Can anybody tell the reason why the struct buffer_head structure which were used till Linux Kernel 2.4 is inefficient and what things are implemented in the struct bio structure used in the new redesigned block layer from kernel 2.5.1 ?
In pre-2.5 kernels, buffer_head used to be the unit of IO . However, doing IO in terms of buffer_head can be inefficient. For example, a single write spanning multiple blocks would result in creation of multiple buffer_head objects, thus wasting space and time. So, a buffer_head struct is best used for providing the block-to-physical memory mapping, which is exactly what it does (and the only thing that it does) from 2.5 kernel onwards.
On the other hand, struct bio is designed to be the unit of IO in later kernel releases. **It represents the active IOs currently in the kernel.** Note that the mapping of block-to-memory is still maintained in buffer_head. However, the buffer_head is now not overloaded with the fields that contain info about currently active IO. So, when higher level code such as filesystem, issues an IO, a request is added to the request_queue. The request in turn contains a pointer to the bio structure. The device driver that controls the device on which IO is issued, picks up the request and serves it.
The struct bio structure is also used for splitting IOs, for example, by RAID disk device drivers. Look at the struct bio definition and you will find that it maintains an array of io_vectors (which are nothing but offsets into memory pages). Also, bi_idx is used to index into these io_vec. By using a different bi_idx value for different disk, each disk will pick up a different set of io_vec to write (or read), and thus the IO would be done in a true parallel fashion.
Use the source, luke !
The two decouple I/O characteristics and operations for "higher levels" (I/O through filesystems) and "low levels" (I/O through block devs). This allows for higher performance because a buffer layer waiting somewhere doesn't stop the block layer from performing work elsewhere. Some explanation about it can be found here, and Jens Axboe talks about it in this interview briefly.