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337 lines
14 KiB
Text
337 lines
14 KiB
Text
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This directory contains source for a library of binary -> decimal
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and decimal -> binary conversion routines, for single-, double-,
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and extended-precision IEEE binary floating-point arithmetic, and
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other IEEE-like binary floating-point, including "double double",
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as in
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T. J. Dekker, "A Floating-Point Technique for Extending the
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Available Precision", Numer. Math. 18 (1971), pp. 224-242
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and
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"Inside Macintosh: PowerPC Numerics", Addison-Wesley, 1994
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The conversion routines use double-precision floating-point arithmetic
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and, where necessary, high precision integer arithmetic. The routines
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are generalizations of the strtod and dtoa routines described in
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David M. Gay, "Correctly Rounded Binary-Decimal and
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Decimal-Binary Conversions", Numerical Analysis Manuscript
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No. 90-10, Bell Labs, Murray Hill, 1990;
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http://cm.bell-labs.com/cm/cs/what/ampl/REFS/rounding.ps.gz
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(based in part on papers by Clinger and Steele & White: see the
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references in the above paper).
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The present conversion routines should be able to use any of IEEE binary,
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VAX, or IBM-mainframe double-precision arithmetic internally, but I (dmg)
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have so far only had a chance to test them with IEEE double precision
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arithmetic.
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The core conversion routines are strtodg for decimal -> binary conversions
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and gdtoa for binary -> decimal conversions. These routines operate
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on arrays of unsigned 32-bit integers of type ULong, a signed 32-bit
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exponent of type Long, and arithmetic characteristics described in
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struct FPI; FPI, Long, and ULong are defined in gdtoa.h. File arith.h
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is supposed to provide #defines that cause gdtoa.h to define its
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types correctly. File arithchk.c is source for a program that
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generates a suitable arith.h on all systems where I've been able to
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test it.
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The core conversion routines are meant to be called by helper routines
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that know details of the particular binary arithmetic of interest and
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convert. The present directory provides helper routines for 5 variants
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of IEEE binary floating-point arithmetic, each indicated by one or
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two letters:
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f IEEE single precision
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d IEEE double precision
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x IEEE extended precision, as on Intel 80x87
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and software emulations of Motorola 68xxx chips
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that do not pad the way the 68xxx does, but
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only store 80 bits
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xL IEEE extended precision, as on Motorola 68xxx chips
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Q quad precision, as on Sun Sparc chips
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dd double double, pairs of IEEE double numbers
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whose sum is the desired value
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For decimal -> binary conversions, there are three families of
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helper routines: one for round-nearest:
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strtof
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strtod
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strtodd
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strtopd
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strtopf
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strtopx
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strtopxL
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strtopQ
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one with rounding direction specified:
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strtorf
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strtord
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strtordd
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strtorx
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strtorxL
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strtorQ
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and one for computing an interval (at most one bit wide) that contains
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the decimal number:
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strtoIf
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strtoId
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strtoIdd
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strtoIx
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strtoIxL
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strtoIQ
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The latter call strtoIg, which makes one call on strtodg and adjusts
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the result to provide the desired interval. On systems where native
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arithmetic can easily make one-ulp adjustments on values in the
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desired floating-point format, it might be more efficient to use the
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native arithmetic. Routine strtodI is a variant of strtoId that
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illustrates one way to do this for IEEE binary double-precision
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arithmetic -- but whether this is more efficient remains to be seen.
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Functions strtod and strtof have "natural" return types, float and
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double -- strtod is specified by the C standard, and strtof appears
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in the stdlib.h of some systems, such as (at least some) Linux systems.
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The other functions write their results to their final argument(s):
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to the final two argument for the strtoI... (interval) functions,
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and to the final argument for the others (strtop... and strtor...).
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Where possible, these arguments have "natural" return types (double*
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or float*), to permit at least some type checking. In reality, they
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are viewed as arrays of ULong (or, for the "x" functions, UShort)
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values. On systems where long double is the appropriate type, one can
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pass long double* final argument(s) to these routines. The int value
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that these routines return is the return value from the call they make
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on strtodg; see the enum of possible return values in gdtoa.h.
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Source files g_ddfmt.c, misc.c, smisc.c, strtod.c, strtodg.c, and ulp.c
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should use true IEEE double arithmetic (not, e.g., double extended),
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at least for storing (and viewing the bits of) the variables declared
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"double" within them.
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One detail indicated in struct FPI is whether the target binary
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arithmetic departs from the IEEE standard by flushing denormalized
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numbers to 0. On systems that do this, the helper routines for
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conversion to double-double format (when compiled with
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Sudden_Underflow #defined) penalize the bottom of the exponent
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range so that they return a nonzero result only when the least
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significant bit of the less significant member of the pair of
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double values returned can be expressed as a normalized double
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value. An alternative would be to drop to 53-bit precision near
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the bottom of the exponent range. To get correct rounding, this
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would (in general) require two calls on strtodg (one specifying
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126-bit arithmetic, then, if necessary, one specifying 53-bit
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arithmetic).
