gcc/libgcc/config/ft32/lib1funcs.S
Jakub Jelinek 8d9254fc8a Update copyright years.
From-SVN: r279813
2020-01-01 12:51:42 +01:00

990 lines
25 KiB
ArmAsm
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

# ieee754 sf routines for FT32
/* Copyright (C) 1995-2020 Free Software Foundation, Inc.
This file is free software; you can redistribute it and/or modify it
under the terms of the GNU General Public License as published by the
Free Software Foundation; either version 3, or (at your option) any
later version.
This file is distributed in the hope that it will be useful, but
WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
General Public License for more details.
Under Section 7 of GPL version 3, you are granted additional
permissions described in the GCC Runtime Library Exception, version
3.1, as published by the Free Software Foundation.
You should have received a copy of the GNU General Public License and
a copy of the GCC Runtime Library Exception along with this program;
see the files COPYING3 and COPYING.RUNTIME respectively. If not, see
<http://www.gnu.org/licenses/>. */
# See http://www.ens-lyon.fr/LIP/Pub/Rapports/PhD/PhD2006/PhD2006-02.pdf
# for implementation details of all except division which is detailed below
#
#ifdef L_fp_tools
// .global __cmpsf2_
nan: .long 0x7FFFFFFF # also abs mask
inf: .long 0x7F800000
sign_mask: .long 0x80000000
m_mask: .long 0x007FFFFF
exp_bias: .long 127
edge_case: .long 0x00FFFFFF
smallest_norm: .long 0x00800000 # implicit bit
high_FF: .long 0xFF000000
high_uint: .long 0xFFFFFFFF
ntz_table:
.byte 32,0,1,12,2,6,0,13,3,0,7,0,0,0,0,14
.byte 10,4,0,0,8,0,0,25,0,0,0,0,0,21,27,15
.byte 31,11,5,0,0,0,0,0,9,0,0,24,0,0,20,26
.byte 30,0,0,0,0,23,0,19,29,0,22,18,28,17,16,0
#endif
# Supply a few 'missing' instructions
# not
.macro not rd,r1
xor \rd,\r1,-1
.endm
# negate
.macro neg x
not \x, \x
add \x, \x, 1
.endm
# set $cc from the result of "ashl reg,dist"
.macro ashlcc reg,dist
.long 0x5de04008 | (\reg << 15) | (\dist << 4)
.endm
# converts an unsigned number x to a signed rep based on the bits in sign
# sign should be 0x00000000 or 0xffffffff.
.macro to_signed x, sign
add \x,\x,\sign # conditionally decrement x
xor \x,\x,\sign # conditionally complement x
.endm
.macro ld32 r,v
ldk \r,(\v>>10)
ldl \r,\r,(\v & 1023)
.endm
# calculate trailing zero count in x, also uses scr.
# Using Seal's algorithm
.macro ntz x, scr
not \scr, \x
add \scr, \scr, 1
and \x, \x, \scr
ashl \scr, \x, 4
add \x, \scr, \x
ashl \scr, \x, 6
add \x, \scr, \x
ashl \scr, \x, 16
sub \x, \scr, \x
lshr \x, \x, 26
ldk \scr, ntz_table
add \x, \x, \scr
lpmi.b \x, \x, 0
.endm
# calculate leading zero count
.macro nlz x, scr
flip \x, \x, 31
ntz \x, \scr
.endm
# Round 26 bit mantissa to nearest
# | 23 bits frac | G | R | S |
.macro round m, s1, s2
ldk \s1,0xc8
and \s2,\m,7
lshr \s1,\s1,\s2
and \s1,\s1,1
lshr \m,\m,2
add \m,\m,\s1
.endm
# If NZ, set the LSB of reg
.macro sticky reg
jmpc z,1f
or \reg,\reg,1 # set the sticky bit to 1
1:
.endm
##########################################################################
##########################################################################
## addition & subtraction
#if defined(L_subsf3) || defined(L_addsub_sf)
.global __subsf3
__subsf3:
# this is subtraction, so we just change the sign of r1
lpm $r2,sign_mask
xor $r1,$r1,$r2
jmp __addsf3
#endif
#if defined(L_addsf3) || defined(L_addsub_sf)
