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1222 1223 1224 1225 1226 1227 1228 1229 1230 1231 1232 1233 1234 1235 1236 1237 1238 1239 1240 1241 1242 1243 1244 1245 1246 1247 1248 1249 1250 1251 1252 1253 1254 1255 1256 1257 1258 1259 1260 1261 1262 1263 1264 1265 1266 1267 1268 1269 1270 1271 1272 1273 1274 1275 1276 1277 1278 1279 1280 1281 1282 1283 1284 | // SPDX-License-Identifier: GPL-2.0-only /* binder_alloc.c * * Android IPC Subsystem * * Copyright (C) 2007-2017 Google, Inc. */ #define pr_fmt(fmt) KBUILD_MODNAME ": " fmt #include <linux/list.h> #include <linux/sched/mm.h> #include <linux/module.h> #include <linux/rtmutex.h> #include <linux/rbtree.h> #include <linux/seq_file.h> #include <linux/vmalloc.h> #include <linux/slab.h> #include <linux/sched.h> #include <linux/list_lru.h> #include <linux/ratelimit.h> #include <asm/cacheflush.h> #include <linux/uaccess.h> #include <linux/highmem.h> #include <linux/sizes.h> #include "binder_alloc.h" #include "binder_trace.h" struct list_lru binder_alloc_lru; static DEFINE_MUTEX(binder_alloc_mmap_lock); enum { BINDER_DEBUG_USER_ERROR = 1U << 0, BINDER_DEBUG_OPEN_CLOSE = 1U << 1, BINDER_DEBUG_BUFFER_ALLOC = 1U << 2, BINDER_DEBUG_BUFFER_ALLOC_ASYNC = 1U << 3, }; static uint32_t binder_alloc_debug_mask = BINDER_DEBUG_USER_ERROR; module_param_named(debug_mask, binder_alloc_debug_mask, uint, 0644); #define binder_alloc_debug(mask, x...) \ do { \ if (binder_alloc_debug_mask & mask) \ pr_info_ratelimited(x); \ } while (0) static struct binder_buffer *binder_buffer_next(struct binder_buffer *buffer) { return list_entry(buffer->entry.next, struct binder_buffer, entry); } static struct binder_buffer *binder_buffer_prev(struct binder_buffer *buffer) { return list_entry(buffer->entry.prev, struct binder_buffer, entry); } static size_t binder_alloc_buffer_size(struct binder_alloc *alloc, struct binder_buffer *buffer) { if (list_is_last(&buffer->entry, &alloc->buffers)) return alloc->buffer + alloc->buffer_size - buffer->user_data; return binder_buffer_next(buffer)->user_data - buffer->user_data; } static void binder_insert_free_buffer(struct binder_alloc *alloc, struct binder_buffer *new_buffer) { struct rb_node **p = &alloc->free_buffers.rb_node; struct rb_node *parent = NULL; struct binder_buffer *buffer; size_t buffer_size; size_t new_buffer_size; BUG_ON(!new_buffer->free); new_buffer_size = binder_alloc_buffer_size(alloc, new_buffer); binder_alloc_debug(BINDER_DEBUG_BUFFER_ALLOC, "%d: add free buffer, size %zd, at %pK\n", alloc->pid, new_buffer_size, new_buffer); while (*p) { parent = *p; buffer = rb_entry(parent, struct binder_buffer, rb_node); BUG_ON(!buffer->free); buffer_size = binder_alloc_buffer_size(alloc, buffer); if (new_buffer_size < buffer_size) p = &parent->rb_left; else p = &parent->rb_right; } rb_link_node(&new_buffer->rb_node, parent, p); rb_insert_color(&new_buffer->rb_node, &alloc->free_buffers); } static void binder_insert_allocated_buffer_locked( struct binder_alloc *alloc, struct binder_buffer *new_buffer) { struct rb_node **p = &alloc->allocated_buffers.rb_node; struct rb_node *parent = NULL; struct binder_buffer *buffer; BUG_ON(new_buffer->free); while (*p) { parent = *p; buffer = rb_entry(parent, struct binder_buffer, rb_node); BUG_ON(buffer->free); if (new_buffer->user_data < buffer->user_data) p = &parent->rb_left; else if (new_buffer->user_data > buffer->user_data) p = &parent->rb_right; else BUG(); } rb_link_node(&new_buffer->rb_node, parent, p); rb_insert_color(&new_buffer->rb_node, &alloc->allocated_buffers); } static struct binder_buffer *binder_alloc_prepare_to_free_locked( struct binder_alloc *alloc, uintptr_t user_ptr) { struct rb_node *n = alloc->allocated_buffers.rb_node; struct binder_buffer *buffer; void __user *uptr; uptr = (void __user *)user_ptr; while (n) { buffer = rb_entry(n, struct binder_buffer, rb_node); BUG_ON(buffer->free); if (uptr < buffer->user_data) n = n->rb_left; else if (uptr > buffer->user_data) n = n->rb_right; else { /* * Guard against user threads attempting to * free the buffer when in use by kernel or * after it's already been freed. */ if (!buffer->allow_user_free) return ERR_PTR(-EPERM); buffer->allow_user_free = 0; return buffer; } } return NULL; } /** * binder_alloc_prepare_to_free() - get buffer given user ptr * @alloc: binder_alloc for this proc * @user_ptr: User pointer to buffer data * * Validate userspace pointer to buffer data and return buffer corresponding to * that user pointer. Search the rb tree for buffer that matches user data * pointer. * * Return: Pointer to buffer or NULL */ struct binder_buffer *binder_alloc_prepare_to_free(struct binder_alloc *alloc, uintptr_t user_ptr) { struct binder_buffer *buffer; mutex_lock(&alloc->mutex); buffer = binder_alloc_prepare_to_free_locked(alloc, user_ptr); mutex_unlock(&alloc->mutex); return buffer; } static int binder_update_page_range(struct binder_alloc *alloc, int allocate, void __user *start, void __user *end) { void __user *page_addr; unsigned long user_page_addr; struct binder_lru_page *page; struct vm_area_struct *vma = NULL; struct mm_struct *mm = NULL; bool need_mm = false; binder_alloc_debug(BINDER_DEBUG_BUFFER_ALLOC, "%d: %s pages %pK-%pK\n", alloc->pid, allocate ? "allocate" : "free", start, end); if (end <= start) return 0; trace_binder_update_page_range(alloc, allocate, start, end); if (allocate == 0) goto free_range; for (page_addr = start; page_addr < end; page_addr += PAGE_SIZE) { page = &alloc->pages[(page_addr - alloc->buffer) / PAGE_SIZE]; if (!page->page_ptr) { need_mm = true; break; } } if (need_mm && mmget_not_zero(alloc->mm)) mm = alloc->mm; if (mm) { mmap_write_lock(mm); vma = alloc->vma; } if (!vma && need_mm) { binder_alloc_debug(BINDER_DEBUG_USER_ERROR, "%d: binder_alloc_buf failed to map pages in userspace, no vma\n", alloc->pid); goto err_no_vma; } for (page_addr = start; page_addr < end; page_addr += PAGE_SIZE) { int ret; bool on_lru; size_t index; index = (page_addr - alloc->buffer) / PAGE_SIZE; page = &alloc->pages[index]; if (page->page_ptr) { trace_binder_alloc_lru_start(alloc, index); on_lru = list_lru_del(&binder_alloc_lru, &page->lru); WARN_ON(!on_lru); trace_binder_alloc_lru_end(alloc, index); continue; } if (WARN_ON(!vma)) goto err_page_ptr_cleared; trace_binder_alloc_page_start(alloc, index); page->page_ptr = alloc_page(GFP_KERNEL | __GFP_HIGHMEM | __GFP_ZERO); if (!page->page_ptr) { pr_err("%d: binder_alloc_buf failed for page at %pK\n", alloc->pid, page_addr); goto err_alloc_page_failed; } page->alloc = alloc; INIT_LIST_HEAD(&page->lru); user_page_addr = (uintptr_t)page_addr; ret = vm_insert_page(vma, user_page_addr, page[0].page_ptr); if (ret) { pr_err("%d: binder_alloc_buf failed to map page at %lx in userspace\n", alloc->pid, user_page_addr); goto err_vm_insert_page_failed; } if (index + 1 > alloc->pages_high) alloc->pages_high = index + 1; trace_binder_alloc_page_end(alloc, index); } if (mm) { mmap_write_unlock(mm); mmput(mm); } return 0; free_range: for (page_addr = end - PAGE_SIZE; 1; page_addr -= PAGE_SIZE) { bool ret; size_t index; index = (page_addr - alloc->buffer) / PAGE_SIZE; page = &alloc->pages[index]; trace_binder_free_lru_start(alloc, index); ret = list_lru_add(&binder_alloc_lru, &page->lru); WARN_ON(!ret); trace_binder_free_lru_end(alloc, index); if (page_addr == start) break; continue; err_vm_insert_page_failed: __free_page(page->page_ptr); page->page_ptr = NULL; err_alloc_page_failed: err_page_ptr_cleared: if (page_addr == start) break; } err_no_vma: if (mm) { mmap_write_unlock(mm); mmput(mm); } return vma ? -ENOMEM : -ESRCH; } static inline void binder_alloc_set_vma(struct binder_alloc *alloc, struct vm_area_struct *vma) { /* pairs with smp_load_acquire in binder_alloc_get_vma() */ smp_store_release(&alloc->vma, vma); } static inline struct vm_area_struct *binder_alloc_get_vma( struct binder_alloc *alloc) { /* pairs with smp_store_release in binder_alloc_set_vma() */ return smp_load_acquire(&alloc->vma); } static bool debug_low_async_space_locked(struct binder_alloc *alloc, int pid) { /* * Find the amount and size of buffers allocated by the current caller; * The idea is that once we cross the threshold, whoever is responsible * for the low async space is likely to try to send another async txn, * and at some point we'll catch them in the act. This is more efficient * than keeping a map per