Commit 8b4a503d authored by Mauro Carvalho Chehab's avatar Mauro Carvalho Chehab Committed by Heiko Carstens

docs: s390: convert docs to ReST and rename to *.rst

Convert all text files with s390 documentation to ReST format.

Tried to preserve as much as possible the original document
format. Still, some of the files required some work in order
for it to be visible on both plain text and after converted
to html.

The conversion is actually:
  - add blank lines and identation in order to identify paragraphs;
  - fix tables markups;
  - add some lists markups;
  - mark literal blocks;
  - adjust title markups.

At its new index.rst, let's add a :orphan: while this is not linked to
the main index.rst file, in order to avoid build warnings.
Signed-off-by: default avatarMauro Carvalho Chehab <mchehab+samsung@kernel.org>
Signed-off-by: default avatarHeiko Carstens <heiko.carstens@de.ibm.com>
parent dc3988f4
......@@ -478,7 +478,7 @@
others).
ccw_timeout_log [S390]
See Documentation/s390/CommonIO for details.
See Documentation/s390/common_io.rst for details.
cgroup_disable= [KNL] Disable a particular controller
Format: {name of the controller(s) to disable}
......@@ -516,7 +516,7 @@
/selinux/checkreqprot.
cio_ignore= [S390]
See Documentation/s390/CommonIO for details.
See Documentation/s390/common_io.rst for details.
clk_ignore_unused
[CLK]
Prevents the clock framework from automatically gating
......
......@@ -27,7 +27,7 @@ not strictly considered I/O devices. They are considered here as well,
although they are not the focus of this document.
Some additional information can also be found in the kernel source under
Documentation/s390/driver-model.txt.
Documentation/s390/driver-model.rst.
The css bus
===========
......@@ -38,7 +38,7 @@ into several categories:
* Standard I/O subchannels, for use by the system. They have a child
device on the ccw bus and are described below.
* I/O subchannels bound to the vfio-ccw driver. See
Documentation/s390/vfio-ccw.txt.
Documentation/s390/vfio-ccw.rst.
* Message subchannels. No Linux driver currently exists.
* CHSC subchannels (at most one). The chsc subchannel driver can be used
to send asynchronous chsc commands.
......
===============================
IBM 3270 Display System support
===============================
This file describes the driver that supports local channel attachment
of IBM 3270 devices. It consists of three sections:
* Introduction
* Installation
* Operation
INTRODUCTION.
Introduction
============
This paper describes installing and operating 3270 devices under
Linux/390. A 3270 device is a block-mode rows-and-columns terminal of
......@@ -17,12 +21,12 @@ twenty and thirty years ago.
You may have 3270s in-house and not know it. If you're using the
VM-ESA operating system, define a 3270 to your virtual machine by using
the command "DEF GRAF <hex-address>" This paper presumes you will be
defining four 3270s with the CP/CMS commands
defining four 3270s with the CP/CMS commands:
DEF GRAF 620
DEF GRAF 621
DEF GRAF 622
DEF GRAF 623
- DEF GRAF 620
- DEF GRAF 621
- DEF GRAF 622
- DEF GRAF 623
Your network connection from VM-ESA allows you to use x3270, tn3270, or
another 3270 emulator, started from an xterm window on your PC or
......@@ -34,7 +38,8 @@ This paper covers installation of the driver and operation of a
dialed-in x3270.
INSTALLATION.
Installation
============
You install the driver by installing a patch, doing a kernel build, and
running the configuration script (config3270.sh, in this directory).
......@@ -59,13 +64,15 @@ Use #CP TERM CONMODE 3270 to change it to 3270. If you generate only
at boot time to a 3270 if it is a 3215.
In brief, these are the steps:
1. Install the tub3270 patch
2. (If a module) add a line to a file in /etc/modprobe.d/*.conf
2. (If a module) add a line to a file in `/etc/modprobe.d/*.conf`
3. (If VM) define devices with DEF GRAF
4. Reboot
5. Configure
To test that everything works, assuming VM and x3270,
1. Bring up an x3270 window.
2. Use the DIAL command in that window.
3. You should immediately see a Linux login screen.
......@@ -74,7 +81,8 @@ Here are the installation steps in detail:
1. The 3270 driver is a part of the official Linux kernel
source. Build a tree with the kernel source and any necessary
patches. Then do
patches. Then do::
make oldconfig
(If you wish to disable 3215 console support, edit
.config; change CONFIG_TN3215's value to "n";
......@@ -84,20 +92,22 @@ Here are the installation steps in detail:
make modules_install
2. (Perform this step only if you have configured tub3270 as a
module.) Add a line to a file /etc/modprobe.d/*.conf to automatically
module.) Add a line to a file `/etc/modprobe.d/*.conf` to automatically
load the driver when it's needed. With this line added, you will see
login prompts appear on your 3270s as soon as boot is complete (or
with emulated 3270s, as soon as you dial into your vm guest using the
command "DIAL <vmguestname>"). Since the line-mode major number is
227, the line to add should be:
227, the line to add should be::
alias char-major-227 tub3270
3. Define graphic devices to your vm guest machine, if you
haven't already. Define them before you reboot (reipl):
DEFINE GRAF 620
DEFINE GRAF 621
DEFINE GRAF 622
DEFINE GRAF 623
- DEFINE GRAF 620
- DEFINE GRAF 621
- DEFINE GRAF 622
- DEFINE GRAF 623
4. Reboot. The reboot process scans hardware devices, including
3270s, and this enables the tub3270 driver once loaded to respond
......@@ -113,7 +123,8 @@ Here are the installation steps in detail:
changes to /etc/inittab.
Then notify /sbin/init that /etc/inittab has changed, by issuing
the telinit command with the q operand:
the telinit command with the q operand::
cd Documentation/s390
sh config3270.sh
sh /tmp/mkdev3270
......@@ -121,7 +132,8 @@ Here are the installation steps in detail:
This should be sufficient for your first time. If your 3270
configuration has changed and you're reusing config3270, you
should follow these steps:
should follow these steps::
Change 3270 configuration
Reboot
Run config3270 and /tmp/mkdev3270
......@@ -132,8 +144,10 @@ Here are the testing steps in detail:
1. Bring up an x3270 window, or use an actual hardware 3278 or
3279, or use the 3270 emulator of your choice. You would be
running the emulator on your PC or workstation. You would use
the command, for example,
the command, for example::
x3270 vm-esa-domain-name &
if you wanted a 3278 Model 4 with 43 rows of 80 columns, the
default model number. The driver does not take advantage of
extended attributes.
......@@ -144,7 +158,8 @@ Here are the testing steps in detail:
2. Use the DIAL command instead of the LOGIN command to connect
to one of the virtual 3270s you defined with the DEF GRAF
commands:
commands::
dial my-vm-guest-name
3. You should immediately see a login prompt from your
......@@ -171,14 +186,17 @@ Here are the testing steps in detail:
Wrong major number? Wrong minor number? There's your
problem!
D. Do you get the message
D. Do you get the message::
"HCPDIA047E my-vm-guest-name 0620 does not exist"?
If so, you must issue the command "DEF GRAF 620" from your VM
3215 console and then reboot the system.
OPERATION.
==========
The driver defines three areas on the 3270 screen: the log area, the
input area, and the status area.
......@@ -203,8 +221,10 @@ which indicates no scrolling will occur. (If you hit ENTER with "Linux
Running" and nothing typed, the application receives a newline.)
You may change the scrolling timeout value. For example, the following
command line:
command line::
echo scrolltime=60 > /proc/tty/driver/tty3270
changes the scrolling timeout value to 60 sec. Set scrolltime to 0 if
you wish to prevent scrolling entirely.
......@@ -228,7 +248,8 @@ cause an EOF also by typing "^D" and hitting ENTER.
No PF key is preassigned to cause a job suspension, but you may cause a
job suspension by typing "^Z" and hitting ENTER. You may wish to
assign this function to a PF key. To make PF7 cause job suspension,
execute the command:
execute the command::
echo pf7=^z > /proc/tty/driver/tty3270
If the input you type does not end with the two characters "^n", the
......@@ -243,8 +264,10 @@ command is entered into the stack only when the input area is not made
invisible (such as for password entry) and it is not identical to the
current top entry. PF10 rotates backward through the command stack;
PF11 rotates forward. You may assign the backward function to any PF
key (or PA key, for that matter), say, PA3, with the command:
key (or PA key, for that matter), say, PA3, with the command::
echo -e pa3=\\033k > /proc/tty/driver/tty3270
This assigns the string ESC-k to PA3. Similarly, the string ESC-j
performs the forward function. (Rationale: In bash with vi-mode line
editing, ESC-k and ESC-j retrieve backward and forward history.
......@@ -252,15 +275,19 @@ Suggestions welcome.)
Is a stack size of twenty commands not to your liking? Change it on
the fly. To change to saving the last 100 commands, execute the
command:
command::
echo recallsize=100 > /proc/tty/driver/tty3270
Have a command you issue frequently? Assign it to a PF or PA key! Use
the command
the command::
echo pf24="mkdir foobar; cd foobar" > /proc/tty/driver/tty3270
to execute the commands mkdir foobar and cd foobar immediately when you
hit PF24. Want to see the command line first, before you execute it?
Use the -n option of the echo command:
Use the -n option of the echo command::
echo -n pf24="mkdir foo; cd foo" > /proc/tty/driver/tty3270
......
===========================
Linux for S/390 and zSeries
===========================
Common Device Support (CDS)
Device Driver I/O Support Routines
Authors : Ingo Adlung
Cornelia Huck
Authors:
- Ingo Adlung
- Cornelia Huck
Copyright, IBM Corp. 1999-2002
Introduction
============
This document describes the common device support routines for Linux/390.
Different than other hardware architectures, ESA/390 has defined a unified
......@@ -34,11 +38,13 @@ below. Some of them implement common Linux device driver interfaces, while
some of them are ESA/390 platform specific.
Note:
In order to write a driver for S/390, you also need to look into the interface
described in Documentation/s390/driver-model.txt.
In order to write a driver for S/390, you also need to look into the interface
described in Documentation/s390/driver-model.rst.
Note for porting drivers from 2.4:
The major changes are:
* The functions use a ccw_device instead of an irq (subchannel).
* All drivers must define a ccw_driver (see driver-model.txt) and the associated
functions.
......@@ -57,10 +63,7 @@ The major changes are:
ccw_device_get_ciw()
get commands from extended sense data.
ccw_device_start()
ccw_device_start_timeout()
ccw_device_start_key()
ccw_device_start_key_timeout()
ccw_device_start(), ccw_device_start_timeout(), ccw_device_start_key(), ccw_device_start_key_timeout()
initiate an I/O request.
ccw_device_resume()
......@@ -82,12 +85,15 @@ first level interrupt handler only and does not comprise a device driver
callable interface. Instead, the functional description of do_IO() also
describes the input to the device specific interrupt handler.
Note: All explanations apply also to the 64 bit architecture s390x.
Note:
All explanations apply also to the 64 bit architecture s390x.
Common Device Support (CDS) for Linux/390 Device Drivers
========================================================
General Information
-------------------
The following chapters describe the I/O related interface routines the
Linux/390 common device support (CDS) provides to allow for device specific
......@@ -101,6 +107,7 @@ can be found in the architecture specific C header file
linux/arch/s390/include/asm/irq.h.
Overview of CDS interface concepts
----------------------------------
Different to other hardware platforms, the ESA/390 architecture doesn't define
interrupt lines managed by a specific interrupt controller and bus systems
......@@ -164,18 +171,26 @@ get_ciw() - get command information word
This call enables a device driver to get information about supported commands
from the extended SenseID data.
struct ciw *
ccw_device_get_ciw(struct ccw_device *cdev, __u32 cmd);
::
struct ciw *
ccw_device_get_ciw(struct ccw_device *cdev, __u32 cmd);
cdev - The ccw_device for which the command is to be retrieved.
cmd - The command type to be retrieved.
==== ========================================================
cdev The ccw_device for which the command is to be retrieved.
cmd The command type to be retrieved.
==== ========================================================
ccw_device_get_ciw() returns:
NULL - No extended data available, invalid device or command not found.
!NULL - The command requested.
===== ================================================================
NULL No extended data available, invalid device or command not found.
!NULL The command requested.
===== ================================================================
ccw_device_start() - Initiate I/O Request
::
ccw_device_start() - Initiate I/O Request
The ccw_device_start() routines is the I/O request front-end processor. All
device driver I/O requests must be issued using this routine. A device driver
......@@ -186,24 +201,26 @@ This description also covers the status information passed to the device
driver's interrupt handler as this is related to the rules (flags) defined
with the associated I/O request when calling ccw_device_start().
int ccw_device_start(struct ccw_device *cdev,
::
int ccw_device_start(struct ccw_device *cdev,
struct ccw1 *cpa,
unsigned long intparm,
__u8 lpm,
unsigned long flags);
int ccw_device_start_timeout(struct ccw_device *cdev,
int ccw_device_start_timeout(struct ccw_device *cdev,
struct ccw1 *cpa,
unsigned long intparm,
__u8 lpm,
unsigned long flags,
int expires);
int ccw_device_start_key(struct ccw_device *cdev,
int ccw_device_start_key(struct ccw_device *cdev,
struct ccw1 *cpa,
unsigned long intparm,
__u8 lpm,
__u8 key,
unsigned long flags);
int ccw_device_start_key_timeout(struct ccw_device *cdev,
int ccw_device_start_key_timeout(struct ccw_device *cdev,
struct ccw1 *cpa,
unsigned long intparm,
__u8 lpm,
......@@ -211,63 +228,73 @@ int ccw_device_start_key_timeout(struct ccw_device *cdev,
unsigned long flags,
int expires);
cdev : ccw_device the I/O is destined for
cpa : logical start address of channel program
user_intparm : user specific interrupt information; will be presented
============= =============================================================
cdev ccw_device the I/O is destined for
cpa logical start address of channel program
user_intparm user specific interrupt information; will be presented
back to the device driver's interrupt handler. Allows a
device driver to associate the interrupt with a
particular I/O request.
lpm : defines the channel path to be used for a specific I/O
lpm defines the channel path to be used for a specific I/O
request. A value of 0 will make cio use the opm.
key : the storage key to use for the I/O (useful for operating on a
key the storage key to use for the I/O (useful for operating on a
storage with a storage key != default key)
flag : defines the action to be performed for I/O processing
expires : timeout value in jiffies. The common I/O layer will terminate
flag defines the action to be performed for I/O processing
expires timeout value in jiffies. The common I/O layer will terminate
the running program after this and call the interrupt handler
with ERR_PTR(-ETIMEDOUT) as irb.
============= =============================================================
Possible flag values are :
Possible flag values are:
DOIO_ALLOW_SUSPEND - channel program may become suspended
DOIO_DENY_PREFETCH - don't allow for CCW prefetch; usually
========================= =============================================
DOIO_ALLOW_SUSPEND channel program may become suspended
DOIO_DENY_PREFETCH don't allow for CCW prefetch; usually
this implies the channel program might
become modified
DOIO_SUPPRESS_INTER - don't call the handler on intermediate status
DOIO_SUPPRESS_INTER don't call the handler on intermediate status
========================= =============================================
The cpa parameter points to the first format 1 CCW of a channel program :
The cpa parameter points to the first format 1 CCW of a channel program::
struct ccw1 {
struct ccw1 {
__u8 cmd_code;/* command code */
__u8 flags; /* flags, like IDA addressing, etc. */
__u16 count; /* byte count */
__u32 cda; /* data address */
} __attribute__ ((packed,aligned(8)));
} __attribute__ ((packed,aligned(8)));
with the following CCW flags values defined :
with the following CCW flags values defined:
CCW_FLAG_DC - data chaining
CCW_FLAG_CC - command chaining
CCW_FLAG_SLI - suppress incorrect length
CCW_FLAG_SKIP - skip
CCW_FLAG_PCI - PCI
CCW_FLAG_IDA - indirect addressing
CCW_FLAG_SUSPEND - suspend
=================== =========================
CCW_FLAG_DC data chaining
CCW_FLAG_CC command chaining
CCW_FLAG_SLI suppress incorrect length
CCW_FLAG_SKIP skip
CCW_FLAG_PCI PCI
CCW_FLAG_IDA indirect addressing
CCW_FLAG_SUSPEND suspend
=================== =========================
Via ccw_device_set_options(), the device driver may specify the following
options for the device:
DOIO_EARLY_NOTIFICATION - allow for early interrupt notification
DOIO_REPORT_ALL - report all interrupt conditions
========================= ======================================
DOIO_EARLY_NOTIFICATION allow for early interrupt notification
DOIO_REPORT_ALL report all interrupt conditions
========================= ======================================
The ccw_device_start() function returns :
The ccw_device_start() function returns:
0 - successful completion or request successfully initiated
-EBUSY - The device is currently processing a previous I/O request, or there is
======== ======================================================================
0 successful completion or request successfully initiated
-EBUSY The device is currently processing a previous I/O request, or there is
a status pending at the device.
-ENODEV - cdev is invalid, the device is not operational or the ccw_device is
-ENODEV cdev is invalid, the device is not operational or the ccw_device is
not online.
======== ======================================================================
When the I/O request completes, the CDS first level interrupt handler will
accumulate the status in a struct irb and then call the device interrupt handler.
......@@ -282,9 +309,11 @@ never started, even though ccw_device_start() returned with successful completio
The irb may contain an error value, and the device driver should check for this
first:
-ETIMEDOUT: the common I/O layer terminated the request after the specified
========== =================================================================
-ETIMEDOUT the common I/O layer terminated the request after the specified
timeout value
-EIO: the common I/O layer terminated the request due to an error state
-EIO the common I/O layer terminated the request due to an error state
========== =================================================================
If the concurrent sense flag in the extended status word (esw) in the irb is
set, the field erw.scnt in the esw describes the number of device specific
......@@ -294,6 +323,7 @@ sensing by the device driver itself is required.
The device interrupt handler can use the following definitions to investigate
the primary unit check source coded in sense byte 0 :
======================= ====
SNS0_CMD_REJECT 0x80
SNS0_INTERVENTION_REQ 0x40
SNS0_BUS_OUT_CHECK 0x20
......@@ -301,36 +331,41 @@ SNS0_EQUIPMENT_CHECK 0x10
SNS0_DATA_CHECK 0x08
SNS0_OVERRUN 0x04
SNS0_INCOMPL_DOMAIN 0x01
======================= ====
Depending on the device status, multiple of those values may be set together.
Please refer to the device specific documentation for details.
The irb->scsw.cstat field provides the (accumulated) subchannel status :
SCHN_STAT_PCI - program controlled interrupt
SCHN_STAT_INCORR_LEN - incorrect length
SCHN_STAT_PROG_CHECK - program check
SCHN_STAT_PROT_CHECK - protection check
SCHN_STAT_CHN_DATA_CHK - channel data check
SCHN_STAT_CHN_CTRL_CHK - channel control check
SCHN_STAT_INTF_CTRL_CHK - interface control check
SCHN_STAT_CHAIN_CHECK - chaining check
========================= ============================
SCHN_STAT_PCI program controlled interrupt
SCHN_STAT_INCORR_LEN incorrect length
SCHN_STAT_PROG_CHECK program check
SCHN_STAT_PROT_CHECK protection check
SCHN_STAT_CHN_DATA_CHK channel data check
SCHN_STAT_CHN_CTRL_CHK channel control check
SCHN_STAT_INTF_CTRL_CHK interface control check
SCHN_STAT_CHAIN_CHECK chaining check
========================= ============================
The irb->scsw.dstat field provides the (accumulated) device status :
DEV_STAT_ATTENTION - attention
DEV_STAT_STAT_MOD - status modifier
DEV_STAT_CU_END - control unit end
DEV_STAT_BUSY - busy
DEV_STAT_CHN_END - channel end
DEV_STAT_DEV_END - device end
DEV_STAT_UNIT_CHECK - unit check
DEV_STAT_UNIT_EXCEP - unit exception
===================== =================
DEV_STAT_ATTENTION attention
DEV_STAT_STAT_MOD status modifier
DEV_STAT_CU_END control unit end
DEV_STAT_BUSY busy
DEV_STAT_CHN_END channel end
DEV_STAT_DEV_END device end
DEV_STAT_UNIT_CHECK unit check
DEV_STAT_UNIT_EXCEP unit exception
===================== =================
Please see the ESA/390 Principles of Operation manual for details on the
individual flag meanings.
Usage Notes :
Usage Notes:
ccw_device_start() must be called disabled and with the ccw device lock held.
