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364 lines
12 KiB
Markdown
364 lines
12 KiB
Markdown
# 4.14 glibc tcache 机制
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- [tcache](#tcache)
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- [安全性分析](#安全性分析)
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- [CTF 实例](#ctf-实例)
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- [参考资料](#参考资料)
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## tcache
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tcache 全名 thread local caching,它为每个线程创建一个缓存(cache),从而实现无锁的分配算法,有不错的性能提升。libc-2.26 正式提供了该机制,并默认开启,具体可以查看这次 [commit](https://sourceware.org/git/?p=glibc.git;a=commitdiff;h=d5c3fafc4307c9b7a4c7d5cb381fcdbfad340bcc)。
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#### 数据结构
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glibc 在编译时使用 `USE_TCACHE` 条件来开启 tcache 机制,并定义了下面一些东西:
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```c
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#if USE_TCACHE
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/* We want 64 entries. This is an arbitrary limit, which tunables can reduce. */
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# define TCACHE_MAX_BINS 64
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# define MAX_TCACHE_SIZE tidx2usize (TCACHE_MAX_BINS-1)
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/* Only used to pre-fill the tunables. */
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# define tidx2usize(idx) (((size_t) idx) * MALLOC_ALIGNMENT + MINSIZE - SIZE_SZ)
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/* When "x" is from chunksize(). */
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# define csize2tidx(x) (((x) - MINSIZE + MALLOC_ALIGNMENT - 1) / MALLOC_ALIGNMENT)
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/* When "x" is a user-provided size. */
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# define usize2tidx(x) csize2tidx (request2size (x))
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/* With rounding and alignment, the bins are...
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idx 0 bytes 0..24 (64-bit) or 0..12 (32-bit)
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idx 1 bytes 25..40 or 13..20
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idx 2 bytes 41..56 or 21..28
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etc. */
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/* This is another arbitrary limit, which tunables can change. Each
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tcache bin will hold at most this number of chunks. */
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# define TCACHE_FILL_COUNT 7
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#endif
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```
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值得注意的比如每个线程默认使用 64 个单链表结构的 bins,每个 bins 最多存放 7 个 chunk。chunk 的大小在 64 位机器上以 16 字节递增,从 24 到 1032 字节。32 位机器上则是以 8 字节递增,从 12 到 512 字节。所以 tcache bin 只用于存放 non-large 的 chunk。
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然后引入了两个新的数据结构,`tcache_entry` 和 `tcache_perthread_struct`:
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```c
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/* We overlay this structure on the user-data portion of a chunk when
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the chunk is stored in the per-thread cache. */
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typedef struct tcache_entry
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{
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struct tcache_entry *next;
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} tcache_entry;
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/* There is one of these for each thread, which contains the
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per-thread cache (hence "tcache_perthread_struct"). Keeping
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overall size low is mildly important. Note that COUNTS and ENTRIES
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are redundant (we could have just counted the linked list each
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time), this is for performance reasons. */
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typedef struct tcache_perthread_struct
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{
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char counts[TCACHE_MAX_BINS];
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tcache_entry *entries[TCACHE_MAX_BINS];
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} tcache_perthread_struct;
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static __thread tcache_perthread_struct *tcache = NULL;
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```
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tcache_perthread_struct 包含一个数组 entries,用于放置 64 个 bins,数组 counts 存放每个 bins 中的 chunk 数量。每个被放入相应 bins 中的 chunk 都会在其用户数据中包含一个 tcache_entry(FD指针),指向同 bins 中的下一个 chunk,构成单链表。
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tcache 初始化操作如下:
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```c
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static void
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tcache_init(void)
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{
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mstate ar_ptr;
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void *victim = 0;
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const size_t bytes = sizeof (tcache_perthread_struct);
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if (tcache_shutting_down)
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return;
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arena_get (ar_ptr, bytes);
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victim = _int_malloc (ar_ptr, bytes);
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if (!victim && ar_ptr != NULL)
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{
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ar_ptr = arena_get_retry (ar_ptr, bytes);
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victim = _int_malloc (ar_ptr, bytes);
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}
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if (ar_ptr != NULL)
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__libc_lock_unlock (ar_ptr->mutex);
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/* In a low memory situation, we may not be able to allocate memory
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- in which case, we just keep trying later. However, we
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typically do this very early, so either there is sufficient
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memory, or there isn't enough memory to do non-trivial
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allocations anyway. */
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if (victim)
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{
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tcache = (tcache_perthread_struct *) victim;
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memset (tcache, 0, sizeof (tcache_perthread_struct));
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}
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}
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```
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#### 使用
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触发在 tcache 中放入 chunk 的操作:
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- free 时:在 fastbin 的操作之前进行,如果 chunk size 符合要求,并且对应的 bins 还未装满,则将其放进去。
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```c
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#if USE_TCACHE
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{
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size_t tc_idx = csize2tidx (size);
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if (tcache
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&& tc_idx < mp_.tcache_bins
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&& tcache->counts[tc_idx] < mp_.tcache_count)
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{
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tcache_put (p, tc_idx);
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return;
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}
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}
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#endif
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```
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- malloc 时:有三个地方会触发。
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- 如果从 fastbin 中成功返回了一个需要的 chunk,那么对应 fastbin 中的其他 chunk 会被放进相应的 tcache bin 中,直到上限。需要注意的是 chunks 在 tcache bin 的顺序和在 fastbin 中的顺序是反过来的。