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By default, the core routine strtodg and strtod set errno to ERANGE
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if the result overflows to +Infinity or underflows to 0. Compile
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these routines with NO_ERRNO #defined to inhibit errno assignments.
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Routine strtod is based on netlib's "dtoa.c from fp", and
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(f = strtod(s,se)) is more efficient for some conversions than, say,
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strtord(s,se,1,&f). Parts of strtod require true IEEE double
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arithmetic with the default rounding mode (round-to-nearest) and, on
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systems with IEEE extended-precision registers, double-precision
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(53-bit) rounding precision. If the machine uses (the equivalent of)
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Intel 80x87 arithmetic, the call
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_control87(PC_53, MCW_PC);
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does this with many compilers. Whether this or another call is
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appropriate depends on the compiler; for this to work, it may be
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necessary to #include "float.h" or another system-dependent header
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file.
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Source file strtodnrp.c gives a strtod that does not require 53-bit
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rounding precision on systems (such as Intel IA32 systems) that may
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suffer double rounding due to use of extended-precision registers.
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For some conversions this variant of strtod is less efficient than the
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one in strtod.c when the latter is run with 53-bit rounding precision.
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The values that the strto* routines return for NaNs are determined by
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gd_qnan.h, which the makefile generates by running the program whose
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source is qnan.c. Note that the rules for distinguishing signaling
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from quiet NaNs are system-dependent. For cross-compilation, you need
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to determine arith.h and gd_qnan.h suitably, e.g., using the
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arithmetic of the target machine.
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C99's hexadecimal floating-point constants are recognized by the
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strto* routines (but this feature has not yet been heavily tested).
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Compiling with NO_HEX_FP #defined disables this feature.
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When compiled with -DINFNAN_CHECK, the strto* routines recognize C99's
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NaN and Infinity syntax. Moreover, unless No_Hex_NaN is #defined, the
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strto* routines also recognize C99's NaN(...) syntax: they accept
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(case insensitively) strings of the form NaN(x), where x is a string
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of hexadecimal digits and spaces; if there is only one string of
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hexadecimal digits, it is taken for the fraction bits of the resulting
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NaN; if there are two or more strings of hexadecimal digits, each
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string is assigned to the next available sequence of 32-bit words of
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fractions bits (starting with the most significant), right-aligned in
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each sequence.
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For binary -> decimal conversions, I've provided just one family
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of helper routines:
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g_ffmt
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g_dfmt
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g_ddfmt
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g_xfmt
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g_xLfmt
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g_Qfmt
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which do a "%g" style conversion either to a specified number of decimal
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places (if their ndig argument is positive), or to the shortest
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decimal string that rounds to the given binary floating-point value
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(if ndig <= 0). They write into a buffer supplied as an argument
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and return either a pointer to the end of the string (a null character)
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in the buffer, if the buffer was long enough, or 0. Other forms of
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conversion are easily done with the help of gdtoa(), such as %e or %f
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style and conversions with direction of rounding specified (so that, if
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desired, the decimal value is either >= or <= the binary value).
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For an example of more general conversions based on dtoa(), see
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netlib's "printf.c from ampl/solvers".
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For double-double -> decimal, g_ddfmt() assumes IEEE-like arithmetic
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of precision max(126, #bits(input)) bits, where #bits(input) is the
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number of mantissa bits needed to represent the sum of the two double
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values in the input.
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The makefile creates a library, gdtoa.a. To use the helper
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routines, a program only needs to include gdtoa.h. All the
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source files for gdtoa.a include a more extensive gdtoaimp.h;
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among other things, gdtoaimp.h has #defines that make "internal"
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names end in _D2A. To make a "system" library, one could modify
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these #defines to make the names start with __.
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Various comments about possible #defines appear in gdtoaimp.h,
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but for most purposes, arith.h should set suitable #defines.
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Systems with preemptive scheduling of multiple threads require some
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manual intervention. On such systems, it's necessary to compile
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dmisc.c, dtoa.c gdota.c, and misc.c with MULTIPLE_THREADS #defined,
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and to provide (or suitably #define) two locks, acquired by
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ACQUIRE_DTOA_LOCK(n) and freed by FREE_DTOA_LOCK(n) for n = 0 or 1.
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(The second lock, accessed in pow5mult, ensures lazy evaluation of
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only one copy of high powers of 5; omitting this lock would introduce
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a small probability of wasting memory, but would otherwise be harmless.)
