systemtap-common 2.3-1ubuntu1 / usr / share / systemtap / tapset / linux / ioblock.stp

// Block I/O tapset
// Copyright (C) 2006 Intel Corp.
// Copyright (C) 2006 IBM Corp.
// Copyright (C) 2010 Red Hat Inc.
//
// This file is part of systemtap, and is free software.  You can
// redistribute it and/or modify it under the terms of the GNU General
// Public License (GPL); either version 2, or (at your option) any
// later version.

%{
#include <linux/bio.h>
#include <linux/genhd.h>
#ifdef STAPCONF_BLK_TYPES
#include <linux/blk_types.h>
#else
#define REQ_WRITE               (1 << BIO_RW)
#endif
%}

/* get i-node number of mapped file */
function __bio_ino:long(bio:long)
%{ /* pure */
    struct bio *bio = (struct bio *)(long)STAP_ARG_bio;
    struct page *bv_page = (bio && bio->bi_vcnt) ? kread(&(bio->bi_io_vec[0].bv_page)) : NULL;
    struct address_space *mapping;
    struct inode *host;
    STAP_RETVALUE = -1;
    if (bv_page && !PageSlab(bv_page) && !PageSwapCache(bv_page)) {
        mapping = kread(&(bv_page->mapping));
        if (mapping && ((unsigned long)mapping & PAGE_MAPPING_ANON) == 0) {
            host = kread(&(mapping->host));
            if (host)
                STAP_RETVALUE = kread(&(host->i_ino));
        }
    }
    CATCH_DEREF_FAULT();
%}

/* returns 0 for read, 1 for write */
function bio_rw_num:long(rw:long)
%{ /* pure */
    long rw = (long)STAP_ARG_rw;
    STAP_RETVALUE = (rw & REQ_WRITE);
%}

/* returns R for read, W for write */
function bio_rw_str(rw:long)
{
    return bio_rw_num(rw) == BIO_READ ? "R" : "W"
}

/* returns start sector */
function __bio_start_sect:long(bio:long)
{
    bi_bdev = bio ? @cast(bio, "bio")->bi_bdev : 0
    bd_part = bi_bdev ? @cast(bi_bdev, "block_device")->bd_part : 0
    return bd_part ? @cast(bd_part, "hd_struct")->start_sect : -1
}

/* returns the block device name */
function __bio_devname:string(bio:long)
{
    return bdevname(@cast(bio, "bio")->bi_bdev)
}

global BIO_READ = 0, BIO_WRITE = 1


/**
 *  probe ioblock.request - Fires whenever making a generic block I/O request.
 *
 *  @name      - name of the probe point
 *  @devname   - block device name
 *  @ino       - i-node number of the mapped file
 *  @sector    - beginning sector for the entire bio
 *  @flags     - see below
 *  	BIO_UPTODATE    0       ok after I/O completion
 *  	BIO_RW_BLOCK    1       RW_AHEAD set, and read/write would block
 *  	BIO_EOF         2       out-out-bounds error
 *  	BIO_SEG_VALID   3       nr_hw_seg valid 
 *  	BIO_CLONED      4       doesn't own data
 *  	BIO_BOUNCED     5       bio is a bounce bio
 *  	BIO_USER_MAPPED 6       contains user pages
 *  	BIO_EOPNOTSUPP  7       not supported
 *  
 *  @rw        - binary trace for read/write request
 *  @vcnt      - bio vector count which represents number of array element (page, offset, length) which make up this I/O request
 *  @idx       - offset into the bio vector array
 *  @phys_segments - number of segments in this bio after physical address coalescing is performed
 *  @hw_segments -   number of segments after physical and DMA remapping hardware coalescing is performed
 *  @size      - total size in bytes
 *  @bdev      - target block device
 *  @bdev_contains - points to the device object which contains the partition (when bio structure represents a partition)
 *  @p_start_sect -  points to the start sector of the partition structure of the device
 *
 * Context:
 *  The process makes block I/O request
 */
probe ioblock.request = kernel.function ("generic_make_request")
{
	name = "ioblock.request"
        devname = __bio_devname($bio)
        ino = __bio_ino($bio)

        sector = $bio->bi_sector
        flags = $bio->bi_flags
        rw = $bio->bi_rw
        vcnt = $bio->bi_vcnt
        idx = $bio->bi_idx
        phys_segments = $bio->bi_phys_segments
	hw_segments = @choose_defined($bio->bi_hw_segments, 0)
        size = $bio->bi_size

        bdev = $bio->bi_bdev
        bdev_contains = $bio->bi_bdev->bd_contains
        p_start_sect = __bio_start_sect($bio)
}

