| /* |
| * arch/alpha/lib/ev6-copy_user.S |
| * |
| * 21264 version contributed by Rick Gorton <rick.gorton@alpha-processor.com> |
| * |
| * Copy to/from user space, handling exceptions as we go.. This |
| * isn't exactly pretty. |
| * |
| * This is essentially the same as "memcpy()", but with a few twists. |
| * Notably, we have to make sure that $0 is always up-to-date and |
| * contains the right "bytes left to copy" value (and that it is updated |
| * only _after_ a successful copy). There is also some rather minor |
| * exception setup stuff.. |
| * |
| * NOTE! This is not directly C-callable, because the calling semantics are |
| * different: |
| * |
| * Inputs: |
| * length in $0 |
| * destination address in $6 |
| * source address in $7 |
| * return address in $28 |
| * |
| * Outputs: |
| * bytes left to copy in $0 |
| * |
| * Clobbers: |
| * $1,$2,$3,$4,$5,$6,$7 |
| * |
| * Much of the information about 21264 scheduling/coding comes from: |
| * Compiler Writer's Guide for the Alpha 21264 |
| * abbreviated as 'CWG' in other comments here |
| * ftp.digital.com/pub/Digital/info/semiconductor/literature/dsc-library.html |
| * Scheduling notation: |
| * E - either cluster |
| * U - upper subcluster; U0 - subcluster U0; U1 - subcluster U1 |
| * L - lower subcluster; L0 - subcluster L0; L1 - subcluster L1 |
| */ |
| |
| #include <asm/export.h> |
| /* Allow an exception for an insn; exit if we get one. */ |
| #define EXI(x,y...) \ |
| 99: x,##y; \ |
| .section __ex_table,"a"; \ |
| .long 99b - .; \ |
| lda $31, $exitin-99b($31); \ |
| .previous |
| |
| #define EXO(x,y...) \ |
| 99: x,##y; \ |
| .section __ex_table,"a"; \ |
| .long 99b - .; \ |
| lda $31, $exitout-99b($31); \ |
| .previous |
| |
| .set noat |
| .align 4 |
| .globl __copy_user |
| .ent __copy_user |
| # Pipeline info: Slotting & Comments |
| __copy_user: |
| .prologue 0 |
| subq $0, 32, $1 # .. E .. .. : Is this going to be a small copy? |
| beq $0, $zerolength # U .. .. .. : U L U L |
| |
| and $6,7,$3 # .. .. .. E : is leading dest misalignment |
| ble $1, $onebyteloop # .. .. U .. : 1st branch : small amount of data |
| beq $3, $destaligned # .. U .. .. : 2nd (one cycle fetcher stall) |
| subq $3, 8, $3 # E .. .. .. : L U U L : trip counter |
| /* |
| * The fetcher stall also hides the 1 cycle cross-cluster stall for $3 (L --> U) |
| * This loop aligns the destination a byte at a time |
| * We know we have at least one trip through this loop |
| */ |
| $aligndest: |
| EXI( ldbu $1,0($7) ) # .. .. .. L : Keep loads separate from stores |
| addq $6,1,$6 # .. .. E .. : Section 3.8 in the CWG |
| addq $3,1,$3 # .. E .. .. : |
| nop # E .. .. .. : U L U L |
| |
| /* |
| * the -1 is to compensate for the inc($6) done in a previous quadpack |
| * which allows us zero dependencies within either quadpack in the loop |
| */ |
| EXO( stb $1,-1($6) ) # .. .. .. L : |
| addq $7,1,$7 # .. .. E .. : Section 3.8 in the CWG |
| subq $0,1,$0 # .. E .. .. : |
| bne $3, $aligndest # U .. .. .. : U L U L |
| |
| /* |
| * If we fell through into here, we have a minimum of 33 - 7 bytes |
| * If we arrived via branch, we have a minimum of 32 bytes |
| */ |
| $destaligned: |
| and $7,7,$1 # .. .. .. E : Check _current_ source alignment |
| bic $0,7,$4 # .. .. E .. : number bytes as a quadword loop |
| EXI( ldq_u $3,0($7) ) # .. L .. .. : Forward fetch for fallthrough code |
| beq $1,$quadaligned # U .. .. .. : U L U L |
| |
| /* |
| * In the worst case, we've just executed an ldq_u here from 0($7) |
| * and we'll repeat it once if we take the branch |
| */ |
| |
| /* Misaligned quadword loop - not unrolled. Leave it that way. */ |
| $misquad: |
| EXI( ldq_u $2,8($7) ) # .. .. .. L : |
| subq $4,8,$4 # .. .. E .. : |
| extql $3,$7,$3 # .. U .. .. : |
| extqh $2,$7,$1 # U .. .. .. : U U L L |
| |
| bis $3,$1,$1 # .. .. .. E : |
| EXO( stq $1,0($6) ) # .. .. L .. : |
