TOMOYO Linux Cross Reference
Linux/arch/m68k/ifpsp060/src/ilsp.S

   ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
   MOTOROLA MICROPROCESSOR & MEMORY TECHNOLOGY GROUP
   M68000 Hi-Performance Microprocessor Division
   M68060 Software Package
   Production Release P1.00 -- October 10, 1994
   
   M68060 Software Package Copyright © 1993, 1994 Motorola Inc.  All rights reserved.
   
   THE SOFTWARE is provided on an "AS IS" basis and without warranty.
  To the maximum extent permitted by applicable law,
  MOTOROLA DISCLAIMS ALL WARRANTIES WHETHER EXPRESS OR IMPLIED,
  INCLUDING IMPLIED WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE
  and any warranty against infringement with regard to the SOFTWARE
  (INCLUDING ANY MODIFIED VERSIONS THEREOF) and any accompanying written materials.
  
  To the maximum extent permitted by applicable law,
  IN NO EVENT SHALL MOTOROLA BE LIABLE FOR ANY DAMAGES WHATSOEVER
  (INCLUDING WITHOUT LIMITATION, DAMAGES FOR LOSS OF BUSINESS PROFITS,
  BUSINESS INTERRUPTION, LOSS OF BUSINESS INFORMATION, OR OTHER PECUNIARY LOSS)
  ARISING OF THE USE OR INABILITY TO USE THE SOFTWARE.
  Motorola assumes no responsibility for the maintenance and support of the SOFTWARE.
  
  You are hereby granted a copyright license to use, modify, and distribute the SOFTWARE
  so long as this entire notice is retained without alteration in any modified and/or
  redistributed versions, and that such modified versions are clearly identified as such.
  No licenses are granted by implication, estoppel or otherwise under any patents
  or trademarks of Motorola, Inc.
  ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
  # litop.s:
  #       This file is appended to the top of the 060FPLSP package
  # and contains the entry points into the package. The user, in
  # effect, branches to one of the branch table entries located here.
  #
  
          bra.l   _060LSP__idivs64_
          short   0x0000
          bra.l   _060LSP__idivu64_
          short   0x0000
  
          bra.l   _060LSP__imuls64_
          short   0x0000
          bra.l   _060LSP__imulu64_
          short   0x0000
  
          bra.l   _060LSP__cmp2_Ab_
          short   0x0000
          bra.l   _060LSP__cmp2_Aw_
          short   0x0000
          bra.l   _060LSP__cmp2_Al_
          short   0x0000
          bra.l   _060LSP__cmp2_Db_
          short   0x0000
          bra.l   _060LSP__cmp2_Dw_
          short   0x0000
          bra.l   _060LSP__cmp2_Dl_
          short   0x0000
  
  # leave room for future possible aditions.
          align   0x200
  
  #########################################################################
  # XDEF **************************************************************** #
  #       _060LSP__idivu64_(): Emulate 64-bit unsigned div instruction.   #
  #       _060LSP__idivs64_(): Emulate 64-bit signed div instruction.     #
  #                                                                       #
  #       This is the library version which is accessed as a subroutine   #
  #       and therefore does not work exactly like the 680X0 div{s,u}.l   #
  #       64-bit divide instruction.                                      #
  #                                                                       #
  # XREF **************************************************************** #
  #       None.                                                           #
  #                                                                       #
  # INPUT *************************************************************** #
  #       0x4(sp)  = divisor                                              #
  #       0x8(sp)  = hi(dividend)                                         #
  #       0xc(sp)  = lo(dividend)                                         #
  #       0x10(sp) = pointer to location to place quotient/remainder      #
  #                                                                       #
  # OUTPUT ************************************************************** #
  #       0x10(sp) = points to location of remainder/quotient.            #
  #                  remainder is in first longword, quotient is in 2nd.  #
  #                                                                       #
  # ALGORITHM *********************************************************** #
  #       If the operands are signed, make them unsigned and save the     #
  # sign info for later. Separate out special cases like divide-by-zero   #
  # or 32-bit divides if possible. Else, use a special math algorithm     #
  # to calculate the result.                                              #
  #       Restore sign info if signed instruction. Set the condition      #
  # codes before performing the final "rts". If the divisor was equal to  #
  # zero, then perform a divide-by-zero using a 16-bit implemented        #
  # divide instruction. This way, the operating system can record that    #
  # the event occurred even though it may not point to the correct place. #
  #                                                                       #
  #########################################################################
  
  set     POSNEG,         -1
  set     NDIVISOR,       -2
  set     NDIVIDEND,      -3
  set     DDSECOND,       -4
 set     DDNORMAL,       -8
 set     DDQUOTIENT,     -12
 set     DIV64_CC,       -16
 
 ##########
 # divs.l #
 ##########
         global          _060LSP__idivs64_
 _060LSP__idivs64_:
 # PROLOGUE BEGIN ########################################################
         link.w          %a6,&-16
         movm.l          &0x3f00,-(%sp)          # save d2-d7
 #       fmovm.l         &0x0,-(%sp)             # save no fpregs
 # PROLOGUE END ##########################################################
 
         mov.w           %cc,DIV64_CC(%a6)
         st              POSNEG(%a6)             # signed operation
         bra.b           ldiv64_cont
 
