%--------------------------------------------------% % vim: ts=4 sw=4 et ft=mercury %--------------------------------------------------% % Copyright (C) 2017-2018 The Mercury team. % This file is distributed under the terms specified in COPYING.LIB. %--------------------------------------------------% % % File: int8.m % Main author: juliensf % Stability: low. % % Predicates and functions for dealing with signed 8-bit integer numbers. % %--------------------------------------------------% :- module int8. :- interface. :- import_module pretty_printer. %--------------------------------------------------% % % Conversion from int. % % from_int(I, I8): % % Convert an int to an int8. % Fails if I is not in [-(2^7), 2^7 - 1]. % :- pred from_int(int::in, int8::out) is semidet. % det_from_int(I) = I8: % % Convert an int to an int8. % Throws an exception if I is not in [-(2^7), 2^7 - 1]. % :- func det_from_int(int) = int8. % cast_from_int(I) = I8: % % Convert an int to an int8. % Always succeeds, but will yield a result that is mathematically equal % to I only if I is in [-(2^7), 2^7 - 1]. % :- func cast_from_int(int) = int8. %--------------------------------------------------% % % Conversion to int. % % to_int(I8) = I: % % Convert an int8 to an int. Since an int can be only 32 or 64 bits, % this is guaranteed to yield a result that is mathematically equal % to the original. % :- func to_int(int8) = int. % cast_to_int(I8) = I: % % Convert an int8 to an int. Since an int can be only 32 or 64 bits, % this is guaranteed to yield a result that is mathematically equal % to the original. % :- func cast_to_int(int8) = int. %--------------------------------------------------% % % Change of signedness. % % cast_from_uint8(U8) = I8: % % Convert a uint8 to an int8. This will yield a result that is % mathematically equal to U8 only if U8 is in [0, 2^7 - 1]. % :- func cast_from_uint8(uint8) = int8. %--------------------------------------------------% % % Comparisons and related operations. % % Less than. % :- pred (int8::in) < (int8::in) is semidet. % Greater than. % :- pred (int8::in) > (int8::in) is semidet. % Less than or equal. % :- pred (int8::in) =< (int8::in) is semidet. % Greater than or equal. % :- pred (int8::in) >= (int8::in) is semidet. % Maximum. % :- func max(int8, int8) = int8. % Minimum. % :- func min(int8, int8) = int8. %--------------------------------------------------% % % Absolute values. % % abs(X) returns the absolute value of X. % Throws an exception if X = int8.min_int8. % :- func abs(int8) = int8. % unchecked_abs(X) returns the absolute value of X, except that the result % is undefined if X = int8.min_int8. % :- func unchecked_abs(int8) = int8. % nabs(X) returns the negative of the absolute value of X. % Unlike abs/1 this function is defined for X = int8.min_int8. % :- func nabs(int8) = int8. %--------------------------------------------------% % % Arithmetic operations. % % Unary plus. % :- func + (int8::in) = (int8::uo) is det. % Unary minus. % :- func - (int8::in) = (int8::uo) is det. % Addition. % :- func int8 + int8 = int8. :- mode in + in = uo is det. :- mode uo + in = in is det. :- mode in + uo = in is det. :- func plus(int8, int8) = int8. % Subtraction. % :- func int8 - int8 = int8. :- mode in - in = uo is det. :- mode uo - in = in is det. :- mode in - uo = in is det. :- func minus(int8, int8) = int8. % Multiplication. % :- func (int8::in) * (int8::in) = (int8::uo) is det. :- func times(int8, int8) = int8. % Flooring integer division. % Truncates towards minus infinity, e.g. (-10_i8) div 3_i8 = (-4_i8). % % Throws a `domain_error' exception if the right operand is zero. % :- func (int8::in) div (int8::in) = (int8::uo) is det. % Truncating integer division. % Truncates towards zero, e.g. (-10_i8) // 3_i8 = (-3_i8). % `div' has nicer mathematical properties for negative operands, % but `//' is typically more efficient. % % Throws