/* * Copyright (c) 2002-2004 Apple Computer, Inc. All rights reserved. * * @APPLE_LICENSE_HEADER_START@ * * The contents of this file constitute Original Code as defined in and * are subject to the Apple Public Source License Version 1.1 (the * "License"). You may not use this file except in compliance with the * License. Please obtain a copy of the License at * http://www.apple.com/publicsource and read it before using this file. * * This Original Code and all software distributed under the License are * distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY KIND, EITHER * EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES, * INCLUDING WITHOUT LIMITATION, ANY WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE OR NON-INFRINGEMENT. Please see the * License for the specific language governing rights and limitations * under the License. * * @APPLE_LICENSE_HEADER_END@ */ ; ; Copy bytes of data around. Handles overlapped data. ; ; #include #include #include ; These routines use CR5 for certain flags: ; Use CR5_lt to indicate non-cached (in bcopy and memcpy) #define noncache 20 ; The bcopy_phys variants use a stack frame so they can call bcopy as a subroutine. #define BCOPY_SF_SIZE 32 // total size #define BCOPY_SF_MSR 16 // we save caller's MSR here (possibly minus VEC and FP) #define kShort 32 // short operands are special cased ; void bcopy_physvir_32(from, to, nbytes) ; ; Attempt to copy physically addressed memory with translation on if conditions are met. ; Otherwise do a normal bcopy_phys. This routine is used because some 32-bit processors ; are very slow doing real-mode (translation off) copies, so we set up temporary BATs ; for the passed phys addrs and do the copy with translation on. ; ; Rules are: - neither source nor destination can cross a page. ; - Interrupts must be disabled when this routine is called. ; - Translation must be on when called. ; ; To do the copy, we build a 128 DBAT for both the source and sink. If both are the same, only one ; is loaded. We do not touch the IBATs, so there is no issue if either physical page ; address is the same as the virtual address of the instructions we are executing. ; ; At the end, we invalidate the used DBATs. ; ; Note that the address parameters are long longs. We will transform these to 64-bit ; values. Note that on 32-bit architectures that this will ignore the high half of the ; passed in value. This should be ok since we can not have any bigger than 32 bit addresses ; there anyhow. ; ; Note also that this routine is used only on 32-bit machines. If you're contemplating use ; on a 64-bit processor, use the physical memory window instead; please refer to copypv() ; for an example of how this is done. .align 5 .globl EXT(bcopy_physvir_32) LEXT(bcopy_physvir_32) mflr r0 ; get return address rlwinm r3,r3,0,1,0 ; Duplicate high half of long long paddr into top of reg mfsprg r8,2 ; get processor feature flags stw r0,8(r1) ; save return address rlwimi r3,r4,0,0,31 ; Combine bottom of long long to full 64-bits stwu r1,-BCOPY_SF_SIZE(r1) ; push on a stack frame so we can call bcopy mtcrf 0x02,r8 ; move pf64Bit to cr6 so we can test subi r0,r7,1 ; get length - 1 rlwinm r4,r5,0,1,0 ; Duplicate high half of long long paddr into top of reg add r11,r3,r0 ; Point to last byte of sink mr r5,r7 ; Get the length into the right register rlwimi r4,r6,0,0,31 ; Combine bottom of long long