diff options
author | Yunhong Jiang <yunhong.jiang@intel.com> | 2015-08-04 12:17:53 -0700 |
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committer | Yunhong Jiang <yunhong.jiang@intel.com> | 2015-08-04 15:44:42 -0700 |
commit | 9ca8dbcc65cfc63d6f5ef3312a33184e1d726e00 (patch) | |
tree | 1c9cafbcd35f783a87880a10f85d1a060db1a563 /kernel/arch/powerpc/lib/checksum_64.S | |
parent | 98260f3884f4a202f9ca5eabed40b1354c489b29 (diff) |
Add the rt linux 4.1.3-rt3 as base
Import the rt linux 4.1.3-rt3 as OPNFV kvm base.
It's from git://git.kernel.org/pub/scm/linux/kernel/git/rt/linux-rt-devel.git linux-4.1.y-rt and
the base is:
commit 0917f823c59692d751951bf5ea699a2d1e2f26a2
Author: Sebastian Andrzej Siewior <bigeasy@linutronix.de>
Date: Sat Jul 25 12:13:34 2015 +0200
Prepare v4.1.3-rt3
Signed-off-by: Sebastian Andrzej Siewior <bigeasy@linutronix.de>
We lose all the git history this way and it's not good. We
should apply another opnfv project repo in future.
Change-Id: I87543d81c9df70d99c5001fbdf646b202c19f423
Signed-off-by: Yunhong Jiang <yunhong.jiang@intel.com>
Diffstat (limited to 'kernel/arch/powerpc/lib/checksum_64.S')
-rw-r--r-- | kernel/arch/powerpc/lib/checksum_64.S | 480 |
1 files changed, 480 insertions, 0 deletions
diff --git a/kernel/arch/powerpc/lib/checksum_64.S b/kernel/arch/powerpc/lib/checksum_64.S new file mode 100644 index 000000000..57a072065 --- /dev/null +++ b/kernel/arch/powerpc/lib/checksum_64.S @@ -0,0 +1,480 @@ +/* + * This file contains assembly-language implementations + * of IP-style 1's complement checksum routines. + * + * Copyright (C) 1995-1996 Gary Thomas (gdt@linuxppc.org) + * + * This program is free software; you can redistribute it and/or + * modify it under the terms of the GNU General Public License + * as published by the Free Software Foundation; either version + * 2 of the License, or (at your option) any later version. + * + * Severely hacked about by Paul Mackerras (paulus@cs.anu.edu.au). + */ + +#include <linux/sys.h> +#include <asm/processor.h> +#include <asm/errno.h> +#include <asm/ppc_asm.h> + +/* + * ip_fast_csum(r3=buf, r4=len) -- Optimized for IP header + * len is in words and is always >= 5. + * + * In practice len == 5, but this is not guaranteed. So this code does not + * attempt to use doubleword instructions. + */ +_GLOBAL(ip_fast_csum) + lwz r0,0(r3) + lwzu r5,4(r3) + addic. r4,r4,-2 + addc r0,r0,r5 + mtctr r4 + blelr- +1: lwzu r4,4(r3) + adde r0,r0,r4 + bdnz 1b + addze r0,r0 /* add in final carry */ + rldicl r4,r0,32,0 /* fold two 32-bit halves together */ + add r0,r0,r4 + srdi r0,r0,32 + rlwinm r3,r0,16,0,31 /* fold two halves together */ + add r3,r0,r3 + not r3,r3 + srwi r3,r3,16 + blr + +/* + * Compute checksum of TCP or UDP pseudo-header: + * csum_tcpudp_magic(r3=saddr, r4=daddr, r5=len, r6=proto, r7=sum) + * No