1366 lines
45 KiB
Groff
1366 lines
45 KiB
Groff
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.\"
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.\" SPDX-License-Identifier: BSD-2-Clause
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.\"
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.\" Copyright (c) 2018-2020 Gavin D. Howard and contributors.
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.\"
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.\" Redistribution and use in source and binary forms, with or without
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.\" modification, are permitted provided that the following conditions are met:
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.\"
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.\" * Redistributions of source code must retain the above copyright notice,
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.\" this list of conditions and the following disclaimer.
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.\"
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.\" * Redistributions in binary form must reproduce the above copyright notice,
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.\" this list of conditions and the following disclaimer in the documentation
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.\" and/or other materials provided with the distribution.
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.\"
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.\" THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
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.\" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
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.\" IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
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.\" ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
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.\" LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
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.\" CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
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.\" SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
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.\" INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
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.\" CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
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.\" ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
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.\" POSSIBILITY OF SUCH DAMAGE.
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.\"
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.TH "BCL" "3" "October 2020" "Gavin D. Howard" "Libraries Manual"
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.SH NAME
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.PP
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bcl - library of arbitrary precision decimal arithmetic
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.SH SYNOPSIS
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.SS Use
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.PP
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\f[I]#include <bcl.h>\f[R]
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.PP
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Link with \f[I]-lbcl\f[R].
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.SS Signals
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.PP
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This procedure will allow clients to use signals to interrupt
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computations running in bcl(3).
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.PP
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\f[B]void bcl_handleSignal(\f[R]\f[I]void\f[R]\f[B]);\f[R]
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.PP
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\f[B]bool bcl_running(\f[R]\f[I]void\f[R]\f[B]);\f[R]
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.SS Setup
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.PP
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These items allow clients to set up bcl(3).
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.PP
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\f[B]BclError bcl_init(\f[R]\f[I]void\f[R]\f[B]);\f[R]
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.PP
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\f[B]void bcl_free(\f[R]\f[I]void\f[R]\f[B]);\f[R]
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.PP
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\f[B]bool bcl_abortOnFatalError(\f[R]\f[I]void\f[R]\f[B]);\f[R]
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.PP
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\f[B]void bcl_setAbortOnFatalError(bool\f[R] \f[I]abrt\f[R]\f[B]);\f[R]
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.PP
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\f[B]void bcl_gc(\f[R]\f[I]void\f[R]\f[B]);\f[R]
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.SS Contexts
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.PP
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These items will allow clients to handle contexts, which are isolated
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from each other.
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This allows more than one client to use bcl(3) in the same program.
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.PP
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\f[B]struct BclCtxt;\f[R]
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.PP
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\f[B]typedef struct BclCtxt* BclContext;\f[R]
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.PP
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\f[B]BclContext bcl_ctxt_create(\f[R]\f[I]void\f[R]\f[B]);\f[R]
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.PP
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\f[B]void bcl_ctxt_free(BclContext\f[R] \f[I]ctxt\f[R]\f[B]);\f[R]
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.PP
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\f[B]BclError bcl_pushContext(BclContext\f[R] \f[I]ctxt\f[R]\f[B]);\f[R]
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.PP
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\f[B]void bcl_popContext(\f[R]\f[I]void\f[R]\f[B]);\f[R]
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.PP
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\f[B]BclContext bcl_context(\f[R]\f[I]void\f[R]\f[B]);\f[R]
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.PP
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\f[B]void bcl_ctxt_freeNums(BclContext\f[R] \f[I]ctxt\f[R]\f[B]);\f[R]
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.PP
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\f[B]size_t bcl_ctxt_scale(BclContext\f[R] \f[I]ctxt\f[R]\f[B]);\f[R]
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.PP
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\f[B]void bcl_ctxt_setScale(BclContext\f[R] \f[I]ctxt\f[R]\f[B],
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size_t\f[R] \f[I]scale\f[R]\f[B]);\f[R]
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.PP
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\f[B]size_t bcl_ctxt_ibase(BclContext\f[R] \f[I]ctxt\f[R]\f[B]);\f[R]
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.PP
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\f[B]void bcl_ctxt_setIbase(BclContext\f[R] \f[I]ctxt\f[R]\f[B],
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size_t\f[R] \f[I]ibase\f[R]\f[B]);\f[R]
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.PP
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\f[B]size_t bcl_ctxt_obase(BclContext\f[R] \f[I]ctxt\f[R]\f[B]);\f[R]
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.PP
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\f[B]void bcl_ctxt_setObase(BclContext\f[R] \f[I]ctxt\f[R]\f[B],
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size_t\f[R] \f[I]obase\f[R]\f[B]);\f[R]
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.SS Errors
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.PP
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These items allow clients to handle errors.
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.PP
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\f[B]typedef enum BclError BclError;\f[R]
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.PP
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\f[B]BclError bcl_err(BclNumber\f[R] \f[I]n\f[R]\f[B]);\f[R]
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.SS Numbers
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.PP
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These items allow clients to manipulate and query the
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arbitrary-precision numbers managed by bcl(3).
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.PP
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\f[B]typedef struct { size_t i; } BclNumber;\f[R]
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.PP
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\f[B]BclNumber bcl_num_create(\f[R]\f[I]void\f[R]\f[B]);\f[R]
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.PP
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\f[B]void bcl_num_free(BclNumber\f[R] \f[I]n\f[R]\f[B]);\f[R]
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.PP
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\f[B]bool bcl_num_neg(BclNumber\f[R] \f[I]n\f[R]\f[B]);\f[R]
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.PP
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\f[B]void bcl_num_setNeg(BclNumber\f[R] \f[I]n\f[R]\f[B], bool\f[R]
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\f[I]neg\f[R]\f[B]);\f[R]
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.PP
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\f[B]size_t bcl_num_scale(BclNumber\f[R] \f[I]n\f[R]\f[B]);\f[R]
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.PP
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\f[B]BclError bcl_num_setScale(BclNumber\f[R] \f[I]n\f[R]\f[B],
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size_t\f[R] \f[I]scale\f[R]\f[B]);\f[R]
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.PP
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\f[B]size_t bcl_num_len(BclNumber\f[R] \f[I]n\f[R]\f[B]);\f[R]
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.SS Conversion
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.PP
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These items allow clients to convert numbers into and from strings and
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integers.
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.PP
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\f[B]BclNumber bcl_parse(const char *restrict\f[R]
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\f[I]val\f[R]\f[B]);\f[R]
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.PP
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\f[B]char* bcl_string(BclNumber\f[R] \f[I]n\f[R]\f[B]);\f[R]
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.PP
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\f[B]BclError bcl_bigdig(BclNumber\f[R] \f[I]n\f[R]\f[B], BclBigDig
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*\f[R]\f[I]result\f[R]\f[B]);\f[R]
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.PP
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\f[B]BclNumber bcl_bigdig2num(BclBigDig\f[R] \f[I]val\f[R]\f[B]);\f[R]
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.SS Math
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.PP
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These items allow clients to run math on numbers.
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.PP
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\f[B]BclNumber bcl_add(BclNumber\f[R] \f[I]a\f[R]\f[B], BclNumber\f[R]
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\f[I]b\f[R]\f[B]);\f[R]
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.PP
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\f[B]BclNumber bcl_sub(BclNumber\f[R] \f[I]a\f[R]\f[B], BclNumber\f[R]
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\f[I]b\f[R]\f[B]);\f[R]
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.PP
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\f[B]BclNumber bcl_mul(BclNumber\f[R] \f[I]a\f[R]\f[B], BclNumber\f[R]
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\f[I]b\f[R]\f[B]);\f[R]
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.PP
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\f[B]BclNumber bcl_div(BclNumber\f[R] \f[I]a\f[R]\f[B], BclNumber\f[R]
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\f[I]b\f[R]\f[B]);\f[R]
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.PP
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\f[B]BclNumber bcl_mod(BclNumber\f[R] \f[I]a\f[R]\f[B], BclNumber\f[R]
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\f[I]b\f[R]\f[B]);\f[R]
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.PP
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\f[B]BclNumber bcl_pow(BclNumber\f[R] \f[I]a\f[R]\f[B], BclNumber\f[R]
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\f[I]b\f[R]\f[B]);\f[R]
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.PP
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\f[B]BclNumber bcl_lshift(BclNumber\f[R] \f[I]a\f[R]\f[B],
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BclNumber\f[R] \f[I]b\f[R]\f[B]);\f[R]
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.PP
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\f[B]BclNumber bcl_rshift(BclNumber\f[R] \f[I]a\f[R]\f[B],
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BclNumber\f[R] \f[I]b\f[R]\f[B]);\f[R]
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.PP
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\f[B]BclNumber bcl_sqrt(BclNumber\f[R] \f[I]a\f[R]\f[B]);\f[R]
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.PP
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\f[B]BclError bcl_divmod(BclNumber\f[R] \f[I]a\f[R]\f[B], BclNumber\f[R]
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\f[I]b\f[R]\f[B], BclNumber *\f[R]\f[I]c\f[R]\f[B], BclNumber
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*\f[R]\f[I]d\f[R]\f[B]);\f[R]
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.PP
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\f[B]BclNumber bcl_modexp(BclNumber\f[R] \f[I]a\f[R]\f[B],
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BclNumber\f[R] \f[I]b\f[R]\f[B], BclNumber\f[R] \f[I]c\f[R]\f[B]);\f[R]
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.SS Miscellaneous
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.PP
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These items are miscellaneous.
