diff options
Diffstat (limited to 'lib/ic/src/iceval.erl')
| -rw-r--r-- | lib/ic/src/iceval.erl | 556 |
1 files changed, 0 insertions, 556 deletions
diff --git a/lib/ic/src/iceval.erl b/lib/ic/src/iceval.erl deleted file mode 100644 index a93e60124c..0000000000 --- a/lib/ic/src/iceval.erl +++ /dev/null @@ -1,556 +0,0 @@ -%% -%% %CopyrightBegin% -%% -%% Copyright Ericsson AB 1997-2016. 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(iceval). - --include("icforms.hrl"). - --export([eval_const/5, eval_e/5]). - --export([check_tk/3, get_val/1, mk_val/1]). - --define(get_max(__X, __Y), if __X > __Y -> __X; true -> __Y end). --define(get_min(__X, __Y), if __X > __Y -> __Y; true -> __X end). - --define(BASE, 100000000000000000000000000000000). --define(FIXED_MAX, 9999999999999999999999999999999). - -%% Called fr: ictype 99, 522, 533 -%% Fixed constants can be declared as: -%% (1) const fixed pi = 3.14D; or -%% (2) typedef fixed<3,2> f32; -%% const f32 pi = 3.14D; -%% Hence, if fixed is declared as (1) we must handle it especially. -eval_const(G, S, N, tk_fixed, Expr) -> - case catch eval_e(G, S, N, tk_fixed, Expr) of - T when element(1, T) == error -> 0; - V when is_record(V, fixed) -> - {ok, {tk_fixed, V#fixed.digits, V#fixed.scale}, V}; - V -> - ic_error:error(G, {bad_tk_match, Expr, tk_fixed, get_val(V)}) - end; -eval_const(G, S, N, TK, Expr) -> - case catch eval_e(G, S, N, TK, Expr) of - T when element(1, T) == error -> 0; - V -> - case check_tk(G, TK, V) of - true -> ok; - false -> - ic_error:error(G, {bad_tk_match, Expr, TK, get_val(V)}) - end, - get_val(V) - end. - - -check_op(G, S, N, Tk, Types, Op, E1, E2) -> - V1 = eval_e(G, S, N, Tk, E1), - V2 = eval_e(G, S, N, Tk, E2), - check_types(G, Op, E1, Types, V1), - check_types(G, Op, E2, Types, V2), - case check_comb(V1, V2) of - true -> - {V1, V2}; - false -> - Err = {bad_type_combination, E1, get_val(V1), get_val(V2)}, - ic_error:error(G, Err), - throw({error, Err}) - end. - -check_op(G, S, N, Tk, Types, Op, E1) -> - V1 = eval_e(G, S, N, Tk, E1), - check_types(G, Op, E1, Types, V1), - V1. - -%% Match the declared type TK against the factual value of an constant -%% -check_tk(_G, _Any, default) -> true; % Default case in union -check_tk(_G, positive_int, V) when is_integer(V) andalso V >= 0 -> true; -check_tk(_G, tk_long, V) when is_integer(V) -> true; -check_tk(_G, tk_longlong, V) when is_integer(V) -> true; %% LLON_G -check_tk(_G, tk_short, V) when is_integer(V) -> true; -check_tk(_G, tk_ushort, V) when is_integer(V) andalso V >= 0 -> true; -check_tk(_G, tk_ulong, V) when is_integer(V) andalso V >= 0 -> true; -check_tk(_G, tk_ulonglong, V) when is_integer(V) andalso V >= 0 -> true; %% ULLON_G -check_tk(_G, tk_float, V) when is_float(V) -> true; -check_tk(_G, tk_double, V) when is_float(V) -> true; -check_tk(_G, tk_boolean, V) -> is_bool(V); -check_tk(_G, tk_char, {char, _V}) -> true; -check_tk(_G, tk_wchar, {wchar, _V}) -> true; %% WCHAR -check_tk(_G, {tk_string, _Len}, {string, _V}) -> true; -check_tk(_G, {tk_wstring, _Len}, {wstring, _V}) -> true; %% WSTRING -check_tk(_G, {tk_fixed, Digits, Scale}, {fixed, Digits, Scale, _V}) -> true; -check_tk(_G, tk_octet, V) when is_integer(V) -> true; -%%check_tk(_G, tk_null, V) when