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-.file "libm_reduce.s"
-
-
-// Copyright (c) 2000 - 2003, 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
-// 05/13/02 Rescheduled for speed, changed interface to pass
-//          parameters in fp registers
-// 02/10/03 Reordered header: .section, .global, .proc, .align;
-//          used data8 for long double data storage
-//
-//*********************************************************************
-//*********************************************************************
-//
-// Function:   __libm_pi_by_two_reduce(x) return r, c, and N where
-//             x = N * pi/4 + (r+c) , where |r+c| <= pi/4.
-//             This function is not designed to be used by the
-//             general user.
-//
-//*********************************************************************
-//
-// Accuracy:       Returns double-precision values
-//
-//*********************************************************************
-//
-// Resources Used:
-//
-//    Floating-Point Registers:
-//      f8  = Input x, return value r
-//      f9  = return value c
-//      f32-f70
-//
-//    General Purpose Registers:
-//      r8  = return value N
-//      r34-r64
-//
-//    Predicate Registers:      p6-p14
-//
-//*********************************************************************
-//
-// IEEE Special Conditions:
-//
-//    No condions should be raised.
-//
-//*********************************************************************
-//
-// I. Introduction
-// ===============
-//
-// For the forward trigonometric functions sin, cos, sincos, and
-// tan, the original algorithms for IA 64 handle arguments up to
-// 1 ulp less than 2^63 in magnitude. For double-extended arguments x,
-// |x| >= 2^63, this routine returns N and r_hi, r_lo where
-//
-//    x  is accurately approximated by
-//    2*K*pi  +  N * pi/2  +  r_hi + r_lo,  |r_hi+r_lo| <= pi/4.
-//    CASE = 1 or 2.
-//    CASE is 1 unless |r_hi + r_lo| < 2^(-33).
-//
-// The exact value of K is not determined, but that information is
-// not required in trigonometric function computations.
-//
-// We first assume the argument x in question satisfies x >= 2^(63).
-// In particular, it is positive. Negative x can be handled by symmetry:
-//
-//   -x  is accurately approximated by
-//         -2*K*pi  +  (-N) * pi/2  -  (r_hi + r_lo),  |r_hi+r_lo| <= pi/4.
-//
-// The idea of the reduction is that
-//
-//       x  *  2/pi   =   N_big  +  N  +  f,      |f| <= 1/2
-//
-// Moreover, for double extended x, |f| >= 2^(-75). (This is an
-// non-obvious fact found by enumeration using a special algorithm
-// involving continued fraction.) The algorithm described below
-// calculates N and an accurate approximation of f.
-//
-// Roughly speaking, an appropriate 256-bit (4 X 64) portion of
-// 2/pi is multiplied with x to give the desired information.
-//
-// II. Representation of 2/PI
-// ==========================
-//
-// The value of 2/pi in binary fixed-point is
-//
-//            .101000101111100110......
-//
-// We store 2/pi in a table, starting at the position corresponding
-// to bit position 63
-//
-//   bit position  63 62 ... 0   -1 -2 -3 -4 -5 -6 -7  ....  -16576
-//
-//              0  0  ... 0  . 1  0  1  0  1  0  1  ....    X
-//
-//                              ^
-//                               |__ implied binary pt
-//
-// III. Algorithm
-// ==============
-//
-// This describes the algorithm in the most natural way using
-// unsigned interger multiplication. The implementation section
-// describes how the integer arithmetic is simulated.
-//
-// STEP 0. Initialization
-// ----------------------
-//
-// Let the input argument x be
-//
-//     x = 2^m * ( 1. b_1 b_2 b_3 ... b_63 ),  63 <= m <= 16383.
-//
-// The first crucial step is to fetch four 64-bit portions of 2/pi.
-// To fulfill this goal, we calculate the bit position L of the
-// beginning of these 256-bit quantity by
-//
-//     L :=  62 - m.
-//
-// Note that -16321 <= L <= -1 because 63 <= m <= 16383; and that
-// the storage of 2/pi is adequate.
-//
-// Fetch P_1, P_2, P_3, P_4 beginning at bit position L thus:
-//
-//      bit position  L  L-1  L-2    ...  L-63
-//
-//      P_1    =      b   b    b     ...    b
-//
-// each b can be 0 or 1. Also, let P_0 be the two bits correspoding to
-// bit positions L+2 and L+1. So, when each of the P_j is interpreted
-// with appropriate scaling, we have
-//
-//      2/pi  =  P_big  + P_0 + (P_1 + P_2 + P_3 + P_4)  +  P_small
-//
-// Note that P_big and P_small can be ignored. The reasons are as follow.
-// First, consider P_big. If P_big = 0, we can certainly ignore it.
-// Otherwise, P_big >= 2^(L+3). Now,
-//
-//        P_big * ulp(x) >=  2^(L+3) * 2^(m-63)
-//                   >=  2^(65-m  +  m-63 )
-//                   >=  2^2
-//
-// Thus, P_big * x is an integer of the form 4*K. So
-//
-//       x = 4*K * (pi/2) + x*(P_0 + P_1 + P_2 + P_3 + P_4)*(pi/2)
-//                + x*P_small*(pi/2).
-//
-// Hence, P_big*x corresponds to information that can be ignored for
-// trigonometic function evaluation.
-//
-// Next, we must estimate the effect of ignoring P_small. The absolute
-// error made by ignoring P_small is bounded by
-//
-//       |P_small * x|  <=  ulp(P_4) * x
-//                  <=  2^(L-255) * 2^(m+1)
-//                  <=  2^(62-m-255 + m + 1)
-//                  <=  2^(-192)
-//
-// Since for double-extended precision, x * 2/pi = integer + f,
-// 0.5 >= |f| >= 2^(-75), the relative error introduced by ignoring
-// P_small is bounded by 2^(-192+75) <= 2^(-117), which is acceptable.
-//
-// Further note that if x is split into x_hi + x_lo where x_lo is the
-// two bits corresponding to bit positions 2^(m-62) and 2^(m-63); then
-//
-//       P_0 * x_hi
-//
-// is also an integer of the form 4*K; and thus can also be ignored.
-// Let M := P_0 * x_lo which is a small integer. The main part of the
-// calculation is really the multiplication of x with the four pieces
-// P_1, P_2, P_3, and P_4.
-//
-// Unless the reduced argument is extremely small in magnitude, it
-// suffices to carry out the multiplication of x with P_1, P_2, and
-// P_3. x*P_4 will be carried out and added on as a correction only
-// when it is found to be needed. Note also that x*P_4 need not be
-// computed exactly. A straightforward multiplication suffices since
-// the rounding error thus produced would be bounded by 2^(-3*64),
-// that is 2^(-192) which is small enough as the reduced argument
-// is bounded from below by 2^(-75).
-//
-// Now that we have four 64-bit data representing 2/pi and a
-// 64-bit x. We first need to calculate a highly accurate product
-// of x and P_1, P_2, P_3. This is best understood as integer
-// multiplication.
-//
-//
-// STEP 1. Multiplication
-// ----------------------
-//
-//
-//                     ---------   ---------   ---------
-//                    |  P_1  |   |  P_2  |   |  P_3  |
-//                    ---------   ---------   ---------
-//
-//                                            ---------
-//             X                              |   X   |
-//                                            ---------
-//      ----------------------------------------------------
-//
-//                                 ---------   ---------
-//                               |  A_hi |   |  A_lo |
-//                               ---------   ---------
-//
-//
-//                    ---------   ---------
-//                   |  B_hi |   |  B_lo |
-//                   ---------   ---------
-//
-//
-//        ---------   ---------
-//       |  C_hi |   |  C_lo |
-//       ---------   ---------
-//
-//      ====================================================
-//       ---------   ---------   ---------   ---------
-//       |  S_0  |   |  S_1  |   |  S_2  |   |  S_3  |
-//       ---------   ---------   ---------   ---------
-//
-//
-//
-// STEP 2. Get N and f
-// -------------------
-//
-// Conceptually, after the individual pieces S_0, S_1, ..., are obtained,
-// we have to sum them and obtain an integer part, N, and a fraction, f.
