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|
.file "coshf.s"
// Copyright (c) 2000 - 2002, Intel Corporation
// All rights reserved.
//
// Contributed 2000 by the Intel Numerics Group, Intel Corporation
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are
// met:
//
// * Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
//
// * Redistributions in binary form must reproduce the above copyright
// notice, this list of conditions and the following disclaimer in the
// documentation and/or other materials provided with the distribution.
//
// * The name of Intel Corporation may not be used to endorse or promote
// products derived from this software without specific prior written
// permission.
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL INTEL OR ITS
// CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
// EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
// PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
// PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY
// OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY OR TORT (INCLUDING
// NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
// SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
//
// Intel Corporation is the author of this code, and requests that all
// problem reports or change requests be submitted to it directly at
// http://www.intel.com/software/products/opensource/libraries/num.htm.
// History
//*********************************************************************
// 02/02/00 Initial version
// 02/16/00 The error tag for coshf overflow changed to 65 (from 64).
// 04/04/00 Unwind support added
// 08/15/00 Bundle added after call to __libm_error_support to properly
// set [the previously overwritten] GR_Parameter_RESULT.
// 05/07/01 Reworked to improve speed of all paths
// 05/20/02 Cleaned up namespace and sf0 syntax
// 11/15/02 Improved algorithm based on expf
//
// API
//*********************************************************************
// float coshf(float)
//
// Overview of operation
//*********************************************************************
// Case 1: 0 < |x| < 0.25
// Evaluate cosh(x) by a 8th order polynomial
// Care is take for the order of multiplication; and A2 is not exactly 1/4!,
// A3 is not exactly 1/6!, etc.
// cosh(x) = 1 + (A1*x^2 + A2*x^4 + A3*x^6 + A4*x^8)
//
// Case 2: 0.25 < |x| < 89.41598
// Algorithm is based on the identity cosh(x) = ( exp(x) + exp(-x) ) / 2.
// The algorithm for exp is described as below. There are a number of
// economies from evaluating both exp(x) and exp(-x). Although we
// are evaluating both quantities, only where the quantities diverge do we
// duplicate the computations. The basic algorithm for exp(x) is described
// below.
//
// Take the input x. w is "how many log2/128 in x?"
// w = x * 64/log2
// NJ = int(w)
// x = NJ*log2/64 + R
// NJ = 64*n + j
// x = n*log2 + (log2/64)*j + R
//
// So, exp(x) = 2^n * 2^(j/64)* exp(R)
//
// T = 2^n * 2^(j/64)
// Construct 2^n
// Get 2^(j/64) table
// actually all the entries of 2^(j/64) table are stored in DP and
// with exponent bits set to 0 -> multiplication on 2^n can be
// performed by doing logical "or" operation with bits presenting 2^n
// exp(R) = 1 + (exp(R) - 1)
// P = exp(R) - 1 approximated by Taylor series of 3rd degree
// P = A3*R^3 + A2*R^2 + R, A3 = 1/6, A2 = 1/2
//
// The final result is reconstructed as follows
// exp(x) = T + T*P
// Special values
//*********************************************************************
// coshf(+0) = 1.0
// coshf(-0) = 1.0
// coshf(+qnan) = +qnan
// coshf(-qnan) = -qnan
// coshf(+snan) = +qnan
// coshf(-snan) = -qnan
// coshf(-inf) = +inf
// coshf(+inf) = +inf
// Overflow and Underflow
//*********************************************************************
// coshf(x) = largest single normal when
// x = 89.41598 = 0x42b2d4fc
//
// There is no underflow.