pid. */ struct rb_node *n; struct binder_buffer *buffer; size_t total_alloc_size = 0; size_t num_buffers = 0; for (n = rb_first(&alloc->allocated_buffers); n != NULL; n = rb_next(n)) { buffer = rb_entry(n, struct binder_buffer, rb_node); if (buffer->pid != pid) continue; if (!buffer->async_transaction) continue; total_alloc_size += binder_alloc_buffer_size(alloc, buffer) + sizeof(struct binder_buffer); num_buffers++; } /* * Warn if this pid has more than 50 transactions, or more than 50% of * async space (which is 25% of total buffer size). Oneway spam is only * detected when the threshold is exceeded. */ if (num_buffers > 50 || total_alloc_size > alloc->buffer_size / 4) { binder_alloc_debug(BINDER_DEBUG_USER_ERROR, "%d: pid %d spamming oneway? %zd buffers allocated for a total size of %zd\n", alloc->pid, pid, num_buffers, total_alloc_size); if (!alloc->oneway_spam_detected) { alloc->oneway_spam_detected = true; return true; } } return false; } static struct binder_buffer *binder_alloc_new_buf_locked( struct binder_alloc *alloc, size_t data_size, size_t offsets_size, size_t extra_buffers_size, int is_async, int pid) { struct rb_node *n = alloc->free_buffers.rb_node; struct binder_buffer *buffer; size_t buffer_size; struct rb_node *best_fit = NULL; void __user *has_page_addr; void __user *end_page_addr; size_t size, data_offsets_size; int ret; /* Check binder_alloc is fully initialized */ if (!binder_alloc_get_vma(alloc)) { binder_alloc_debug(BINDER_DEBUG_USER_ERROR, "%d: binder_alloc_buf, no vma\n", alloc->pid); return ERR_PTR(-ESRCH); } data_offsets_size = ALIGN(data_size, sizeof(void *)) + ALIGN(offsets_size, sizeof(void *)); if (data_offsets_size < data_size || data_offsets_size < offsets_size) { binder_alloc_debug(BINDER_DEBUG_BUFFER_ALLOC, "%d: got transaction with invalid size %zd-%zd\n", alloc->pid, data_size, offsets_size); return ERR_PTR(-EINVAL); } size = data_offsets_size + ALIGN(extra_buffers_size, sizeof(void *)); if (size < data_offsets_size || size < extra_buffers_size) { binder_alloc_debug(BINDER_DEBUG_BUFFER_ALLOC, "%d: got transaction with invalid extra_buffers_size %zd\n", alloc->pid, extra_buffers_size); return ERR_PTR(-EINVAL); } if (is_async && alloc->free_async_space < size + sizeof(struct binder_buffer)) { binder_alloc_debug(BINDER_DEBUG_BUFFER_ALLOC, "%d: binder_alloc_buf size %zd failed, no async space left\n", alloc->pid, size); return ERR_PTR(-ENOSPC); } /* Pad 0-size buffers so they get assigned unique addresses */ size = max(size, sizeof(void *)); while (n) { buffer = rb_entry(n, struct binder_buffer, rb_node); BUG_ON(!buffer->free); buffer_size = binder_alloc_buffer_size(alloc, buffer); if (size < buffer_size) { best_fit = n; n = n->rb_left; } else if (size > buffer_size) n = n->rb_right; else { best_fit = n; break; } } if (best_fit == NULL) { size_t allocated_buffers = 0; size_t largest_alloc_size = 0; size_t total_alloc_size = 0; size_t free_buffers = 0; size_t largest_free_size = 0; size_t total_free_size = 0; for (n = rb_first(&alloc->allocated_buffers); n != NULL; n = rb_next(n)) { buffer = rb_entry(n, struct binder_buffer, rb_node); buffer_size = binder_alloc_buffer_size(alloc, buffer); allocated_buffers++; total_alloc_size += buffer_size; if (buffer_size > largest_alloc_size) largest_alloc_size = buffer_size; } for (n = rb_first(&alloc->free_buffers); n != NULL; n = rb_next(n)) { buffer = rb_entry(n, struct binder_buffer, rb_node); buffer_size = binder_alloc_buffer_size(alloc, buffer); free_buffers++; total_free_size += buffer_size; if (buffer_size > largest_free_size) largest_free_size = buffer_size; } binder_alloc_debug(BINDER_DEBUG_USER_ERROR, "%d: binder_alloc_buf size %zd failed, no address space\n", alloc->pid, size); binder_alloc_debug(BINDER_DEBUG_USER_ERROR, "allocated: %zd (num: %zd largest: %zd), free: %zd (num: %zd largest: %zd)\n", total_alloc_size, allocated_buffers, largest_alloc_size, total_free_size, free_buffers, largest_free_size); return ERR_PTR(-ENOSPC); } if (n == NULL) { buffer = rb_entry(best_fit, struct binder_buffer, rb_node); buffer_size = binder_alloc_buffer_size(alloc, buffer); } binder_alloc_debug(BINDER_DEBUG_BUFFER_ALLOC, "%d: binder_alloc_buf