to full 64-bits ; This test for page overflow may not work if the length is negative. Negative lengths are invalid input ; to bcopy_physvir() on 32-bit machines, and will result in a panic. add r12,r4,r0 ; Point to last byte of source xor r7,r11,r3 ; See if we went to next page xor r8,r12,r4 ; See if we went to next page or r0,r7,r8 ; Combine wrap // li r9,((PTE_WIMG_CB_CACHED_COHERENT<<3)|2) ; Set default attributes li r9,((2<<3)|2) ; Set default attributes rlwinm. r0,r0,0,0,19 ; Did we overflow a page? li r7,2 ; Set validity flags li r8,2 ; Set validity flags bne- bcopy_phys1 ; Overflowed page, do normal physical copy... rlwimi r11,r9,0,15,31 ; Set sink lower DBAT value rlwimi r12,r9,0,15,31 ; Set source lower DBAT value rlwimi r7,r11,0,0,14 ; Set sink upper DBAT value rlwimi r8,r12,0,0,14 ; Set source upper DBAT value cmplw cr1,r11,r12 ; See if sink and source are same block sync mtdbatl 0,r11 ; Set sink lower DBAT mtdbatu 0,r7 ; Set sink upper DBAT beq- cr1,bcpvsame ; Source and sink are in same block mtdbatl 1,r12 ; Set source lower DBAT mtdbatu 1,r8 ; Set source upper DBAT bcpvsame: sync ; wait for the BATs to stabilize isync bl EXT(bcopy) ; BATs set up, args in r3-r5, so do the copy with DR on li r0,0 ; Get set to invalidate upper half of BATs sync ; Make sure all is well mtdbatu 0,r0 ; Clear sink upper DBAT mtdbatu 1,r0 ; Clear source upper DBAT sync isync lwz r0,BCOPY_SF_SIZE+8(r1) ; get return address addi r1,r1,BCOPY_SF_SIZE ; pop off stack frame mtlr r0 blr ; void bcopy_phys(from, to, nbytes) ; ; Turns off data translation before the copy. This one will not work in user state. ; This routine is used on 32 and 64-bit machines. ; ; Note that the address parameters are long longs. We will transform these to 64-bit ; values. Note that on 32-bit architectures that this will ignore the high half of the ; passed in value. This should be ok since we can not have any bigger than 32 bit addresses ; there anyhow. ; ; Also note that you probably will not be happy if either the sink or source spans across the ; boundary between RAM and I/O space. Good chance of hanging the machine and this code ; will not check, so be careful. ; ; NOTE: when called, translation must be on, and we must be in 32-bit mode. ; Interrupts may or may not be disabled. .align 5 .globl EXT(bcopy_phys) LEXT(bcopy_phys) mflr r0 ; get return address rlwinm r3,r3,0,1,0 ; Duplicate high half of long long paddr into top of reg stw r0,8(r1) ; save mfsprg r8,2 ; get processor feature flags stwu r1,-BCOPY_SF_SIZE(r1) ; push on a stack frame so we can call bcopy rlwimi r3,r4,0,0,31 ; Combine bottom of long long to full 64-bits rlwinm r4,r5,0,1,0 ; Duplicate high half of long long paddr into top of reg mtcrf 0x02,r8 ; move pf64Bit to cr6 so we can test rlwimi r4,r6,0,0,31 ; Combine bottom of long long to full 64-bits mr r5,r7 ; Get the length into the right register bcopy_phys1: ; enter from bcopy_physvir with pf64Bit in cr6 and parms in r3-r5 mfmsr r9 ; Get the MSR lis r6,hi16(MASK(MSR_VEC)) ; Get vector enable ori r6,r6,lo16(MASK(MSR_FP)|MASK(MSR_DR)) ; Add in FP and DR andc r9,r9,r6 ; unconditionally turn DR, VEC, and FP off bt++ pf64Bitb,bcopy_phys64 ; skip if 64-bit (only they take hint) ; 32-bit CPUs mtmsr r9 ; turn DR, FP, and VEC off isync ; Wait for it bl EXT(bcopy) ; do the copy with translation off and caching on mfmsr r9 ; Get the MSR ori r9,r9,lo16(MASK(MSR_DR)) ; turn