// Registers used
//*********************************************************************
// Floating Point registers used:
// f8 input, output
// f6,f7, f9 -> f15, f32 -> f45
// General registers used:
// r2, r3, r16 -> r38
// Predicate registers used:
// p6 -> p15
// Assembly macros
//*********************************************************************
// integer registers used
// scratch
rNJ = r2
rNJ_neg = r3
rJ_neg = r16
rN_neg = r17
rSignexp_x = r18
rExp_x = r18
rExp_mask = r19
rExp_bias = r20
rAd1 = r21
rAd2 = r22
rJ = r23
rN = r24
rTblAddr = r25
rA3 = r26
rExpHalf = r27
rLn2Div64 = r28
rGt_ln = r29
r17ones_m1 = r29
rRightShifter = r30
rJ_mask = r30
r64DivLn2 = r31
rN_mask = r31
// stacked
GR_SAVE_PFS = r32
GR_SAVE_B0 = r33
GR_SAVE_GP = r34
GR_Parameter_X = r35
GR_Parameter_Y = r36
GR_Parameter_RESULT = r37
GR_Parameter_TAG = r38
// floating point registers used
FR_X = f10
FR_Y = f1
FR_RESULT = f8
// scratch
fRightShifter = f6
f64DivLn2 = f7
fNormX = f9
fNint = f10
fN = f11
fR = f12
fLn2Div64 = f13
fA2 = f14
fA3 = f15
// stacked
fP = f32
fT = f33
fMIN_SGL_OFLOW_ARG = f34
fMAX_SGL_NORM_ARG = f35
fRSqr = f36
fA1 = f37
fA21 = f37
fA4 = f38
fA43 = f38
fA4321 = f38
fX4 = f39
fTmp = f39
fGt_pln = f39
fWre_urm_f8 = f40
fXsq = f40
fP_neg = f41
fT_neg = f42
fExp = f43
fExp_neg = f44
fAbsX = f45
RODATA
.align 16
LOCAL_OBJECT_START(_coshf_table)
data4 0x42b2d4fd // Smallest single arg to overflow single result
data4 0x42b2d4fc // Largest single arg to give normal single result
data4 0x00000000 // pad
data4 0x00000000 // pad
//
// 2^(j/64) table, j goes from 0 to 63
data8 0x0000000000000000 // 2^(0/64)
data8 0x00002C9A3E778061 // 2^(1/64)
data8 0x000059B0D3158574 // 2^(2/64)
data8 0x0000874518759BC8 // 2^(3/64)
data8 0x0000B5586CF9890F // 2^(4/64)
data8 0x0000E3EC32D3D1A2 // 2^(5/64)
data8 0x00011301D0125B51 // 2^(6/64)
data8 0x0001429AAEA92DE0 // 2^(7/64)
data8 0x000172B83C7D517B // 2^(8/64)
data8 0x0001A35BEB6FCB75 // 2^(9/64)
data8 0x0001D4873168B9AA // 2^(10/64)
data8 0x0002063B88628CD6 // 2^(11/64)
data8 0x0002387A6E756238 // 2^(12/64)
data8 0x00026B4565E27CDD // 2^(13/64)
data8 0x00029E9DF51FDEE1 // 2^(14/64)
data8 0x0002D285A6E4030B // 2^(15/64)
data8 0x000306FE0A31B715 // 2^(16/64)
data8 0x00033C08B26416FF // 2^(17/64)
data8 0x000371A7373AA9CB // 2^(18/64)
data8 0x0003A7DB34E59FF7 // 2^(19/64)
data8 0x0003DEA64C123422 // 2^(20/64)