 ##########
 # divu.l #
 ##########
         global          _060LSP__idivu64_
 _060LSP__idivu64_:
 # PROLOGUE BEGIN ########################################################
         link.w          %a6,&-16
         movm.l          &0x3f00,-(%sp)          # save d2-d7
 #       fmovm.l         &0x0,-(%sp)             # save no fpregs
 # PROLOGUE END ##########################################################
 
         mov.w           %cc,DIV64_CC(%a6)
         sf              POSNEG(%a6)             # unsigned operation
 
 ldiv64_cont:
         mov.l           0x8(%a6),%d7            # fetch divisor
 
         beq.w           ldiv64eq0               # divisor is = 0!!!
 
         mov.l           0xc(%a6), %d5           # get dividend hi
         mov.l           0x10(%a6), %d6          # get dividend lo
 
 # separate signed and unsigned divide
         tst.b           POSNEG(%a6)             # signed or unsigned?
         beq.b           ldspecialcases          # use positive divide
 
 # save the sign of the divisor
 # make divisor unsigned if it's negative
         tst.l           %d7                     # chk sign of divisor
         slt             NDIVISOR(%a6)           # save sign of divisor
         bpl.b           ldsgndividend
         neg.l           %d7                     # complement negative divisor
 
 # save the sign of the dividend
 # make dividend unsigned if it's negative
 ldsgndividend:
         tst.l           %d5                     # chk sign of hi(dividend)
         slt             NDIVIDEND(%a6)          # save sign of dividend
         bpl.b           ldspecialcases
 
         mov.w           &0x0, %cc               # clear 'X' cc bit
         negx.l          %d6                     # complement signed dividend
         negx.l          %d5
 
 # extract some special cases:
 #       - is (dividend == 0) ?
 #       - is (hi(dividend) == 0 && (divisor <= lo(dividend))) ? (32-bit div)
 ldspecialcases:
         tst.l           %d5                     # is (hi(dividend) == 0)
         bne.b           ldnormaldivide          # no, so try it the long way
 
         tst.l           %d6                     # is (lo(dividend) == 0), too
         beq.w           lddone                  # yes, so (dividend == 0)
 
         cmp.l           %d7,%d6                 # is (divisor <= lo(dividend))
         bls.b           ld32bitdivide           # yes, so use 32 bit divide
 
         exg             %d5,%d6                 # q = 0, r = dividend
         bra.w           ldivfinish              # can't divide, we're done.
 
 ld32bitdivide:
         tdivu.l         %d7, %d5:%d6            # it's only a 32/32 bit div!
 
         bra.b           ldivfinish
 
 ldnormaldivide:
 # last special case:
 #       - is hi(dividend) >= divisor ? if yes, then overflow
         cmp.l           %d7,%d5
         bls.b           lddovf                  # answer won't fit in 32 bits
 
 # perform the divide algorithm:
         bsr.l           ldclassical             # do int divide
 
 # separate into signed and unsigned finishes.
 ldivfinish:
         tst.b           POSNEG(%a6)             # do divs, divu separately
         beq.b           lddone                  # divu has no processing!!!
 
 # it was a divs.l, so ccode setting is a little more complicated...
         tst.b           NDIVIDEND(%a6)          # remainder has same sign
         beq.b           ldcc                    # as dividend.
         neg.l           %d5                     # sgn(rem) = sgn(dividend)
 ldcc:
         mov.b           NDIVISOR(%a6), %d0
         eor.b           %d0, NDIVIDEND(%a6)     # chk if quotient is negative
         beq.b           ldqpos                  # branch to quot positive
 
 # 0x80000000 is the largest number representable as a 32-bit negative
 # number. the negative of 0x80000000 is 0x80000000.
         cmpi.l          %d6, &0x80000000        # will (-quot) fit in 32 bits?
         bhi.b           lddovf
 
         neg.l           %d6                     # make (-quot) 2's comp
 
         bra.b           lddone
 
 ldqpos:
         btst            &0x1f, %d6              # will (+quot) fit in 32 bits?
         bne.b           lddovf
 
 lddone:
 # if the register numbers are the same, only the quotient gets saved.
 # so, if we always save the quotient second, we save ourselves a cmp&beq
         andi.w          &0x10,DIV64_CC(%a6)
         mov.w           DIV64_CC(%a6),%cc
         tst.l           %d6                     # may set 'N' ccode bit
 
 # here, the result is in d1 and d0. the current strategy is to save
 # the values at the location pointed to by a0.
 # use movm here to not disturb the condition codes.
 ldexit:
         movm.l          &0x0060,([0x14,%a6])    # save result
 
