/* * linux/arch/arm/lib/copypage-xscale.S * * Copyright (C) 1995-2005 Russell King * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License version 2 as * published by the Free Software Foundation. * * This handles the mini data cache, as found on SA11x0 and XScale * processors. When we copy a user page page, we map it in such a way * that accesses to this page will not touch the main data cache, but * will be cached in the mini data cache. This prevents us thrashing * the main data cache on page faults. */ #include #include #include #include #include #include #include "mm.h" /* * 0xffff8000 to 0xffffffff is reserved for any ARM architecture * specific hacks for copying pages efficiently. */ #define COPYPAGE_MINICACHE 0xffff8000 #define minicache_pgprot __pgprot(L_PTE_PRESENT | L_PTE_YOUNG | \ L_PTE_MT_MINICACHE) static DEFINE_SPINLOCK(minicache_lock); /* * XScale mini-dcache optimised copy_user_highpage * * We flush the destination cache lines just before we write the data into the * corresponding address. Since the Dcache is read-allocate, this removes the * Dcache aliasing issue. The writes will be forwarded to the write buffer, * and merged as appropriate. */ static void __attribute__((naked)) mc_copy_user_page(void *from, void *to) { /* * Strangely enough, best performance is achieved * when prefetching destination as well. (NP) */ asm volatile( "stmfd sp!, {r4, r5, lr} \n\ mov lr, %2 \n\ pld [r0, #0] \n\ pld [r0, #32] \n\ pld [r1, #0] \n\ pld [r1, #32] \n\ 1: pld [r0, #64] \n\ pld [r0, #96] \n\ pld [r1, #64] \n\ pld [r1, #96] \n\ 2: ldrd r2, [r0], #8 \n\ ldrd r4, [r0], #8 \n\ mov ip, r1 \n\ strd r2, [r1], #8 \n\ ldrd r2, [r0], #8 \n\ strd r4, [r1], #8 \n\ ldrd r4, [r0], #8 \n\ strd r2, [r1], #8 \n\ strd r4, [r1], #8 \n\ mcr p15, 0, ip, c7, c10, 1 @ clean D line\n\ ldrd r2, [r0], #8 \n\ mcr p15, 0, ip, c7, c6, 1 @ invalidate D line\n\ ldrd r4, [r0], #8 \n\ mov ip, r1 \n\ strd r2, [r1], #8 \n\ ldrd r2, [r0], #8 \n\ strd r4, [r1], #8 \n\ ldrd r4, [r0], #8 \n\ strd r2, [r1], #8 \n\ strd r4, [r1], #8 \n\ mcr p15, 0, ip, c7, c10, 1 @ clean D line\n\ subs lr, lr, #1 \n\ mcr p15, 0, ip, c7, c6, 1 @ invalidate D line\n\ bgt 1b \n\ beq 2b \n\ ldmfd sp!, {r4, r5, pc} " : : "r" (from), "r" (to), "I" (PAGE_SIZE / 64 - 1)); } void xscale_mc_copy_user_highpage(struct page *to, struct page *from, unsigned long vaddr) { void *kto = kmap_atomic(to, KM_USER1); if (test_and_clear_bit(PG_dcache_dirty, &from->flags)) __flush_dcache_page(page_mapping(from), from); spin_lock(&minicache_lock); set_pte_ext(TOP_PTE(COPYPAGE_MINICACHE), pfn_pte(page_to_pfn(from), minicache_pgprot), 0); flush_tlb_kernel_page(COPYPAGE_MINICACHE); mc_copy_user_page((void *)COPYPAGE_MINICACHE, kto); spin_unlock(&minicache_lock); kunmap_atomic(kto, KM_USER1); } /* * XScale optimised clear_user_page */ void xscale_mc_clear_user_highpage(struct page *page, unsigned long vaddr) { void *kaddr = kmap_atomic(page, KM_USER0); asm volatile( "mov r1, %1 \n\ mov r2, #0 \n\ mov r3, #0 \n\ 1: mov ip, %0 \n\ strd r2, [%0], #8 \n\ strd r2, [%0], #8 \n\ strd r2, [%0], #8 \n\ strd r2, [%0], #8 \n\ mcr p15, 0, ip, c7, c10, 1 @ clean D line\n\ subs r1, r1, #1 \n\ mcr p15, 0, ip, c7, c6, 1 @ invalidate D line\n\ bne 1b" : : "r" (kaddr), "I" (PAGE_SIZE / 32) : "r1", "r2", "r3", "ip"); kunmap_atomic(kaddr, KM_USER0); } struct cpu_user_fns xscale_mc_user_fns __initdata = { .cpu_clear_user_highpage = xscale_mc_clear_user_highpage, .cpu_copy_user_highpage = xscale_mc_copy_user_highpage, };