.global __addsf3
__addsf3:
# x in $r0, y in $r1, result z in $r0 --||| 100 instructions +/- |||--
# unpack e, calc d
bextu $r2,$r0,(8<<5)|23 # ex in r2
bextu $r3,$r1,(8<<5)|23 # ey in r3
sub $r5,$r2,$r3 # d = ex - ey
# Special values are 0x00 and 0xff in ex and ey.
# If (ex&ey) != 0 or (xy|ey)=255 then there may be
# a special value.
tst $r2,$r3
jmpc nz,1f
jmp slow
1: or $r4,$r2,$r3
cmp $r4,255
jmpc nz,no_special_vals
slow:
# Check for early exit
cmp $r2,0
jmpc z,test_if_not_255
cmp $r3,0
jmpc nz,no_early_exit
test_if_not_255:
cmp $r2,255
jmpc z,no_early_exit
cmp $r3,255
jmpc z,no_early_exit
or $r6,$r2,$r3
cmp $r6,0
jmpc nz,was_not_zero
and $r0,$r0,$r1
lpm $r1,sign_mask
and $r0,$r0,$r1
return
was_not_zero:
cmp $r2,0
jmpc nz,ret_x
move $r0,$r1
return
ret_x:
return
no_early_exit:
# setup to test for special values
sub $r6,$r2,1
and $r6,$r6,0xFE
sub $r7,$r3,1
and $r7,$r7,0xFE
# test for special values
cmp $r6,$r7
jmpc gte,ex_spec_is_gte
move $r6,$r7
ex_spec_is_gte:
cmp $r6,0xFE
jmpc nz,no_special_vals
cmp $r5,0
jmpc ns,d_gte_0
cmp $r3,0xFF
jmpc z,ret_y
cmp $r2,0
jmpc z,ret_y
ret_y:
move $r0,$r1
return
d_gte_0:
cmp $r5,0
jmpc z,d_is_0
cmp $r2,0xFF
jmpc z,ret_x
cmp $r3,0
jmpc z,ret_x
d_is_0:
cmp $r2,0xFF
jmpc nz,no_special_vals
ashl $r6,$r0,9 # clear all except x frac
ashl $r7,$r1,9 # clear all except y frac
or $r6,$r6,$r7
cmp $r6,0
jmpc nz,ret_nan
lshr $r4,$r0,31 # sx in r4
lshr $r5,$r1,31 # sy in r4
cmp $r4,$r5
jmpc nz,ret_nan
return
ret_nan:
lpm $r0,nan
return
no_special_vals:
ldk $r8,(1<<10)|(9<<5)|26 # setup implicit bit and mask for e
#----------------------
ashr $r4,$r0,31 # sx in r4
ashl $r0,$r0,3 # shift mx 3 for GRS bits
bins $r0,$r0,$r8 # clear sx, ex and add implicit bit mx
# change mx to signed mantissa
to_signed $r0,$r4
#----------------------
ashr $r4,$r1,31 # sy in r4
ashl $r1,$r1,3 # shift my 3 for GRS bits
bins $r1,$r1,$r8 # clear sy, ey and add implicit bit my
# change my to signed mantissa
to_signed $r1,$r4
#----------------------
# test if we swap ms based on d sign
cmp $r5,0
jmpc gte,noswap
# swap mx & my
xor $r0,$r0,$r1
xor $r1,$r0,$r1
xor $r0,$r0,$r1
# d positive means that ex>=ey, so ez = ex
# d negative means that ey>ex, so ez = ey
move $r2,$r3
# |d|
neg $r5
noswap:
# now $r2 = ez = max(ex,ey)
cmp $r5,26 # max necessary alignment shift is 26
jmpc lt,under_26
ldk $r5,26
under_26:
ldk $r7,-1
ashl $r7,$r7,$r5 # create inverse of mask for test of S bit value in discarded my
not $r7,$r7
tst $r1,$r7 # determine value of sticky bit
# shift my >> |d|
ashr $r1,$r1,$r5
sticky $r1
# add ms
add $r0,$r0,$r1
# $r4 = sign(mx), mx = |mx|
ashr $r4,$r0,31
xor $r0,$r0,$r4
sub $r0,$r0,$r4
# realign mantissa using leading zero count
flip $r7,$r0,31
ntz $r7,$r8
ashl $r0,$r0,$r7
btst $r0,(6<<5)|0 # test low bits for sticky again
lshr $r0,$r0,6
sticky $r0
# update exponent
add $r2,$r2,5
sub $r2,$r2,$r7
# Round to nearest
round $r0,$r7,$r6
# detect_exp_update
lshr $r6,$r0,24
add $r2,$r2,$r6
# final tests
# mz == 0? if so, we just bail with a +0
cmp $r0,0
jmpc nz,msum_not_zero
ldk $r0,0
return
msum_not_zero:
# Combined check that (1 <= ez <= 254)
sub $r3,$r2,1
cmp $r3,254
jmpc b,no_special_ret
# underflow?
cmp $r2,0
jmpc gt,no_under
ldk $r0,0
jmp pack_sz
no_under:
# overflow?
cmp $r2,255
jmpc lt,no_special_ret
ldk $r0,0x7F8
ashl $r0,$r0,20
jmp pack_sz
no_special_ret:
# Pack ez
ldl $r2,$r2,(8<<5)|23
bins $r0,$r0,$r2 # width = 8, pos = 23 pack ez
# Pack sz
pack_sz:
ldl $r4,$r4,(1<<5)|31
bins $r0,$r0,$r4 # width = 1, pos = 31 set sz to sy
return
#endif
##########################################################################
##########################################################################
## multiplication
#ifdef L_mulsf3
.global __mulsf3
__mulsf3:
# x in $r0, y in $r1, result z in $r0 --||| 61 instructions +/- |||--
# unpack e
bextu $r2,$r0,(8<<5)|23 # ex in r2
bextu $r3,$r1,(8<<5)|23 # ey in r3
# calc result sign
xor $r4,$r0,$r1
lpm $r5,sign_mask
and $r4,$r4,$r5 # sz in r4
# unpack m add implicit bit
ldk $r5,(1<<10)|(9<<5)|23 # setup implicit bit and mask for e
#----------------------
bins $r0,$r0,$r5 # clear sx, ex and add implicit bit mx
sub $r6,$r2,1
cmp $r6,254
jmpc b,1f
jmp slow_mul
1: sub $r6,$r3,1
cmp $r6,254
jmpc b,no_special_vals_mul
slow_mul:
# Check for early exit
cmp $r2,0
jmpc z,op_is_zero
cmp $r3,0
jmpc nz,no_early_exit_mul
op_is_zero:
cmp $r2,255
jmpc z,no_early_exit_mul
cmp $r3,255
jmpc z,no_early_exit_mul
move $r0,$r4
return
no_early_exit_mul:
# setup to test for special values
sub $r6,$r2,1
and $r6,$r6,0xFE
sub $r7,$r3,1
and $r7,$r7,0xFE
# test for special values
cmp $r6,$r7
jmpc gte,ex_spec_is_gte_ey_mul
move $r6,$r7
ex_spec_is_gte_ey_mul:
cmp $r6,0xFE
jmpc nz,no_special_vals_mul
cmp $r2,0xFF
jmpc nz,ex_not_FF_mul
ashl $r6,$r0,9
cmp $r6,0
jmpc nz,ret_nan
cmp $r3,0
jmpc z,ret_nan
ashl $r6,$r1,1
lpm $r7,high_FF
cmp $r6,$r7
jmpc a,ret_nan
cmp $r6,0
jmpc z,ret_nan
# infinity
lpm $r0,inf
or $r0,$r0,$r4
return
ex_not_FF_mul:
cmp $r2,0
jmpc nz,no_nan_mul
cmp $r3,0xFF
jmpc nz,no_nan_mul
jmp ret_nan
no_nan_mul:
lpm $r0,nan
and $r0,$r0,$r1
or $r0,$r0,$r4
return
ret_nan:
lpm $r0,nan
return
no_special_vals_mul:
bins $r1,$r1,$r5 # clear sy, ey and add implicit bit my
# calc ez
add $r3,$r2,$r3
sub $r3,$r3,127 # ez in r3
# (r1,r2) = R0 * R1
mul $r2,$r0,$r1
muluh $r1,$r0,$r1
btst $r1,(1<<5)|15 # XXX use jmpx
jmpc z,mul_z0
# mz is 1X.XX...X
# 48-bit product is in (r1,r2). The low 22 bits of r2
# are discarded.
lshr $r0,$r2,22
ashl $r1,$r1,10
or $r0,$r0,$r1 # r0 = (r1,r2) >> 22
ashlcc 2,10
sticky $r0
add $r3,$r3,1 # bump exponent
# Round to nearest
round $r0, $r1, $r2
lshr $r6,$r0,24
add $r3,$r3,$r6
sub $r6,$r3,1
cmp $r6,254
jmpc b,no_special_ret_mul
special_ret_mul:
# When the final exponent <= 0, result is flushed to 0 except
# for the border case 0x00FFFFFF which is promoted to next higher
# FP no., that is, the smallest "normalized" number.
cmp $r3,0
jmpc gt,exp_normal
# Pack ez
ldl $r3,$r3,(8<<5)|23
bins $r0,$r0,$r3 # width = 8, pos = 23 pack ez
lpm $r2,edge_case
cmp $r0,$r2
jmpc nz,no_edge_case
lpm $r0,smallest_norm
jmp pack_sz_mul
no_edge_case:
ldk $r0,0
jmp pack_sz_mul
exp_normal:
# overflow?
cmp $r3,255
jmpc lt,no_special_ret_mul
ldk $r0,0x7F8
ashl $r0,$r0,20
jmp pack_sz_mul
no_special_ret_mul:
# Pack ez
ldl $r3,$r3,(8<<5)|23
bins $r0,$r0,$r3 # width = 8, pos = 23 pack ez
# Pack sz
pack_sz_mul:
or $r0,$r0,$r4
return
mul_z0:
# mz is 0X.XX...X
# 48-bit product is in (r1,r2). The low 21 bits of r2
# are discarded.
lshr $r0,$r2,21
ashl $r1,$r1,11
or $r0,$r0,$r1 # r0 = (r1,r2) >> 22
ashlcc 2,11
sticky $r0
# Round to nearest
round $r0, $r1, $r2
lshr $r6,$r0,24
add $r3,$r3,$r6
sub $r6,$r3,1
cmp $r6,254
jmpc b,no_special_ret_mul
jmp special_ret_mul
#endif
##########################################################################
##########################################################################
## division
## See http://perso.ens-lyon.fr/gilles.villard/BIBLIOGRAPHIE/PDF/arith19.pdf
## for implementation details
#ifdef L_divsf3
dc_1: .long 0xffffe7d7
dc_2: .long 0xffffffe8
dc_3: .long 0xffbad86f
dc_4: .long 0xfffbece7
dc_5: .long 0xf3672b51
dc_6: .long 0xfd9d3a3e
dc_7: .long 0x9a3c4390
dc_8: .long 0xd4d2ce9b
dc_9: .long 0x1bba92b3
dc_10: .long 0x525a1a8b
dc_11: .long 0x0452b1bf
dc_12: .long 0xFFFFFFC0
spec_val_test: .long 0x7F7FFFFF
.global __divsf3
__divsf3:
push $r13
# x in $r0, y in $r1, result z in $r0 --||| 73 instructions +/- |||-
bextu $r10,$r0,(8<<5)|23 # ex in r2
bextu $r11,$r1,(8<<5)|23 # ey in r3
lpm $r6, m_mask
and $r2, $r0, $r6 # mx
and $r3, $r1, $r6 # my
cmp $r2,$r3
bextu $r2,$r30,(1<<5)|4 # c = Tx >= T;
ashl $r3,$r3,9 # T = X << 9;
lpm $r13, sign_mask
ashl $r4,$r0,8 # X8 = X << 8;
or $r4,$r4,$r13 # Mx = X8 | 0x80000000;
lshr $r5,$r4,$r2 # S = Mx >> c;
# calc D
sub $r2, $r11, $r2
add $r12, $r10, 125
sub $r2, $r12, $r2 # int D = (Ex + 125) - (Ey - c);
# calc result sign
xor $r12,$r0,$r1
and $r12,$r12,$r13 # Sr = ( X ˆ Y ) & 0x80000000;
# check early exit
cmp $r10, 0
