/* SPDX-License-Identifier: GPL-2.0 */ /* * "memcpy" implementation of SuperH * * Copyright (C) 1999 Niibe Yutaka * Copyright (c) 2002 STMicroelectronics Ltd * Modified from memcpy.S and micro-optimised for SH4 * Stuart Menefy (stuart.menefy@st.com) * */ #include <linux/linkage.h> /* * void *memcpy(void *dst, const void *src, size_t n); * * It is assumed that there is no overlap between src and dst. * If there is an overlap, then the results are undefined. */ ! ! GHIJ KLMN OPQR --> ...G HIJK LMNO PQR. ! ! Size is 16 or greater, and may have trailing bytes .balign 32 .Lcase1: ! Read a long word and write a long word at once ! At the start of each iteration, r7 contains last long load add #-1,r5 ! 79 EX mov r4,r2 ! 5 MT (0 cycles latency) mov.l @(r0,r5),r7 ! 21 LS (2 cycles latency) add #-4,r5 ! 50 EX add #7,r2 ! 79 EX ! #ifdef CONFIG_CPU_LITTLE_ENDIAN ! 6 cycles, 4 bytes per iteration 3: mov.l @(r0,r5),r1 ! 21 LS (latency=2) ! NMLK mov r7, r3 ! 5 MT (latency=0) ! RQPO cmp/hi r2,r0 ! 57 MT shll16 r3 ! 103 EX mov r1,r6 ! 5 MT (latency=0) shll8 r3 ! 102 EX ! Oxxx shlr8 r6 ! 106 EX ! xNML mov r1, r7 ! 5 MT (latency=0) or r6,r3 ! 82 EX ! ONML bt/s 3b ! 109 BR mov.l r3,@-r0 ! 30 LS #else 3: mov.l @(r0,r5),r1 ! 21 LS (latency=2) ! KLMN mov r7,r3 ! 5 MT (latency=0) ! OPQR cmp/hi r2,r0 ! 57 MT shlr16 r3 ! 107 EX shlr8 r3 ! 106 EX ! xxxO mov r1,r6 ! 5 MT (latency=0) shll8 r6 ! 102 EX ! LMNx mov r1,r7 ! 5 MT (latency=0) or r6,r3 ! 82 EX ! LMNO bt/s 3b ! 109 BR mov.l r3,@-r0 ! 30 LS #endif ! Finally, copy a byte at once, if necessary add #4,r5 ! 50 EX cmp/eq r4,r0 ! 54 MT add #-6,r2 ! 50 EX bt 9f ! 109 BR 8: cmp/hi r2,r0 ! 57 MT mov.b @(r0,r5),r1 ! 20 LS (latency=2) bt/s 8b ! 109 BR mov.b r1,@-r0 ! 29 LS 9: rts nop ! ! GHIJ KLMN OPQR --> .GHI JKLM NOPQ R... ! ! Size is 16 or greater, and may have trailing bytes .balign 32 .Lcase3: ! Read a long word and write a long word at once ! At the start of each iteration, r7 contains last long load add #-3,r5 ! 79 EX mov r4,r2 ! 5 MT (0 cycles latency) mov.l @(r0,r5),r7 ! 21 LS (2 cycles latency) add #-4,r5 ! 50 EX add #7,r2 ! 79 EX ! #ifdef CONFIG_CPU_LITTLE_ENDIAN ! 6 cycles, 4 bytes per iteration 3: mov.l @(r0,r5),r1 ! 21 LS (latency=2) ! NMLK mov r7, r3 ! 5 MT (latency=0) ! RQPO cmp/hi r2,r0 ! 57 MT shll8 r3 ! 102 EX ! QPOx mov r1,r6 ! 5 MT (latency=0) shlr16 r6 ! 107 EX shlr8 r6 ! 