size %zd got buffer %pK size %zd\n", alloc->pid, size, buffer, buffer_size); has_page_addr = (void __user *) (((uintptr_t)buffer->user_data + buffer_size) & PAGE_MASK); WARN_ON(n && buffer_size != size); end_page_addr = (void __user *)PAGE_ALIGN((uintptr_t)buffer->user_data + size); if (end_page_addr > has_page_addr) end_page_addr = has_page_addr; ret = binder_update_page_range(alloc, 1, (void __user *) PAGE_ALIGN((uintptr_t)buffer->user_data), end_page_addr); if (ret) return ERR_PTR(ret); if (buffer_size != size) { struct binder_buffer *new_buffer; new_buffer = kzalloc(sizeof(*buffer), GFP_KERNEL); if (!new_buffer) { pr_err("%s: %d failed to alloc new buffer struct\n", __func__, alloc->pid); goto err_alloc_buf_struct_failed; } new_buffer->user_data = (u8 __user *)buffer->user_data + size; list_add(&new_buffer->entry, &buffer->entry); new_buffer->free = 1; binder_insert_free_buffer(alloc, new_buffer); } rb_erase(best_fit, &alloc->free_buffers); buffer->free = 0; buffer->allow_user_free = 0; binder_insert_allocated_buffer_locked(alloc, buffer); binder_alloc_debug(BINDER_DEBUG_BUFFER_ALLOC, "%d: binder_alloc_buf size %zd got %pK\n", alloc->pid, size, buffer); buffer->data_size = data_size; buffer->offsets_size = offsets_size; buffer->async_transaction = is_async; buffer->extra_buffers_size = extra_buffers_size; buffer->pid = pid; buffer->oneway_spam_suspect = false; if (is_async) { alloc->free_async_space -= size + sizeof(struct binder_buffer); binder_alloc_debug(BINDER_DEBUG_BUFFER_ALLOC_ASYNC, "%d: binder_alloc_buf size %zd async free %zd\n", alloc->pid, size, alloc->free_async_space); if (alloc->free_async_space < alloc->buffer_size / 10) { /* * Start detecting spammers once we have less than 20% * of async space left (which is less than 10% of total * buffer size). */ buffer->oneway_spam_suspect = debug_low_async_space_locked(alloc, pid); } else { alloc->oneway_spam_detected = false; } } return buffer; err_alloc_buf_struct_failed: binder_update_page_range(alloc, 0, (void __user *) PAGE_ALIGN((uintptr_t)buffer->user_data), end_page_addr); return ERR_PTR(-ENOMEM); } /** * binder_alloc_new_buf() - Allocate a new binder buffer * @alloc: binder_alloc for this proc * @data_size: size of user data buffer * @offsets_size: user specified buffer offset * @extra_buffers_size: size of extra space for meta-data (eg, security context) * @is_async: buffer for async transaction * @pid: pid to attribute allocation to (used for debugging) * * Allocate a new buffer given the requested sizes. Returns * the kernel version of the buffer pointer. The size allocated * is the sum of the three given sizes (each rounded up to * pointer-sized boundary) * * Return: The allocated buffer or %NULL if error */ struct binder_buffer *binder_alloc_new_buf(struct binder_alloc *alloc, size_t data_size, size_t offsets_size, size_t extra_buffers_size, int is_async, int pid) { struct binder_buffer *buffer; mutex_lock(&alloc->mutex); buffer = binder_alloc_new_buf_locked(alloc, data_size, offsets_size, extra_buffers_size, is_async, pid); mutex_unlock(&alloc->mutex); return buffer; } static void __user *buffer_start_page(struct binder_buffer *buffer) { return (void __user *)((uintptr_t)buffer->user_data & PAGE_MASK); } static void __user *prev_buffer_end_page(struct binder_buffer *buffer) { return (void __user *) (((uintptr_t)(buffer->user_data) - 1) & PAGE_MASK); } static void binder_delete_free_buffer(struct binder_alloc *alloc, struct binder_buffer *buffer) { struct binder_buffer *prev, *next = NULL; bool to_free = true; BUG_ON(alloc->buffers.next == &buffer->entry); prev = binder_buffer_prev(buffer); BUG_ON(!prev->free); if (prev_buffer_end_page(prev) == buffer_start_page(buffer)) { to_free = false; binder_alloc_debug(BINDER_DEBUG_BUFFER_ALLOC, "%d: merge free, buffer %pK share page with %pK\n", alloc->pid, buffer->user_data, prev->user_data); } if (!list_is_last(&buffer->entry, &alloc->buffers)) { next = binder_buffer_next(buffer); if (buffer_start_page(next) == buffer_start_page(buffer)) { to_free = false; binder_alloc_debug(BINDER_DEBUG_BUFFER_ALLOC, "%d: merge free, buffer %pK share page with %pK\n", alloc->pid, buffer->user_data, next->user_data); } } if (PAGE_ALIGNED(buffer->user_data)) { binder_alloc_debug(BINDER_DEBUG_BUFFER_ALLOC, "%d: merge free, buffer start %pK is page aligned\n", alloc->pid, buffer->user_data); to_free = false; } if (to_free) { binder_alloc_debug(BINDER_DEBUG_BUFFER_ALLOC, "%d: merge free, buffer %pK do not share page with %pK or %pK\n", alloc->pid, buffer->user_data, prev->user_data, next ? next->user_data : NULL); binder_update_page_range(alloc, 0, buffer_start_page(buffer), buffer_start_page(buffer) + PAGE_SIZE); } list_del(&buffer->entry); kfree(buffer); } static void binder_free_buf_locked(struct binder_alloc *alloc, struct binder_buffer *buffer) { size_t size, buffer_size; buffer_size = binder_alloc_buffer_size(alloc, buffer); size = ALIGN(buffer->data_size, sizeof(void *)) + ALIGN(buffer->offsets_size, sizeof(void *)) + ALIGN(buffer->extra_buffers_size, sizeof(void *)); binder_alloc_debug(BINDER_DEBUG_BUFFER_ALLOC, "%d: binder_free_buf %pK size %zd buffer_size %zd\n", alloc->pid, buffer, size, buffer_size); BUG_ON(buffer->free); BUG_ON(size > buffer_size); BUG_ON(buffer->transaction != NULL); BUG_ON(buffer->user_data < alloc->buffer); BUG_ON(buffer->user_data > alloc->buffer + alloc->buffer_size); if (buffer->async_transaction) { alloc->free_async_space += buffer_size + sizeof(struct binder_buffer); binder_alloc_debug(BINDER_DEBUG_BUFFER_ALLOC_ASYNC, "%d: binder_free_buf size %zd async free %zd\n", alloc->pid, size, alloc->free_async_space); } binder_update_page_range(alloc, 0, (void __user *)PAGE_ALIGN((uintptr_t)buffer->user_data), (void __user *)(((uintptr_t) buffer->user_data + buffer_size) & PAGE_MASK)); rb_erase(&buffer->rb_node, &alloc->allocated_buffers); buffer->free = 1; if (!list_is_last(&buffer->entry, &alloc->buffers)) { struct binder_buffer *next = binder_buffer_next(buffer); if (next->free) { rb_erase(&next->rb_node, &alloc->free_buffers); binder_delete_free_buffer(alloc, next); } } if (alloc->buffers.next != &buffer->entry) { struct binder_buffer *prev = binder_buffer_prev(buffer); if (prev->free) { binder_delete_free_buffer(alloc, buffer); rb_erase(&prev->rb_node, &alloc->free_buffers); buffer = prev; } } binder_insert_free_buffer(alloc, buffer); } static void binder_alloc_clear_buf(struct binder_alloc *alloc, struct binder_buffer *buffer); /** * binder_alloc_free_buf() - free a binder buffer * @alloc: binder_alloc for this proc * @buffer: kernel pointer to buffer * * Free the buffer allocated via binder_alloc_new_buf() */ void binder_alloc_free_buf(struct binder_alloc *alloc, struct binder_buffer *buffer) { /* * We could eliminate the call to binder_alloc_clear_buf() * from binder_alloc_deferred_release() by moving this to * binder_alloc_free_buf_locked(). However, that could * increase contention for the alloc mutex if clear_on_free * is used frequently for large buffers. The mutex is not * needed for correctness here. */ if (buffer->clear_on_free) { binder_alloc_clear_buf(alloc, buffer); buffer->clear_on_free = false; } mutex_lock(&alloc->mutex); binder_free_buf_locked(alloc, buffer); mutex_unlock(&alloc->mutex); } /** * binder_alloc_mmap_handler() - map virtual address space for proc * @alloc: alloc structure for this proc * @vma: vma passed to mmap() * * Called by binder_mmap() to initialize the space specified in * vma for allocating binder buffers * * Return: * 0 = success * -EBUSY = address space already mapped * -ENOMEM = failed to map memory to given address space */ int binder_alloc_mmap_handler(struct binder_alloc *alloc, struct vm_area_struct *vma) { int ret; const char *failure_string; struct binder_buffer *buffer; if (unlikely(vma->vm_mm != alloc->mm)) { ret = -EINVAL; failure_string = "invalid vma->vm_mm"; goto err_invalid_mm; } mutex_lock(&binder_alloc_mmap_lock); if (alloc->buffer_size) { ret = -EBUSY; failure_string = "already mapped"; goto err_already_mapped; } alloc->buffer_size = min_t(unsigned long, vma->vm_end - vma->vm_start, SZ_4M); mutex_unlock(&binder_alloc_mmap_lock); alloc->buffer = (void __user *)vma->vm_start; alloc->pages = kcalloc(alloc->buffer_size / PAGE_SIZE, sizeof(alloc->pages[0]), GFP_KERNEL); if (alloc->pages == NULL) { ret = -ENOMEM; failure_string = "alloc page array"; goto err_alloc_pages_failed; } buffer = kzalloc(sizeof(*buffer), GFP_KERNEL); if (!buffer) { ret = -ENOMEM; failure_string = "alloc buffer struct"; goto err_alloc_buf_struct_failed; } buffer->user_data = alloc->buffer; list_add(&buffer->entry, &alloc->buffers); buffer->free = 1; binder_insert_free_buffer(alloc, buffer); alloc->free_async_space = alloc->buffer_size / 2; /* Signal binder_alloc is fully initialized */ binder_alloc_set_vma(alloc, vma); return 0; err_alloc_buf_struct_failed: kfree(alloc->pages); alloc->pages = NULL; err_alloc_pages_failed: alloc->buffer = NULL; mutex_lock(&binder_alloc_mmap_lock); alloc->buffer_size = 0; err_already_mapped: mutex_unlock(&binder_alloc_mmap_lock); err_invalid_mm: binder_alloc_debug(BINDER_DEBUG_USER_ERROR, "%s: %d %lx-%lx %s failed %d\n", __func__, alloc->pid, vma->vm_start, vma->vm_end, failure_string, ret); return ret; } void binder_alloc_deferred_release(struct binder_alloc *alloc) { struct rb_node *n; int buffers, page_count; struct binder_buffer *buffer; buffers = 0; mutex_lock(&alloc->mutex); BUG_ON(alloc->vma); while ((n = rb_first(&alloc->allocated_buffers))) { buffer = rb_entry(n, struct binder_buffer, rb_node); /* Transaction should already have been freed */ BUG_ON(buffer->transaction); if (buffer->clear_on_free) { binder_alloc_clear_buf(alloc, buffer); buffer->clear_on_free = false; } binder_free_buf_locked(alloc, buffer); buffers++; } while (!list_empty(&alloc->buffers)) { buffer = list_first_entry(&alloc->buffers, struct binder_buffer, entry); WARN_ON(!buffer->free); list_del(&buffer->entry); WARN_ON_ONCE(!list_empty(&alloc->buffers)); kfree(buffer); } page_count = 0; if (alloc->pages) { int i; for (i = 0; i < alloc->buffer_size / PAGE_SIZE; i++) { void __user *page_addr; bool on_lru; if (!alloc->pages[i].page_ptr) continue; on_lru = list_lru_del(&binder_alloc_lru, &alloc->pages[i].lru); page_addr = alloc->buffer + i * PAGE_SIZE; binder_alloc_debug(BINDER_DEBUG_BUFFER_ALLOC, "%s: %d: page %d at %pK %s\n", __func__, alloc->pid, i, page_addr, on_lru ? "on lru" : "active"); __free_page(alloc->pages[i].page_ptr); page_count++; } kfree(alloc->pages); } mutex_unlock(&alloc->mutex); if (alloc->mm) mmdrop(alloc->mm); binder_alloc_debug(BINDER_DEBUG_OPEN_CLOSE, "%s: %d buffers %d, pages %d\n", __func__, alloc->pid, buffers, page_count); } static void print_binder_buffer(struct seq_file *m, const char *prefix, struct binder_buffer *buffer) { seq_printf(m, "%s %d: %pK size %zd:%zd:%zd %s\n", prefix, buffer->debug_id, buffer->user_data, buffer->data_size, buffer->offsets_size, buffer->extra_buffers_size, buffer->transaction ? "active" : "delivered"); } /** * binder_alloc_print_allocated() - print buffer info * @m: seq_file for output via seq_printf() * @alloc: binder_alloc for this proc * * Prints information about every buffer associated with * the binder_alloc state to the given seq_file */ void binder_alloc_print_allocated(struct seq_file *m, struct binder_alloc *alloc) { struct rb_node *n; mutex_lock(&alloc->mutex); for (n = rb_first(&alloc->allocated_buffers); n != NULL; n = rb_next(n)) print_binder_buffer(m, " buffer", rb_entry(n, struct binder_buffer, rb_node)); mutex_unlock(&alloc->mutex); } /** * binder_alloc_print_pages() - print page usage * @m: seq_file for output via seq_printf() * @alloc: binder_alloc for this proc */ void binder_alloc_print_pages(struct seq_file *m, struct binder_alloc *alloc) { struct binder_lru_page *page; int i; int active = 0; int lru = 0; int free = 0; mutex_lock(&alloc->mutex); /* * Make sure the binder_alloc is fully initialized, otherwise we might * read inconsistent state. */ if (binder_alloc_get_vma(alloc) != NULL) { for (i = 0; i < alloc->buffer_size / PAGE_SIZE; i++) { page = &alloc->pages[i]; if (!page->page_ptr) free++; else if (list_empty(&page->lru)) active++; else lru++; } } mutex_unlock(&alloc->mutex); seq_printf(m, " pages: %d:%d:%d\n", active, lru, free); seq_printf(m, " pages high watermark: %zu\n", alloc->pages_high); } /** * binder_alloc_get_allocated_count() - return count of buffers * @alloc: binder_alloc for this proc * * Return: count of allocated buffers */ int binder_alloc_get_allocated_count(struct