jmpc nz, no_early_ret_dev
cmp $r11, 0
jmpc z, no_early_ret_dev
cmp $r11, 255
jmpc z, no_early_ret_dev
move $r0, $r12
pop $r13
return
no_early_ret_dev:
# setup to test for special values
sub $r8,$r10,1
and $r8,$r8,0xFE
sub $r9,$r11,1
and $r9,$r9,0xFE
# test for special values
cmp $r8, $r9
jmpc gte, absXm1_gte_absYm1
move $r8, $r9
absXm1_gte_absYm1:
cmp $r8, 0xFE
jmpc nz, no_spec_ret_div
cmp $r10, 0xFF
jmpc nz, ex_not_FF_div
lpm $r6, m_mask
and $r2, $r0, $r6 # mx
cmp $r2, 0
jmpc nz, ret_nan_div
cmp $r11, 0xFF
jmpc z, ret_nan_div
jmp ret_inf_div
ex_not_FF_div:
cmp $r11, 0xFF
jmpc nz, ey_not_FF_div
ashl $r13, $r1, 9
cmp $r13, 0
jmpc nz, ret_nan_div
move $r0, $r12
pop $r13
return
ey_not_FF_div:
or $r10, $r10, $r11
cmp $r10, 0
jmpc z, ret_nan_div
ret_inf_div:
lpm $r6, inf
move $r0, $r6
or $r0, $r0, $r12
pop $r13
return
ret_nan_div:
lpm $r0, nan
pop $r13
return
no_spec_ret_div:
# check for overflow
ldk $r6, 0xFE
cmp $r2, $r6
jmpc lt, no_overflow_div
lpm $r6, inf
or $r0, $r12, $r6
pop $r13
return
no_overflow_div:
# check for underflow
cmp $r2, 0
jmpc ns, no_underflow_div
xnor $r6, $r6, $r6 # -1
cmp $r2, $r6
jmpc nz, ret_sr_div
ldk $r7, 0xFF
xor $r6, $r6, $r7 # 0xFF ^ -1 = 0xFFFFFF00
cmp $r4, $r6
jmpc nz, ret_sr_div
lpm $r6, sign_mask
cmp $r4, $r6
jmpc nz, ret_sr_div
lshr $r0, $r6, 8
or $r0, $r0, $r12
pop $r13
return
ret_sr_div:
move $r0, $r12
pop $r13
return
no_underflow_div:
lpm $r6, dc_1
muluh $r7, $r3, $r6 # i0 = mul( T , 0xffffe7d7 );
lpm $r6, dc_2
sub $r7, $r6, $r7 # i1 = 0xffffffe8 - i0;
muluh $r7, $r5, $r7 # i2 = mul( S , i1 );
add $r7, $r7, 0x20 # i3 = 0x00000020 + i2;
muluh $r8, $r3, $r3 # i4 = mul( T , T );
muluh $r9, $r5, $r8 # i5 = mul( S , i4 );
lpm $r6, dc_3
muluh $r10, $r3, $r6 # i6 = mul( T , 0xffbad86f );
lpm $r6, dc_4
sub $r10, $r6, $r10 # i7 = 0xfffbece7 - i6;
muluh $r10, $r9, $r10 # i8 = mul( i5 , i7 );
add $r7, $r7, $r10 # i9 = i3 + i8;
muluh $r9, $r8, $r9 # i10 = mul( i4 , i5 );
lpm $r6, dc_5
muluh $r10, $r3, $r6 # i11 = mul( T , 0xf3672b51 );
lpm $r6, dc_6
sub $r10, $r6, $r10 # i12 = 0xfd9d3a3e - i11;
lpm $r6, dc_7
muluh $r11, $r3, $r6 # i13 = mul( T , 0x9a3c4390 );
lpm $r6, dc_8
sub $r11, $r6, $r11 # i14 = 0xd4d2ce9b - i13
muluh $r11, $r8, $r11 # i15 = mul( i4 , i14 );
add $r10, $r10, $r11 # i16 = i12 + i15;
muluh $r10, $r9, $r10 # i17 = mul( i10 , i16 )
add $r7, $r7, $r10 # i18 = i9 + i17;
muluh $r10, $r8, $r8 # i19 = mul( i4 , i4 );
lpm $r6, dc_9
muluh $r11, $r3, $r6 # i20 = mul( T , 0x1bba92b3 );
lpm $r6, dc_10
sub $r11, $r6, $r11 # i21 = 0x525a1a8b - i20;
lpm $r6, dc_11
muluh $r8, $r8, $r6 # i22 = mul( i4 , 0x0452b1bf );
add $r8, $r11, $r8 # i23 = i21 + i22;
muluh $r8, $r10, $r8 # i24 = mul( i19 , i23 );
muluh $r8, $r9, $r8 # i25 = mul( i10 , i24 );
add $r3, $r7, $r8 # V = i18 + i25;
# W = V & 0xFFFFFFC0;
lpm $r6, dc_12
and $r3, $r3, $r6 # W