......@@ -387,19 +422,26 @@ setting the CCW suspend flag on a particular CCW, the channel program execution
is suspended. In order to resume channel program execution the CIO layer
provides the ccw_device_resume() routine.
int ccw_device_resume(struct ccw_device *cdev);
::
cdev - ccw_device the resume operation is requested for
int ccw_device_resume(struct ccw_device *cdev);
==== ================================================
cdev ccw_device the resume operation is requested for
==== ================================================
The ccw_device_resume() function returns:
0 - suspended channel program is resumed
-EBUSY - status pending
-ENODEV - cdev invalid or not-operational subchannel
-EINVAL - resume function not applicable
-ENOTCONN - there is no I/O request pending for completion
========= ==============================================
0 suspended channel program is resumed
-EBUSY status pending
-ENODEV cdev invalid or not-operational subchannel
-EINVAL resume function not applicable
-ENOTCONN there is no I/O request pending for completion
========= ==============================================
Usage Notes:
Please have a look at the ccw_device_start() usage notes for more details on
suspended channel programs.
......@@ -412,22 +454,28 @@ command is provided.
ccw_device_halt() must be called disabled and with the ccw device lock held.
int ccw_device_halt(struct ccw_device *cdev,
::
int ccw_device_halt(struct ccw_device *cdev,
unsigned long intparm);
cdev : ccw_device the halt operation is requested for
intparm : interruption parameter; value is only used if no I/O
======= =====================================================
cdev ccw_device the halt operation is requested for
intparm interruption parameter; value is only used if no I/O
is outstanding, otherwise the intparm associated with
the I/O request is returned
======= =====================================================
The ccw_device_halt() function returns :
The ccw_device_halt() function returns:
0 - request successfully initiated
-EBUSY - the device is currently busy, or status pending.
-ENODEV - cdev invalid.
-EINVAL - The device is not operational or the ccw device is not online.
======= ==============================================================
0 request successfully initiated
-EBUSY the device is currently busy, or status pending.
-ENODEV cdev invalid.
-EINVAL The device is not operational or the ccw device is not online.
======= ==============================================================
Usage Notes :
Usage Notes:
A device driver may write a never-ending channel program by writing a channel
program that at its end loops back to its beginning by means of a transfer in
......@@ -438,25 +486,34 @@ can then perform an appropriate action. Prior to interrupt of an outstanding
read to a network device (with or without PCI flag) a ccw_device_halt()
is required to end the pending operation.
ccw_device_clear() - Terminage I/O Request Processing
::
ccw_device_clear() - Terminage I/O Request Processing
In order to terminate all I/O processing at the subchannel, the clear subchannel
(CSCH) command is used. It can be issued via ccw_device_clear().
ccw_device_clear() must be called disabled and with the ccw device lock held.
int ccw_device_clear(struct ccw_device *cdev, unsigned long intparm);
::
int ccw_device_clear(struct ccw_device *cdev, unsigned long intparm);
cdev: ccw_device the clear operation is requested for
intparm: interruption parameter (see ccw_device_halt())
======= ===============================================
cdev ccw_device the clear operation is requested for
intparm interruption parameter (see ccw_device_halt())
======= ===============================================
The ccw_device_clear() function returns:
0 - request successfully initiated
-ENODEV - cdev invalid
-EINVAL - The device is not operational or the ccw device is not online.
======= ==============================================================
0 request successfully initiated
-ENODEV cdev invalid
-EINVAL The device is not operational or the ccw device is not online.
======= ==============================================================
Miscellaneous Support Routines
------------------------------
This chapter describes various routines to be used in a Linux/390 device
driver programming environment.
......@@ -466,7 +523,8 @@ get_ccwdev_lock()
Get the address of the device specific lock. This is then used in
spin_lock() / spin_unlock() calls.
::
__u8 ccw_device_get_path_mask(struct ccw_device *cdev);
__u8 ccw_device_get_path_mask(struct ccw_device *cdev);
Get the mask of the path currently available for cdev.
S/390 common I/O-Layer - command line parameters, procfs and debugfs entries
============================================================================
======================
S/390 common I/O-Layer
======================
command line parameters, procfs and debugfs entries
===================================================
Command line parameters
-----------------------
......@@ -28,14 +32,20 @@ Command line parameters
keywords can be used to refer to the CCW based boot device and CCW console
device respectively (these are probably useful only when combined with the '!'
operator). The '!' operator will cause the I/O-layer to _not_ ignore a device.
The command line is parsed from left to right.
The command line
is parsed from left to right.
For example::
For example,
cio_ignore=0.0.0023-0.0.0042,0.0.4711
will ignore all devices ranging from 0.0.0023 to 0.0.0042 and the device
0.0.4711, if detected.
As another example,
As another example::
cio_ignore=all,!0.0.4711,!0.0.fd00-0.0.fd02
will ignore all devices but 0.0.4711, 0.0.fd00, 0.0.fd01, 0.0.fd02.
By default, no devices are ignored.
......@@ -54,6 +64,7 @@ Command line parameters
devices.
For example, if devices 0.0.0023 to 0.0.0042 and 0.0.4711 are ignored,
- echo free 0.0.0030-0.0.0032 > /proc/cio_ignore
will un-ignore devices 0.0.0030 to 0.0.0032 and will leave devices 0.0.0023
to 0.0.002f, 0.0.0033 to 0.0.0042 and 0.0.4711 ignored;
......@@ -75,13 +86,17 @@ Command line parameters
disappears and then reappears, it will then be ignored. To make
known devices go away, you need the "purge" command (see below).
For example,
For example::
"echo add 0.0.a000-0.0.accc, 0.0.af00-0.0.afff > /proc/cio_ignore"
will add 0.0.a000-0.0.accc and 0.0.af00-0.0.afff to the list of ignored
devices.
You can remove already known but now ignored devices via
You can remove already known but now ignored devices via::
"echo purge > /proc/cio_ignore"
All devices ignored but still registered and not online (= not in use)
will be deregistered and thus removed from the system.
......@@ -121,5 +136,5 @@ debugfs entries
The level of logging can be changed to be more or less verbose by piping to
/sys/kernel/debug/s390dbf/cio_*/level a number between 0 and 6; see the
documentation on the S/390 debug feature (Documentation/s390/s390dbf.txt)
documentation on the S/390 debug feature (Documentation/s390/s390dbf.rst)
for details.
==================
DASD device driver
==================
S/390's disk devices (DASDs) are managed by Linux via the DASD device
driver. It is valid for all types of DASDs and represents them to
......@@ -34,19 +36,22 @@ accessibility of the DASD from other OSs. In a later stage we will
provide support of partitions, maybe VTOC oriented or using a kind of
partition table in the label record.
USAGE
Usage
=====
-Low-level format (?CKD only)
For using an ECKD-DASD as a Linux harddisk you have to low-level
format the tracks by issuing the BLKDASDFORMAT-ioctl on that
device. This will erase any data on that volume including IBM volume
labels, VTOCs etc. The ioctl may take a 'struct format_data *' or
'NULL' as an argument.
typedef struct {
labels, VTOCs etc. The ioctl may take a `struct format_data *` or
'NULL' as an argument::
typedef struct {
int start_unit;
int stop_unit;
int blksize;
} format_data_t;
} format_data_t;
When a NULL argument is passed to the BLKDASDFORMAT ioctl the whole
disk is formatted to a blocksize of 1024 bytes. Otherwise start_unit
and stop_unit are the first and last track to be formatted. If
......@@ -56,17 +61,23 @@ up to the last track. blksize can be any power of two between 512 and
1kB blocks anyway and you gain approx. 50% of capacity increasing your
blksize from 512 byte to 1kB.
-Make a filesystem
Make a filesystem
=================
Then you can mk??fs the filesystem of your choice on that volume or
partition. For reasons of sanity you should build your filesystem on
the partition /dev/dd?1 instead of the whole volume. You only lose 3kB
but may be sure that you can reuse your data after introduction of a
real partition table.
BUGS:
Bugs
====
- Performance sometimes is rather low because we don't fully exploit clustering
TODO-List:
TODO-List
=========
- Add IBM'S Disk layout to genhd
- Enhance driver to use more than one major number
- Enable usage as a module
......
=============================================
Debugging on Linux for s/390 & z/Architecture
=============================================
Debugging on Linux for s/390 & z/Architecture
by
Denis Joseph Barrow (djbarrow@de.ibm.com,barrow_dj@yahoo.com)
Copyright (C) 2000-2001 IBM Deutschland Entwicklung GmbH, IBM Corporation
Best viewed with fixed width fonts
Denis Joseph Barrow (djbarrow@de.ibm.com,barrow_dj@yahoo.com)
Copyright (C) 2000-2001 IBM Deutschland Entwicklung GmbH, IBM Corporation
.. Best viewed with fixed width fonts
Overview of Document:
=====================
......@@ -17,27 +20,27 @@ It is intended like the Enterprise Systems Architecture/390 Reference Summary
to be printed out & used as a quick cheat sheet self help style reference when
problems occur.
Contents
========
Register Set
Address Spaces on Intel Linux
Address Spaces on Linux for s/390 & z/Architecture
The Linux for s/390 & z/Architecture Kernel Task Structure
Register Usage & Stackframes on Linux for s/390 & z/Architecture
A sample program with comments
Compiling programs for debugging on Linux for s/390 & z/Architecture
Debugging under VM
s/390 & z/Architecture IO Overview
Debugging IO on s/390 & z/Architecture under VM
GDB on s/390 & z/Architecture
Stack chaining in gdb by hand
Examining core dumps
ldd
Debugging modules
The proc file system
SysRq
References
Special Thanks
.. Contents
========
Register Set
Address Spaces on Intel Linux
Address Spaces on Linux for s/390 & z/Architecture
The Linux for s/390 & z/Architecture Kernel Task Structure
Register Usage & Stackframes on Linux for s/390 & z/Architecture
A sample program with comments
Compiling programs for debugging on Linux for s/390 & z/Architecture
Debugging under VM
s/390 & z/Architecture IO Overview
Debugging IO on s/390 & z/Architecture under VM
GDB on s/390 & z/Architecture
Stack chaining in gdb by hand
Examining core dumps
ldd
Debugging modules
The proc file system
SysRq
References
Special Thanks
Register Set
============
......@@ -59,12 +62,14 @@ Access register 0 (and access register 1 on z/Architecture, which needs a
64 bit pointer) is currently used by the pthread library as a pointer to
the current running threads private area.
16 64 bit floating point registers (fp0-fp15 ) IEEE & HFP floating
16 64-bit floating point registers (fp0-fp15 ) IEEE & HFP floating
point format compliant on G5 upwards & a Floating point control reg (FPC)
4 64 bit registers (fp0,fp2,fp4 & fp6) HFP only on older machines.
4 64-bit registers (fp0,fp2,fp4 & fp6) HFP only on older machines.
Note:
Linux (currently) always uses IEEE & emulates G5 IEEE format on older machines,
( provided the kernel is configured for this ).
Linux (currently) always uses IEEE & emulates G5 IEEE format on older
machines, ( provided the kernel is configured for this ).
The PSW is the most important register on the machine it
......@@ -206,14 +211,18 @@ It exists between the real addresses 0-4096 on s/390 and between 0-8192 on
z/Architecture and is exchanged with one page on s/390 or two pages on
z/Architecture in absolute storage by the set prefix instruction during Linux
startup.
This page is mapped to a different prefix for each processor in an SMP
configuration (assuming the OS designer is sane of course).
Bytes 0-512 (200 hex) on s/390 and 0-512, 4096-4544, 4604-5119 currently on
z/Architecture are used by the processor itself for holding such information
as exception indications and entry points for exceptions.
Bytes after 0xc00 hex are used by linux for per processor globals on s/390 and
z/Architecture (there is a gap on z/Architecture currently between 0xc00 and
0x1000, too, which is used by Linux).
The closest thing to this on traditional architectures is the interrupt
vector table. This is a good thing & does simplify some of the kernel coding
however it means that we now cannot catch stray NULL pointers in the
......@@ -225,14 +234,15 @@ Address Spaces on Intel Linux
=============================
The traditional Intel Linux is approximately mapped as follows forgive
the ascii art.
0xFFFFFFFF 4GB Himem *****************
the ascii art::
0xFFFFFFFF 4GB Himem *****************
* *
* Kernel Space *
* *
***************** ****************
User Space Himem * User Stack * * *
(typically 0xC0000000 3GB ) ***************** * *
User Space Himem * User Stack * * *
(typically 0xC0000000 3GB ) ***************** * *
* Shared Libs * * Next Process *
***************** * to *
* * <== * Run * <==
......@@ -240,12 +250,13 @@ User Space Himem * User Stack * * *
* Data BSS * * *
* Text * * *
* Sections * * *
0x00000000 ***************** ****************
0x00000000 ***************** ****************
Now it is easy to see that on Intel it is quite easy to recognise a kernel
address as being one greater than user space himem (in this case 0xC0000000),
and addresses of less than this are the ones in the current running program on
this processor (if an smp box).
If using the virtual machine ( VM ) as a debugger it is quite difficult to
know which user process is running as the address space you are looking at
could be from any process in the run queue.
......@@ -256,6 +267,7 @@ of Real Address=Virtual Address-User Space Himem.
This means that on Intel the kernel linux can typically only address
Himem=0xFFFFFFFF-0xC0000000=1GB & this is all the RAM these machines
can typically use.
They can lower User Himem to 2GB or lower & thus be
able to use 2GB of RAM however this shrinks the maximum size
of User Space from 3GB to 2GB they have a no win limit of 4GB unless
......@@ -275,12 +287,12 @@ currently 4TB of physical memory currently on z/Architecture.
Address Spaces on Linux for s/390 & z/Architecture
==================================================
Our addressing scheme is basically as follows:
Our addressing scheme is basically as follows::
Primary Space Home Space
Himem 0x7fffffff 2GB on s/390 ***************** ****************
currently 0x3ffffffffff (2^42)-1 * User Stack * * *
on z/Architecture. ***************** * *
Himem 0x7fffffff 2GB on s/390 ***************** ****************
currently 0x3ffffffffff (2^42)-1 * User Stack * * *
on z/Architecture. ***************** * *
* Shared Libs * * *
***************** * *
* * * Kernel *
......@@ -288,7 +300,7 @@ on z/Architecture. ***************** * *
* Data BSS * * *
* Text * * *
* Sections * * *
0x00000000 ***************** ****************
0x00000000 ***************** ****************
This also means that we need to look at the PSW problem state bit and the
addressing mode to decide whether we are looking at user or kernel space.
......@@ -304,20 +316,25 @@ instruction on a user space address is performed.
When also looking at the ASCE control registers, this means:
User space:
- runs in primary or access register mode
- cr1 contains the user asce
- cr7 contains the user asce
- cr13 contains the kernel asce
Kernel space:
- runs in home space mode
- cr1 contains the user or kernel asce
-> the kernel asce is loaded when a uaccess requires primary or
- the kernel asce is loaded when a uaccess requires primary or
secondary address mode
- cr7 contains the user or kernel asce, (changed with set_fs())
- cr13 contains the kernel asce
In case of uaccess the kernel changes to:
- primary space mode in case of a uaccess (copy_to_user) and uses
e.g. the mvcp instruction to access user space. However the kernel
will stay in home space mode if the mvcos instruction is available
......@@ -337,40 +354,43 @@ Virtual Addresses on s/390 & z/Architecture
A virtual address on s/390 is made up of 3 parts
The SX (segment index, roughly corresponding to the PGD & PMD in Linux
terminology) being bits 1-11.
The PX (page index, corresponding to the page table entry (pte) in Linux
terminology) being bits 12-19.
The remaining bits BX (the byte index are the offset in the page )
i.e. bits 20 to 31.
On z/Architecture in linux we currently make up an address from 4 parts.
The region index bits (RX) 0-32 we currently use bits 22-32
The segment index (SX) being bits 33-43
The page index (PX) being bits 44-51
The byte index (BX) being bits 52-63
- The region index bits (RX) 0-32 we currently use bits 22-32
- The segment index (SX) being bits 33-43
- The page index (PX) being bits 44-51
- The byte index (BX) being bits 52-63
Notes:
1) s/390 has no PMD so the PMD is really the PGD also.
A lot of this stuff is defined in pgtable.h.
2) Also seeing as s/390's page indexes are only 1k in size
(bits 12-19 x 4 bytes per pte ) we use 1 ( page 4k )
to make the best use of memory by updating 4 segment indices
entries each time we mess with a PMD & use offsets
0,1024,2048 & 3072 in this page as for our segment indexes.
On z/Architecture our page indexes are now 2k in size
( bits 12-19 x 8 bytes per pte ) we do a similar trick
but only mess with 2 segment indices each time we mess with
a PMD.
3) As z/Architecture supports up to a massive 5-level page table lookup we
can only use 3 currently on Linux ( as this is all the generic kernel
currently supports ) however this may change in future
this allows us to access ( according to my sums )
4TB of virtual storage per process i.e.
4096*512(PTES)*1024(PMDS)*2048(PGD) = 4398046511104 bytes,
enough for another 2 or 3 of years I think :-).
to do this we use a region-third-table designation type in
our address space control registers.
1) s/390 has no PMD so the PMD is really the PGD also.
A lot of this stuff is defined in pgtable.h.
2) Also seeing as s/390's page indexes are only 1k in size
(bits 12-19 x 4 bytes per pte ) we use 1 ( page 4k )
to make the best use of memory by updating 4 segment indices
entries each time we mess with a PMD & use offsets
0,1024,2048 & 3072 in this page as for our segment indexes.
On z/Architecture our page indexes are now 2k in size
( bits 12-19 x 8 bytes per pte ) we do a similar trick
but only mess with 2 segment indices each time we mess with
a PMD.
3) As z/Architecture supports up to a massive 5-level page table lookup we
can only use 3 currently on Linux ( as this is all the generic kernel
currently supports ) however this may change in future
this allows us to access ( according to my sums )
4TB of virtual storage per process i.e.
4096*512(PTES)*1024(PMDS)*2048(PGD) = 4398046511104 bytes,
enough for another 2 or 3 of years I think :-).
to do this we use a region-third-table designation type in
our address space control registers.
The Linux for s/390 & z/Architecture Kernel Task Structure
......@@ -382,7 +402,7 @@ the __LC_KERNEL_STACK variable in the spare prefix area for this cpu
(which we use for per-processor globals).
The kernel stack pointer is intimately tied with the task structure for
each processor as follows.
each processor as follows::
s/390
************************
......@@ -391,7 +411,7 @@ each processor as follows.
************************
* 1 page task_struct *
* ( 4K ) *
8K aligned ************************
8K aligned ************************
z/Architecture
************************
......@@ -400,20 +420,21 @@ each processor as follows.
************************
* 2 page task_struct *
* ( 8K ) *
16K aligned ************************
16K aligned ************************
What this means is that we don't need to dedicate any register or global
variable to point to the current running process & can retrieve it with the
following very simple construct for s/390 & one very similar for z/Architecture.
following very simple construct for s/390 & one very similar for
z/Architecture::
static inline struct task_struct * get_current(void)
{
static inline struct task_struct * get_current(void)
{
struct task_struct *current;
__asm__("lhi %0,-8192\n\t"
"nr %0,15"
: "=r" (current) );
return current;
}
}
i.e. just anding the current kernel stack pointer with the mask -8192.
Thankfully because Linux doesn't have support for nested IO interrupts
......@@ -443,87 +464,95 @@ didn't have to maintain compatibility with older linkage formats.
Glossary:
---------
alloca:
This is a built in compiler function for runtime allocation
of extra space on the callers stack which is obviously freed
up on function exit ( e.g. the caller may choose to allocate nothing
of a buffer of 4k if required for temporary purposes ), it generates
very efficient code ( a few cycles ) when compared to alternatives
like malloc.
This is a built in compiler function for runtime allocation
of extra space on the callers stack which is obviously freed
up on function exit ( e.g. the caller may choose to allocate nothing
of a buffer of 4k if required for temporary purposes ), it generates
very efficient code ( a few cycles ) when compared to alternatives
like malloc.
automatics: These are local variables on the stack,
i.e they aren't in registers & they aren't static.
automatics:
These are local variables on the stack, i.e they aren't in registers &
they aren't static.
back-chain:
This is a pointer to the stack pointer before entering a
framed functions ( see frameless function ) prologue got by
dereferencing the address of the current stack pointer,
This is a pointer to the stack pointer before entering a
framed functions ( see frameless function ) prologue got by
dereferencing the address of the current stack pointer,
i.e. got by accessing the 32 bit value at the stack pointers
current location.
current location.
base-pointer:
This is a pointer to the back of the literal pool which
is an area just behind each procedure used to store constants
in each function.
This is a pointer to the back of the literal pool which
is an area just behind each procedure used to store constants
in each function.
call-clobbered: The caller probably needs to save these registers if there
is something of value in them, on the stack or elsewhere before making a
call to another procedure so that it can restore it later.
call-clobbered:
The caller probably needs to save these registers if there
is something of value in them, on the stack or elsewhere before making a
call to another procedure so that it can restore it later.
epilogue:
The code generated by the compiler to return to the caller.
frameless-function
A frameless function in Linux for s390 & z/Architecture is one which doesn't
need more than the register save area (96 bytes on s/390, 160 on z/Architecture)
given to it by the caller.
A frameless function never:
1) Sets up a back chain.