 # EPILOGUE BEGIN ########################################################
 #       fmovm.l         (%sp)+,&0x0             # restore no fpregs
         movm.l          (%sp)+,&0x00fc          # restore d2-d7
         unlk            %a6
 # EPILOGUE END ##########################################################
 
         rts
 
 # the result should be the unchanged dividend
 lddovf:
         mov.l           0xc(%a6), %d5           # get dividend hi
         mov.l           0x10(%a6), %d6          # get dividend lo
 
         andi.w          &0x1c,DIV64_CC(%a6)
         ori.w           &0x02,DIV64_CC(%a6)     # set 'V' ccode bit
         mov.w           DIV64_CC(%a6),%cc
 
         bra.b           ldexit
 
 ldiv64eq0:
         mov.l           0xc(%a6),([0x14,%a6])
         mov.l           0x10(%a6),([0x14,%a6],0x4)
 
         mov.w           DIV64_CC(%a6),%cc
 
 # EPILOGUE BEGIN ########################################################
 #       fmovm.l         (%sp)+,&0x0             # restore no fpregs
         movm.l          (%sp)+,&0x00fc          # restore d2-d7
         unlk            %a6
 # EPILOGUE END ##########################################################
 
         divu.w          &0x0,%d0                # force a divbyzero exception
         rts
 
 ###########################################################################
 #########################################################################
 # This routine uses the 'classical' Algorithm D from Donald Knuth's     #
 # Art of Computer Programming, vol II, Seminumerical Algorithms.        #
 # For this implementation b=2**16, and the target is U1U2U3U4/V1V2,     #
 # where U,V are words of the quadword dividend and longword divisor,    #
 # and U1, V1 are the most significant words.                            #
 #                                                                       #
 # The most sig. longword of the 64 bit dividend must be in %d5, least   #
 # in %d6. The divisor must be in the variable ddivisor, and the         #
 # signed/unsigned flag ddusign must be set (0=unsigned,1=signed).       #
 # The quotient is returned in %d6, remainder in %d5, unless the         #
 # v (overflow) bit is set in the saved %ccr. If overflow, the dividend  #
 # is unchanged.                                                         #
 #########################################################################
 ldclassical:
 # if the divisor msw is 0, use simpler algorithm then the full blown
 # one at ddknuth:
 
         cmpi.l          %d7, &0xffff
         bhi.b           lddknuth                # go use D. Knuth algorithm
 
 # Since the divisor is only a word (and larger than the mslw of the dividend),
 # a simpler algorithm may be used :
 # In the general case, four quotient words would be created by
 # dividing the divisor word into each dividend word. In this case,
 # the first two quotient words must be zero, or overflow would occur.
 # Since we already checked this case above, we can treat the most significant
 # longword of the dividend as (0) remainder (see Knuth) and merely complete
 # the last two divisions to get a quotient longword and word remainder:
 
         clr.l           %d1
         swap            %d5                     # same as r*b if previous step rqd
         swap            %d6                     # get u3 to lsw position
         mov.w           %d6, %d5                # rb + u3
 
         divu.w          %d7, %d5
 
         mov.w           %d5, %d1                # first quotient word
         swap            %d6                     # get u4
         mov.w           %d6, %d5                # rb + u4
 
         divu.w          %d7, %d5
 
         swap            %d1
         mov.w           %d5, %d1                # 2nd quotient 'digit'
         clr.w           %d5
         swap            %d5                     # now remainder
         mov.l           %d1, %d6                # and quotient
 
         rts
 
 lddknuth:
 # In this algorithm, the divisor is treated as a 2 digit (word) number
 # which is divided into a 3 digit (word) dividend to get one quotient
 # digit (word). After subtraction, the dividend is shifted and the
 # process repeated. Before beginning, the divisor and quotient are
 # 'normalized' so that the process of estimating the quotient digit
 # will yield verifiably correct results..
 
         clr.l           DDNORMAL(%a6)           # count of shifts for normalization
         clr.b           DDSECOND(%a6)           # clear flag for quotient digits
         clr.l           %d1                     # %d1 will hold trial quotient
 lddnchk:
         btst            &31, %d7                # must we normalize? first word of
         bne.b           lddnormalized           # divisor (V1) must be >= 65536/2
         addq.l          &0x1, DDNORMAL(%a6)     # count normalization shifts
         lsl.l           &0x1, %d7               # shift the divisor
         lsl.l           &0x1, %d6               # shift u4,u3 with overflow to u2
         roxl.l          &0x1, %d5               # shift u1,u2
         bra.w           lddnchk
 lddnormalized:
 
 # Now calculate an estimate of the quotient words (msw first, then lsw).
 # The comments use subscripts for the first quotient digit determination.
         mov.l           %d7, %d3                # divisor
         mov.l           %d5, %d2                # dividend mslw
         swap            %d2
         swap            %d3
         cmp.w           %d2, %d3                # V1 = U1 ?
         bne.b           lddqcalc1
         mov.w           &0xffff, %d1            # use max trial quotient word
         bra.b           lddadj0
 lddqcalc1:
         mov.l           %d5, %d1
 
         divu.w          %d3, %d1                # use quotient of mslw/msw
 
         andi.l          &0x0000ffff, %d1        # zero any remainder
 lddadj0:
 