data8 0x0004160A21F72E2A // 2^(21/64)
data8 0x00044E086061892D // 2^(22/64)
data8 0x000486A2B5C13CD0 // 2^(23/64)
data8 0x0004BFDAD5362A27 // 2^(24/64)
data8 0x0004F9B2769D2CA7 // 2^(25/64)
data8 0x0005342B569D4F82 // 2^(26/64)
data8 0x00056F4736B527DA // 2^(27/64)
data8 0x0005AB07DD485429 // 2^(28/64)
data8 0x0005E76F15AD2148 // 2^(29/64)
data8 0x0006247EB03A5585 // 2^(30/64)
data8 0x0006623882552225 // 2^(31/64)
data8 0x0006A09E667F3BCD // 2^(32/64)
data8 0x0006DFB23C651A2F // 2^(33/64)
data8 0x00071F75E8EC5F74 // 2^(34/64)
data8 0x00075FEB564267C9 // 2^(35/64)
data8 0x0007A11473EB0187 // 2^(36/64)
data8 0x0007E2F336CF4E62 // 2^(37/64)
data8 0x00082589994CCE13 // 2^(38/64)
data8 0x000868D99B4492ED // 2^(39/64)
data8 0x0008ACE5422AA0DB // 2^(40/64)
data8 0x0008F1AE99157736 // 2^(41/64)
data8 0x00093737B0CDC5E5 // 2^(42/64)
data8 0x00097D829FDE4E50 // 2^(43/64)
data8 0x0009C49182A3F090 // 2^(44/64)
data8 0x000A0C667B5DE565 // 2^(45/64)
data8 0x000A5503B23E255D // 2^(46/64)
data8 0x000A9E6B5579FDBF // 2^(47/64)
data8 0x000AE89F995AD3AD // 2^(48/64)
data8 0x000B33A2B84F15FB // 2^(49/64)
data8 0x000B7F76F2FB5E47 // 2^(50/64)
data8 0x000BCC1E904BC1D2 // 2^(51/64)
data8 0x000C199BDD85529C // 2^(52/64)
data8 0x000C67F12E57D14B // 2^(53/64)
data8 0x000CB720DCEF9069 // 2^(54/64)
data8 0x000D072D4A07897C // 2^(55/64)
data8 0x000D5818DCFBA487 // 2^(56/64)
data8 0x000DA9E603DB3285 // 2^(57/64)
data8 0x000DFC97337B9B5F // 2^(58/64)
data8 0x000E502EE78B3FF6 // 2^(59/64)
data8 0x000EA4AFA2A490DA // 2^(60/64)
data8 0x000EFA1BEE615A27 // 2^(61/64)
data8 0x000F50765B6E4540 // 2^(62/64)
data8 0x000FA7C1819E90D8 // 2^(63/64)
LOCAL_OBJECT_END(_coshf_table)
LOCAL_OBJECT_START(cosh_p_table)
data8 0x3efa3001dcf5905b // A4
data8 0x3f56c1437543543e // A3
data8 0x3fa5555572601504 // A2
data8 0x3fdfffffffe2f097 // A1
LOCAL_OBJECT_END(cosh_p_table)
.section .text
GLOBAL_IEEE754_ENTRY(coshf)
{ .mlx
getf.exp rSignexp_x = f8 // Must recompute if x unorm
movl r64DivLn2 = 0x40571547652B82FE // 64/ln(2)
}
{ .mlx
addl rTblAddr = @ltoff(_coshf_table),gp
movl rRightShifter = 0x43E8000000000000 // DP Right Shifter
}
;;
{ .mfi
// point to the beginning of the table
ld8 rTblAddr = [rTblAddr]
fclass.m p6, p0 = f8, 0x0b // Test for x=unorm
addl rA3 = 0x3E2AA, r0 // high bits of 1.0/6.0 rounded to SP
}
{ .mfi
nop.m 0
fnorm.s1 fNormX = f8 // normalized x