-// Here, |f| <= 1/2, and N is an integer. Note also that N need only to
-// be known to module 2^k, k >= 2. In the case when |f| is small enough,
-// we would need to add in the value x*P_4.
-//
-//
-// STEP 3. Get reduced argument
-// ----------------------------
-//
-// The value f is not yet the reduced argument that we seek. The
-// equation
-//
-//       x * 2/pi = 4K  + N  + f
-//
-// says that
-//
-//         x   =  2*K*pi  + N * pi/2  +  f * (pi/2).
-//
-// Thus, the reduced argument is given by
-//
-//       reduced argument =  f * pi/2.
-//
-// This multiplication must be performed to extra precision.
-//
-// IV. Implementation
-// ==================
-//
-// Step 0. Initialization
-// ----------------------
-//
-// Set sgn_x := sign(x); x := |x|; x_lo := 2 lsb of x.
-//
-// In memory, 2/pi is stored contigously as
-//
-//  0x00000000 0x00000000 0xA2F....
-//                       ^
-//                       |__ implied binary bit
-//
-// Given x = 2^m * 1.xxxx...xxx; we calculate L := 62 - m. Thus
-// -1 <= L <= -16321. We fetch from memory 5 integer pieces of data.
-//
-// P_0 is the two bits corresponding to bit positions L+2 and L+1
-// P_1 is the 64-bit starting at bit position  L
-// P_2 is the 64-bit starting at bit position  L-64
-// P_3 is the 64-bit starting at bit position  L-128
-// P_4 is the 64-bit starting at bit position  L-192
-//
-// For example, if m = 63, P_0 would be 0 and P_1 would look like
-// 0xA2F...
-//
-// If m = 65, P_0 would be the two msb of 0xA, thus, P_0 is 10 in binary.
-// P_1 in binary would be  1 0 0 0 1 0 1 1 1 1 ....
-//
-// Step 1. Multiplication
-// ----------------------
-//
-// At this point, P_1, P_2, P_3, P_4 are integers. They are
-// supposed to be interpreted as
-//
-//  2^(L-63)     * P_1;
-//  2^(L-63-64)  * P_2;
-//  2^(L-63-128) * P_3;
-// 2^(L-63-192) * P_4;
-//
-// Since each of them need to be multiplied to x, we would scale
-// both x and the P_j's by some convenient factors: scale each
-// of P_j's up by 2^(63-L), and scale x down by 2^(L-63).
-//
-//   p_1 := fcvt.xf ( P_1 )
-//   p_2 := fcvt.xf ( P_2 ) * 2^(-64)
-//   p_3 := fcvt.xf ( P_3 ) * 2^(-128)
-//   p_4 := fcvt.xf ( P_4 ) * 2^(-192)
-//   x   := replace exponent of x by -1
-//          because 2^m    * 1.xxxx...xxx  * 2^(L-63)
-//          is      2^(-1) * 1.xxxx...xxx
-//
-// We are now faced with the task of computing the following
-//
-//                     ---------   ---------   ---------
-//                    |  P_1  |   |  P_2  |   |  P_3  |
-//                    ---------   ---------   ---------
-//
-//                                             ---------
-//             X                              |   X   |
-//                                            ---------
-//       ----------------------------------------------------
-//
-//                                 ---------   ---------
-//                                |  A_hi |   |  A_lo |
-//                                ---------   ---------
-//
-//                     ---------   ---------
-//                    |  B_hi |   |  B_lo |
-//                    ---------   ---------
-//
-//         ---------   ---------
-//        |  C_hi |   |  C_lo |
-//        ---------   ---------
-//
-//      ====================================================
-//       -----------   ---------   ---------   ---------
-//       |    S_0  |   |  S_1  |   |  S_2  |   |  S_3  |
-//       -----------   ---------   ---------   ---------
-//        ^          ^
-//        |          |___ binary point
-//        |
-//        |___ possibly one more bit
-//
-// Let FPSR3 be set to round towards zero with widest precision
-// and exponent range. Unless an explicit FPSR is given,
-// round-to-nearest with widest precision and exponent range is
-// used.
-//
-// Define sigma_C := 2^63; sigma_B := 2^(-1); sigma_C := 2^(-65).
-//
-// Tmp_C := fmpy.fpsr3( x, p_1 );
-// If Tmp_C >= sigma_C then
-//    C_hi := Tmp_C;
-//    C_lo := x*p_1 - C_hi ...fma, exact
-// Else
-//    C_hi := fadd.fpsr3(sigma_C, Tmp_C) - sigma_C
-//                   ...subtraction is exact, regardless
-//                   ...of rounding direction
-//    C_lo := x*p_1 - C_hi ...fma, exact
-// End If
-//
-// Tmp_B := fmpy.fpsr3( x, p_2 );
-// If Tmp_B >= sigma_B then
-//    B_hi := Tmp_B;
-//    B_lo := x*p_2 - B_hi ...fma, exact
-// Else
-//    B_hi := fadd.fpsr3(sigma_B, Tmp_B) - sigma_B
-//                   ...subtraction is exact, regardless
-//                   ...of rounding direction
-//    B_lo := x*p_2 - B_hi ...fma, exact
-// End If
-//
-// Tmp_A := fmpy.fpsr3( x, p_3 );
-// If Tmp_A >= sigma_A then
-//    A_hi := Tmp_A;
-//    A_lo := x*p_3 - A_hi ...fma, exact
-// Else
-//    A_hi := fadd.fpsr3(sigma_A, Tmp_A) - sigma_A
-//                   ...subtraction is exact, regardless
-//                   ...of rounding direction
-//    A_lo := x*p_3 - A_hi ...fma, exact
-// End If
-//
-// ...Note that C_hi is of integer value. We need only the
-// ...last few bits. Thus we can ensure C_hi is never a big
-// ...integer, freeing us from overflow worry.
-//
-// Tmp_C := fadd.fpsr3( C_hi, 2^(70) ) - 2^(70);
-// ...Tmp_C is the upper portion of C_hi
-// C_hi := C_hi - Tmp_C
-// ...0 <= C_hi < 2^7
-//
-// Step 2. Get N and f
-// -------------------
-//
-// At this point, we have all the components to obtain
-// S_0, S_1, S_2, S_3 and thus N and f. We start by adding
-// C_lo and B_hi. This sum together with C_hi gives a good
-// estimation of N and f.
-//
-// A := fadd.fpsr3( B_hi, C_lo )
-// B := max( B_hi, C_lo )
-// b := min( B_hi, C_lo )
-//
-// a := (B - A) + b      ...exact. Note that a is either 0
-//                   ...or 2^(-64).
-//
-// N := round_to_nearest_integer_value( A );
-// f := A - N;            ...exact because lsb(A) >= 2^(-64)
-//                   ...and |f| <= 1/2.
-//
-// f := f + a            ...exact because a is 0 or 2^(-64);
-//                   ...the msb of the sum is <= 1/2
-//                   ...lsb >= 2^(-64).
