📄 sb1.c
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/* * Copyright (C) 1996 David S. Miller (dm@engr.sgi.com) * Copyright (C) 1997, 2001 Ralf Baechle (ralf@gnu.org) * Copyright (C) 2000 Sibyte * * Written by Justin Carlson (carlson@sibyte.com) * * * 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. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ /* * In this entire file, I'm not sure what the role of the L2 on the sb1250 * is. Since it is coherent to the system, we should never need to flush * it...right?...right??? -JDC */#include <asm/mmu_context.h>/* These are probed at ld_mmu time */static unsigned int icache_size;static unsigned int dcache_size;static unsigned int icache_line_size;static unsigned int dcache_line_size;static unsigned int icache_assoc;static unsigned int dcache_assoc;static unsigned int icache_sets;static unsigned int dcache_sets;static unsigned int tlb_entries;void pgd_init(unsigned long page){ unsigned long *p = (unsigned long *) page; int i; for (i = 0; i < USER_PTRS_PER_PGD; i+=8) { p[i + 0] = (unsigned long) invalid_pte_table; p[i + 1] = (unsigned long) invalid_pte_table; p[i + 2] = (unsigned long) invalid_pte_table; p[i + 3] = (unsigned long) invalid_pte_table; p[i + 4] = (unsigned long) invalid_pte_table; p[i + 5] = (unsigned long) invalid_pte_table; p[i + 6] = (unsigned long) invalid_pte_table; p[i + 7] = (unsigned long) invalid_pte_table; }}void flush_tlb_all(void){ unsigned long flags; unsigned long old_ctx; int entry; __save_and_cli(flags); /* Save old context and create impossible VPN2 value */ old_ctx = (get_entryhi() & 0xff); set_entrylo0(0); set_entrylo1(0); for (entry = 0; entry < tlb_entries; entry++) { set_entryhi(KSEG0 + (PAGE_SIZE << 1) * entry); set_index(entry); tlb_write_indexed(); } set_entryhi(old_ctx); __restore_flags(flags); }/* These are the functions hooked by the memory management function pointers */static void sb1_clear_page(void *page){ /* JDCXXX - This should be bottlenecked by the write buffer, but these things tend to be mildly unpredictable...should check this on the performance model */ /* We prefetch 4 lines ahead. We're also "cheating" slightly here... since we know we're on an SB1, we force the assembler to take 64-bit operands to speed things up */ __asm__ __volatile__( ".set push \n" ".set noreorder \n" ".set noat \n" ".set mips4 \n" " addiu $1, %0, %2 \n" /* Calculate the end of the page to clear */ " pref 5, 0(%0) \n" /* Prefetch the first 4 lines */ " pref 5, 32(%0) \n" " pref 5, 64(%0) \n" " pref 5, 96(%0) \n" "1: sd $0, 0(%0) \n" /* Throw out a cacheline of 0's */ " sd $0, 8(%0) \n" " sd $0, 16(%0) \n" " sd $0, 24(%0) \n" " pref 5,128(%0) \n" /* Prefetch 4 lines ahead */ " bne $1, %0, 1b \n" " addiu %0, %0, 32 \n" /* Next cacheline (This instruction better be short piped!) */ ".set pop \n" :"=r" (page) :"0" (page), "I" (PAGE_SIZE-32) :"$1","memory");}static void sb1_copy_page(void *to, void *from){ /* This should be optimized in assembly...can't use ld/sd, though, * because the top 32 bits could be nuked if we took an interrupt * during the routine. And this is not a good place to be cli()'ing */ /* The pref's used here are using "streaming" hints, which cause the * copied data to be kicked out of the cache sooner. A page copy often * ends up copying a lot more data than is commonly used, so this seems * to make sense in terms of reducing cache pollution, but I've no real * performance data to back this up */ __asm__ __volatile__( ".set push \n" ".set noreorder \n" ".set noat \n" ".set mips4 \n" " addiu $1, %0, %4 \n" /* Calculate the end of the page to copy */ " pref 4, 