/**
 * probe ioblock.end - Fires whenever a block I/O transfer is complete.
 *
 *  @name      - name of the probe point
 *  @devname   - block device name
 *  @ino       - i-node number of the mapped file
 *  @bytes_done - number of bytes transferred
 *  @sector    - beginning sector for the entire bio
 *  @flags     - see below
 *      BIO_UPTODATE    0       ok after I/O completion
 *      BIO_RW_BLOCK    1       RW_AHEAD set, and read/write would block
 *      BIO_EOF         2       out-out-bounds error
 *      BIO_SEG_VALID   3       nr_hw_seg valid
 *      BIO_CLONED      4       doesn't own data
 *      BIO_BOUNCED     5       bio is a bounce bio
 *      BIO_USER_MAPPED 6       contains user pages
 *      BIO_EOPNOTSUPP  7       not supported
 *  @error     - 0 on success
 *  @rw        - binary trace for read/write request
 *  @vcnt      - bio vector count which represents number of array element (page, offset, length) which makes up this I/O request
 *  @idx       - offset into the bio vector array
 *  @phys_segments - number of segments in this bio after physical address coalescing is performed.
 *  @hw_segments -   number of segments after physical and DMA remapping hardware coalescing is performed
 *  @size      - total size in bytes
 *
 * Context:
 *  The process signals the transfer is done.
 */
probe ioblock.end = kernel.function("bio_endio")
{
	name = "ioblock.end"
        devname = __bio_devname($bio)
        ino = __bio_ino($bio)

        bytes_done = @choose_defined($bytes_done, $bio->bi_size)
        error = $error

        sector = $bio->bi_sector
        flags = $bio->bi_flags
        rw = $bio->bi_rw
        vcnt = $bio->bi_vcnt
        idx = $bio->bi_idx
        phys_segments = $bio->bi_phys_segments
	hw_segments = @choose_defined($bio->bi_hw_segments, 0)
        size = $bio->bi_size
}

/**
 * probe ioblock_trace.bounce - Fires whenever a buffer bounce is needed for at least one page of a block IO request.
 *
 *  @name      - name of the probe point
 *  @q         - request queue on which this bio was queued.
 *  @devname   - device for which a buffer bounce was needed.
 *  @ino       - i-node number of the mapped file
 *  @bytes_done - number of bytes transferred
 *  @sector    - beginning sector for the entire bio
 *  @flags     - see below
 *      BIO_UPTODATE    0       ok after I/O completion
 *      BIO_RW_BLOCK    1       RW_AHEAD set, and read/write would block
 *      BIO_EOF         2       out-out-bounds error
 *      BIO_SEG_VALID   3       nr_hw_seg valid
 *      BIO_CLONED      4       doesn't own data
 *      BIO_BOUNCED     5       bio is a bounce bio
 *      BIO_USER_MAPPED 6       contains user pages
 *      BIO_EOPNOTSUPP  7       not supported
 *  @rw        - binary trace for read/write request
 *  @vcnt      - bio vector count which represents number of array element (page, offset, length) which makes up this I/O request
 *  @idx       - offset into the bio vector array
 *  @phys_segments - number of segments in this bio after physical address coalescing is performed.
 *  @size      - total size in bytes
 *  @bdev      - target block device
 *  @bdev_contains - points to the device object which contains the partition (when bio structure represents a partition)
 *  @p_start_sect -  points to the start sector of the partition structure of the device
 *
 * Context :
 *	The process creating a block IO request.
 */
probe ioblock_trace.bounce = kernel.trace("block_bio_bounce")
{
	name = "ioblock_trace.bounce"
	q = $q
        devname = __bio_devname($bio)
        ino = __bio_ino($bio)

        bytes_done = $bio->bi_size
        sector = $bio->bi_sector
        flags = $bio->bi_flags
        rw = $bio->bi_rw
        vcnt = $bio->bi_vcnt
        idx = $bio->bi_idx
        phys_segments = $bio->bi_phys_segments
        size = $bio->bi_size
        bdev_contains = $bio->bi_bdev->bd_contains
        bdev = $bio->bi_bdev
        p_start_sect = __bio_start_sect($bio)
}