2) Calls alloca.
3) Calls other normal functions
4) Has automatics.
The code generated by the compiler to return to the caller.
frameless-function:
A frameless function in Linux for s390 & z/Architecture is one which doesn't
need more than the register save area (96 bytes on s/390, 160 on z/Architecture)
given to it by the caller.
A frameless function never:
1) Sets up a back chain.
2) Calls alloca.
3) Calls other normal functions
4) Has automatics.
GOT-pointer:
This is a pointer to the global-offset-table in ELF
( Executable Linkable Format, Linux'es most common executable format ),
all globals & shared library objects are found using this pointer.
This is a pointer to the global-offset-table in ELF
( Executable Linkable Format, Linux'es most common executable format ),
all globals & shared library objects are found using this pointer.
lazy-binding
ELF shared libraries are typically only loaded when routines in the shared
library are actually first called at runtime. This is lazy binding.
ELF shared libraries are typically only loaded when routines in the shared
library are actually first called at runtime. This is lazy binding.
procedure-linkage-table
This is a table found from the GOT which contains pointers to routines
in other shared libraries which can't be called to by easier means.
This is a table found from the GOT which contains pointers to routines
in other shared libraries which can't be called to by easier means.
prologue:
The code generated by the compiler to set up the stack frame.
The code generated by the compiler to set up the stack frame.
outgoing-args:
This is extra area allocated on the stack of the calling function if the
parameters for the callee's cannot all be put in registers, the same
area can be reused by each function the caller calls.
This is extra area allocated on the stack of the calling function if the
parameters for the callee's cannot all be put in registers, the same
area can be reused by each function the caller calls.
routine-descriptor:
A COFF executable format based concept of a procedure reference
actually being 8 bytes or more as opposed to a simple pointer to the routine.
This is typically defined as follows
Routine Descriptor offset 0=Pointer to Function
Routine Descriptor offset 4=Pointer to Table of Contents
The table of contents/TOC is roughly equivalent to a GOT pointer.
& it means that shared libraries etc. can be shared between several
environments each with their own TOC.
A COFF executable format based concept of a procedure reference
actually being 8 bytes or more as opposed to a simple pointer to the routine.
This is typically defined as follows:
- Routine Descriptor offset 0=Pointer to Function
- Routine Descriptor offset 4=Pointer to Table of Contents
static-chain: This is used in nested functions a concept adopted from pascal
by gcc not used in ansi C or C++ ( although quite useful ), basically it
is a pointer used to reference local variables of enclosing functions.
You might come across this stuff once or twice in your lifetime.
The table of contents/TOC is roughly equivalent to a GOT pointer.
& it means that shared libraries etc. can be shared between several
environments each with their own TOC.
e.g.
The function below should return 11 though gcc may get upset & toss warnings
about unused variables.
int FunctionA(int a)
{
static-chain:
This is used in nested functions a concept adopted from pascal
by gcc not used in ansi C or C++ ( although quite useful ), basically it
is a pointer used to reference local variables of enclosing functions.
You might come across this stuff once or twice in your lifetime.
e.g.
The function below should return 11 though gcc may get upset & toss warnings
about unused variables::
int FunctionA(int a)
{
int b;
FunctionC(int c)
{
......@@ -531,11 +560,13 @@ int FunctionA(int a)
}
FunctionC(10);
return(b);
}
}
s/390 & z/Architecture Register usage
=====================================
======== ========================================== ===============
r0 used by syscalls/assembly call-clobbered
r1 used by syscalls/assembly call-clobbered
r2 argument 0 / return value 0 call-clobbered
......@@ -557,45 +588,53 @@ f0 argument 0 / return value ( float/double ) call-clobbered
f2 argument 1 call-clobbered
f4 z/Architecture argument 2 saved
f6 z/Architecture argument 3 saved
======== ========================================== ===============
The remaining floating points
f1,f3,f5 f7-f15 are call-clobbered.
Notes:
------
1) The only requirement is that registers which are used
by the callee are saved, e.g. the compiler is perfectly
capable of using r11 for purposes other than a frame a
frame pointer if a frame pointer is not needed.
by the callee are saved, e.g. the compiler is perfectly
capable of using r11 for purposes other than a frame a
frame pointer if a frame pointer is not needed.
2) In functions with variable arguments e.g. printf the calling procedure
is identical to one without variable arguments & the same number of
parameters. However, the prologue of this function is somewhat more
hairy owing to it having to move these parameters to the stack to
get va_start, va_arg & va_end to work.
is identical to one without variable arguments & the same number of
parameters. However, the prologue of this function is somewhat more
hairy owing to it having to move these parameters to the stack to
get va_start, va_arg & va_end to work.
3) Access registers are currently unused by gcc but are used in
the kernel. Possibilities exist to use them at the moment for
temporary storage but it isn't recommended.
the kernel. Possibilities exist to use them at the moment for
temporary storage but it isn't recommended.
4) Only 4 of the floating point registers are used for
parameter passing as older machines such as G3 only have only 4
& it keeps the stack frame compatible with other compilers.
However with IEEE floating point emulation under linux on the
older machines you are free to use the other 12.
parameter passing as older machines such as G3 only have only 4
& it keeps the stack frame compatible with other compilers.
However with IEEE floating point emulation under linux on the
older machines you are free to use the other 12.
5) A long long or double parameter cannot be have the
first 4 bytes in a register & the second four bytes in the
outgoing args area. It must be purely in the outgoing args
area if crossing this boundary.
first 4 bytes in a register & the second four bytes in the
outgoing args area. It must be purely in the outgoing args
area if crossing this boundary.
6) Floating point parameters are mixed with outgoing args
on the outgoing args area in the order the are passed in as parameters.
on the outgoing args area in the order the are passed in as parameters.
7) Floating point arguments 2 & 3 are saved in the outgoing args area for
z/Architecture
z/Architecture
Stack Frame Layout
------------------
========= ============== ======================================================
s/390 z/Architecture
========= ============== ======================================================
0 0 back chain ( a 0 here signifies end of back chain )
4 8 eos ( end of stack, not used on Linux for S390 used in other linkage formats )
8 16 glue used in other s/390 linkage formats for saved routine descriptors etc.
12 24 glue used in other s/390 linkage formats for saved routine descriptors etc.
4 8 eos ( end of stack, not used on Linux for S390 used
in other linkage formats )
8 16 glue used in other s/390 linkage formats for saved
routine descriptors etc.
12 24 glue used in other s/390 linkage formats for saved
routine descriptors etc.
16 32 scratch area
20 40 scratch area
24 48 saved r6 of caller function
......@@ -616,6 +655,7 @@ s/390 z/Architecture
96+x+y 160+x+y alloca space of caller ( if used )
96+x+y+z 160+x+y+z automatics of caller ( if used )
0 back-chain
========= ============== ======================================================
A sample program with comments.
===============================
......@@ -623,18 +663,20 @@ A sample program with comments.
Comments on the function test
-----------------------------
1) It didn't need to set up a pointer to the constant pool gpr13 as it is not
used ( :-( ).
used ( :-( ).
2) This is a frameless function & no stack is bought.
3) The compiler was clever enough to recognise that it could return the
value in r2 as well as use it for the passed in parameter ( :-) ).
value in r2 as well as use it for the passed in parameter ( :-) ).
4) The basr ( branch relative & save ) trick works as follows the instruction
has a special case with r0,r0 with some instruction operands is understood as
the literal value 0, some risc architectures also do this ). So now
we are branching to the next address & the address new program counter is
in r13,so now we subtract the size of the function prologue we have executed
+ the size of the literal pool to get to the top of the literal pool
0040037c int test(int b)
{ # Function prologue below
has a special case with r0,r0 with some instruction operands is understood as
the literal value 0, some risc architectures also do this ). So now
we are branching to the next address & the address new program counter is
in r13,so now we subtract the size of the function prologue we have executed
the size of the literal pool to get to the top of the literal pool::
0040037c int test(int b)
{ # Function prologue below
40037c: 90 de f0 34 stm %r13,%r14,52(%r15) # Save registers r13 & r14
400380: 0d d0 basr %r13,%r0 # Set up pointer to constant pool using
400382: a7 da ff fa ahi %r13,-6 # basr trick
......@@ -645,16 +687,16 @@ in r13,so now we subtract the size of the function prologue we have executed
# Function epilogue below
40038a: 98 de f0 34 lm %r13,%r14,52(%r15) # restore registers r13 & 14
40038e: 07 fe br %r14 # return
}
}
Comments on the function main
-----------------------------
1) The compiler did this function optimally ( 8-) )
1) The compiler did this function optimally ( 8-) )::
Literal pool for main.
400390: ff ff ff ec .long 0xffffffec
main(int argc,char *argv[])
{ # Function prologue below
Literal pool for main.
400390: ff ff ff ec .long 0xffffffec
main(int argc,char *argv[])
{ # Function prologue below
400394: 90 bf f0 2c stm %r11,%r15,44(%r15) # Save necessary registers
400398: 18 0f lr %r0,%r15 # copy stack pointer to r0
40039a: a7 fa ff a0 ahi %r15,-96 # Make area for callee saving
......@@ -672,14 +714,16 @@ main(int argc,char *argv[])
# Function Epilogue below
4003b4: 98 bf f0 8c lm %r11,%r15,140(%r15)# Restore necessary registers.
4003b8: 07 fe br %r14 # return to do program exit
}
}
Compiler updates
----------------
main(int argc,char *argv[])
{
::
main(int argc,char *argv[])
{
4004fc: 90 7f f0 1c stm %r7,%r15,28(%r15)
400500: a7 d5 00 04 bras %r13,400508 <main+0xc>
400504: 00 40 04 f4 .long 0x004004f4
......@@ -698,7 +742,7 @@ main(int argc,char *argv[])
40051c: 58 40 f0 98 l %r4,152(%r15)
400520: 98 7f f0 7c lm %r7,%r15,124(%r15)
400524: 07 f4 br %r4
}
}
Hartmut ( our compiler developer ) also has been threatening to take out the
......@@ -713,10 +757,11 @@ below too so I'll avoid repeating myself & just say that
some of the instructions have g's on the end of them to indicate
they are 64 bit & the stack offsets are a bigger,
the only other difference you'll find between 32 & 64 bit is that
we now use f4 & f6 for floating point arguments on 64 bit.
00000000800005b0 <test>:
int test(int b)
{
we now use f4 & f6 for floating point arguments on 64 bit::
00000000800005b0 <test>:
int test(int b)
{
return(5+b);
800005b0: a7 2a 00 05 ahi %r2,5
800005b4: b9 14 00 22 lgfr %r2,%r2 # downcast to integer
......@@ -724,11 +769,11 @@ int test(int b)
800005ba: 07 07 bcr 0,%r7
}
}
00000000800005bc <main>:
main(int argc,char *argv[])
{
00000000800005bc <main>:
main(int argc,char *argv[])
{
800005bc: eb bf f0 58 00 24 stmg %r11,%r15,88(%r15)
800005c2: b9 04 00 1f lgr %r1,%r15
800005c6: a7 fb ff 60 aghi %r15,-160
......@@ -740,7 +785,7 @@ main(int argc,char *argv[])
800005da: e3 40 f1 10 00 04 lg %r4,272(%r15)
800005e0: eb bf f0 f8 00 04 lmg %r11,%r15,248(%r15)
800005e6: 07 f4 br %r4
}
}
......@@ -755,7 +800,7 @@ This is typically done adding/appending the flags -g or -gdwarf-2 to the
CFLAGS & LDFLAGS variables Makefile of the program concerned.
If using gdb & you would like accurate displays of registers &
stack traces compile without optimisation i.e make sure
stack traces compile without optimisation i.e make sure
that there is no -O2 or similar on the CFLAGS line of the Makefile &
the emitted gcc commands, obviously this will produce worse code
( not advisable for shipment ) but it is an aid to the debugging process.
......@@ -806,19 +851,23 @@ Also it is very easy to tell the length of a 390 instruction from the 2 most
significant bits in the instruction (not that this info is really useful except
if you are trying to make sense of a hexdump of code).
Here is a table
======================= ==================
Bits Instruction Length
------------------------------------------
======================= ==================
00 2 Bytes
01 4 Bytes
10 4 Bytes
11 6 Bytes
======================= ==================
The debugger also displays other useful info on the same line such as the
addresses being operated on destination addresses of branches & condition codes.
e.g.
00019736' AHI A7DAFF0E CC 1
000198BA' BRC A7840004 -> 000198C2' CC 0
000198CE' STM 900EF068 >> 0FA95E78 CC 2
e.g.::
00019736' AHI A7DAFF0E CC 1
000198BA' BRC A7840004 -> 000198C2' CC 0
000198CE' STM 900EF068 >> 0FA95E78 CC 2
......@@ -826,54 +875,79 @@ Useful VM debugger commands
---------------------------
I suppose I'd better mention this before I start
to list the current active traces do
Q TR
to list the current active traces do::
Q TR
there can be a maximum of 255 of these per set
( more about trace sets later ).
To stop traces issue a
TR END.
To delete a particular breakpoint issue
TR DEL <breakpoint number>
To stop traces issue a::
TR END.
To delete a particular breakpoint issue::
TR DEL <breakpoint number>
The PA1 key drops to CP mode so you can issue debugger commands,
Doing alt c (on my 3270 console at least ) clears the screen.
hitting b <enter> comes back to the running operating system
from cp mode ( in our case linux ).
It is typically useful to add shortcuts to your profile.exec file
if you have one ( this is roughly equivalent to autoexec.bat in DOS ).
file here are a few from mine.
/* this gives me command history on issuing f12 */
set pf12 retrieve
/* this continues */
set pf8 imm b
/* goes to trace set a */
set pf1 imm tr goto a
/* goes to trace set b */
set pf2 imm tr goto b
/* goes to trace set c */
set pf3 imm tr goto c
file here are a few from mine::
/* this gives me command history on issuing f12 */
set pf12 retrieve
/* this continues */
set pf8 imm b
/* goes to trace set a */
set pf1 imm tr goto a
/* goes to trace set b */
set pf2 imm tr goto b
/* goes to trace set c */
set pf3 imm tr goto c
Instruction Tracing
-------------------
Setting a simple breakpoint
TR I PSWA <address>
To debug a particular function try
TR I R <function address range>
TR I on its own will single step.
TR I DATA <MNEMONIC> <OPTIONAL RANGE> will trace for particular mnemonics
e.g.
TR I DATA 4D R 0197BC.4000
Setting a simple breakpoint::
TR I PSWA <address>
To debug a particular function try::
TR I R <function address range>
TR I on its own will single step.
TR I DATA <MNEMONIC> <OPTIONAL RANGE> will trace for particular mnemonics
e.g.::
TR I DATA 4D R 0197BC.4000
will trace for BAS'es ( opcode 4D ) in the range 0197BC.4000
if you were inclined you could add traces for all branch instructions &
suffix them with the run prefix so you would have a backtrace on screen
when a program crashes.
TR BR <INTO OR FROM> will trace branches into or out of an address.
e.g.
TR BR INTO 0 is often quite useful if a program is getting awkward & deciding
when a program crashes::
TR BR <INTO OR FROM> will trace branches into or out of an address.
e.g.::
TR BR INTO 0
is often quite useful if a program is getting awkward & deciding
to branch to 0 & crashing as this will stop at the address before in jumps to 0.
TR I R <address range> RUN cmd d g
::
TR I R <address range> RUN cmd d g
single steps a range of addresses but stays running &
displays the gprs on each step.
......@@ -881,31 +955,53 @@ displays the gprs on each step.
Displaying & modifying Registers
--------------------------------
D G will display all the gprs
D G
will display all the gprs
Adding a extra G to all the commands is necessary to access the full 64 bit
content in VM on z/Architecture. Obviously this isn't required for access
registers as these are still 32 bit.
e.g. DGG instead of DG
D X will display all the control registers
D AR will display all the access registers
D AR4-7 will display access registers 4 to 7
CPU ALL D G will display the GRPS of all CPUS in the configuration
D PSW will display the current PSW
st PSW 2000 will put the value 2000 into the PSW &
cause crash your machine.
D PREFIX displays the prefix offset
e.g.
DGG
instead of DG
D X
will display all the control registers
D AR
will display all the access registers
D AR4-7
will display access registers 4 to 7
CPU ALL D G
will display the GRPS of all CPUS in the configuration
D PSW
will display the current PSW
st PSW 2000
will put the value 2000 into the PSW & cause crash your machine.
D PREFIX
displays the prefix offset
Displaying Memory
-----------------
To display memory mapped using the current PSW's mapping try
D <range>
To display memory mapped using the current PSW's mapping try::
D <range>
To make VM display a message each time it hits a particular address and
continue try
D I<range> will disassemble/display a range of instructions.
ST addr 32 bit word will store a 32 bit aligned address
D T<range> will display the EBCDIC in an address (if you are that way inclined)
D R<range> will display real addresses ( without DAT ) but with prefixing.
continue try:
D I<range>
will disassemble/display a range of instructions.
ST addr 32 bit word
will store a 32 bit aligned address
D T<range>
will display the EBCDIC in an address (if you are that way inclined)
D R<range>
will display real addresses ( without DAT ) but with prefixing.
There are other complex options to display if you need to get at say home space
but are in primary space the easiest thing to do is to temporarily
modify the PSW to the other addressing mode, display the stuff & then
......@@ -916,19 +1012,29 @@ restore it.
Hints
-----
If you want to issue a debugger command without halting your virtual machine
with the PA1 key try prefixing the command with #CP e.g.
#cp tr i pswa 2000
with the PA1 key try prefixing the command with #CP e.g.::
#cp tr i pswa 2000
also suffixing most debugger commands with RUN will cause them not
to stop just display the mnemonic at the current instruction on the console.
If you have several breakpoints you want to put into your program &
you get fed up of cross referencing with System.map
you can do the following trick for several symbols.
grep do_signal System.map
which emits the following among other things
0001f4e0 T do_signal
now you can do
TR I PSWA 0001f4e0 cmd msg * do_signal
::
grep do_signal System.map
which emits the following among other things::
0001f4e0 T do_signal
now you can do::
TR I PSWA 0001f4e0 cmd msg * do_signal
This sends a message to your own console each time do_signal is entered.
( As an aside I wrote a perl script once which automatically generated a REXX
script with breakpoints on every kernel procedure, this isn't a good idea
......@@ -940,33 +1046,37 @@ in the file menu called "Save Screen In File" - this is very good for keeping a
copy of traces.
From CMS help <command name> will give you online help on a particular command.
e.g.
HELP DISPLAY
e.g.::
HELP DISPLAY
Also CP has a file called profile.exec which automatically gets called
on startup of CMS ( like autoexec.bat ), keeping on a DOS analogy session
CP has a feature similar to doskey, it may be useful for you to
use profile.exec to define some keystrokes.
e.g.
SET PF9 IMM B
This does a single step in VM on pressing F8.
This does a single step in VM on pressing F8.
SET PF10 ^
This sets up the ^ key.
which can be used for ^c (ctrl-c),^z (ctrl-z) which can't be typed directly
into some 3270 consoles.
This sets up the ^ key.
which can be used for ^c (ctrl-c),^z (ctrl-z) which can't be typed
directly into some 3270 consoles.
SET PF11 ^-
This types the starting keystrokes for a sysrq see SysRq below.
This types the starting keystrokes for a sysrq see SysRq below.
SET PF12 RETRIEVE
This retrieves command history on pressing F12.
This retrieves command history on pressing F12.
Sometimes in VM the display is set up to scroll automatically this
can be very annoying if there are messages you wish to look at
to stop this do
TERM MORE 255 255
This will nearly stop automatic screen updates, however it will
cause a denial of service if lots of messages go to the 3270 console,
so it would be foolish to use this as the default on a production machine.
This will nearly stop automatic screen updates, however it will
cause a denial of service if lots of messages go to the 3270 console,
so it would be foolish to use this as the default on a production machine.
Tracing particular processes
......@@ -976,28 +1086,44 @@ very seldom collide with text segments of user programs ( thanks Martin ),
this simplifies debugging the kernel.
However it is quite common for user processes to have addresses which collide
this can make debugging a particular process under VM painful under normal
circumstances as the process may change when doing a
TR I R <address range>.
circumstances as the process may change when doing a::
TR I R <address range>.
Thankfully after reading VM's online help I figured out how to debug
I particular process.
Your first problem is to find the STD ( segment table designation )
of the program you wish to debug.
There are several ways you can do this here are a few
1) objdump --syms <program to be debugged> | grep main
To get the address of main in the program.
tr i pswa <address of main>
Run::
objdump --syms <program to be debugged> | grep main
To get the address of main in the program. Then::
tr i pswa <address of main>
Start the program, if VM drops to CP on what looks like the entry
point of the main function this is most likely the process you wish to debug.
Now do a D X13 or D XG13 on z/Architecture.
On 31 bit the STD is bits 1-19 ( the STO segment table origin )
& 25-31 ( the STL segment table length ) of CR13.
now type
TR I R STD <CR13's value> 0.7fffffff
e.g.