 # now test the trial quotient and adjust. This step plus the
 # normalization assures (according to Knuth) that the trial
 # quotient will be at worst 1 too large.
         mov.l           %d6, -(%sp)
         clr.w           %d6                     # word u3 left
         swap            %d6                     # in lsw position
 lddadj1: mov.l          %d7, %d3
         mov.l           %d1, %d2
         mulu.w          %d7, %d2                # V2q
         swap            %d3
         mulu.w          %d1, %d3                # V1q
         mov.l           %d5, %d4                # U1U2
         sub.l           %d3, %d4                # U1U2 - V1q
 
         swap            %d4
 
         mov.w           %d4,%d0
         mov.w           %d6,%d4                 # insert lower word (U3)
 
         tst.w           %d0                     # is upper word set?
         bne.w           lddadjd1
 
 #       add.l           %d6, %d4                # (U1U2 - V1q) + U3
 
         cmp.l           %d2, %d4
         bls.b           lddadjd1                # is V2q > (U1U2-V1q) + U3 ?
         subq.l          &0x1, %d1               # yes, decrement and recheck
         bra.b           lddadj1
 lddadjd1:
 # now test the word by multiplying it by the divisor (V1V2) and comparing
 # the 3 digit (word) result with the current dividend words
         mov.l           %d5, -(%sp)             # save %d5 (%d6 already saved)
         mov.l           %d1, %d6
         swap            %d6                     # shift answer to ms 3 words
         mov.l           %d7, %d5
         bsr.l           ldmm2
         mov.l           %d5, %d2                # now %d2,%d3 are trial*divisor
         mov.l           %d6, %d3
         mov.l           (%sp)+, %d5             # restore dividend
         mov.l           (%sp)+, %d6
         sub.l           %d3, %d6
         subx.l          %d2, %d5                # subtract double precision
         bcc             ldd2nd                  # no carry, do next quotient digit
         subq.l          &0x1, %d1               # q is one too large
 # need to add back divisor longword to current ms 3 digits of dividend
 # - according to Knuth, this is done only 2 out of 65536 times for random
 # divisor, dividend selection.
         clr.l           %d2
         mov.l           %d7, %d3
         swap            %d3
         clr.w           %d3                     # %d3 now ls word of divisor
         add.l           %d3, %d6                # aligned with 3rd word of dividend
         addx.l          %d2, %d5
         mov.l           %d7, %d3
         clr.w           %d3                     # %d3 now ms word of divisor
         swap            %d3                     # aligned with 2nd word of dividend
         add.l           %d3, %d5
 ldd2nd:
         tst.b           DDSECOND(%a6)   # both q words done?
         bne.b           lddremain
 # first quotient digit now correct. store digit and shift the
 # (subtracted) dividend
         mov.w           %d1, DDQUOTIENT(%a6)
         clr.l           %d1
         swap            %d5
         swap            %d6
         mov.w           %d6, %d5
         clr.w           %d6
         st              DDSECOND(%a6)           # second digit
         bra.w           lddnormalized
 lddremain:
 # add 2nd word to quotient, get the remainder.
         mov.w           %d1, DDQUOTIENT+2(%a6)
 # shift down one word/digit to renormalize remainder.
         mov.w           %d5, %d6
         swap            %d6
         swap            %d5
         mov.l           DDNORMAL(%a6), %d7      # get norm shift count
         beq.b           lddrn
         subq.l          &0x1, %d7               # set for loop count
 lddnlp:
         lsr.l           &0x1, %d5               # shift into %d6
         roxr.l          &0x1, %d6
         dbf             %d7, lddnlp
 lddrn:
         mov.l           %d6, %d5                # remainder
         mov.l           DDQUOTIENT(%a6), %d6    # quotient
 
         rts
 ldmm2:
 # factors for the 32X32->64 multiplication are in %d5 and %d6.
 # returns 64 bit result in %d5 (hi) %d6(lo).
 # destroys %d2,%d3,%d4.
 
 # multiply hi,lo words of each factor to get 4 intermediate products
         mov.l           %d6, %d2
         mov.l           %d6, %d3
         mov.l           %d5, %d4
         swap            %d3
         swap            %d4
         mulu.w          %d5, %d6                # %d6 <- lsw*lsw
         mulu.w          %d3, %d5                # %d5 <- msw-dest*lsw-source
         mulu.w          %d4, %d2                # %d2 <- msw-source*lsw-dest
         mulu.w          %d4, %d3                # %d3 <- msw*msw
 # now use swap and addx to consolidate to two longwords
         clr.l           %d4
         swap            %d6
         add.w           %d5, %d6                # add msw of l*l to lsw of m*l product
         addx.w          %d4, %d3                # add any carry to m*m product
         add.w           %d2, %d6                # add in lsw of other m*l product
         addx.w          %d4, %d3                # add any carry to m*m product
         swap            %d6                     # %d6 is low 32 bits of final product
         clr.w           %d5
         clr.w           %d2                     # lsw of two mixed products used,
         swap            %d5                     # now use msws of longwords
         swap            %d2
         add.l           %d2, %d5
         add.l           %d3, %d5        # %d5 now ms 32 bits of final product
         rts
 