translation back on (but leave VEC and FP off) mtmsr r9 ; restore msr isync ; wait for it to happen lwz r0,BCOPY_SF_SIZE+8(r1) ; get return address once translation is back on mtlr r0 addi r1,r1,BCOPY_SF_SIZE ; pop off stack frame blr ; 64-bit: turn DR off and SF on. bcopy_phys64: ; r9 = MSR with DP, VEC, and FP off ori r8,r9,lo16(MASK(MSR_DR)) ; make a copy with DR back on... this is what we return to caller srdi r2,r3,31 ; Get a 1 if source is in I/O memory li r0,1 ; Note - we use this in a couple places below srdi r10,r4,31 ; Get a 1 if sink is in I/O memory std r8,BCOPY_SF_MSR(r1) ; save caller's MSR so we remember whether EE was on rldimi r9,r0,63,MSR_SF_BIT ; set SF on in MSR we will copy with cmpldi cr0,r2,1 ; Is source in I/O memory? cmpldi cr7,r10,1 ; Is sink in I/O memory? mtmsrd r9 ; turn 64-bit addressing on, data translation off isync ; wait for it to happen cror cr7_eq,cr0_eq,cr7_eq ; See if either source or sink is in I/O area beq-- cr7,io_space_real_mode_copy ; an operand is in I/O space bl EXT(bcopy) ; do copy with DR off and SF on, cache enabled bcopy_phys64x: mfmsr r9 ; Get the MSR we used to copy rldicl r9,r9,0,MSR_SF_BIT+1 ; clear SF ori r9,r9,lo16(MASK(MSR_DR)) ; turn translation back on mtmsrd r9 ; turn 64-bit mode off, translation back on isync ; wait for it to happen lwz r0,BCOPY_SF_SIZE+8(r1) ; get return address once translation is back on ld r8,BCOPY_SF_MSR(r1) ; get caller's MSR once translation is back on mtlr r0 mtmsrd r8,1 ; turn EE back on if necessary addi r1,r1,BCOPY_SF_SIZE ; pop off stack frame blr ; We need to copy with DR off, but one of the operands is in I/O space. To avoid wedging U3, ; which cannot handle a cache burst in I/O space, we must turn caching off for the real memory access. ; This can only be done by setting bits in HID4. We cannot lose control and execute random code in ; this state, so we have to disable interrupts as well. This is an unpleasant hack. io_space_real_mode_copy: ; r0=1, r9=MSR we want to copy with sldi r11,r0,31-MSR_EE_BIT ; Get a mask for the EE bit sldi r0,r0,32+8 ; Get the right bit to turn off caching andc r9,r9,r11 ; Turn off EE bit mfspr r2,hid4 ; Get HID4 mtmsrd r9,1 ; Force off EE or r2,r2,r0 ; Set bit to make real accesses cache-inhibited sync ; Sync up mtspr hid4,r2 ; Make real accesses cache-inhibited isync ; Toss prefetches lis r12,0xE000 ; Get the unlikeliest ESID possible srdi r12,r12,1 ; Make 0x7FFFFFFFF0000000 slbie r12 ; Make sure the ERAT is cleared sync isync bl EXT(bcopy_nc) ; copy with SF on and EE, DR, VEC, and FP off, cache inhibited li r0,1 ; Get a 1 sldi r0,r0,32+8 ; Get the right bit to turn off caching mfspr r2,hid4 ; Get HID4 andc r2,r2,r0 ; Clear bit to make real accesses cache-inhibited sync ; Sync up mtspr hid4,r2 ; Make real accesses not cache-inhibited isync ; Toss prefetches lis r12,0xE000 ; Get the unlikeliest ESID possible srdi r12,r12,1 ; Make 0x7FFFFFFFF0000000 slbie r12 ; Make sure the ERAT is cleared b bcopy_phys64x ; ; shortcopy ; ; Special case short operands (<32 bytes), which are very common. Note that the check for ; reverse vs normal moves isn't quite correct in 64-bit mode; in rare cases we will move in ; reverse when it wasn't necessary to do so. This is OK, since performance of the two cases ; is similar. We do get the direction right when it counts (ie, when the operands overlap.) ; Also note that we use the