arch/s390/math-emu/qrnnd.S - android_kernel_htc_msm8960 - Gitiles

 # S/390 __udiv_qrnnd

 # r2 : &__r
 # r3 : upper half of 64 bit word n
 # r4 : lower half of 64 bit word n
 # r5 : divisor d
 # the reminder r of the division is to be stored to &__r and
 # the quotient q is to be returned

         .text
         .globl __udiv_qrnnd
 __udiv_qrnnd:
         st    %r2,24(%r15)        # store pointer to reminder for later
         lr    %r0,%r3             # reload n
 	lr    %r1,%r4
 	ltr   %r2,%r5             # reload and test divisor
         jp    5f
         # divisor >= 0x80000000
 	srdl  %r0,2               # n/4
         srl   %r2,1               # d/2
         slr   %r1,%r2             # special case if last bit of d is set
         brc   3,0f                #  (n/4) div (n/2) can overflow by 1
         ahi   %r0,-1              #  trick: subtract n/2, then divide
 0:      dr    %r0,%r2             # signed division
         ahi   %r1,1               #  trick part 2: add 1 to the quotient
         # now (n >> 2) = (d >> 1) * %r1 + %r0
 	lhi   %r3,1
         nr    %r3,%r1             # test last bit of q
         jz    1f
         alr   %r0,%r2             # add (d>>1) to r
 1:      srl   %r1,1               # q >>= 1
         # now (n >> 2) = (d&-2) * %r1 + %r0
         lhi   %r3,1
         nr    %r3,%r5             # test last bit of d
         jz    2f
         slr   %r0,%r1             # r -= q
 	brc   3,2f                # borrow ?
 	alr   %r0,%r5             # r += d
 	ahi   %r1,-1
 2:      # now (n >> 2) = d * %r1 + %r0
         alr   %r1,%r1             # q <<= 1
         alr   %r0,%r0             # r <<= 1
         brc   12,3f               # overflow on r ?
         slr   %r0,%r5             # r -= d
         ahi   %r1,1               # q += 1
 3:      lhi   %r3,2
         nr    %r3,%r4             # test next to last bit of n
         jz    4f
         ahi   %r0,1               # r += 1
 4:      clr   %r0,%r5             # r >= d ?
         jl    6f
         slr   %r0,%r5             # r -= d
         ahi   %r1,1               # q += 1
         # now (n >> 1) = d * %r1 + %r0
         j     6f
 5:      # divisor < 0x80000000
 	srdl  %r0,1
         dr    %r0,%r2             # signed division
         # now (n >> 1) = d * %r1 + %r0
 6:      alr   %r1,%r1             # q <<= 1
         alr   %r0,%r0             # r <<= 1
         brc   12,7f               # overflow on r ?
         slr   %r0,%r5             # r -= d
         ahi   %r1,1               # q += 1
 7:      lhi   %r3,1
         nr    %r3,%r4             # isolate last bit of n
         alr   %r0,%r3             # r += (n & 1)
         clr   %r0,%r5             # r >= d ?
         jl    8f
         slr   %r0,%r5             # r -= d
         ahi   %r1,1               # q += 1
 8:      # now n = d * %r1 + %r0
 	l     %r2,24(%r15)
         st    %r0,0(%r2)
         lr    %r2,%r1
         br    %r14
 	.end	__udiv_qrnnd
	# S/390 __udiv_qrnnd

	# r2 : &__r
	# r3 : upper half of 64 bit word n
	# r4 : lower half of 64 bit word n
	# r5 : divisor d
	# the reminder r of the division is to be stored to &__r and
	# the quotient q is to be returned

	.text
	.globl __udiv_qrnnd
	__udiv_qrnnd:
	st %r2,24(%r15) # store pointer to reminder for later
	lr %r0,%r3 # reload n
	lr %r1,%r4
	ltr %r2,%r5 # reload and test divisor
	jp 5f
	# divisor >= 0x80000000
	srdl %r0,2 # n/4
	srl %r2,1 # d/2
	slr %r1,%r2 # special case if last bit of d is set
	brc 3,0f # (n/4) div (n/2) can overflow by 1
	ahi %r0,-1 # trick: subtract n/2, then divide
	0: dr %r0,%r2 # signed division
	ahi %r1,1 # trick part 2: add 1 to the quotient
	# now (n >> 2) = (d >> 1) * %r1 + %r0
	lhi %r3,1
	nr %r3,%r1 # test last bit of q
	jz 1f
	alr %r0,%r2 # add (d>>1) to r
	1: srl %r1,1 # q >>= 1
	# now (n >> 2) = (d&-2) * %r1 + %r0
	lhi %r3,1
	nr %r3,%r5 # test last bit of d
	jz 2f
	slr %r0,%r1 # r -= q
	brc 3,2f # borrow ?
	alr %r0,%r5 # r += d
	ahi %r1,-1
	2: # now (n >> 2) = d * %r1 + %r0
	alr %r1,%r1 # q <<= 1
	alr %r0,%r0 # r <<= 1
	brc 12,3f # overflow on r ?
	slr %r0,%r5 # r -= d
	ahi %r1,1 # q += 1
	3: lhi %r3,2
	nr %r3,%r4 # test next to last bit of n
	jz 4f
	ahi %r0,1 # r += 1
	4: clr %r0,%r5 # r >= d ?
	jl 6f
	slr %r0,%r5 # r -= d
	ahi %r1,1 # q += 1
	# now (n >> 1) = d * %r1 + %r0
	j 6f
	5: # divisor < 0x80000000
	srdl %r0,1
	dr %r0,%r2 # signed division
	# now (n >> 1) = d * %r1 + %r0
	6: alr %r1,%r1 # q <<= 1
	alr %r0,%r0 # r <<= 1
	brc 12,7f # overflow on r ?
	slr %r0,%r5 # r -= d
	ahi %r1,1 # q += 1
	7: lhi %r3,1
	nr %r3,%r4 # isolate last bit of n
	alr %r0,%r3 # r += (n & 1)
	clr %r0,%r5 # r >= d ?
	jl 8f
	slr %r0,%r5 # r -= d
	ahi %r1,1 # q += 1
	8: # now n = d * %r1 + %r0
	l %r2,24(%r15)
	st %r0,0(%r2)
	lr %r2,%r1
	br %r14
	.end __udiv_qrnnd