/* * Copyright (c) 2003 Apple Computer, Inc. All rights reserved. * * @APPLE_LICENSE_HEADER_START@ * * This file contains Original Code and/or Modifications of Original Code * as defined in and that are subject to the Apple Public Source License * Version 2.0 (the 'License'). You may not use this file except in * compliance with the License. Please obtain a copy of the License at * http://www.opensource.apple.com/apsl/ and read it before using this * file. * * The 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, QUIET ENJOYMENT OR NON-INFRINGEMENT. * Please see the License for the specific language governing rights and * limitations under the License. * * @APPLE_LICENSE_HEADER_END@ */ /* ==================================== * Very Long Operand BCOPY for Mac OS X * ==================================== * * Version of 2/21/2004, tuned for the IBM 970. This is for operands at * least several pages long. It is called from bcopy()/memcpy()/memmove(), * and runs both in 32 and 64-bit mode. * * We use the following additional strategies not used by the shorter * operand paths. Mostly, we try to optimize for memory bandwidth: * 1. Use DCBZ128 to avoid reading destination lines. Because this code * resides on the commmpage, it can use a private interface with the * kernel to minimize alignment exceptions if the destination is * uncached. The kernel will clear cr7 whenever it emulates a DCBZ or * DCBZ128 on the commpage. Thus we take at most one exception per call, * which is amortized across the very long operand. * 2. Copy larger chunks per iteration to minimize R/W bus turnaround * and maximize DRAM page locality (opening a new page is expensive.) * We use 256-byte chunks. * 3. Touch in one source chunk ahead with DCBT. This is probably the * least important change, and probably only helps restart the * hardware stream at the start of each source page. */ #define rs r13 #define rd r14 #define rc r15 #define rx r16 #define c16 r3 #define c32 r4 #define c48 r5 #define c64 r6 #define c80 r7 #define c96 r8 #define c112 r9 #define c256 r10 #define c384 r11 #define rv r12 // vrsave // Offsets within the "red zone" (which is 224 bytes long): #define rzR3 -8 #define rzR13 -16 #define rzR14 -24 #define rzR15 -32 #define rzR16 -40 #define rzV20 -64 #define rzV21 -80 #define rzV22 -96 #define rzV23 -112 #include #include #include #include .text /* * WARNING: this code is written for 32-bit mode, and ported by the kernel if necessary * to 64-bit mode for use in the 64-bit commpage. This "port" consists of the following * simple transformations: * - all word compares are changed to doubleword * - all "srwi[.]" opcodes are changed to "srdi[.]" * Nothing else is done. For this to work, the following rules must be * carefully followed: * - do not use carry or overflow * - only use record mode if you are sure the results are mode-invariant * for example, all "andi." and almost all "rlwinm." are fine * - do not use "slwi", "slw", or "srw" * An imaginative programmer could break the porting model in other ways, but the above * are the most likely problem areas. It is perhaps surprising how well in practice * this simple method works. */ // Entry point. This is a subroutine of bcopy(). When called: // r0 = return address (also stored in caller's SF) // r4 = source ptr // r5 = length (at least several pages) // r12 = dest ptr // // We only do "forward" moves, ie non-overlapping or toward 0. We return with non-volatiles // and r3 preserved. .align 5 bigcopy_970: neg r2,r12 // is destination cache-line-aligned? std r3,rzR3(r1) // save caller's r3, which must be preserved for memcpy() std r13,rzR13(r1) // spill non-volatile regs we use to redzone std r14,rzR14(r1) std r15,rzR15(r1) andi. r2,r2,0x7F // #bytes to align std r16,rzR16(r1) mr rs,r4 // copy parameters into nonvolatile registers mr rd,r12 mr rc,r5 mr rx,r0 // also save return address beq 1f // skip if already aligned // Cache-line-align destination. mr r3,rd // set up dest ptr for memcpy() mr r5,r2 // number of bytes to copy add rs,rs,r2 // then bump our parameters past initial copy add rd,rd,r2 sub rc,rc,r2 bla _COMM_PAGE_MEMCPY // 128-byte-align destination // Load constant offsets and check whether