G3/G4 "backend" code, even on G5. This is OK too, since G5 has ; plenty of load/store dispatch bandwidth in this case, the extra ops are hidden by latency, ; and using word instead of doubleword moves reduces the possibility of unaligned accesses, ; which cost about 20 cycles if they cross a 32-byte boundary on G5. Finally, because we ; might do unaligned accesses this code cannot be called from bcopy_nc(). ; r4 = destination ; r5 = length (<32) ; r6 = source ; r12 = (dest - source) .align 5 shortcopy: cmplw r12,r5 ; must move reverse if (dest-source)0) ; r6 = source ; r12 = (dest - source) ; cr5 = noncache flag copyit32: ; WARNING! can drop down to this label cmplw cr1,r12,r5 ; must move reverse if (dest-source)0) ; r6 = source ; r8 = inverse of largest mask smaller than operand length ; r9 = neg(dest), used to compute alignment ; cr5 = noncache flag forward32bit: ; enter from 64-bit CPUs with word aligned uncached operands rlwinm r7,r9,0,0x1F ; get bytes to 32-byte-align destination andc. r0,r7,r8 ; limit to the maximum front end move mtcrf 0x01,r0 ; move length to cr6 and cr7 one cr at a time... beq alline ; Already on a line... mtcrf 0x02,r0 ; ...since moving more than one is slower on G4 and G5 sub r5,r5,r0 ; Set the length left to move bf 31,alhalf ; No single byte to do... lbz r7,0(r6) ; Get the byte addi r6,r6,1 ; Point to the next stb r7,0(r4) ; Save the single addi r4,r4,1 ; Bump sink ; Sink is halfword aligned here alhalf: bf 30,alword ; No halfword to do... lhz r7,0(r6) ; Get the halfword addi r6,r6,2 ; Point to the next sth r7,0(r4) ; Save the halfword addi r4,r4,2 ; Bump sink ; Sink is word aligned here alword: bf 29,aldouble ; No word to do... lwz r7,0(r6) ; Get the word addi r6,r6,4 ; Point to the next stw r7,0(r4) ; Save the word addi r4,r4,4 ; Bump sink ; Sink is double aligned here aldouble: bf 28,alquad ; No double to do... lwz r7,0(r6) ; Get the first word lwz r8,4(r6) ; Get the second word addi r6,r6,8 ; Point to the next stw r7,0(r4) ; Save the first word stw r8,4(r4) ; Save the second word addi r4,r4,8 ; Bump sink ; Sink is quadword aligned here alquad: bf 27,alline ; No quad to do... lwz r7,0(r6) ; Get the first word lwz r8,4(r6) ; Get the second word lwz r9,8(r6) ; Get the third word stw r7,0(r4) ; Save the first word lwz r11,12(r6) ; Get the fourth word addi r6,r6,16 ; Point to the next stw r8,4(r4) ; Save the second word stw r9,8(r4) ; Save the third word stw r11,12(r4) ; Save the fourth word addi r4,r4,16 ; Bump sink ; Sink is line aligned here alline: rlwinm. r0,r5,27,5,31 ; Get the number of full lines to move mtcrf 0x02,r5 ; move length to cr6 and cr7 one cr at a time... mtcrf 0x01,r5 ; ...since moving more than one is slower on G4 and G5 beq- backend ; No full lines to move mtctr r0 ; set up loop count li r0,96 ; Stride for touch ahead b nxtline .align 4 nxtline: lwz r2,0(r6) ; Get the first word lwz r5,4(r6) ; Get the second word lwz r7,8(r6) ; Get the third word lwz r8,12(r6) ; Get the fourth word lwz r9,16(r6) ; Get the fifth word lwz r10,20(r6) ; Get the sixth word lwz r11,24(r6) ; Get the seventh word lwz r12,28(r6) ; Get the eighth word bt- noncache,skipz ; Skip if we are not cached... dcbz 0,r4 ; Blow away the whole line because we are replacing it dcbt r6,r0 ; Touch ahead a bit skipz: addi r6,r6,32 ; Point to the next stw r2,0(r4) ; Save the first word stw r5,4(r4) ; Save the second word stw