real gain trying to do this specially for 64 bit, but + * the 32 bit addition may spill into the upper bits of + * the doubleword so we still must fold it down from 64. + */ +_GLOBAL(csum_tcpudp_magic) + rlwimi r5,r6,16,0,15 /* put proto in upper half of len */ + addc r0,r3,r4 /* add 4 32-bit words together */ + adde r0,r0,r5 + adde r0,r0,r7 + rldicl r4,r0,32,0 /* fold 64 bit value */ + add r0,r4,r0 + srdi r0,r0,32 + rlwinm r3,r0,16,0,31 /* fold two halves together */ + add r3,r0,r3 + not r3,r3 + srwi r3,r3,16 + blr + +/* + * Computes the checksum of a memory block at buff, length len, + * and adds in "sum" (32-bit). + * + * csum_partial(r3=buff, r4=len, r5=sum) + */ +_GLOBAL(csum_partial) + addic r0,r5,0 /* clear carry */ + + srdi. r6,r4,3 /* less than 8 bytes? */ + beq .Lcsum_tail_word + + /* + * If only halfword aligned, align to a double word. Since odd + * aligned addresses should be rare and they would require more + * work to calculate the correct checksum, we ignore that case + * and take the potential slowdown of unaligned loads. + */ + rldicl. r6,r3,64-1,64-2 /* r6 = (r3 & 0x3) >> 1 */ + beq .Lcsum_aligned + + li r7,4 + sub r6,r7,r6 + mtctr r6 + +1: + lhz r6,0(r3) /* align to doubleword */ + subi r4,r4,2 + addi r3,r3,2 + adde r0,r0,r6 + bdnz 1b + +.Lcsum_aligned: + /* + * We unroll the loop such that each iteration is 64 bytes with an + * entry and exit limb of 64 bytes, meaning a minimum size of + * 128 bytes. + */ + srdi. r6,r4,7 + beq .Lcsum_tail_doublewords /* len < 128 */ + + srdi r6,r4,6 + subi r6,r6,1 + mtctr r6 + + stdu r1,-STACKFRAMESIZE(r1) + std r14,STK_REG(R14)(r1) + std r15,STK_REG(R15)(r1) + std r16,STK_REG(R16)(r1) + + ld r6,0(r3) + ld r9,8(r3) + + ld r10,16(r3) + ld r11,24(r3) + + /* + * On POWER6 and POWER7 back to back addes take 2 cycles because of + * the XER dependency. This means the fastest this loop can go is + * 16 cycles per iteration. The scheduling of the loop below has + * been shown to hit this on both POWER6 and POWER7. + */ + .align 5 +2: + adde r0,r0,r6 + ld r12,32(r3) + ld r14,40(r3) + + adde r0,r0,r9 + ld r15,48(r3) + ld r16,56(r3) + addi r3,r3,64 + + adde r0,r0,r10 + + adde r0,r0,r11 + + adde r0,r0,r12 + + adde r0,r0,r14 + + adde r0,r0,r15 + ld r6,0(r3) + ld r9,8(r3) + + adde r0,r0,r16 + ld r10,16(r3) + ld r11,24(r3) + bdnz 2b + + + adde r0,r0,r6 + ld r12,32(r3) + ld r14,40(r3) + + adde r0,r0,r9 + ld r15,48(r3) + ld r16,56(r3) + addi r3,r3,64 + + adde r0,r0,r10 + adde r0,r0,r11 + adde r0,r0,r12 + adde r0,r0,r14 + adde r0,r0,r15 + adde r0,r0,r16 + + ld r14,STK_REG(R14)(r1) + ld r15,STK_REG(R15)(r1) + ld r16,STK_REG(R16)(r1) + addi r1,r1,STACKFRAMESIZE + + andi. r4,r4,63 + +.Lcsum_tail_doublewords: /* Up to 127 bytes to go */ + srdi. r6,r4,3 + beq .Lcsum_tail_word + + mtctr r6 +3: + ld r6,0(r3) + addi r3,r3,8 + adde r0,r0,r6 + bdnz 3b + + andi. r4,r4,7 + +.Lcsum_tail_word: /* Up to 7 bytes to go */ + srdi. r6,r4,2 + beq .Lcsum_tail_halfword + + lwz r6,0(r3) + addi r3,r3,4 + adde r0,r0,r6 + subi r4,r4,4 + +.Lcsum_tail_halfword: /* Up to 3 bytes to go */ + srdi. r6,r4,1 + beq .Lcsum_tail_byte + + lhz r6,0(r3) + addi r3,r3,2 + adde r0,r0,r6 + subi r4,r4,2 + +.Lcsum_tail_byte: /* Up to 1 byte to go */ + andi. r6,r4,1 + beq .Lcsum_finish + + lbz r6,0(r3) + sldi r9,r6,8 /* Pad the byte out to 16 bits */ + adde r0,r0,r9 + +.Lcsum_finish: + addze r0,r0 /* add in final carry */ + rldicl r4,r0,32,0 /* fold two 32 bit halves together */ + add r3,r4,r0 + srdi r3,r3,32 + blr + + + .macro srcnr +100: + .section __ex_table,"a" + .align 3 + .llong 100b,.Lsrc_error_nr + .previous + .endm + + .macro source +150: + .section __ex_table,"a" + .align 3 + .llong 150b,.Lsrc_error + .previous + .endm + + .macro dstnr +200: + .section __ex_table,"a" + .align 3 + .llong 200b,.Ldest_error_nr + .previous + .endm + + .macro dest +250: + .section __ex_table,"a" + .align 3 + .llong 250b,.Ldest_error + .previous + .endm + +/* + * Computes the checksum of a memory block at src, length len, + * and adds in "sum" (32-bit), while copying the block to dst. + * If an access exception occurs on src or dst, it stores -EFAULT + * to *src_err or *dst_err respectively. The caller must take any action + * required in this case (zeroing memory, recalculating partial checksum etc). + * + * csum_partial_copy_generic(r3=src, r4=dst, r5=len, r6=sum, r7=src_err, r8=dst_err) + */ +_GLOBAL(csum_partial_copy_generic) + addic r0,r6,0 /* clear carry */ + + srdi. r6,r5,3 /* less than 8 bytes? */ + beq .Lcopy_tail_word + + /* + * If only halfword aligned, align to a double word. Since odd + * aligned addresses should be rare and they would require more + * work to calculate the correct checksum, we ignore that case + * and take the potential slowdown of unaligned loads. + * + * If the source and destination are relatively unaligned we only + * align the source. This keeps things simple. + */ + rldicl. r6,r3,64-1,64-2 /* r6 = (r3 & 0x3) >> 1 */ + beq .Lcopy_aligned + + li r9,4 + sub r6,r9,r6 + mtctr r6 + +1: +srcnr; lhz r6,0(r3) /* align to doubleword */ + subi r5,r5,2 + addi r3,r3,2 + adde r0,r0,r6 +dstnr; sth r6,0(r4) + addi r4,r4,2 + bdnz 1b + +.Lcopy_aligned: + /* + * We unroll the loop such that each iteration is 64 bytes with an + * entry and exit limb of 64 bytes, meaning a minimum size of + * 128 bytes. + */ + srdi. r6,r5,7 + beq .Lcopy_tail_doublewords /* len < 128 */ + + srdi r6,r5,6 + subi r6,r6,1 + mtctr r6 + + stdu r1,-STACKFRAMESIZE(r1) + std r14,STK_REG(R14)(r1) + std r15,STK_REG(R15)(r1) + std r16,STK_REG(R16)(r1) + +source; ld r6,0(r3) +source; ld r9,8(r3) + +source; ld