/* * spiffs_cache.c * * Created on: Jun 23, 2013 * Author: petera */ #include "spiffs.h" #include "spiffs_nucleus.h" #if SPIFFS_CACHE // returns cached page for give page index, or null if no such cached page static spiffs_cache_page *spiffs_cache_page_get(spiffs *fs, spiffs_page_ix pix) { spiffs_cache *cache = spiffs_get_cache(fs); if ((cache->cpage_use_map & cache->cpage_use_mask) == 0) return 0; int i; for (i = 0; i < cache->cpage_count; i++) { spiffs_cache_page *cp = spiffs_get_cache_page_hdr(fs, cache, i); if ((cache->cpage_use_map & (1 << i)) && (cp->flags & SPIFFS_CACHE_FLAG_TYPE_WR) == 0 && cp->ucache.spix.pix == pix) { //SPIFFS_CACHE_DBG("CACHE_GET: have cache page "_SPIPRIi" for "_SPIPRIpg"\n", i, pix); cp->last_access = cache->last_access; return cp; } } //SPIFFS_CACHE_DBG("CACHE_GET: no cache for "_SPIPRIpg"\n", pix); return 0; } // frees cached page static s32_t spiffs_cache_page_free(spiffs *fs, int ix, u8_t write_back) { s32_t res = SPIFFS_OK; spiffs_cache *cache = spiffs_get_cache(fs); spiffs_cache_page *cp = spiffs_get_cache_page_hdr(fs, cache, ix); if (cache->cpage_use_map & (1 << ix)) { if (write_back && (cp->flags & SPIFFS_CACHE_FLAG_TYPE_WR) == 0 && (cp->flags & SPIFFS_CACHE_FLAG_DIRTY)) { u8_t *mem = spiffs_get_cache_page(fs, cache, ix); SPIFFS_CACHE_DBG("CACHE_FREE: write cache page "_SPIPRIi" pix "_SPIPRIpg"\n", ix, cp->pix); res = SPIFFS_HAL_WRITE(fs, SPIFFS_PAGE_TO_PADDR(fs, cp->ucache.spix.pix), SPIFFS_CFG_LOG_PAGE_SZ(fs), mem); } #if SPIFFS_CACHE_WR if (cp->flags & SPIFFS_CACHE_FLAG_TYPE_WR) { SPIFFS_CACHE_DBG("CACHE_FREE: free cache page "_SPIPRIi" objid "_SPIPRIid"\n", ix, cp->obj_id); } else #endif { SPIFFS_CACHE_DBG("CACHE_FREE: free cache page "_SPIPRIi" pix "_SPIPRIpg"\n", ix, cp->pix); } cache->cpage_use_map &= ~(1 << ix); cp->flags = 0; } return res; } // removes the oldest accessed cached page static s32_t spiffs_cache_page_remove_oldest(spiffs *fs, u8_t flag_mask, u8_t flags) { s32_t res = SPIFFS_OK; spiffs_cache *cache = spiffs_get_cache(fs); if ((cache->cpage_use_map & cache->cpage_use_mask) != cache->cpage_use_mask) { // at least one free cpage return SPIFFS_OK; } // all busy, scan thru all to find the cpage which has oldest access int i; int cand_ix = -1; u32_t oldest_val = 0; for (i = 0; i < cache->cpage_count; i++) { spiffs_cache_page *cp = spiffs_get_cache_page_hdr(fs, cache, i); if ((cache->last_access - cp->last_access) > oldest_val && (cp->flags & flag_mask) == flags) { oldest_val = cache->last_access - cp->last_access; cand_ix = i; } } if (cand_ix >= 0) { res = spiffs_cache_page_free(fs, cand_ix, 1); } return res; } // allocates a new cached page and returns it, or null if all cache pages are busy static spiffs_cache_page *spiffs_cache_page_allocate(spiffs *fs) { spiffs_cache *cache = spiffs_get_cache(fs); if (cache->cpage_use_map == 0xffffffff) { // out of cache memory return 0; } int i; for (i = 0; i < cache->cpage_count; i++) { if ((cache->cpage_use_map & (1 << i)) == 0) { spiffs_cache_page *cp = spiffs_get_cache_page_hdr(fs, cache, i); cache->cpage_use_map |= (1 << i); cp->last_access = cache->last_access; //SPIFFS_CACHE_DBG("CACHE_ALLO: allocated cache page "_SPIPRIi"\n", i); return cp; } } // out of cache entries return 0; } // drops the cache page for give page index void spiffs_cache_drop_page(spiffs *fs, spiffs_page_ix pix) { spiffs_cache_page *cp = spiffs_cache_page_get(fs, pix); if (cp) { spiffs_cache_page_free(fs, cp->ix, 0); } } // ------------------------------ // reads from spi flash or the cache s32_t spiffs_phys_rd( spiffs *fs, u8_t op, spiffs_file fh, u32_t addr, u32_t len, u8_t *dst) { (void)fh; s32_t res = SPIFFS_OK; spiffs_cache *cache = spiffs_get_cache(fs); spiffs_cache_page *cp = spiffs_cache_page_get(fs, SPIFFS_PADDR_TO_PAGE(fs, addr)); cache->last_access++; if (cp) { // we've already got one, you see #if SPIFFS_CACHE_STATS fs->cache_hits++; #endif cp->last_access = cache->last_access; u8_t *mem = spiffs_get_cache_page(fs, cache, cp->ix); _SPIFFS_MEMCPY(dst, &mem[SPIFFS_PADDR_TO_PAGE_OFFSET(fs, addr)], len); } else { if ((op & SPIFFS_OP_TYPE_MASK) == SPIFFS_OP_T_OBJ_LU2) { // for second layer lookup functions, we do not cache in order to prevent shredding return SPIFFS_HAL_READ(fs, addr, len, dst); } #if SPIFFS_CACHE_STATS fs->cache_misses++; #endif // this operation will always free one cache page (unless all already free), // the result code stems from the write operation of the possibly freed cache page res = spiffs_cache_page_remove_oldest(fs, SPIFFS_CACHE_FLAG_TYPE_WR, 0); cp = spiffs_cache_page_allocate(fs); if (cp) { cp->flags = SPIFFS_CACHE_FLAG_WRTHRU; cp->ucache.spix.pix = SPIFFS_PADDR_TO_PAGE(fs, addr); SPIFFS_CACHE_DBG("CACHE_ALLO: allocated cache page "_SPIPRIi" for pix "_SPIPRIpg "\n", cp->ix, cp->pix); s32_t res2 = SPIFFS_HAL_READ(fs, addr - SPIFFS_PADDR_TO_PAGE_OFFSET(fs, addr), SPIFFS_CFG_LOG_PAGE_SZ(fs), spiffs_get_cache_page(fs, cache, cp->ix)); if (res2 != SPIFFS_OK) { // honor read failure before possible write failure (bad idea?) res = res2; } u8_t *mem = spiffs_get_cache_page(fs, cache, cp->ix); _SPIFFS_MEMCPY(dst, &mem[SPIFFS_PADDR_TO_PAGE_OFFSET(fs, addr)], len); } else { // this will never happen, last resort for sake of symmetry s32_t res2 = SPIFFS_HAL_READ(fs, addr, len, dst); if (res2 != SPIFFS_OK) { // honor read failure before possible write failure (bad idea?) res = res2; } } } return res; } // writes to spi flash and/or the cache s32_t spiffs_phys_wr( spiffs *fs, u8_t op, spiffs_file fh, u32_t addr, u32_t len, u8_t *src) { (void)fh; spiffs_page_ix pix = SPIFFS_PADDR_TO_PAGE(fs, addr); spiffs_cache *cache = spiffs_get_cache(fs); spiffs_cache_page *cp = spiffs_cache_page_get(fs, pix); if (cp && (op & SPIFFS_OP_COM_MASK) != SPIFFS_OP_C_WRTHRU) { // have a cache page // copy in data to cache page if ((op & SPIFFS_OP_COM_MASK) == SPIFFS_OP_C_DELE && (op & SPIFFS_OP_TYPE_MASK) != SPIFFS_OP_T_OBJ_LU) { // page is being deleted, wipe from cache - unless it is a lookup page spiffs_cache_page_free(fs, cp->ix, 0); return SPIFFS_HAL_WRITE(fs, addr, len, src); } u8_t *mem = spiffs_get_cache_page(fs, cache, cp->ix); _SPIFFS_MEMCPY(&mem[SPIFFS_PADDR_TO_PAGE_OFFSET(fs, addr)], src, len); cache->last_access++; cp->last_access = cache->last_access; if (cp->flags & SPIFFS_CACHE_FLAG_WRTHRU) { // page is being updated, no write-cache, just pass thru return SPIFFS_HAL_WRITE(fs, addr, len, src); } else { return SPIFFS_OK; } } else { // no cache page, no write cache - just write thru return SPIFFS_HAL_WRITE(fs, addr, len, src); } } #if SPIFFS_CACHE_WR // returns the cache page that this fd refers, or null if no cache page spiffs_cache_page *spiffs_cache_page_get_by_fd(spiffs *fs, spiffs_fd *fd) { spiffs_cache *cache = spiffs_get_cache(fs); if ((cache->cpage_use_map & cache->cpage_use_mask) == 0) { // all cpages free, no cpage cannot be assigned to obj_id return 0; } int i; for (i = 0; i < cache->cpage_count; i++) { spiffs_cache_page *cp = spiffs_get_cache_page_hdr(fs, cache, i); if ((cache->cpage_use_map & (1 << i)) && (cp->flags & SPIFFS_CACHE_FLAG_TYPE_WR) && cp->ucache.swrc.obj_id == fd->obj_id) { return cp; } } return 0; } // allocates a new cache page and refers this to given fd - flushes an old cache // page if all cache is busy spiffs_cache_page *spiffs_cache_page_allocate_by_fd(spiffs *fs, spiffs_fd *fd) { // before this function is called, it is ensured that there is no already existing // cache page with same object id spiffs_cache_page_remove_oldest(fs, SPIFFS_CACHE_FLAG_TYPE_WR, 0); spiffs_cache_page *cp = spiffs_cache_page_allocate(fs); if (cp == 0) { // could not get cache page return 0; } cp->flags = SPIFFS_CACHE_FLAG_TYPE_WR; cp->ucache.swrc.obj_id = fd->obj_id; fd->cache_page = cp; SPIFFS_CACHE_DBG("CACHE_ALLO: allocated cache page "_SPIPRIi" for fd "_SPIPRIfd ":"_SPIPRIid "\n", cp->ix, fd->file_nbr, fd->obj_id); return cp; } // unrefers all fds that this cache page refers to and releases the cache page void spiffs_cache_fd_release(spiffs *fs, spiffs_cache_page *cp) { if (cp == 0) return; u32_t i; spiffs_fd *fds = (spiffs_fd *)fs->fd_space; for (i = 0; i < fs->fd_count; i++) { spiffs_fd *cur_fd = &fds[i]; if (cur_fd->file_nbr != 0 && cur_fd->cache_page == cp) { cur_fd->cache_page = 0; } } spiffs_cache_page_free(fs, cp->ix, 0); cp->ucache.swrc.obj_id = 0; } #endif // initializes the cache void spiffs_cache_init(spiffs *fs) { if (fs->cache == 0) return; u32_t sz = fs->cache_size; u32_t cache_mask = 0; int i; int cache_entries = (sz - sizeof(spiffs_cache)) / (SPIFFS_CACHE_PAGE_SIZE(fs)); if (cache_entries <= 0) return; for (i = 0; i < cache_entries; i++) { cache_mask <<= 1; cache_mask |= 1; } spiffs_cache cache; memset(&cache, 0, sizeof(spiffs_cache)); cache.cpage_count = cache_entries; cache.cpages = (u8_t *)((u8_t *)fs->cache + sizeof(spiffs_cache)); cache.cpage_use_map = 0xffffffff; cache.cpage_use_mask = cache_mask; _SPIFFS_MEMCPY(fs->cache, &cache, sizeof(spiffs_cache)); spiffs_cache *c = spiffs_get_cache(fs); memset(c->cpages, 0, c->cpage_count * SPIFFS_CACHE_PAGE_SIZE(fs)); c->cpage_use_map &= ~(c->cpage_use_mask); for (i = 0; i < cache.cpage_count; i++) { spiffs_get_cache_page_hdr(fs, c, i)->ix = i; } } #endif // SPIFFS_CACHE