r7,8(r4) ; Save the third word stw r8,12(r4) ; Save the fourth word stw r9,16(r4) ; Save the fifth word stw r10,20(r4) ; Save the sixth word stw r11,24(r4) ; Save the seventh word stw r12,28(r4) ; Save the eighth word addi r4,r4,32 ; Bump sink bdnz+ nxtline ; Do the next line, if any... ; Move backend quadword backend: ; Join here from "shortcopy" for forward moves <32 bytes bf 27,noquad ; No quad to do... lwz r7,0(r6) ; Get the first word lwz r8,4(r6) ; Get the second word lwz r9,8(r6) ; Get the third word lwz r11,12(r6) ; Get the fourth word stw r7,0(r4) ; Save the first word addi r6,r6,16 ; Point to the next stw r8,4(r4) ; Save the second word stw r9,8(r4) ; Save the third word stw r11,12(r4) ; Save the fourth word addi r4,r4,16 ; Bump sink ; Move backend double noquad: bf 28,nodouble ; No double to do... lwz r7,0(r6) ; Get the first word lwz r8,4(r6) ; Get the second word addi r6,r6,8 ; Point to the next stw r7,0(r4) ; Save the first word stw r8,4(r4) ; Save the second word addi r4,r4,8 ; Bump sink ; Move backend word nodouble: bf 29,noword ; No word to do... lwz r7,0(r6) ; Get the word addi r6,r6,4 ; Point to the next stw r7,0(r4) ; Save the word addi r4,r4,4 ; Bump sink ; Move backend halfword noword: bf 30,nohalf ; No halfword to do... lhz r7,0(r6) ; Get the halfword addi r6,r6,2 ; Point to the next sth r7,0(r4) ; Save the halfword addi r4,r4,2 ; Bump sink ; Move backend byte nohalf: bflr 31 ; Leave cuz we are all done... lbz r7,0(r6) ; Get the byte stb r7,0(r4) ; Save the single blr ; Reverse moves on 32-bit machines, also reverse word aligned uncached moves on 64-bit machines. ; NOTE: we never do an unaligned access if the source and destination are "relatively" ; word aligned. We depend on this in the uncached case on 64-bit processors. ; These are slower because we don't bother with dcbz. Fortunately, reverse moves are uncommon. ; r4 = destination ; r5 = length (>0) ; r6 = source ; r8 = inverse of largest mask smaller than operand length ; cr5 = noncache flag (but we don't dcbz anyway) reverse32bit: ; here from 64-bit code with word aligned uncached operands add r4,r5,r4 ; Point past the last sink byte add r6,r5,r6 ; Point past the last source byte rlwinm r7,r4,0,0x1F ; Calculate the length to align dest on cache boundary li r12,-1 ; Make sure we touch in the actual line andc. r0,r7,r8 ; Apply movement limit dcbt r12,r6 ; Touch in the last line of source mtcrf 0x01,r0 ; move length to cr6 and cr7 one cr at a time... dcbtst r12,r4 ; Touch in the last line of the sink mtcrf 0x02,r0 ; ...since moving more than one is slower on G4 and G5 beq- balline ; Aready on cache line boundary (or too short to bother) sub r5,r5,r0 ; Precaculate move length left after alignment bf 31,balhalf ; No single byte to do... lbz r7,-1(r6) ; Get the byte subi r6,r6,1 ; Point to the next stb r7,-1(r4) ; Save the single subi r4,r4,1 ; Bump sink ; Sink is halfword aligned here balhalf: bf 30,balword ; No halfword to do... lhz r7,-2(r6) ; Get the halfword subi r6,r6,2 ; Point to the next sth r7,-2(r4) ; Save the halfword subi r4,r4,2 ; Bump sink ; Sink is word aligned here balword: bf 29,baldouble ; No word to do... lwz r7,-4(r6) ; Get the word subi r6,r6,4 ; Point to the next stw r7,-4(r4) ; Save the word subi r4,r4,4 ; Bump sink ; Sink is double aligned here baldouble: bf 28,balquad ; No double to do... lwz r7,-8(r6) ; Get the first word lwz r8,-4(r6) ; Get