/* * ARC Cache Management * * Copyright (C) 2014-15 Synopsys, Inc. (www.synopsys.com) * Copyright (C) 2004, 2007-2010, 2011-2012 Synopsys, Inc. (www.synopsys.com) * * 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. */ #include #include #include #include #include #include #include #include #include #include #include static int l2_line_sz; static int ioc_exists; int slc_enable = 1, ioc_enable = 0; unsigned long perip_base = ARC_UNCACHED_ADDR_SPACE; /* legacy value for boot */ unsigned long perip_end = 0xFFFFFFFF; /* legacy value */ void (*_cache_line_loop_ic_fn)(phys_addr_t paddr, unsigned long vaddr, unsigned long sz, const int cacheop); void (*__dma_cache_wback_inv)(phys_addr_t start, unsigned long sz); void (*__dma_cache_inv)(phys_addr_t start, unsigned long sz); void (*__dma_cache_wback)(phys_addr_t start, unsigned long sz); char *arc_cache_mumbojumbo(int c, char *buf, int len) { int n = 0; struct cpuinfo_arc_cache *p; #define PR_CACHE(p, cfg, str) \ if (!(p)->ver) \ n += scnprintf(buf + n, len - n, str"\t\t: N/A\n"); \ else \ n += scnprintf(buf + n, len - n, \ str"\t\t: %uK, %dway/set, %uB Line, %s%s%s\n", \ (p)->sz_k, (p)->assoc, (p)->line_len, \ (p)->vipt ? "VIPT" : "PIPT", \ (p)->alias ? " aliasing" : "", \ IS_USED_CFG(cfg)); PR_CACHE(&cpuinfo_arc700[c].icache, CONFIG_ARC_HAS_ICACHE, "I-Cache"); PR_CACHE(&cpuinfo_arc700[c].dcache, CONFIG_ARC_HAS_DCACHE, "D-Cache"); p = &cpuinfo_arc700[c].slc; if (p->ver) n += scnprintf(buf + n, len - n, "SLC\t\t: %uK, %uB Line%s\n", p->sz_k, p->line_len, IS_USED_RUN(slc_enable)); n += scnprintf(buf + n, len - n, "Peripherals\t: %#lx%s%s\n", perip_base, IS_AVAIL3(ioc_exists, ioc_enable, ", IO-Coherency ")); return buf; } /* * Read the Cache Build Confuration Registers, Decode them and save into * the cpuinfo structure for later use. * No Validation done here, simply read/convert the BCRs */ static void read_decode_cache_bcr_arcv2(int cpu) { struct cpuinfo_arc_cache *p_slc = &cpuinfo_arc700[cpu].slc; struct bcr_generic sbcr; struct bcr_slc_cfg { #ifdef CONFIG_CPU_BIG_ENDIAN unsigned int pad:24, way:2, lsz:2, sz:4; #else unsigned int sz:4, lsz:2, way:2, pad:24; #endif } slc_cfg; struct bcr_clust_cfg { #ifdef CONFIG_CPU_BIG_ENDIAN unsigned int pad:7, c:1, num_entries:8, num_cores:8, ver:8; #else unsigned int ver:8, num_cores:8, num_entries:8, c:1, pad:7; #endif } cbcr; struct bcr_volatile { #ifdef CONFIG_CPU_BIG_ENDIAN unsigned int start:4, limit:4, pad:22, order:1, disable:1; #else unsigned int disable:1, order:1, pad:22, limit:4, start:4; #endif } vol; READ_BCR(ARC_REG_SLC_BCR, sbcr); if (sbcr.ver) { READ_BCR(ARC_REG_SLC_CFG, slc_cfg); p_slc->ver = sbcr.ver; p_slc->sz_k = 128 << slc_cfg.sz; l2_line_sz = p_slc->line_len = (slc_cfg.lsz == 0) ? 128 : 64; } READ_BCR(ARC_REG_CLUSTER_BCR, cbcr); if (cbcr.c) ioc_exists = 1; else ioc_enable = 0; /* HS 2.0 didn't have AUX_VOL */ if (cpuinfo_arc700[cpu].core.family > 0x51) { READ_BCR(AUX_VOL, vol); perip_base = vol.start << 28; /* HS 3.0 has limit and strict-ordering fields */ if (cpuinfo_arc700[cpu].core.family > 0x52) perip_end = (vol.limit << 28) - 1; } } void read_decode_cache_bcr(void) { struct cpuinfo_arc_cache *p_ic, *p_dc; unsigned int cpu = smp_processor_id(); struct bcr_cache { #ifdef CONFIG_CPU_BIG_ENDIAN unsigned int pad:12, line_len:4, sz:4, config:4, ver:8; #else unsigned int ver:8, config:4, sz:4, line_len:4, pad:12; #endif } ibcr, dbcr; p_ic = &cpuinfo_arc700[cpu].icache; READ_BCR(ARC_REG_IC_BCR, ibcr); if (!ibcr.ver) goto