binder_alloc *alloc) { struct rb_node *n; int count = 0; mutex_lock(&alloc->mutex); for (n = rb_first(&alloc->allocated_buffers); n != NULL; n = rb_next(n)) count++; mutex_unlock(&alloc->mutex); return count; } /** * binder_alloc_vma_close() - invalidate address space * @alloc: binder_alloc for this proc * * Called from binder_vma_close() when releasing address space. * Clears alloc->vma to prevent new incoming transactions from * allocating more buffers. */ void binder_alloc_vma_close(struct binder_alloc *alloc) { binder_alloc_set_vma(alloc, NULL); } /** * binder_alloc_free_page() - shrinker callback to free pages * @item: item to free * @lock: lock protecting the item * @cb_arg: callback argument * * Called from list_lru_walk() in binder_shrink_scan() to free * up pages when the system is under memory pressure. */ enum lru_status binder_alloc_free_page(struct list_head *item, struct list_lru_one *lru, spinlock_t *lock, void *cb_arg) __must_hold(lock) { struct mm_struct *mm = NULL; struct binder_lru_page *page = container_of(item, struct binder_lru_page, lru); struct binder_alloc *alloc; uintptr_t page_addr; size_t index; struct vm_area_struct *vma; alloc = page->alloc; if (!mutex_trylock(&alloc->mutex)) goto err_get_alloc_mutex_failed; if (!page->page_ptr) goto err_page_already_freed; index = page - alloc->pages; page_addr = (uintptr_t)alloc->buffer + index * PAGE_SIZE; mm = alloc->mm; if (!mmget_not_zero(mm)) goto err_mmget; if (!mmap_read_trylock(mm)) goto err_mmap_read_lock_failed; vma = binder_alloc_get_vma(alloc); list_lru_isolate(lru, item); spin_unlock(lock); if (vma) { trace_binder_unmap_user_start(alloc, index); zap_page_range_single(vma, page_addr, PAGE_SIZE, NULL); trace_binder_unmap_user_end(alloc, index); } mmap_read_unlock(mm); mmput_async(mm); trace_binder_unmap_kernel_start(alloc, index); __free_page(page->page_ptr); page->page_ptr = NULL; trace_binder_unmap_kernel_end(alloc, index); spin_lock(lock); mutex_unlock(&alloc->mutex); return LRU_REMOVED_RETRY; err_mmap_read_lock_failed: mmput_async(mm); err_mmget: err_page_already_freed: mutex_unlock(&alloc->mutex); err_get_alloc_mutex_failed: return LRU_SKIP; } static unsigned long binder_shrink_count(struct shrinker *shrink, struct shrink_control *sc) { return list_lru_count(&binder_alloc_lru); } static unsigned long binder_shrink_scan(struct shrinker *shrink, struct shrink_control *sc) { return list_lru_walk(&binder_alloc_lru, binder_alloc_free_page, NULL, sc->nr_to_scan); } static struct shrinker binder_shrinker = { .count_objects = binder_shrink_count, .scan_objects = binder_shrink_scan, .seeks = DEFAULT_SEEKS, }; /** * binder_alloc_init() - called by binder_open() for per-proc initialization * @alloc: binder_alloc for this proc * * Called from binder_open() to initialize binder_alloc fields for * new binder proc */ void binder_alloc_init(struct binder_alloc *alloc) { alloc->pid = current->group_leader->pid; alloc->mm = current->mm; mmgrab(alloc->mm); mutex_init(&alloc->mutex); INIT_LIST_HEAD(&alloc->buffers); } int binder_alloc_shrinker_init(void) { int ret = list_lru_init(&binder_alloc_lru); if (ret == 0) { ret = register_shrinker(&binder_shrinker, "android-binder"); if (ret) list_lru_destroy(&binder_alloc_lru); } return ret; } void binder_alloc_shrinker_exit(void) { unregister_shrinker(&binder_shrinker); list_lru_destroy(&binder_alloc_lru); } /** * check_buffer() - verify that buffer/offset is safe to access * @alloc: binder_alloc for this proc * @buffer: binder buffer to be accessed * @offset: offset into @buffer data * @bytes: bytes to access from offset * * Check that the @offset/@bytes are within the size of the given * @buffer and that the buffer is currently active and not freeable. * Offsets must also be multiples of sizeof(u32). The kernel is * allowed to touch the buffer in two cases: * * 1) when the buffer is being created: * (buffer->free == 0 && buffer->allow_user_free == 0) * 2) when the buffer is being torn down: * (buffer->free == 0 && buffer->transaction == NULL). * * Return: true if the buffer is safe to access */ static inline bool check_buffer(struct binder_alloc *alloc, struct binder_buffer *buffer, binder_size_t