-//
-// N := convert to integer format( C_hi + N );
-// M := P_0 * x_lo;
-// N := N + M;
-//
-// If sgn_x == 1 (that is original x was negative)
-// N := 2^10 - N
-// ...this maintains N to be non-negative, but still
-// ...equivalent to the (negated N) mod 4.
-// End If
-//
-// If |f| >= 2^(-33)
-//
-// ...Case 1
-// CASE := 1
-// g := A_hi + B_lo;
-// s_hi := f + g;
-// s_lo := (f - s_hi) + g;
-//
-// Else
-//
-// ...Case 2
-// CASE := 2
-// A := fadd.fpsr3( A_hi, B_lo )
-// B := max( A_hi, B_lo )
-// b := min( A_hi, B_lo )
-//
-// a := (B - A) + b      ...exact. Note that a is either 0
-//                   ...or 2^(-128).
-//
-// f_hi := A + f;
-// f_lo := (f - f_hi) + A;
-// ...this is exact.
-// ...f-f_hi is exact because either |f| >= |A|, in which
-// ...case f-f_hi is clearly exact; or otherwise, 0<|f|<|A|
-// ...means msb(f) <= msb(A) = 2^(-64) => |f| = 2^(-64).
-// ...If f = 2^(-64), f-f_hi involves cancellation and is
-// ...exact. If f = -2^(-64), then A + f is exact. Hence
-// ...f-f_hi is -A exactly, giving f_lo = 0.
-//
-// f_lo := f_lo + a;
-//
-// If |f| >= 2^(-50) then
-//    s_hi := f_hi;
-//    s_lo := f_lo;
-// Else
-//    f_lo := (f_lo + A_lo) + x*p_4
-//    s_hi := f_hi + f_lo
-//    s_lo := (f_hi - s_hi) + f_lo
-// End If
-//
-// End If
-//
-// Step 3. Get reduced argument
-// ----------------------------
-//
-// If sgn_x == 0 (that is original x is positive)
-//
-// D_hi := Pi_by_2_hi
-// D_lo := Pi_by_2_lo
-// ...load from table
-//
-// Else
-//
-// D_hi := neg_Pi_by_2_hi
-// D_lo := neg_Pi_by_2_lo
-// ...load from table
-// End If
-//
-// r_hi :=  s_hi*D_hi
-// r_lo :=  s_hi*D_hi - r_hi         ...fma
-// r_lo := (s_hi*D_lo + r_lo) + s_lo*D_hi
-//
-// Return  N, r_hi, r_lo
-//
-FR_input_X = f8
-FR_r_hi    = f8
-FR_r_lo    = f9
-
-FR_X       = f32
-FR_N       = f33
-FR_p_1     = f34
-FR_TWOM33  = f35
-FR_TWOM50  = f36
-FR_g       = f37
-FR_p_2     = f38
-FR_f       = f39
-FR_s_lo    = f40
-FR_p_3     = f41
-FR_f_abs   = f42
-FR_D_lo    = f43
-FR_p_4     = f44
-FR_D_hi    = f45
-FR_Tmp2_C  = f46
-FR_s_hi    = f47
-FR_sigma_A = f48
-FR_A       = f49
-FR_sigma_B = f50
-FR_B       = f51
-FR_sigma_C = f52
-FR_b       = f53
-FR_ScaleP2 = f54
-FR_ScaleP3 = f55
-FR_ScaleP4 = f56
-FR_Tmp_A   = f57
-FR_Tmp_B   = f58
-FR_Tmp_C   = f59
-FR_A_hi    = f60
-FR_f_hi    = f61
-FR_RSHF    = f62
-FR_A_lo    = f63
-FR_B_hi    = f64
-FR_a       = f65
-FR_B_lo    = f66
-FR_f_lo    = f67
-FR_N_fix   = f68
-FR_C_hi    = f69
-FR_C_lo    = f70
-
-GR_N       = r8
-GR_Exp_x   = r36
-GR_Temp    = r37
-GR_BIASL63 = r38
-GR_CASE    = r39
-GR_x_lo    = r40
-GR_sgn_x   = r41
-GR_M       = r42
-GR_BASE    = r43
-GR_LENGTH1 = r44
-GR_LENGTH2 = r45
-GR_ASUB    = r46
-GR_P_0     = r47
-GR_P_1     = r48
-GR_P_2     = r49
-GR_P_3     = r50
-GR_P_4     = r51
-GR_START   = r52
-GR_SEGMENT = r53
-GR_A       = r54
-GR_B       = r55
-GR_C       = r56
-GR_D       = r57
-GR_E       = r58
-GR_TEMP1   = r59
-GR_TEMP2   = r60
-GR_TEMP3   = r61
-GR_TEMP4   = r62
-GR_TEMP5   = r63
-GR_TEMP6   = r64
-GR_rshf    = r64
-
-RODATA
-.align 64
-
-LOCAL_OBJECT_START(Constants_Bits_of_2_by_pi)
-data8 0x0000000000000000,0xA2F9836E4E441529
-data8 0xFC2757D1F534DDC0,0xDB6295993C439041
-data8 0xFE5163ABDEBBC561,0xB7246E3A424DD2E0
-data8 0x06492EEA09D1921C,0xFE1DEB1CB129A73E
-data8 0xE88235F52EBB4484,0xE99C7026B45F7E41
-data8 0x3991D639835339F4,0x9C845F8BBDF9283B
-data8 0x1FF897FFDE05980F,0xEF2F118B5A0A6D1F
-data8 0x6D367ECF27CB09B7,0x4F463F669E5FEA2D
-data8 0x7527BAC7EBE5F17B,0x3D0739F78A5292EA
-data8 0x6BFB5FB11F8D5D08,0x56033046FC7B6BAB
-data8 0xF0CFBC209AF4361D,0xA9E391615EE61B08
-data8 0x6599855F14A06840,0x8DFFD8804D732731
-data8 0x06061556CA73A8C9,0x60E27BC08C6B47C4
-data8 0x19C367CDDCE8092A,0x8359C4768B961CA6
-data8 0xDDAF44D15719053E,0xA5FF07053F7E33E8
-data8 0x32C2DE4F98327DBB,0xC33D26EF6B1E5EF8
-data8 0x9F3A1F35CAF27F1D,0x87F121907C7C246A
-data8 0xFA6ED5772D30433B,0x15C614B59D19C3C2
-data8 0xC4AD414D2C5D000C,0x467D862D71E39AC6
-data8 0x9B0062337CD2B497,0xA7B4D55537F63ED7
-data8 0x1810A3FC764D2A9D,0x64ABD770F87C6357
-data8 0xB07AE715175649C0,0xD9D63B3884A7CB23
-data8 0x24778AD623545AB9,0x1F001B0AF1DFCE19
-data8 0xFF319F6A1E666157,0x9947FBACD87F7EB7
-data8 0x652289E83260BFE6,0xCDC4EF09366CD43F
-data8 0x5DD7DE16DE3B5892,0x9BDE2822D2E88628
-data8 0x4D58E232CAC616E3,0x08CB7DE050C017A7
-data8 0x1DF35BE01834132E,0x6212830148835B8E
-data8 0xF57FB0ADF2E91E43,0x4A48D36710D8DDAA
-data8 0x425FAECE616AA428,0x0AB499D3F2A6067F
-data8 0x775C83C2A3883C61,0x78738A5A8CAFBDD7
-data8 0x6F63A62DCBBFF4EF,0x818D67C12645CA55
-data8 0x36D9CAD2A8288D61,0xC277C9121426049B
-data8 0x4612C459C444C5C8,0x91B24DF31700AD43
-data8 0xD4E5492910D5FDFC,0xBE00CC941EEECE70
-data8 0xF53E1380F1ECC3E7,0xB328F8C79405933E