dc_chk; if (ibcr.ver <= 3) { BUG_ON(ibcr.config != 3); p_ic->assoc = 2; /* Fixed to 2w set assoc */ } else if (ibcr.ver >= 4) { p_ic->assoc = 1 << ibcr.config; /* 1,2,4,8 */ } p_ic->line_len = 8 << ibcr.line_len; p_ic->sz_k = 1 << (ibcr.sz - 1); p_ic->ver = ibcr.ver; p_ic->vipt = 1; p_ic->alias = p_ic->sz_k/p_ic->assoc/TO_KB(PAGE_SIZE) > 1; dc_chk: p_dc = &cpuinfo_arc700[cpu].dcache; READ_BCR(ARC_REG_DC_BCR, dbcr); if (!dbcr.ver) goto slc_chk; if (dbcr.ver <= 3) { BUG_ON(dbcr.config != 2); p_dc->assoc = 4; /* Fixed to 4w set assoc */ p_dc->vipt = 1; p_dc->alias = p_dc->sz_k/p_dc->assoc/TO_KB(PAGE_SIZE) > 1; } else if (dbcr.ver >= 4) { p_dc->assoc = 1 << dbcr.config; /* 1,2,4,8 */ p_dc->vipt = 0; p_dc->alias = 0; /* PIPT so can't VIPT alias */ } p_dc->line_len = 16 << dbcr.line_len; p_dc->sz_k = 1 << (dbcr.sz - 1); p_dc->ver = dbcr.ver; slc_chk: if (is_isa_arcv2()) read_decode_cache_bcr_arcv2(cpu); } /* * Line Operation on {I,D}-Cache */ #define OP_INV 0x1 #define OP_FLUSH 0x2 #define OP_FLUSH_N_INV 0x3 #define OP_INV_IC 0x4 /* * I-Cache Aliasing in ARC700 VIPT caches (MMU v1-v3) * * ARC VIPT I-cache uses vaddr to index into cache and paddr to match the tag. * The orig Cache Management Module "CDU" only required paddr to invalidate a * certain line since it sufficed as index in Non-Aliasing VIPT cache-geometry. * Infact for distinct V1,V2,P: all of {V1-P},{V2-P},{P-P} would end up fetching * the exact same line. * * However for larger Caches (way-size > page-size) - i.e. in Aliasing config, * paddr alone could not be used to correctly index the cache. * * ------------------ * MMU v1/v2 (Fixed Page Size 8k) * ------------------ * The solution was to provide CDU with these additonal vaddr bits. These * would be bits [x:13], x would depend on cache-geometry, 13 comes from * standard page size of 8k. * H/w folks chose [17:13] to be a future safe range, and moreso these 5 bits * of vaddr could easily be "stuffed" in the paddr as bits [4:0] since the * orig 5 bits of paddr were anyways ignored by CDU line ops, as they * represent the offset within cache-line. The adv of using this "clumsy" * interface for additional info was no new reg was needed in CDU programming * model. * * 17:13 represented the max num of bits passable, actual bits needed were * fewer, based on the num-of-aliases possible. * -for 2 alias possibility, only bit 13 needed (32K cache) * -for 4 alias possibility, bits 14:13 needed (64K cache) * * ------------------ * MMU v3 * ------------------ * This ver of MMU supports variable page sizes (1k-16k): although Linux will * only support 8k (default), 16k and 4k. * However from hardware perspective, smaller page sizes aggravate aliasing * meaning more vaddr bits needed to disambiguate the cache-line-op ; * the existing scheme of piggybacking won't work for certain configurations. * Two new registers IC_PTAG and DC_PTAG inttoduced. * "tag" bits are provided in PTAG, index bits in existing IVIL/IVDL/FLDL regs */ static inline void __cache_line_loop_v2(phys_addr_t paddr, unsigned long vaddr, unsigned long sz, const int op) { unsigned int aux_cmd; int num_lines; const int full_page = __builtin_constant_p(sz) && sz == PAGE_SIZE; if (op == OP_INV_IC) { aux_cmd = ARC_REG_IC_IVIL; } else { /* d$ cmd: INV (discard or wback-n-discard) OR FLUSH (wback) */ aux_cmd = op & OP_INV ? ARC_REG_DC_IVDL : ARC_REG_DC_FLDL; } /* Ensure we properly floor/ceil the non-line aligned/sized requests * and have @paddr - aligned