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```c
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#if USE_TCACHE
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/* While we're here, if we see other chunks of the same size,
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stash them in the tcache. */
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size_t tc_idx = csize2tidx (nb);
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if (tcache && tc_idx < mp_.tcache_bins)
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{
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mchunkptr tc_victim;
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/* While bin not empty and tcache not full, copy chunks. */
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while (tcache->counts[tc_idx] < mp_.tcache_count
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&& (tc_victim = *fb) != NULL)
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{
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if (SINGLE_THREAD_P)
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*fb = tc_victim->fd;
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else
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{
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REMOVE_FB (fb, pp, tc_victim);
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if (__glibc_unlikely (tc_victim == NULL))
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break;
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}
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tcache_put (tc_victim, tc_idx);
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}
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}
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#endif
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```
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- smallbin 中的情况与 fastbin 相似,双链表中的剩余 chunk 会被填充到 tcache bin 中,直到上限。
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```c
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#if USE_TCACHE
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/* While we're here, if we see other chunks of the same size,
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stash them in the tcache. */
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size_t tc_idx = csize2tidx (nb);
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if (tcache && tc_idx < mp_.tcache_bins)
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{
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mchunkptr tc_victim;
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/* While bin not empty and tcache not full, copy chunks over. */
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while (tcache->counts[tc_idx] < mp_.tcache_count
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&& (tc_victim = last (bin)) != bin)
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{
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if (tc_victim != 0)
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{
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bck = tc_victim->bk;
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set_inuse_bit_at_offset (tc_victim, nb);
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if (av != &main_arena)
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set_non_main_arena (tc_victim);
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bin->bk = bck;
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bck->fd = bin;
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tcache_put (tc_victim, tc_idx);
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}
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}
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}
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#endif
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```
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- binning code(chunk合并等其他情况)中,每一个符合要求的 chunk 都会优先被放入 tcache,而不是直接返回(除非tcache被装满)。寻找结束后,tcache 会返回其中一个。
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```c
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#if USE_TCACHE
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/* Fill cache first, return to user only if cache fills.
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We may return one of these chunks later. */
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if (tcache_nb
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&& tcache->counts[tc_idx] < mp_.tcache_count)
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{
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tcache_put (victim, tc_idx);
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return_cached = 1;
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continue;
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}
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else
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{
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#endif
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```
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触发从 tcache 中取出 chunk 的操作:
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- 在 `__libc_malloc()` 调用 `_int_malloc()` 之前,如果 tcache bin 中有符合要求的 chunk,则直接将它返回。
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```c
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#if USE_TCACHE
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/* int_free also calls request2size, be careful to not pad twice. */
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size_t tbytes;
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checked_request2size (bytes, tbytes);
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size_t tc_idx = csize2tidx (tbytes);
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MAYBE_INIT_TCACHE ();
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DIAG_PUSH_NEEDS_COMMENT;
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if (tc_idx < mp_.tcache_bins
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/*&& tc_idx < TCACHE_MAX_BINS*/ /* to appease gcc */
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&& tcache
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&& tcache->entries[tc_idx] != NULL)
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{
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return tcache_get (tc_idx);
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}
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DIAG_POP_NEEDS_COMMENT;
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#endif
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```
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- bining code 中,如果在 tcache 中放入 chunk 达到上限,则会直接返回最后一个 chunk。
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```c
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#if USE_TCACHE
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/* If we've processed as many chunks as we're allowed while
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filling the cache, return one of the cached ones. */
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++tcache_unsorted_count;
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if (return_cached
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&& mp_.tcache_unsorted_limit > 0
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&& tcache_unsorted_count > mp_.tcache_unsorted_limit)
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{
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return tcache_get (tc_idx);
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}
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#endif
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```
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当然默认情况下没有限制,所以这段代码也不会执行:
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```c
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.tcache_unsorted_limit = 0 /* No limit. */
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```
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- binning code 结束后,如果没有直接返回(如上),那么如果有至少一个符合要求的 chunk 被找到,则返回最后一个。
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```c
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#if USE_TCACHE
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/* If all the small chunks we found ended up cached, return one now. */
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if (return_cached)
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{
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return tcache_get (tc_idx);
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}
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#endif
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```