/**
 * probe ioblock_trace.request - Fires just as a generic block I/O request is created for a bio.
 *
 *  @name      - name of the probe point
 *  @q         - request queue on which this bio was queued.
 *  @devname   - block device name
 *  @ino       - i-node number of the mapped file
 *  @bytes_done - number of bytes transferred
 *  @sector    - beginning sector for the entire bio
 *  @flags     - see below
 *	BIO_UPTODATE    0       ok after I/O completion
 *	BIO_RW_BLOCK    1       RW_AHEAD set, and read/write would block
 *	BIO_EOF         2       out-out-bounds error
 *	BIO_SEG_VALID   3       nr_hw_seg valid
 *	BIO_CLONED      4       doesn't own data
 *	BIO_BOUNCED     5       bio is a bounce bio
 *	BIO_USER_MAPPED 6       contains user pages
 *	BIO_EOPNOTSUPP  7       not supported
 *
 *  @rw        - binary trace for read/write request
 *  @vcnt      - bio vector count which represents number of array element (page, offset, length) which make up this I/O request
 *  @idx       - offset into the bio vector array
 *  @phys_segments - number of segments in this bio after physical address coalescing is performed.
 *  @size      - total size in bytes
 *  @bdev      - target block device
 *  @bdev_contains - points to the device object which contains the partition (when bio structure represents a partition)
 *  @p_start_sect -  points to the start sector of the partition structure of the device
 *
 * Context:
 *  The process makes block I/O request
 */

probe ioblock_trace.request = kernel.trace("block_bio_queue")
{
	name = "ioblock_trace.request"
	q = $q
        devname = __bio_devname($bio)
        ino = __bio_ino($bio)

        bytes_done = $bio->bi_size
        sector = $bio->bi_sector
        flags = $bio->bi_flags
        rw = $bio->bi_rw
        vcnt = $bio->bi_vcnt
        idx = $bio->bi_idx
        phys_segments = $bio->bi_phys_segments
        size = $bio->bi_size
        bdev_contains = $bio->bi_bdev->bd_contains
        bdev = $bio->bi_bdev
        p_start_sect = __bio_start_sect($bio)
}

/**
 * probe ioblock_trace.end - Fires whenever a block I/O transfer is complete.
 *
 *  @name      - name of the probe point
 *  @q         - request queue on which this bio was queued.
 *  @devname   - block device name
 *  @ino       - i-node number of the mapped file
 *  @bytes_done - number of bytes transferred
 *  @sector    - beginning sector for the entire bio
 *  @flags     - see below
 *      BIO_UPTODATE    0       ok after I/O completion
 *      BIO_RW_BLOCK    1       RW_AHEAD set, and read/write would block
 *      BIO_EOF         2       out-out-bounds error
 *      BIO_SEG_VALID   3       nr_hw_seg valid
 *      BIO_CLONED      4       doesn't own data
 *      BIO_BOUNCED     5       bio is a bounce bio
 *      BIO_USER_MAPPED 6       contains user pages
 *      BIO_EOPNOTSUPP  7       not supported
 *
 *  @rw        - binary trace for read/write request
 *  @vcnt      - bio vector count which represents number of array element (page, offset, length) which makes up this I/O request
 *  @idx       - offset into the bio vector array
 *  @phys_segments - number of segments in this bio after physical address coalescing is performed.
 *  @size      - total size in bytes
 *  @bdev      - target block device
 *  @bdev_contains - points to the device object which contains the partition (when bio structure represents a partition)
 *  @p_start_sect -  points to the start sector of the partition structure of the device
 *
 * Context:
 *  The process signals the transfer is done.
 */
probe ioblock_trace.end = kernel.trace("block_bio_complete")
{
	name = "ioblock_trace.end"
	q = $q
        devname = __bio_devname($bio)
        ino = __bio_ino($bio)

        bytes_done = $bio->bi_size

        sector = $bio->bi_sector
        flags = $bio->bi_flags
        rw = $bio->bi_rw
        vcnt = $bio->bi_vcnt
        idx = $bio->bi_idx
        phys_segments = $bio->bi_phys_segments
        size = $bio->bi_size
        bdev_contains = $bio->bi_bdev->bd_contains
        bdev = $bio->bi_bdev
        p_start_sect = __bio_start_sect($bio)
}