-data8 0x71C1B3092EF3450B,0x9C12887B20AB9FB5
-data8 0x2EC292472F327B6D,0x550C90A7721FE76B
-data8 0x96CB314A1679E279,0x4189DFF49794E884
-data8 0xE6E29731996BED88,0x365F5F0EFDBBB49A
-data8 0x486CA46742727132,0x5D8DB8159F09E5BC
-data8 0x25318D3974F71C05,0x30010C0D68084B58
-data8 0xEE2C90AA4702E774,0x24D6BDA67DF77248
-data8 0x6EEF169FA6948EF6,0x91B45153D1F20ACF
-data8 0x3398207E4BF56863,0xB25F3EDD035D407F
-data8 0x8985295255C06437,0x10D86D324832754C
-data8 0x5BD4714E6E5445C1,0x090B69F52AD56614
-data8 0x9D072750045DDB3B,0xB4C576EA17F9877D
-data8 0x6B49BA271D296996,0xACCCC65414AD6AE2
-data8 0x9089D98850722CBE,0xA4049407777030F3
-data8 0x27FC00A871EA49C2,0x663DE06483DD9797
-data8 0x3FA3FD94438C860D,0xDE41319D39928C70
-data8 0xDDE7B7173BDF082B,0x3715A0805C93805A
-data8 0x921110D8E80FAF80,0x6C4BFFDB0F903876
-data8 0x185915A562BBCB61,0xB989C7BD401004F2
-data8 0xD2277549F6B6EBBB,0x22DBAA140A2F2689
-data8 0x768364333B091A94,0x0EAA3A51C2A31DAE
-data8 0xEDAF12265C4DC26D,0x9C7A2D9756C0833F
-data8 0x03F6F0098C402B99,0x316D07B43915200C
-data8 0x5BC3D8C492F54BAD,0xC6A5CA4ECD37A736
-data8 0xA9E69492AB6842DD,0xDE6319EF8C76528B
-data8 0x6837DBFCABA1AE31,0x15DFA1AE00DAFB0C
-data8 0x664D64B705ED3065,0x29BF56573AFF47B9
-data8 0xF96AF3BE75DF9328,0x3080ABF68C6615CB
-data8 0x040622FA1DE4D9A4,0xB33D8F1B5709CD36
-data8 0xE9424EA4BE13B523,0x331AAAF0A8654FA5
-data8 0xC1D20F3F0BCD785B,0x76F923048B7B7217
-data8 0x8953A6C6E26E6F00,0xEBEF584A9BB7DAC4
-data8 0xBA66AACFCF761D02,0xD12DF1B1C1998C77
-data8 0xADC3DA4886A05DF7,0xF480C62FF0AC9AEC
-data8 0xDDBC5C3F6DDED01F,0xC790B6DB2A3A25A3
-data8 0x9AAF009353AD0457,0xB6B42D297E804BA7
-data8 0x07DA0EAA76A1597B,0x2A12162DB7DCFDE5
-data8 0xFAFEDB89FDBE896C,0x76E4FCA90670803E
-data8 0x156E85FF87FD073E,0x2833676186182AEA
-data8 0xBD4DAFE7B36E6D8F,0x3967955BBF3148D7
-data8 0x8416DF30432DC735,0x6125CE70C9B8CB30
-data8 0xFD6CBFA200A4E46C,0x05A0DD5A476F21D2
-data8 0x1262845CB9496170,0xE0566B0152993755
-data8 0x50B7D51EC4F1335F,0x6E13E4305DA92E85
-data8 0xC3B21D3632A1A4B7,0x08D4B1EA21F716E4
-data8 0x698F77FF2780030C,0x2D408DA0CD4F99A5
-data8 0x20D3A2B30A5D2F42,0xF9B4CBDA11D0BE7D
-data8 0xC1DB9BBD17AB81A2,0xCA5C6A0817552E55
-data8 0x0027F0147F8607E1,0x640B148D4196DEBE
-data8 0x872AFDDAB6256B34,0x897BFEF3059EBFB9
-data8 0x4F6A68A82A4A5AC4,0x4FBCF82D985AD795
-data8 0xC7F48D4D0DA63A20,0x5F57A4B13F149538
-data8 0x800120CC86DD71B6,0xDEC9F560BF11654D
-data8 0x6B0701ACB08CD0C0,0xB24855510EFB1EC3
-data8 0x72953B06A33540C0,0x7BDC06CC45E0FA29
-data8 0x4EC8CAD641F3E8DE,0x647CD8649B31BED9
-data8 0xC397A4D45877C5E3,0x6913DAF03C3ABA46
-data8 0x18465F7555F5BDD2,0xC6926E5D2EACED44
-data8 0x0E423E1C87C461E9,0xFD29F3D6E7CA7C22
-data8 0x35916FC5E0088DD7,0xFFE26A6EC6FDB0C1
-data8 0x0893745D7CB2AD6B,0x9D6ECD7B723E6A11
-data8 0xC6A9CFF7DF7329BA,0xC9B55100B70DB2E2
-data8 0x24BA74607DE58AD8,0x742C150D0C188194
-data8 0x667E162901767A9F,0xBEFDFDEF4556367E
-data8 0xD913D9ECB9BA8BFC,0x97C427A831C36EF1
-data8 0x36C59456A8D8B5A8,0xB40ECCCF2D891234
-data8 0x576F89562CE3CE99,0xB920D6AA5E6B9C2A
-data8 0x3ECC5F114A0BFDFB,0xF4E16D3B8E2C86E2
-data8 0x84D4E9A9B4FCD1EE,0xEFC9352E61392F44
-data8 0x2138C8D91B0AFC81,0x6A4AFBD81C2F84B4
-data8 0x538C994ECC2254DC,0x552AD6C6C096190B
-data8 0xB8701A649569605A,0x26EE523F0F117F11
-data8 0xB5F4F5CBFC2DBC34,0xEEBC34CC5DE8605E
-data8 0xDD9B8E67EF3392B8,0x17C99B5861BC57E1
-data8 0xC68351103ED84871,0xDDDD1C2DA118AF46
-data8 0x2C21D7F359987AD9,0xC0549EFA864FFC06
-data8 0x56AE79E536228922,0xAD38DC9367AAE855
-data8 0x3826829BE7CAA40D,0x51B133990ED7A948
-data8 0x0569F0B265A7887F,0x974C8836D1F9B392
-data8 0x214A827B21CF98DC,0x9F405547DC3A74E1
-data8 0x42EB67DF9DFE5FD4,0x5EA4677B7AACBAA2
-data8 0xF65523882B55BA41,0x086E59862A218347
-data8 0x39E6E389D49EE540,0xFB49E956FFCA0F1C
-data8 0x8A59C52BFA94C5C1,0xD3CFC50FAE5ADB86
-data8 0xC5476243853B8621,0x94792C8761107B4C
-data8 0x2A1A2C8012BF4390,0x2688893C78E4C4A8
-data8 0x7BDBE5C23AC4EAF4,0x268A67F7BF920D2B
-data8 0xA365B1933D0B7CBD,0xDC51A463DD27DDE1
-data8 0x6919949A9529A828,0xCE68B4ED09209F44
-data8 0xCA984E638270237C,0x7E32B90F8EF5A7E7
-data8 0x561408F1212A9DB5,0x4D7E6F5119A5ABF9
-data8 0xB5D6DF8261DD9602,0x36169F3AC4A1A283
-data8 0x6DED727A8D39A9B8,0x825C326B5B2746ED
-data8 0x34007700D255F4FC,0x4D59018071E0E13F
-data8 0x89B295F364A8F1AE,0xA74B38FC4CEAB2BB
-LOCAL_OBJECT_END(Constants_Bits_of_2_by_pi)
-
-LOCAL_OBJECT_START(Constants_Bits_of_pi_by_2)
-data8 0xC90FDAA22168C234,0x00003FFF
-data8 0xC4C6628B80DC1CD1,0x00003FBF
-LOCAL_OBJECT_END(Constants_Bits_of_pi_by_2)
-
-.section .text
-.global __libm_pi_by_2_reduce#
-.proc __libm_pi_by_2_reduce#
-.align 32
-
-__libm_pi_by_2_reduce:
-
-//    X is in f8
-//    Place the two-piece result r (r_hi) in f8 and c (r_lo) in f9
-//    N is returned in r8