 #########################################################################
 # XDEF **************************************************************** #
 #       _060LSP__imulu64_(): Emulate 64-bit unsigned mul instruction    #
 #       _060LSP__imuls64_(): Emulate 64-bit signed mul instruction.     #
 #                                                                       #
 #       This is the library version which is accessed as a subroutine   #
 #       and therefore does not work exactly like the 680X0 mul{s,u}.l   #
 #       64-bit multiply instruction.                                    #
 #                                                                       #
 # XREF **************************************************************** #
 #       None                                                            #
 #                                                                       #
 # INPUT *************************************************************** #
 #       0x4(sp) = multiplier                                            #
 #       0x8(sp) = multiplicand                                          #
 #       0xc(sp) = pointer to location to place 64-bit result            #
 #                                                                       #
 # OUTPUT ************************************************************** #
 #       0xc(sp) = points to location of 64-bit result                   #
 #                                                                       #
 # ALGORITHM *********************************************************** #
 #       Perform the multiply in pieces using 16x16->32 unsigned         #
 # multiplies and "add" instructions.                                    #
 #       Set the condition codes as appropriate before performing an     #
 # "rts".                                                                #
 #                                                                       #
 #########################################################################
 
 set MUL64_CC, -4
 
         global          _060LSP__imulu64_
 _060LSP__imulu64_:
 
 # PROLOGUE BEGIN ########################################################
         link.w          %a6,&-4
         movm.l          &0x3800,-(%sp)          # save d2-d4
 #       fmovm.l         &0x0,-(%sp)             # save no fpregs
 # PROLOGUE END ##########################################################
 
         mov.w           %cc,MUL64_CC(%a6)       # save incoming ccodes
 
         mov.l           0x8(%a6),%d0            # store multiplier in d0
         beq.w           mulu64_zero             # handle zero separately
 
         mov.l           0xc(%a6),%d1            # get multiplicand in d1
         beq.w           mulu64_zero             # handle zero separately
 
 #########################################################################
 #       63                         32                           0       #
 #       ----------------------------                                    #
 #       | hi(mplier) * hi(mplicand)|                                    #
 #       ----------------------------                                    #
 #                    -----------------------------                      #
 #                    | hi(mplier) * lo(mplicand) |                      #
 #                    -----------------------------                      #
 #                    -----------------------------                      #
 #                    | lo(mplier) * hi(mplicand) |                      #
 #                    -----------------------------                      #
 #         |                        -----------------------------        #
 #       --|--                      | lo(mplier) * lo(mplicand) |        #
 #         |                        -----------------------------        #
 #       ========================================================        #
 #       --------------------------------------------------------        #
 #       |       hi(result)         |        lo(result)         |        #
 #       --------------------------------------------------------        #
 #########################################################################
 mulu64_alg:
 # load temp registers with operands
         mov.l           %d0,%d2                 # mr in d2
         mov.l           %d0,%d3                 # mr in d3
         mov.l           %d1,%d4                 # md in d4
         swap            %d3                     # hi(mr) in lo d3
         swap            %d4                     # hi(md) in lo d4
 
 # complete necessary multiplies:
         mulu.w          %d1,%d0                 # [1] lo(mr) * lo(md)
         mulu.w          %d3,%d1                 # [2] hi(mr) * lo(md)
         mulu.w          %d4,%d2                 # [3] lo(mr) * hi(md)
         mulu.w          %d4,%d3                 # [4] hi(mr) * hi(md)
 
 # add lo portions of [2],[3] to hi portion of [1].
 # add carries produced from these adds to [4].
 # lo([1]) is the final lo 16 bits of the result.
         clr.l           %d4                     # load d4 w/ zero value
         swap            %d0                     # hi([1]) <==> lo([1])
         add.w           %d1,%d0                 # hi([1]) + lo([2])
         addx.l          %d4,%d3                 #    [4]  + carry
         add.w           %d2,%d0                 # hi([1]) + lo([3])
         addx.l          %d4,%d3                 #    [4]  + carry
         swap            %d0                     # lo([1]) <==> hi([1])
 
 # lo portions of [2],[3] have been added in to final result.
 # now, clear lo, put hi in lo reg, and add to [4]
         clr.w           %d1                     # clear lo([2])
         clr.w           %d2                     # clear hi([3])
         swap            %d1                     # hi([2]) in lo d1
         swap            %d2                     # hi([3]) in lo d2
         add.l           %d2,%d1                 #    [4]  + hi([2])
         add.l           %d3,%d1                 #    [4]  + hi([3])
 