# round and pack final values
ashl $r0, $r2, 23 # pack D
or $r0, $r0, $r12 # pack Sr
ashl $r12, $r1, 8
or $r12, $r12, $r13 # My
muluh $r10, $r3, $r12
lshr $r11, $r5, 1
cmp $r10, $r11
jmpc gte, div_ret_1
add $r3, $r3, 0x40
div_ret_1:
lshr $r3, $r3, 7
add $r0, $r0, $r3
pop $r13
return
#endif
##########################################################################
##########################################################################
## Negate
#ifdef L_negsf
.global __negsf
__negsf:
lpm $r1, sign_mask
xor $r0, $r0, $r1
return
#endif
##########################################################################
##########################################################################
## float to int & unsigned int
#ifdef L_fixsfsi
.global __fixsfsi
__fixsfsi: # 20 instructions
bextu $r1,$r0,(8<<5)|23 # e in r1
lshr $r2,$r0,31 # s in r2
lpm $r3, m_mask
and $r0,$r0,$r3 # m in r0
# test nan
cmp $r1,0xFF
jmpc nz, int_not_nan
cmp $r0,0
jmpc z, int_not_nan
ldk $r0,0
return
int_not_nan:
# test edges
cmp $r1, 127
jmpc gte, int_not_zero # lower limit
ldk $r0,0
return
int_not_zero:
cmp $r1, 158
jmpc lt, int_not_max # upper limit
lpm $r0, nan
cmp $r2, 0
jmpc z, int_positive
xnor $r0, $r0, 0
return
int_not_max:
lpm $r3, smallest_norm
or $r0, $r0, $r3 # set implicit bit
sub $r1, $r1, 150
cmp $r1, 0
jmpc s, shift_right
ashl $r0, $r0, $r1
jmp set_int_sign
shift_right:
xnor $r1, $r1, 0
add $r1, $r1, 1
lshr $r0, $r0, $r1
set_int_sign:
cmp $r2, 0
jmpc z, int_positive
xnor $r0, $r0, 0
add $r0, $r0, 1
int_positive:
return
#endif
#ifdef L_fixunssfsi
.global __fixunssfsi
__fixunssfsi: # 19 instructions
lshr $r2, $r0, 31 # s in r2
cmp $r2, 0
jmpc z, uint_not_neg
ldk $r0, 0
return
uint_not_neg:
bextu $r1, $r0, (8<<5)|23 # e in r1
sub $r1, $r1, 127
lpm $r3, m_mask
and $r0, $r0, $r3 # m in r0
# test nan
cmp $r1, 0xFF
jmpc nz, uint_not_nan
cmp $r0, 0
jmpc z, uint_not_nan
ldk $r0, 0
return
uint_not_nan:
# test edges
cmp $r1, 0
jmpc ns, uint_not_zero # lower limit
ldk $r0, 0
return
uint_not_zero:
lpm $r3, smallest_norm
or $r0, $r0, $r3 # set implicit bit
cmp $r1, 23
jmpc lt, shift_uint_right
sub $r1, $r1, 23
ashl $r0, $r0, $r1
return
shift_uint_right:
ldk $r3, 23
sub $r1, $r3, $r1
lshr $r0, $r0, $r1
return
#endif
##########################################################################
##########################################################################
## int & unsigned int to float
.macro i2f x, s1, s2, s3, lbl
move \s1, \x
nlz \s1, \s2
cmp \s1, 8
jmpc s, float_round\lbl
sub \s2, \s1, 8
ashl \x, \x, \s2
jmp float_no_round\lbl
float_round\lbl:
cmp \s1, 6
jmpc s, float_shift_right\lbl
sub \s2, \s1, 6
ashl \x, \x, \s2
jmp float_round_and_pack\lbl
float_shift_right\lbl:
ldk \s2, 6
sub \s2, \s2, \s1
xnor \s3, \s3 ,\s3 # 0xFFFFFFFF
ashl \s3, \s3 ,\s2 # create inverse of mask for test of S bit value in discarded my