addl rExpHalf = 0xFFFE, r0 // exponent of 1/2
}
;;
{ .mfi
setf.d f64DivLn2 = r64DivLn2 // load 64/ln(2) to FP reg
fclass.m p15, p0 = f8, 0x1e3 // test for NaT,NaN,Inf
nop.i 0
}
{ .mlx
// load Right Shifter to FP reg
setf.d fRightShifter = rRightShifter
movl rLn2Div64 = 0x3F862E42FEFA39EF // DP ln(2)/64 in GR
}
;;
{ .mfi
mov rExp_mask = 0x1ffff
fcmp.eq.s1 p13, p0 = f0, f8 // test for x = 0.0
shl rA3 = rA3, 12 // 0x3E2AA000, approx to 1.0/6.0 in SP
}
{ .mfb
nop.m 0
nop.f 0
(p6) br.cond.spnt COSH_UNORM // Branch if x=unorm
}
;;
COSH_COMMON:
{ .mfi
setf.exp fA2 = rExpHalf // load A2 to FP reg
nop.f 0
mov rExp_bias = 0xffff
}
{ .mfb
setf.d fLn2Div64 = rLn2Div64 // load ln(2)/64 to FP reg
(p15) fma.s.s0 f8 = f8, f8, f0 // result if x = NaT,NaN,Inf
(p15) br.ret.spnt b0 // exit here if x = NaT,NaN,Inf
}
;;
{ .mfi
// min overflow and max normal threshold
ldfps fMIN_SGL_OFLOW_ARG, fMAX_SGL_NORM_ARG = [rTblAddr], 8
nop.f 0
and rExp_x = rExp_mask, rSignexp_x // Biased exponent of x
}
{ .mfb
setf.s fA3 = rA3 // load A3 to FP reg
(p13) fma.s.s0 f8 = f1, f1, f0 // result if x = 0.0
(p13) br.ret.spnt b0 // exit here if x =0.0
}
;;
{ .mfi
sub rExp_x = rExp_x, rExp_bias // True exponent of x
fmerge.s fAbsX = f0, fNormX // Form |x|
nop.i 0
}
;;
{ .mfi
nop.m 0
// x*(64/ln(2)) + Right Shifter
fma.s1 fNint = fNormX, f64DivLn2, fRightShifter
add rTblAddr = 8, rTblAddr
}
{ .mfb
cmp.gt p7, p0 = -2, rExp_x // Test |x| < 2^(-2)
fma.s1 fXsq = fNormX, fNormX, f0 // x*x for small path
(p7) br.cond.spnt COSH_SMALL // Branch if 0 < |x| < 2^-2
}
;;
{ .mfi
nop.m 0
// check for overflow
fcmp.ge.s1 p12, p13 = fAbsX, fMIN_SGL_OFLOW_ARG
mov rJ_mask = 0x3f // 6-bit mask for J
}
;;
{ .mfb
nop.m 0
fms.s1 fN = fNint, f1, fRightShifter // n in FP register
// branch out if overflow
(p12) br.cond.spnt COSH_CERTAIN_OVERFLOW
}
;;
{ .mfi
getf.sig rNJ = fNint // bits of n, j
// check for possible overflow
fcmp.gt.s1 p13, p0 = fAbsX, fMAX_SGL_NORM_ARG
nop.i 0
}
;;
{ .mfi
addl rN = 0xFFBF - 63, rNJ // biased and shifted n-1,j
fnma.s1 fR = fLn2Div64, fN, fNormX // R = x - N*ln(2)/64
and rJ = rJ_mask, rNJ // bits of j
}
{ .mfi
sub rNJ_neg = r0, rNJ // bits of n, j for -x
nop.f 0
andcm rN_mask = -1, rJ_mask // 0xff...fc0 to mask N
}
;;
{ .mfi
shladd rJ = rJ, 3, rTblAddr // address in the 2^(j/64) table
nop.f 0
and rN = rN_mask, rN // biased, shifted n-1
}
{ .mfi
addl rN_neg = 0xFFBF - 63, rNJ_neg // -x biased, shifted n-1,j
