// SPDX-License-Identifier: GPL-2.0-only /* * Copyright (C) 2019 HUAWEI, Inc. * https://www.huawei.com/ * Copyright (C) 2024 Alibaba Cloud */ #include "compress.h" #include #define LZ4_MAX_DISTANCE_PAGES (DIV_ROUND_UP(LZ4_DISTANCE_MAX, PAGE_SIZE) + 1) static int z_erofs_load_lz4_config(struct super_block *sb, struct erofs_super_block *dsb, void *data, int size) { struct erofs_sb_info *sbi = EROFS_SB(sb); struct z_erofs_lz4_cfgs *lz4 = data; u16 distance; if (lz4) { if (size < sizeof(struct z_erofs_lz4_cfgs)) { erofs_err(sb, "invalid lz4 cfgs, size=%u", size); return -EINVAL; } distance = le16_to_cpu(lz4->max_distance); sbi->lz4.max_pclusterblks = le16_to_cpu(lz4->max_pclusterblks); if (!sbi->lz4.max_pclusterblks) { sbi->lz4.max_pclusterblks = 1; /* reserved case */ } else if (sbi->lz4.max_pclusterblks > erofs_blknr(sb, Z_EROFS_PCLUSTER_MAX_SIZE)) { erofs_err(sb, "too large lz4 pclusterblks %u", sbi->lz4.max_pclusterblks); return -EINVAL; } } else { distance = le16_to_cpu(dsb->u1.lz4_max_distance); sbi->lz4.max_pclusterblks = 1; } sbi->lz4.max_distance_pages = distance ? DIV_ROUND_UP(distance, PAGE_SIZE) + 1 : LZ4_MAX_DISTANCE_PAGES; return z_erofs_gbuf_growsize(sbi->lz4.max_pclusterblks); } /* * Fill all gaps with bounce pages if it's a sparse page list. Also check if * all physical pages are consecutive, which can be seen for moderate CR. */ static int z_erofs_lz4_prepare_dstpages(struct z_erofs_decompress_req *rq, struct page **pagepool) { struct page *availables[LZ4_MAX_DISTANCE_PAGES] = { NULL }; unsigned long bounced[DIV_ROUND_UP(LZ4_MAX_DISTANCE_PAGES, BITS_PER_LONG)] = { 0 }; unsigned int lz4_max_distance_pages = EROFS_SB(rq->sb)->lz4.max_distance_pages; void *kaddr = NULL; unsigned int i, j, top; top = 0; for (i = j = 0; i < rq->outpages; ++i, ++j) { struct page *const page = rq->out[i]; struct page *victim; if (j >= lz4_max_distance_pages) j = 0; /* 'valid' bounced can only be tested after a complete round */ if (!rq->fillgaps && test_bit(j, bounced)) { DBG_BUGON(i < lz4_max_distance_pages); DBG_BUGON(top >= lz4_max_distance_pages); availables[top++] = rq->out[i - lz4_max_distance_pages]; } if (page) { __clear_bit(j, bounced); if (!PageHighMem(page)) { if (!i) { kaddr = page_address(page); continue; } if (kaddr && kaddr + PAGE_SIZE == page_address(page)) { kaddr += PAGE_SIZE; continue; } } kaddr = NULL; continue; } kaddr = NULL; __set_bit(j, bounced); if (top) { victim = availables[--top]; } else { victim = __erofs_allocpage(pagepool, rq->gfp, true); if (!victim) return -ENOMEM; set_page_private(victim, Z_EROFS_SHORTLIVED_PAGE); } rq->out[i] = victim; } return kaddr ? 1 : 0; } static void *z_erofs_lz4_handle_overlap(const struct z_erofs_decompress_req *rq, void *inpage, void *out, unsigned int *inputmargin, int *maptype, bool may_inplace) { unsigned int oend, omargin, cnt, i; struct page **in; void *src; /* * If in-place I/O isn't used, for example, the bounce compressed cache * can hold data for incomplete read requests. Just map the compressed * buffer as well and decompress directly. */ if (!rq->inplace_io) { if (rq->inpages <= 1) { *maptype = 0; return inpage; } kunmap_local(inpage); src = erofs_vm_map_ram(rq->in, rq->inpages); if (!src) return ERR_PTR(-ENOMEM); *maptype = 1; return src; } /* * Then, deal with in-place I/Os. The reasons why in-place I/O is useful * are: (1) It minimizes memory footprint during the I/O submission, * which is useful