106 EX ! xxxN mov r1, r7 ! 5 MT (latency=0) or r6,r3 ! 82 EX ! QPON bt/s 3b ! 109 BR mov.l r3,@-r0 ! 30 LS #else 3: mov r7,r3 ! OPQR shlr8 r3 ! xOPQ mov.l @(r0,r5),r7 ! KLMN mov r7,r6 shll16 r6 shll8 r6 ! Nxxx or r6,r3 ! NOPQ cmp/hi r2,r0 bt/s 3b mov.l r3,@-r0 #endif ! Finally, copy a byte at once, if necessary add #6,r5 ! 50 EX cmp/eq r4,r0 ! 54 MT add #-6,r2 ! 50 EX bt 9f ! 109 BR 8: cmp/hi r2,r0 ! 57 MT mov.b @(r0,r5),r1 ! 20 LS (latency=2) bt/s 8b ! 109 BR mov.b r1,@-r0 ! 29 LS 9: rts nop ENTRY(memcpy) ! Calculate the invariants which will be used in the remainder ! of the code: ! ! r4 --> [ ... ] DST [ ... ] SRC ! [ ... ] [ ... ] ! : : ! r0 --> [ ... ] r0+r5 --> [ ... ] ! ! ! Short circuit the common case of src, dst and len being 32 bit aligned ! and test for zero length move mov r6, r0 ! 5 MT (0 cycle latency) or r4, r0 ! 82 EX or r5, r0 ! 82 EX tst r6, r6 ! 86 MT bt/s 99f ! 111 BR (zero len) tst #3, r0 ! 87 MT mov r4, r0 ! 5 MT (0 cycle latency) add r6, r0 ! 49 EX mov #16, r1 ! 6 EX bt/s .Lcase00 ! 111 BR (aligned) sub r4, r5 ! 75 EX ! Arguments are not nicely long word aligned or zero len. ! Check for small copies, and if so do a simple byte at a time copy. ! ! Deciding on an exact value of 'small' is not easy, as the point at which ! using the optimised routines become worthwhile varies (these are the ! cycle counts for differnet sizes using byte-at-a-time vs. optimised): ! size byte-at-time long word byte ! 16 42 39-40 46-50 50-55 ! 24 58 43-44 54-58 62-67 ! 36 82 49-50 66-70 80-85 ! However the penalty for getting it 'wrong' is much higher for long word ! aligned data (and this is more common), so use a value of 16. cmp/gt r6,r1 ! 56 MT add #-1,r5 ! 50 EX bf/s 6f ! 108 BR (not small) mov r5, r3 ! 5 MT (latency=0) shlr r6 ! 104 EX mov.b @(r0,r5),r1 ! 20 LS (latency=2) bf/s 4f ! 111 BR add #-1,r3 ! 50 EX tst r6, r6 ! 86 MT bt/s 98f ! 110 BR mov.b r1,@-r0 ! 29 LS ! 4 cycles, 2 bytes per iteration 3: mov.b @(r0,r5),r1 ! 20 LS (latency=2) 4: mov.b @(r0,r3),r2 ! 20 LS (latency=2) dt r6 ! 67 EX mov.b r1,@-r0 ! 29 LS bf/s 3b ! 111 BR mov.b r2,@-r0 ! 29 LS 98: rts nop 99: rts mov r4, r0 ! Size is not small, so its worthwhile looking for optimisations. ! First align destination to a long word boundary. ! ! r5 = normal value -1 6: tst #3, r0 ! 87 MT mov #3, r3 ! 6 EX bt/s 2f ! 111 BR and r0,r3 ! 78 EX ! 