nop.f 0
and rJ_neg = rJ_mask, rNJ_neg // bits of j for -x
}
;;
{ .mfi
ld8 rJ = [rJ] // Table value
nop.f 0
shl rN = rN, 46 // 2^(n-1) bits in DP format
}
{ .mfi
shladd rJ_neg = rJ_neg, 3, rTblAddr // addr in 2^(j/64) table -x
nop.f 0
and rN_neg = rN_mask, rN_neg // biased, shifted n-1 for -x
}
;;
{ .mfi
ld8 rJ_neg = [rJ_neg] // Table value for -x
nop.f 0
shl rN_neg = rN_neg, 46 // 2^(n-1) bits in DP format for -x
}
;;
{ .mfi
or rN = rN, rJ // bits of 2^n * 2^(j/64) in DP format
nop.f 0
nop.i 0
}
;;
{ .mmf
setf.d fT = rN // 2^(n-1) * 2^(j/64)
or rN_neg = rN_neg, rJ_neg // -x bits of 2^n * 2^(j/64) in DP
fma.s1 fRSqr = fR, fR, f0 // R^2
}
;;
{ .mfi
setf.d fT_neg = rN_neg // 2^(n-1) * 2^(j/64) for -x
fma.s1 fP = fA3, fR, fA2 // A3*R + A2
nop.i 0
}
{ .mfi
nop.m 0
fnma.s1 fP_neg = fA3, fR, fA2 // A3*R + A2 for -x
nop.i 0
}
;;
{ .mfi
nop.m 0
fma.s1 fP = fP, fRSqr, fR // P = (A3*R + A2)*R^2 + R
nop.i 0
}
{ .mfi
nop.m 0
fms.s1 fP_neg = fP_neg, fRSqr, fR // P = (A3*R + A2)*R^2 + R, -x
nop.i 0
}
;;
{ .mfi
nop.m 0
fmpy.s0 fTmp = fLn2Div64, fLn2Div64 // Force inexact
nop.i 0
}
;;
{ .mfi
nop.m 0
fma.s1 fExp = fP, fT, fT // exp(x)/2
nop.i 0
}
{ .mfb
nop.m 0
fma.s1 fExp_neg = fP_neg, fT_neg, fT_neg // exp(-x)/2
// branch out if possible overflow result
(p13) br.cond.spnt COSH_POSSIBLE_OVERFLOW
}
;;
{ .mfb
nop.m 0
// final result in the absence of overflow
fma.s.s0 f8 = fExp, f1, fExp_neg // result = (exp(x)+exp(-x))/2
// exit here in the absence of overflow
br.ret.sptk b0 // Exit main path, 0.25 <= |x| < 89.41598
}
;;
// Here if 0 < |x| < 0.25. Evaluate 8th order polynomial.
COSH_SMALL:
{ .mmi
add rAd1 = 0x200, rTblAddr
add rAd2 = 0x210, rTblAddr
nop.i 0
}
;;
{ .mmi
ldfpd fA4, fA3 = [rAd1]
ldfpd fA2, fA1 = [rAd2]
nop.i 0
}
;;
{ .mfi
nop.m 0
fma.s1 fX4 = fXsq, fXsq, f0
nop.i 0
}
;;
{ .mfi
nop.m 0
fma.s1 fA43 = fXsq, fA4, fA3
nop.i 0
}
{ .mfi
nop.m 0
fma.s1 fA21 = fXsq, fA2, fA1
nop.i 0
}
;;
{ .mfi
nop.m 0
fma.s1 fA4321 = fX4, fA43, fA21
nop.i 0
}
;;
// Dummy multiply to generate inexact
{ .mfi
nop.m 0
fmpy.s0 fTmp = fA4, fA4
nop.i 0
}
{ .mfb
nop.m 0
fma.s.s0 f8 = fA4321, fXsq, f1
br.ret.sptk b0 // Exit if 0 < |x| < 0.25
}
;;
COSH_POSSIBLE_OVERFLOW:
// Here if fMAX_SGL_NORM_ARG < x < fMIN_SGL_OFLOW_ARG
// This cannot happen if input is a single, only if input higher precision.
// Overflow is a possibility, not a certainty.