 # now, grab the condition codes. only one that can be set is 'N'.
 # 'N' CAN be set if the operation is unsigned if bit 63 is set.
         mov.w           MUL64_CC(%a6),%d4
         andi.b          &0x10,%d4               # keep old 'X' bit
         tst.l           %d1                     # may set 'N' bit
         bpl.b           mulu64_ddone
         ori.b           &0x8,%d4                # set 'N' bit
 mulu64_ddone:
         mov.w           %d4,%cc
 
 # here, the result is in d1 and d0. the current strategy is to save
 # the values at the location pointed to by a0.
 # use movm here to not disturb the condition codes.
 mulu64_end:
         exg             %d1,%d0
         movm.l          &0x0003,([0x10,%a6])            # save result
 
 # EPILOGUE BEGIN ########################################################
 #       fmovm.l         (%sp)+,&0x0             # restore no fpregs
         movm.l          (%sp)+,&0x001c          # restore d2-d4
         unlk            %a6
 # EPILOGUE END ##########################################################
 
         rts
 
 # one or both of the operands is zero so the result is also zero.
 # save the zero result to the register file and set the 'Z' ccode bit.
 mulu64_zero:
         clr.l           %d0
         clr.l           %d1
 
         mov.w           MUL64_CC(%a6),%d4
         andi.b          &0x10,%d4
         ori.b           &0x4,%d4
         mov.w           %d4,%cc                 # set 'Z' ccode bit
 
         bra.b           mulu64_end
 
 ##########
 # muls.l #
 ##########
         global          _060LSP__imuls64_
 _060LSP__imuls64_:
 
 # PROLOGUE BEGIN ########################################################
         link.w          %a6,&-4
         movm.l          &0x3c00,-(%sp)          # save d2-d5
 #       fmovm.l         &0x0,-(%sp)             # save no fpregs
 # PROLOGUE END ##########################################################
 
         mov.w           %cc,MUL64_CC(%a6)       # save incoming ccodes
 
         mov.l           0x8(%a6),%d0            # store multiplier in d0
         beq.b           mulu64_zero             # handle zero separately
 
         mov.l           0xc(%a6),%d1            # get multiplicand in d1
         beq.b           mulu64_zero             # handle zero separately
 
         clr.b           %d5                     # clear sign tag
         tst.l           %d0                     # is multiplier negative?
         bge.b           muls64_chk_md_sgn       # no
         neg.l           %d0                     # make multiplier positive
 
         ori.b           &0x1,%d5                # save multiplier sgn
 
 # the result sign is the exclusive or of the operand sign bits.
 muls64_chk_md_sgn:
         tst.l           %d1                     # is multiplicand negative?
         bge.b           muls64_alg              # no
         neg.l           %d1                     # make multiplicand positive
 
         eori.b          &0x1,%d5                # calculate correct sign
 
 #########################################################################
 #       63                         32                           0       #
 #       ----------------------------                                    #
 #       | hi(mplier) * hi(mplicand)|                                    #
 #       ----------------------------                                    #
 #                    -----------------------------                      #
 #                    | hi(mplier) * lo(mplicand) |                      #
 #                    -----------------------------                      #
 #                    -----------------------------                      #
 #                    | lo(mplier) * hi(mplicand) |                      #
 #                    -----------------------------                      #
 #         |                        -----------------------------        #
 #       --|--                      | lo(mplier) * lo(mplicand) |        #
 #         |                        -----------------------------        #
 #       ========================================================        #
 #       --------------------------------------------------------        #
 #       |       hi(result)         |        lo(result)         |        #
 #       --------------------------------------------------------        #
 #########################################################################
 muls64_alg:
 # load temp registers with operands
         mov.l           %d0,%d2                 # mr in d2
         mov.l           %d0,%d3                 # mr in d3
         mov.l           %d1,%d4                 # md in d4
         swap            %d3                     # hi(mr) in lo d3
         swap            %d4                     # hi(md) in lo d4
 
 # complete necessary multiplies:
         mulu.w          %d1,%d0                 # [1] lo(mr) * lo(md)
         mulu.w          %d3,%d1                 # [2] hi(mr) * lo(md)
         mulu.w          %d4,%d2                 # [3] lo(mr) * hi(md)
         mulu.w          %d4,%d3                 # [4] hi(mr) * hi(md)
 
 # add lo portions of [2],[3] to hi portion of [1].
 # add carries produced from these adds to [4].
 # lo([1]) is the final lo 16 bits of the result.
         clr.l           %d4                     # load d4 w/ zero value
         swap            %d0                     # hi([1]) <==> lo([1])
         add.w           %d1,%d0                 # hi([1]) + lo([2])
         addx.l          %d4,%d3                 #    [4]  + carry
         add.w           %d2,%d0                 # hi([1]) + lo([3])
         addx.l          %d4,%d3                 #    [4]  + carry
         swap            %d0                     # lo([1]) <==> hi([1])
 