r10,16(r3) +source; ld r11,24(r3) + + /* + * On POWER6 and POWER7 back to back addes take 2 cycles because of + * the XER dependency. This means the fastest this loop can go is + * 16 cycles per iteration. The scheduling of the loop below has + * been shown to hit this on both POWER6 and POWER7. + */ + .align 5 +2: + adde r0,r0,r6 +source; ld r12,32(r3) +source; ld r14,40(r3) + + adde r0,r0,r9 +source; ld r15,48(r3) +source; ld r16,56(r3) + addi r3,r3,64 + + adde r0,r0,r10 +dest; std r6,0(r4) +dest; std r9,8(r4) + + adde r0,r0,r11 +dest; std r10,16(r4) +dest; std r11,24(r4) + + adde r0,r0,r12 +dest; std r12,32(r4) +dest; std r14,40(r4) + + adde r0,r0,r14 +dest; std r15,48(r4) +dest; std r16,56(r4) + addi r4,r4,64 + + adde r0,r0,r15 +source; ld r6,0(r3) +source; ld r9,8(r3) + + adde r0,r0,r16 +source; ld r10,16(r3) +source; ld r11,24(r3) + bdnz 2b + + + adde r0,r0,r6 +source; ld r12,32(r3) +source; ld r14,40(r3) + + adde r0,r0,r9 +source; ld r15,48(r3) +source; ld r16,56(r3) + addi r3,r3,64 + + adde r0,r0,r10 +dest; std r6,0(r4) +dest; std r9,8(r4) + + adde r0,r0,r11 +dest; std r10,16(r4) +dest; std r11,24(r4) + + adde r0,r0,r12 +dest; std r12,32(r4) +dest; std r14,40(r4) + + adde r0,r0,r14 +dest; std r15,48(r4) +dest; std r16,56(r4) + addi r4,r4,64 + + adde r0,r0,r15 + adde r0,r0,r16 + + ld r14,STK_REG(R14)(r1) + ld r15,STK_REG(R15)(r1) + ld r16,STK_REG(R16)(r1) + addi r1,r1,STACKFRAMESIZE + + andi. r5,r5,63 + +.Lcopy_tail_doublewords: /* Up to 127 bytes to go */ + srdi. r6,r5,3 + beq .Lcopy_tail_word + + mtctr r6 +3: +srcnr; ld r6,0(r3) + addi r3,r3,8 + adde r0,r0,r6 +dstnr; std r6,0(r4) + addi r4,r4,8 + bdnz 3b + + andi. r5,r5,7 + +.Lcopy_tail_word: /* Up to 7 bytes to go */ + srdi. r6,r5,2 + beq .Lcopy_tail_halfword + +srcnr; lwz r6,0(r3) + addi r3,r3,4 + adde r0,r0,r6 +dstnr; stw r6,0(r4) + addi r4,r4,4 + subi r5,r5,4 + +.Lcopy_tail_halfword: /* Up to 3 bytes to go */ + srdi. r6,r5,1 + beq .Lcopy_tail_byte + +srcnr; lhz r6,0(r3) + addi r3,r3,2 + adde r0,r0,r6 +dstnr; sth r6,0(r4) + addi r4,r4,2 + subi r5,r5,2 + +.Lcopy_tail_byte: /* Up to 1 byte to go */ + andi. r6,r5,1 + beq .Lcopy_finish + +srcnr; lbz r6,0(r3) + sldi r9,r6,8 /* Pad the byte out to 16 bits */ + adde r0,r0,r9 +dstnr; stb r6,0(r4) + +.Lcopy_finish: + addze r0,r0 /* add in final carry */ + rldicl r4,r0,32,0 /* fold two 32 bit halves together */ + add r3,r4,r0 + srdi r3,r3,32 + blr + +.Lsrc_error: + ld r14,STK_REG(R14)(r1) + ld r15,STK_REG(R15)(r1) + ld r16,STK_REG(R16)(r1) + addi r1,r1,STACKFRAMESIZE +.Lsrc_error_nr: + cmpdi 0,r7,0 + beqlr + li r6,-EFAULT + stw r6,0(r7) + blr + +.Ldest_error: + ld r14,STK_REG(R14)(r1) + ld r15,STK_REG(R15)(r1) + ld r16,STK_REG(R16)(r1) + addi r1,r1,STACKFRAMESIZE +.Ldest_error_nr: + cmpdi 0,r8,0 + beqlr + li r6,-EFAULT + stw r6,0(r8) + blr |