TR I R STD 8F32E1FF 0.7fffffff
Another very useful variation is
TR STORE INTO STD <CR13's value> <address range>
now type::
TR I R STD <CR13's value> 0.7fffffff
e.g.::
TR I R STD 8F32E1FF 0.7fffffff
Another very useful variation is::
TR STORE INTO STD <CR13's value> <address range>
for finding out when a particular variable changes.
An alternative way of finding the STD of a currently running process
......@@ -1006,39 +1132,70 @@ could be quite convenient if you aren't updating the kernel much &
so your kernel structures will stay constant for a reasonable period of
time ).
grep task /proc/<pid>/status
from this you should see something like
task: 0f160000 ksp: 0f161de8 pt_regs: 0f161f68
::
grep task /proc/<pid>/status
from this you should see something like::
task: 0f160000 ksp: 0f161de8 pt_regs: 0f161f68
This now gives you a pointer to the task structure.
Now make CC:="s390-gcc -g" kernel/sched.s
Now make::
CC:="s390-gcc -g" kernel/sched.s
To get the task_struct stabinfo.
( task_struct is defined in include/linux/sched.h ).
Now we want to look at
task->active_mm->pgd
on my machine the active_mm in the task structure stab is
active_mm:(4,12),672,32
its offset is 672/8=84=0x54
the pgd member in the mm_struct stab is
pgd:(4,6)=*(29,5),96,32
so its offset is 96/8=12=0xc
so we'll
hexdump -s 0xf160054 /dev/mem | more
so we'll::
hexdump -s 0xf160054 /dev/mem | more
i.e. task_struct+active_mm offset
to look at the active_mm member
f160054 0fee cc60 0019 e334 0000 0000 0000 0011
hexdump -s 0x0feecc6c /dev/mem | more
i.e. active_mm+pgd offset
feecc6c 0f2c 0000 0000 0001 0000 0001 0000 0010
to look at the active_mm member::
f160054 0fee cc60 0019 e334 0000 0000 0000 0011
::
hexdump -s 0x0feecc6c /dev/mem | more
i.e. active_mm+pgd offset::
feecc6c 0f2c 0000 0000 0001 0000 0001 0000 0010
we get something like
now do
TR I R STD <pgd|0x7f> 0.7fffffff
now do::
TR I R STD <pgd|0x7f> 0.7fffffff
i.e. the 0x7f is added because the pgd only
gives the page table origin & we need to set the low bits
to the maximum possible segment table length.
TR I R STD 0f2c007f 0.7fffffff
on z/Architecture you'll probably need to do
TR I R STD <pgd|0x7> 0.ffffffffffffffff
::
TR I R STD 0f2c007f 0.7fffffff
on z/Architecture you'll probably need to do::
TR I R STD <pgd|0x7> 0.ffffffffffffffff
to set the TableType to 0x1 & the Table length to 3.
......@@ -1051,18 +1208,21 @@ You can restart linux & trace these using the tr prog <range or value> trace
option.
The most common ones you will normally be tracing for is
1=operation exception
2=privileged operation exception
4=protection exception
5=addressing exception
6=specification exception
10=segment translation exception
11=page translation exception
The most common ones you will normally be tracing for is:
- 1=operation exception
- 2=privileged operation exception
- 4=protection exception
- 5=addressing exception
- 6=specification exception
- 10=segment translation exception
- 11=page translation exception
The full list of these is on page 22 of the current s/390 Reference Summary.
e.g.
tr prog 10 will trace segment translation exceptions.
tr prog on its own will trace all program interruption codes.
Trace Sets
......@@ -1074,17 +1234,25 @@ till a driver is open before you start tracing IO, but know in your
heart that you are going to have to make several runs through the code till you
have a clue whats going on.
What you can do is
TR I PSWA <Driver open address>
What you can do is::
TR I PSWA <Driver open address>
hit b to continue till breakpoint
reach the breakpoint
now do your
TR GOTO B
TR IO 7c08-7c09 inst int run
now do your::
TR GOTO B
TR IO 7c08-7c09 inst int run
or whatever the IO channels you wish to trace are & hit b
To got back to the initial trace set do
TR GOTO INITIAL
To got back to the initial trace set do::
TR GOTO INITIAL
& the TR I PSWA <Driver open address> will be the only active breakpoint again.
......@@ -1093,11 +1261,14 @@ Tracing linux syscalls under VM
Syscalls are implemented on Linux for S390 by the Supervisor call instruction
(SVC). There 256 possibilities of these as the instruction is made up of a 0xA
opcode and the second byte being the syscall number. They are traced using the
simple command:
TR SVC <Optional value or range>
simple command::
TR SVC <Optional value or range>
the syscalls are defined in linux/arch/s390/include/asm/unistd.h
e.g. to trace all file opens just do
TR SVC 5 ( as this is the syscall number of open )
e.g. to trace all file opens just do::
TR SVC 5 ( as this is the syscall number of open )
SMP Specific commands
......@@ -1105,33 +1276,51 @@ SMP Specific commands
To find out how many cpus you have
Q CPUS displays all the CPU's available to your virtual machine
To find the cpu that the current cpu VM debugger commands are being directed at
do Q CPU to change the current cpu VM debugger commands are being directed at do
CPU <desired cpu no>
do Q CPU to change the current cpu VM debugger commands are being directed at
do::
CPU <desired cpu no>
On a SMP guest issue a command to all CPUs try prefixing the command with cpu
all. To issue a command to a particular cpu try cpu <cpu number> e.g.
CPU 01 TR I R 2000.3000
all. To issue a command to a particular cpu try cpu <cpu number> e.g.::
CPU 01 TR I R 2000.3000
If you are running on a guest with several cpus & you have a IO related problem
& cannot follow the flow of code but you know it isn't smp related.
from the bash prompt issue
shutdown -h now or halt.
do a Q CPUS to find out how many cpus you have
detach each one of them from cp except cpu 0
by issuing a
DETACH CPU 01-(number of cpus in configuration)
from the bash prompt issue::
shutdown -h now or halt.
do a::
Q CPUS
to find out how many cpus you have detach each one of them from cp except
cpu 0 by issuing a::
DETACH CPU 01-(number of cpus in configuration)
& boot linux again.
TR SIGP will trace inter processor signal processor instructions.
TR SIGP
will trace inter processor signal processor instructions.
DEFINE CPU 01-(number in configuration)
will get your guests cpus back.
will get your guests cpus back.
Help for displaying ascii textstrings
-------------------------------------
On the very latest VM Nucleus'es VM can now display ascii
( thanks Neale for the hint ) by doing
D TX<lowaddr>.<len>
e.g.
D TX0.100
( thanks Neale for the hint ) by doing::
D TX<lowaddr>.<len>
e.g.::
D TX0.100
Alternatively
=============
......@@ -1143,45 +1332,64 @@ to your xterm if you are debugging from a linuxbox.
This is quite useful when looking at a parameter passed in as a text string
under VM ( unless you are good at decoding ASCII in your head ).
e.g. consider tracing an open syscall
TR SVC 5
We have stopped at a breakpoint
000151B0' SVC 0A05 -> 0001909A' CC 0
e.g. consider tracing an open syscall::
TR SVC 5
We have stopped at a breakpoint::
000151B0' SVC 0A05 -> 0001909A' CC 0
D 20.8 to check the SVC old psw in the prefix area and see was it from userspace
(for the layout of the prefix area consult the "Fixed Storage Locations"
chapter of the s/390 Reference Summary if you have it available).
V00000020 070C2000 800151B2
::
V00000020 070C2000 800151B2
The problem state bit wasn't set & it's also too early in the boot sequence
for it to be a userspace SVC if it was we would have to temporarily switch the
psw to user space addressing so we could get at the first parameter of the open
in gpr2.
Next do a
D G2
GPR 2 = 00014CB4
Now display what gpr2 is pointing to
D 00014CB4.20
V00014CB4 2F646576 2F636F6E 736F6C65 00001BF5
V00014CC4 FC00014C B4001001 E0001000 B8070707
Next do a::
D G2
GPR 2 = 00014CB4
Now display what gpr2 is pointing to::
D 00014CB4.20
V00014CB4 2F646576 2F636F6E 736F6C65 00001BF5
V00014CC4 FC00014C B4001001 E0001000 B8070707
Now copy the text till the first 00 hex ( which is the end of the string
to an xterm & do hex2ascii on it.
hex2ascii 2F646576 2F636F6E 736F6C65 00
outputs
Decoded Hex:=/ d e v / c o n s o l e 0x00
to an xterm & do hex2ascii on it::
hex2ascii 2F646576 2F636F6E 736F6C65 00
outputs::
Decoded Hex:=/ d e v / c o n s o l e 0x00
We were opening the console device,
You can compile the code below yourself for practice :-),
/*
::
/*
* hex2ascii.c
* a useful little tool for converting a hexadecimal command line to ascii
*
* Author(s): Denis Joseph Barrow (djbarrow@de.ibm.com,barrow_dj@yahoo.com)
* (C) 2000 IBM Deutschland Entwicklung GmbH, IBM Corporation.
*/
#include <stdio.h>
#include <stdio.h>
int main(int argc,char *argv[])
{
int main(int argc,char *argv[])
{
int cnt1,cnt2,len,toggle=0;
int startcnt=1;
unsigned char c,hex;
......@@ -1228,7 +1436,7 @@ int main(int argc,char *argv[])
}
}
printf("\n");
}
}
......@@ -1254,42 +1462,52 @@ behind the current stackpointer.
Here is some practice.
boot the kernel & hit PA1 at some random time
d g to display the gprs, this should display something like
GPR 0 = 00000001 00156018 0014359C 00000000
GPR 4 = 00000001 001B8888 000003E0 00000000
GPR 8 = 00100080 00100084 00000000 000FE000
GPR 12 = 00010400 8001B2DC 8001B36A 000FFED8
d g to display the gprs, this should display something like::
GPR 0 = 00000001 00156018 0014359C 00000000
GPR 4 = 00000001 001B8888 000003E0 00000000
GPR 8 = 00100080 00100084 00000000 000FE000
GPR 12 = 00010400 8001B2DC 8001B36A 000FFED8
Note that GPR14 is a return address but as we are real men we are going to
trace the stack.
display 0x40 bytes after the stack pointer.
display 0x40 bytes after the stack pointer::
V000FFED8 000FFF38 8001B838 80014C8E 000FFF38
V000FFEE8 00000000 00000000 000003E0 00000000
V000FFEF8 00100080 00100084 00000000 000FE000
V000FFF08 00010400 8001B2DC 8001B36A 000FFED8
V000FFED8 000FFF38 8001B838 80014C8E 000FFF38
V000FFEE8 00000000 00000000 000003E0 00000000
V000FFEF8 00100080 00100084 00000000 000FE000
V000FFF08 00010400 8001B2DC 8001B36A 000FFED8
Ah now look at whats in sp+56 (sp+0x38) this is 8001B36A our saved r14 if
you look above at our stackframe & also agrees with GPR14.
now backchain
d 000FFF38.40
we now are taking the contents of SP to get our first backchain.
now backchain::
V000FFF38 000FFFA0 00000000 00014995 00147094
V000FFF48 00147090 001470A0 000003E0 00000000
V000FFF58 00100080 00100084 00000000 001BF1D0
V000FFF68 00010400 800149BA 80014CA6 000FFF38
d 000FFF38.40
we now are taking the contents of SP to get our first backchain::
V000FFF38 000FFFA0 00000000 00014995 00147094
V000FFF48 00147090 001470A0 000003E0 00000000
V000FFF58 00100080 00100084 00000000 001BF1D0
V000FFF68 00010400 800149BA 80014CA6 000FFF38
This displays a 2nd return address of 80014CA6
now do d 000FFFA0.40 for our 3rd backchain
now do::
d 000FFFA0.40
V000FFFA0 04B52002 0001107F 00000000 00000000
V000FFFB0 00000000 00000000 FF000000 0001107F
V000FFFC0 00000000 00000000 00000000 00000000
V000FFFD0 00010400 80010802 8001085A 000FFFA0
for our 3rd backchain::
V000FFFA0 04B52002 0001107F 00000000 00000000
V000FFFB0 00000000 00000000 FF000000 0001107F
V000FFFC0 00000000 00000000 00000000 00000000
V000FFFD0 00010400 80010802 8001085A 000FFFA0
our 3rd return address is 8001085A
......@@ -1297,23 +1515,35 @@ our 3rd return address is 8001085A
as the 04B52002 looks suspiciously like rubbish it is fair to assume that the
kernel entry routines for the sake of optimisation don't set up a backchain.
now look at System.map to see if the addresses make any sense.
now look at System.map to see if the addresses make any sense::
grep -i 0001b3 System.map
outputs among other things::
0001b304 T cpu_idle
grep -i 0001b3 System.map
outputs among other things
0001b304 T cpu_idle
so 8001B36A
is cpu_idle+0x66 ( quiet the cpu is asleep, don't wake it )
::
grep -i 00014 System.map
produces among other things::
00014a78 T start_kernel
grep -i 00014 System.map
produces among other things
00014a78 T start_kernel
so 0014CA6 is start_kernel+some hex number I can't add in my head.
grep -i 00108 System.map
this produces
00010800 T _stext
::
grep -i 00108 System.map
this produces::
00010800 T _stext
so 8001085A is _stext+0x5a
Congrats you've done your first backchain.
......@@ -1337,47 +1567,49 @@ system might be choking with around 64.
Here is some of the common IO terminology:
Subchannel:
This is the logical number most IO commands use to talk to an IO device. There
can be up to 0x10000 (65536) of these in a configuration, typically there are a
few hundred. Under VM for simplicity they are allocated contiguously, however
on the native hardware they are not. They typically stay consistent between
boots provided no new hardware is inserted or removed.
Under Linux for s390 we use these as IRQ's and also when issuing an IO command
(CLEAR SUBCHANNEL, HALT SUBCHANNEL, MODIFY SUBCHANNEL, RESUME SUBCHANNEL,
START SUBCHANNEL, STORE SUBCHANNEL and TEST SUBCHANNEL). We use this as the ID
of the device we wish to talk to. The most important of these instructions are
START SUBCHANNEL (to start IO), TEST SUBCHANNEL (to check whether the IO
completed successfully) and HALT SUBCHANNEL (to kill IO). A subchannel can have
up to 8 channel paths to a device, this offers redundancy if one is not
available.
This is the logical number most IO commands use to talk to an IO device. There
can be up to 0x10000 (65536) of these in a configuration, typically there are a
few hundred. Under VM for simplicity they are allocated contiguously, however
on the native hardware they are not. They typically stay consistent between
boots provided no new hardware is inserted or removed.
Under Linux for s390 we use these as IRQ's and also when issuing an IO command
(CLEAR SUBCHANNEL, HALT SUBCHANNEL, MODIFY SUBCHANNEL, RESUME SUBCHANNEL,
START SUBCHANNEL, STORE SUBCHANNEL and TEST SUBCHANNEL). We use this as the ID
of the device we wish to talk to. The most important of these instructions are
START SUBCHANNEL (to start IO), TEST SUBCHANNEL (to check whether the IO
completed successfully) and HALT SUBCHANNEL (to kill IO). A subchannel can have
up to 8 channel paths to a device, this offers redundancy if one is not
available.
Device Number:
This number remains static and is closely tied to the hardware. There are 65536
of these, made up of a CHPID (Channel Path ID, the most significant 8 bits) and
another lsb 8 bits. These remain static even if more devices are inserted or
removed from the hardware. There is a 1 to 1 mapping between subchannels and
device numbers, provided devices aren't inserted or removed.
This number remains static and is closely tied to the hardware. There are 65536
of these, made up of a CHPID (Channel Path ID, the most significant 8 bits) and
another lsb 8 bits. These remain static even if more devices are inserted or
removed from the hardware. There is a 1 to 1 mapping between subchannels and
device numbers, provided devices aren't inserted or removed.
Channel Control Words:
CCWs are linked lists of instructions initially pointed to by an operation
request block (ORB), which is initially given to Start Subchannel (SSCH)
command along with the subchannel number for the IO subsystem to process
while the CPU continues executing normal code.
CCWs come in two flavours, Format 0 (24 bit for backward compatibility) and
Format 1 (31 bit). These are typically used to issue read and write (and many
other) instructions. They consist of a length field and an absolute address
field.
Each IO typically gets 1 or 2 interrupts, one for channel end (primary status)
when the channel is idle, and the second for device end (secondary status).
Sometimes you get both concurrently. You check how the IO went on by issuing a
TEST SUBCHANNEL at each interrupt, from which you receive an Interruption
response block (IRB). If you get channel and device end status in the IRB
without channel checks etc. your IO probably went okay. If you didn't you
probably need to examine the IRB, extended status word etc.
If an error occurs, more sophisticated control units have a facility known as
concurrent sense. This means that if an error occurs Extended sense information
will be presented in the Extended status word in the IRB. If not you have to
issue a subsequent SENSE CCW command after the test subchannel.
CCWs are linked lists of instructions initially pointed to by an operation
request block (ORB), which is initially given to Start Subchannel (SSCH)
command along with the subchannel number for the IO subsystem to process
while the CPU continues executing normal code.
CCWs come in two flavours, Format 0 (24 bit for backward compatibility) and
Format 1 (31 bit). These are typically used to issue read and write (and many
other) instructions. They consist of a length field and an absolute address
field.
Each IO typically gets 1 or 2 interrupts, one for channel end (primary status)
when the channel is idle, and the second for device end (secondary status).
Sometimes you get both concurrently. You check how the IO went on by issuing a
TEST SUBCHANNEL at each interrupt, from which you receive an Interruption
response block (IRB). If you get channel and device end status in the IRB
without channel checks etc. your IO probably went okay. If you didn't you
probably need to examine the IRB, extended status word etc.
If an error occurs, more sophisticated control units have a facility known as
concurrent sense. This means that if an error occurs Extended sense information
will be presented in the Extended status word in the IRB. If not you have to
issue a subsequent SENSE CCW command after the test subchannel.
TPI (Test pending interrupt) can also be used for polled IO, but in
......@@ -1388,13 +1620,17 @@ Store Subchannel and Modify Subchannel can be used to examine and modify
operating characteristics of a subchannel (e.g. channel paths).
Other IO related Terms:
Sysplex: S390's Clustering Technology
QDIO: S390's new high speed IO architecture to support devices such as gigabit
ethernet, this architecture is also designed to be forward compatible with
upcoming 64 bit machines.
Sysplex:
S390's Clustering Technology
QDIO:
S390's new high speed IO architecture to support devices such as gigabit
ethernet, this architecture is also designed to be forward compatible with
upcoming 64 bit machines.
General Concepts
----------------
Input Output Processors (IOP's) are responsible for communicating between
the mainframe CPU's & the channel & relieve the mainframe CPU's from the
......@@ -1410,7 +1646,7 @@ IO devices are attached to control units, control units provide the
logic to interface the channel paths & channel path IO protocols to
the IO devices, they can be integrated with the devices or housed separately
& often talk to several similar devices ( typical examples would be raid
controllers or a control unit which connects to 1000 3270 terminals ).
controllers or a control unit which connects to 1000 3270 terminals )::
+---------------------------------------------------------------+
......@@ -1433,9 +1669,9 @@ controllers or a control unit which connects to 1000 3270 terminals ).
| | | | | |
+----------+ +----------+ +----------+
| | | | |
+----------+ +----------+ +----------+ +----------+ +----------+
|I/O Device| |I/O Device| |I/O Device| |I/O Device| |I/O Device|
+----------+ +----------+ +----------+ +----------+ +----------+
+----------+ +----------+ +----------+ +----------+ +----------+
|I/O Device| |I/O Device| |I/O Device| |I/O Device| |I/O Device|
+----------+ +----------+ +----------+ +----------+ +----------+
CPU = Central Processing Unit
C = Channel
IOP = IP Processor
......@@ -1489,27 +1725,25 @@ Debugging IO on s/390 & z/Architecture under VM
Now we are ready to go on with IO tracing commands under VM
A few self explanatory queries:
Q OSA
Q CTC
Q DISK ( This command is CMS specific )
Q DASD
A few self explanatory queries::
Q OSA
Q CTC
Q DISK ( This command is CMS specific )
Q DASD
Q OSA on my machine returns::
Q OSA on my machine returns
OSA 7C08 ON OSA 7C08 SUBCHANNEL = 0000
OSA 7C09 ON OSA 7C09 SUBCHANNEL = 0001
OSA 7C14 ON OSA 7C14 SUBCHANNEL = 0002
OSA 7C15 ON OSA 7C15 SUBCHANNEL = 0003
OSA 7C08 ON OSA 7C08 SUBCHANNEL = 0000
OSA 7C09 ON OSA 7C09 SUBCHANNEL = 0001
OSA 7C14 ON OSA 7C14 SUBCHANNEL = 0002
OSA 7C15 ON OSA 7C15 SUBCHANNEL = 0003
If you have a guest with certain privileges you may be able to see devices
which don't belong to you. To avoid this, add the option V.
e.g.
