_float(lists:reverse(Exp ++ "e0." ++ Int))};
format_number({Int, Frac, Exp}) ->
{float, list_to_float(lists:reverse(Exp ++ "e" ++ Frac ++ "." ++ Int))}.
tr(<<$r, Rest/binary>>, T, Stack, Opts) ->
tru(Rest, T, Stack, Opts);
tr(<<>>, T, Stack, Opts) ->
?incomplete(tr, <<>>, T, Stack, Opts);
tr(Bin, T, Stack, Opts) ->
?error([Bin, T, Stack, Opts]).
tru(<<$u, Rest/binary>>, T, Stack, Opts) ->
true(Rest, T, Stack, Opts);
tru(<<>>, T, Stack, Opts) ->
?incomplete(tru, <<>>, T, Stack, Opts);
tru(Bin, T, Stack, Opts) ->
?error([Bin, T, Stack, Opts]).
true(<<$e, Rest/binary>>, T, Stack, Opts) ->
?event([{literal, true}], maybe_done, Rest, T, Stack, Opts);
true(<<>>, T, Stack, Opts) ->
?incomplete(true, <<>>, T, Stack, Opts);
true(Bin, T, Stack, Opts) ->
?error([Bin, T, Stack, Opts]).
fa(<<$a, Rest/binary>>, T, Stack, Opts) ->
fal(Rest, T, Stack, Opts);
fa(<<>>, T, Stack, Opts) ->
?incomplete(fa, <<>>, T, Stack, Opts);
fa(Bin, T, Stack, Opts) ->
?error([Bin, T, Stack, Opts]).
fal(<<$l, Rest/binary>>, T, Stack, Opts) ->
fals(Rest, T, Stack, Opts);
fal(<<>>, T, Stack, Opts) ->
?incomplete(fal, <<>>, T, Stack, Opts);
fal(Bin, T, Stack, Opts) ->
?error([Bin, T, Stack, Opts]).
fals(<<$s, Rest/binary>>, T, Stack, Opts) ->
false(Rest, T, Stack, Opts);
fals(<<>>, T, Stack, Opts) ->
?incomplete(fals, <<>>, T, Stack, Opts);
fals(Bin, T, Stack, Opts) ->
?error([Bin, T, Stack, Opts]).
false(<<$e, Rest/binary>>, T, Stack, Opts) ->
?event([{literal, false}], maybe_done, Rest, T, Stack, Opts);
false(<<>>, T, Stack, Opts) ->
?incomplete(false, <<>>, T, Stack, Opts);
false(Bin, T, Stack, Opts) ->
?error([Bin, T, Stack, Opts]).
nu(<<$u, Rest/binary>>, T, Stack, Opts) ->
nul(Rest, T, Stack, Opts);
nu(<<>>, T, Stack, Opts) ->
?incomplete(nu, <<>>, T, Stack, Opts);
nu(Bin, T, Stack, Opts) ->
?error([Bin, T, Stack, Opts]).
nul(<<$l, Rest/binary>>, T, Stack, Opts) ->
null(Rest, T, Stack, Opts);
nul(<<>>, T, Stack, Opts) ->
?incomplete(nul, <<>>, T, Stack, Opts);
nul(Bin, T, Stack, Opts) ->
?error([Bin, T, Stack, Opts]).
null(<<$l, Rest/binary>>, T, Stack, Opts) ->
?event([{literal, null}], maybe_done, Rest, T, Stack, Opts);
null(<<>>, T, Stack, Opts) ->
?incomplete(null, <<>>, T, Stack, Opts);
null(Bin, T, Stack, Opts) ->
?error([Bin, T, Stack, Opts]).
maybe_done(<<?end_object, Rest/binary>>, T, [object|Stack], Opts) ->
?event([end_object], maybe_done, Rest, T, Stack, Opts);
maybe_done(<<?end_array, Rest/binary>>, T, [array|Stack], Opts) ->
?event([end_array], maybe_done, Rest, T, Stack, Opts);
maybe_done(<<?comma, Rest/binary>>, T, [object|Stack], Opts) ->
key(Rest, T, [key|Stack], Opts);
maybe_done(<<?comma, Rest/binary>>, T, [array|_] = Stack, Opts) ->
value(Rest, T, Stack, Opts);
maybe_done(<<S, Rest/binary>>, T, Stack, Opts) when ?is_whitespace(S) ->
maybe_done(Rest, T, Stack, Opts);
maybe_done(Rest, T, [], Opts) ->
?event([end_json], done, Rest, T, [], Opts);
maybe_done(<<>>, T, Stack, Opts) ->
?incomplete(maybe_done, <<>>, T, Stack, Opts);
maybe_done(Bin, T, Stack, Opts) ->
?error([Bin, T, Stack, Opts]).
done(<<S, Rest/binary>>, T, [], Opts) when ?is_whitespace(S) ->
done(Rest, T, [], Opts);
done(<<>>, T, [], Opts) -> ?incomplete(done, <<>>, T, [], Opts);
done(Bin, T, [], Opts) -> ?error([Bin, T, [], Opts]).
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