to cache line and integral @num_lines. * This however can be avoided for page sized since: * -@paddr will be cache-line aligned already (being page aligned) * -@sz will be integral multiple of line size (being page sized). */ if (!full_page) { sz += paddr & ~CACHE_LINE_MASK; paddr &= CACHE_LINE_MASK; vaddr &= CACHE_LINE_MASK; } num_lines = DIV_ROUND_UP(sz, L1_CACHE_BYTES); /* MMUv2 and before: paddr contains stuffed vaddrs bits */ paddr |= (vaddr >> PAGE_SHIFT) & 0x1F; while (num_lines-- > 0) { write_aux_reg(aux_cmd, paddr); paddr += L1_CACHE_BYTES; } } /* * For ARC700 MMUv3 I-cache and D-cache flushes * Also reused for HS38 aliasing I-cache configuration */ static inline void __cache_line_loop_v3(phys_addr_t paddr, unsigned long vaddr, unsigned long sz, const int op) { unsigned int aux_cmd, aux_tag; int num_lines; const int full_page = __builtin_constant_p(sz) && sz == PAGE_SIZE; if (op == OP_INV_IC) { aux_cmd = ARC_REG_IC_IVIL; aux_tag = ARC_REG_IC_PTAG; } else { aux_cmd = op & OP_INV ? ARC_REG_DC_IVDL : ARC_REG_DC_FLDL; aux_tag = ARC_REG_DC_PTAG; } /* Ensure we properly floor/ceil the non-line aligned/sized requests * and have @paddr - aligned to cache line and integral @num_lines. * This however can be avoided for page sized since: * -@paddr will be cache-line aligned already (being page aligned) * -@sz will be integral multiple of line size (being page sized). */ if (!full_page) { sz += paddr & ~CACHE_LINE_MASK; paddr &= CACHE_LINE_MASK; vaddr &= CACHE_LINE_MASK; } num_lines = DIV_ROUND_UP(sz, L1_CACHE_BYTES); /* * MMUv3, cache ops require paddr in PTAG reg * if V-P const for loop, PTAG can be written once outside loop */ if (full_page) write_aux_reg(aux_tag, paddr); /* * This is technically for MMU v4, using the MMU v3 programming model * Special work for HS38 aliasing I-cache configuration with PAE40 * - upper 8 bits of paddr need to be written into PTAG_HI * - (and needs to be written before the lower 32 bits) * Note that PTAG_HI is hoisted outside the line loop */ if (is_pae40_enabled() && op == OP_INV_IC) write_aux_reg(ARC_REG_IC_PTAG_HI, (u64)paddr >> 32); while (num_lines-- > 0) { if (!full_page) { write_aux_reg(aux_tag, paddr); paddr += L1_CACHE_BYTES; } write_aux_reg(aux_cmd, vaddr); vaddr += L1_CACHE_BYTES; } } /* * In HS38x (MMU v4), I-cache is VIPT (can alias), D-cache is PIPT * Here's how cache ops are implemented * * - D-cache: only paddr needed (in DC_IVDL/DC_FLDL) * - I-cache Non Aliasing: Despite VIPT, only paddr needed (in IC_IVIL) * - I-cache Aliasing: Both vaddr and paddr needed (in IC_IVIL, IC_PTAG * respectively, similar to MMU v3 programming model, hence * __cache_line_loop_v3() is used) * * If PAE40 is enabled, independent of aliasing considerations, the higher bits * needs to be written into PTAG_HI */ static inline void __cache_line_loop_v4(phys_addr_t paddr, unsigned long vaddr, unsigned long sz, const int cacheop) { unsigned int aux_cmd; int num_lines; const int full_page_op = __builtin_constant_p(sz) && sz == PAGE_SIZE; if (cacheop == OP_INV_IC) { aux_cmd = ARC_REG_IC_IVIL; } else { /* d$ cmd: INV (discard or wback-n-discard) OR FLUSH (wback) */ aux_cmd = cacheop & OP_INV ? ARC_REG_DC_IVDL : ARC_REG_DC_FLDL; } /* Ensure we properly floor/ceil the non-line aligned/sized requests * and have @paddr - aligned to cache line and integral @num_lines. * This however can be avoided for page sized since: * -@paddr will be cache-line aligned already (being page aligned) * -@sz will be integral