Q V OSA
e.g.::
Q V OSA
Now using the device numbers returned by this command we will
Trace the io starting up on the first device 7c08 & 7c09
......@@ -1524,34 +1758,47 @@ A good trick is tracing all the IO's and CCWS and spooling them into the reader
of another VM guest so he can ftp the logfile back to his own machine. I'll do
a small bit of this and give you a look at the output.
1) Spool stdout to VM reader
SP PRT TO (another vm guest ) or * for the local vm guest
2) Fill the reader with the trace
TR IO 7c08-7c09 INST INT CCW PRT RUN
3) Start up linux
i 00c
4) Finish the trace
TR END
5) close the reader
C PRT
6) list reader contents
RDRLIST
7) copy it to linux4's minidisk
RECEIVE / LOG TXT A1 ( replace
1) Spool stdout to VM reader::
SP PRT TO (another vm guest ) or * for the local vm guest
2) Fill the reader with the trace::
TR IO 7c08-7c09 INST INT CCW PRT RUN
3) Start up linux::
i 00c
4) Finish the trace::
TR END
5) close the reader::
C PRT
6) list reader contents::
RDRLIST
7) copy it to linux4's minidisk::
RECEIVE / LOG TXT A1 ( replace
8)
filel & press F11 to look at it
You should see something like:
You should see something like::
00020942' SSCH B2334000 0048813C CC 0 SCH 0000 DEV 7C08
00020942' SSCH B2334000 0048813C CC 0 SCH 0000 DEV 7C08
CPA 000FFDF0 PARM 00E2C9C4 KEY 0 FPI C0 LPM 80
CCW 000FFDF0 E4200100 00487FE8 0000 E4240100 ........
IDAL 43D8AFE8
IDAL 0FB76000
00020B0A' I/O DEV 7C08 -> 000197BC' SCH 0000 PARM 00E2C9C4
00021628' TSCH B2354000 >> 00488164 CC 0 SCH 0000 DEV 7C08
00020B0A' I/O DEV 7C08 -> 000197BC' SCH 0000 PARM 00E2C9C4
00021628' TSCH B2354000 >> 00488164 CC 0 SCH 0000 DEV 7C08
CCWA 000FFDF8 DEV STS 0C SCH STS 00 CNT 00EC
KEY 0 FPI C0 CC 0 CTLS 4007
00022238' STSCH B2344000 >> 00488108 CC 0 SCH 0000 DEV 7C08
00022238' STSCH B2344000 >> 00488108 CC 0 SCH 0000 DEV 7C08
If you don't like messing up your readed ( because you possibly booted from it )
you can alternatively spool it to another readers guest.
......@@ -1563,37 +1810,52 @@ These commands are listed only because they have
been of use to me in the past & may be of use to
you too. For more complete info on each of the commands
use type HELP <command> from CMS.
detaching devices
DET <devno range>
ATT <devno range> <guest>
detaching devices::
DET <devno range>
ATT <devno range> <guest>
attach a device to guest * for your own guest
READY <devno> cause VM to issue a fake interrupt.
The VARY command is normally only available to VM administrators.
VARY ON PATH <path> TO <devno range>
VARY OFF PATH <PATH> FROM <devno range>
READY <devno>
cause VM to issue a fake interrupt.
The VARY command is normally only available to VM administrators::
VARY ON PATH <path> TO <devno range>
VARY OFF PATH <PATH> FROM <devno range>
This is used to switch on or off channel paths to devices.
Q CHPID <channel path ID>
This displays state of devices using this channel path
This displays state of devices using this channel path
D SCHIB <subchannel>
This displays the subchannel information SCHIB block for the device.
this I believe is also only available to administrators.
This displays the subchannel information SCHIB block for the device.
this I believe is also only available to administrators.
DEFINE CTC <devno>
defines a virtual CTC channel to channel connection
2 need to be defined on each guest for the CTC driver to use.
defines a virtual CTC channel to channel connection
2 need to be defined on each guest for the CTC driver to use.
COUPLE devno userid remote devno
Joins a local virtual device to a remote virtual device
( commonly used for the CTC driver ).
Joins a local virtual device to a remote virtual device
( commonly used for the CTC driver ).
Building a VM ramdisk under CMS which linux can use::
def vfb-<blocksize> <subchannel> <number blocks>
Building a VM ramdisk under CMS which linux can use
def vfb-<blocksize> <subchannel> <number blocks>
blocksize is commonly 4096 for linux.
Formatting it
format <subchannel> <driver letter e.g. x> (blksize <blocksize>
Sharing a disk between multiple guests
LINK userid devno1 devno2 mode password
Formatting it::
format <subchannel> <driver letter e.g. x> (blksize <blocksize>
Sharing a disk between multiple guests::
LINK userid devno1 devno2 mode password
......@@ -1609,113 +1871,169 @@ gdb <victim program> <optional corefile>
Online help
-----------
help: gives help on commands
e.g.
help
help display
e.g.::
help
help display
Note gdb's online help is very good use it.
Assembly
--------
info registers: displays registers other than floating point.
info all-registers: displays floating points as well.
disassemble: disassembles
e.g.
disassemble without parameters will disassemble the current function
disassemble $pc $pc+10
info registers:
displays registers other than floating point.
info all-registers:
displays floating points as well.
disassemble:
disassembles
e.g.::
disassemble without parameters will disassemble the current function
disassemble $pc $pc+10
Viewing & modifying variables
-----------------------------
print or p: displays variable or register
print or p:
displays variable or register
e.g. p/x $sp will display the stack pointer
display: prints variable or register each time program stops
e.g.
display/x $pc will display the program counter
display argc
display:
prints variable or register each time program stops
e.g.::
display/x $pc will display the program counter
display argc
undisplay:
undo's display's
undisplay : undo's display's
info breakpoints:
shows all current breakpoints
info breakpoints: shows all current breakpoints
info stack:
shows stack back trace (if this doesn't work too well, I'll show
you the stacktrace by hand below).
info stack: shows stack back trace (if this doesn't work too well, I'll show
you the stacktrace by hand below).
info locals:
displays local variables.
info locals: displays local variables.
info args:
display current procedure arguments.
info args: display current procedure arguments.
set args:
will set argc & argv each time the victim program is invoked
set args: will set argc & argv each time the victim program is invoked.
e.g.::
set <variable>=value
set argc=100
set $pc=0
set <variable>=value
set argc=100
set $pc=0
Modifying execution
-------------------
step: steps n lines of sourcecode
step steps 1 line.
step 100 steps 100 lines of code.
step:
steps n lines of sourcecode
next: like step except this will not step into subroutines
step
steps 1 line.
stepi: steps a single machine code instruction.
e.g. stepi 100
step 100
steps 100 lines of code.
nexti: steps a single machine code instruction but will not step into
subroutines.
next:
like step except this will not step into subroutines
finish: will run until exit of the current routine
stepi:
steps a single machine code instruction.
run: (re)starts a program
e.g.::
cont: continues a program
stepi 100
quit: exits gdb.
nexti:
steps a single machine code instruction but will not step into
subroutines.
finish:
will run until exit of the current routine
run:
(re)starts a program
cont:
continues a program
quit:
exits gdb.
breakpoints
------------
break
sets a breakpoint
e.g.
break main
sets a breakpoint
break *$pc
e.g.::
break *0x400618
break main
break *$pc
break *0x400618
Here's a really useful one for large programs
rbr
Set a breakpoint for all functions matching REGEXP
e.g.
rbr 390
Set a breakpoint for all functions matching REGEXP
e.g.::
rbr 390
will set a breakpoint with all functions with 390 in their name.
info breakpoints
lists all breakpoints
lists all breakpoints
delete:
delete breakpoint by number or delete them all
delete: delete breakpoint by number or delete them all
e.g.
delete 1 will delete the first breakpoint
delete will delete them all
watch: This will set a watchpoint ( usually hardware assisted ),
delete 1
will delete the first breakpoint
delete
will delete them all
watch:
This will set a watchpoint ( usually hardware assisted ),
This will watch a variable till it changes
e.g.
watch cnt, will watch the variable cnt till it changes.
watch cnt
will watch the variable cnt till it changes.
As an aside unfortunately gdb's, architecture independent watchpoint code
is inconsistent & not very good, watchpoints usually work but not always.
info watchpoints: Display currently active watchpoints
info watchpoints:
Display currently active watchpoints
condition: ( another useful one )
Specify breakpoint number N to break only if COND is true.
Usage is `condition N COND', where N is an integer and COND is an
Specify breakpoint number N to break only if COND is true.
Usage is `condition N COND`, where N is an integer and COND is an
expression to be evaluated whenever breakpoint N is reached.
......@@ -1723,41 +2041,51 @@ expression to be evaluated whenever breakpoint N is reached.
User defined functions/macros
-----------------------------
define: ( Note this is very very useful,simple & powerful )
usage define <name> <list of commands> end
examples which you should consider putting into .gdbinit in your home directory
define d
stepi
disassemble $pc $pc+10
end
examples which you should consider putting into .gdbinit in your home
directory::
define e
nexti
disassemble $pc $pc+10
end
define d
stepi
disassemble $pc $pc+10
end
define e
nexti
disassemble $pc $pc+10
end
Other hard to classify stuff
----------------------------
signal n:
sends the victim program a signal.
e.g. signal 3 will send a SIGQUIT.
sends the victim program a signal.
e.g. `signal 3` will send a SIGQUIT.
info signals:
what gdb does when the victim receives certain signals.
what gdb does when the victim receives certain signals.
list:
e.g.
list lists current function source
list 1,10 list first 10 lines of current file.
e.g.:
list
lists current function source
list 1,10
list first 10 lines of current file.
list test.c:1,10
directory:
Adds directories to be searched for source if gdb cannot find the source.
(note it is a bit sensitive about slashes)
e.g. To add the root of the filesystem to the searchpath do
directory //
Adds directories to be searched for source if gdb cannot find the source.
(note it is a bit sensitive about slashes)
e.g. To add the root of the filesystem to the searchpath do::
directory //
call <function>
......@@ -1779,7 +2107,8 @@ to make space for the "hello world" string.
hints
-----
1) command completion works just like bash
( if you are a bad typist like me this really helps )
( if you are a bad typist like me this really helps )
e.g. hit br <TAB> & cursor up & down :-).
2) if you have a debugging problem that takes a few steps to recreate
......@@ -1787,43 +2116,65 @@ put the steps into a file called .gdbinit in your current working directory
if you have defined a few extra useful user defined commands put these in
your home directory & they will be read each time gdb is launched.
A typical .gdbinit file might be.
break main
run
break runtime_exception
cont
A typical .gdbinit file might be.::
break main
run
break runtime_exception
cont
stack chaining in gdb by hand
-----------------------------
This is done using a the same trick described for VM
p/x (*($sp+56))&0x7fffffff get the first backchain.
This is done using a the same trick described for VM::
p/x (*($sp+56))&0x7fffffff
get the first backchain.
For z/Architecture
Replace 56 with 112 & ignore the &0x7fffffff
in the macros below & do nasty casts to longs like the following
as gdb unfortunately deals with printed arguments as ints which
messes up everything.
i.e. here is a 3rd backchain dereference
p/x *(long *)(***(long ***)$sp+112)
i.e. here is a 3rd backchain dereference::
p/x *(long *)(***(long ***)$sp+112)
this outputs::
$5 = 0x528f18
this outputs
$5 = 0x528f18
on my machine.
Now you can use
info symbol (*($sp+56))&0x7fffffff
you might see something like.
rl_getc + 36 in section .text telling you what is located at address 0x528f18
Now do.
p/x (*(*$sp+56))&0x7fffffff
This outputs
$6 = 0x528ed0
Now do.
info symbol (*(*$sp+56))&0x7fffffff
rl_read_key + 180 in section .text
now do
p/x (*(**$sp+56))&0x7fffffff
Now you can use::
info symbol (*($sp+56))&0x7fffffff
you might see something like::
rl_getc + 36 in section .text
telling you what is located at address 0x528f18
Now do::
p/x (*(*$sp+56))&0x7fffffff
This outputs::
$6 = 0x528ed0
Now do::
info symbol (*(*$sp+56))&0x7fffffff
rl_read_key + 180 in section .text
now do::
p/x (*(**$sp+56))&0x7fffffff
& so on.
Disassembling instructions without debug info
......@@ -1831,87 +2182,116 @@ Disassembling instructions without debug info
gdb typically complains if there is a lack of debugging
symbols in the disassemble command with
"No function contains specified address." To get around
this do
x/<number lines to disassemble>xi <address>
e.g.
x/20xi 0x400730
this do::
x/<number lines to disassemble>xi <address>
e.g.::
Note: Remember gdb has history just like bash you don't need to retype the
whole line just use the up & down arrows.
x/20xi 0x400730
Note:
Remember gdb has history just like bash you don't need to retype the
whole line just use the up & down arrows.
For more info
-------------
From your linuxbox do
man gdb or info gdb.
From your linuxbox do::
man gdb
or::
info gdb.
core dumps
----------
What a core dump ?,
What a core dump ?
^^^^^^^^^^^^^^^^^^
A core dump is a file generated by the kernel (if allowed) which contains the
registers and all active pages of the program which has crashed.
From this file gdb will allow you to look at the registers, stack trace and
memory of the program as if it just crashed on your system. It is usually
called core and created in the current working directory.
This is very useful in that a customer can mail a core dump to a technical
support department and the technical support department can reconstruct what
happened. Provided they have an identical copy of this program with debugging
symbols compiled in and the source base of this build is available.
In short it is far more useful than something like a crash log could ever hope
to be.
Why have I never seen one ?.
Probably because you haven't used the command
ulimit -c unlimited in bash
to allow core dumps, now do
ulimit -a
Why have I never seen one ?
^^^^^^^^^^^^^^^^^^^^^^^^^^^
Probably because you haven't used the command::
ulimit -c unlimited in bash
to allow core dumps, now do::
ulimit -a
to verify that the limit was accepted.
A sample core dump
To create this I'm going to do
ulimit -c unlimited
gdb
To create this I'm going to do::
ulimit -c unlimited
gdb
to launch gdb (my victim app. ) now be bad & do the following from another
telnet/xterm session to the same machine
ps -aux | grep gdb
kill -SIGSEGV <gdb's pid>
or alternatively use killall -SIGSEGV gdb if you have the killall command.
Now look at the core dump.
./gdb core
Displays the following
GNU gdb 4.18
Copyright 1998 Free Software Foundation, Inc.
GDB is free software, covered by the GNU General Public License, and you are
welcome to change it and/or distribute copies of it under certain conditions.
Type "show copying" to see the conditions.
There is absolutely no warranty for GDB. Type "show warranty" for details.
This GDB was configured as "s390-ibm-linux"...
Core was generated by `./gdb'.
Program terminated with signal 11, Segmentation fault.
Reading symbols from /usr/lib/libncurses.so.4...done.
Reading symbols from /lib/libm.so.6...done.
Reading symbols from /lib/libc.so.6...done.
Reading symbols from /lib/ld-linux.so.2...done.
#0 0x40126d1a in read () from /lib/libc.so.6
Setting up the environment for debugging gdb.
Breakpoint 1 at 0x4dc6f8: file utils.c, line 471.
Breakpoint 2 at 0x4d87a4: file top.c, line 2609.
(top-gdb) info stack
#0 0x40126d1a in read () from /lib/libc.so.6
#1 0x528f26 in rl_getc (stream=0x7ffffde8) at input.c:402
#2 0x528ed0 in rl_read_key () at input.c:381
#3 0x5167e6 in readline_internal_char () at readline.c:454
#4 0x5168ee in readline_internal_charloop () at readline.c:507
#5 0x51692c in readline_internal () at readline.c:521
#6 0x5164fe in readline (prompt=0x7ffff810)
telnet/xterm session to the same machine::
ps -aux | grep gdb
kill -SIGSEGV <gdb's pid>
or alternatively use `killall -SIGSEGV gdb` if you have the killall command.
Now look at the core dump::
./gdb core
Displays the following::
GNU gdb 4.18
Copyright 1998 Free Software Foundation, Inc.
GDB is free software, covered by the GNU General Public License, and you are
welcome to change it and/or distribute copies of it under certain conditions.
Type "show copying" to see the conditions.
There is absolutely no warranty for GDB. Type "show warranty" for details.
This GDB was configured as "s390-ibm-linux"...
Core was generated by `./gdb'.
Program terminated with signal 11, Segmentation fault.
Reading symbols from /usr/lib/libncurses.so.4...done.
Reading symbols from /lib/libm.so.6...done.
Reading symbols from /lib/libc.so.6...done.
Reading symbols from /lib/ld-linux.so.2...done.
#0 0x40126d1a in read () from /lib/libc.so.6
Setting up the environment for debugging gdb.
Breakpoint 1 at 0x4dc6f8: file utils.c, line 471.
Breakpoint 2 at 0x4d87a4: file top.c, line 2609.
(top-gdb) info stack
#0 0x40126d1a in read () from /lib/libc.so.6
#1 0x528f26 in rl_getc (stream=0x7ffffde8) at input.c:402
#2 0x528ed0 in rl_read_key () at input.c:381
#3 0x5167e6 in readline_internal_char () at readline.c:454
#4 0x5168ee in readline_internal_charloop () at readline.c:507
#5 0x51692c in readline_internal () at readline.c:521
#6 0x5164fe in readline (prompt=0x7ffff810)
at readline.c:349
#7 0x4d7a8a in command_line_input (prompt=0x564420 "(gdb) ", repeat=1,
#7 0x4d7a8a in command_line_input (prompt=0x564420 "(gdb) ", repeat=1,
annotation_suffix=0x4d6b44 "prompt") at top.c:2091
#8 0x4d6cf0 in command_loop () at top.c:1345
#9 0x4e25bc in main (argc=1, argv=0x7ffffdf4) at main.c:635
#8 0x4d6cf0 in command_loop () at top.c:1345
#9 0x4e25bc in main (argc=1, argv=0x7ffffdf4) at main.c:635
LDD
......@@ -1919,13 +2299,17 @@ LDD
This is a program which lists the shared libraries which a library needs,
Note you also get the relocations of the shared library text segments which
help when using objdump --source.
e.g.
e.g.::
ldd ./gdb
outputs
libncurses.so.4 => /usr/lib/libncurses.so.4 (0x40018000)
libm.so.6 => /lib/libm.so.6 (0x4005e000)
libc.so.6 => /lib/libc.so.6 (0x40084000)
/lib/ld-linux.so.2 => /lib/ld-linux.so.2 (0x40000000)
outputs::
libncurses.so.4 => /usr/lib/libncurses.so.4 (0x40018000)
libm.so.6 => /lib/libm.so.6 (0x4005e000)
libc.so.6 => /lib/libc.so.6 (0x40084000)
/lib/ld-linux.so.2 => /lib/ld-linux.so.2 (0x40000000)
Debugging shared libraries
......@@ -1936,6 +2320,7 @@ first time & you end up in functions like _dl_runtime_resolve this is
the ld.so doing lazy binding, lazy binding is a concept in ELF where
shared library functions are not loaded into memory unless they are
actually used, great for saving memory but a pain to debug.
To get around this either relink the program -static or exit gdb type
export LD_BIND_NOW=true this will stop lazy binding & restart the gdb'ing
the program in question.
......@@ -1955,106 +2340,127 @@ It is a filesystem created by the kernel with files which are created on demand
by the kernel if read, or can be used to modify kernel parameters,
it is a powerful concept.
e.g.
e.g.::
cat /proc/sys/net/ipv4/ip_forward
On my machine outputs::
0
telling me ip_forwarding is not on to switch it on I can do::
echo 1 > /proc/sys/net/ipv4/ip_forward
cat it again::
cat /proc/sys/net/ipv4/ip_forward
On my machine now outputs::
1
cat /proc/sys/net/ipv4/ip_forward
On my machine outputs
0
telling me ip_forwarding is not on to switch it on I can do
echo 1 > /proc/sys/net/ipv4/ip_forward
cat it again
cat /proc/sys/net/ipv4/ip_forward
On my machine now outputs
1
IP forwarding is on.
There is a lot of useful info in here best found by going in and having a look
around, so I'll take you through some entries I consider important.
