On Wed, Aug 7, 2019 at 7:16 PM Joel Fernandes (Google) <joel@xxxxxxxxxxxxxxxxx> wrote: > The page_idle tracking feature currently requires looking up the pagemap > for a process followed by interacting with /sys/kernel/mm/page_idle. > Looking up PFN from pagemap in Android devices is not supported by > unprivileged process and requires SYS_ADMIN and gives 0 for the PFN. > > This patch adds support to directly interact with page_idle tracking at > the PID level by introducing a /proc/<pid>/page_idle file. It follows > the exact same semantics as the global /sys/kernel/mm/page_idle, but now > looking up PFN through pagemap is not needed since the interface uses > virtual frame numbers, and at the same time also does not require > SYS_ADMIN. > > In Android, we are using this for the heap profiler (heapprofd) which > profiles and pin points code paths which allocates and leaves memory > idle for long periods of time. This method solves the security issue > with userspace learning the PFN, and while at it is also shown to yield > better results than the pagemap lookup, the theory being that the window > where the address space can change is reduced by eliminating the > intermediate pagemap look up stage. In virtual address indexing, the > process's mmap_sem is held for the duration of the access. What happens when you use this interface on shared pages, like memory inherited from the zygote, library file mappings and so on? If two profilers ran concurrently for two different processes that both map the same libraries, would they end up messing up each other's data? Can this be used to observe which library pages other processes are accessing, even if you don't have access to those processes, as long as you can map the same libraries? I realize that there are already a bunch of ways to do that with side channels and such; but if you're adding an interface that allows this by design, it seems to me like something that should be gated behind some sort of privilege check. If the heap profiler is only interested in anonymous, process-private memory, that might be an easy way out? Limit (unprivileged) use of this interface to pages that aren't shared with any other processes? > +/* Helper to get the start and end frame given a pos and count */ > +static int page_idle_get_frames(loff_t pos, size_t count, struct mm_struct *mm, > + unsigned long *start, unsigned long *end) > +{ > + unsigned long max_frame; > + > + /* If an mm is not given, assume we want physical frames */ > + max_frame = mm ? (mm->task_size >> PAGE_SHIFT) : max_pfn; > + > + if (pos % BITMAP_CHUNK_SIZE || count % BITMAP_CHUNK_SIZE) > + return -EINVAL; > + > + *start = pos * BITS_PER_BYTE; > + if (*start >= max_frame) > + return -ENXIO; > + > + *end = *start + count * BITS_PER_BYTE; > + if (*end > max_frame) > + *end = max_frame; > + return 0; > +} You could add some overflow checks for the multiplications. I haven't seen any place where it actually matters, but it seems unclean; and in particular, on a 32-bit architecture where the maximum user address is very high (like with a 4G:4G split), it looks like this function might theoretically return with `*start > *end`, which could be confusing to callers. [...] > for (; pfn < end_pfn; pfn++) { > bit = pfn % BITMAP_CHUNK_BITS; > if (!bit) > *out = 0ULL; > - page = page_idle_get_page(pfn); > - if (page) { > - if (page_is_idle(page)) { > - /* > - * The page might have been referenced via a > - * pte, in which case it is not idle. Clear > - * refs and recheck. > - */ > - page_idle_clear_pte_refs(page); > - if (page_is_idle(page)) > - *out |= 1ULL << bit; > - } > + page = page_idle_get_page_pfn(pfn); > + if (page && page_idle_pte_check(page)) { > + *out |= 1ULL << bit; > put_page(page); > } The `page && !page_idle_pte_check(page)` case looks like it's missing a put_page(); you probably intended to write something like this? page = page_idle_get_page_pfn(pfn); if (page) { if (page_idle_pte_check(page)) *out |= 1ULL << bit; put_page(page); } [...] > +/* page_idle tracking for /proc/<pid>/page_idle */ > + > +struct page_node { > + struct page *page; > + unsigned long addr; > + struct list_head list; > +}; > + > +struct page_idle_proc_priv { > + unsigned long start_addr; > + char *buffer; > + int write; > + > + /* Pre-allocate and provide nodes to pte_page_idle_proc_add() */ > + struct page_node *page_nodes; > + int cur_page_node; > + struct list_head *idle_page_list; > +}; A linked list is a weird data structure to use if the list elements are just consecutive array elements. > +/* > + * Add page to list to be set as idle later. > + */ > +static void pte_page_idle_proc_add(struct page *page, > + unsigned long addr, struct mm_walk *walk) > +{ > + struct page *page_get = NULL; > + struct page_node *pn; > + int bit; > + unsigned long frames; > + struct page_idle_proc_priv *priv = walk->private; > + u64 *chunk = (u64 *)priv->buffer; > + > + if (priv->write) { > + VM_BUG_ON(!page); > + > + /* Find whether this page was asked to be marked */ > + frames = (addr - priv->start_addr) >> PAGE_SHIFT; > + bit = frames % BITMAP_CHUNK_BITS; > + chunk = &chunk[frames / BITMAP_CHUNK_BITS]; > + if (((*chunk >> bit) & 1) == 0) > + return; This means that BITMAP_CHUNK_SIZE is UAPI on big-endian systems, right? My opinion is that it would be slightly nicer to design the UAPI such that incrementing virtual addresses are mapped to incrementing offsets in the buffer (iow, either use bytewise access or use little-endian), but I'm not going to ask you to redesign the UAPI this late. [...] > +ssize_t page_idle_proc_generic(struct file *file, char __user *ubuff, > + size_t count, loff_t *pos, int write) > +{ [...] > + down_read(&mm->mmap_sem); [...] > + > + if (!write && !walk_error) > + ret = copy_to_user(ubuff, buffer, count); > + > + up_read(&mm->mmap_sem); I'd move the up_read() above the copy_to_user(); copy_to_user() can block, and there's no reason to hold the mmap_sem across copy_to_user(). Sorry about only chiming in at v5 with all this.