integer(V) -> true; -%%check_tk(_G, tk_void, V) when integer(V) -> true; -%%check_tk(_G, tk_any, V) when integer(V) -> true; -%%check_tk(_G, {tk_objref, "", "Object"}, V) when integer(V) -> true. -check_tk(_G, {tk_enum, _, _, Body}, {enum_id, Id}) -> - until(fun(X) when X == Id -> true; - (_X) -> - false - end, Body); -check_tk(_G, _TK, _V) -> - false. - -get_val({string, X}) -> X; -get_val({wstring, X}) -> X; %% WCHAR -get_val({char, X}) -> X; -get_val({wchar, X}) -> X; %% WSTRING -get_val({enum_id, X}) -> X; -get_val(X) -> X. - -check_types(G, Op, Expr, TypeList, V) -> - case until(fun(int) when is_integer(V) -> true; - (float) when is_float(V) -> true; - (bool) when V==true -> true; - (bool) when V==false -> true; - (fixed) when is_record(V, fixed) -> true; - (_) -> false end, - TypeList) of - true -> true; - false -> - Err = {bad_type, Expr, Op, TypeList, V}, - ic_error:error(G, Err), - throw({error, Err}) - end. - -%%get_op(T) when tuple(T) -> element(1, T). - -%% Should be in lists -until(F, [H|T]) -> - case F(H) of - true -> true; - false -> until(F, T) - end; -until(_F, []) -> false. - -%% Section of all the boolean operators (because Erlang ops don't like -%% boolean values. -e_or(X, Y) when is_integer(X) andalso is_integer(Y) -> X bor Y; -e_or(true, _) -> true; -e_or(_, true) -> true; -e_or(_, _) -> false. - -e_and(X, Y) when is_integer(X) andalso is_integer(Y) -> X band Y; -e_and(true, true) -> true; -e_and(_, _) -> false. - -e_xor(X, Y) when is_integer(X) andalso is_integer(Y) -> X bxor Y; -e_xor(X, X) -> false; -e_xor(_, _) -> true. - -%% Handling infix operators (+,-,*,/) for fixed type. -%% Boundries determined as fixed<max(d1-s1,d2-s2) + max(s1,s2) + 1, max(s1,s2)> -e_fixed_add(#fixed{digits = D1, scale = S1, value = V1}, - #fixed{digits = D2, scale = S2, value = V2}) -> - Scale = ?get_max(S1, S2), - Digits = ?get_max((D1-S1), (D2-S2)) + Scale +1, - %% We must normalize the values before adding. Why? - %% 4.23 and 5.2 are represented as 423 and 52. To be able to get the - %% correct result we must add 4230 and 5200 == 9430. - {PV1, PV2} = normalize(S1, V1, S2, V2), - check_fixed_overflow(#fixed{digits = Digits, - scale = Scale, - value = (PV1 + PV2)}). - -%% Boundries determined as fixed<max(d1-s1,d2-s2) + max(s1,s2) + 1, max(s1,s2)> -e_fixed_sub(#fixed{digits = D1, scale = S1, value = V1}, - #fixed{digits = D2, scale = S2, value = V2}) -> - Scale = ?get_max(S1, S2), - Digits = ?get_max((D1-S1), (D2-S2)) + Scale +1, - {PV1, PV2} = normalize(S1, V1, S2, V2), - check_fixed_overflow(#fixed{digits = Digits, - scale = Scale, - value = (PV1 - PV2)}). - -%% Boundries determined as fixed<d1+d2, s1+s2> -e_fixed_mul(#fixed{digits = D1, scale = S1, value = V1}, - #fixed{digits = D2, scale = S2, value = V2}) -> - check_fixed_overflow(#fixed{digits = (D1+D2), - scale = (S1+S2), - value = V1*V2}). - -%% Boundries determined as fixed<(d1-s1+s2) + s inf ,s inf> -e_fixed_div(#fixed{digits = D1, scale = S1, value = V1}, - #fixed{digits = _D2, scale = S2, value = V2}) -> - {PV1, PV2} = normalize(S1, V1, S2, V2), - DigitsMin = (D1-S1+S2), - R1 = (PV1 div PV2), - R2 = (R1*?BASE + (PV1 rem PV2) * (?BASE div PV2)), - {Result2, Sinf} = delete_zeros_value(R2, 