3 cycles, 1 byte per iteration 1: dt r3 ! 67 EX mov.b @(r0,r5),r1 ! 19 LS (latency=2) add #-1, r6 ! 79 EX bf/s 1b ! 109 BR mov.b r1,@-r0 ! 28 LS 2: add #1, r5 ! 79 EX ! Now select the appropriate bulk transfer code based on relative ! alignment of src and dst. mov r0, r3 ! 5 MT (latency=0) mov r5, r0 ! 5 MT (latency=0) tst #1, r0 ! 87 MT bf/s 1f ! 111 BR mov #64, r7 ! 6 EX ! bit 0 clear cmp/ge r7, r6 ! 55 MT bt/s 2f ! 111 BR tst #2, r0 ! 87 MT ! small bt/s .Lcase0 mov r3, r0 bra .Lcase2 nop ! big 2: bt/s .Lcase0b mov r3, r0 bra .Lcase2b nop ! bit 0 set 1: tst #2, r0 ! 87 MT bt/s .Lcase1 mov r3, r0 bra .Lcase3 nop ! ! GHIJ KLMN OPQR --> GHIJ KLMN OPQR ! ! src, dst and size are all long word aligned ! size is non-zero .balign 32 .Lcase00: mov #64, r1 ! 6 EX mov r5, r3 ! 5 MT (latency=0) cmp/gt r6, r1 ! 56 MT add #-4, r5 ! 50 EX bf .Lcase00b ! 108 BR (big loop) shlr2 r6 ! 105 EX shlr r6 ! 104 EX mov.l @(r0, r5), r1 ! 21 LS (latency=2) bf/s 4f ! 111 BR add #-8, r3 ! 50 EX tst r6, r6 ! 86 MT bt/s 5f ! 110 BR mov.l r1,@-r0 ! 30 LS ! 4 cycles, 2 long words per iteration 3: mov.l @(r0, r5), r1 ! 21 LS (latency=2) 4: mov.l @(r0, r3), r2 ! 21 LS (latency=2) dt r6 ! 67 EX mov.l r1, @-r0 ! 30 LS bf/s 3b ! 109 BR mov.l r2, @-r0 ! 30 LS 5: rts nop ! Size is 16 or greater and less than 64, but may have trailing bytes .balign 32 .Lcase0: add #-4, r5 ! 50 EX mov r4, r7 ! 5 MT (latency=0) mov.l @(r0, r5), r1 ! 21 LS (latency=2) mov #4, r2 ! 6 EX add #11, r7 ! 50 EX tst r2, r6 ! 86 MT mov r5, r3 ! 5 MT (latency=0) bt/s 4f ! 111 BR add #-4, r3 ! 50 EX mov.l r1,@-r0 ! 30 LS ! 4 cycles, 2 long words per iteration 3: mov.l @(r0, r5), r1 ! 21 LS (latency=2) 4: mov.l @(r0, r3), r2 ! 21 LS (latency=2) cmp/hi r7, r0 mov.l r1, @-r0 ! 30 LS bt/s 3b ! 109 BR mov.l r2, @-r0 ! 30 LS ! Copy the final 0-3 bytes add #3,r5 ! 50 EX cmp/eq r0, r4 ! 54 MT add #-10, r7 ! 50 EX bt 9f ! 110 BR ! 3 cycles, 1 byte per iteration 1: mov.b @(r0,r5),r1 ! 19 LS cmp/hi r7,r0 ! 57 MT bt/s 1b ! 111 BR mov.b r1,@-r0 ! 28 LS 9: rts nop ! Size is at least 64 bytes, so will be going round the big loop at least once. ! ! r2 = rounded up r4 ! r3 = rounded down r0 .balign 32 .Lcase0b: add #-4, r5 ! 50 EX .Lcase00b: mov r0, r3 ! 5 MT (latency=0) mov #(~0x1f), r1 ! 6 EX and r1, r3 ! 78 EX mov r4, r2 ! 5 MT (latency=0) cmp/eq r3, r0 ! 54 MT add #0x1f, r2 ! 50 EX bt/s 1f ! 110 BR and r1, r2 ! 