for slow storage (including network devices and * low-end HDDs/eMMCs) but with a lot inflight I/Os; (2) If in-place * decompression can also be applied, it will reuse the unique buffer so * that no extra CPU D-cache is polluted with temporary compressed data * for extreme performance. */ oend = rq->pageofs_out + rq->outputsize; omargin = PAGE_ALIGN(oend) - oend; if (!rq->partial_decoding && may_inplace && omargin >= LZ4_DECOMPRESS_INPLACE_MARGIN(rq->inputsize)) { for (i = 0; i < rq->inpages; ++i) if (rq->out[rq->outpages - rq->inpages + i] != rq->in[i]) break; if (i >= rq->inpages) { kunmap_local(inpage); *maptype = 3; return out + ((rq->outpages - rq->inpages) << PAGE_SHIFT); } } /* * If in-place decompression can't be applied, copy compressed data that * may potentially overlap during decompression to a per-CPU buffer. */ src = z_erofs_get_gbuf(rq->inpages); if (!src) { DBG_BUGON(1); kunmap_local(inpage); return ERR_PTR(-EFAULT); } for (i = 0, in = rq->in; i < rq->inputsize; i += cnt, ++in) { cnt = min_t(u32, rq->inputsize - i, PAGE_SIZE - *inputmargin); if (!inpage) inpage = kmap_local_page(*in); memcpy(src + i, inpage + *inputmargin, cnt); kunmap_local(inpage); inpage = NULL; *inputmargin = 0; } *maptype = 2; return src; } /* * Get the exact on-disk size of the compressed data: * - For LZ4, it should apply if the zero_padding feature is on (5.3+); * - For others, zero_padding is enabled all the time. */ const char *z_erofs_fixup_insize(struct z_erofs_decompress_req *rq, const char *padbuf, unsigned int padbufsize) { const char *padend; padend = memchr_inv(padbuf, 0, padbufsize); if (!padend) return "compressed data start not found"; rq->inputsize -= padend - padbuf; rq->pageofs_in += padend - padbuf; return NULL; } static int z_erofs_lz4_decompress_mem(struct z_erofs_decompress_req *rq, u8 *dst) { bool support_0padding = false, may_inplace = false; unsigned int inputmargin; u8 *out, *headpage, *src; const char *reason; int ret, maptype; DBG_BUGON(*rq->in == NULL); headpage = kmap_local_page(*rq->in); /* LZ4 decompression inplace is only safe if zero_padding is enabled */ if (erofs_sb_has_zero_padding(EROFS_SB(rq->sb))) { support_0padding = true; reason = z_erofs_fixup_insize(rq, headpage + rq->pageofs_in, min_t(unsigned int, rq->inputsize, rq->sb->s_blocksize - rq->pageofs_in)); if (reason) { kunmap_local(headpage); return IS_ERR(reason) ? PTR_ERR(reason) : -EFSCORRUPTED; } may_inplace = !((rq->pageofs_in + rq->inputsize) & (rq->sb->s_blocksize - 1)); } inputmargin = rq->pageofs_in; src = z_erofs_lz4_handle_overlap(rq, headpage, dst, &inputmargin, &maptype, may_inplace); if (IS_ERR(src)) return PTR_ERR(src); out = dst + rq->pageofs_out; /* legacy format could compress extra data in a pcluster. */ if (rq->partial_decoding || !support_0padding) ret = LZ4_decompress_safe_partial(src + inputmargin, out, rq->inputsize, rq->outputsize, rq->outputsize); else ret = LZ4_decompress_safe(src + inputmargin, out, rq->inputsize, rq->outputsize); if (ret != rq->outputsize) { if (ret >= 0) memset(out + ret, 0, rq->outputsize - ret); ret = -EFSCORRUPTED; } else { ret = 0; } if (maptype == 0) { kunmap_local(headpage); } else if (maptype == 1) { vm_unmap_ram(src, rq->inpages); } else if (maptype == 2) { z_erofs_put_gbuf(src); } else if (maptype != 3) { DBG_BUGON(1); return -EFAULT; } return ret; } static const char *z_erofs_lz4_decompress(struct z_erofs_decompress_req *rq, struct page **pagepool) { unsigned int dst_maptype; void *dst; int ret; /* one optimized fast path only for non bigpcluster cases yet */ if (rq->inpages == 1 && rq->outpages == 1 && !rq->inplace_io) { DBG_BUGON(!