offset, size_t bytes) { size_t buffer_size = binder_alloc_buffer_size(alloc, buffer); return buffer_size >= bytes && offset <= buffer_size - bytes && IS_ALIGNED(offset, sizeof(u32)) && !buffer->free && (!buffer->allow_user_free || !buffer->transaction); } /** * binder_alloc_get_page() - get kernel pointer for given buffer offset * @alloc: binder_alloc for this proc * @buffer: binder buffer to be accessed * @buffer_offset: offset into @buffer data * @pgoffp: address to copy final page offset to * * Lookup the struct page corresponding to the address * at @buffer_offset into @buffer->user_data. If @pgoffp is not * NULL, the byte-offset into the page is written there. * * The caller is responsible to ensure that the offset points * to a valid address within the @buffer and that @buffer is * not freeable by the user. Since it can't be freed, we are * guaranteed that the corresponding elements of @alloc->pages[] * cannot change. * * Return: struct page */ static struct page *binder_alloc_get_page(struct binder_alloc *alloc, struct binder_buffer *buffer, binder_size_t buffer_offset, pgoff_t *pgoffp) { binder_size_t buffer_space_offset = buffer_offset + (buffer->user_data - alloc->buffer); pgoff_t pgoff = buffer_space_offset & ~PAGE_MASK; size_t index = buffer_space_offset >> PAGE_SHIFT; struct binder_lru_page *lru_page; lru_page = &alloc->pages[index]; *pgoffp = pgoff; return lru_page->page_ptr; } /** * binder_alloc_clear_buf() - zero out buffer * @alloc: binder_alloc for this proc * @buffer: binder buffer to be cleared * * memset the given buffer to 0 */ static void binder_alloc_clear_buf(struct binder_alloc *alloc, struct binder_buffer *buffer) { size_t bytes = binder_alloc_buffer_size(alloc, buffer); binder_size_t buffer_offset = 0; while (bytes) { unsigned long size; struct page *page; pgoff_t pgoff; page = binder_alloc_get_page(alloc, buffer, buffer_offset, &pgoff); size = min_t(size_t, bytes, PAGE_SIZE - pgoff); memset_page(page, pgoff, 0, size); bytes -= size; buffer_offset += size; } } /** * binder_alloc_copy_user_to_buffer() - copy src user to tgt user * @alloc: binder_alloc for this proc * @buffer: binder buffer to be accessed * @buffer_offset: offset into @buffer data * @from: userspace pointer to source buffer * @bytes: bytes to copy * * Copy bytes from source userspace to target buffer. * * Return: bytes remaining to be copied */ unsigned long binder_alloc_copy_user_to_buffer(struct binder_alloc *alloc, struct binder_buffer *buffer, binder_size_t buffer_offset, const void __user *from, size_t bytes) { if (!check_buffer(alloc, buffer, buffer_offset, bytes)) return bytes; while (bytes) { unsigned long size; unsigned long ret; struct page *page; pgoff_t pgoff; void *kptr; page = binder_alloc_get_page(alloc, buffer, buffer_offset, &pgoff); size = min_t(size_t, bytes, PAGE_SIZE - pgoff); kptr = kmap_local_page(page) + pgoff; ret = copy_from_user(kptr, from, size); kunmap_local(kptr); if (ret) return bytes - size + ret; bytes -= size; from += size; buffer_offset += size; } return 0; } static int binder_alloc_do_buffer_copy(struct binder_alloc *alloc, bool to_buffer, struct binder_buffer *buffer, binder_size_t buffer_offset, void *ptr, size_t bytes) { /* All copies must be 32-bit aligned and 32-bit size */ if (!check_buffer(alloc, buffer, buffer_offset, bytes)) return -EINVAL; while (bytes) { unsigned long size; struct page *page; pgoff_t pgoff; page = binder_alloc_get_page(alloc, buffer, buffer_offset, &pgoff); size = min_t(size_t, bytes, PAGE_SIZE - pgoff); if (to_buffer) memcpy_to_page(page, pgoff, ptr, size); else memcpy_from_page(ptr, page, pgoff, size); bytes -= size; pgoff = 0; ptr = ptr + size; buffer_offset += size; } return 0; } int binder_alloc_copy_to_buffer(struct binder_alloc *alloc, struct binder_buffer *buffer, binder_size_t buffer_offset, void *src, size_t bytes) { return binder_alloc_do_buffer_copy(alloc, true, buffer, buffer_offset, src, bytes); } int binder_alloc_copy_from_buffer(struct binder_alloc *alloc, void *dest, struct binder_buffer *buffer, binder_size_t buffer_offset, size_t bytes) { return binder_alloc_do_buffer_copy(alloc, false, buffer, buffer_offset, dest, bytes); } |