All the processes running on the machine have their own entry defined by
/proc/<pid>
So lets have a look at the init process
cd /proc/1
cat cmdline
emits
init [2]
So lets have a look at the init process::
cd /proc/1
cat cmdline
emits::
init [2]
::
cd /proc/1/fd
cd /proc/1/fd
This contains numerical entries of all the open files,
some of these you can cat e.g. stdout (2)
cat /proc/29/maps
on my machine emits
00400000-00478000 r-xp 00000000 5f:00 4103 /bin/bash
00478000-0047e000 rw-p 00077000 5f:00 4103 /bin/bash
0047e000-00492000 rwxp 00000000 00:00 0
40000000-40015000 r-xp 00000000 5f:00 14382 /lib/ld-2.1.2.so
40015000-40016000 rw-p 00014000 5f:00 14382 /lib/ld-2.1.2.so
40016000-40017000 rwxp 00000000 00:00 0
40017000-40018000 rw-p 00000000 00:00 0
40018000-4001b000 r-xp 00000000 5f:00 14435 /lib/libtermcap.so.2.0.8
4001b000-4001c000 rw-p 00002000 5f:00 14435 /lib/libtermcap.so.2.0.8
4001c000-4010d000 r-xp 00000000 5f:00 14387 /lib/libc-2.1.2.so
4010d000-40111000 rw-p 000f0000 5f:00 14387 /lib/libc-2.1.2.so
40111000-40114000 rw-p 00000000 00:00 0
40114000-4011e000 r-xp 00000000 5f:00 14408 /lib/libnss_files-2.1.2.so
4011e000-4011f000 rw-p 00009000 5f:00 14408 /lib/libnss_files-2.1.2.so
7fffd000-80000000 rwxp ffffe000 00:00 0
some of these you can cat e.g. stdout (2)::
cat /proc/29/maps
on my machine emits::
00400000-00478000 r-xp 00000000 5f:00 4103 /bin/bash
00478000-0047e000 rw-p 00077000 5f:00 4103 /bin/bash
0047e000-00492000 rwxp 00000000 00:00 0
40000000-40015000 r-xp 00000000 5f:00 14382 /lib/ld-2.1.2.so
40015000-40016000 rw-p 00014000 5f:00 14382 /lib/ld-2.1.2.so
40016000-40017000 rwxp 00000000 00:00 0
40017000-40018000 rw-p 00000000 00:00 0
40018000-4001b000 r-xp 00000000 5f:00 14435 /lib/libtermcap.so.2.0.8
4001b000-4001c000 rw-p 00002000 5f:00 14435 /lib/libtermcap.so.2.0.8
4001c000-4010d000 r-xp 00000000 5f:00 14387 /lib/libc-2.1.2.so
4010d000-40111000 rw-p 000f0000 5f:00 14387 /lib/libc-2.1.2.so
40111000-40114000 rw-p 00000000 00:00 0
40114000-4011e000 r-xp 00000000 5f:00 14408 /lib/libnss_files-2.1.2.so
4011e000-4011f000 rw-p 00009000 5f:00 14408 /lib/libnss_files-2.1.2.so
7fffd000-80000000 rwxp ffffe000 00:00 0
Showing us the shared libraries init uses where they are in memory
& memory access permissions for each virtual memory area.
/proc/1/cwd is a softlink to the current working directory.
/proc/1/root is the root of the filesystem for this process.
/proc/1/mem is the current running processes memory which you
can read & write to like a file.
strace uses this sometimes as it is a bit faster than the
rather inefficient ptrace interface for peeking at DATA.
cat status
Name: init
State: S (sleeping)
Pid: 1
PPid: 0
Uid: 0 0 0 0
Gid: 0 0 0 0
Groups:
VmSize: 408 kB
VmLck: 0 kB
VmRSS: 208 kB
VmData: 24 kB
VmStk: 8 kB
VmExe: 368 kB
VmLib: 0 kB
SigPnd: 0000000000000000
SigBlk: 0000000000000000
SigIgn: 7fffffffd7f0d8fc
SigCgt: 00000000280b2603
CapInh: 00000000fffffeff
CapPrm: 00000000ffffffff
CapEff: 00000000fffffeff
User PSW: 070de000 80414146
task: 004b6000 tss: 004b62d8 ksp: 004b7ca8 pt_regs: 004b7f68
User GPRS:
00000400 00000000 0000000b 7ffffa90
00000000 00000000 00000000 0045d9f4
0045cafc 7ffffa90 7fffff18 0045cb08
00010400 804039e8 80403af8 7ffff8b0
User ACRS:
00000000 00000000 00000000 00000000
00000001 00000000 00000000 00000000
00000000 00000000 00000000 00000000
00000000 00000000 00000000 00000000
Kernel BackChain CallChain BackChain CallChain
::
cat status
Name: init
State: S (sleeping)
Pid: 1
PPid: 0
Uid: 0 0 0 0
Gid: 0 0 0 0
Groups:
VmSize: 408 kB
VmLck: 0 kB
VmRSS: 208 kB
VmData: 24 kB
VmStk: 8 kB
VmExe: 368 kB
VmLib: 0 kB
SigPnd: 0000000000000000
SigBlk: 0000000000000000
SigIgn: 7fffffffd7f0d8fc
SigCgt: 00000000280b2603
CapInh: 00000000fffffeff
CapPrm: 00000000ffffffff
CapEff: 00000000fffffeff
User PSW: 070de000 80414146
task: 004b6000 tss: 004b62d8 ksp: 004b7ca8 pt_regs: 004b7f68
User GPRS:
00000400 00000000 0000000b 7ffffa90
00000000 00000000 00000000 0045d9f4
0045cafc 7ffffa90 7fffff18 0045cb08
00010400 804039e8 80403af8 7ffff8b0
User ACRS:
00000000 00000000 00000000 00000000
00000001 00000000 00000000 00000000
00000000 00000000 00000000 00000000
00000000 00000000 00000000 00000000
Kernel BackChain CallChain BackChain CallChain
004b7ca8 8002bd0c 004b7d18 8002b92c
004b7db8 8005cd50 004b7e38 8005d12a
004b7f08 80019114
Showing among other things memory usage & status of some signals &
the processes'es registers from the kernel task_structure
as well as a backchain which may be useful if a process crashes
......@@ -2067,11 +2473,16 @@ debug feature
Some of our drivers now support a "debug feature" in
/proc/s390dbf see s390dbf.txt in the linux/Documentation directory
for more info.
e.g.
to switch on the lcs "debug feature"
echo 5 > /proc/s390dbf/lcs/level
& then after the error occurred.
cat /proc/s390dbf/lcs/sprintf >/logfile
to switch on the lcs "debug feature"::
echo 5 > /proc/s390dbf/lcs/level
& then after the error occurred::
cat /proc/s390dbf/lcs/sprintf >/logfile
the logfile now contains some information which may help
tech support resolve a problem in the field.
......@@ -2083,11 +2494,16 @@ ifconfig is a quite useful command
it gives the current state of network drivers.
If you suspect your network device driver is dead
one way to check is type
ifconfig <network device>
one way to check is type::
ifconfig <network device>
e.g. tr0
You should see something like
tr0 Link encap:16/4 Mbps Token Ring (New) HWaddr 00:04:AC:20:8E:48
You should see something like::
ifconfig tr0
tr0 Link encap:16/4 Mbps Token Ring (New) HWaddr 00:04:AC:20:8E:48
inet addr:9.164.185.132 Bcast:9.164.191.255 Mask:255.255.224.0
UP BROADCAST RUNNING MULTICAST MTU:2000 Metric:1
RX packets:246134 errors:0 dropped:0 overruns:0 frame:0
......@@ -2095,19 +2511,29 @@ tr0 Link encap:16/4 Mbps Token Ring (New) HWaddr 00:04:AC:20:8E:48
collisions:0 txqueuelen:100
if the device doesn't say up
try
/etc/rc.d/init.d/network start
try::
/etc/rc.d/init.d/network start
( this starts the network stack & hopefully calls ifconfig tr0 up ).
ifconfig looks at the output of /proc/net/dev and presents it in a more
presentable form.
Now ping the device from a machine in the same subnet.
if the RX packets count & TX packets counts don't increment you probably
have problems.
next
cat /proc/net/arp
next::
cat /proc/net/arp
Do you see any hardware addresses in the cache if not you may have problems.
Next try
ping -c 5 <broadcast_addr> i.e. the Bcast field above in the output of
Next try::
ping -c 5 <broadcast_addr>
i.e. the Bcast field above in the output of
ifconfig. Do you see any replies from machines other than the local machine
if not you may have problems. also if the TX packets count in ifconfig
hasn't incremented either you have serious problems in your driver
......@@ -2119,28 +2545,43 @@ chandev
-------
There is a new device layer for channel devices, some
drivers e.g. lcs are registered with this layer.
If the device uses the channel device layer you'll be
able to find what interrupts it uses & the current state
of the device.
See the manpage chandev.8 &type cat /proc/chandev for more info.
SysRq
=====
This is now supported by linux for s/390 & z/Architecture.
To enable it do compile the kernel with
Kernel Hacking -> Magic SysRq Key Enabled
echo "1" > /proc/sys/kernel/sysrq
also type
echo "8" >/proc/sys/kernel/printk
To enable it do compile the kernel with::
Kernel Hacking -> Magic SysRq Key Enabled
Then::
echo "1" > /proc/sys/kernel/sysrq
also type::
echo "8" >/proc/sys/kernel/printk
To make printk output go to console.
On 390 all commands are prefixed with
^-
e.g.
^-t will show tasks.
^-? or some unknown command will display help.
On 390 all commands are prefixed with::
^-
e.g.::
^-t will show tasks.
^-? or some unknown command will display help.
The sysrq key reading is very picky ( I have to type the keys in an
xterm session & paste them into the x3270 console )
xterm session & paste them into the x3270 console )
& it may be wise to predefine the keys as described in the VM hints above
This is particularly useful for syncing disks unmounting & rebooting
......@@ -2150,19 +2591,19 @@ Read Documentation/admin-guide/sysrq.rst for more info
References:
===========
Enterprise Systems Architecture Reference Summary
Enterprise Systems Architecture Principles of Operation
Hartmut Penners s390 stack frame sheet.
IBM Mainframe Channel Attachment a technology brief from a CISCO webpage
Various bits of man & info pages of Linux.
Linux & GDB source.
Various info & man pages.
CMS Help on tracing commands.
Linux for s/390 Elf Application Binary Interface
Linux for z/Series Elf Application Binary Interface ( Both Highly Recommended )
z/Architecture Principles of Operation SA22-7832-00
Enterprise Systems Architecture/390 Reference Summary SA22-7209-01 & the
Enterprise Systems Architecture/390 Principles of Operation SA22-7201-05
- Enterprise Systems Architecture Reference Summary
- Enterprise Systems Architecture Principles of Operation
- Hartmut Penners s390 stack frame sheet.
- IBM Mainframe Channel Attachment a technology brief from a CISCO webpage
- Various bits of man & info pages of Linux.
- Linux & GDB source.
- Various info & man pages.
- CMS Help on tracing commands.
- Linux for s/390 Elf Application Binary Interface
- Linux for z/Series Elf Application Binary Interface ( Both Highly Recommended )
- z/Architecture Principles of Operation SA22-7832-00
- Enterprise Systems Architecture/390 Reference Summary SA22-7209-01 & the
- Enterprise Systems Architecture/390 Principles of Operation SA22-7201-05
Special Thanks
==============
......
=============================
S/390 driver model interfaces
-----------------------------
=============================
1. CCW devices
--------------
......@@ -8,9 +9,9 @@ All devices which can be addressed by means of ccws are called 'CCW devices' -
even if they aren't actually driven by ccws.
All ccw devices are accessed via a subchannel, this is reflected in the
structures under devices/:
structures under devices/::
devices/
devices/
- system/
- css0/
- 0.0.0000/0.0.0815/
......@@ -35,14 +36,18 @@ be found under bus/ccw/devices/.
All ccw devices export some data via sysfs.
cutype: The control unit type / model.
cutype:
The control unit type / model.
devtype: The device type / model, if applicable.
devtype:
The device type / model, if applicable.
availability: Can be 'good' or 'boxed'; 'no path' or 'no device' for
availability:
Can be 'good' or 'boxed'; 'no path' or 'no device' for
disconnected devices.
online: An interface to set the device online and offline.
online:
An interface to set the device online and offline.
In the special case of the device being disconnected (see the
notify function under 1.2), piping 0 to online will forcibly delete
the device.
......@@ -52,9 +57,11 @@ The device drivers can add entries to export per-device data and interfaces.
There is also some data exported on a per-subchannel basis (see under
bus/css/devices/):
chpids: Via which chpids the device is connected.
chpids:
Via which chpids the device is connected.
pimpampom: The path installed, path available and path operational masks.
pimpampom:
The path installed, path available and path operational masks.
There also might be additional data, for example for block devices.
......@@ -74,9 +81,9 @@ b. After a. has been performed, if necessary, the device is finally brought up
------------------------------------
The basic struct ccw_device and struct ccw_driver data structures can be found
under include/asm/ccwdev.h.
under include/asm/ccwdev.h::
struct ccw_device {
struct ccw_device {
spinlock_t *ccwlock;
struct ccw_device_private *private;
struct ccw_device_id id;
......@@ -87,9 +94,9 @@ struct ccw_device {
void (*handler) (struct ccw_device *dev, unsigned long intparm,
struct irb *irb);
};
};
struct ccw_driver {
struct ccw_driver {
struct module *owner;
struct ccw_device_id *ids;
int (*probe) (struct ccw_device *);
......@@ -99,16 +106,16 @@ struct ccw_driver {
int (*notify) (struct ccw_device *, int);
struct device_driver driver;
char *name;
};
};
The 'private' field contains data needed for internal i/o operation only, and
is not available to the device driver.
Each driver should declare in a MODULE_DEVICE_TABLE into which CU types/models
and/or device types/models it is interested. This information can later be found
in the struct ccw_device_id fields:
in the struct ccw_device_id fields::
struct ccw_device_id {
struct ccw_device_id {
__u16 match_flags;
__u16 cu_type;
......@@ -117,34 +124,50 @@ struct ccw_device_id {
__u8 dev_model;
unsigned long driver_info;
};
};
The functions in ccw_driver should be used in the following way:
probe: This function is called by the device layer for each device the driver
probe:
This function is called by the device layer for each device the driver
is interested in. The driver should only allocate private structures
to put in dev->driver_data and create attributes (if needed). Also,
the interrupt handler (see below) should be set here.
int (*probe) (struct ccw_device *cdev);
::
int (*probe) (struct ccw_device *cdev);
Parameters: cdev - the device to be probed.
Parameters:
cdev
- the device to be probed.
remove: This function is called by the device layer upon removal of the driver,
remove:
This function is called by the device layer upon removal of the driver,
the device or the module. The driver should perform cleanups here.
int (*remove) (struct ccw_device *cdev);
::
Parameters: cdev - the device to be removed.
int (*remove) (struct ccw_device *cdev);
Parameters:
cdev
- the device to be removed.
set_online: This function is called by the common I/O layer when the device is
set_online:
This function is called by the common I/O layer when the device is
activated via the 'online' attribute. The driver should finally
setup and activate the device here.
int (*set_online) (struct ccw_device *);
::
int (*set_online) (struct ccw_device *);
Parameters: cdev - the device to be activated. The common layer has
Parameters:
cdev
- the device to be activated. The common layer has
verified that the device is not already online.
......@@ -152,15 +175,22 @@ set_offline: This function is called by the common I/O layer when the device is
de-activated via the 'online' attribute. The driver should shut
down the device, but not de-allocate its private data.
int (*set_offline) (struct ccw_device *);
::
int (*set_offline) (struct ccw_device *);
Parameters: cdev - the device to be deactivated. The common layer has
Parameters:
cdev
- the device to be deactivated. The common layer has
verified that the device is online.
notify: This function is called by the common I/O layer for some state changes
notify:
This function is called by the common I/O layer for some state changes
of the device.
Signalled to the driver are:
* In online state, device detached (CIO_GONE) or last path gone
(CIO_NO_PATH). The driver must return !0 to keep the device; for
return code 0, the device will be deleted as usual (also when no
......@@ -174,10 +204,16 @@ notify: This function is called by the common I/O layer for some state changes
wants the device back: !0 for keeping, 0 to make the device being
removed and re-registered.
int (*notify) (struct ccw_device *, int);
::
int (*notify) (struct ccw_device *, int);
Parameters:
cdev
- the device whose state changed.
Parameters: cdev - the device whose state changed.
event - the event that happened. This can be one of CIO_GONE,
event
- the event that happened. This can be one of CIO_GONE,
CIO_NO_PATH or CIO_OPER.
The handler field of the struct ccw_device is meant to be set to the interrupt
......@@ -189,7 +225,9 @@ before the driver is called, and is deregistered during set_offline() after the
driver has been called. Also, after registering / before deregistering, path
grouping resp. disbanding of the path group (if applicable) are performed.
void (*handler) (struct ccw_device *dev, unsigned long intparm, struct irb *irb);
::
void (*handler) (struct ccw_device *dev, unsigned long intparm, struct irb *irb);
Parameters: dev - the device the handler is called for
intparm - the intparm which allows the device driver to identify
......@@ -237,18 +275,22 @@ only the logical state and not the physical state, since we cannot track the
latter consistently due to lacking machine support (we don't need to be aware
of it anyway).
status - Can be 'online' or 'offline'.
status
- Can be 'online' or 'offline'.
Piping 'on' or 'off' sets the chpid logically online/offline.
Piping 'on' to an online chpid triggers path reprobing for all devices
the chpid connects to. This can be used to force the kernel to re-use
a channel path the user knows to be online, but the machine hasn't
created a machine check for.
type - The physical type of the channel path.
type
- The physical type of the channel path.
shared - Whether the channel path is shared.
shared
- Whether the channel path is shared.
cmg - The channel measurement group.
cmg
- The channel measurement group.
3. System devices
-----------------
......@@ -279,9 +321,8 @@ Netiucv connections show up under devices/iucv/ as "netiucv<ifnum>". The interfa
number is assigned sequentially to the connections defined via the 'connection'
attribute.
user - shows the connection partner.
buffer - maximum buffer size.
Pipe to it to change buffer size.
user
- shows the connection partner.
buffer
- maximum buffer size. Pipe to it to change buffer size.
:orphan:
=================
s390 Architecture
=================
.. toctree::
:maxdepth: 1
cds
3270
debugging390
driver-model
monreader
qeth
s390dbf
vfio-ap
vfio-ccw
zfcpdump
dasd
common_io
text_files
.. only:: subproject and html
Indices
=======
* :ref:`genindex`
=================================================
Linux API for read access to z/VM Monitor Records
=================================================
Date : 2004-Nov-26
Author: Gerald Schaefer (geraldsc@de.ibm.com)
Linux API for read access to z/VM Monitor Records
=================================================
Description
===========
This item delivers a new Linux API in the form of a misc char device that is
usable from user space and allows read access to the z/VM Monitor Records
collected by the *MONITOR System Service of z/VM.
collected by the `*MONITOR` System Service of z/VM.
User Requirements
=================
The z/VM guest on which you want to access this API needs to be configured in
order to allow IUCV connections to the *MONITOR service, i.e. it needs the
IUCV *MONITOR statement in its user entry. If the monitor DCSS to be used is
order to allow IUCV connections to the `*MONITOR` service, i.e. it needs the
IUCV `*MONITOR` statement in its user entry. If the monitor DCSS to be used is
restricted (likely), you also need the NAMESAVE <DCSS NAME> statement.
This item will use the IUCV device driver to access the z/VM services, so you
need a kernel with IUCV support. You also need z/VM version 4.4 or 5.1.
......@@ -50,7 +52,9 @@ Your guest virtual storage has to end below the starting address of the DCSS
and you have to specify the "mem=" kernel parameter in your parmfile with a
value greater than the ending address of the DCSS.
Example: DEF STOR 140M
Example::
DEF STOR 140M
This defines 140MB storage size for your guest, the parameter "mem=160M" is
added to the parmfile.
......@@ -66,24 +70,27 @@ kernel, the kernel parameter "monreader.mondcss=<DCSS NAME>" can be specified
in the parmfile.
The default name for the DCSS is "MONDCSS" if none is specified. In case that
there are other users already connected to the *MONITOR service (e.g.
there are other users already connected to the `*MONITOR` service (e.g.
Performance Toolkit), the monitor DCSS is already defined and you have to use
the same DCSS. The CP command Q MONITOR (Class E privileged) shows the name
of the monitor DCSS, if already defined, and the users connected to the
*MONITOR service.
`*MONITOR` service.
Refer to the "z/VM Performance" book (SC24-6109-00) on how to create a monitor
DCSS if your z/VM doesn't have one already, you need Class E privileges to
define and save a DCSS.
Example:
--------
modprobe monreader mondcss=MYDCSS
::
modprobe monreader mondcss=MYDCSS
This loads the module and sets the DCSS name to "MYDCSS".
NOTE:
-----
This API provides no interface to control the *MONITOR service, e.g. specify
This API provides no interface to control the `*MONITOR` service, e.g. specify
which data should be collected. This can be done by the CP command MONITOR
(Class E privileged), see "CP Command and Utility Reference".
......@@ -98,6 +105,7 @@ If your distribution does not support udev, a device node will not be created
automatically and you have to create it manually after loading the module.
Therefore you need to know the major and minor numbers of the device. These
numbers can be found in /sys/class/misc/monreader/dev.