| addq $7,8,$7 # .. E .. .. : |
| subq $0,8,$0 # E .. .. .. : U L L U |
| |
| addq $6,8,$6 # .. .. .. E : |
| bis $2,$2,$3 # .. .. E .. : |
| nop # .. E .. .. : |
| bne $4,$misquad # U .. .. .. : U L U L |
| |
| nop # .. .. .. E |
| nop # .. .. E .. |
| nop # .. E .. .. |
| beq $0,$zerolength # U .. .. .. : U L U L |
| |
| /* We know we have at least one trip through the byte loop */ |
| EXI ( ldbu $2,0($7) ) # .. .. .. L : No loads in the same quad |
| addq $6,1,$6 # .. .. E .. : as the store (Section 3.8 in CWG) |
| nop # .. E .. .. : |
| br $31, $dirtyentry # L0 .. .. .. : L U U L |
| /* Do the trailing byte loop load, then hop into the store part of the loop */ |
| |
| /* |
| * A minimum of (33 - 7) bytes to do a quad at a time. |
| * Based upon the usage context, it's worth the effort to unroll this loop |
| * $0 - number of bytes to be moved |
| * $4 - number of bytes to move as quadwords |
| * $6 is current destination address |
| * $7 is current source address |
| */ |
| $quadaligned: |
| subq $4, 32, $2 # .. .. .. E : do not unroll for small stuff |
| nop # .. .. E .. |
| nop # .. E .. .. |
| blt $2, $onequad # U .. .. .. : U L U L |
| |
| /* |
| * There is a significant assumption here that the source and destination |
| * addresses differ by more than 32 bytes. In this particular case, a |
| * sparsity of registers further bounds this to be a minimum of 8 bytes. |
| * But if this isn't met, then the output result will be incorrect. |
| * Furthermore, due to a lack of available registers, we really can't |
| * unroll this to be an 8x loop (which would enable us to use the wh64 |
| * instruction memory hint instruction). |
| */ |
| $unroll4: |
| EXI( ldq $1,0($7) ) # .. .. .. L |
| EXI( ldq $2,8($7) ) # .. .. L .. |
| subq $4,32,$4 # .. E .. .. |
| nop # E .. .. .. : U U L L |
| |
| addq $7,16,$7 # .. .. .. E |
| EXO( stq $1,0($6) ) # .. .. L .. |
| EXO( stq $2,8($6) ) # .. L .. .. |
| subq $0,16,$0 # E .. .. .. : U L L U |
| |
| addq $6,16,$6 # .. .. .. E |
| EXI( ldq $1,0($7) ) # .. .. L .. |
| EXI( ldq $2,8($7) ) # .. L .. .. |
| subq $4, 32, $3 # E .. .. .. : U U L L : is there enough for another trip? |
| |
| EXO( stq $1,0($6) ) # .. .. .. L |
| EXO( stq $2,8($6) ) # .. .. L .. |
| subq $0,16,$0 # .. E .. .. |
| addq $7,16,$7 # E .. .. .. : U L L U |
| |
| nop # .. .. .. E |
| nop # .. .. E .. |
| addq $6,16,$6 # .. E .. .. |
| bgt $3,$unroll4 # U .. .. .. : U L U L |
| |
| nop |
| nop |
| nop |
| beq $4, $noquads |
| |
| $onequad: |
| EXI( ldq $1,0($7) ) |
| subq $4,8,$4 |
| addq $7,8,$7 |
| nop |
| |
| EXO( stq $1,0($6) ) |
| subq $0,8,$0 |
| addq $6,8,$6 |
| bne $4,$onequad |
| |
| $noquads: |
| nop |
| nop |
| nop |
| beq $0,$zerolength |
| |
| /* |
| * For small copies (or the tail of a larger copy), do a very simple byte loop. |
| * There's no point in doing a lot of complex alignment calculations to try to |
| * to quadword stuff for a small amount of data. |
| * $0 - remaining number of bytes left to copy |
| * $6 - current dest addr |
| * $7 - current source addr |
| */ |
| |
| $onebyteloop: |
| EXI ( ldbu $2,0($7) ) # .. .. .. L : No loads in the same quad |
| addq $6,1,$6 # .. .. E .. : as the store (Section 3.8 in CWG) |
| nop # .. E .. .. : |
| nop # E .. .. .. : U L U L |
| |
| $dirtyentry: |
| /* |
| * the -1 is to compensate for the inc($6) done in a previous quadpack |
| * which allows us zero dependencies within either quadpack in the loop |
| */ |
| EXO ( stb $2,-1($6) ) # .. .. .. L : |
| addq $7,1,$7 # .. .. E .. : quadpack as the load |
| subq $0,1,$0 # .. E .. .. : change count _after_ copy |
| bgt $0,$onebyteloop # U .. .. .. : U L U L |
| |
| $zerolength: |
| $exitin: |
| $exitout: # Destination for exception recovery(?) |
| nop # .. .. .. E |
| nop # .. .. E .. |
| nop # .. E .. .. |
| ret $31,($28),1 # L0 .. .. .. : L U L U |
| |
| .end __copy_user |
| EXPORT_SYMBOL(__copy_user) |