78 EX ! copy initial words until cache line aligned mov.l @(r0, r5), r1 ! 21 LS (latency=2) tst #4, r0 ! 87 MT mov r5, r6 ! 5 MT (latency=0) add #-4, r6 ! 50 EX bt/s 4f ! 111 BR add #8, r3 ! 50 EX tst #0x18, r0 ! 87 MT bt/s 1f ! 109 BR mov.l r1,@-r0 ! 30 LS ! 4 cycles, 2 long words per iteration 3: mov.l @(r0, r5), r1 ! 21 LS (latency=2) 4: mov.l @(r0, r6), r7 ! 21 LS (latency=2) cmp/eq r3, r0 ! 54 MT mov.l r1, @-r0 ! 30 LS bf/s 3b ! 109 BR mov.l r7, @-r0 ! 30 LS ! Copy the cache line aligned blocks ! ! In use: r0, r2, r4, r5 ! Scratch: r1, r3, r6, r7 ! ! We could do this with the four scratch registers, but if src ! and dest hit the same cache line, this will thrash, so make ! use of additional registers. ! ! We also need r0 as a temporary (for movca), so 'undo' the invariant: ! r5: src (was r0+r5) ! r1: dest (was r0) ! this can be reversed at the end, so we don't need to save any extra ! state. ! 1: mov.l r8, @-r15 ! 30 LS add r0, r5 ! 49 EX mov.l r9, @-r15 ! 30 LS mov r0, r1 ! 5 MT (latency=0) mov.l r10, @-r15 ! 30 LS add #-0x1c, r5 ! 50 EX mov.l r11, @-r15 ! 30 LS ! 16 cycles, 32 bytes per iteration 2: mov.l @(0x00,r5),r0 ! 18 LS (latency=2) add #-0x20, r1 ! 50 EX mov.l @(0x04,r5),r3 ! 18 LS (latency=2) mov.l @(0x08,r5),r6 ! 18 LS (latency=2) mov.l @(0x0c,r5),r7 ! 18 LS (latency=2) mov.l @(0x10,r5),r8 ! 18 LS (latency=2) mov.l @(0x14,r5),r9 ! 18 LS (latency=2) mov.l @(0x18,r5),r10 ! 18 LS (latency=2) mov.l @(0x1c,r5),r11 ! 18 LS (latency=2) movca.l r0,@r1 ! 40 LS (latency=3-7) mov.l r3,@(0x04,r1) ! 33 LS mov.l r6,@(0x08,r1) ! 33 LS mov.l r7,@(0x0c,r1) ! 33 LS mov.l r8,@(0x10,r1) ! 33 LS add #-0x20, r5 ! 50 EX mov.l r9,@(0x14,r1) ! 33 LS cmp/eq r2,r1 ! 54 MT mov.l r10,@(0x18,r1) ! 33 LS bf/s 2b ! 109 BR mov.l r11,@(0x1c,r1) ! 33 LS mov r1, r0 ! 5 MT (latency=0) mov.l @r15+, r11 ! 15 LS sub r1, r5 ! 75 EX mov.l @r15+, r10 ! 15 LS cmp/eq r4, r0 ! 54 MT bf/s 1f ! 109 BR mov.l @r15+, r9 ! 15 LS rts 1: mov.l @r15+, r8 ! 15 LS sub r4, r1 ! 75 EX (len remaining) ! number of trailing bytes is non-zero ! ! invariants restored (r5 already decremented by 4) ! also r1=num bytes remaining mov #4, r2 ! 6 EX mov r4, r7 ! 5 MT (latency=0) add #0x1c, r5 ! 50 EX (back to -4) cmp/hs r2, r1 ! 58 MT bf/s 5f ! 108 BR add #11, r7 ! 50 EX mov.l @(r0, r5), r6 ! 21 LS (latency=2) tst r2, r1 ! 86 MT mov r5, r3 ! 5 MT (latency=0) bt/s 4f ! 