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.PP
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\f[B]void bcl_zero(BclNumber\f[R] \f[I]n\f[R]\f[B]);\f[R]
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.PP
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\f[B]void bcl_one(BclNumber\f[R] \f[I]n\f[R]\f[B]);\f[R]
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.PP
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\f[B]ssize_t bcl_cmp(BclNumber\f[R] \f[I]a\f[R]\f[B], BclNumber\f[R]
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\f[I]b\f[R]\f[B]);\f[R]
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.PP
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\f[B]BclError bcl_copy(BclNumber\f[R] \f[I]d\f[R]\f[B], BclNumber\f[R]
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\f[I]s\f[R]\f[B]);\f[R]
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.PP
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\f[B]BclNumber bcl_dup(BclNumber\f[R] \f[I]s\f[R]\f[B]);\f[R]
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.SS Pseudo-Random Number Generator
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.PP
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These items allow clients to manipulate the seeded pseudo-random number
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generator in bcl(3).
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.PP
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\f[B]#define BCL_SEED_ULONGS\f[R]
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.PP
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\f[B]#define BCL_SEED_SIZE\f[R]
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.PP
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\f[B]typedef unsigned long BclBigDig;\f[R]
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.PP
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\f[B]typedef unsigned long BclRandInt;\f[R]
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.PP
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\f[B]BclNumber bcl_irand(BclNumber\f[R] \f[I]a\f[R]\f[B]);\f[R]
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.PP
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\f[B]BclNumber bcl_frand(size_t\f[R] \f[I]places\f[R]\f[B]);\f[R]
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.PP
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\f[B]BclNumber bcl_ifrand(BclNumber\f[R] \f[I]a\f[R]\f[B], size_t\f[R]
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\f[I]places\f[R]\f[B]);\f[R]
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.PP
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\f[B]BclError bcl_rand_seedWithNum(BclNumber\f[R]
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\f[I]n\f[R]\f[B]);\f[R]
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.PP
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\f[B]BclError bcl_rand_seed(unsigned char\f[R]
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\f[I]seed\f[R]\f[B][\f[R]\f[I]BC_SEED_SIZE\f[R]\f[B]]);\f[R]
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.PP
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\f[B]void bcl_rand_reseed(\f[R]\f[I]void\f[R]\f[B]);\f[R]
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.PP
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\f[B]BclNumber bcl_rand_seed2num(\f[R]\f[I]void\f[R]\f[B]);\f[R]
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.PP
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\f[B]BclRandInt bcl_rand_int(\f[R]\f[I]void\f[R]\f[B]);\f[R]
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.PP
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\f[B]BclRandInt bcl_rand_bounded(BclRandInt\f[R]
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\f[I]bound\f[R]\f[B]);\f[R]
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.SH DESCRIPTION
|
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.PP
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bcl(3) is a library that implements arbitrary-precision decimal math, as
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standardized by
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POSIX (https://pubs.opengroup.org/onlinepubs/9699919799/utilities/bc.html)
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in bc(1).
|
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.PP
|
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bcl(3) is async-signal-safe if
|
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\f[B]bcl_handleSignal(\f[R]\f[I]void\f[R]\f[B])\f[R] is used properly.
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(See the \f[B]SIGNAL HANDLING\f[R] section.)
|
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.PP
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All of the items in its interface are described below.
|
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See the documentation for each function for what each function can
|
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return.
|
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.SS Signals
|
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.TP
|
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\f[B]void bcl_handleSignal(\f[R]\f[I]void\f[R]\f[B])\f[R]
|
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An async-signal-safe function that can be called from a signal handler.
|
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If called from a signal handler on the same thread as any executing
|
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bcl(3) functions, it will interrupt the functions and force them to
|
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return early.
|
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It is undefined behavior if this function is called from a thread that
|
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is \f[I]not\f[R] executing any bcl(3) functions while any bcl(3)
|
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functions are executing.
|
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.RS
|
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.PP
|
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If execution \f[I]is\f[R] interrupted,
|
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\f[B]bcl_handleSignal(\f[R]\f[I]void\f[R]\f[B])\f[R] does \f[I]not\f[R]
|
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return to its caller.
|
||
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.PP
|
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See the \f[B]SIGNAL HANDLING\f[R] section.
|
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.RE
|
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.TP
|
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\f[B]bool bcl_running(\f[R]\f[I]void\f[R]\f[B])\f[R]
|
||
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An async-signal-safe function that can be called from a signal handler.
|
||
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It will return \f[B]true\f[R] if any bcl(3) procedures are running,
|
||
|
which means it is safe to call
|
||
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\f[B]bcl_handleSignal(\f[R]\f[I]void\f[R]\f[B])\f[R].
|
||
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Otherwise, it returns \f[B]false\f[R].
|
||
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.RS
|
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.PP
|
||
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See the \f[B]SIGNAL HANDLING\f[R] section.
|
||
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.RE
|
||
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.SS Setup
|
||
|
.TP
|
||
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\f[B]BclError bcl_init(\f[R]\f[I]void\f[R]\f[B])\f[R]
|
||
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Initializes this library.
|
||
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This function can be called multiple times, but each call must be
|
||
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matched by a call to \f[B]bcl_free(\f[R]\f[I]void\f[R]\f[B])\f[R].
|
||
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This is to make it possible for multiple libraries and applications to
|
||
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initialize bcl(3) without problem.
|
||
|
.RS
|
||
|
.PP
|
||
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If there was no error, \f[B]BCL_ERROR_NONE\f[R] is returned.
|
||
|
Otherwise, this function can return:
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_FATAL_ALLOC_ERR\f[R]
|
||
|
.PP
|
||
|
This function must be the first one clients call.
|
||
|
Calling any other function without calling this one first is undefined
|
||
|
behavior.
|
||
|
.RE
|
||
|
.TP
|
||
|
\f[B]void bcl_free(\f[R]\f[I]void\f[R]\f[B])\f[R]
|
||
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Decrements bcl(3)\[cq]s reference count and frees the data associated
|
||
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with it if the reference count is \f[B]0\f[R].
|
||
|
.RS
|
||
|
.PP
|
||
|
This function must be the last one clients call.
|
||
|
Calling this function before calling any other function is undefined
|
||
|
behavior.
|
||
|
.RE
|
||
|
.TP
|
||
|
\f[B]bool bcl_abortOnFatalError(\f[R]\f[I]void\f[R]\f[B])\f[R]
|
||
|
Queries and returns the current state of calling \f[B]abort()\f[R] on
|
||
|
fatal errors.
|
||
|
If \f[B]true\f[R] is returned, bcl(3) will cause a \f[B]SIGABRT\f[R] if
|
||
|
a fatal error occurs.
|
||
|
.RS
|
||
|
.PP
|
||
|
If activated, clients do not need to check for fatal errors.
|
||
|
.RE
|
||
|
.TP
|
||
|
\f[B]void bcl_setAbortOnFatalError(bool\f[R] \f[I]abrt\f[R]\f[B])\f[R]
|
||
|
Sets the state of calling \f[B]abort()\f[R] on fatal errors.
|
||
|
If \f[I]abrt\f[R] is \f[B]false\f[R], bcl(3) will not cause a
|
||
|
\f[B]SIGABRT\f[R] on fatal errors after the call.
|
||
|
If \f[I]abrt\f[R] is \f[B]true\f[R], bcl(3) will cause a
|
||
|
\f[B]SIGABRT\f[R] on fatal errors after the call.
|
||
|
.RS
|
||
|
.PP
|
||
|
If activated, clients do not need to check for fatal errors.
|
||
|
.RE
|
||
|
.TP
|
||
|
\f[B]void bcl_gc(\f[R]\f[I]void\f[R]\f[B])\f[R]
|
||
|
Garbage collects cached instances of arbitrary-precision numbers.
|
||
|
This only frees the memory of numbers that are \f[I]not\f[R] in use, so
|
||
|
it is safe to call at any time.
|
||
|
.SS Contexts
|
||
|
.PP
|
||
|
All procedures that take a \f[B]BclContext\f[R] parameter a require a
|
||
|
valid context as an argument.
|
||
|
.TP
|
||
|
\f[B]struct BclCtxt\f[R]
|
||
|
A forward declaration for a hidden \f[B]struct\f[R] type.
|
||
|
Clients cannot access the internals of the \f[B]struct\f[R] type
|
||
|
directly.
|
||
|
All interactions with the type are done through pointers.
|
||
|
See \f[B]BclContext\f[R] below.
|
||
|
.TP
|
||
|
\f[B]BclContext\f[R]
|
||
|
A typedef to a pointer of \f[B]struct BclCtxt\f[R].
|
||
|
This is the only handle clients can get to \f[B]struct BclCtxt\f[R].
|
||
|
.RS
|
||
|
.PP
|
||
|
A \f[B]BclContext\f[R] contains the values \f[B]scale\f[R],
|
||
|
\f[B]ibase\f[R], and \f[B]obase\f[R], as well as a list of numbers.
|
||
|
.PP
|
||
|
\f[B]scale\f[R] is a value used to control how many decimal places
|
||
|
calculations should use.