the second word subi r6,r6,8 ; Point to the next stw r7,-8(r4) ; Save the first word stw r8,-4(r4) ; Save the second word subi r4,r4,8 ; Bump sink ; Sink is quadword aligned here balquad: bf 27,balline ; No quad to do... lwz r7,-16(r6) ; Get the first word lwz r8,-12(r6) ; Get the second word lwz r9,-8(r6) ; Get the third word lwz r11,-4(r6) ; Get the fourth word stw r7,-16(r4) ; Save the first word subi r6,r6,16 ; Point to the next stw r8,-12(r4) ; Save the second word stw r9,-8(r4) ; Save the third word stw r11,-4(r4) ; Save the fourth word subi r4,r4,16 ; Bump sink ; Sink is line aligned here balline: rlwinm. r0,r5,27,5,31 ; Get the number of full lines to move mtcrf 0x02,r5 ; move length to cr6 and cr7 one cr at a time... mtcrf 0x01,r5 ; ...since moving more than one is slower on G4 and G5 beq- bbackend ; No full lines to move mtctr r0 ; set up loop count b bnxtline .align 4 bnxtline: lwz r7,-32(r6) ; Get the first word lwz r5,-28(r6) ; Get the second word lwz r2,-24(r6) ; Get the third word lwz r12,-20(r6) ; Get the third word lwz r11,-16(r6) ; Get the fifth word lwz r10,-12(r6) ; Get the sixth word lwz r9,-8(r6) ; Get the seventh word lwz r8,-4(r6) ; Get the eighth word subi r6,r6,32 ; Point to the next stw r7,-32(r4) ; Get the first word stw r5,-28(r4) ; Get the second word stw r2,-24(r4) ; Get the third word stw r12,-20(r4) ; Get the third word stw r11,-16(r4) ; Get the fifth word stw r10,-12(r4) ; Get the sixth word stw r9,-8(r4) ; Get the seventh word stw r8,-4(r4) ; Get the eighth word subi r4,r4,32 ; Bump sink bdnz+ bnxtline ; Do the next line, if any... ; ; Note: We touched these lines in at the beginning ; ; Move backend quadword bbackend: ; Join here from "shortcopy" for reverse moves of <32 bytes bf 27,bnoquad ; No quad to do... lwz r7,-16(r6) ; Get the first word lwz r8,-12(r6) ; Get the second word lwz r9,-8(r6) ; Get the third word lwz r11,-4(r6) ; Get the fourth word stw r7,-16(r4) ; Save the first word subi r6,r6,16 ; Point to the next stw r8,-12(r4) ; Save the second word stw r9,-8(r4) ; Save the third word stw r11,-4(r4) ; Save the fourth word subi r4,r4,16 ; Bump sink ; Move backend double bnoquad: bf 28,bnodouble ; No double to do... lwz r7,-8(r6) ; Get the first word lwz r8,-4(r6) ; Get the second word subi r6,r6,8 ; Point to the next stw r7,-8(r4) ; Save the first word stw r8,-4(r4) ; Save the second word subi r4,r4,8 ; Bump sink ; Move backend word bnodouble: bf 29,bnoword ; No word to do... lwz r7,-4(r6) ; Get the word subi r6,r6,4 ; Point to the next stw r7,-4(r4) ; Save the word subi r4,r4,4 ; Bump sink ; Move backend halfword bnoword: bf 30,bnohalf ; No halfword to do... lhz r7,-2(r6) ; Get the halfword subi r6,r6,2 ; Point to the next sth r7,-2(r4) ; Save the halfword subi r4,r4,2 ; Bump sink ; Move backend byte bnohalf: bflr 31 ; Leave cuz we are all done... lbz r7,-1(r6) ; Get the byte stb r7,-1(r4) ; Save the single blr // Here on 64-bit processors, which have a 128-byte cache line. This can be // called either in 32 or 64-bit mode, which makes the test for reverse moves // a little tricky. We've already filtered out the (sou==dest) and (len==0) // special cases. // // When entered: // r4 = destination (32 or 64-bit ptr) // r5 = length (always 32 bits) // r6 = source (32 or 64-bit ptr) // r12 = (dest - source), reverse move required if (dest-source)=length, in mode-independent way li r0,0 // get a 0 