111 BR add #-4, r3 ! 50 EX cmp/hs r2, r1 ! 58 MT bt/s 5f ! 111 BR mov.l r6,@-r0 ! 30 LS ! 4 cycles, 2 long words per iteration 3: mov.l @(r0, r5), r6 ! 21 LS (latency=2) 4: mov.l @(r0, r3), r2 ! 21 LS (latency=2) cmp/hi r7, r0 mov.l r6, @-r0 ! 30 LS bt/s 3b ! 109 BR mov.l r2, @-r0 ! 30 LS ! Copy the final 0-3 bytes 5: cmp/eq r0, r4 ! 54 MT add #-10, r7 ! 50 EX bt 9f ! 110 BR add #3,r5 ! 50 EX ! 3 cycles, 1 byte per iteration 1: mov.b @(r0,r5),r1 ! 19 LS cmp/hi r7,r0 ! 57 MT bt/s 1b ! 111 BR mov.b r1,@-r0 ! 28 LS 9: rts nop ! ! GHIJ KLMN OPQR --> ..GH IJKL MNOP QR.. ! .balign 32 .Lcase2: ! Size is 16 or greater and less then 64, but may have trailing bytes 2: mov r5, r6 ! 5 MT (latency=0) add #-2,r5 ! 50 EX mov r4,r2 ! 5 MT (latency=0) add #-4,r6 ! 50 EX add #7,r2 ! 50 EX 3: mov.w @(r0,r5),r1 ! 20 LS (latency=2) mov.w @(r0,r6),r3 ! 20 LS (latency=2) cmp/hi r2,r0 ! 57 MT mov.w r1,@-r0 ! 29 LS bt/s 3b ! 111 BR mov.w r3,@-r0 ! 29 LS bra 10f nop .balign 32 .Lcase2b: ! Size is at least 64 bytes, so will be going round the big loop at least once. ! ! r2 = rounded up r4 ! r3 = rounded down r0 mov r0, r3 ! 5 MT (latency=0) mov #(~0x1f), r1 ! 6 EX and r1, r3 ! 78 EX mov r4, r2 ! 5 MT (latency=0) cmp/eq r3, r0 ! 54 MT add #0x1f, r2 ! 50 EX add #-2, r5 ! 50 EX bt/s 1f ! 110 BR and r1, r2 ! 78 EX ! Copy a short word one at a time until we are cache line aligned ! Normal values: r0, r2, r3, r4 ! Unused: r1, r6, r7 ! Mod: r5 (=r5-2) ! add #2, r3 ! 50 EX 2: mov.w @(r0,r5),r1 ! 20 LS (latency=2) cmp/eq r3,r0 ! 54 MT bf/s 2b ! 111 BR mov.w r1,@-r0 ! 29 LS ! Copy the cache line aligned blocks ! ! In use: r0, r2, r4, r5 (=r5-2) ! Scratch: r1, r3, r6, r7 ! ! We could do this with the four scratch registers, but if src ! and dest hit the same cache line, this will thrash, so make ! use of additional registers. ! ! We also need r0 as a temporary (for movca), so 'undo' the invariant: ! r5: src (was r0+r5) ! r1: dest (was r0) ! this can be reversed at the end, so we don't need to save any extra ! state. ! 1: mov.l r8, @-r15 ! 30 LS add r0, r5 ! 49 EX mov.l r9, @-r15 ! 30 LS mov r0, r1 ! 5 MT (latency=0) mov.l r10, @-r15 ! 30 LS add #-0x1e, r5 ! 50 EX mov.l r11, @-r15 ! 30 LS mov.l r12, @-r15 ! 30 LS ! 17 cycles, 32 bytes per iteration #ifdef CONFIG_CPU_LITTLE_ENDIAN 2: mov.w @r5+, r0 ! 14 LS (latency=2) ..JI add #-0x20, r1 ! 50 EX mov.l @r5+, r3 ! 