-
-{ .mfi
-      alloc  r34 = ar.pfs,2,34,0,0
-      fsetc.s3 0x00,0x7F     // Set sf3 to round to zero, 82-bit prec, td, ftz
-      nop.i 999
-}
-{ .mfi
-      addl           GR_BASE   = @ltoff(Constants_Bits_of_2_by_pi#), gp
-      nop.f 999
-      mov GR_BIASL63 = 0x1003E
-}
-;;
-
-
-//    L         -1-2-3-4
-//    0 0 0 0 0. 1 0 1 0
-//    M          0 1 2 .... 63, 64 65 ... 127, 128
-//     ---------------------------------------------
-//    Segment 0.        1     ,      2       ,    3
-//    START = M - 63                        M = 128 becomes 65
-//    LENGTH1  = START & 0x3F               65 become position 1
-//    SEGMENT  = shr(START,6) + 1      0 maps to 1,   64 maps to 2,
-//    LENGTH2  = 64 - LENGTH1
-//    Address_BASE = shladd(SEGMENT,3) + BASE
-
-
-{ .mmi
-      getf.exp GR_Exp_x = FR_input_X
-      ld8 GR_BASE = [GR_BASE]
-      mov GR_TEMP5 = 0x0FFFE
-}
-;;
-
-//    Define sigma_C := 2^63; sigma_B := 2^(-1); sigma_A := 2^(-65).
-{ .mmi
-      getf.sig GR_x_lo = FR_input_X
-      mov GR_TEMP6 = 0x0FFBE
-      nop.i 999
-}
-;;
-
-//    Special Code for testing DE arguments
-//          movl GR_BIASL63 = 0x0000000000013FFE
-//          movl GR_x_lo = 0xFFFFFFFFFFFFFFFF
-//          setf.exp FR_X = GR_BIASL63
-//          setf.sig FR_ScaleP3 = GR_x_lo
-//          fmerge.se FR_X = FR_X,FR_ScaleP3
-//    Set sgn_x := sign(x); x := |x|; x_lo := 2 lsb of x.
-//    2/pi is stored contigously as
-//    0x00000000 0x00000000.0xA2F....
-//    M = EXP - BIAS  ( M >= 63)
-//    Given x = 2^m * 1.xxxx...xxx; we calculate L := 62 - m.
-//    Thus -1 <= L <= -16321.
-{ .mmi
-      setf.exp FR_sigma_B = GR_TEMP5
-      setf.exp FR_sigma_A = GR_TEMP6
-      extr.u GR_M = GR_Exp_x,0,17
-}
-;;
-
-{ .mii
-      and  GR_x_lo = 0x03,GR_x_lo
-      sub  GR_START = GR_M,GR_BIASL63
-      add  GR_BASE = 8,GR_BASE           // To effectively add 1 to SEGMENT
-}
-;;
-
-{ .mii
-      and  GR_LENGTH1 = 0x3F,GR_START
-      shr.u  GR_SEGMENT = GR_START,6
-      nop.i 999
-}
-;;
-
-{ .mmi
-      shladd GR_BASE = GR_SEGMENT,3,GR_BASE
-      sub  GR_LENGTH2 = 0x40,GR_LENGTH1
-      cmp.le p6,p7 = 0x2,GR_LENGTH1
-}
-;;
-
-//    P_0 is the two bits corresponding to bit positions L+2 and L+1
-//    P_1 is the 64-bit starting at bit position  L
-//    P_2 is the 64-bit starting at bit position  L-64
-//    P_3 is the 64-bit starting at bit position  L-128
-//    P_4 is the 64-bit starting at bit position  L-192
-//    P_1 is made up of Alo and Bhi
-//    P_1 = deposit Alo, position 0, length2  into P_1,position length1
-//          deposit Bhi, position length2, length1 into P_1, position 0
-//    P_2 is made up of Blo and Chi
-//    P_2 = deposit Blo, position 0, length2  into P_2, position length1
-//          deposit Chi, position length2, length1 into P_2, position 0
-//    P_3 is made up of Clo and Dhi
-//    P_3 = deposit Clo, position 0, length2  into P_3, position length1
-//          deposit Dhi, position length2, length1 into P_3, position 0
-//    P_4 is made up of Clo and Dhi
-//    P_4 = deposit Dlo, position 0, length2  into P_4, position length1
-//          deposit Ehi, position length2, length1 into P_4, position 0
-{ .mfi
-      ld8 GR_A = [GR_BASE],8
-      fabs FR_X = FR_input_X
-(p7)  cmp.eq.unc p8,p9 = 0x1,GR_LENGTH1
-}
-;;
-
-//    ld_64 A at Base and increment Base by 8
-//    ld_64 B at Base and increment Base by 8
-//    ld_64 C at Base and increment Base by 8
-//    ld_64 D at Base and increment Base by 8
-//    ld_64 E at Base and increment Base by 8
-//                                          A/B/C/D
-//                                    ---------------------
-//    A, B, C, D, and E look like    | length1 | length2   |
-//                                    ---------------------
-//                                       hi        lo
-{ .mlx
-      ld8 GR_B = [GR_BASE],8
-      movl GR_rshf = 0x43e8000000000000   // 1.10000 2^63 for right shift N_fix
-}
-;;
-
-{ .mmi
-      ld8 GR_C = [GR_BASE],8
-      nop.m 999
-(p8)  extr.u GR_Temp = GR_A,63,1
-}
-;;
-
-//    If length1 >= 2,
-//       P_0 = deposit Ahi, position length2, 2 bit into P_0 at position 0.
-{ .mii
-      ld8 GR_D = [GR_BASE],8
-      shl GR_TEMP1 = GR_A,GR_LENGTH1   // MM instruction
-(p6)  shr.u GR_P_0 = GR_A,GR_LENGTH2   // MM instruction
-}
-;;
-
-{ .mii
-      ld8 GR_E = [GR_BASE],-40
-      shl GR_TEMP2 = GR_B,GR_LENGTH1   // MM instruction
-      shr.u GR_P_1 = GR_B,GR_LENGTH2   // MM instruction
-}
-;;
-
-//    Else
-//       Load 16 bit of ASUB from (Base_Address_of_A - 2)
-//       P_0 = ASUB & 0x3
-//       If length1 == 0,
-//          P_0 complete
-//       Else
-//          Deposit element 63 from Ahi and place in element 0 of P_0.