lis r10,hi16(0x80000000)// get 0x80000000 addze. r0,r0 // set cr0 on carry bit (beq if reverse move required) neg r9,r4 // start to get alignment for destination sraw r8,r10,r11 // get mask based on operand length, to limit alignment bt-- noncache,c64uncached// skip if uncached beq-- c64rdouble // handle cached reverse moves // Forward, cached or doubleword aligned uncached. This is the common case. // NOTE: we never do an unaligned access if the source and destination are "relatively" // doubleword aligned. We depend on this in the uncached case. // r4 = destination // r5 = length (>0) // r6 = source // r8 = inverse of largest mask smaller than operand length // r9 = neg(dest), used to compute alignment // cr5 = noncache flag c64double: rlwinm r7,r9,0,0x7F // get #bytes to 128-byte align destination andc r7,r7,r8 // limit by operand length andi. r8,r7,7 // r8 <- #bytes to doubleword align srwi r9,r7,3 // r9 <- #doublewords to 128-byte align sub r5,r5,r7 // adjust length remaining cmpwi cr1,r9,0 // any doublewords to move to cache align? srwi r10,r5,7 // r10 <- 128-byte chunks to xfer after aligning dest cmpwi cr7,r10,0 // set cr7 on chunk count beq c64double2 // dest already doubleword aligned mtctr r8 b c64double1 .align 5 // align inner loops c64double1: // copy bytes until dest is doubleword aligned lbz r0,0(r6) addi r6,r6,1 stb r0,0(r4) addi r4,r4,1 bdnz c64double1 c64double2: // r9/cr1=doublewords, r10/cr7=128-byte chunks beq cr1,c64double4 // no doublewords to xfer in order to cache align mtctr r9 b c64double3 .align 5 // align inner loops c64double3: // copy doublewords until dest is 128-byte aligned ld r7,0(r6) addi r6,r6,8 std r7,0(r4) addi r4,r4,8 bdnz c64double3 // Here to xfer 128-byte chunks, if any. Since we only have 8 GPRs for // data (64 bytes), we load/store each twice per 128-byte chunk. c64double4: // r10/cr7=128-byte chunks rlwinm r0,r5,29,28,31 // r0 <- count of leftover doublewords, after moving chunks cmpwi cr1,r0,0 // set cr1 on leftover doublewords beq cr7,c64double7 // no 128-byte chunks ; We must check for (source-dest)<128 in a mode-independent way. If within 128 bytes, ; turn on "noncache" because we cannot use dcbz128 even if operands are cacheable. sub r8,r6,r4 // r8 <- (source - dest) rldicr. r0,r8,0,63-7 // zero low 7 bits and check for 0, mode independent cror noncache,cr0_eq,noncache // turn on "noncache" flag if (source-dest)<128 mtctr r10 b c64InnerLoop .align 5 // align inner loop c64InnerLoop: // loop copying 128-byte cache lines to 128-aligned destination ld r0,0(r6) // start pipe: load 1st half-line ld r2,8(r6) ld r7,16(r6) ld r8,24(r6) ld r9,32(r6) ld r10,40(r6) ld r11,48(r6) ld r12,56(r6) bt noncache,c64InnerLoop1 // skip if uncached or overlap dcbz128 0,r4 // avoid prefetch of next cache line c64InnerLoop1: std r0,0(r4) std r2,8(r4) std r7,16(r4) std r8,24(r4) std r9,32(r4) std r10,40(r4) std r11,48(r4) std r12,56(r4) ld r0,64(r6) // load 2nd half of chunk ld r2,72(r6) ld r7,80(r6) ld r8,88(r6) ld r9,96(r6) ld r10,104(r6) ld r11,112(r6) ld r12,120(r6) addi r6,r6,128 std r0,64(r4) std r2,72(r4) std r7,80(r4) std r8,88(r4) std r9,96(r4) std r10,104(r4) std r11,112(r4) std r12,120(r4) addi r4,r4,128 // advance to next dest chunk bdnz c64InnerLoop // loop if more chunks c64double7: // r5 <- leftover bytes, cr1 set on doubleword count rlwinm r0,r5,29,28,31 // r0 <- count of leftover doublewords (0-15) andi. r5,r5,7 // r5/cr0 <- count of leftover bytes (0-7) beq cr1,c64byte // no leftover doublewords mtctr r0 b c64double8 .align 5 // align inner loop c64double8: // loop copying leftover doublewords ld r0,0(r6) addi r6,r6,8 std r0,0(r4) addi r4,r4,8 bdnz c64double8 // Forward byte loop. c64byte: // r5/cr0 <- byte count (can be big if unaligned uncached) beqlr // done if no leftover bytes mtctr r5 b c64byte1 .align 5 // align inner loop c64byte1: lbz r0,0(r6) addi r6,r6,1 stb r0,0(r4) addi r4,r4,1 bdnz c64byte1 blr // Uncached copies. We must avoid unaligned accesses, since they always take alignment // exceptions on uncached memory on 64-bit processors. This may mean we copy long operands // a byte at a time, but that is still much faster than alignment exceptions. // r4 = destination // r5 = length (>0) // r6 = source // r8 = inverse of largest mask smaller than operand length // r9 = neg(dest), used to compute alignment // r12 = (dest-source), used to test relative alignment // cr0 = beq if reverse move required // cr5 = noncache flag c64uncached: rlwinm r10,r12,0,29,31 // relatively doubleword aligned? rlwinm r11,r12,0,30,31 // relatively word aligned? cmpwi cr7,r10,0 // set cr7 beq if doubleword aligned cmpwi cr1,r11,0 // set cr1 beq if word aligned beq-- c64reverseUncached beq cr7,c64double // doubleword aligned beq cr1,forward32bit // word aligned, use G3/G4 code cmpwi r5,0 // set cr0 on byte count b c64byte // unaligned operands c64reverseUncached: beq cr7,c64rdouble // doubleword aligned so can use LD/STD beq cr1,reverse32bit // word aligned, use G3/G4 code add r6,r6,r5 // point to (end+1) of source and dest add r4,r4,r5 cmpwi r5,0 // set cr0 on length b c64rbyte // copy a byte at a time // Reverse doubleword copies. This is used for all cached copies, and doubleword // aligned uncached copies. // r4 = destination // r5 = length (>0) // r6 = source // r8 = inverse of largest mask of low-order 1s smaller than operand length // cr5 = noncache flag c64rdouble: add r6,r6,r5 // point to (end+1) of source and dest add r4,r4,r5 rlwinm r7,r4,0,29,31 // r7 <- #bytes to doubleword align dest andc. r7,r7,r8 // limit by operand length sub r5,r5,r7 // adjust length srwi r8,r5,6 // r8 <- 64-byte chunks to xfer cmpwi cr1,r8,0 // any chunks? beq c64rd2 // source already doubleword aligned mtctr r7 c64rd1: // copy bytes until source doublword aligned lbzu r0,-1(r6) stbu r0,-1(r4) bdnz c64rd1 c64rd2: // r8/cr1 <- count of 64-byte chunks rlwinm r0,r5,29,29,31 // r0 <- count of leftover doublewords andi. r5,r5,7 // r5/cr0 <- count of leftover bytes cmpwi cr7,r0,0 // leftover doublewords? beq cr1,c64rd4 // no chunks to xfer mtctr r8 b c64rd3 .align 5 // align inner loop c64rd3: // loop copying 64-byte chunks ld r7,-8(r6) ld r8,-16(r6) ld r9,-24(r6) ld r10,-32(r6) ld r11,-40(r6) ld r12,-48(r6) std r7,-8(r4) std r8,-16(r4) ld r7,-56(r6) ldu r8,-64(r6) std r9,-24(r4) std r10,-32(r4) std r11,-40(r4) std r12,-48(r4) std r7,-56(r4) stdu r8,-64(r4) bdnz c64rd3 c64rd4: // r0/cr7 = leftover doublewords r5/cr0 = leftover bytes beq cr7,c64rbyte // no leftover doublewords mtctr r0 c64rd5: // loop copying leftover doublewords ldu r0,-8(r6) stdu r0,-8(r4) bdnz c64rd5 // Reverse byte loop. c64rbyte: // r5/cr0 <- byte count (can be big if unaligned uncached) beqlr // done if no leftover bytes mtctr r5 c64rbyte1: lbzu r0,-1(r6) stbu r0,-1(r4) bdnz c64rbyte1 blr