*rq->out); dst = kmap_local_page(*rq->out); dst_maptype = 0; } else { /* general decoding path which can be used for all cases */ ret = z_erofs_lz4_prepare_dstpages(rq, pagepool); if (ret < 0) return ERR_PTR(ret); if (ret > 0) { dst = page_address(*rq->out); dst_maptype = 1; } else { dst = erofs_vm_map_ram(rq->out, rq->outpages); if (!dst) return ERR_PTR(-ENOMEM); dst_maptype = 2; } } ret = z_erofs_lz4_decompress_mem(rq, dst); if (!dst_maptype) kunmap_local(dst); else if (dst_maptype == 2) vm_unmap_ram(dst, rq->outpages); return ERR_PTR(ret); } static const char *z_erofs_transform_plain(struct z_erofs_decompress_req *rq, struct page **pagepool) { const unsigned int nrpages_in = rq->inpages, nrpages_out = rq->outpages; const unsigned int bs = rq->sb->s_blocksize; unsigned int cur = 0, ni = 0, no, pi, po, insz, cnt; u8 *kin; if (rq->outputsize > rq->inputsize) return ERR_PTR(-EOPNOTSUPP); if (rq->alg == Z_EROFS_COMPRESSION_INTERLACED) { cur = bs - (rq->pageofs_out & (bs - 1)); pi = (rq->pageofs_in + rq->inputsize - cur) & ~PAGE_MASK; cur = min(cur, rq->outputsize); if (cur && rq->out[0]) { kin = kmap_local_page(rq->in[nrpages_in - 1]); if (rq->out[0] == rq->in[nrpages_in - 1]) memmove(kin + rq->pageofs_out, kin + pi, cur); else memcpy_to_page(rq->out[0], rq->pageofs_out, kin + pi, cur); kunmap_local(kin); } rq->outputsize -= cur; } for (; rq->outputsize; rq->pageofs_in = 0, cur += insz, ni++) { insz = min(PAGE_SIZE - rq->pageofs_in, rq->outputsize); rq->outputsize -= insz; if (!rq->in[ni]) continue; kin = kmap_local_page(rq->in[ni]); pi = 0; do { no = (rq->pageofs_out + cur + pi) >> PAGE_SHIFT; po = (rq->pageofs_out + cur + pi) & ~PAGE_MASK; DBG_BUGON(no >= nrpages_out); cnt = min(insz - pi, PAGE_SIZE - po); if (rq->out[no] == rq->in[ni]) memmove(kin + po, kin + rq->pageofs_in + pi, cnt); else if (rq->out[no]) memcpy_to_page(rq->out[no], po, kin + rq->pageofs_in + pi, cnt); pi += cnt; } while (pi < insz); kunmap_local(kin); } DBG_BUGON(ni > nrpages_in); return NULL; } const char *z_erofs_stream_switch_bufs(struct z_erofs_stream_dctx *dctx, void **dst, void **src, struct page **pgpl) { struct z_erofs_decompress_req *rq = dctx->rq; struct page **pgo, *tmppage; unsigned int j; if (!dctx->avail_out) { if (++dctx->no >= rq->outpages || !rq->outputsize) return "insufficient space for decompressed data"; if (dctx->kout) kunmap_local(dctx->kout); dctx->avail_out = min(rq->outputsize, PAGE_SIZE - rq->pageofs_out); rq->outputsize -= dctx->avail_out; pgo = &rq->out[dctx->no]; if (!*pgo && rq->fillgaps) { /* deduped */ *pgo = erofs_allocpage(pgpl, rq->gfp); if (!*pgo) { dctx->kout = NULL; return ERR_PTR(-ENOMEM); } set_page_private(*pgo, Z_EROFS_SHORTLIVED_PAGE); } if (*pgo) { dctx->kout = kmap_local_page(*pgo); *dst = dctx->kout + rq->pageofs_out; } else { *dst = dctx->kout = NULL; } rq->pageofs_out = 0; } if (dctx->inbuf_pos == dctx->inbuf_sz && rq->inputsize) { if (++dctx->ni >= rq->inpages) return "invalid compressed data"; if (dctx->kout) /* unlike kmap(), take care of the orders */ kunmap_local(dctx->kout); kunmap_local(dctx->kin); dctx->inbuf_sz = min_t(u32, rq->inputsize, PAGE_SIZE); rq->inputsize -= dctx->inbuf_sz; dctx->kin = kmap_local_page(rq->in[dctx->ni]); *src = dctx->kin; dctx->bounced = false; if (dctx->kout) { j = (u8 *)*dst - dctx->kout; dctx->kout = kmap_local_page(rq->out[dctx->no]); *dst = dctx->kout + j; } dctx->inbuf_pos = 0; } /* * Handle overlapping: Use the given bounce buffer if the input data is * under processing; Or utilize short-lived pages from the on-stack page * pool, where pages are shared among the same request. Note that only * a few inplace I/O pages need to be doubled. */ if (!dctx->bounced && rq->out[dctx->no] == rq->in[dctx->ni]) { memcpy(dctx->bounce, *src, dctx->inbuf_sz); *src = dctx->bounce; dctx->bounced = true; } for (j = dctx->ni + 1; j < rq->inpages; ++j) { if (rq->out[dctx->no] != rq->in[j]) continue; tmppage = erofs_allocpage(pgpl, rq->gfp); if (!tmppage) return ERR_PTR(-ENOMEM); set_page_private(tmppage, Z_EROFS_SHORTLIVED_PAGE); copy_highpage(tmppage, rq->in[j]); rq->in[j] = tmppage; } return NULL; } const struct z_erofs_decompressor *z_erofs_decomp[] = { [Z_EROFS_COMPRESSION_SHIFTED] = &(const struct z_erofs_decompressor) { .decompress = z_erofs_transform_plain, .name = "shifted" }, [Z_EROFS_COMPRESSION_INTERLACED] = &(const struct z_erofs_decompressor) { .decompress = z_erofs_transform_plain, .name = "interlaced" }, [Z_EROFS_COMPRESSION_LZ4] = &(const struct z_erofs_decompressor) { .config = z_erofs_load_lz4_config, .decompress = z_erofs_lz4_decompress, .init = z_erofs_gbuf_init, .exit = z_erofs_gbuf_exit, .name = "lz4" }, #ifdef CONFIG_EROFS_FS_ZIP_LZMA [Z_EROFS_COMPRESSION_LZMA] = &z_erofs_lzma_decomp, #endif #ifdef CONFIG_EROFS_FS_ZIP_DEFLATE [Z_EROFS_COMPRESSION_DEFLATE] = &z_erofs_deflate_decomp, #endif #ifdef CONFIG_EROFS_FS_ZIP_ZSTD [Z_EROFS_COMPRESSION_ZSTD] = &z_erofs_zstd_decomp, #endif }; int z_erofs_parse_cfgs(struct super_block *sb, struct erofs_super_block *dsb) { struct erofs_sb_info *sbi = EROFS_SB(sb); struct erofs_buf buf = __EROFS_BUF_INITIALIZER; unsigned int algs, alg; erofs_off_t offset; int size, ret = 0; if (!erofs_sb_has_compr_cfgs(sbi)) { sbi->available_compr_algs = 1 << Z_EROFS_COMPRESSION_LZ4; return z_erofs_load_lz4_config(sb, dsb, NULL, 0); } sbi->available_compr_algs = le16_to_cpu(dsb->u1.available_compr_algs); if (sbi->available_compr_algs & ~Z_EROFS_ALL_COMPR_ALGS) { erofs_err(sb, "unidentified algorithms %x, please upgrade kernel", sbi->available_compr_algs & ~Z_EROFS_ALL_COMPR_ALGS); return -EOPNOTSUPP; } (void)erofs_init_metabuf(&buf, sb, false); offset = EROFS_SUPER_OFFSET + sbi->sb_size; alg = 0; for (algs = sbi->available_compr_algs; algs; algs >>= 1, ++alg) { const struct z_erofs_decompressor *dec = z_erofs_decomp[alg]; void *data; if (!(algs & 1)) continue; data = erofs_read_metadata(sb, &buf, &offset, &size); if (IS_ERR(data)) { ret = PTR_ERR(data); break; } if (alg < Z_EROFS_COMPRESSION_MAX && dec && dec->config) { ret = dec->config(sb, dsb, data, size); } else { erofs_err(sb, "algorithm %d isn't enabled on this kernel", alg); ret = -EOPNOTSUPP; } kfree(data); if (ret) break; } erofs_put_metabuf(&buf); return ret; } int __init z_erofs_init_decompressor(void) { int i, err; for (i = 0; i < Z_EROFS_COMPRESSION_MAX; ++i) { err = z_erofs_decomp[i] ? z_erofs_decomp[i]->init() : 0; if (err) { while (i--) if (z_erofs_decomp[i]) z_erofs_decomp[i]->exit(); return err; } } return 0; } void z_erofs_exit_decompressor(void) { int i; for (i = 0; i < Z_EROFS_COMPRESSION_MAX; ++i) if (z_erofs_decomp[i]) z_erofs_decomp[i]->exit(); }