source is 16-byte aligned. // NB: the kernel clears cr7 if it emulates a dcbz128 on the commpage, // and we dcbz only if cr7 beq is set. 1: dcbt 0,rs // touch in 1st line of source andi. r0,rs,15 // check source alignment mfspr rv,vrsave // save caller's bitmask li c16,16 // load the constant offsets for x-form ops li c32,32 srwi r2,rc,8 // get number of 256-byte chunks to xfer li r0,-256 // we use 24 VRs (ie, 0-23) li c48,48 li c64,64 li c80,80 or r0,r0,rv // add our bits to caller's li c96,96 mtctr r2 // set up loop count li c112,112 cmpd cr7,r2,r2 // initialize cr7_eq to "on", so we dcbz128 mtspr vrsave,r0 // say we use vr0..vr23 li c256,256 li c384,384 beq LalignedLoop // handle aligned sources // Set up for unaligned loop. lvsl v0,0,rs // get permute vector for left shift lvxl v1,0,rs // prime the loop li r0,rzV20 // save non-volatile VRs in redzone stvx v20,r1,r0 li r0,rzV21 stvx v21,r1,r0 li r0,rzV22 stvx v22,r1,r0 li r0,rzV23 stvx v23,r1,r0 b LunalignedLoop // enter unaligned loop // Main loop for unaligned operands. We loop over 256-byte chunks (2 cache lines). // Destination is 128-byte aligned, source is unaligned. .align 5 LunalignedLoop: dcbt c256,rs // touch in next chunk dcbt c384,rs addi r2,rs,128 // point to 2nd 128 bytes of source lvxl v2,c16,rs lvxl v3,c32,rs lvxl v4,c48,rs lvxl v5,c64,rs lvxl v6,c80,rs lvxl v7,c96,rs lvxl v8,c112,rs lvxl v9,0,r2 addi rs,rs,256 // point to next source chunk lvxl v10,c16,r2 lvxl v11,c32,r2 vperm v17,v1,v2,v0 lvxl v12,c48,r2 lvxl v13,c64,r2 vperm v18,v2,v3,v0 lvxl v14,c80,r2 lvxl v15,c96,r2 vperm v19,v3,v4,v0 lvxl v16,c112,r2 lvxl v1,0,rs // peek ahead at first source quad in next chunk vperm v20,v4,v5,v0 addi r2,rd,128 // point to 2nd 128 bytes of dest bne-- cr7,1f // skip dcbz's if cr7 beq has been turned off by kernel dcbz128 0,rd dcbz128 0,r2 1: vperm v21,v5,v6,v0 stvxl v17,0,rd vperm v22,v6,v7,v0 stvxl v18,c16,rd vperm v23,v7,v8,v0 stvxl v19,c32,rd vperm v17,v8,v9,v0 stvxl v20,c48,rd vperm v18,v9,v10,v0 stvxl v21,c64,rd vperm v19,v10,v11,v0 stvxl v22,c80,rd vperm v20,v11,v12,v0 stvxl v23,c96,rd vperm v21,v12,v13,v0 stvxl v17,c112,rd vperm v22,v13,v14,v0 addi rd,rd,256 // point to next dest chunk stvxl v18,0,r2 vperm v23,v14,v15,v0 stvxl v19,c16,r2 vperm v17,v15,v16,v0 stvxl v20,c32,r2 vperm v18,v16,v1,v0 stvxl v21,c48,r2 stvxl v22,c64,r2 stvxl v23,c80,r2 stvxl v17,c96,r2 stvxl v18,c112,r2 bdnz++ LunalignedLoop // loop if another 256 bytes to go li r6,rzV20 // restore non-volatile VRs li r7,rzV21 li r8,rzV22 li r9,rzV23 lvx v20,r1,r6 lvx v21,r1,r7 lvx v22,r1,r8 lvx v23,r1,r9 b Ldone // Aligned loop. Destination is 128-byte aligned, and source is 16-byte // aligned. Loop over 256-byte chunks (2 cache lines.) .align 5 LalignedLoop: dcbt c256,rs // touch in next chunk dcbt c384,rs addi r2,rs,128 // point to 2nd 128 bytes of source lvxl v1,0,rs lvxl v2,c16,rs lvxl v3,c32,rs lvxl v4,c48,rs lvxl v5,c64,rs lvxl v6,c80,rs lvxl v7,c96,rs lvxl v8,c112,rs lvxl v9,0,r2 lvxl v10,c16,r2 lvxl v11,c32,r2 lvxl v12,c48,r2 lvxl v13,c64,r2 lvxl v14,c80,r2 lvxl v15,c96,r2 lvxl v16,c112,r2 addi r2,rd,128 // point to 2nd 128 bytes of dest bne-- cr7,1f // skip dcbz's if cr7 beq has been turned off by kernel dcbz128 0,rd dcbz128 0,r2 1: addi rs,rs,256 // point to next source chunk stvxl v1,0,rd stvxl v2,c16,rd stvxl v3,c32,rd stvxl v4,c48,rd stvxl v5,c64,rd stvxl v6,c80,rd stvxl v7,c96,rd stvxl v8,c112,rd addi rd,rd,256 // point to next dest chunk stvxl v9,0,r2 stvxl v10,c16,r2 stvxl v11,c32,r2 stvxl v12,c48,r2 stvxl v13,c64,r2 stvxl v14,c80,r2 stvxl v15,c96,r2 stvxl v16,c112,r2 bdnz++ LalignedLoop // loop if another 256 bytes to go // Done, except for 0..255 leftover bytes at end. // rs = source ptr // rd = dest ptr // rc = remaining count in low 7 bits // rv = caller's vrsave // rx = caller's return address Ldone: andi. r5,rc,0xFF // any leftover bytes? (0..255) mtspr vrsave,rv // restore bitmap of live vr's mr r3,rd mr r4,rs bnela _COMM_PAGE_MEMCPY // copy leftover bytes mtlr rx // restore return address ld r3,rzR3(r1) // restore non-volatile GPRs from redzone ld r13,rzR13(r1) ld r14,rzR14(r1) ld r15,rzR15(r1) ld r16,rzR16(r1) blr COMMPAGE_DESCRIPTOR(bigcopy_970,_COMM_PAGE_BIGCOPY,0,0,kPort32to64+kCommPageBoth)