0, R1), - check_fixed_overflow(#fixed{digits = DigitsMin + Sinf, scale = Sinf, - value = Result2}). - - -%% Checks combination of argument types, basically floats and ints are -%% interchangeable, and all types are allowed with themselves. No -%% other combinations are allowed -%% -check_comb(X, Y) when is_integer(X) andalso is_integer(Y) -> true; -check_comb(X, Y) when is_float(X) andalso is_integer(Y) -> true; -check_comb(X, Y) when is_integer(X) andalso is_float(Y) -> true; -check_comb(X, Y) when is_float(X) andalso is_float(Y) -> true; -check_comb({X, _}, {X, _}) -> true; % Strings and chars are tuples -check_comb({fixed, _, _, _}, {fixed, _, _, _}) -> true; -check_comb(X, Y) -> - case {is_bool(X), is_bool(Y)} of - {true, true} -> - true; - _ -> - false - end. - -is_bool(true) -> true; -is_bool(false) -> true; -is_bool(_) -> false. - - -%%%% (15) -eval_e(G, S, N, Tk, {'or', T1, T2}) -> - {E1, E2} = check_op(G, S, N, Tk, [int, bool], 'or', T1, T2), - e_or(E1, E2); - -%%%% (16) -eval_e(G, S, N, Tk, {'xor', T1, T2}) -> - {E1, E2} = check_op(G, S, N, Tk, [int, bool], 'xor', T1, T2), - e_xor(E1, E2); - -%%%% (17) -eval_e(G, S, N, Tk, {'and', T1, T2}) -> - {E1, E2} = check_op(G, S, N, Tk, [int, bool], 'and', T1, T2), - e_and(E1, E2); - -%%%% (18) -eval_e(G, S, N, Tk, {'rshift', T1, T2}) -> - {E1, E2} = check_op(G, S, N, Tk, [int], 'rshift', T1, T2), - E1 bsr E2; -eval_e(G, S, N, Tk, {'lshift', T1, T2}) -> - {E1, E2} = check_op(G, S, N, Tk, [int], 'lshift', T1, T2), - E1 bsl E2; - -%%%% (19) -eval_e(G, S, N, Tk, {'+', T1, T2}) -> - case check_op(G, S, N, Tk, [int, float, fixed], '+', T1, T2) of - {F1, F2} when is_record(F1,fixed) andalso is_record(F2,fixed) -> - e_fixed_add(F1, F2); - {E1, E2} -> - E1 + E2 - end; -eval_e(G, S, N, Tk, {'-', T1, T2}) -> - case check_op(G, S, N, Tk, [int, float, fixed], '-', T1, T2) of - {F1, F2} when is_record(F1,fixed) andalso is_record(F2,fixed) -> - e_fixed_sub(F1, F2); - {E1, E2} -> - E1 - E2 - end; - -%%%% (20) -eval_e(G, S, N, Tk, {'*', T1, T2}) -> - case check_op(G, S, N, Tk, [int, float, fixed], '*', T1, T2) of - {F1, F2} when is_record(F1,fixed) andalso is_record(F2,fixed) -> - e_fixed_mul(F1, F2); - {E1, E2} -> - E1 * E2 - end; -eval_e(G, S, N, Tk, {'/', T1, T2}) -> - case check_op(G, S, N, Tk, [int, float, fixed], '/', T1, T2) of - {F1, F2} when is_record(F1,fixed) andalso is_record(F2,fixed) -> - e_fixed_div(F1, F2); - {E1, E2} -> - E1 / E2 - end; -eval_e(G, S, N, Tk, {'%', T1, T2}) -> - {E1, E2} = check_op(G, S, N, Tk, [int], '%', T1, T2), - E1 rem E2; - -%%%% (21) -eval_e(G, S, N, Tk, {{'-', _Line}, T}) -> - case check_op(G, S, N, Tk, [int, float, fixed], '-', T) of - F when is_record(F,fixed) -> - F#fixed{value = -(F#fixed.value)}; - Number -> - -Number - end; -eval_e(G, S, N, Tk, {{'+', _Line}, T}) -> - check_op(G, S, N, Tk, [int, float, fixed], '+', T); -eval_e(G, S, N, Tk, {{'~', Line}, T}) -> - ic_error:error(G, {unsupported_op, {'~', Line}}), - eval_e(G, S, N, Tk, T); - - -%% Ints are repr. by an Erlang integer val, floats and doubles by -%% Erlang floats, chars and strings must be tuplerized for type -%% checking. These tuples are removed just before returning from top -%% function. -%% -eval_e(_G, _S, _N, tk_fixed, {'<fixed_pt_literal>', _Line, X}) -> - create_fixed(X); -eval_e(G, _S, _N, {tk_fixed, Digits, Scale}, {'<fixed_pt_literal>', Line, X}) - when Digits < 32, Digits >= Scale -> - case convert_fixed(X, [], Digits, Digits-Scale) of - {error, Format, Args} -> - ic_error:error(G, {bad_fixed, Format, Args, Line}); - FixedData -> - {fixed, Digits, Scale, FixedData} - end; -eval_e(_G, _S, _N, _Tk, {'<integer_literal>', _Line, X}) -> list_to_integer(X); -eval_e(_G, _S, _N, {tk_string,_}, {'<string_literal>', _Line, X}) -> {string, X}; -eval_e(_G, _S, _N, {tk_wstring,_}, {'<wstring_literal>', _Line, X}) -> {wstring, X}; %% WSTRING -eval_e(_G, _S, _N, tk_char, {'<character_literal>', _Line, X}) -> {char, hd(X)}; -eval_e(_G, _S, _N, tk_wchar, {'<wcharacter_literal>', _Line, X}) -> {wchar, hd(X)}; %% WCHAR -eval_e(_G, _S, _N, _Tk, {'TRUE', _Line}) -> true; -eval_e(_G, _S, _N, _Tk, {'FALSE', _Line}) -> false; -eval_e(_G, _S, _N, _Tk, {'<floating_pt_literal>', _Line, X}) -> to_float(X); -%% Some possible error conditions -eval_e(_G, _S, _N, _Tk, {'<character_literal>', _Line, X}) -> {char, hd(X)}; %% ERROR? -%% -eval_e(G, S, N, _Tk, X) when element(1, X) == scoped_id -> - mk_val(ictype:scoped_lookup(G, S, N, X)); -eval_e(_G, _S, _N, _Tk, {default, _}) -> default; % Default case in union -eval_e(G, _S, _N, Tk, Val) -> - ic_error:error(G, {plain_error_string, Val, - io_lib:format("value and declared type ~p differ", [Tk])}). - -%% A fixed type can be 123.45 or 123 but we represent it as integers (i.e. 12345 or 123). -convert_fixed([], Acc, 0, _) -> - list_to_integer(lists:reverse(Acc)); -convert_fixed([], _Acc, _, _) -> - {error, "Fixed type do not match the digits field", []}; -convert_fixed([$.|Rest], Acc, Digits, 0) -> - convert_fixed(Rest, Acc, Digits, -1); -convert_fixed([$.|_Rest], _Acc, _, _) -> - {error, "Fixed decimal point placed incorrectly", []}; -convert_fixed([X|Rest], Acc, Digits, Position) -> - convert_fixed(Rest, [X|Acc], Digits-1, Position-1). - - -create_fixed([$0|Rest]) -> - %% Leading zeros shall be ignored. - create_fixed(Rest); -create_fixed(Fixed) -> - create_fixed(Fixed, [], 0, 0, false). - -create_fixed([], Acc, Total, Frac, true) -> - {Fixed, N} = remove_trailing_zeros(Acc, 0), - Digits = Total-N, - Scale = Frac-N, - #fixed{digits = Digits, scale = Scale, value = list_to_integer(Fixed)}; -create_fixed([], Acc, Total, _Frac, false) -> - %% A '.' never found. Hence, must be 2000D - #fixed{digits = Total, scale = 0, value = list_to_integer(lists:reverse(Acc))}; -create_fixed([$.|Rest], Acc, Total, _, _) -> - create_fixed(Rest, Acc, Total, 0, true); -create_fixed([X|Rest], Acc, Total, Frac, FoundDot) -> - create_fixed(Rest, [X|Acc], Total+1, Frac+1, FoundDot). - -remove_trailing_zeros([$0|Rest], N) -> - remove_trailing_zeros(Rest, N+1); -remove_trailing_zeros(Fixed, N) -> - {lists:reverse(Fixed), N}. - -%% Make the newly looked up value a value that can be type checked. -mk_val({_, _, {tk_string, _}, V}) -> {string, V}; -mk_val({_, _, {tk_wstring, _}, V}) -> {wstring, V}; %% WSTRING -mk_val({_, _, tk_char, V}) -> {char, V}; -mk_val({_, _, tk_wchar, V}) -> {wchar, V}; %% WCHAR -mk_val({_, _, enum_val, V}) -> - {enum_id, ic_forms:get_id2(V)}; -mk_val(X) when