multiple of line size (being page sized). */ if (!full_page_op) { sz += paddr & ~CACHE_LINE_MASK; paddr &= CACHE_LINE_MASK; } num_lines = DIV_ROUND_UP(sz, L1_CACHE_BYTES); /* * For HS38 PAE40 configuration * - upper 8 bits of paddr need to be written into PTAG_HI * - (and needs to be written before the lower 32 bits) */ if (is_pae40_enabled()) { if (cacheop == OP_INV_IC) /* * Non aliasing I-cache in HS38, * aliasing I-cache handled in __cache_line_loop_v3() */ write_aux_reg(ARC_REG_IC_PTAG_HI, (u64)paddr >> 32); else write_aux_reg(ARC_REG_DC_PTAG_HI, (u64)paddr >> 32); } while (num_lines-- > 0) { write_aux_reg(aux_cmd, paddr); paddr += L1_CACHE_BYTES; } } #if (CONFIG_ARC_MMU_VER < 3) #define __cache_line_loop __cache_line_loop_v2 #elif (CONFIG_ARC_MMU_VER == 3) #define __cache_line_loop __cache_line_loop_v3 #elif (CONFIG_ARC_MMU_VER > 3) #define __cache_line_loop __cache_line_loop_v4 #endif #ifdef CONFIG_ARC_HAS_DCACHE /*************************************************************** * Machine specific helpers for Entire D-Cache or Per Line ops */ static inline void __before_dc_op(const int op) { if (op == OP_FLUSH_N_INV) { /* Dcache provides 2 cmd: FLUSH or INV * INV inturn has sub-modes: DISCARD or FLUSH-BEFORE * flush-n-inv is achieved by INV cmd but with IM=1 * So toggle INV sub-mode depending on op request and default */ const unsigned int ctl = ARC_REG_DC_CTRL; write_aux_reg(ctl, read_aux_reg(ctl) | DC_CTRL_INV_MODE_FLUSH); } } static inline void __after_dc_op(const int op) { if (op & OP_FLUSH) { const unsigned int ctl = ARC_REG_DC_CTRL; unsigned int reg; /* flush / flush-n-inv both wait */ while ((reg = read_aux_reg(ctl)) & DC_CTRL_FLUSH_STATUS) ; /* Switch back to default Invalidate mode */ if (op == OP_FLUSH_N_INV) write_aux_reg(ctl, reg & ~DC_CTRL_INV_MODE_FLUSH); } } /* * Operation on Entire D-Cache * @op = {OP_INV, OP_FLUSH, OP_FLUSH_N_INV} * Note that constant propagation ensures all the checks are gone * in generated code */ static inline void __dc_entire_op(const int op) { int aux; __before_dc_op(op); if (op & OP_INV) /* Inv or flush-n-inv use same cmd reg */ aux = ARC_REG_DC_IVDC; else aux = ARC_REG_DC_FLSH; write_aux_reg(aux, 0x1); __after_dc_op(op); } /* For kernel mappings cache operation: index is same as paddr */ #define __dc_line_op_k(p, sz, op) __dc_line_op(p, p, sz, op) /* * D-Cache Line ops: Per Line INV (discard or wback+discard) or FLUSH (wback) */ static inline void __dc_line_op(phys_addr_t paddr, unsigned long vaddr, unsigned long sz, const int op) { unsigned long flags; local_irq_save(flags); __before_dc_op(op); __cache_line_loop(paddr, vaddr, sz, op); __after_dc_op(op); local_irq_restore(flags); } #else #define __dc_entire_op(op) #define __dc_line_op(paddr, vaddr, sz, op) #define __dc_line_op_k(paddr, sz, op) #endif /* CONFIG_ARC_HAS_DCACHE */ #ifdef CONFIG_ARC_HAS_ICACHE static inline void __ic_entire_inv(void) { write_aux_reg(ARC_REG_IC_IVIC, 1); read_aux_reg(ARC_REG_IC_CTRL); /* blocks */ } static inline void __ic_line_inv_vaddr_local(phys_addr_t paddr, unsigned long vaddr, unsigned long sz) { unsigned long flags; local_irq_save(flags); (*_cache_line_loop_ic_fn)(paddr, vaddr, sz, OP_INV_IC); local_irq_restore(flags); } #ifndef CONFIG_SMP #define __ic_line_inv_vaddr(p, v, s) __ic_line_inv_vaddr_local(p, v, s) #else struct ic_inv_args { phys_addr_t paddr, vaddr; int sz; }; static void __ic_line_inv_vaddr_helper(void *info) { struct ic_inv_args *ic_inv = info; __ic_line_inv_vaddr_local(ic_inv->paddr, ic_inv->vaddr, ic_inv->sz); } static void __ic_line_inv_vaddr(phys_addr_t paddr, unsigned long vaddr, unsigned long sz) { struct ic_inv_args ic_inv = { .paddr = paddr, .vaddr = vaddr, .sz = sz }; on_each_cpu(__ic_line_inv_vaddr_helper, &ic_inv, 1); } #endif /* CONFIG_SMP */ #else /* !CONFIG_ARC_HAS_ICACHE */ #define __ic_entire_inv() #define __ic_line_inv_vaddr(pstart, vstart, sz) #endif /* CONFIG_ARC_HAS_ICACHE */ noinline void slc_op(phys_addr_t paddr, unsigned long sz, const int op) { #ifdef CONFIG_ISA_ARCV2 /* * SLC is shared between all cores and concurrent aux operations from * multiple cores need to be serialized using a spinlock * A concurrent operation can be silently ignored and/or the old/new * operation can remain incomplete forever (lockup in SLC_CTRL_BUSY loop * below) */ static DEFINE_SPINLOCK(lock); unsigned long flags; unsigned int ctrl; phys_addr_t end; spin_lock_irqsave(&lock, flags); /* * The Region Flush operation is specified by CTRL.RGN_OP[11..9] * - b'000 (default) is Flush, * - b'001 is Invalidate if CTRL.IM == 0 * - b'001 is Flush-n-Invalidate if CTRL.IM == 1 */ ctrl = read_aux_reg(ARC_REG_SLC_CTRL); /* Don't rely on default value of IM bit */ if (!(op & OP_FLUSH)) /* i.e. OP_INV */ ctrl &= ~SLC_CTRL_IM; /* clear IM: Disable flush before Inv */ else ctrl |= SLC_CTRL_IM; if (op & OP_INV) ctrl |= SLC_CTRL_RGN_OP_INV; /* Inv or flush-n-inv */ else ctrl &= ~SLC_CTRL_RGN_OP_INV; write_aux_reg(ARC_REG_SLC_CTRL, ctrl); /* * Lower bits are ignored, no need to clip * END needs to be setup before START (latter triggers the operation) * END can't be same as START, so add (l2_line_sz - 1) to sz */ end = paddr + sz + l2_line_sz - 1; if (is_pae40_enabled()) write_aux_reg(ARC_REG_SLC_RGN_END1, upper_32_bits(end)); write_aux_reg(ARC_REG_SLC_RGN_END, lower_32_bits(end)); if (is_pae40_enabled()) write_aux_reg(ARC_REG_SLC_RGN_START1, upper_32_bits(paddr)); write_aux_reg(ARC_REG_SLC_RGN_START, lower_32_bits(paddr)); while (read_aux_reg(ARC_REG_SLC_CTRL) & SLC_CTRL_BUSY); spin_unlock_irqrestore(&lock, flags); #endif } /*********************************************************** * Exported APIs */ /* * Handle cache congruency of kernel and userspace mappings of page when kernel * writes-to/reads-from * * The idea is to defer flushing of kernel mapping after a WRITE, possible if: * -dcache is NOT aliasing, hence any U/K-mappings of page are congruent * -U-mapping doesn't exist yet for page (finalised in update_mmu_cache) * -In SMP, if hardware caches are coherent * * There's a corollary case, where kernel READs from a userspace mapped page. * If the U-mapping is not congruent to to K-mapping, former needs flushing. */ void flush_dcache_page(struct page *page) { struct address_space *mapping; if (!cache_is_vipt_aliasing()) { clear_bit(PG_dc_clean, &page->flags); return; } /* don't handle anon pages here */ mapping = page_mapping(page); if (!mapping) return; /* * pagecache page, file not yet mapped to userspace * Make a note that K-mapping is dirty */ if (!mapping_mapped(mapping)) { clear_bit(PG_dc_clean, &page->flags); } else if (page_mapcount(page)) { /* kernel reading from page with U-mapping */ phys_addr_t paddr = (unsigned long)page_address(page); unsigned long vaddr = page->index << PAGE_SHIFT; if (addr_not_cache_congruent(paddr, vaddr)) __flush_dcache_page(paddr, vaddr); } } EXPORT_SYMBOL(flush_dcache_page); /* * DMA ops for systems with L1 cache only * Make memory coherent with L1 cache by