15 LS (latency=2) NMLK mov.l @r5+, r6 ! 15 LS (latency=2) RQPO shll16 r0 ! 103 EX JI.. mov.l @r5+, r7 ! 15 LS (latency=2) xtrct r3, r0 ! 48 EX LKJI mov.l @r5+, r8 ! 15 LS (latency=2) xtrct r6, r3 ! 48 EX PONM mov.l @r5+, r9 ! 15 LS (latency=2) xtrct r7, r6 ! 48 EX mov.l @r5+, r10 ! 15 LS (latency=2) xtrct r8, r7 ! 48 EX mov.l @r5+, r11 ! 15 LS (latency=2) xtrct r9, r8 ! 48 EX mov.w @r5+, r12 ! 15 LS (latency=2) xtrct r10, r9 ! 48 EX movca.l r0,@r1 ! 40 LS (latency=3-7) xtrct r11, r10 ! 48 EX mov.l r3, @(0x04,r1) ! 33 LS xtrct r12, r11 ! 48 EX mov.l r6, @(0x08,r1) ! 33 LS mov.l r7, @(0x0c,r1) ! 33 LS mov.l r8, @(0x10,r1) ! 33 LS add #-0x40, r5 ! 50 EX mov.l r9, @(0x14,r1) ! 33 LS cmp/eq r2,r1 ! 54 MT mov.l r10, @(0x18,r1) ! 33 LS bf/s 2b ! 109 BR mov.l r11, @(0x1c,r1) ! 33 LS #else 2: mov.w @(0x1e,r5), r0 ! 17 LS (latency=2) add #-2, r5 ! 50 EX mov.l @(0x1c,r5), r3 ! 18 LS (latency=2) add #-4, r1 ! 50 EX mov.l @(0x18,r5), r6 ! 18 LS (latency=2) shll16 r0 ! 103 EX mov.l @(0x14,r5), r7 ! 18 LS (latency=2) xtrct r3, r0 ! 48 EX mov.l @(0x10,r5), r8 ! 18 LS (latency=2) xtrct r6, r3 ! 48 EX mov.l @(0x0c,r5), r9 ! 18 LS (latency=2) xtrct r7, r6 ! 48 EX mov.l @(0x08,r5), r10 ! 18 LS (latency=2) xtrct r8, r7 ! 48 EX mov.l @(0x04,r5), r11 ! 18 LS (latency=2) xtrct r9, r8 ! 48 EX mov.l @(0x00,r5), r12 ! 18 LS (latency=2) xtrct r10, r9 ! 48 EX movca.l r0,@r1 ! 40 LS (latency=3-7) add #-0x1c, r1 ! 50 EX mov.l r3, @(0x18,r1) ! 33 LS xtrct r11, r10 ! 48 EX mov.l r6, @(0x14,r1) ! 33 LS xtrct r12, r11 ! 48 EX mov.l r7, @(0x10,r1) ! 33 LS mov.l r8, @(0x0c,r1) ! 33 LS add #-0x1e, r5 ! 50 EX mov.l r9, @(0x08,r1) ! 33 LS cmp/eq r2,r1 ! 54 MT mov.l r10, @(0x04,r1) ! 33 LS bf/s 2b ! 109 BR mov.l r11, @(0x00,r1) ! 33 LS #endif mov.l @r15+, r12 mov r1, r0 ! 5 MT (latency=0) mov.l @r15+, r11 ! 15 LS sub r1, r5 ! 75 EX mov.l @r15+, r10 ! 15 LS cmp/eq r4, r0 ! 54 MT bf/s 1f ! 109 BR mov.l @r15+, r9 ! 15 LS rts 1: mov.l @r15+, r8 ! 15 LS add #0x1e, r5 ! 50 EX ! Finish off a short word at a time ! r5 must be invariant - 2 10: mov r4,r2 ! 5 MT (latency=0) add #1,r2 ! 50 EX cmp/hi r2, r0 ! 57 MT bf/s 1f ! 109 BR add #2, r2 ! 50 EX 3: mov.w @(r0,r5),r1 ! 20 LS cmp/hi r2,r0 ! 57 MT bt/s 3b ! 109 BR mov.w r1,@-r0 ! 29 LS 1: ! ! Finally, copy the last byte if necessary cmp/eq r4,r0 ! 54 MT bt/s 9b add #1,r5 mov.b @(r0,r5),r1 rts mov.b r1,@-r0