element(1, X) == error -> X; -mk_val({_, _, _TK, V}) -> - V; -mk_val(V) -> V. - - - -%% Floating point numbers -%% -%% Conversion to Erlang floating points is neccessary because -%% list_to_float BIF differs from IDL floats. "1e2" ".4e2" is -%% allowed in IDL and must be translated to "1.0e2" and "0.4e2" - -to_float(X) -> - list_to_float(erlangify(X)). - -erlangify([$. | R]) -> - [$0, $. | R]; -erlangify(R) -> - look_for_dot(R). - -look_for_dot([$. | R]) -> [$. | dot_pending(R)]; -look_for_dot([$e | R]) -> [$., $0, $e | R]; -look_for_dot([$E | R]) -> [$., $0, $E | R]; -look_for_dot([X | R]) -> [X | look_for_dot(R)]. - -dot_pending([$e | R]) -> [$0, $e | R]; -dot_pending([$E | R]) -> [$0, $E | R]; -dot_pending([]) -> [$0]; -dot_pending(R) -> R. - - -%%------------------------------------------------------------------ -%%--------------- Fixed Datatype Helper Functions ------------------ -%%------------------------------------------------------------------ -%% Pretty?! No, but since we now the upper-limit this is the fastest way -%% to calculate 10^x -power(0) -> 1; -power(1) -> 10; -power(2) -> 100; -power(3) -> 1000; -power(4) -> 10000; -power(5) -> 100000; -power(6) -> 1000000; -power(7) -> 10000000; -power(8) -> 100000000; -power(9) -> 1000000000; -power(10) -> 10000000000; -power(11) -> 100000000000; -power(12) -> 1000000000000; -power(13) -> 10000000000000; -power(14) -> 100000000000000; -power(15) -> 1000000000000000; -power(16) -> 10000000000000000; -power(17) -> 100000000000000000; -power(18) -> 1000000000000000000; -power(19) -> 10000000000000000000; -power(20) -> 100000000000000000000; -power(21) -> 1000000000000000000000; -power(22) -> 10000000000000000000000; -power(23) -> 100000000000000000000000; -power(24) -> 1000000000000000000000000; -power(25) -> 10000000000000000000000000; -power(26) -> 100000000000000000000000000; -power(27) -> 1000000000000000000000000000; -power(28) -> 10000000000000000000000000000; -power(29) -> 100000000000000000000000000000; -power(30) -> 1000000000000000000000000000000; -power(31) -> 10000000000000000000000000000000; -power(_) -> 10000000000000000000000000000000. - - - -%% If the result of an operation (+, -, * or /) causes overflow we use this -%% operation. However, since these calculations are performed during compiletime, -%% shouldn't the IDL-specification be changed to not cause overflow?! But, since -%% the OMG standard allows this we must support it. -check_fixed_overflow(#fixed{digits = Digits, scale = Scale, value = Value}) -> - case count_digits(abs(Value)) of - overflow -> - {N, NewVal} = cut_overflow(0, Value), -% NewDigits = Digits - N, - if - N > Scale -> - #fixed{digits = 31, scale = 0, value = NewVal}; - true -> - NewScale = Scale - N, - {NewVal2, Removed} = delete_zeros(NewVal, NewScale), - #fixed{digits = 31, scale = NewScale-Removed, value = NewVal2} - end; - Count when Count > Digits -> - Diff = Count-Digits, - if - Diff > Scale -> - #fixed{digits = Digits, scale = 0, - value = (Value div power(Diff))}; - true -> - NewScale = Scale-Diff, - {NewVal, Removed} = delete_zeros((Value div power(Diff)), NewScale), - #fixed{digits = Digits-Removed, - scale = NewScale-Removed, - value = NewVal} - end; - Count -> - {NewVal, Removed} = delete_zeros(Value, Scale), - #fixed{digits = Count-Removed, scale = Scale-Removed, value = NewVal} - end. - -%% This function see to that the values are of the same baase. -normalize(S, V1, S, V2) -> - {V1, V2}; -normalize(S1, V1, S2, V2) when S1 > S2 -> - {V1, V2*power(S1-S2)}; -normalize(S1, V1, S2, V2) -> - {V1*power(S2-S1), V2}. - -%% If we have access to the integer part of the fixed type we use this -%% operation to remove all trailing zeros. If we know the scale, length of -%% fraction part, we can use delete_zeros as well. But, after a division -%% it's hard to know the scale and we don't need to calcluate the integer part. -delete_zeros_value(0, N, _) -> - {0, 32-N}; -delete_zeros_value(X, N, M) when X > M, (X rem 10) == 0 -> - delete_zeros_value((X div 10), N+1, M); -delete_zeros_value(X, N, _) -> - {X, 32-N}. - -%% If we know the exact scale of a fixed type we can use this operation to -%% remove all trailing zeros. -delete_zeros(0, _) -> - {0,0}; -delete_zeros(X, Max) -> - delete_zeros(X, 0, Max). -delete_zeros(X, Max, Max) -> - {X, Max}; -delete_zeros(X, N, Max) when (X rem 10) == 0 -> - delete_zeros((X div 10), N+1, Max); -delete_zeros(X, N, _) -> - {X, N}. - -cut_overflow(N, X) when X > ?FIXED_MAX -> - cut_overflow(N+1, (X div 10)); -cut_overflow(N, X) -> - {N, X}. - -%% A fast way to check the size of a fixed data type. -count_digits(X) when X > ?FIXED_MAX -> overflow; -count_digits(X) when X >= 1000000000000000000000000000000 -> 31; -count_digits(X) when X >= 100000000000000000000000000000 -> 30; -count_digits(X) when X >= 10000000000000000000000000000 -> 29; -count_digits(X) when X >= 1000000000000000000000000000 -> 28; -count_digits(X) when X >= 100000000000000000000000000 -> 27; -count_digits(X) when X >= 10000000000000000000000000 -> 26; -count_digits(X) when X >= 1000000000000000000000000 -> 25; -count_digits(X) when X >= 100000000000000000000000 -> 24; -count_digits(X) when X >= 10000000000000000000000 -> 23; -count_digits(X) when X >= 1000000000000000000000 -> 22; -count_digits(X) when X >= 100000000000000000000 -> 21; -count_digits(X) when X >= 10000000000000000000 -> 20; -count_digits(X) when X >= 1000000000000000000 -> 19; -count_digits(X) when X >= 100000000000000000 -> 18; -count_digits(X) when X >= 10000000000000000 -> 17; -count_digits(X) when X >= 1000000000000000 -> 16; -count_digits(X) when X >= 100000000000000 -> 15; -count_digits(X) when X >= 10000000000000 -> 14; -count_digits(X) when X >= 1000000000000 -> 13; -count_digits(X) when X >= 100000000000 -> 12; -count_digits(X) when X >= 10000000000 -> 11; -count_digits(X) when X >= 1000000000 -> 10; -count_digits(X) when X >= 100000000 -> 9; -count_digits(X) when X >= 10000000 -> 8; -count_digits(X) when X >= 1000000 -> 7; -count_digits(X) when X >= 100000 -> 6; -count_digits(X) when X >= 10000 -> 5; -count_digits(X) when X >= 1000 -> 4; -count_digits(X) when X >= 100 -> 3; -count_digits(X) when X >= 10 -> 2; -count_digits(_X) -> 1. - -%%------------------------------------------------------------------ -%%--------------- END Fixed Datatype Helper Functions -------------- -%%------------------------------------------------------------------ |