mirror of
https://github.com/Mikaela/Limnoria.git
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164 lines
4.8 KiB
Python
164 lines
4.8 KiB
Python
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"""Utilities for handling IEEE 754 floating point special values
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This python module implements constants and functions for working with
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IEEE754 double-precision special values. It provides constants for
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Not-a-Number (NaN), Positive Infinity (PosInf), and Negative Infinity
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(NegInf), as well as functions to test for these values.
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The code is implemented in pure python by taking advantage of the
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'struct' standard module. Care has been taken to generate proper
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results on both big-endian and little-endian machines. Some efficiency
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could be gained by translating the core routines into C.
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See <http://babbage.cs.qc.edu/courses/cs341/IEEE-754references.html>
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for reference material on the IEEE 754 floating point standard.
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Further information on this package is available at
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<http://www.analytics.washington.edu/statcomp/projects/rzope/fpconst/>.
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Author: Gregory R. Warnes <gregory_r_warnes@groton.pfizer.com>
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Date:: 2003-04-08
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Copyright: (c) 2003, Pfizer, Inc.
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"""
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__version__ = "0.7.0"
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ident = "$Id$"
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import struct, operator
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# check endianess
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_big_endian = struct.pack('i',1)[0] != '\x01'
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# and define appropriate constants
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if(_big_endian):
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NaN = struct.unpack('d', '\x7F\xF8\x00\x00\x00\x00\x00\x00')[0]
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PosInf = struct.unpack('d', '\x7F\xF0\x00\x00\x00\x00\x00\x00')[0]
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NegInf = -PosInf
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else:
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NaN = struct.unpack('d', '\x00\x00\x00\x00\x00\x00\xf8\xff')[0]
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PosInf = struct.unpack('d', '\x00\x00\x00\x00\x00\x00\xf0\x7f')[0]
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NegInf = -PosInf
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def _double_as_bytes(dval):
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"Use struct.unpack to decode a double precision float into eight bytes"
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tmp = list(struct.unpack('8B',struct.pack('d', dval)))
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if not _big_endian:
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tmp.reverse()
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return tmp
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##
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## Functions to extract components of the IEEE 754 floating point format
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##
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def _sign(dval):
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"Extract the sign bit from a double-precision floating point value"
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bb = _double_as_bytes(dval)
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return bb[0] >> 7 & 0x01
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def _exponent(dval):
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"""Extract the exponentent bits from a double-precision floating
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point value.
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Note that for normalized values, the exponent bits have an offset
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of 1023. As a consequence, the actual exponentent is obtained
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by subtracting 1023 from the value returned by this function
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"""
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bb = _double_as_bytes(dval)
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return (bb[0] << 4 | bb[1] >> 4) & 0x7ff
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def _mantissa(dval):
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"""Extract the _mantissa bits from a double-precision floating
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point value."""
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bb = _double_as_bytes(dval)
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mantissa = bb[1] & 0x0f << 48
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mantissa += bb[2] << 40
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mantissa += bb[3] << 32
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mantissa += bb[4]
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return mantissa
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def _zero_mantissa(dval):
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"""Determine whether the mantissa bits of the given double are all
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zero."""
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bb = _double_as_bytes(dval)
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return ((bb[1] & 0x0f) | reduce(operator.or_, bb[2:])) == 0
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##
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## Functions to test for IEEE 754 special values
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##
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def isNaN(value):
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"Determine if the argument is a IEEE 754 NaN (Not a Number) value."
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return (_exponent(value)==0x7ff and not _zero_mantissa(value))
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def isInf(value):
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"""Determine if the argument is an infinite IEEE 754 value (positive
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or negative inifinity)"""
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return (_exponent(value)==0x7ff and _zero_mantissa(value))
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def isFinite(value):
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"""Determine if the argument is an finite IEEE 754 value (i.e., is
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not NaN, positive or negative inifinity)"""
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return (_exponent(value)!=0x7ff)
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def isPosInf(value):
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"Determine if the argument is a IEEE 754 positive infinity value"
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return (_sign(value)==0 and _exponent(value)==0x7ff and \
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_zero_mantissa(value))
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def isNegInf(value):
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"Determine if the argument is a IEEE 754 negative infinity value"
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return (_sign(value)==1 and _exponent(value)==0x7ff and \
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_zero_mantissa(value))
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##
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## Functions to test public functions.
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##
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def test_isNaN():
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assert( not isNaN(PosInf) )
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assert( not isNaN(NegInf) )
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assert( isNaN(NaN ) )
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assert( not isNaN( 1.0) )
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assert( not isNaN( -1.0) )
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def test_isInf():
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assert( isInf(PosInf) )
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assert( isInf(NegInf) )
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assert( not isInf(NaN ) )
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assert( not isInf( 1.0) )
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assert( not isInf( -1.0) )
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def test_isFinite():
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assert( not isFinite(PosInf) )
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assert( not isFinite(NegInf) )
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assert( not isFinite(NaN ) )
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assert( isFinite( 1.0) )
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assert( isFinite( -1.0) )
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def test_isPosInf():
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assert( isPosInf(PosInf) )
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assert( not isPosInf(NegInf) )
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assert( not isPosInf(NaN ) )
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assert( not isPosInf( 1.0) )
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assert( not isPosInf( -1.0) )
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def test_isNegInf():
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assert( not isNegInf(PosInf) )
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assert( isNegInf(NegInf) )
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assert( not isNegInf(NaN ) )
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assert( not isNegInf( 1.0) )
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assert( not isNegInf( -1.0) )
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# overall test
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def test():
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test_isNaN()
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test_isInf()
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test_isFinite()
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test_isPosInf()
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test_isNegInf()
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if __name__ == "__main__":
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test()
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