|
||
|
A value of \f[B]0\f[R] means that calculations are done on integers
|
||
|
only, where applicable, and a value of 20, for example, means that all
|
||
|
applicable calculations return results with 20 decimal places.
|
||
|
The default is \f[B]0\f[R].
|
||
|
.PP
|
||
|
\f[B]ibase\f[R] is a value used to control the input base.
|
||
|
The minimum \f[B]ibase\f[R] is \f[B]2\f[R], and the maximum is
|
||
|
\f[B]36\f[R].
|
||
|
If \f[B]ibase\f[R] is \f[B]2\f[R], numbers are parsed as though they are
|
||
|
in binary, and any digits larger than \f[B]1\f[R] are clamped.
|
||
|
Likewise, a value of \f[B]10\f[R] means that numbers are parsed as
|
||
|
though they are decimal, and any larger digits are clamped.
|
||
|
The default is \f[B]10\f[R].
|
||
|
.PP
|
||
|
\f[B]obase\f[R] is a value used to control the output base.
|
||
|
The minimum \f[B]obase\f[R] is \f[B]0\f[R] and the maximum is
|
||
|
\f[B]BC_BASE_MAX\f[R] (see the \f[B]LIMITS\f[R] section).
|
||
|
.PP
|
||
|
Numbers created in one context are not valid in another context.
|
||
|
It is undefined behavior to use a number created in a different context.
|
||
|
Contexts are meant to isolate the numbers used by different clients in
|
||
|
the same application.
|
||
|
.RE
|
||
|
.TP
|
||
|
\f[B]BclContext bcl_ctxt_create(\f[R]\f[I]void\f[R]\f[B])\f[R]
|
||
|
Creates a context and returns it.
|
||
|
Returns \f[B]NULL\f[R] if there was an error.
|
||
|
.TP
|
||
|
\f[B]void bcl_ctxt_free(BclContext\f[R] \f[I]ctxt\f[R]\f[B])\f[R]
|
||
|
Frees \f[I]ctxt\f[R], after which it is no longer valid.
|
||
|
It is undefined behavior to attempt to use an invalid context.
|
||
|
.TP
|
||
|
\f[B]BclError bcl_pushContext(BclContext\f[R] \f[I]ctxt\f[R]\f[B])\f[R]
|
||
|
Pushes \f[I]ctxt\f[R] onto bcl(3)\[cq]s stack of contexts.
|
||
|
\f[I]ctxt\f[R] must have been created with
|
||
|
\f[B]bcl_ctxt_create(\f[R]\f[I]void\f[R]\f[B])\f[R].
|
||
|
.RS
|
||
|
.PP
|
||
|
If there was no error, \f[B]BCL_ERROR_NONE\f[R] is returned.
|
||
|
Otherwise, this function can return:
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_FATAL_ALLOC_ERR\f[R]
|
||
|
.PP
|
||
|
There \f[I]must\f[R] be a valid context to do any arithmetic.
|
||
|
.RE
|
||
|
.TP
|
||
|
\f[B]void bcl_popContext(\f[R]\f[I]void\f[R]\f[B])\f[R]
|
||
|
Pops the current context off of the stack, if one exists.
|
||
|
.TP
|
||
|
\f[B]BclContext bcl_context(\f[R]\f[I]void\f[R]\f[B])\f[R]
|
||
|
Returns the current context, or \f[B]NULL\f[R] if no context exists.
|
||
|
.TP
|
||
|
\f[B]void bcl_ctxt_freeNums(BclContext\f[R] \f[I]ctxt\f[R]\f[B])\f[R]
|
||
|
Frees all numbers in use that are associated with \f[I]ctxt\f[R].
|
||
|
It is undefined behavior to attempt to use a number associated with
|
||
|
\f[I]ctxt\f[R] after calling this procedure unless such numbers have
|
||
|
been created with \f[B]bcl_num_create(\f[R]\f[I]void\f[R]\f[B])\f[R]
|
||
|
after calling this procedure.
|
||
|
.TP
|
||
|
\f[B]size_t bcl_ctxt_scale(BclContext\f[R] \f[I]ctxt\f[R]\f[B])\f[R]
|
||
|
Returns the \f[B]scale\f[R] for given context.
|
||
|
.TP
|
||
|
\f[B]void bcl_ctxt_setScale(BclContext\f[R] \f[I]ctxt\f[R]\f[B], size_t\f[R] \f[I]scale\f[R]\f[B])\f[R]
|
||
|
Sets the \f[B]scale\f[R] for the given context to the argument
|
||
|
\f[I]scale\f[R].
|
||
|
.TP
|
||
|
\f[B]size_t bcl_ctxt_ibase(BclContext\f[R] \f[I]ctxt\f[R]\f[B])\f[R]
|
||
|
Returns the \f[B]ibase\f[R] for the given context.
|
||
|
.TP
|
||
|
\f[B]void bcl_ctxt_setIbase(BclContext\f[R] \f[I]ctxt\f[R]\f[B], size_t\f[R] \f[I]ibase\f[R]\f[B])\f[R]
|
||
|
Sets the \f[B]ibase\f[R] for the given context to the argument
|
||
|
\f[I]ibase\f[R].
|
||
|
If the argument \f[I]ibase\f[R] is invalid, it clamped, so an
|
||
|
\f[I]ibase\f[R] of \f[B]0\f[R] or \f[B]1\f[R] is clamped to \f[B]2\f[R],
|
||
|
and any values above \f[B]36\f[R] are clamped to \f[B]36\f[R].
|
||
|
.TP
|
||
|
\f[B]size_t bcl_ctxt_obase(BclContext\f[R] \f[I]ctxt\f[R]\f[B])\f[R]
|
||
|
Returns the \f[B]obase\f[R] for the given context.
|
||
|
.TP
|
||
|
\f[B]void bcl_ctxt_setObase(BclContext\f[R] \f[I]ctxt\f[R]\f[B], size_t\f[R] \f[I]obase\f[R]\f[B])\f[R]
|
||
|
Sets the \f[B]obase\f[R] for the given context to the argument
|
||
|
\f[I]obase\f[R].
|
||
|
.SS Errors
|
||
|
.TP
|
||
|
\f[B]BclError\f[R]
|
||
|
An \f[B]enum\f[R] of possible error codes.
|
||
|
See the \f[B]ERRORS\f[R] section for a complete listing the codes.
|
||
|
.TP
|
||
|
\f[B]BclError bcl_err(BclNumber\f[R] \f[I]n\f[R]\f[B])\f[R]
|
||
|
Checks for errors in a \f[B]BclNumber\f[R].
|
||
|
All functions that can return a \f[B]BclNumber\f[R] can encode an error
|
||
|
in the number, and this function will return the error, if any.
|
||
|
If there was no error, it will return \f[B]BCL_ERROR_NONE\f[R].
|
||
|
.RS
|
||
|
.PP
|
||
|
There must be a valid current context.
|
||
|
.RE
|
||
|
.SS Numbers
|
||
|
.PP
|
||
|
All procedures in this section require a valid current context.
|
||
|
.TP
|
||
|
\f[B]BclNumber\f[R]
|
||
|
A handle to an arbitrary-precision number.
|
||
|
The actual number type is not exposed; the \f[B]BclNumber\f[R] handle is
|
||
|
the only way clients can refer to instances of arbitrary-precision
|
||
|
numbers.
|
||
|
.TP
|
||
|
\f[B]BclNumber bcl_num_create(\f[R]\f[I]void\f[R]\f[B])\f[R]
|
||
|
Creates and returns a \f[B]BclNumber\f[R].
|
||
|
.RS
|
||
|
.PP
|
||
|
bcl(3) will encode an error in the return value, if there was one.
|
||
|
The error can be queried with \f[B]bcl_err(BclNumber)\f[R].
|
||
|
Possible errors include:
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_CONTEXT\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_FATAL_ALLOC_ERR\f[R]
|
||
|
.RE
|
||
|
.TP
|
||
|
\f[B]void bcl_num_free(BclNumber\f[R] \f[I]n\f[R]\f[B])\f[R]
|
||
|
Frees \f[I]n\f[R].
|
||
|
It is undefined behavior to use \f[I]n\f[R] after calling this function.
|
||
|
.TP
|
||
|
\f[B]bool bcl_num_neg(BclNumber\f[R] \f[I]n\f[R]\f[B])\f[R]
|
||
|
Returns \f[B]true\f[R] if \f[I]n\f[R] is negative, \f[B]false\f[R]
|
||
|
otherwise.
|
||
|
.TP
|
||
|
\f[B]void bcl_num_setNeg(BclNumber\f[R] \f[I]n\f[R]\f[B], bool\f[R] \f[I]neg\f[R]\f[B])\f[R]
|
||
|
Sets \f[I]n\f[R]\[cq]s sign to \f[I]neg\f[R], where \f[B]true\f[R] is
|
||
|
negative, and \f[B]false\f[R] is positive.
|
||
|
.TP
|
||
|
\f[B]size_t bcl_num_scale(BclNumber\f[R] \f[I]n\f[R]\f[B])\f[R]
|
||
|
Returns the \f[I]scale\f[R] of \f[I]n\f[R].