 # lo portions of [2],[3] have been added in to final result.
 # now, clear lo, put hi in lo reg, and add to [4]
         clr.w           %d1                     # clear lo([2])
         clr.w           %d2                     # clear hi([3])
         swap            %d1                     # hi([2]) in lo d1
         swap            %d2                     # hi([3]) in lo d2
         add.l           %d2,%d1                 #    [4]  + hi([2])
         add.l           %d3,%d1                 #    [4]  + hi([3])
 
         tst.b           %d5                     # should result be signed?
         beq.b           muls64_done             # no
 
 # result should be a signed negative number.
 # compute 2's complement of the unsigned number:
 #   -negate all bits and add 1
 muls64_neg:
         not.l           %d0                     # negate lo(result) bits
         not.l           %d1                     # negate hi(result) bits
         addq.l          &1,%d0                  # add 1 to lo(result)
         addx.l          %d4,%d1                 # add carry to hi(result)
 
 muls64_done:
         mov.w           MUL64_CC(%a6),%d4
         andi.b          &0x10,%d4               # keep old 'X' bit
         tst.l           %d1                     # may set 'N' bit
         bpl.b           muls64_ddone
         ori.b           &0x8,%d4                # set 'N' bit
 muls64_ddone:
         mov.w           %d4,%cc
 
 # here, the result is in d1 and d0. the current strategy is to save
 # the values at the location pointed to by a0.
 # use movm here to not disturb the condition codes.
 muls64_end:
         exg             %d1,%d0
         movm.l          &0x0003,([0x10,%a6])    # save result at (a0)
 
 # EPILOGUE BEGIN ########################################################
 #       fmovm.l         (%sp)+,&0x0             # restore no fpregs
         movm.l          (%sp)+,&0x003c          # restore d2-d5
         unlk            %a6
 # EPILOGUE END ##########################################################
 
         rts
 
 # one or both of the operands is zero so the result is also zero.
 # save the zero result to the register file and set the 'Z' ccode bit.
 muls64_zero:
         clr.l           %d0
         clr.l           %d1
 
         mov.w           MUL64_CC(%a6),%d4
         andi.b          &0x10,%d4
         ori.b           &0x4,%d4
         mov.w           %d4,%cc                 # set 'Z' ccode bit
 
         bra.b           muls64_end
 
 #########################################################################
 # XDEF **************************************************************** #
 #       _060LSP__cmp2_Ab_(): Emulate "cmp2.b An,<ea>".                  #
 #       _060LSP__cmp2_Aw_(): Emulate "cmp2.w An,<ea>".                  #
 #       _060LSP__cmp2_Al_(): Emulate "cmp2.l An,<ea>".                  #
 #       _060LSP__cmp2_Db_(): Emulate "cmp2.b Dn,<ea>".                  #
 #       _060LSP__cmp2_Dw_(): Emulate "cmp2.w Dn,<ea>".                  #
 #       _060LSP__cmp2_Dl_(): Emulate "cmp2.l Dn,<ea>".                  #
 #                                                                       #
 #       This is the library version which is accessed as a subroutine   #
 #       and therefore does not work exactly like the 680X0 "cmp2"       #
 #       instruction.                                                    #
 #                                                                       #
 # XREF **************************************************************** #
 #       None                                                            #
 #                                                                       #
 # INPUT *************************************************************** #
 #       0x4(sp) = Rn                                                    #
 #       0x8(sp) = pointer to boundary pair                              #
 #                                                                       #
 # OUTPUT ************************************************************** #
 #       cc = condition codes are set correctly                          #
 #                                                                       #
 # ALGORITHM *********************************************************** #
 #       In the interest of simplicity, all operands are converted to    #
 # longword size whether the operation is byte, word, or long. The       #
 # bounds are sign extended accordingly. If Rn is a data register, Rn is #
 # also sign extended. If Rn is an address register, it need not be sign #
 # extended since the full register is always used.                      #
 #       The condition codes are set correctly before the final "rts".   #
 #                                                                       #
 #########################################################################
 
 set     CMP2_CC,        -4
 
         global          _060LSP__cmp2_Ab_
 _060LSP__cmp2_Ab_:
 
 # PROLOGUE BEGIN ########################################################
         link.w          %a6,&-4
         movm.l          &0x3800,-(%sp)          # save d2-d4
 #       fmovm.l         &0x0,-(%sp)             # save no fpregs
 # PROLOGUE END ##########################################################
 
         mov.w           %cc,CMP2_CC(%a6)
         mov.l           0x8(%a6), %d2           # get regval
 
         mov.b           ([0xc,%a6],0x0),%d0
         mov.b           ([0xc,%a6],0x1),%d1
 
         extb.l          %d0                     # sign extend lo bnd
         extb.l          %d1                     # sign extend hi bnd
         bra.w           l_cmp2_cmp              # go do the compare emulation
 
         global          _060LSP__cmp2_Aw_
 _060LSP__cmp2_Aw_:
 
