tools/readahead_example.txt - platform/external/bcc - Git at Google

 Demonstration of readahead, the Linux eBPF/bcc version

 Read-ahead mechanism is used by operation sytems to optimize sequential operations
 by reading ahead some pages to avoid more expensive filesystem operations. This tool
 shows the performance of the read-ahead caching on the system under a given load to
 investigate any caching issues. It shows a count for unused pages in the cache and
 also prints a histogram showing how long they have remianed there.

 Usage Scenario
 ==============

 Consider that you are developing a React Native application which performs aggressive
 reads while re-encoding a video in local-storage. Usually such an app would be multi-
 layered and have transitional library dependencies. The actual read may be performed
 by some unknown native library which may or may not be using hints to the OS, such as
 madvise(p, LEN, MADV_SEQUENTIAL). If high IOPS is observed in such an app, running
 readahead may pin the issue much faster in this case as the developer digs deeper
 into what may be causing this.

 An example where such an issue can surface is: https://github.com/boltdb/bolt/issues/691

 # readahead -d 30
 Tracing... Hit Ctrl-C to end.
 ^C
 Read-ahead unused pages: 6765
 Histogram of read-ahead used page age (ms):

      age (ms)            : count     distribution
          0 -> 1          : 4236     |****************************************|
          2 -> 3          : 394      |***                                     |
          4 -> 7          : 1670     |***************                         |
          8 -> 15         : 2132     |********************                    |
         16 -> 31         : 401      |***                                     |
         32 -> 63         : 1256     |***********                             |
         64 -> 127        : 2352     |**********************                  |
        128 -> 255        : 357      |***                                     |
        256 -> 511        : 369      |***                                     |
        512 -> 1023       : 366      |***                                     |
       1024 -> 2047       : 181      |*                                       |
       2048 -> 4095       : 439      |****                                    |
       4096 -> 8191       : 188      |*                                       |

 In the example above, we recorded system-wide stats for 30 seconds. We can observe that
 while most of the pages stayed in the readahead cache for quite less time, after 30
 seconds 6765 pages still remained in the cache, yet unaccessed.

 Note on Kprobes Usage
 =====================

 This tool uses Kprobes on the following kernel functions:

 __do_page_cache_readahead()/do_page_cache_ra() (After kernel version 5.10 (include), __do_page_cache_readahead was renamed to do_page_cache_ra)
 __page_cache_alloc()
 mark_page_accessed()

 Since the tool uses Kprobes, depending on your linux kernel's compilation, these
 functions may be inlined and hence not available for Kprobes. To see whether you have
 the functions available, check vmlinux source and binary to confirm whether inlining is
 happening or not. You can also check /proc/kallsyms on the host and verify if the target
 functions are present there before using this tool.
	Demonstration of readahead, the Linux eBPF/bcc version

	Read-ahead mechanism is used by operation sytems to optimize sequential operations
	by reading ahead some pages to avoid more expensive filesystem operations. This tool
	shows the performance of the read-ahead caching on the system under a given load to
	investigate any caching issues. It shows a count for unused pages in the cache and
	also prints a histogram showing how long they have remianed there.

	Usage Scenario
	==============

	Consider that you are developing a React Native application which performs aggressive
	reads while re-encoding a video in local-storage. Usually such an app would be multi-
	layered and have transitional library dependencies. The actual read may be performed
	by some unknown native library which may or may not be using hints to the OS, such as
	madvise(p, LEN, MADV_SEQUENTIAL). If high IOPS is observed in such an app, running
	readahead may pin the issue much faster in this case as the developer digs deeper
	into what may be causing this.

	An example where such an issue can surface is: https://github.com/boltdb/bolt/issues/691

	# readahead -d 30
	Tracing... Hit Ctrl-C to end.
	^C
	Read-ahead unused pages: 6765
	Histogram of read-ahead used page age (ms):

	age (ms) : count distribution
	0 -> 1 : 4236 \|****************************************\|
	2 -> 3 : 394 \|*** \|
	4 -> 7 : 1670 \|*************** \|
	8 -> 15 : 2132 \|******************** \|
	16 -> 31 : 401 \|*** \|
	32 -> 63 : 1256 \|*********** \|
	64 -> 127 : 2352 \|********************** \|
	128 -> 255 : 357 \|*** \|
	256 -> 511 : 369 \|*** \|
	512 -> 1023 : 366 \|*** \|
	1024 -> 2047 : 181 \|* \|
	2048 -> 4095 : 439 \|**** \|
	4096 -> 8191 : 188 \|* \|

	In the example above, we recorded system-wide stats for 30 seconds. We can observe that
	while most of the pages stayed in the readahead cache for quite less time, after 30
	seconds 6765 pages still remained in the cache, yet unaccessed.

	Note on Kprobes Usage
	=====================

	This tool uses Kprobes on the following kernel functions:

	__do_page_cache_readahead()/do_page_cache_ra() (After kernel version 5.10 (include), __do_page_cache_readahead was renamed to do_page_cache_ra)
	__page_cache_alloc()
	mark_page_accessed()

	Since the tool uses Kprobes, depending on your linux kernel's compilation, these
	functions may be inlined and hence not available for Kprobes. To see whether you have
	the functions available, check vmlinux source and binary to confirm whether inlining is
	happening or not. You can also check /proc/kallsyms on the host and verify if the target
	functions are present there before using this tool.