|
||
|
.RS
|
||
|
.PP
|
||
|
The \f[I]scale\f[R] of a number is the number of decimal places it has
|
||
|
after the radix (decimal point).
|
||
|
.RE
|
||
|
.TP
|
||
|
\f[B]BclError bcl_num_setScale(BclNumber\f[R] \f[I]n\f[R]\f[B], size_t\f[R] \f[I]scale\f[R]\f[B])\f[R]
|
||
|
Sets the \f[I]scale\f[R] of \f[I]n\f[R] to the argument \f[I]scale\f[R].
|
||
|
If the argument \f[I]scale\f[R] is greater than the \f[I]scale\f[R] of
|
||
|
\f[I]n\f[R], \f[I]n\f[R] is extended.
|
||
|
If the argument \f[I]scale\f[R] is less than the \f[I]scale\f[R] of
|
||
|
\f[I]n\f[R], \f[I]n\f[R] is truncated.
|
||
|
.RS
|
||
|
.PP
|
||
|
If there was no error, \f[B]BCL_ERROR_NONE\f[R] is returned.
|
||
|
Otherwise, this function can return:
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_NUM\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_CONTEXT\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_FATAL_ALLOC_ERR\f[R]
|
||
|
.RE
|
||
|
.TP
|
||
|
\f[B]size_t bcl_num_len(BclNumber\f[R] \f[I]n\f[R]\f[B])\f[R]
|
||
|
Returns the number of \f[I]significant decimal digits\f[R] in
|
||
|
\f[I]n\f[R].
|
||
|
.SS Conversion
|
||
|
.PP
|
||
|
All procedures in this section require a valid current context.
|
||
|
.PP
|
||
|
All procedures in this section consume the given \f[B]BclNumber\f[R]
|
||
|
arguments that are not given to pointer arguments.
|
||
|
See the \f[B]Consumption and Propagation\f[R] subsection below.
|
||
|
.TP
|
||
|
\f[B]BclNumber bcl_parse(const char *restrict\f[R] \f[I]val\f[R]\f[B])\f[R]
|
||
|
Parses a number string according to the current context\[cq]s
|
||
|
\f[B]ibase\f[R] and returns the resulting number.
|
||
|
.RS
|
||
|
.PP
|
||
|
\f[I]val\f[R] must be non-\f[B]NULL\f[R] and a valid string.
|
||
|
See \f[B]BCL_ERROR_PARSE_INVALID_STR\f[R] in the \f[B]ERRORS\f[R]
|
||
|
section for more information.
|
||
|
.PP
|
||
|
bcl(3) will encode an error in the return value, if there was one.
|
||
|
The error can be queried with \f[B]bcl_err(BclNumber)\f[R].
|
||
|
Possible errors include:
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_NUM\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_CONTEXT\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_PARSE_INVALID_STR\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_FATAL_ALLOC_ERR\f[R]
|
||
|
.RE
|
||
|
.TP
|
||
|
\f[B]char* bcl_string(BclNumber\f[R] \f[I]n\f[R]\f[B])\f[R]
|
||
|
Returns a string representation of \f[I]n\f[R] according the the current
|
||
|
context\[cq]s \f[B]ibase\f[R].
|
||
|
The string is dynamically allocated and must be freed by the caller.
|
||
|
.RS
|
||
|
.PP
|
||
|
\f[I]n\f[R] is consumed; it cannot be used after the call.
|
||
|
See the \f[B]Consumption and Propagation\f[R] subsection below.
|
||
|
.RE
|
||
|
.TP
|
||
|
\f[B]BclError bcl_bigdig(BclNumber\f[R] \f[I]n\f[R]\f[B], BclBigDig *\f[R]\f[I]result\f[R]\f[B])\f[R]
|
||
|
Converts \f[I]n\f[R] into a \f[B]BclBigDig\f[R] and returns the result
|
||
|
in the space pointed to by \f[I]result\f[R].
|
||
|
.RS
|
||
|
.PP
|
||
|
\f[I]a\f[R] must be smaller than \f[B]BC_OVERFLOW_MAX\f[R].
|
||
|
See the \f[B]LIMITS\f[R] section.
|
||
|
.PP
|
||
|
If there was no error, \f[B]BCL_ERROR_NONE\f[R] is returned.
|
||
|
Otherwise, this function can return:
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_NUM\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_CONTEXT\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_MATH_OVERFLOW\f[R]
|
||
|
.PP
|
||
|
\f[I]n\f[R] is consumed; it cannot be used after the call.
|
||
|
See the \f[B]Consumption and Propagation\f[R] subsection below.
|
||
|
.RE
|
||
|
.TP
|
||
|
\f[B]BclNumber bcl_bigdig2num(BclBigDig\f[R] \f[I]val\f[R]\f[B])\f[R]
|
||
|
Creates a \f[B]BclNumber\f[R] from \f[I]val\f[R].
|
||
|
.RS
|
||
|
.PP
|
||
|
bcl(3) will encode an error in the return value, if there was one.
|
||
|
The error can be queried with \f[B]bcl_err(BclNumber)\f[R].
|
||
|
Possible errors include:
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_CONTEXT\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_FATAL_ALLOC_ERR\f[R]
|
||
|
.RE
|
||
|
.SS Math
|
||
|
.PP
|
||
|
All procedures in this section require a valid current context.
|
||
|
.PP
|
||
|
All procedures in this section can return the following errors:
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_NUM\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_CONTEXT\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_FATAL_ALLOC_ERR\f[R]
|
||
|
.TP
|
||
|
\f[B]BclNumber bcl_add(BclNumber\f[R] \f[I]a\f[R]\f[B], BclNumber\f[R] \f[I]b\f[R]\f[B])\f[R]
|
||
|
Adds \f[I]a\f[R] and \f[I]b\f[R] and returns the result.
|
||
|
The \f[I]scale\f[R] of the result is the max of the \f[I]scale\f[R]s of
|
||
|
\f[I]a\f[R] and \f[I]b\f[R].
|
||
|
.RS
|
||
|
.PP
|
||
|
\f[I]a\f[R] and \f[I]b\f[R] are consumed; they cannot be used after the
|
||
|
call.
|
||
|
See the \f[B]Consumption and Propagation\f[R] subsection below.
|
||
|
.PP
|
||
|
\f[I]a\f[R] and \f[I]b\f[R] can be the same number.
|
||
|
.PP
|
||
|
bcl(3) will encode an error in the return value, if there was one.
|
||
|
The error can be queried with \f[B]bcl_err(BclNumber)\f[R].
|
||
|
Possible errors include:
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_NUM\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_CONTEXT\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_FATAL_ALLOC_ERR\f[R]
|
||
|
.RE
|
||
|
.TP
|
||
|
\f[B]BclNumber bcl_sub(BclNumber\f[R] \f[I]a\f[R]\f[B], BclNumber\f[R] \f[I]b\f[R]\f[B])\f[R]
|
||
|
Subtracts \f[I]b\f[R] from \f[I]a\f[R] and returns the result.
|
||
|
The \f[I]scale\f[R] of the result is the max of the \f[I]scale\f[R]s of
|
||
|
\f[I]a\f[R] and \f[I]b\f[R].
|
||
|
.RS
|
||
|
.PP
|
||
|
\f[I]a\f[R] and \f[I]b\f[R] are consumed; they cannot be used after the
|
||
|
call.
|
||
|
See the \f[B]Consumption and Propagation\f[R] subsection below.
|
||
|
.PP
|
||
|
\f[I]a\f[R] and \f[I]b\f[R] can be the same number.
|
||
|
.PP
|
||
|
bcl(3) will encode an error in the return value, if there was one.
|
||
|
The error can be queried with \f[B]bcl_err(BclNumber)\f[R].
|
||
|
Possible errors include:
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_NUM\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_CONTEXT\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_FATAL_ALLOC_ERR\f[R]
|
||
|
.RE
|
||
|
.TP
|
||
|
\f[B]BclNumber bcl_mul(BclNumber\f[R] \f[I]a\f[R]\f[B], BclNumber\f[R] \f[I]b\f[R]\f[B])\f[R]
|
||
|
Multiplies \f[I]a\f[R] and \f[I]b\f[R] and returns the result.
|
||
|
If \f[I]ascale\f[R] is the \f[I]scale\f[R] of \f[I]a\f[R] and
|
||
|
\f[I]bscale\f[R] is the \f[I]scale\f[R] of \f[I]b\f[R], the
|
||
|
\f[I]scale\f[R] of the result is equal to
|
||
|
\f[B]min(ascale+bscale,max(scale,ascale,bscale))\f[R], where
|
||
|
\f[B]min()\f[R] and \f[B]max()\f[R] return the obvious values.
|
||
|
.RS
|
||
|
.PP
|
||
|
\f[I]a\f[R] and \f[I]b\f[R] are consumed; they cannot be used after the
|
||
|
call.
|
||
|
See the \f[B]Consumption and Propagation\f[R] subsection below.
|
||
|
.PP
|
||
|
\f[I]a\f[R] and \f[I]b\f[R] can be the same number.
|
||
|
.PP
|
||
|
bcl(3) will encode an error in the return value, if there was one.
|
||
|
The error can be queried with \f[B]bcl_err(BclNumber)\f[R].