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Routines that call dtoa or gdtoa directly must also invoke freedtoa(s)
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to free the value s returned by dtoa or gdtoa. It's OK to do so whether
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or not MULTIPLE_THREADS is #defined, and the helper g_*fmt routines
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listed above all do this indirectly (in gfmt_D2A(), which they all call).
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By default, there is a private pool of memory of length 2000 bytes
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for intermediate quantities, and MALLOC (see gdtoaimp.h) is called only
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if the private pool does not suffice. 2000 is large enough that MALLOC
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is called only under very unusual circumstances (decimal -> binary
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conversion of very long strings) for conversions to and from double
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precision. For systems with preemptively scheduled multiple threads
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or for conversions to extended or quad, it may be appropriate to
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#define PRIVATE_MEM nnnn, where nnnn is a suitable value > 2000.
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For extended and quad precisions, -DPRIVATE_MEM=20000 is probably
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plenty even for many digits at the ends of the exponent range.
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Use of the private pool avoids some overhead.
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Directory test provides some test routines. See its README.
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I've also tested this stuff (except double double conversions)
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with Vern Paxson's testbase program: see
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V. Paxson and W. Kahan, "A Program for Testing IEEE Binary-Decimal
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Conversion", manuscript, May 1991,
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ftp://ftp.ee.lbl.gov/testbase-report.ps.Z .
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(The same ftp directory has source for testbase.)
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Some system-dependent additions to CFLAGS in the makefile:
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HU-UX: -Aa -Ae
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OSF (DEC Unix): -ieee_with_no_inexact
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SunOS 4.1x: -DKR_headers -DBad_float_h
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If you want to put this stuff into a shared library and your
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operating system requires export lists for shared libraries,
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the following would be an appropriate export list:
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dtoa
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freedtoa
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g_Qfmt
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g_ddfmt
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g_dfmt
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g_ffmt
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g_xLfmt
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g_xfmt
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gdtoa
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strtoIQ
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strtoId
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strtoIdd
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strtoIf
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strtoIx
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strtoIxL
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strtod
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strtodI
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strtodg
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strtof
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strtopQ
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strtopd
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strtopdd
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strtopf
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strtopx
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strtopxL
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strtorQ
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strtord
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strtordd
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strtorf
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strtorx
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strtorxL
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When time permits, I (dmg) hope to write in more detail about the
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present conversion routines; for now, this README file must suffice.
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Meanwhile, if you wish to write helper functions for other kinds of
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IEEE-like arithmetic, some explanation of struct FPI and the bits
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array may be helpful. Both gdtoa and strtodg operate on a bits array
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described by FPI *fpi. The bits array is of type ULong, a 32-bit
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unsigned integer type. Floating-point numbers have fpi->nbits bits,
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with the least significant 32 bits in bits[0], the next 32 bits in
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bits[1], etc. These numbers are regarded as integers multiplied by
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2^e (i.e., 2 to the power of the exponent e), where e is the second
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argument (be) to gdtoa and is stored in *exp by strtodg. The minimum
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and maximum exponent values fpi->emin and fpi->emax for normalized
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floating-point numbers reflect this arrangement. For example, the
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P754 standard for binary IEEE arithmetic specifies doubles as having
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53 bits, with normalized values of the form 1.xxxxx... times 2^(b-1023),
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with 52 bits (the x's) and the biased exponent b represented explicitly;
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b is an unsigned integer in the range 1 <= b <= 2046 for normalized
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finite doubles, b = 0 for denormals, and b = 2047 for Infinities and NaNs.
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To turn an IEEE double into the representation used by strtodg and gdtoa,
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we multiply 1.xxxx... by 2^52 (to make it an integer) and reduce the
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exponent e = (b-1023) by 52:
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fpi->emin = 1 - 1023 - 52
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fpi->emax = 1046 - 1023 - 52
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In various wrappers for IEEE double, we actually write -53 + 1 rather
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than -52, to emphasize that there are 53 bits including one implicit bit.
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Field fpi->rounding indicates the desired rounding direction, with
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possible values
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FPI_Round_zero = toward 0,
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FPI_Round_near = unbiased rounding -- the IEEE default,
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FPI_Round_up = toward +Infinity, and
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FPI_Round_down = toward -Infinity
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given in gdtoa.h.
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Field fpi->sudden_underflow indicates whether strtodg should return
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denormals or flush them to zero. Normal floating-point numbers have
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bit fpi->nbits in the bits array on. Denormals have it off, with
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exponent = fpi->emin. Strtodg provides distinct return values for normals
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and denormals; see gdtoa.h.
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Compiling g__fmt.c, strtod.c, and strtodg.c with -DUSE_LOCALE causes
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the decimal-point character to be taken from the current locale; otherwise
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it is '.'.
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Please send comments to David M. Gay (dmg at acm dot org, with " at "
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changed at "@" and " dot " changed to ".").
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