-//       Endif
-//    Endif
-
-{ .mii
-(p7)  ld2 GR_ASUB = [GR_BASE],8
-      shl GR_TEMP3 = GR_C,GR_LENGTH1   // MM instruction
-      shr.u GR_P_2 = GR_C,GR_LENGTH2   // MM instruction
-}
-;;
-
-{ .mii
-      setf.d FR_RSHF = GR_rshf         // Form right shift const 1.100 * 2^63
-      shl GR_TEMP4 = GR_D,GR_LENGTH1   // MM instruction
-      shr.u GR_P_3 = GR_D,GR_LENGTH2   // MM instruction
-}
-;;
-
-{ .mmi
-(p7)  and GR_P_0 = 0x03,GR_ASUB
-(p6)  and GR_P_0 = 0x03,GR_P_0
-      shr.u GR_P_4 = GR_E,GR_LENGTH2   // MM instruction
-}
-;;
-
-{ .mmi
-      nop.m 999
-      or GR_P_1 = GR_P_1,GR_TEMP1
-(p8)  and GR_P_0 = 0x1,GR_P_0
-}
-;;
-
-{ .mmi
-      setf.sig FR_p_1 = GR_P_1
-      or GR_P_2 = GR_P_2,GR_TEMP2
-(p8)  shladd GR_P_0 = GR_P_0,1,GR_Temp
-}
-;;
-
-{ .mmf
-      setf.sig FR_p_2 = GR_P_2
-      or GR_P_3 = GR_P_3,GR_TEMP3
-      fmerge.se FR_X = FR_sigma_B,FR_X
-}
-;;
-
-{ .mmi
-      setf.sig FR_p_3 = GR_P_3
-      or GR_P_4 = GR_P_4,GR_TEMP4
-      pmpy2.r GR_M = GR_P_0,GR_x_lo
-}
-;;
-
-//    P_1, P_2, P_3, P_4 are integers. They should be
-//    2^(L-63)     * P_1;
-//    2^(L-63-64)  * P_2;
-//    2^(L-63-128) * P_3;
-//    2^(L-63-192) * P_4;
-//    Since each of them need to be multiplied to x, we would scale
-//    both x and the P_j's by some convenient factors: scale each
-//    of P_j's up by 2^(63-L), and scale x down by 2^(L-63).
-//    p_1 := fcvt.xf ( P_1 )
-//    p_2 := fcvt.xf ( P_2 ) * 2^(-64)
-//    p_3 := fcvt.xf ( P_3 ) * 2^(-128)
-//    p_4 := fcvt.xf ( P_4 ) * 2^(-192)
-//    x= Set x's exp to -1 because 2^m*1.x...x *2^(L-63)=2^(-1)*1.x...xxx
-//             ---------   ---------   ---------
-//             |  P_1  |   |  P_2  |   |  P_3  |
-//             ---------   ---------   ---------
-//                                           ---------
-//            X                              |   X   |
-//                                           ---------
-//      ----------------------------------------------------
-//                               ---------   ---------
-//                               |  A_hi |   |  A_lo |
-//                               ---------   ---------
-//                   ---------   ---------
-//                   |  B_hi |   |  B_lo |
-//                   ---------   ---------
-//       ---------   ---------
-//       |  C_hi |   |  C_lo |
-//       ---------   ---------
-//     ====================================================
-//    -----------   ---------   ---------   ---------
-//    |    S_0  |   |  S_1  |   |  S_2  |   |  S_3  |
-//    -----------   ---------   ---------   ---------
-//    |            |___ binary point
-//    |___ possibly one more bit
-//
-//    Let FPSR3 be set to round towards zero with widest precision
-//    and exponent range. Unless an explicit FPSR is given,
-//    round-to-nearest with widest precision and exponent range is
-//    used.
-{ .mmi
-      setf.sig FR_p_4 = GR_P_4
-      mov GR_TEMP1 = 0x0FFBF
-      nop.i 999
-}
-;;
-
-{ .mmi
-      setf.exp FR_ScaleP2 = GR_TEMP1
-      mov GR_TEMP2 = 0x0FF7F
-      nop.i 999
-}
-;;
-
-{ .mmi
-      setf.exp FR_ScaleP3 = GR_TEMP2
-      mov GR_TEMP4 = 0x1003E
-      nop.i 999
-}
-;;
-
-{ .mmf
-      setf.exp FR_sigma_C = GR_TEMP4
-      mov GR_Temp = 0x0FFDE
-      fcvt.xuf.s1 FR_p_1 = FR_p_1
-}
-;;
-
-{ .mfi
-      setf.exp FR_TWOM33 = GR_Temp
-      fcvt.xuf.s1 FR_p_2 = FR_p_2
-      nop.i 999
-}
-;;
-
-{ .mfi
-      nop.m 999
-      fcvt.xuf.s1 FR_p_3 = FR_p_3
-      nop.i 999
-}
-;;
-
-{ .mfi
-      nop.m 999
-      fcvt.xuf.s1 FR_p_4 = FR_p_4
-      nop.i 999
-}
-;;
-
-//    Tmp_C := fmpy.fpsr3( x, p_1 );
-//    Tmp_B := fmpy.fpsr3( x, p_2 );
-//    Tmp_A := fmpy.fpsr3( x, p_3 );
-//    If Tmp_C >= sigma_C then
-//      C_hi := Tmp_C;
-//      C_lo := x*p_1 - C_hi ...fma, exact
-//    Else
-//      C_hi := fadd.fpsr3(sigma_C, Tmp_C) - sigma_C
-//      C_lo := x*p_1 - C_hi ...fma, exact
-//    End If
-//    If Tmp_B >= sigma_B then
-//      B_hi := Tmp_B;
-//      B_lo := x*p_2 - B_hi ...fma, exact
-//    Else
-//      B_hi := fadd.fpsr3(sigma_B, Tmp_B) - sigma_B
-//      B_lo := x*p_2 - B_hi ...fma, exact
-//    End If
-//    If Tmp_A >= sigma_A then
-//      A_hi := Tmp_A;
-//      A_lo := x*p_3 - A_hi ...fma, exact
-//    Else
-//      A_hi := fadd.fpsr3(sigma_A, Tmp_A) - sigma_A
-//      Exact, regardless ...of rounding direction
-//      A_lo := x*p_3 - A_hi ...fma, exact
-//    Endif
-{ .mfi
-      nop.m 999
-      fmpy.s3 FR_Tmp_C = FR_X,FR_p_1
-      nop.i 999
-}
-;;
-
-{ .mfi
-      mov GR_TEMP3 = 0x0FF3F
-      fmpy.s1 FR_p_2 = FR_p_2,FR_ScaleP2
-      nop.i 999
-}
-;;
-
-{ .mmf
-      setf.exp FR_ScaleP4 = GR_TEMP3
-      mov GR_TEMP4 = 0x10045
-      fmpy.s1 FR_p_3 = FR_p_3,FR_ScaleP3
-}
-;;
-
-{ .mfi
-      nop.m 999
-      fadd.s3 FR_C_hi = FR_sigma_C,FR_Tmp_C   // For Tmp_C < sigma_C case
-      nop.i 999
-}
-;;
-
-{ .mmf
-      setf.exp FR_Tmp2_C = GR_TEMP4
-      nop.m 999
-      fmpy.s3 FR_Tmp_B = FR_X,FR_p_2
-}
-;;
-
-{ .mfi
-      addl           GR_BASE   = @ltoff(Constants_Bits_of_pi_by_2#), gp