|
||
|
Possible errors include:
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_NUM\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_CONTEXT\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_FATAL_ALLOC_ERR\f[R]
|
||
|
.RE
|
||
|
.TP
|
||
|
\f[B]BclNumber bcl_div(BclNumber\f[R] \f[I]a\f[R]\f[B], BclNumber\f[R] \f[I]b\f[R]\f[B])\f[R]
|
||
|
Divides \f[I]a\f[R] by \f[I]b\f[R] and returns the result.
|
||
|
The \f[I]scale\f[R] of the result is the \f[I]scale\f[R] of the current
|
||
|
context.
|
||
|
.RS
|
||
|
.PP
|
||
|
\f[I]b\f[R] cannot be \f[B]0\f[R].
|
||
|
.PP
|
||
|
\f[I]a\f[R] and \f[I]b\f[R] are consumed; they cannot be used after the
|
||
|
call.
|
||
|
See the \f[B]Consumption and Propagation\f[R] subsection below.
|
||
|
.PP
|
||
|
\f[I]a\f[R] and \f[I]b\f[R] can be the same number.
|
||
|
.PP
|
||
|
bcl(3) will encode an error in the return value, if there was one.
|
||
|
The error can be queried with \f[B]bcl_err(BclNumber)\f[R].
|
||
|
Possible errors include:
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_NUM\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_CONTEXT\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_MATH_DIVIDE_BY_ZERO\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_FATAL_ALLOC_ERR\f[R]
|
||
|
.RE
|
||
|
.TP
|
||
|
\f[B]BclNumber bcl_mod(BclNumber\f[R] \f[I]a\f[R]\f[B], BclNumber\f[R] \f[I]b\f[R]\f[B])\f[R]
|
||
|
Divides \f[I]a\f[R] by \f[I]b\f[R] to the \f[I]scale\f[R] of the current
|
||
|
context, computes the modulus \f[B]a-(a/b)*b\f[R], and returns the
|
||
|
modulus.
|
||
|
.RS
|
||
|
.PP
|
||
|
\f[I]b\f[R] cannot be \f[B]0\f[R].
|
||
|
.PP
|
||
|
\f[I]a\f[R] and \f[I]b\f[R] are consumed; they cannot be used after the
|
||
|
call.
|
||
|
See the \f[B]Consumption and Propagation\f[R] subsection below.
|
||
|
.PP
|
||
|
\f[I]a\f[R] and \f[I]b\f[R] can be the same number.
|
||
|
.PP
|
||
|
bcl(3) will encode an error in the return value, if there was one.
|
||
|
The error can be queried with \f[B]bcl_err(BclNumber)\f[R].
|
||
|
Possible errors include:
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_NUM\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_CONTEXT\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_MATH_DIVIDE_BY_ZERO\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_FATAL_ALLOC_ERR\f[R]
|
||
|
.RE
|
||
|
.TP
|
||
|
\f[B]BclNumber bcl_pow(BclNumber\f[R] \f[I]a\f[R]\f[B], BclNumber\f[R] \f[I]b\f[R]\f[B])\f[R]
|
||
|
Calculates \f[I]a\f[R] to the power of \f[I]b\f[R] to the
|
||
|
\f[I]scale\f[R] of the current context.
|
||
|
\f[I]b\f[R] must be an integer, but can be negative.
|
||
|
If it is negative, \f[I]a\f[R] must be non-zero.
|
||
|
.RS
|
||
|
.PP
|
||
|
\f[I]b\f[R] must be an integer.
|
||
|
If \f[I]b\f[R] is negative, \f[I]a\f[R] must not be \f[B]0\f[R].
|
||
|
.PP
|
||
|
\f[I]a\f[R] must be smaller than \f[B]BC_OVERFLOW_MAX\f[R].
|
||
|
See the \f[B]LIMITS\f[R] section.
|
||
|
.PP
|
||
|
\f[I]a\f[R] and \f[I]b\f[R] are consumed; they cannot be used after the
|
||
|
call.
|
||
|
See the \f[B]Consumption and Propagation\f[R] subsection below.
|
||
|
.PP
|
||
|
\f[I]a\f[R] and \f[I]b\f[R] can be the same number.
|
||
|
.PP
|
||
|
bcl(3) will encode an error in the return value, if there was one.
|
||
|
The error can be queried with \f[B]bcl_err(BclNumber)\f[R].
|
||
|
Possible errors include:
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_NUM\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_CONTEXT\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_MATH_NON_INTEGER\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_MATH_OVERFLOW\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_MATH_DIVIDE_BY_ZERO\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_FATAL_ALLOC_ERR\f[R]
|
||
|
.RE
|
||
|
.TP
|
||
|
\f[B]BclNumber bcl_lshift(BclNumber\f[R] \f[I]a\f[R]\f[B], BclNumber\f[R] \f[I]b\f[R]\f[B])\f[R]
|
||
|
Shifts \f[I]a\f[R] left (moves the radix right) by \f[I]b\f[R] places
|
||
|
and returns the result.
|
||
|
This is done in decimal.
|
||
|
\f[I]b\f[R] must be an integer.
|
||
|
.RS
|
||
|
.PP
|
||
|
\f[I]b\f[R] must be an integer.
|
||
|
.PP
|
||
|
\f[I]a\f[R] and \f[I]b\f[R] are consumed; they cannot be used after the
|
||
|
call.
|
||
|
See the \f[B]Consumption and Propagation\f[R] subsection below.
|
||
|
.PP
|
||
|
\f[I]a\f[R] and \f[I]b\f[R] can be the same number.
|
||
|
.PP
|
||
|
bcl(3) will encode an error in the return value, if there was one.
|
||
|
The error can be queried with \f[B]bcl_err(BclNumber)\f[R].
|
||
|
Possible errors include:
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_NUM\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_CONTEXT\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_MATH_NON_INTEGER\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_FATAL_ALLOC_ERR\f[R]
|
||
|
.RE
|
||
|
.TP
|
||
|
\f[B]BclNumber bcl_rshift(BclNumber\f[R] \f[I]a\f[R]\f[B], BclNumber\f[R] \f[I]b\f[R]\f[B])\f[R]
|
||
|
Shifts \f[I]a\f[R] right (moves the radix left) by \f[I]b\f[R] places
|
||
|
and returns the result.
|
||
|
This is done in decimal.
|
||
|
\f[I]b\f[R] must be an integer.
|
||
|
.RS
|
||
|
.PP
|
||
|
\f[I]b\f[R] must be an integer.
|
||
|
.PP
|
||
|
\f[I]a\f[R] and \f[I]b\f[R] are consumed; they cannot be used after the
|
||
|
call.
|
||
|
See the \f[B]Consumption and Propagation\f[R] subsection below.
|
||
|
.PP
|
||
|
\f[I]a\f[R] and \f[I]b\f[R] can be the same number.
|
||
|
.PP
|
||
|
bcl(3) will encode an error in the return value, if there was one.
|
||
|
The error can be queried with \f[B]bcl_err(BclNumber)\f[R].
|
||
|
Possible errors include:
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_NUM\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_CONTEXT\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_MATH_NON_INTEGER\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_FATAL_ALLOC_ERR\f[R]
|
||
|
.RE
|
||
|
.TP
|
||
|
\f[B]BclNumber bcl_sqrt(BclNumber\f[R] \f[I]a\f[R]\f[B])\f[R]
|
||
|
Calculates the square root of \f[I]a\f[R] and returns the result.
|
||
|
The \f[I]scale\f[R] of the result is equal to the \f[B]scale\f[R] of the
|
||
|
current context.
|
||
|
.RS
|
||
|
.PP
|
||
|
\f[I]a\f[R] cannot be negative.
|
||
|
.PP
|
||
|
\f[I]a\f[R] is consumed; it cannot be used after the call.
|
||
|
See the \f[B]Consumption and Propagation\f[R] subsection below.
|
||
|
.PP
|
||
|
bcl(3) will encode an error in the return value, if there was one.
|
||
|
The error can be queried with \f[B]bcl_err(BclNumber)\f[R].
|
||
|
Possible errors include:
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_NUM\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_CONTEXT\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_MATH_NEGATIVE\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_FATAL_ALLOC_ERR\f[R]
|
||
|
.RE
|
||
|
.TP
|
||
|
\f[B]BclError bcl_divmod(BclNumber\f[R] \f[I]a\f[R]\f[B], BclNumber\f[R] \f[I]b\f[R]\f[B], BclNumber *\f[R]\f[I]c\f[R]\f[B], BclNumber *\f[R]\f[I]d\f[R]\f[B])\f[R]
|
||
|
Divides \f[I]a\f[R] by \f[I]b\f[R] and returns the quotient in a new
|
||
|
number which is put into the space pointed to by \f[I]c\f[R], and puts
|
||
|
the modulus in a new number which is put into the space pointed to by
|
||
|
\f[I]d\f[R].
|
||
|
.RS
|
||
|
.PP
|
||
|
\f[I]b\f[R] cannot be \f[B]0\f[R].
|
||
|
.PP
|
||
|
\f[I]a\f[R] and \f[I]b\f[R] are consumed; they cannot be used after the
|
||
|
call.
|
||
|
See the \f[B]Consumption and Propagation\f[R] subsection below.