flushing/invalidating L1 lines */ static void __dma_cache_wback_inv_l1(phys_addr_t start, unsigned long sz) { __dc_line_op_k(start, sz, OP_FLUSH_N_INV); } static void __dma_cache_inv_l1(phys_addr_t start, unsigned long sz) { __dc_line_op_k(start, sz, OP_INV); } static void __dma_cache_wback_l1(phys_addr_t start, unsigned long sz) { __dc_line_op_k(start, sz, OP_FLUSH); } /* * DMA ops for systems with both L1 and L2 caches, but without IOC * Both L1 and L2 lines need to be explicitly flushed/invalidated */ static void __dma_cache_wback_inv_slc(phys_addr_t start, unsigned long sz) { __dc_line_op_k(start, sz, OP_FLUSH_N_INV); slc_op(start, sz, OP_FLUSH_N_INV); } static void __dma_cache_inv_slc(phys_addr_t start, unsigned long sz) { __dc_line_op_k(start, sz, OP_INV); slc_op(start, sz, OP_INV); } static void __dma_cache_wback_slc(phys_addr_t start, unsigned long sz) { __dc_line_op_k(start, sz, OP_FLUSH); slc_op(start, sz, OP_FLUSH); } /* * DMA ops for systems with IOC * IOC hardware snoops all DMA traffic keeping the caches consistent with * memory - eliding need for any explicit cache maintenance of DMA buffers */ static void __dma_cache_wback_inv_ioc(phys_addr_t start, unsigned long sz) {} static void __dma_cache_inv_ioc(phys_addr_t start, unsigned long sz) {} static void __dma_cache_wback_ioc(phys_addr_t start, unsigned long sz) {} /* * Exported DMA API */ void dma_cache_wback_inv(phys_addr_t start, unsigned long sz) { __dma_cache_wback_inv(start, sz); } EXPORT_SYMBOL(dma_cache_wback_inv); void dma_cache_inv(phys_addr_t start, unsigned long sz) { __dma_cache_inv(start, sz); } EXPORT_SYMBOL(dma_cache_inv); void dma_cache_wback(phys_addr_t start, unsigned long sz) { __dma_cache_wback(start, sz); } EXPORT_SYMBOL(dma_cache_wback); /* * This is API for making I/D Caches consistent when modifying * kernel code (loadable modules, kprobes, kgdb...) * This is called on insmod, with kernel virtual address for CODE of * the module. ARC cache maintenance ops require PHY address thus we * need to convert vmalloc addr to PHY addr */ void flush_icache_range(unsigned long kstart, unsigned long kend) { unsigned int tot_sz; WARN(kstart < TASK_SIZE, "%s() can't handle user vaddr", __func__); /* Shortcut for bigger flush ranges. * Here we don't care if this was kernel virtual or phy addr */ tot_sz = kend - kstart; if (tot_sz > PAGE_SIZE) { flush_cache_all(); return; } /* Case: Kernel Phy addr (0x8000_0000 onwards) */ if (likely(kstart > PAGE_OFFSET)) { /* * The 2nd arg despite being paddr will be used to index icache * This is OK since no alternate virtual mappings will exist * given the callers for this case: kprobe/kgdb in built-in * kernel code only. */ __sync_icache_dcache(kstart, kstart, kend - kstart); return; } /* * Case: Kernel Vaddr (0x7000_0000 to 0x7fff_ffff) * (1) ARC Cache Maintenance ops only take Phy addr, hence special * handling of kernel vaddr. * * (2) Despite @tot_sz being < PAGE_SIZE (bigger cases handled already), * it still needs to handle a 2 page scenario, where the range * straddles across 2 virtual pages and hence need for loop */ while (tot_sz > 0) { unsigned int off, sz; unsigned long phy, pfn; off = kstart % PAGE_SIZE; pfn = vmalloc_to_pfn((void *)kstart); phy = (pfn << PAGE_SHIFT) + off; sz = min_t(unsigned int, tot_sz, PAGE_SIZE - off); __sync_icache_dcache(phy, kstart, sz); kstart += sz; tot_sz -= sz; } } EXPORT_SYMBOL(flush_icache_range); /* * General purpose helper to make I and D cache lines consistent. * @paddr