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另外还需要注意的是 tcache 中的 chunk 不会被合并,无论是相邻 chunk,还是 chunk 和 top chunk。因为这些 chunk 会被标记为 inuse。
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## 安全性分析
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`tcache_put()` 和 `tcache_get()` 分别用于从单链表中放入和取出 chunk:
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```c
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/* Caller must ensure that we know tc_idx is valid and there's room
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for more chunks. */
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static __always_inline void
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tcache_put (mchunkptr chunk, size_t tc_idx)
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{
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tcache_entry *e = (tcache_entry *) chunk2mem (chunk);
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assert (tc_idx < TCACHE_MAX_BINS);
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e->next = tcache->entries[tc_idx];
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tcache->entries[tc_idx] = e;
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++(tcache->counts[tc_idx]);
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}
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/* Caller must ensure that we know tc_idx is valid and there's
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available chunks to remove. */
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static __always_inline void *
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tcache_get (size_t tc_idx)
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{
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tcache_entry *e = tcache->entries[tc_idx];
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assert (tc_idx < TCACHE_MAX_BINS);
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assert (tcache->entries[tc_idx] > 0);
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tcache->entries[tc_idx] = e->next;
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--(tcache->counts[tc_idx]);
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return (void *) e;
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}
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```
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可以看到注释部分,它假设调用者已经对参数进行了有效性检查,然而由于对 tcache 的操作在 free 和 malloc 中往往都处于很靠前的位置,导致原来的许多有效性检查都被无视了。这样做虽然有利于提升执行效率,但对安全性造成了负面影响。
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#### tcache_dup
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```c
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#include <stdlib.h>
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#include <stdio.h>
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int main() {
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void *p1 = malloc(0x10);
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printf("1st malloc(0x10): %p\n", p1);
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printf("Freeing the first one\n");
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free(p1);
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printf("Freeing the first one again\n");
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free(p1);
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printf("2nd malloc(0x10): %p\n", malloc(0x10));
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printf("3rd malloc(0x10): %p\n", malloc(0x10));
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}
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```
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```
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$ ./tcache_dup
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1st malloc(0x10): 0x56088c39f260
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Freeing the first one
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Freeing the first one again
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2nd malloc(0x10): 0x56088c39f260
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3rd malloc(0x10): 0x56088c39f260
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```
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tcache_dup 与 fastbin_dup 类似,但其实更加简单,因为它并不局限于 fastbin,只要在 tcache chunk 范围内的都可以,而且 double-free 也不再需要考虑 top 的问题,直接 free 两次就可以了。然后我们就可以得到相同的 chunk。
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第一次 free 后:
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```
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gdb-peda$ x/4gx 0x0000555555756260-0x10
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0x555555756250: 0x0000000000000000 0x0000000000000021
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0x555555756260: 0x0000000000000000 0x0000000000000000
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gdb-peda$ vmmap heap
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Start End Perm Name
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0x0000555555756000 0x0000555555777000 rw-p [heap]
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gdb-peda$ x/10gx 0x0000555555756000+0x10
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0x555555756010: 0x0000000000000001 0x0000000000000000 <-- counts
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0x555555756020: 0x0000000000000000 0x0000000000000000
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0x555555756030: 0x0000000000000000 0x0000000000000000
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0x555555756040: 0x0000000000000000 0x0000000000000000
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0x555555756050: 0x0000555555756260 0x0000000000000000 <-- entries
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```
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chunk 被放入相应的 tcache bin 中,可以看到该 tcache bin 的 counts 被设为 1,表示有 1 个 chunk,入口为 0x0000555555756260。
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第二次 free 后:
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```
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gdb-peda$ x/4gx 0x0000555555756260-0x10
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0x555555756250: 0x0000000000000000 0x0000000000000021 <-- chunk 1 [double freed]
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0x555555756260: 0x0000555555756260 0x0000000000000000
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gdb-peda$ x/10gx 0x0000555555756000+0x10
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0x555555756010: 0x0000000000000002 0x0000000000000000 <-- counts
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0x555555756020: 0x0000000000000000 0x0000000000000000
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0x555555756030: 0x0000000000000000 0x0000000000000000
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0x555555756040: 0x0000000000000000 0x0000000000000000
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0x555555756050: 0x0000555555756260 0x0000000000000000 <-- entries
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```
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counts 变成 2,入口不变,表示 tcache bin 已经有两个 chunk 了,虽然是相同的。
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两次 malloc 后:
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```
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gdb-peda$ x/10gx 0x0000555555756000+0x10
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0x555555756010: 0x0000000000000000 0x0000000000000000 <-- counts
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0x555555756020: 0x0000000000000000 0x0000000000000000
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0x555555756030: 0x0000000000000000 0x0000000000000000
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0x555555756040: 0x0000000000000000 0x0000000000000000
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0x555555756050: 0x0000555555756260 0x0000000000000000
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```
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于是我们得到了两个指向同一块内存区域的指针。
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#### tcache_house_of_spirit
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#### tcache_overlapping_chunks
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#### tcache_poisoning
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这一节的代码可以在[这里](../src/Others/4.14_glibc_tcache)找到。其他的一些情况可以参考章节 3.3.6。
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## CTF 实例
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在最近的 CTF 中,已经开始尝试使用 libc-2.26,比如章节 6.1.15、6.1.19 中的例子。
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## 参考资料
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- [thread local caching in glibc malloc](http://tukan.farm/2017/07/08/tcache/)
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- [MallocInternals](https://sourceware.org/glibc/wiki/MallocInternals)
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