|
||
|
.PP
|
||
|
\f[I]c\f[R] and \f[I]d\f[R] cannot point to the same place, nor can they
|
||
|
point to the space occupied by \f[I]a\f[R] or \f[I]b\f[R].
|
||
|
.PP
|
||
|
If there was no error, \f[B]BCL_ERROR_NONE\f[R] is returned.
|
||
|
Otherwise, this function can return:
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_NUM\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_CONTEXT\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_MATH_DIVIDE_BY_ZERO\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_FATAL_ALLOC_ERR\f[R]
|
||
|
.RE
|
||
|
.TP
|
||
|
\f[B]BclNumber bcl_modexp(BclNumber\f[R] \f[I]a\f[R]\f[B], BclNumber\f[R] \f[I]b\f[R]\f[B], BclNumber\f[R] \f[I]c\f[R]\f[B])\f[R]
|
||
|
Computes a modular exponentiation where \f[I]a\f[R] is the base,
|
||
|
\f[I]b\f[R] is the exponent, and \f[I]c\f[R] is the modulus, and returns
|
||
|
the result.
|
||
|
The \f[I]scale\f[R] of the result is equal to the \f[B]scale\f[R] of the
|
||
|
current context.
|
||
|
.RS
|
||
|
.PP
|
||
|
\f[I]a\f[R], \f[I]b\f[R], and \f[I]c\f[R] must be integers.
|
||
|
\f[I]c\f[R] must not be \f[B]0\f[R].
|
||
|
\f[I]b\f[R] must not be negative.
|
||
|
.PP
|
||
|
\f[I]a\f[R], \f[I]b\f[R], and \f[I]c\f[R] are consumed; they cannot be
|
||
|
used after the call.
|
||
|
See the \f[B]Consumption and Propagation\f[R] subsection below.
|
||
|
.PP
|
||
|
bcl(3) will encode an error in the return value, if there was one.
|
||
|
The error can be queried with \f[B]bcl_err(BclNumber)\f[R].
|
||
|
Possible errors include:
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_NUM\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_CONTEXT\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_MATH_NEGATIVE\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_MATH_NON_INTEGER\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_MATH_DIVIDE_BY_ZERO\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_FATAL_ALLOC_ERR\f[R]
|
||
|
.RE
|
||
|
.SS Miscellaneous
|
||
|
.TP
|
||
|
\f[B]void bcl_zero(BclNumber\f[R] \f[I]n\f[R]\f[B])\f[R]
|
||
|
Sets \f[I]n\f[R] to \f[B]0\f[R].
|
||
|
.TP
|
||
|
\f[B]void bcl_one(BclNumber\f[R] \f[I]n\f[R]\f[B])\f[R]
|
||
|
Sets \f[I]n\f[R] to \f[B]1\f[R].
|
||
|
.TP
|
||
|
\f[B]ssize_t bcl_cmp(BclNumber\f[R] \f[I]a\f[R]\f[B], BclNumber\f[R] \f[I]b\f[R]\f[B])\f[R]
|
||
|
Compares \f[I]a\f[R] and \f[I]b\f[R] and returns \f[B]0\f[R] if
|
||
|
\f[I]a\f[R] and \f[I]b\f[R] are equal, \f[B]<0\f[R] if \f[I]a\f[R] is
|
||
|
less than \f[I]b\f[R], and \f[B]>0\f[R] if \f[I]a\f[R] is greater than
|
||
|
\f[I]b\f[R].
|
||
|
.TP
|
||
|
\f[B]BclError bcl_copy(BclNumber\f[R] \f[I]d\f[R]\f[B], BclNumber\f[R] \f[I]s\f[R]\f[B])\f[R]
|
||
|
Copies \f[I]s\f[R] into \f[I]d\f[R].
|
||
|
.RS
|
||
|
.PP
|
||
|
If there was no error, \f[B]BCL_ERROR_NONE\f[R] is returned.
|
||
|
Otherwise, this function can return:
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_NUM\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_CONTEXT\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_FATAL_ALLOC_ERR\f[R]
|
||
|
.RE
|
||
|
.TP
|
||
|
\f[B]BclNumber bcl_dup(BclNumber\f[R] \f[I]s\f[R]\f[B])\f[R]
|
||
|
Creates and returns a new \f[B]BclNumber\f[R] that is a copy of
|
||
|
\f[I]s\f[R].
|
||
|
.RS
|
||
|
.PP
|
||
|
bcl(3) will encode an error in the return value, if there was one.
|
||
|
The error can be queried with \f[B]bcl_err(BclNumber)\f[R].
|
||
|
Possible errors include:
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_NUM\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_CONTEXT\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_FATAL_ALLOC_ERR\f[R]
|
||
|
.RE
|
||
|
.SS Pseudo-Random Number Generator
|
||
|
.PP
|
||
|
The pseudo-random number generator in bcl(3) is a \f[I]seeded\f[R] PRNG.
|
||
|
Given the same seed twice, it will produce the same sequence of
|
||
|
pseudo-random numbers twice.
|
||
|
.PP
|
||
|
By default, bcl(3) attempts to seed the PRNG with data from
|
||
|
\f[B]/dev/urandom\f[R].
|
||
|
If that fails, it seeds itself with by calling \f[B]libc\f[R]\[cq]s
|
||
|
\f[B]srand(time(NULL))\f[R] and then calling \f[B]rand()\f[R] for each
|
||
|
byte, since \f[B]rand()\f[R] is only guaranteed to return \f[B]15\f[R]
|
||
|
bits.
|
||
|
.PP
|
||
|
This should provide fairly good seeding in the standard case while also
|
||
|
remaining fairly portable.
|
||
|
.PP
|
||
|
If necessary, the PRNG can be reseeded with one of the following
|
||
|
functions:
|
||
|
.IP \[bu] 2
|
||
|
\f[B]bcl_rand_seedWithNum(BclNumber)\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]bcl_rand_seed(unsigned char[BC_SEED_SIZE])\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]bcl_rand_reseed(\f[R]\f[I]void\f[R]\f[B])\f[R]
|
||
|
.PP
|
||
|
The following items allow clients to use the pseudo-random number
|
||
|
generator.
|
||
|
All procedures require a valid current context.
|
||
|
.TP
|
||
|
\f[B]BCL_SEED_ULONGS\f[R]
|
||
|
The number of \f[B]unsigned long\f[R]\[cq]s in a seed for bcl(3)\[cq]s
|
||
|
random number generator.
|
||
|
.TP
|
||
|
\f[B]BCL_SEED_SIZE\f[R]
|
||
|
The size, in \f[B]char\f[R]\[cq]s, of a seed for bcl(3)\[cq]s random
|
||
|
number generator.
|
||
|
.TP
|
||
|
\f[B]BclBigDig\f[R]
|
||
|
bcl(3)\[cq]s overflow type (see the \f[B]PERFORMANCE\f[R] section).
|
||
|
.TP
|
||
|
\f[B]BclRandInt\f[R]
|
||
|
An unsigned integer type returned by bcl(3)\[cq]s random number
|
||
|
generator.
|
||
|
.TP
|
||
|
\f[B]BclNumber bcl_irand(BclNumber\f[R] \f[I]a\f[R]\f[B])\f[R]
|
||
|
Returns a random number that is not larger than \f[I]a\f[R] in a new
|
||
|
number.
|
||
|
If \f[I]a\f[R] is \f[B]0\f[R] or \f[B]1\f[R], the new number is equal to
|
||
|
\f[B]0\f[R].
|
||
|
The bound is unlimited, so it is not bound to the size of
|
||
|
\f[B]BclRandInt\f[R].
|
||
|
This is done by generating as many random numbers as necessary,
|
||
|
multiplying them by certain exponents, and adding them all together.
|
||
|
.RS
|
||
|
.PP
|
||
|
\f[I]a\f[R] must be an integer and non-negative.
|
||
|
.PP
|
||
|
\f[I]a\f[R] is consumed; it cannot be used after the call.
|
||
|
See the \f[B]Consumption and Propagation\f[R] subsection below.
|
||
|
.PP
|
||
|
This procedure requires a valid current context.
|
||
|
.PP
|
||
|
bcl(3) will encode an error in the return value, if there was one.
|
||
|
The error can be queried with \f[B]bcl_err(BclNumber)\f[R].
|
||
|
Possible errors include:
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_NUM\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_CONTEXT\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_MATH_NEGATIVE\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_MATH_NON_INTEGER\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_FATAL_ALLOC_ERR\f[R]
|
||
|
.RE
|
||
|
.TP
|
||
|
\f[B]BclNumber bcl_frand(size_t\f[R] \f[I]places\f[R]\f[B])\f[R]
|
||
|
Returns a random number between \f[B]0\f[R] (inclusive) and \f[B]1\f[R]
|
||
|
(exclusive) that has \f[I]places\f[R] decimal digits after the radix
|
||
|
(decimal point).
|
||
|
There are no limits on \f[I]places\f[R].
|
||
|
.RS
|
||
|
.PP
|
||
|
This procedure requires a valid current context.
|
||
|
.PP
|
||
|
bcl(3) will encode an error in the return value, if there was one.
|
||
|
The error can be queried with \f[B]bcl_err(BclNumber)\f[R].