is phy addr of region * @vaddr is typically user vaddr (breakpoint) or kernel vaddr (vmalloc) * However in one instance, when called by kprobe (for a breakpt in * builtin kernel code) @vaddr will be paddr only, meaning CDU operation will * use a paddr to index the cache (despite VIPT). This is fine since since a * builtin kernel page will not have any virtual mappings. * kprobe on loadable module will be kernel vaddr. */ void __sync_icache_dcache(phys_addr_t paddr, unsigned long vaddr, int len) { __dc_line_op(paddr, vaddr, len, OP_FLUSH_N_INV); __ic_line_inv_vaddr(paddr, vaddr, len); } /* wrapper to compile time eliminate alignment checks in flush loop */ void __inv_icache_page(phys_addr_t paddr, unsigned long vaddr) { __ic_line_inv_vaddr(paddr, vaddr, PAGE_SIZE); } /* * wrapper to clearout kernel or userspace mappings of a page * For kernel mappings @vaddr == @paddr */ void __flush_dcache_page(phys_addr_t paddr, unsigned long vaddr) { __dc_line_op(paddr, vaddr & PAGE_MASK, PAGE_SIZE, OP_FLUSH_N_INV); } noinline void flush_cache_all(void) { unsigned long flags; local_irq_save(flags); __ic_entire_inv(); __dc_entire_op(OP_FLUSH_N_INV); local_irq_restore(flags); } #ifdef CONFIG_ARC_CACHE_VIPT_ALIASING void flush_cache_mm(struct mm_struct *mm) { flush_cache_all(); } void flush_cache_page(struct vm_area_struct *vma, unsigned long u_vaddr, unsigned long pfn) { phys_addr_t paddr = pfn << PAGE_SHIFT; u_vaddr &= PAGE_MASK; __flush_dcache_page(paddr, u_vaddr); if (vma->vm_flags & VM_EXEC) __inv_icache_page(paddr, u_vaddr); } void flush_cache_range(struct vm_area_struct *vma, unsigned long start, unsigned long end) { flush_cache_all(); } void flush_anon_page(struct vm_area_struct *vma, struct page *page, unsigned long u_vaddr) { /* TBD: do we really need to clear the kernel mapping */ __flush_dcache_page((phys_addr_t)page_address(page), u_vaddr); __flush_dcache_page((phys_addr_t)page_address(page), (phys_addr_t)page_address(page)); } #endif void copy_user_highpage(struct page *to, struct page *from, unsigned long u_vaddr, struct vm_area_struct *vma) { void *kfrom = kmap_atomic(from); void *kto = kmap_atomic(to); int clean_src_k_mappings = 0; /* * If SRC page was already mapped in userspace AND it's U-mapping is * not congruent with K-mapping, sync former to physical page so that * K-mapping in memcpy below, sees the right data * * Note that while @u_vaddr refers to DST page's userspace vaddr, it is * equally valid for SRC page as well * * For !VIPT cache, all of this gets compiled out as * addr_not_cache_congruent() is 0 */ if (page_mapcount(from) && addr_not_cache_congruent(kfrom, u_vaddr)) { __flush_dcache_page((unsigned long)kfrom, u_vaddr); clean_src_k_mappings = 1; } copy_page(kto, kfrom); /* * Mark DST page K-mapping as dirty for a later finalization by * update_mmu_cache(). Although the finalization could have been done * here as well (given that both vaddr/paddr are available). * But update_mmu_cache() already has code to do that for other * non copied user pages (e.g. read faults which wire in pagecache page * directly). */ clear_bit(PG_dc_clean, &to->flags); /* * if SRC was already usermapped and non-congruent to kernel mapping * sync the kernel mapping back to physical page */ if (clean_src_k_mappings) { __flush_dcache_page((unsigned long)kfrom, (unsigned long)kfrom); set_bit(PG_dc_clean, &from->flags); } else { clear_bit(PG_dc_clean, &from->flags); } kunmap_atomic(kto); kunmap_atomic(kfrom); } void