xnor \s3, \s3 ,0 # NOT
tst \x, \s3 # determine value of sticky bit
lshr \x, \x, \s2
jmpc z,float_round_and_pack\lbl
or \x, \x, 1 # set the sticky bit to 1
float_round_and_pack\lbl:
bextu \s2, \x, (1<<5)|2 # extract low bit of m
or \x, \x, \s2 # or p into r
add \x, \x, 1
lshr \x, \x, 2
btst \x, (1<<5)|24 # test for carry from round
jmpc z, float_no_round\lbl
sub \s1, \s1, 1 # inc e for carry (actually dec nlz)
lshr \x, \x, 1
float_no_round\lbl:
ldk \s2, 158
sub \s1, \s2, \s1
# Pack e
ldl \s1, \s1, (8<<5)|23
bins \x, \x, \s1
.endm
#ifdef L_floatsisf
.global __floatsisf
__floatsisf: # 32 instructions
cmp $r0, 0
jmpc nz, float_not_zero
return
float_not_zero:
ashr $r1, $r0, 31 # s in r1
xor $r0, $r0, $r1 # cond neg
sub $r0, $r0, $r1
i2f $r0, $r2, $r3, $r4, 1
ldl $r1, $r1, (1<<5)|31
bins $r0, $r0, $r1
return
#endif
#ifdef L_floatunsisf
.global __floatunsisf
__floatunsisf: # 26 instructions
cmp $r0, 0
jmpc nz, float_not_zero2
return
float_not_zero2:
i2f $r0, $r1, $r2, $r3, 2
return
#endif
#if 0
##########################################################################
##########################################################################
## float compare
__cmpsf2_:
# calc abs vals
lpm $r3, nan # also abs mask
and $r2, $r0, $r3
and $r3, $r1, $r3
# test if either abs is nan
lpm $r4, inf
cmp $r2, $r4
jmpc gt, cmp_is_gt
cmp $r3, $r4
jmpc gt, cmp_is_gt
# test if both are 0
or $r2, $r2, $r3
cmp $r2, 0
jmpc z, cmp_is_eq
# test if eq
cmp $r0, $r1
jmpc z, cmp_is_eq
# -- if either is pos
and $r2, $r0, $r1
cmp $r2, 0
jmpc s, cmp_both_neg
cmp $r0, $r1
jmpc gt, cmp_is_gt
# r0 < r1
lpm $r0, high_uint
return
cmp_both_neg:
cmp $r0, $r1
jmpc lt, cmp_is_gt
# r0 < r1
lpm $r0, high_uint
return
cmp_is_gt:
ldk $r0, 1
return
cmp_is_eq:
ldk $r0, 0
return
#endif
#ifdef L_udivsi3
.global __udivsi3
__udivsi3:
# $r0 is dividend
# $r1 is divisor
ldk $r2,0
push $r28
ldk $r28,-32
0:
lshr $r3,$r0,31 # Shift $r2:$r0 left one
ashl $r0,$r0,1
ashl $r2,$r2,1
or $r2,$r2,$r3
cmp $r2,$r1
jmpc b,1f
2:
sub $r2,$r2,$r1
add $r0,$r0,1
1:
add $r28,$r28,1
jmpx 31,$r28,1,0b
pop $r28
# $r0: quotient
# $r2: remainder
return
#endif
#ifdef L_umodsi3
.global __umodsi3
__umodsi3:
call __udivsi3
move $r0,$r2
return
#endif
#ifdef L_divsi3
.global __divsi3
__divsi3:
xor $r5,$r0,$r1 # $r5 is sign of result
ashr $r2,$r0,31 # $r0 = abs($r0)
xor $r0,$r0,$r2
sub $r0,$r0,$r2
ashr $r2,$r1,31 # $r1 = abs($r1)
xor $r1,$r1,$r2
sub $r1,$r1,$r2
call __udivsi3
ashr $r5,$r5,31
xor $r0,$r0,$r5
sub $r0,$r0,$r5
return
#endif
#ifdef L_modsi3
.global __modsi3
__modsi3:
move $r5,$r0 # $r5 is sign of result
ashr $r2,$r0,31 # $r0 = abs($r0)
xor $r0,$r0,$r2
sub $r0,$r0,$r2
ashr $r2,$r1,31 # $r1 = abs($r1)
xor $r1,$r1,$r2
sub $r1,$r1,$r2
call __umodsi3
ashr $r5,$r5,31
xor $r0,$r0,$r5
sub $r0,$r0,$r5
return
#endif