|
||
|
Possible errors include:
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_CONTEXT\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_FATAL_ALLOC_ERR\f[R]
|
||
|
.RE
|
||
|
.TP
|
||
|
\f[B]BclNumber bcl_ifrand(BclNumber\f[R] \f[I]a\f[R]\f[B], size_t\f[R] \f[I]places\f[R]\f[B])\f[R]
|
||
|
Returns a random number less than \f[I]a\f[R] with \f[I]places\f[R]
|
||
|
decimal digits after the radix (decimal point).
|
||
|
There are no limits on \f[I]a\f[R] or \f[I]places\f[R].
|
||
|
.RS
|
||
|
.PP
|
||
|
\f[I]a\f[R] must be an integer and non-negative.
|
||
|
.PP
|
||
|
\f[I]a\f[R] is consumed; it cannot be used after the call.
|
||
|
See the \f[B]Consumption and Propagation\f[R] subsection below.
|
||
|
.PP
|
||
|
This procedure requires a valid current context.
|
||
|
.PP
|
||
|
bcl(3) will encode an error in the return value, if there was one.
|
||
|
The error can be queried with \f[B]bcl_err(BclNumber)\f[R].
|
||
|
Possible errors include:
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_NUM\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_CONTEXT\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_MATH_NEGATIVE\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_MATH_NON_INTEGER\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_FATAL_ALLOC_ERR\f[R]
|
||
|
.RE
|
||
|
.TP
|
||
|
\f[B]BclError bcl_rand_seedWithNum(BclNumber\f[R] \f[I]n\f[R]\f[B])\f[R]
|
||
|
Seeds the PRNG with \f[I]n\f[R].
|
||
|
.RS
|
||
|
.PP
|
||
|
\f[I]n\f[R] is \f[I]not\f[R] consumed.
|
||
|
.PP
|
||
|
This procedure requires a valid current context.
|
||
|
.PP
|
||
|
If there was no error, \f[B]BCL_ERROR_NONE\f[R] is returned.
|
||
|
Otherwise, this function can return:
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_NUM\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_CONTEXT\f[R]
|
||
|
.PP
|
||
|
Note that if \f[B]bcl_rand_seed2num(\f[R]\f[I]void\f[R]\f[B])\f[R] or
|
||
|
\f[B]bcl_rand_seed2num_err(BclNumber)\f[R] are called right after this
|
||
|
function, they are not guaranteed to return a number equal to
|
||
|
\f[I]n\f[R].
|
||
|
.RE
|
||
|
.TP
|
||
|
\f[B]BclError bcl_rand_seed(unsigned char\f[R] \f[I]seed\f[R]\f[B][\f[R]\f[I]BC_SEED_SIZE\f[R]\f[B]])\f[R]
|
||
|
Seeds the PRNG with the bytes in \f[I]seed\f[R].
|
||
|
.RS
|
||
|
.PP
|
||
|
If there was no error, \f[B]BCL_ERROR_NONE\f[R] is returned.
|
||
|
Otherwise, this function can return:
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_CONTEXT\f[R]
|
||
|
.RE
|
||
|
.TP
|
||
|
\f[B]void bcl_rand_reseed(\f[R]\f[I]void\f[R]\f[B])\f[R]
|
||
|
Reseeds the PRNG with the default reseeding behavior.
|
||
|
First, it attempts to read data from \f[B]/dev/urandom\f[R] and falls
|
||
|
back to \f[B]libc\f[R]\[cq]s \f[B]rand()\f[R].
|
||
|
.RS
|
||
|
.PP
|
||
|
This procedure cannot fail.
|
||
|
.RE
|
||
|
.TP
|
||
|
\f[B]BclNumber bcl_rand_seed2num(\f[R]\f[I]void\f[R]\f[B])\f[R]
|
||
|
Returns the current seed of the PRNG as a \f[B]BclNumber\f[R].
|
||
|
.RS
|
||
|
.PP
|
||
|
This procedure requires a valid current context.
|
||
|
.PP
|
||
|
bcl(3) will encode an error in the return value, if there was one.
|
||
|
The error can be queried with \f[B]bcl_err(BclNumber)\f[R].
|
||
|
Possible errors include:
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_INVALID_CONTEXT\f[R]
|
||
|
.IP \[bu] 2
|
||
|
\f[B]BCL_ERROR_FATAL_ALLOC_ERR\f[R]
|
||
|
.RE
|
||
|
.TP
|
||
|
\f[B]BclRandInt bcl_rand_int(\f[R]\f[I]void\f[R]\f[B])\f[R]
|
||
|
Returns a random integer between \f[B]0\f[R] and \f[B]BC_RAND_MAX\f[R]
|
||
|
(inclusive).
|
||
|
.RS
|
||
|
.PP
|
||
|
This procedure cannot fail.
|
||
|
.RE
|
||
|
.TP
|
||
|
\f[B]BclRandInt bcl_rand_bounded(BclRandInt\f[R] \f[I]bound\f[R]\f[B])\f[R]
|
||
|
Returns a random integer between \f[B]0\f[R] and \f[I]bound\f[R]
|
||
|
(exclusive).
|
||
|
Bias is removed before returning the integer.
|
||
|
.RS
|
||
|
.PP
|
||
|
This procedure cannot fail.
|
||
|
.RE
|
||
|
.SS Consumption and Propagation
|
||
|
.PP
|
||
|
Some functions are listed as consuming some or all of their arguments.
|
||
|
This means that the arguments are freed, regardless of if there were
|
||
|
errors or not.
|
||
|
.PP
|
||
|
This is to enable compact code like the following:
|
||
|
.IP
|
||
|
.nf
|
||
|
\f[C]
|
||
|
BclNumber n = bcl_num_add(bcl_num_mul(a, b), bcl_num_div(c, d));
|
||
|
\f[R]
|
||
|
.fi
|
||
|
.PP
|
||
|
If arguments to those functions were not consumed, memory would be
|
||
|
leaked until reclaimed with \f[B]bcl_ctxt_freeNums(BclContext)\f[R].
|
||
|
.PP
|
||
|
When errors occur, they are propagated through.
|
||
|
The result should always be checked with \f[B]bcl_err(BclNumber)\f[R],
|
||
|
so the example above should properly be:
|
||
|
.IP
|
||
|
.nf
|
||
|
\f[C]
|
||
|
BclNumber n = bcl_num_add(bcl_num_mul(a, b), bcl_num_div(c, d));
|
||
|
if (bc_num_err(n) != BCL_ERROR_NONE) {
|
||
|
// Handle the error.
|
||
|
}
|
||
|
\f[R]
|
||
|
.fi
|
||
|
.SH ERRORS
|
||
|
.PP
|
||
|
Most functions in bcl(3) return, directly or indirectly, any one of the
|
||
|
error codes defined in \f[B]BclError\f[R].
|
||
|
The complete list of codes is the following:
|
||
|
.TP
|
||
|
\f[B]BCL_ERROR_NONE\f[R]
|
||
|
Success; no error occurred.
|
||
|
.TP
|
||
|
\f[B]BCL_ERROR_INVALID_NUM\f[R]
|
||
|
An invalid \f[B]BclNumber\f[R] was given as a parameter.
|
||
|
.TP
|
||
|
\f[B]BCL_ERROR_INVALID_CONTEXT\f[R]
|
||
|
An invalid \f[B]BclContext\f[R] is being used.
|
||
|
.TP
|
||
|
\f[B]BCL_ERROR_SIGNAL\f[R]
|
||
|
A signal interrupted execution.
|
||
|
.TP
|
||
|
\f[B]BCL_ERROR_MATH_NEGATIVE\f[R]
|
||
|
A negative number was given as an argument to a parameter that cannot
|
||
|
accept negative numbers, such as for square roots.
|
||
|
.TP
|
||
|
\f[B]BCL_ERROR_MATH_NON_INTEGER\f[R]
|
||
|
A non-integer was given as an argument to a parameter that cannot accept
|
||
|
non-integer numbers, such as for the second parameter of
|
||
|
\f[B]bcl_num_pow()\f[R].
|
||
|
.TP
|
||
|
\f[B]BCL_ERROR_MATH_OVERFLOW\f[R]
|
||
|
A number that would overflow its result was given as an argument, such
|
||
|
as for converting a \f[B]BclNumber\f[R] to a \f[B]BclBigDig\f[R].
|
||
|
.TP
|
||
|
\f[B]BCL_ERROR_MATH_DIVIDE_BY_ZERO\f[R]
|
||
|
A divide by zero occurred.
|
||
|
.TP
|
||
|
\f[B]BCL_ERROR_PARSE_INVALID_STR\f[R]
|
||
|
An invalid number string was passed to a parsing function.
|
||
|
.RS
|
||
|
.PP
|
||
|
A valid number string can only be one radix (period).
|
||
|
In addition, any lowercase ASCII letters, symbols, or non-ASCII
|
||
|
characters are invalid.
|
||
|
It is allowed for the first character to be a dash.
|
||
|
In that case, the number is considered to be negative.
|
||
|
.PP
|
||
|
There is one exception to the above: one lowercase \f[B]e\f[R] is
|
||
|
allowed in the number, after the radix, if it exists.
|
||
|
If the letter \f[B]e\f[R] exists, the number is considered to be in
|
||
|
scientific notation, where the part before the \f[B]e\f[R] is the
|
||
|
number, and the part after, which must be an integer, is the exponent.