 # PROLOGUE BEGIN ########################################################
         link.w          %a6,&-4
         movm.l          &0x3800,-(%sp)          # save d2-d4
 #       fmovm.l         &0x0,-(%sp)             # save no fpregs
 # PROLOGUE END ##########################################################
 
         mov.w           %cc,CMP2_CC(%a6)
         mov.l           0x8(%a6), %d2           # get regval
 
         mov.w           ([0xc,%a6],0x0),%d0
         mov.w           ([0xc,%a6],0x2),%d1
 
         ext.l           %d0                     # sign extend lo bnd
         ext.l           %d1                     # sign extend hi bnd
         bra.w           l_cmp2_cmp              # go do the compare emulation
 
         global          _060LSP__cmp2_Al_
 _060LSP__cmp2_Al_:
 
 # PROLOGUE BEGIN ########################################################
         link.w          %a6,&-4
         movm.l          &0x3800,-(%sp)          # save d2-d4
 #       fmovm.l         &0x0,-(%sp)             # save no fpregs
 # PROLOGUE END ##########################################################
 
         mov.w           %cc,CMP2_CC(%a6)
         mov.l           0x8(%a6), %d2           # get regval
 
         mov.l           ([0xc,%a6],0x0),%d0
         mov.l           ([0xc,%a6],0x4),%d1
         bra.w           l_cmp2_cmp              # go do the compare emulation
 
         global          _060LSP__cmp2_Db_
 _060LSP__cmp2_Db_:
 
 # PROLOGUE BEGIN ########################################################
         link.w          %a6,&-4
         movm.l          &0x3800,-(%sp)          # save d2-d4
 #       fmovm.l         &0x0,-(%sp)             # save no fpregs
 # PROLOGUE END ##########################################################
 
         mov.w           %cc,CMP2_CC(%a6)
         mov.l           0x8(%a6), %d2           # get regval
 
         mov.b           ([0xc,%a6],0x0),%d0
         mov.b           ([0xc,%a6],0x1),%d1
 
         extb.l          %d0                     # sign extend lo bnd
         extb.l          %d1                     # sign extend hi bnd
 
 # operation is a data register compare.
 # sign extend byte to long so we can do simple longword compares.
         extb.l          %d2                     # sign extend data byte
         bra.w           l_cmp2_cmp              # go do the compare emulation
 
         global          _060LSP__cmp2_Dw_
 _060LSP__cmp2_Dw_:
 
 # PROLOGUE BEGIN ########################################################
         link.w          %a6,&-4
         movm.l          &0x3800,-(%sp)          # save d2-d4
 #       fmovm.l         &0x0,-(%sp)             # save no fpregs
 # PROLOGUE END ##########################################################
 
         mov.w           %cc,CMP2_CC(%a6)
         mov.l           0x8(%a6), %d2           # get regval
 
         mov.w           ([0xc,%a6],0x0),%d0
         mov.w           ([0xc,%a6],0x2),%d1
 
         ext.l           %d0                     # sign extend lo bnd
         ext.l           %d1                     # sign extend hi bnd
 
 # operation is a data register compare.
 # sign extend word to long so we can do simple longword compares.
         ext.l           %d2                     # sign extend data word
         bra.w           l_cmp2_cmp              # go emulate compare
 
         global          _060LSP__cmp2_Dl_
 _060LSP__cmp2_Dl_:
 
 # PROLOGUE BEGIN ########################################################
         link.w          %a6,&-4
         movm.l          &0x3800,-(%sp)          # save d2-d4
 #       fmovm.l         &0x0,-(%sp)             # save no fpregs
 # PROLOGUE END ##########################################################
 
         mov.w           %cc,CMP2_CC(%a6)
         mov.l           0x8(%a6), %d2           # get regval
 
         mov.l           ([0xc,%a6],0x0),%d0
         mov.l           ([0xc,%a6],0x4),%d1
 
 #
 # To set the ccodes correctly:
 #       (1) save 'Z' bit from (Rn - lo)
 #       (2) save 'Z' and 'N' bits from ((hi - lo) - (Rn - hi))
 #       (3) keep 'X', 'N', and 'V' from before instruction
 #       (4) combine ccodes
 #
 l_cmp2_cmp:
         sub.l           %d0, %d2                # (Rn - lo)
         mov.w           %cc, %d3                # fetch resulting ccodes
         andi.b          &0x4, %d3               # keep 'Z' bit
         sub.l           %d0, %d1                # (hi - lo)
         cmp.l           %d1,%d2                 # ((hi - lo) - (Rn - hi))
 
         mov.w           %cc, %d4                # fetch resulting ccodes
         or.b            %d4, %d3                # combine w/ earlier ccodes
         andi.b          &0x5, %d3               # keep 'Z' and 'N'
 
         mov.w           CMP2_CC(%a6), %d4       # fetch old ccodes
         andi.b          &0x1a, %d4              # keep 'X','N','V' bits
         or.b            %d3, %d4                # insert new ccodes
         mov.w           %d4,%cc                 # save new ccodes
 
 # EPILOGUE BEGIN ########################################################
 #       fmovm.l         (%sp)+,&0x0             # restore no fpregs
         movm.l          (%sp)+,&0x001c          # restore d2-d4
         unlk            %a6
 # EPILOGUE END ##########################################################
 
         rts

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