clear_user_page(void *to, unsigned long u_vaddr, struct page *page) { clear_page(to); clear_bit(PG_dc_clean, &page->flags); } EXPORT_SYMBOL(clear_user_page); /********************************************************************** * Explicit Cache flush request from user space via syscall * Needed for JITs which generate code on the fly */ SYSCALL_DEFINE3(cacheflush, uint32_t, start, uint32_t, sz, uint32_t, flags) { /* TBD: optimize this */ flush_cache_all(); return 0; } void arc_cache_init(void) { unsigned int __maybe_unused cpu = smp_processor_id(); char str[256]; printk(arc_cache_mumbojumbo(0, str, sizeof(str))); /* * Only master CPU needs to execute rest of function: * - Assume SMP so all cores will have same cache config so * any geomtry checks will be same for all * - IOC setup / dma callbacks only need to be setup once */ if (cpu) return; if (IS_ENABLED(CONFIG_ARC_HAS_ICACHE)) { struct cpuinfo_arc_cache *ic = &cpuinfo_arc700[cpu].icache; if (!ic->ver) panic("cache support enabled but non-existent cache\n"); if (ic->line_len != L1_CACHE_BYTES) panic("ICache line [%d] != kernel Config [%d]", ic->line_len, L1_CACHE_BYTES); if (ic->ver != CONFIG_ARC_MMU_VER) panic("Cache ver [%d] doesn't match MMU ver [%d]\n", ic->ver, CONFIG_ARC_MMU_VER); /* * In MMU v4 (HS38x) the aliasing icache config uses IVIL/PTAG * pair to provide vaddr/paddr respectively, just as in MMU v3 */ if (is_isa_arcv2() && ic->alias) _cache_line_loop_ic_fn = __cache_line_loop_v3; else _cache_line_loop_ic_fn = __cache_line_loop; } if (IS_ENABLED(CONFIG_ARC_HAS_DCACHE)) { struct cpuinfo_arc_cache *dc = &cpuinfo_arc700[cpu].dcache; if (!dc->ver) panic("cache support enabled but non-existent cache\n"); if (dc->line_len != L1_CACHE_BYTES) panic("DCache line [%d] != kernel Config [%d]", dc->line_len, L1_CACHE_BYTES); /* check for D-Cache aliasing on ARCompact: ARCv2 has PIPT */ if (is_isa_arcompact()) { int handled = IS_ENABLED(CONFIG_ARC_CACHE_VIPT_ALIASING); int num_colors = dc->sz_k/dc->assoc/TO_KB(PAGE_SIZE); if (dc->alias) { if (!handled) panic("Enable CONFIG_ARC_CACHE_VIPT_ALIASING\n"); if (CACHE_COLORS_NUM != num_colors) panic("CACHE_COLORS_NUM not optimized for config\n"); } else if (!dc->alias && handled) { panic("Disable CONFIG_ARC_CACHE_VIPT_ALIASING\n"); } } } if (is_isa_arcv2() && l2_line_sz && !slc_enable) { /* IM set : flush before invalidate */ write_aux_reg(ARC_REG_SLC_CTRL, read_aux_reg(ARC_REG_SLC_CTRL) | SLC_CTRL_IM); write_aux_reg(ARC_REG_SLC_INVALIDATE, 1); /* Important to wait for flush to complete */ while (read_aux_reg(ARC_REG_SLC_CTRL) & SLC_CTRL_BUSY); write_aux_reg(ARC_REG_SLC_CTRL, read_aux_reg(ARC_REG_SLC_CTRL) | SLC_CTRL_DISABLE); } if (is_isa_arcv2() && ioc_enable) { /* IO coherency base - 0x8z */ write_aux_reg(ARC_REG_IO_COH_AP0_BASE, 0x80000); /* IO coherency aperture size - 512Mb: 0x8z-0xAz */ write_aux_reg(ARC_REG_IO_COH_AP0_SIZE, 0x11); /* Enable partial writes */ write_aux_reg(ARC_REG_IO_COH_PARTIAL, 1); /* Enable IO coherency */ write_aux_reg(ARC_REG_IO_COH_ENABLE, 1); __dma_cache_wback_inv = __dma_cache_wback_inv_ioc; __dma_cache_inv = __dma_cache_inv_ioc; __dma_cache_wback = __dma_cache_wback_ioc; } else if (is_isa_arcv2() && l2_line_sz && slc_enable) { __dma_cache_wback_inv = __dma_cache_wback_inv_slc; __dma_cache_inv = __dma_cache_inv_slc; __dma_cache_wback = __dma_cache_wback_slc; } else { __dma_cache_wback_inv = __dma_cache_wback_inv_l1; __dma_cache_inv = __dma_cache_inv_l1; __dma_cache_wback = __dma_cache_wback_l1; } }