Typing cat /sys/class/misc/monreader/dev will give an output of the form
<major>:<minor>. The device node can be created via the mknod command, enter
mknod <name> c <major> <minor>, where <name> is the name of the device node
......@@ -105,10 +113,13 @@ to be created.
Example:
--------
# modprobe monreader
# cat /sys/class/misc/monreader/dev
10:63
# mknod /dev/monreader c 10 63
::
# modprobe monreader
# cat /sys/class/misc/monreader/dev
10:63
# mknod /dev/monreader c 10 63
This loads the module with the default monitor DCSS (MONDCSS) and creates a
device node.
......@@ -133,20 +144,21 @@ last byte of data. The start address is needed to handle "end-of-frame" records
correctly (domain 1, record 13), i.e. it can be used to determine the record
start offset relative to a 4K page (frame) boundary.
See "Appendix A: *MONITOR" in the "z/VM Performance" document for a description
See "Appendix A: `*MONITOR`" in the "z/VM Performance" document for a description
of the monitor control element layout. The layout of the monitor records can
be found here (z/VM 5.1): http://www.vm.ibm.com/pubs/mon510/index.html
The layout of the data stream provided by the monreader device is as follows:
...
<0 byte read>
<first MCE> \
<first set of records> |
... |- data set
<last MCE> |
<last set of records> /
<0 byte read>
...
The layout of the data stream provided by the monreader device is as follows::
...
<0 byte read>
<first MCE> \
<first set of records> |
... |- data set
<last MCE> |
<last set of records> /
<0 byte read>
...
There may be more than one combination of MCE and corresponding record set
within one data set and the end of each data set is indicated by a successful
......@@ -165,14 +177,18 @@ As with most char devices, error conditions are indicated by returning a
negative value for the number of bytes read. In this case, the errno variable
indicates the error condition:
EIO: reply failed, read data is invalid and the application
EIO:
reply failed, read data is invalid and the application
should discard the data read since the last successful read with 0 size.
EFAULT: copy_to_user failed, read data is invalid and the application should
EFAULT:
copy_to_user failed, read data is invalid and the application should
discard the data read since the last successful read with 0 size.
EAGAIN: occurs on a non-blocking read if there is no data available at the
EAGAIN:
occurs on a non-blocking read if there is no data available at the
moment. There is no data missing or corrupted, just try again or rather
use polling for non-blocking reads.
EOVERFLOW: message limit reached, the data read since the last successful
EOVERFLOW:
message limit reached, the data read since the last successful
read with 0 size is valid but subsequent records may be missing.
In the last case (EOVERFLOW) there may be missing data, in the first two cases
......@@ -183,7 +199,7 @@ Open:
-----
Only one user is allowed to open the char device. If it is already in use, the
open function will fail (return a negative value) and set errno to EBUSY.
The open function may also fail if an IUCV connection to the *MONITOR service
The open function may also fail if an IUCV connection to the `*MONITOR` service
cannot be established. In this case errno will be set to EIO and an error
message with an IPUSER SEVER code will be printed into syslog. The IPUSER SEVER
codes are described in the "z/VM Performance" book, Appendix A.
......@@ -194,4 +210,3 @@ As soon as the device is opened, incoming messages will be accepted and they
will account for the message limit, i.e. opening the device without reading
from it will provoke the "message limit reached" error (EOVERFLOW error code)
eventually.
=============================
IBM s390 QDIO Ethernet Driver
=============================
OSA and HiperSockets Bridge Port Support
========================================
Uevents
-------
To generate the events the device must be assigned a role of either
a primary or a secondary Bridge Port. For more information, see
......@@ -13,12 +17,15 @@ of some configured Bridge Port device on the channel changes, a udev
event with ACTION=CHANGE is emitted on behalf of the corresponding
ccwgroup device. The event has the following attributes:
BRIDGEPORT=statechange - indicates that the Bridge Port device changed
BRIDGEPORT=statechange
indicates that the Bridge Port device changed
its state.
ROLE={primary|secondary|none} - the role assigned to the port.
ROLE={primary|secondary|none}
the role assigned to the port.
STATE={active|standby|inactive} - the newly assumed state of the port.
STATE={active|standby|inactive}
the newly assumed state of the port.
When run on HiperSockets Bridge Capable Port hardware with host address
notifications enabled, a udev event with ACTION=CHANGE is emitted.
......@@ -26,25 +33,32 @@ It is emitted on behalf of the corresponding ccwgroup device when a host
or a VLAN is registered or unregistered on the network served by the device.
The event has the following attributes:
BRIDGEDHOST={reset|register|deregister|abort} - host address
BRIDGEDHOST={reset|register|deregister|abort}
host address
notifications are started afresh, a new host or VLAN is registered or
deregistered on the Bridge Port HiperSockets channel, or address
notifications are aborted.
VLAN=numeric-vlan-id - VLAN ID on which the event occurred. Not included
VLAN=numeric-vlan-id
VLAN ID on which the event occurred. Not included
if no VLAN is involved in the event.
MAC=xx:xx:xx:xx:xx:xx - MAC address of the host that is being registered
MAC=xx:xx:xx:xx:xx:xx
MAC address of the host that is being registered
or deregistered from the HiperSockets channel. Not reported if the
event reports the creation or destruction of a VLAN.
NTOK_BUSID=x.y.zzzz - device bus ID (CSSID, SSID and device number).
NTOK_BUSID=x.y.zzzz
device bus ID (CSSID, SSID and device number).
NTOK_IID=xx - device IID.
NTOK_IID=xx
device IID.
NTOK_CHPID=xx - device CHPID.
NTOK_CHPID=xx
device CHPID.
NTOK_CHID=xxxx - device channel ID.
NTOK_CHID=xxxx
device channel ID.
Note that the NTOK_* attributes refer to devices other than the one
Note that the `NTOK_*` attributes refer to devices other than the one
connected to the system on which the OS is running.
==================
S390 Debug Feature
==================
files: arch/s390/kernel/debug.c
arch/s390/include/asm/debug.h
files:
- arch/s390/kernel/debug.c
- arch/s390/include/asm/debug.h
Description:
------------
......@@ -11,9 +13,11 @@ where log records can be stored efficiently in memory, where each component
(e.g. device drivers) can have one separate debug log.
One purpose of this is to inspect the debug logs after a production system crash
in order to analyze the reason for the crash.
If the system still runs but only a subcomponent which uses dbf fails,
it is possible to look at the debug logs on a live system via the Linux
debugfs filesystem.
The debug feature may also very useful for kernel and driver development.
Design:
......@@ -76,183 +80,287 @@ through writing a number string "x" to the 'level' debugfs file which is
provided for every debug log. Debugging can be switched off completely
by using "-" on the 'level' debugfs file.
Example:
Example::
> echo "-" > /sys/kernel/debug/s390dbf/dasd/level
> echo "-" > /sys/kernel/debug/s390dbf/dasd/level
It is also possible to deactivate the debug feature globally for every
debug log. You can change the behavior using 2 sysctl parameters in
/proc/sys/s390dbf:
There are currently 2 possible triggers, which stop the debug feature
globally. The first possibility is to use the "debug_active" sysctl. If
set to 1 the debug feature is running. If "debug_active" is set to 0 the
debug feature is turned off.
The second trigger which stops the debug feature is a kernel oops.
That prevents the debug feature from overwriting debug information that
happened before the oops. After an oops you can reactivate the debug feature
by piping 1 to /proc/sys/s390dbf/debug_active. Nevertheless, its not
suggested to use an oopsed kernel in a production environment.
If you want to disallow the deactivation of the debug feature, you can use
the "debug_stoppable" sysctl. If you set "debug_stoppable" to 0 the debug
feature cannot be stopped. If the debug feature is already stopped, it
will stay deactivated.
----------------------------------------------------------------------------
Kernel Interfaces:
------------------
----------------------------------------------------------------------------
debug_info_t *debug_register(char *name, int pages, int nr_areas,
::
debug_info_t *debug_register(char *name, int pages, int nr_areas,
int buf_size);
Parameter: name: Name of debug log (e.g. used for debugfs entry)
pages: number of pages, which will be allocated per area
nr_areas: number of debug areas
buf_size: size of data area in each debug entry
Parameter:
name:
Name of debug log (e.g. used for debugfs entry)
pages:
Number of pages, which will be allocated per area
nr_areas:
Number of debug areas
buf_size:
Size of data area in each debug entry
Return Value:
Handle for generated debug area
Return Value: Handle for generated debug area
NULL if register failed
Description: Allocates memory for a debug log
Must not be called within an interrupt handler
----------------------------------------------------------------------------
debug_info_t *debug_register_mode(char *name, int pages, int nr_areas,
::
debug_info_t *debug_register_mode(char *name, int pages, int nr_areas,
int buf_size, mode_t mode, uid_t uid,
gid_t gid);
Parameter: name: Name of debug log (e.g. used for debugfs entry)
pages: Number of pages, which will be allocated per area
nr_areas: Number of debug areas
buf_size: Size of data area in each debug entry
mode: File mode for debugfs files. E.g. S_IRWXUGO
uid: User ID for debugfs files. Currently only 0 is
Parameter:
name:
Name of debug log (e.g. used for debugfs entry)
pages:
Number of pages, which will be allocated per area
nr_areas:
Number of debug areas
buf_size:
Size of data area in each debug entry
mode:
File mode for debugfs files. E.g. S_IRWXUGO
uid:
User ID for debugfs files. Currently only 0 is
supported.
gid: Group ID for debugfs files. Currently only 0 is
gid:
Group ID for debugfs files. Currently only 0 is
supported.
Return Value: Handle for generated debug area
Return Value:
Handle for generated debug area
NULL if register failed
Description: Allocates memory for a debug log
Description:
Allocates memory for a debug log
Must not be called within an interrupt handler
---------------------------------------------------------------------------
void debug_unregister (debug_info_t * id);
Parameter: id: handle for debug log
::
Return Value: none
void debug_unregister (debug_info_t * id);
Description: frees memory for a debug log and removes all registered debug
Parameter:
id:
handle for debug log
Return Value:
none
Description:
frees memory for a debug log and removes all registered debug
views.
Must not be called within an interrupt handler
---------------------------------------------------------------------------
void debug_set_level (debug_info_t * id, int new_level);
::
void debug_set_level (debug_info_t * id, int new_level);
Parameter: id: handle for debug log
new_level: new debug level
Return Value: none
Return Value:
none
Description: Sets new actual debug level if new_level is valid.
Description:
Sets new actual debug level if new_level is valid.
---------------------------------------------------------------------------
bool debug_level_enabled (debug_info_t * id, int level);
Parameter: id: handle for debug log
level: debug level
::
Return Value: True if level is less or equal to the current debug level.
bool debug_level_enabled (debug_info_t * id, int level);
Description: Returns true if debug events for the specified level would be
Parameter:
id:
handle for debug log
level:
debug level
Return Value:
True if level is less or equal to the current debug level.
Description:
Returns true if debug events for the specified level would be
logged. Otherwise returns false.
---------------------------------------------------------------------------
void debug_stop_all(void);
Parameter: none
::
Return Value: none
void debug_stop_all(void);
Description: stops the debug feature if stopping is allowed. Currently
Parameter:
none
Return Value:
none
Description:
stops the debug feature if stopping is allowed. Currently
used in case of a kernel oops.
---------------------------------------------------------------------------
debug_entry_t* debug_event (debug_info_t* id, int level, void* data,
::
debug_entry_t* debug_event (debug_info_t* id, int level, void* data,
int length);
Parameter: id: handle for debug log
level: debug level
data: pointer to data for debug entry
length: length of data in bytes
Parameter:
id:
handle for debug log
level:
debug level
data:
pointer to data for debug entry
length:
length of data in bytes
Return Value: Address of written debug entry
Return Value:
Address of written debug entry
Description: writes debug entry to active debug area (if level <= actual
Description:
writes debug entry to active debug area (if level <= actual
debug level)
---------------------------------------------------------------------------
debug_entry_t* debug_int_event (debug_info_t * id, int level,
::
debug_entry_t* debug_int_event (debug_info_t * id, int level,
unsigned int data);
debug_entry_t* debug_long_event(debug_info_t * id, int level,
debug_entry_t* debug_long_event(debug_info_t * id, int level,
unsigned long data);
Parameter: id: handle for debug log
level: debug level
data: integer value for debug entry
Parameter:
id:
handle for debug log
level:
debug level
data:
integer value for debug entry
Return Value: Address of written debug entry
Return Value:
Address of written debug entry
Description: writes debug entry to active debug area (if level <= actual
Description:
writes debug entry to active debug area (if level <= actual
debug level)
---------------------------------------------------------------------------
debug_entry_t* debug_text_event (debug_info_t * id, int level,
::
debug_entry_t* debug_text_event (debug_info_t * id, int level,
const char* data);
Parameter: id: handle for debug log
level: debug level
data: string for debug entry
Parameter:
id:
handle for debug log
level:
debug level
data:
string for debug entry
Return Value: Address of written debug entry
Return Value:
Address of written debug entry
Description: writes debug entry in ascii format to active debug area
Description:
writes debug entry in ascii format to active debug area
(if level <= actual debug level)
---------------------------------------------------------------------------
debug_entry_t* debug_sprintf_event (debug_info_t * id, int level,
::
debug_entry_t* debug_sprintf_event (debug_info_t * id, int level,
char* string,...);
Parameter: id: handle for debug log
level: debug level
string: format string for debug entry
...: varargs used as in sprintf()
Parameter:
id:
handle for debug log
level:
debug level
string:
format string for debug entry
...:
varargs used as in sprintf()
Return Value: Address of written debug entry
Description: writes debug entry with format string and varargs (longs) to
Description:
writes debug entry with format string and varargs (longs) to
active debug area (if level $<=$ actual debug level).
floats and long long datatypes cannot be used as varargs.
---------------------------------------------------------------------------
debug_entry_t* debug_exception (debug_info_t* id, int level, void* data,
::
debug_entry_t* debug_exception (debug_info_t* id, int level, void* data,
int length);
Parameter: id: handle for debug log
level: debug level
data: pointer to data for debug entry
length: length of data in bytes
Parameter:
id:
handle for debug log
level:
debug level
data:
pointer to data for debug entry
length:
length of data in bytes
Return Value: Address of written debug entry
Return Value:
Address of written debug entry
Description: writes debug entry to active debug area (if level <= actual
Description:
writes debug entry to active debug area (if level <= actual
debug level) and switches to next debug area
---------------------------------------------------------------------------
debug_entry_t* debug_int_exception (debug_info_t * id, int level,
::
debug_entry_t* debug_int_exception (debug_info_t * id, int level,
unsigned int data);
debug_entry_t* debug_long_exception(debug_info_t * id, int level,
debug_entry_t* debug_long_exception(debug_info_t * id, int level,
unsigned long data);
Parameter: id: handle for debug log
......@@ -265,7 +373,10 @@ Description: writes debug entry to active debug area (if level <= actual
debug level) and switches to next debug area
---------------------------------------------------------------------------
debug_entry_t* debug_text_exception (debug_info_t * id, int level,
::
debug_entry_t* debug_text_exception (debug_info_t * id, int level,
const char* data);
Parameter: id: handle for debug log
......@@ -279,7 +390,10 @@ Description: writes debug entry in ascii format to active debug area
area
---------------------------------------------------------------------------
debug_entry_t* debug_sprintf_exception (debug_info_t * id, int level,
::
debug_entry_t* debug_sprintf_exception (debug_info_t * id, int level,
char* string,...);
Parameter: id: handle for debug log
......@@ -296,7 +410,9 @@ Description: writes debug entry with format string and varargs (longs) to
---------------------------------------------------------------------------
int debug_register_view (debug_info_t * id, struct debug_view *view);
::
int debug_register_view (debug_info_t * id, struct debug_view *view);
Parameter: id: handle for debug log
view: pointer to debug view struct
......@@ -307,7 +423,10 @@ Return Value: 0 : ok
Description: registers new debug view and creates debugfs dir entry
---------------------------------------------------------------------------
int debug_unregister_view (debug_info_t * id, struct debug_view *view);
::
int debug_unregister_view (debug_info_t * id, struct debug_view *view);
Parameter: id: handle for debug log
view: pointer to debug view struct
......@@ -323,23 +442,27 @@ Predefined views:
-----------------
extern struct debug_view debug_hex_ascii_view;
extern struct debug_view debug_raw_view;
extern struct debug_view debug_sprintf_view;
Examples
--------
/*
::
/*
* hex_ascii- + raw-view Example
*/
#include <linux/init.h>
#include <asm/debug.h>
#include <linux/init.h>
#include <asm/debug.h>
static debug_info_t* debug_info;
static debug_info_t* debug_info;
static int init(void)
{
static int init(void)
{
/* register 4 debug areas with one page each and 4 byte data field */
debug_info = debug_register ("test", 1, 4, 4 );
......@@ -351,29 +474,31 @@ static int init(void)
debug_event(debug_info, 3, &debug_info, 4);
return 0;
}
}
static void cleanup(void)
{
static void cleanup(void)
{
debug_unregister (debug_info);
}
}
module_init(init);
module_exit(cleanup);
module_init(init);
module_exit(cleanup);
---------------------------------------------------------------------------
/*
::
/*
* sprintf-view Example
*/
#include <linux/init.h>
#include <asm/debug.h>
#include <linux/init.h>
#include <asm/debug.h>
static debug_info_t* debug_info;
static debug_info_t* debug_info;
static int init(void)
{
static int init(void)
{
/* register 4 debug areas with one page each and data field for */
/* format string pointer + 2 varargs (= 3 * sizeof(long)) */
......@@ -384,52 +509,50 @@ static int init(void)
debug_sprintf_exception(debug_info, 1, "pointer to debug info: %p\n",&debug_info);
return 0;
}
}
static void cleanup(void)
{
static void cleanup(void)
{
debug_unregister (debug_info);
}
module_init(init);
module_exit(cleanup);
}
module_init(init);
module_exit(cleanup);
Debugfs Interface
----------------
-----------------
Views to the debug logs can be investigated through reading the corresponding
debugfs-files:
Example:
> ls /sys/kernel/debug/s390dbf/dasd
flush hex_ascii level pages raw
> cat /sys/kernel/debug/s390dbf/dasd/hex_ascii | sort -k2,2 -s
00 00974733272:680099 2 - 02 0006ad7e 07 ea 4a 90 | ....
00 00974733272:682210 2 - 02 0006ade6 46 52 45 45 | FREE
00 00974733272:682213 2 - 02 0006adf6 07 ea 4a 90 | ....
00 00974733272:682281 1 * 02 0006ab08 41 4c 4c 43 | EXCP
01 00974733272:682284 2 - 02 0006ab16 45 43 4b 44 | ECKD
01 00974733272:682287 2 - 02 0006ab28 00 00 00 04 | ....
01 00974733272:682289 2 - 02 0006ab3e 00 00 00 20 | ...
01 00974733272:682297 2 - 02 0006ad7e 07 ea 4a 90 | ....
01 00974733272:684384 2 - 00 0006ade6 46 52 45 45 | FREE
01 00974733272:684388 2 - 00 0006adf6 07 ea 4a 90 | ....
Example::
> ls /sys/kernel/debug/s390dbf/dasd
flush hex_ascii level pages raw
> cat /sys/kernel/debug/s390dbf/dasd/hex_ascii | sort -k2,2 -s
00 00974733272:680099 2 - 02 0006ad7e 07 ea 4a 90 | ....
00 00974733272:682210 2 - 02 0006ade6 46 52 45 45 | FREE
00 00974733272:682213 2 - 02 0006adf6 07 ea 4a 90 | ....
00 00974733272:682281 1 * 02 0006ab08 41 4c 4c 43 | EXCP
01 00974733272:682284 2 - 02 0006ab16 45 43 4b 44 | ECKD
01 00974733272:682287 2 - 02 0006ab28 00 00 00 04 | ....
01 00974733272:682289 2 - 02 0006ab3e 00 00 00 20 | ...
01 00974733272:682297 2 - 02 0006ad7e 07 ea 4a 90 | ....
01 00974733272:684384 2 - 00 0006ade6 46 52 45 45 | FREE
01 00974733272:684388 2 - 00 0006adf6 07 ea 4a 90 | ....
See section about predefined views for explanation of the above output!
Changing the debug level
------------------------
Example:
Example::
> cat /sys/kernel/debug/s390dbf/dasd/level
3
> echo "5" > /sys/kernel/debug/s390dbf/dasd/level
> cat /sys/kernel/debug/s390dbf/dasd/level
5
> cat /sys/kernel/debug/s390dbf/dasd/level
3
> echo "5" > /sys/kernel/debug/s390dbf/dasd/level
> cat /sys/kernel/debug/s390dbf/dasd/level
5
Flushing debug areas
--------------------
......@@ -439,11 +562,13 @@ are flushed.
