struct ion_heap_ops {
int (*allocate) (struct ion_heap *heap,
struct ion_buffer *buffer, unsigned long len,
unsigned long align, unsigned long flags);
void (*free) (struct ion_buffer *buffer);
int (*phys) (struct ion_heap *heap, struct ion_buffer *buffer,
ion_phys_addr_t *addr, size_t *len);
struct scatterlist *(*map_dma) (struct ion_heap *heap,
struct ion_buffer *buffer);
void (*unmap_dma) (struct ion_heap *heap,
struct ion_buffer *buffer);
void * (*map_kernel) (struct ion_heap *heap,
struct ion_buffer *buffer);
void (*unmap_kernel) (struct ion_heap *heap,
struct ion_buffer *buffer);
int (*map_user) (struct ion_heap *heap, struct ion_buffer *buffer,
struct vm_area_struct *vma);
};
方法phys(),返回的是的物理地址和buffer的长度,但必须是连续的物理buffer,如果没有连续的物理buffer,是不能提供改回调。
map_kernel() and unmap_kernel(),把物理内存映射到kernel virtual address space.
map_user(),映射物理内存到用户空间,为啥没有unmap_user()方法呢,因为映射到用户空间,是以FD(文件描述符)的形式映射的,当FD close了就自动unmap。
ION可以释放内存嘛?
答案是否定的。它主要的是提供给applications间共享内存。
ION和PMem可以共存嘛?
可以,但是不能共享buffers.
1:open ION device-------open("/dev/ion", O_RDONLY),返回一个FD(相当于ION client)
2: 客户端要填充如下数据结构,除了handle,也就是你要申请的data:
struct ion_allocation_data {
size_t len;
size_t align;
unsigned int flags;
struct ion_handle *handle;
}
3: user space clients 用ioctl跟ION通信
int ioctl(int client_fd, ION_IOC_ALLOC, struct ion_allocation_data *allocation_data)
返回的FD的buffer。
4:FD可以通过Binder机制进行进程间的share
for example:
>adb shell
#mount -t debugfs NONE /d
#cd /d/ion/
#ls
922
vmalloc
...
# cat vmalloc
cat vmalloc
client pid size
total bytes currently allocated: 0
# cat 922
cat 922
heap_name: size_in_bytes : handle refcount : buffer
client refcount: 1
Feature |
ION |
DMABUF |
Memory Manager Role |
ION replaces PMEM as the manager of provisioned memory pools. The list of ION heaps can be extended per device. |
DMABUF is a buffer sharing framework, designed to integrate with the memory allocators in DMA mapping frameworks, like the work-in-progress DMA-contiguous allocator, also known as theContiguous Memory Allocator (CMA). DMABUF exporters have the option to implement custom allocators. |
User Space Access Control |
ION offers the /dev/ion interface for user-space programs to allocate and share buffers. Any user program with ION access can cripple the system by depleting the ION heaps. Android checks user and group IDs to block unauthorized access to ION heaps. |
DMABUF offers only kernel APIs. Access control is a function of the permissions on the devices using the DMABUF feature. |
Global Client and Buffer Database |
ION contains a device driver associated with /dev/ion. The device structure contains a database that tracks the allocated ION buffers, handles and file descriptors, all grouped by user clients and kernel clients. ION validates all client calls according to the rules of the database. For example, there is a rule that a client cannot have two handles to the same buffer. |
The DMA debug facility implements a global hashtable,dma_entry_hash, to track DMA buffers, but only when the kernel was built with theCONFIG_DMA_API_DEBUGoption. |
Cross-architecture Usage |
ION usage today is limited to architectures that run the Android kernel. |
DMABUF usage is cross-architecture. The DMA mapping redesign preparation patchset modified the DMA mapping code in 9 architectures besides the ARM architecture. |
Buffer Synchronization |
ION considers buffer synchronization to be an orthogonal problem. |
DMABUF provides a pair of APIs for synchronization. The buffer-user callsdma_buf_map_attachment() whenever it wants to use the buffer for DMA . Once the DMA for the current buffer-user is over, it signals 'end-of-DMA' to the exporter via a call todma_buf_unmap_attachment(). |
Delayed Buffer Allocation |
ION allocates the physical memory before the buffer is shared. |
DMABUF can defer the allocation until the first call todma_buf_map_attachment(). The exporter of DMA buffer has the opportunity to scan all client attachments, collate their buffer constraints, then choose the appropriate backing storage. |