0(%0) \n" /* Prefetch the first 3 lines to be read and copied */ " pref 5, 0(%1) \n" " pref 4, 32(%0) \n" " pref 5, 32(%1) \n" " pref 4, 64(%0) \n" " pref 5, 64(%1) \n" "1: lw $2, 0(%0) \n" /* Block copy a cacheline */ " lw $3, 4(%0) \n" " lw $4, 8(%0) \n" " lw $5, 12(%0) \n" " lw $6, 16(%0) \n" " lw $7, 20(%0) \n" " lw $8, 24(%0) \n" " lw $9, 28(%0) \n" " pref 4, 96(%0) \n" /* Prefetch ahead */ " pref 5, 96(%1) \n" " sw $2, 0(%1) \n" " sw $3, 4(%1) \n" " sw $4, 8(%1) \n" " sw $5, 12(%1) \n" " sw $6, 16(%1) \n" " sw $7, 20(%1) \n" " sw $8, 24(%1) \n" " sw $9, 28(%1) \n" " addiu %1, %1, 32 \n" /* Next cacheline */ " nop \n" /* Force next add to short pipe */ " nop \n" /* Force next add to short pipe */ " bne $1, %0, 1b \n" " addiu %0, %0, 32 \n" /* Next cacheline */ ".set pop \n" :"=r" (to), "=r" (from) : "0" (from), "1" (to), "I" (PAGE_SIZE-32) :"$1","$2","$3","$4","$5","$6","$7","$8","$9","memory");/* unsigned long *src = from; unsigned long *dest = to; unsigned long *target = (unsigned long *) (((unsigned long)src) + PAGE_SIZE); while (src != target) { *dest++ = *src++; }*/}/* * The dcache is fully coherent to the system, with one * big caveat: the instruction stream. In other words, * if we miss in the icache, and have dirty data in the * L1 dcache, then we'll go out to memory (or the L2) and * get the not-as-recent data. * * So the only time we have to flush the dcache is when * we're flushing the icache. Since the L2 is fully * coherent to everything, including I/O, we never have * to flush it */static void sb1_flush_cache_all(void){ /* * Haven't worried too much about speed here; given that we're flushing * the icache, the time to invalidate is dwarfed by the time it's going * to take to refill it. Register usage: * * $1 - moving cache index * $2 - set count */ if (icache_sets) { __asm__ __volatile__ ( ".set push \n" ".set noreorder \n" ".set noat \n" ".set mips4 \n" " move $1, %2 \n" /* Start at index 0 */ "1: cache 0, 0($1) \n" /* Invalidate this index */ " addiu %1, %1, -1 \n" /* Decrement loop count */ " bnez %1, 1b \n" /* loop test */ " addu $1, $1, %0 \n" /* Next address JDCXXX - Should be short piped */ ".set pop \n" ::"r" (icache_line_size), "r" (icache_sets * icache_assoc), "r" (KSEG0) :"$1"); } if (dcache_sets) { __asm__ __volatile__ ( ".set push \n" ".set noreorder \n" ".set noat \n" ".set mips4 \n" " move $1, %2 \n" /* Start at index 0 */ "1: cache 0x1, 0($1) \n" /* WB/Invalidate this index */ " addiu %1, %1, -1 \n" /* Decrement loop count */ " bnez %1, 1b \n" /* loop test */ " addu $1, $1, %0 \n" /* Next address JDCXXX - Should be short piped */ ".set pop \n" ::"r" (dcache_line_size), "r" (dcache_sets * dcache_assoc), "r" (KSEG0) :"$1"); }}/* * When flushing a range in the icache, we have to first writeback * the dcache for the same range, so new ifetches will see any * data that was dirty in the dcache */static void sb1_flush_icache_range(unsigned long start, unsigned long end){ /* JDCXXX - Implement me! */ sb1_flush_cache_all();}static void sb1_flush_cache_mm(struct mm_struct *mm){ /* Don't need to do this, as the dcache is physically tagged */}static void sb1_flush_cache_range(struct mm_struct *mm, unsigned long start, unsigned long end){ /* Don't need to do this, as the dcache is physically tagged */}static void sb1_flush_cache_sigtramp(unsigned long page){ /* JDCXXX - Implement me! */ sb1_flush_cache_all();}/* * This only needs to make sure stores done up to this * point are visible to other agents outside the CPU. Given * the coherent nature of the ZBus, all that's required here is * a sync to make sure the data gets out to the caches and is * visible to an arbitrary A Phase from an external agent * * Actually, I'm not even sure that's necessary; the semantics * of this function aren't clear. If it's supposed to serve as * a memory barrier, this is needed. If it's only meant to * prevent data from being invisible to non-cpu memory accessors * for some indefinite period of time (e.g. in a non-coherent * dcache) then this function would be a complete nop. */static void sb1_flush_page_to_ram(struct page *page){ __asm__ __volatile__( " sync \n" /* Short pipe */ :::"memory"); }/* Cribbed from the r2300 code */static void sb1_flush_cache_page(struct vm_area_struct *vma, unsigned long page){ sb1_flush_cache_all();#if 0 struct mm_struct *mm = vma->vm_mm; unsigned long physpage; /* No icache flush needed without context; */ if (mm->context == 0) return; /* No icache flush needed if the page isn't executable */ if (!(vma->vm_flags & VM_EXEC)) return; physpage = (unsigned long) page_address(page); if (physpage) sb1_flush_icache_range(physpage, physpage + PAGE_SIZE);#endif}/* * Cache set values (from the mips64 spec) * 0 - 64 * 1 - 128 * 2 - 256 * 3 - 512 * 4 - 1024 * 5 - 2048 * 6 - 4096 * 7 - Reserved */static unsigned int decode_cache_sets(unsigned int config_field){ if (config_field == 7) { /* JDCXXX - Find a graceful way to abort. */ return 0; } return (1<<(config_field + 6));}/* * Cache line size values (from the mips64 spec) * 0 - No cache present. * 1 - 4 bytes * 2 - 8 bytes * 3 - 16 bytes * 4 - 32 bytes * 5 - 64 bytes * 6 - 128 bytes * 7 - Reserved */static unsigned int decode_cache_line_size(unsigned int config_field){ if (config_field == 0) { return 0; } else if (config_field == 7) { /* JDCXXX - Find a graceful way to abort. */ return 0; } return (1<<(config_field + 1));}/* * Relevant bits of the config1 register format (from the MIPS32/MIPS64 specs) * * 24:22 Icache sets per way * 21:19 Icache line size * 18:16 Icache Associativity * 15:13 Dcache sets per way * 12:10 Dcache line size * 9:7 Dcache Associativity */static void probe_cache_sizes(void){ u32 config1; __asm__ __volatile__( ".set push \n" ".set mips64 \n" " mfc0 %0, $16, 1 \n" /* Get config1 register */ ".set pop \n" :"=r" (config1)); icache_line_size = decode_cache_line_size((config1 >> 19) & 0x7); dcache_line_size = decode_cache_line_size((config1 >> 10) & 0x7); icache_sets = decode_cache_sets((config1 >> 22) & 0x7); dcache_sets = decode_cache_sets((config1 >> 13) & 0x7); icache_assoc = ((config1 >> 16) & 0x7) + 1; dcache_assoc = ((config1 >> 7) & 0x7) + 1; icache_size = icache_line_size * icache_sets * icache_assoc; dcache_size = dcache_line_size * dcache_sets * dcache_assoc; tlb_entries = ((config1 >> 25) & 0x3f) + 1;}/* This is called from loadmmu.c. We have to set up all the memory management function pointers, as well as initialize the caches and tlbs */void ld_mmu_sb1(void){ probe_cache_sizes(); _clear_page = sb1_clear_page; _copy_page = sb1_copy_page; _flush_cache_all = sb1_flush_cache_all; _flush_cache_mm = sb1_flush_cache_mm; _flush_cache_range = sb1_flush_cache_range; _flush_cache_page = sb1_flush_cache_page; _flush_cache_sigtramp = sb1_flush_cache_sigtramp; _flush_page_to_ram = sb1_flush_page_to_ram; _flush_icache_page = sb1_flush_cache_page; _flush_icache_range = sb1_flush_icache_range; /* * JDCXXX I'm not sure whether these are necessary: is this the right * place to initialize the tlb? If it is, why is it done * at this level instead of as common code in loadmmu()? */ flush_cache_all(); flush_tlb_all(); /* Turn on caching in kseg0 */ set_cp0_config(CONF_CM_CMASK, 0);}⌨️ 快捷键说明
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