a `domain_error' exception if the right operand is zero. % :- func (int8::in) // (int8::in) = (int8::uo) is det. % (/)/2 is a synonym for (//)/2. % :- func (int8::in) / (int8::in) = (int8::uo) is det. % unchecked_quotient(X, Y) is the same as X // Y, but the behaviour % is undefined if the right operand is zero. % :- func unchecked_quotient(int8::in, int8::in) = (int8::uo) is det. % Modulus. % X mod Y = X - (X div Y) * Y % % Throws a `domain_error' exception if the right operand is zero. % :- func (int8::in) mod (int8::in) = (int8::uo) is det. % Remainder. % X rem Y = X - (X // Y) * Y. % % Throws a `domain_error/` exception if the right operand is zero. % :- func (int8::in) rem (int8::in) = (int8::uo) is det. % unchecked_rem(X, Y) is the same as X rem Y, but the behaviour is % undefined if the right operand is zero. % :- func unchecked_rem(int8::in, int8::in) = (int8::uo) is det. % even(X) is equivalent to (X mod 2i8 = 0i8). % :- pred even(int8::in) is semidet. % odd(X) is equivalent to (not even(X)), i.e. (X mod 2i8 = 1i8). % :- pred odd(int8::in) is semidet. %--------------------------------------------------% % % Shift operations. % % Left shift. % X << Y returns X "left shifted" by Y bits. % The bit positions vacated by the shift are filled by zeros. % Throws an exception if Y is not in [0, 8). % :- func (int8::in) << (int::in) = (int8::uo) is det. % unchecked_left_shift(X, Y) is the same as X << Y except that the % behaviour is undefined if Y is not in [0, 8). % It will typically be implemented more efficiently than X << Y. % :- func unchecked_left_shift(int8::in, int::in) = (int8::uo) is det. % Right shift. % X >> Y returns X "right shifted" by Y bits. % The bit positions vacated by the shift are filled by the sign bit. % Throws an exception if Y is not in [0, 8). % :- func (int8::in) >> (int::in) = (int8::uo) is det. % unchecked_right_shift(X, Y) is the same as X >> Y except that the % behaviour is undefined if Y is not in [0, 8). % It will typically be implemented more efficiently than X >> Y. % :- func unchecked_right_shift(int8::in, int::in) = (int8::uo) is det. %--------------------------------------------------% % % Logical operations. % % Bitwise and. % :- func (int8::in) /\ (int8::in) = (int8::uo) is det. % Bitwise or. % :- func (int8::in) \/ (int8::in) = (int8::uo) is det. % Bitwise exclusive or (xor). % :- func xor(int8, int8) = int8. :- mode xor(in, in) = uo is det. :- mode xor(in, uo) = in is det. :- mode xor(uo, in) = in is det. % Bitwise complement. % :- func \ (int8::in) = (int8::uo) is det. %--------------------------------------------------% % % Operations on bits and bytes. % % num_zeros(I) = N: % % N is the number of zeros in the binary representation of I. % :- func num_zeros(int8) = int. % num_ones(I) = N: % N is the number of ones in the binary representation of I. % :- func num_ones(int8) = int. % num_leading_zeros(I) = N: % % N is the number of leading zeros in the binary representation of I, % starting at the most significant bit position. % Note that num_leading_zeros(0i8) = 8. % :- func num_leading_zeros(int8) = int. % num_trailing_zeros(I) = N: % % N is the number of trailing zeros in the binary representation of I, % starting at the least significant bit position. % Note that num_trailing_zeros(0i8) = 8. % :- func num_trailing_zeros(int8) = int. % reverse_bits(A) = B: % % B is the is value that results from reversing the bits in the binary % representation of A. % :- func reverse_bits(int8) = int8. %--------------------------------------------------% % % Limits. :- func min_int8 = int8. :- func max_int8 = int8. %--------------------------------------------------% % % Prettyprinting. % % Convert an int8 to a pretty_printer.doc for formatting. % :- func int8_to_doc(int8) = pretty_printer.doc. %--------------------------------------------------% %--------------------------------------------------%