// Recompute result using status field 2 with user's rounding mode,
// and wre set. If result is larger than largest single, then we have
// overflow
{ .mfi
mov rGt_ln = 0x1007f // Exponent for largest single + 1 ulp
fsetc.s2 0x7F,0x42 // Get user's round mode, set wre
nop.i 0
}
;;
{ .mfi
setf.exp fGt_pln = rGt_ln // Create largest single + 1 ulp
fma.s.s2 fWre_urm_f8 = fP, fT, fT // Result with wre set
nop.i 0
}
;;
{ .mfi
nop.m 0
fsetc.s2 0x7F,0x40 // Turn off wre in sf2
nop.i 0
}
;;
{ .mfi
nop.m 0
fcmp.ge.s1 p6, p0 = fWre_urm_f8, fGt_pln // Test for overflow
nop.i 0
}
;;
{ .mfb
nop.m 0
nop.f 0
(p6) br.cond.spnt COSH_CERTAIN_OVERFLOW // Branch if overflow
}
;;
{ .mfb
nop.m 0
fma.s.s0 f8 = fP, fT, fT
br.ret.sptk b0 // Exit if really no overflow
}
;;
// here if overflow
COSH_CERTAIN_OVERFLOW:
{ .mmi
addl r17ones_m1 = 0x1FFFE, r0
;;
setf.exp fTmp = r17ones_m1
nop.i 0
}
;;
{ .mfi
alloc r32 = ar.pfs, 0, 3, 4, 0 // get some registers
fmerge.s FR_X = f8,f8
nop.i 0
}
{ .mfb
mov GR_Parameter_TAG = 65
fma.s.s0 FR_RESULT = fTmp, fTmp, f0 // Set I,O and +INF result
br.cond.sptk __libm_error_region
}
;;
// Here if x unorm
COSH_UNORM:
{ .mfb
getf.exp rSignexp_x = fNormX // Must recompute if x unorm
fcmp.eq.s0 p6, p0 = f8, f0 // Set D flag
br.cond.sptk COSH_COMMON // Return to main path
}
;;
GLOBAL_IEEE754_END(coshf)
LOCAL_LIBM_ENTRY(__libm_error_region)
.prologue
{ .mfi
add GR_Parameter_Y=-32,sp // Parameter 2 value
nop.f 0
.save ar.pfs,GR_SAVE_PFS
mov GR_SAVE_PFS=ar.pfs // Save ar.pfs
}
{ .mfi
.fframe 64
add sp=-64,sp // Create new stack
nop.f 0
mov GR_SAVE_GP=gp // Save gp
};;
{ .mmi
stfs [GR_Parameter_Y] = FR_Y,16 // Store Parameter 2 on stack
add GR_Parameter_X = 16,sp // Parameter 1 address
.save b0, GR_SAVE_B0
mov GR_SAVE_B0=b0 // Save b0
};;
.body
{ .mfi
stfs [GR_Parameter_X] = FR_X // Store Parameter 1 on stack
nop.f 0
add GR_Parameter_RESULT = 0,GR_Parameter_Y // Parameter 3 address
}
{ .mib
stfs [GR_Parameter_Y] = FR_RESULT // Store Parameter 3 on stack
add GR_Parameter_Y = -16,GR_Parameter_Y
br.call.sptk b0=__libm_error_support# // Call error handling function
};;
{ .mmi
add GR_Parameter_RESULT = 48,sp
nop.m 0
nop.i 0
};;
{ .mmi
ldfs f8 = [GR_Parameter_RESULT] // Get return result off stack
.restore sp
add sp = 64,sp // Restore stack pointer
mov b0 = GR_SAVE_B0 // Restore return address
};;
{ .mib
mov gp = GR_SAVE_GP // Restore gp
mov ar.pfs = GR_SAVE_PFS // Restore ar.pfs
br.ret.sptk b0 // Return
};;
LOCAL_LIBM_END(__libm_error_region)
.type __libm_error_support#,@function
.global __libm_error_support#
|