-      fcmp.ge.s1 p12,  p9 = FR_Tmp_C,FR_sigma_C
-      nop.i 999
-}
-{ .mfi
-      nop.m 999
-      fmpy.s3 FR_Tmp_A = FR_X,FR_p_3
-      nop.i 99
-}
-;;
-
-{ .mfi
-      ld8 GR_BASE = [GR_BASE]
-(p12) mov FR_C_hi = FR_Tmp_C
-      nop.i 999
-}
-{ .mfi
-      nop.m 999
-(p9)  fsub.s1 FR_C_hi = FR_C_hi,FR_sigma_C
-      nop.i 999
-}
-;;
-
-
-
-//   End If
-//   Step 3. Get reduced argument
-//   If sgn_x == 0 (that is original x is positive)
-//      D_hi := Pi_by_2_hi
-//      D_lo := Pi_by_2_lo
-//      Load from table
-//   Else
-//      D_hi := neg_Pi_by_2_hi
-//      D_lo := neg_Pi_by_2_lo
-//      Load from table
-//   End If
-
-{ .mfi
-      nop.m 999
-      fmpy.s1 FR_p_4 = FR_p_4,FR_ScaleP4
-      nop.i 999
-}
-{ .mfi
-      nop.m 999
-      fadd.s3 FR_B_hi = FR_sigma_B,FR_Tmp_B     // For Tmp_B < sigma_B case
-      nop.i 999
-}
-;;
-
-{ .mfi
-      nop.m 999
-      fadd.s3 FR_A_hi = FR_sigma_A,FR_Tmp_A     // For Tmp_A < sigma_A case
-      nop.i 999
-}
-;;
-
-{ .mfi
-      nop.m 999
-      fcmp.ge.s1 p13, p10 = FR_Tmp_B,FR_sigma_B
-      nop.i 999
-}
-{ .mfi
-      nop.m 999
-      fms.s1 FR_C_lo = FR_X,FR_p_1,FR_C_hi
-      nop.i 999
-}
-;;
-
-{ .mfi
-      ldfe FR_D_hi = [GR_BASE],16
-      fcmp.ge.s1 p14, p11 = FR_Tmp_A,FR_sigma_A
-      nop.i 999
-}
-;;
-
-{ .mfi
-      ldfe FR_D_lo = [GR_BASE]
-(p13) mov FR_B_hi = FR_Tmp_B
-      nop.i 999
-}
-{ .mfi
-      nop.m 999
-(p10) fsub.s1 FR_B_hi = FR_B_hi,FR_sigma_B
-      nop.i 999
-}
-;;
-
-{ .mfi
-      nop.m 999
-(p14) mov FR_A_hi = FR_Tmp_A
-      nop.i 999
-}
-{ .mfi
-      nop.m 999
-(p11) fsub.s1 FR_A_hi = FR_A_hi,FR_sigma_A
-      nop.i 999
-}
-;;
-
-//    Note that C_hi is of integer value. We need only the
-//    last few bits. Thus we can ensure C_hi is never a big
-//    integer, freeing us from overflow worry.
-//    Tmp_C := fadd.fpsr3( C_hi, 2^(70) ) - 2^(70);
-//    Tmp_C is the upper portion of C_hi
-{ .mfi
-      nop.m 999
-      fadd.s3 FR_Tmp_C = FR_C_hi,FR_Tmp2_C
-      tbit.z p12,p9 = GR_Exp_x, 17
-}
-;;
-
-{ .mfi
-      nop.m 999
-      fms.s1 FR_B_lo = FR_X,FR_p_2,FR_B_hi
-      nop.i 999
-}
-{ .mfi
-      nop.m 999
-      fadd.s3 FR_A = FR_B_hi,FR_C_lo
-      nop.i 999
-}
-;;
-
-{ .mfi
-      nop.m 999
-      fms.s1 FR_A_lo = FR_X,FR_p_3,FR_A_hi
-      nop.i 999
-}
-;;
-
-{ .mfi
-      nop.m 999
-      fsub.s1 FR_Tmp_C = FR_Tmp_C,FR_Tmp2_C
-      nop.i 999
-}
-;;
-
-//    *******************
-//    Step 2. Get N and f
-//    *******************
-//    We have all the components to obtain
-//    S_0, S_1, S_2, S_3 and thus N and f. We start by adding
-//    C_lo and B_hi. This sum together with C_hi estimates
-//    N and f well.
-//    A := fadd.fpsr3( B_hi, C_lo )
-//    B := max( B_hi, C_lo )
-//    b := min( B_hi, C_lo )
-{ .mfi
-      nop.m 999
-      fmax.s1 FR_B = FR_B_hi,FR_C_lo
-      nop.i 999
-}
-;;
-
-// We use a right-shift trick to get the integer part of A into the rightmost
-// bits of the significand by adding 1.1000..00 * 2^63.  This operation is good
-// if |A| < 2^61, which it is in this case.  We are doing this to save a few
-// cycles over using fcvt.fx followed by fnorm.  The second step of the trick
-// is to subtract the same constant to float the rounded integer into a fp reg.
-
-{ .mfi
-      nop.m 999
-//    N := round_to_nearest_integer_value( A );
-      fma.s1 FR_N_fix = FR_A, f1, FR_RSHF
-      nop.i 999
-}
-;;
-
-{ .mfi
-      nop.m 999
-      fmin.s1 FR_b = FR_B_hi,FR_C_lo
-      nop.i 999
-}
-{ .mfi
-      nop.m 999
-//    C_hi := C_hi - Tmp_C ...0 <= C_hi < 2^7
-      fsub.s1 FR_C_hi = FR_C_hi,FR_Tmp_C
-      nop.i 999
-}
-;;
-
-{ .mfi
-      nop.m 999
-//    a := (B - A) + b: Exact - note that a is either 0 or 2^(-64).
-      fsub.s1 FR_a = FR_B,FR_A
-      nop.i 999
-}
-;;
-
-{ .mfi
-      nop.m 999
-      fms.s1 FR_N = FR_N_fix, f1, FR_RSHF
-      nop.i 999
-}
-;;
-
-{ .mfi
-      nop.m 999
-      fadd.s1 FR_a = FR_a,FR_b
-      nop.i 999
-}
-;;
-
-//    f := A - N; Exact because lsb(A) >= 2^(-64) and |f| <= 1/2.
-//    N := convert to integer format( C_hi + N );
-//    M := P_0 * x_lo;
-//    N := N + M;
-{ .mfi
-      nop.m 999
-      fsub.s1 FR_f = FR_A,FR_N
-      nop.i 999
-}
-{ .mfi
-      nop.m 999
-      fadd.s1 FR_N = FR_N,FR_C_hi
-      nop.i 999
-}
-;;
-
-{ .mfi
-      nop.m 999
-(p9)  fsub.s1 FR_D_hi = f0, FR_D_hi
-      nop.i 999
-}
-{ .mfi
-      nop.m 999
-(p9)  fsub.s1 FR_D_lo = f0, FR_D_lo
-      nop.i 999
-}
-;;
-
-{ .mfi
-      nop.m 999
-      fadd.s1 FR_g = FR_A_hi,FR_B_lo          // For Case 1, g=A_hi+B_lo
-      nop.i 999
-}
-{ .mfi
-      nop.m 999
-      fadd.s3 FR_A = FR_A_hi,FR_B_lo          // For Case 2, A=A_hi+B_lo w/ sf3
-      nop.i 999
-}
-;;
-
-{ .mfi
-      mov GR_Temp = 0x0FFCD                   // For Case 2, exponent of 2^-50
-      fmax.s1 FR_B = FR_A_hi,FR_B_lo          // For Case 2, B=max(A_hi,B_lo)
-      nop.i 999
-}
-;;
-
-//    f = f + a      Exact because a is 0 or 2^(-64);
-//    the msb of the sum is <= 1/2 and lsb >= 2^(-64).