|
||
|
There can be a dash right after the \f[B]e\f[R] to indicate a negative
|
||
|
exponent.
|
||
|
.PP
|
||
|
\f[B]WARNING\f[R]: Both the number and the exponent in scientific
|
||
|
notation are interpreted according to the current \f[B]ibase\f[R], but
|
||
|
the number is still multiplied by \f[B]10\[ha]exponent\f[R] regardless
|
||
|
of the current \f[B]ibase\f[R].
|
||
|
For example, if \f[B]ibase\f[R] is \f[B]16\f[R] and bcl(3) is given the
|
||
|
number string \f[B]FFeA\f[R], the resulting decimal number will be
|
||
|
\f[B]2550000000000\f[R], and if bcl(3) is given the number string
|
||
|
\f[B]10e-4\f[R], the resulting decimal number will be \f[B]0.0016\f[R].
|
||
|
.RE
|
||
|
.TP
|
||
|
\f[B]BCL_ERROR_FATAL_ALLOC_ERR\f[R]
|
||
|
bcl(3) failed to allocate memory.
|
||
|
.RS
|
||
|
.PP
|
||
|
If clients call \f[B]bcl_setAbortOnFatalError()\f[R] with an
|
||
|
\f[B]true\f[R] argument, this error will cause bcl(3) to throw a
|
||
|
\f[B]SIGABRT\f[R].
|
||
|
This behavior can also be turned off later by calling that same function
|
||
|
with a \f[B]false\f[R] argument.
|
||
|
By default, this behavior is off.
|
||
|
.PP
|
||
|
It is highly recommended that client libraries do \f[I]not\f[R] activate
|
||
|
this behavior.
|
||
|
.RE
|
||
|
.TP
|
||
|
\f[B]BCL_ERROR_FATAL_UNKNOWN_ERR\f[R]
|
||
|
An unknown error occurred.
|
||
|
.RS
|
||
|
.PP
|
||
|
If clients call \f[B]bcl_setAbortOnFatalError()\f[R] with an
|
||
|
\f[B]true\f[R] argument, this error will cause bcl(3) to throw a
|
||
|
\f[B]SIGABRT\f[R].
|
||
|
This behavior can also be turned off later by calling that same function
|
||
|
with a \f[B]false\f[R] argument.
|
||
|
By default, this behavior is off.
|
||
|
.PP
|
||
|
It is highly recommended that client libraries do \f[I]not\f[R] activate
|
||
|
this behavior.
|
||
|
.RE
|
||
|
.SH ATTRIBUTES
|
||
|
.PP
|
||
|
When \f[B]bcl_handleSignal(\f[R]\f[I]void\f[R]\f[B])\f[R] is used
|
||
|
properly, bcl(3) is async-signal-safe.
|
||
|
.PP
|
||
|
bcl(3) is \f[I]MT-Unsafe\f[R]: it is unsafe to call any functions from
|
||
|
more than one thread.
|
||
|
.SH PERFORMANCE
|
||
|
.PP
|
||
|
Most bc(1) implementations use \f[B]char\f[R] types to calculate the
|
||
|
value of \f[B]1\f[R] decimal digit at a time, but that can be slow.
|
||
|
bcl(3) does something different.
|
||
|
.PP
|
||
|
It uses large integers to calculate more than \f[B]1\f[R] decimal digit
|
||
|
at a time.
|
||
|
If built in a environment where \f[B]BC_LONG_BIT\f[R] (see the
|
||
|
\f[B]LIMITS\f[R] section) is \f[B]64\f[R], then each integer has
|
||
|
\f[B]9\f[R] decimal digits.
|
||
|
If built in an environment where \f[B]BC_LONG_BIT\f[R] is \f[B]32\f[R]
|
||
|
then each integer has \f[B]4\f[R] decimal digits.
|
||
|
This value (the number of decimal digits per large integer) is called
|
||
|
\f[B]BC_BASE_DIGS\f[R].
|
||
|
.PP
|
||
|
In addition, this bcl(3) uses an even larger integer for overflow
|
||
|
checking.
|
||
|
This integer type depends on the value of \f[B]BC_LONG_BIT\f[R], but is
|
||
|
always at least twice as large as the integer type used to store digits.
|
||
|
.SH LIMITS
|
||
|
.PP
|
||
|
The following are the limits on bcl(3):
|
||
|
.TP
|
||
|
\f[B]BC_LONG_BIT\f[R]
|
||
|
The number of bits in the \f[B]long\f[R] type in the environment where
|
||
|
bcl(3) was built.
|
||
|
This determines how many decimal digits can be stored in a single large
|
||
|
integer (see the \f[B]PERFORMANCE\f[R] section).
|
||
|
.TP
|
||
|
\f[B]BC_BASE_DIGS\f[R]
|
||
|
The number of decimal digits per large integer (see the
|
||
|
\f[B]PERFORMANCE\f[R] section).
|
||
|
Depends on \f[B]BC_LONG_BIT\f[R].
|
||
|
.TP
|
||
|
\f[B]BC_BASE_POW\f[R]
|
||
|
The max decimal number that each large integer can store (see
|
||
|
\f[B]BC_BASE_DIGS\f[R]) plus \f[B]1\f[R].
|
||
|
Depends on \f[B]BC_BASE_DIGS\f[R].
|
||
|
.TP
|
||
|
\f[B]BC_OVERFLOW_MAX\f[R]
|
||
|
The max number that the overflow type (see the \f[B]PERFORMANCE\f[R]
|
||
|
section) can hold.
|
||
|
Depends on \f[B]BC_LONG_BIT\f[R].
|
||
|
.TP
|
||
|
\f[B]BC_BASE_MAX\f[R]
|
||
|
The maximum output base.
|
||
|
Set at \f[B]BC_BASE_POW\f[R].
|
||
|
.TP
|
||
|
\f[B]BC_SCALE_MAX\f[R]
|
||
|
The maximum \f[B]scale\f[R].
|
||
|
Set at \f[B]BC_OVERFLOW_MAX-1\f[R].
|
||
|
.TP
|
||
|
\f[B]BC_NUM_MAX\f[R]
|
||
|
The maximum length of a number (in decimal digits), which includes
|
||
|
digits after the decimal point.
|
||
|
Set at \f[B]BC_OVERFLOW_MAX-1\f[R].
|
||
|
.TP
|
||
|
\f[B]BC_RAND_MAX\f[R]
|
||
|
The maximum integer (inclusive) returned by the \f[B]bcl_rand_int()\f[R]
|
||
|
function.
|
||
|
Set at \f[B]2\[ha]BC_LONG_BIT-1\f[R].
|
||
|
.TP
|
||
|
Exponent
|
||
|
The maximum allowable exponent (positive or negative).
|
||
|
Set at \f[B]BC_OVERFLOW_MAX\f[R].
|
||
|
.PP
|
||
|
These limits are meant to be effectively non-existent; the limits are so
|
||
|
large (at least on 64-bit machines) that there should not be any point
|
||
|
at which they become a problem.
|
||
|
In fact, memory should be exhausted before these limits should be hit.
|
||
|
.SH SIGNAL HANDLING
|
||
|
.PP
|
||
|
If a signal handler calls
|
||
|
\f[B]bcl_handleSignal(\f[R]\f[I]void\f[R]\f[B])\f[R] from the same
|
||
|
thread that there are bcl(3) functions executing in, it will cause all
|
||
|
execution to stop as soon as possible, interrupting long-running
|
||
|
calculations, if necessary and cause the function that was executing to
|
||
|
return.
|
||
|
If possible, the error code \f[B]BC_ERROR_SIGNAL\f[R] is returned.
|
||
|
.PP
|
||
|
If execution \f[I]is\f[R] interrupted,
|
||
|
\f[B]bcl_handleSignal(\f[R]\f[I]void\f[R]\f[B])\f[R] does \f[I]not\f[R]
|
||
|
return to its caller.
|
||
|
.PP
|
||
|
It is undefined behavior if
|
||
|
\f[B]bcl_handleSignal(\f[R]\f[I]void\f[R]\f[B])\f[R] is called from a
|
||
|
thread that is not executing bcl(3) functions, if bcl(3) functions are
|
||
|
executing.
|
||
|
.SH SEE ALSO
|
||
|
.PP
|
||
|
bc(1) and dc(1)
|
||
|
.SH STANDARDS
|
||
|
.PP
|
||
|
bcl(3) is compliant with the arithmetic defined in the IEEE Std
|
||
|
1003.1-2017
|
||
|
(\[lq]POSIX.1-2017\[rq]) (https://pubs.opengroup.org/onlinepubs/9699919799/utilities/bc.html)
|
||
|
specification for bc(1).
|
||
|
.PP
|
||
|
Note that the specification explicitly says that bc(1) only accepts
|
||
|
numbers that use a period (\f[B].\f[R]) as a radix point, regardless of
|
||
|
the value of \f[B]LC_NUMERIC\f[R].
|
||
|
This is also true of bcl(3).
|
||
|
.SH BUGS
|
||
|
.PP
|
||
|
None are known.
|
||
|
Report bugs at https://git.yzena.com/gavin/bc.
|
||
|
.SH AUTHORS
|
||
|
.PP
|
||
|
Gavin D.
|
||
|
Howard <gavin@yzena.com> and contributors.
|