-{ .mfi
-      setf.exp FR_TWOM50 = GR_Temp            // For Case 2, form 2^-50
-      fcvt.fx.s1 FR_N = FR_N
-      nop.i 999
-}
-{ .mfi
-      nop.m 999
-      fadd.s1 FR_f = FR_f,FR_a
-      nop.i 999
-}
-;;
-
-{ .mfi
-      nop.m 999
-      fmin.s1 FR_b = FR_A_hi,FR_B_lo          // For Case 2, b=min(A_hi,B_lo)
-      nop.i 999
-}
-;;
-
-{ .mfi
-      nop.m 999
-      fsub.s1 FR_a = FR_B,FR_A                // For Case 2, a=B-A
-      nop.i 999
-}
-;;
-
-{ .mfi
-      nop.m 999
-      fadd.s1 FR_s_hi = FR_f,FR_g             // For Case 1, s_hi=f+g
-      nop.i 999
-}
-{ .mfi
-      nop.m 999
-      fadd.s1 FR_f_hi = FR_A,FR_f             // For Case 2, f_hi=A+f
-      nop.i 999
-}
-;;
-
-{ .mfi
-      nop.m 999
-      fabs FR_f_abs = FR_f
-      nop.i 999
-}
-;;
-
-{ .mfi
-      getf.sig GR_N = FR_N
-      fsetc.s3 0x7F,0x40                 // Reset sf3 to user settings + td
-      nop.i 999
-}
-;;
-
-{ .mfi
-      nop.m 999
-      fsub.s1 FR_s_lo = FR_f,FR_s_hi          // For Case 1, s_lo=f-s_hi
-      nop.i 999
-}
-{ .mfi
-      nop.m 999
-      fsub.s1 FR_f_lo = FR_f,FR_f_hi          // For Case 2, f_lo=f-f_hi
-      nop.i 999
-}
-;;
-
-{ .mfi
-      nop.m 999
-      fmpy.s1 FR_r_hi = FR_s_hi,FR_D_hi       // For Case 1, r_hi=s_hi*D_hi
-      nop.i 999
-}
-{ .mfi
-      nop.m 999
-      fadd.s1 FR_a = FR_a,FR_b                // For Case 2, a=a+b
-      nop.i 999
-}
-;;
-
-
-//    If sgn_x == 1 (that is original x was negative)
-//       N := 2^10 - N
-//       this maintains N to be non-negative, but still
-//       equivalent to the (negated N) mod 4.
-//    End If
-{ .mfi
-      add GR_N = GR_N,GR_M
-      fcmp.ge.s1 p13, p10 = FR_f_abs,FR_TWOM33
-      mov GR_Temp = 0x00400
-}
-;;
-
-{ .mfi
-(p9)  sub GR_N = GR_Temp,GR_N
-      fadd.s1 FR_s_lo = FR_s_lo,FR_g           // For Case 1, s_lo=s_lo+g
-      nop.i 999
-}
-{ .mfi
-      nop.m 999
-      fadd.s1 FR_f_lo = FR_f_lo,FR_A           // For Case 2, f_lo=f_lo+A
-      nop.i 999
-}
-;;
-
-//       a := (B - A) + b      Exact.
-//       Note that a is either 0 or 2^(-128).
-//       f_hi := A + f;
-//       f_lo := (f - f_hi) + A
-//       f_lo=f-f_hi is exact because either |f| >= |A|, in which
-//       case f-f_hi is clearly exact; or otherwise, 0<|f|<|A|
-//       means msb(f) <= msb(A) = 2^(-64) => |f| = 2^(-64).
-//       If f = 2^(-64), f-f_hi involves cancellation and is
-//       exact. If f = -2^(-64), then A + f is exact. Hence
-//       f-f_hi is -A exactly, giving f_lo = 0.
-//       f_lo := f_lo + a;
-
-//    If |f| >= 2^(-33)
-//       Case 1
-//       CASE := 1
-//       g := A_hi + B_lo;
-//       s_hi := f + g;
-//       s_lo := (f - s_hi) + g;
-//   Else
-//       Case 2
-//       CASE := 2
-//       A := fadd.fpsr3( A_hi, B_lo )
-//       B := max( A_hi, B_lo )
-//       b := min( A_hi, B_lo )
-
-{ .mfi
-      nop.m 999
-(p10) fcmp.ge.unc.s1 p14, p11 = FR_f_abs,FR_TWOM50
-      nop.i 999
-}
-{ .mfi
-      nop.m 999
-(p13) fms.s1 FR_r_lo = FR_s_hi,FR_D_hi,FR_r_hi //For Case 1, r_lo=s_hi*D_hi+r_hi
-      nop.i 999
-}
-;;
-
-//       If |f| >= 2^(-50) then
-//          s_hi := f_hi;
-//          s_lo := f_lo;
-//       Else
-//          f_lo := (f_lo + A_lo) + x*p_4
-//          s_hi := f_hi + f_lo
-//          s_lo := (f_hi - s_hi) + f_lo
-//       End If
-{ .mfi
-      nop.m 999
-(p14) mov FR_s_hi = FR_f_hi
-      nop.i 999
-}
-{ .mfi
-      nop.m 999
-(p10) fadd.s1 FR_f_lo = FR_f_lo,FR_a
-      nop.i 999
-}
-;;
-
-{ .mfi
-      nop.m 999
-(p14) mov FR_s_lo = FR_f_lo
-      nop.i 999
-}
-{ .mfi
-      nop.m 999
-(p11) fadd.s1 FR_f_lo = FR_f_lo,FR_A_lo
-      nop.i 999
-}
-;;
-
-{ .mfi
-      nop.m 999
-(p11) fma.s1 FR_f_lo = FR_X,FR_p_4,FR_f_lo
-      nop.i 999
-}
-;;
-
-{ .mfi
-      nop.m 999
-(p13) fma.s1 FR_r_lo = FR_s_hi,FR_D_lo,FR_r_lo //For Case 1, r_lo=s_hi*D_lo+r_lo
-      nop.i 999
-}
-{ .mfi
-      nop.m 999
-(p11) fadd.s1 FR_s_hi = FR_f_hi,FR_f_lo
-      nop.i 999
-}
-;;
-
-//   r_hi :=  s_hi*D_hi
-//   r_lo :=  s_hi*D_hi - r_hi  with fma
-//   r_lo := (s_hi*D_lo + r_lo) + s_lo*D_hi
-{ .mfi
-      nop.m 999
-(p10) fmpy.s1 FR_r_hi = FR_s_hi,FR_D_hi
-      nop.i 999
-}
-{ .mfi
-      nop.m 999
-(p11) fsub.s1 FR_s_lo = FR_f_hi,FR_s_hi
-      nop.i 999
-}
-;;
-
-{ .mfi
-      nop.m 999
-(p10) fms.s1 FR_r_lo = FR_s_hi,FR_D_hi,FR_r_hi
-      nop.i 999
-}
-{ .mfi
-      nop.m 999
-(p11) fadd.s1 FR_s_lo = FR_s_lo,FR_f_lo
-      nop.i 999
-}
-;;
-
-{ .mfi
-      nop.m 999
-(p10) fma.s1 FR_r_lo = FR_s_hi,FR_D_lo,FR_r_lo
-      nop.i 999
-}
-;;
-
-//   Return  N, r_hi, r_lo
-//   We do not return CASE
-{ .mfb
-      nop.m 999
-      fma.s1 FR_r_lo = FR_s_lo,FR_D_hi,FR_r_lo
-      br.ret.sptk   b0
-}
-;;
-
-.endp __libm_pi_by_2_reduce#