Examples:
1. Flush debug area 0:
> echo "0" > /sys/kernel/debug/s390dbf/dasd/flush
1. Flush debug area 0::
> echo "0" > /sys/kernel/debug/s390dbf/dasd/flush
2. Flush all debug areas:
> echo "-" > /sys/kernel/debug/s390dbf/dasd/flush
2. Flush all debug areas::
> echo "-" > /sys/kernel/debug/s390dbf/dasd/flush
Changing the size of debug areas
------------------------------------
......@@ -453,17 +578,21 @@ also flush the debug areas.
Example:
Define 4 pages for the debug areas of debug feature "dasd":
> echo "4" > /sys/kernel/debug/s390dbf/dasd/pages
Define 4 pages for the debug areas of debug feature "dasd"::
> echo "4" > /sys/kernel/debug/s390dbf/dasd/pages
Stooping the debug feature
--------------------------
Example:
1. Check if stopping is allowed
> cat /proc/sys/s390dbf/debug_stoppable
2. Stop debug feature
> echo 0 > /proc/sys/s390dbf/debug_active
1. Check if stopping is allowed::
> cat /proc/sys/s390dbf/debug_stoppable
2. Stop debug feature::
> echo 0 > /proc/sys/s390dbf/debug_active
lcrash Interface
----------------
......@@ -506,18 +635,21 @@ and for each vararg a long value. So e.g. for a debug entry with a format
string plus two varargs one would need to allocate a (3 * sizeof(long))
byte data area in the debug_register() function.
IMPORTANT: Using "%s" in sprintf event functions is dangerous. You can only
use "%s" in the sprintf event functions, if the memory for the passed string is
available as long as the debug feature exists. The reason behind this is that
due to performance considerations only a pointer to the string is stored in
the debug feature. If you log a string that is freed afterwards, you will get
an OOPS when inspecting the debug feature, because then the debug feature will
access the already freed memory.
IMPORTANT:
Using "%s" in sprintf event functions is dangerous. You can only
use "%s" in the sprintf event functions, if the memory for the passed string
is available as long as the debug feature exists. The reason behind this is
that due to performance considerations only a pointer to the string is stored
in the debug feature. If you log a string that is freed afterwards, you will
get an OOPS when inspecting the debug feature, because then the debug feature
will access the already freed memory.
NOTE: If using the sprintf view do NOT use other event/exception functions
than the sprintf-event and -exception functions.
NOTE:
If using the sprintf view do NOT use other event/exception functions
than the sprintf-event and -exception functions.
The format of the hex_ascii and sprintf view is as follows:
- Number of area
- Timestamp (formatted as seconds and microseconds since 00:00:00 Coordinated
Universal Time (UTC), January 1, 1970)
......@@ -528,6 +660,7 @@ The format of the hex_ascii and sprintf view is as follows:
- data field
The format of the raw view is:
- Header as described in debug.h
- datafield
......@@ -543,32 +676,32 @@ Defining views
--------------
Views are specified with the 'debug_view' structure. There are defined
callback functions which are used for reading and writing the debugfs files:
callback functions which are used for reading and writing the debugfs files::
struct debug_view {
struct debug_view {
char name[DEBUG_MAX_PROCF_LEN];
debug_prolog_proc_t* prolog_proc;
debug_header_proc_t* header_proc;
debug_format_proc_t* format_proc;
debug_input_proc_t* input_proc;
void* private_data;
};
};
where
where::
typedef int (debug_header_proc_t) (debug_info_t* id,
typedef int (debug_header_proc_t) (debug_info_t* id,
struct debug_view* view,
int area,
debug_entry_t* entry,
char* out_buf);
typedef int (debug_format_proc_t) (debug_info_t* id,
typedef int (debug_format_proc_t) (debug_info_t* id,
struct debug_view* view, char* out_buf,
const char* in_buf);
typedef int (debug_prolog_proc_t) (debug_info_t* id,
typedef int (debug_prolog_proc_t) (debug_info_t* id,
struct debug_view* view,
char* out_buf);
typedef int (debug_input_proc_t) (debug_info_t* id,
typedef int (debug_input_proc_t) (debug_info_t* id,
struct debug_view* view,
struct file* file, const char* user_buf,
size_t in_buf_size, loff_t* offset);
......@@ -577,14 +710,14 @@ typedef int (debug_input_proc_t) (debug_info_t* id,
The "private_data" member can be used as pointer to view specific data.
It is not used by the debug feature itself.
The output when reading a debugfs file is structured like this:
The output when reading a debugfs file is structured like this::
"prolog_proc output"
"prolog_proc output"
"header_proc output 1" "format_proc output 1"
"header_proc output 2" "format_proc output 2"
"header_proc output 3" "format_proc output 3"
...
"header_proc output 1" "format_proc output 1"
"header_proc output 2" "format_proc output 2"
"header_proc output 3" "format_proc output 3"
...
When a view is read from the debugfs, the Debug Feature calls the
'prolog_proc' once for writing the prolog.
......@@ -597,32 +730,33 @@ the view (e.g. like with 'echo "0" > /sys/kernel/debug/s390dbf/dasd/level).
For header_proc there can be used the default function
debug_dflt_header_fn() which is defined in debug.h.
and which produces the same header output as the predefined views.
E.g:
00 00964419409:440761 2 - 00 88023ec
E.g::
00 00964419409:440761 2 - 00 88023ec
In order to see how to use the callback functions check the implementation
of the default views!
Example
Example::
#include <asm/debug.h>
#include <asm/debug.h>
#define UNKNOWNSTR "data: %08x"
#define UNKNOWNSTR "data: %08x"
const char* messages[] =
{"This error...........\n",
const char* messages[] =
{"This error...........\n",
"That error...........\n",
"Problem..............\n",
"Something went wrong.\n",
"Everything ok........\n",
NULL
};
};
static int debug_test_format_fn(
static int debug_test_format_fn(
debug_info_t * id, struct debug_view *view,
char *out_buf, const char *in_buf
)
{
)
{
int i, rc = 0;
if(id->buf_size >= 4) {
......@@ -634,34 +768,36 @@ static int debug_test_format_fn(
}
out:
return rc;
}
}
struct debug_view debug_test_view = {
struct debug_view debug_test_view = {
"myview", /* name of view */
NULL, /* no prolog */
&debug_dflt_header_fn, /* default header for each entry */
&debug_test_format_fn, /* our own format function */
NULL, /* no input function */
NULL /* no private data */
};
};
=====
test:
=====
debug_info_t *debug_info;
...
debug_info = debug_register ("test", 0, 4, 4 ));
debug_register_view(debug_info, &debug_test_view);
for(i = 0; i < 10; i ++) debug_int_event(debug_info, 1, i);
> cat /sys/kernel/debug/s390dbf/test/myview
00 00964419734:611402 1 - 00 88042ca This error...........
00 00964419734:611405 1 - 00 88042ca That error...........
00 00964419734:611408 1 - 00 88042ca Problem..............
00 00964419734:611411 1 - 00 88042ca Something went wrong.
00 00964419734:611414 1 - 00 88042ca Everything ok........
00 00964419734:611417 1 - 00 88042ca data: 00000005
00 00964419734:611419 1 - 00 88042ca data: 00000006
00 00964419734:611422 1 - 00 88042ca data: 00000007
00 00964419734:611425 1 - 00 88042ca data: 00000008
00 00964419734:611428 1 - 00 88042ca data: 00000009
::
debug_info_t *debug_info;
...
debug_info = debug_register ("test", 0, 4, 4 ));
debug_register_view(debug_info, &debug_test_view);
for(i = 0; i < 10; i ++) debug_int_event(debug_info, 1, i);
> cat /sys/kernel/debug/s390dbf/test/myview
00 00964419734:611402 1 - 00 88042ca This error...........
00 00964419734:611405 1 - 00 88042ca That error...........
00 00964419734:611408 1 - 00 88042ca Problem..............
00 00964419734:611411 1 - 00 88042ca Something went wrong.
00 00964419734:611414 1 - 00 88042ca Everything ok........
00 00964419734:611417 1 - 00 88042ca data: 00000005
00 00964419734:611419 1 - 00 88042ca data: 00000006
00 00964419734:611422 1 - 00 88042ca data: 00000007
00 00964419734:611425 1 - 00 88042ca data: 00000008
00 00964419734:611428 1 - 00 88042ca data: 00000009
ibm 3270 changelog
------------------
.. include:: 3270.ChangeLog
:literal:
ibm 3270 config3270.sh
----------------------
.. literalinclude:: config3270.sh
:language: shell
Introduction:
===============================
Adjunct Processor (AP) facility
===============================
Introduction
============
The Adjunct Processor (AP) facility is an IBM Z cryptographic facility comprised
of three AP instructions and from 1 up to 256 PCIe cryptographic adapter cards.
......@@ -11,7 +16,7 @@ framework. This implementation relies considerably on the s390 virtualization
facilities which do most of the hard work of providing direct access to AP
devices.
AP Architectural Overview:
AP Architectural Overview
=========================
To facilitate the comprehension of the design, let's start with some
definitions:
......@@ -31,13 +36,13 @@ definitions:
in the LPAR, the AP bus detects the AP adapter cards assigned to the LPAR and
creates a sysfs device for each assigned adapter. For example, if AP adapters
4 and 10 (0x0a) are assigned to the LPAR, the AP bus will create the following
sysfs device entries:
sysfs device entries::
/sys/devices/ap/card04
/sys/devices/ap/card0a
Symbolic links to these devices will also be created in the AP bus devices
sub-directory:
sub-directory::
/sys/bus/ap/devices/[card04]
/sys/bus/ap/devices/[card04]
......@@ -84,7 +89,7 @@ definitions:
the cross product of the AP adapter and usage domain numbers detected when the
AP bus module is loaded. For example, if adapters 4 and 10 (0x0a) and usage
domains 6 and 71 (0x47) are assigned to the LPAR, the AP bus will create the
following sysfs entries:
following sysfs entries::
/sys/devices/ap/card04/04.0006
/sys/devices/ap/card04/04.0047
......@@ -92,7 +97,7 @@ definitions:
/sys/devices/ap/card0a/0a.0047
The following symbolic links to these devices will be created in the AP bus
devices subdirectory:
devices subdirectory::
/sys/bus/ap/devices/[04.0006]
/sys/bus/ap/devices/[04.0047]
......@@ -112,7 +117,7 @@ definitions:
domain that is not one of the usage domains, but the modified domain
must be one of the control domains.
AP and SIE:
AP and SIE
==========
Let's now take a look at how AP instructions executed on a guest are interpreted
by the hardware.
......@@ -153,7 +158,7 @@ and 2 and usage domains 5 and 6 are assigned to a guest, the APQNs (1,5), (1,6),
The APQNs can provide secure key functionality - i.e., a private key is stored
on the adapter card for each of its domains - so each APQN must be assigned to
at most one guest or to the linux host.
at most one guest or to the linux host::
Example 1: Valid configuration:
------------------------------
......@@ -181,8 +186,8 @@ at most one guest or to the linux host.
This is an invalid configuration because both guests have access to
APQN (1,6).
The Design:
===========
The Design
==========
The design introduces three new objects:
1. AP matrix device
......@@ -205,7 +210,7 @@ The VFIO AP (vfio_ap) device driver serves the following purposes:
Reserve APQNs for exclusive use of KVM guests
---------------------------------------------
The following block diagram illustrates the mechanism by which APQNs are
reserved:
reserved::
+------------------+
7 remove | |
......@@ -214,29 +219,29 @@ reserved:
| +------------------+
|
|
| +------------------+ +-----------------+
| +------------------+ +----------------+
| 5 register driver | | 3 create | |
| +----------------> Device core +----------> matrix device |
| | | | | |
| | +--------^---------+ +-----------------+
| | +--------^---------+ +----------------+
| | |
| | +-------------------+
| | +-----------------------------------+ |
| | | 4 register AP driver | | 2 register device
| | | | |
+--------+---+-v---+ +--------+-------+-+
| | | |
| ap_bus +--------------------- > vfio_ap driver |
| | 8 probe | |
+--------^---------+ +--^--^------------+
6 edit | | |
+--------+---+-v---+ +--------+-------+-+
| | | |
| ap_bus +--------------------- > vfio_ap driver |
| | 8 probe | |
+--------^---------+ +--^--^------------+
6 edit | | |
apmask | +-----------------------------+ | 9 mdev create
aqmask | | 1 modprobe |
+--------+-----+---+ +----------------+-+ +------------------+
| | | |8 create | mediated |
| admin | | VFIO device core |---------> matrix |
| + | | | device |
+------+-+---------+ +--------^---------+ +--------^---------+
+--------+-----+---+ +----------------+-+ +----------------+
| | | |8 create | mediated |
| admin | | VFIO device core |---------> matrix |
| + | | | device |
+------+-+---------+ +--------^---------+ +--------^-------+
| | | |
| | 9 create vfio_ap-passthrough | |
| +------------------------------+ |
......@@ -250,7 +255,7 @@ The process for reserving an AP queue for use by a KVM guest is:
device with the device core. This will serve as the parent device for
all mediated matrix devices used to configure an AP matrix for a guest.
3. The /sys/devices/vfio_ap/matrix device is created by the device core
4 The vfio_ap device driver will register with the AP bus for AP queue devices
4. The vfio_ap device driver will register with the AP bus for AP queue devices
of type 10 and higher (CEX4 and newer). The driver will provide the vfio_ap
driver's probe and remove callback interfaces. Devices older than CEX4 queues
are not supported to simplify the implementation by not needlessly
......@@ -266,13 +271,14 @@ The process for reserving an AP queue for use by a KVM guest is:
it.
9. The administrator creates a passthrough type mediated matrix device to be
used by a guest
10 The administrator assigns the adapters, usage domains and control domains
10. The administrator assigns the adapters, usage domains and control domains
to be exclusively used by a guest.
Set up the VFIO mediated device interfaces
------------------------------------------
The VFIO AP device driver utilizes the common interface of the VFIO mediated
device core driver to:
* Register an AP mediated bus driver to add a mediated matrix device to and
remove it from a VFIO group.
* Create and destroy a mediated matrix device
......@@ -280,7 +286,7 @@ device core driver to:
* Add a mediated matrix device to and remove it from an IOMMU group
The following high-level block diagram shows the main components and interfaces
of the VFIO AP mediated matrix device driver:
of the VFIO AP mediated matrix device driver::
+-------------+
| |
......@@ -306,7 +312,8 @@ structures, mdev functions and callback interfaces for managing the mediated
matrix device.
* sysfs attribute structures:
* supported_type_groups
supported_type_groups
The VFIO mediated device framework supports creation of user-defined
mediated device types. These mediated device types are specified
via the 'supported_type_groups' structure when a device is registered
......@@ -318,61 +325,72 @@ matrix device.
The VFIO AP device driver will register one mediated device type for
passthrough devices:
/sys/devices/vfio_ap/matrix/mdev_supported_types/vfio_ap-passthrough
Only the read-only attributes required by the VFIO mdev framework will
be provided:
be provided::
... name
... device_api
... available_instances
... device_api
Where:
* name: specifies the name of the mediated device type
* device_api: the mediated device type's API
* available_instances: the number of mediated matrix passthrough devices
* name:
specifies the name of the mediated device type
* device_api:
the mediated device type's API
* available_instances:
the number of mediated matrix passthrough devices
that can be created
* device_api: specifies the VFIO API
* mdev_attr_groups
* device_api:
specifies the VFIO API
mdev_attr_groups
This attribute group identifies the user-defined sysfs attributes of the
mediated device. When a device is registered with the VFIO mediated device
framework, the sysfs attribute files identified in the 'mdev_attr_groups'
structure will be created in the mediated matrix device's directory. The
sysfs attributes for a mediated matrix device are:
* assign_adapter:
* unassign_adapter:
assign_adapter / unassign_adapter:
Write-only attributes for assigning/unassigning an AP adapter to/from the
mediated matrix device. To assign/unassign an adapter, the APID of the
adapter is echoed to the respective attribute file.
* assign_domain:
* unassign_domain:
assign_domain / unassign_domain:
Write-only attributes for assigning/unassigning an AP usage domain to/from
the mediated matrix device. To assign/unassign a domain, the domain
number of the the usage domain is echoed to the respective attribute
file.
* matrix:
matrix:
A read-only file for displaying the APQNs derived from the cross product
of the adapter and domain numbers assigned to the mediated matrix device.
* assign_control_domain:
* unassign_control_domain:
assign_control_domain / unassign_control_domain:
Write-only attributes for assigning/unassigning an AP control domain
to/from the mediated matrix device. To assign/unassign a control domain,
the ID of the domain to be assigned/unassigned is echoed to the respective
attribute file.
* control_domains:
control_domains:
A read-only file for displaying the control domain numbers assigned to the
mediated matrix device.
* functions:
* create:
create:
allocates the ap_matrix_mdev structure used by the vfio_ap driver to:
* Store the reference to the KVM structure for the guest using the mdev
* Store the AP matrix configuration for the adapters, domains, and control
domains assigned via the corresponding sysfs attributes files
* remove:
remove:
deallocates the mediated matrix device's ap_matrix_mdev structure. This will
be allowed only if a running guest is not using the mdev.
* callback interfaces
* open:
open:
The vfio_ap driver uses this callback to register a
VFIO_GROUP_NOTIFY_SET_KVM notifier callback function for the mdev matrix
device. The open is invoked when QEMU connects the VFIO iommu group
......@@ -380,16 +398,17 @@ matrix device.
to configure the KVM guest is provided via this callback. The KVM structure,
is used to configure the guest's access to the AP matrix defined via the
mediated matrix device's sysfs attribute files.
* release:
release:
unregisters the VFIO_GROUP_NOTIFY_SET_KVM notifier callback function for the
mdev matrix device and deconfigures the guest's AP matrix.
Configure the APM, AQM and ADM in the CRYCB:
Configure the APM, AQM and ADM in the CRYCB
-------------------------------------------
Configuring the AP matrix for a KVM guest will be performed when the
VFIO_GROUP_NOTIFY_SET_KVM notifier callback is invoked. The notifier
function is called when QEMU connects to KVM. The guest's AP matrix is
configured via it's CRYCB by:
* Setting the bits in the APM corresponding to the APIDs assigned to the
mediated matrix device via its 'assign_adapter' interface.
* Setting the bits in the AQM corresponding to the domains assigned to the
......@@ -418,12 +437,12 @@ available to a KVM guest via the following CPU model features:
Note: If the user chooses to specify a CPU model different than the 'host'
model to QEMU, the CPU model features and facilities need to be turned on
explicitly; for example:
explicitly; for example::
/usr/bin/qemu-system-s390x ... -cpu z13,ap=on,apqci=on,apft=on
A guest can be precluded from using AP features/facilities by turning them off
explicitly; for example:
explicitly; for example::
/usr/bin/qemu-system-s390x ... -cpu host,ap=off,apqci=off,apft=off
......@@ -435,7 +454,7 @@ the APFT facility is not installed on the guest, then the probe of device
drivers will fail since only type 10 and newer devices can be configured for
guest use.
Example:
Example
=======
Let's now provide an example to illustrate how KVM guests may be given
access to AP facilities. For this example, we will show how to configure
......@@ -444,30 +463,36 @@ look like this:
Guest1
------
=========== ===== ============
CARD.DOMAIN TYPE MODE
------------------------------
=========== ===== ============
05 CEX5C CCA-Coproc
05.0004 CEX5C CCA-Coproc
05.00ab CEX5C CCA-Coproc
06 CEX5A Accelerator
06.0004 CEX5A Accelerator
06.00ab CEX5C CCA-Coproc
=========== ===== ============
Guest2
------
=========== ===== ============
CARD.DOMAIN TYPE MODE
------------------------------
=========== ===== ============
05 CEX5A Accelerator
05.0047 CEX5A Accelerator
05.00ff CEX5A Accelerator
=========== ===== ============
Guest2
------
=========== ===== ============
CARD.DOMAIN TYPE MODE
------------------------------
=========== ===== ============
06 CEX5A Accelerator
06.0047 CEX5A Accelerator
06.00ff CEX5A Accelerator
=========== ===== ============
These are the steps:
......@@ -492,7 +517,8 @@ These are the steps:
* VFIO_MDEV_DEVICE
* KVM
If using make menuconfig select the following to build the vfio_ap module:
If using make menuconfig select the following to build the vfio_ap module::
-> Device Drivers
-> IOMMU Hardware Support
select S390 AP IOMMU Support
......@@ -507,7 +533,7 @@ These are the steps:
bitmasks marking a subset of the APQN range as 'usable by the default AP
queue device drivers' or 'not usable by the default device drivers' and thus
available for use by the vfio_ap device driver'. The location of the sysfs
files containing the masks are:
files containing the masks are::
/sys/bus/ap/apmask
/sys/bus/ap/aqmask
......@@ -526,7 +552,7 @@ These are the steps:
queue device drivers; otherwise, the APQI is usable by the vfio_ap device
driver.
Take, for example, the following mask:
Take, for example, the following mask::
0x7dffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff
......@@ -550,7 +576,7 @@ These are the steps:
* An absolute hex string starting with 0x - like "0x12345678" - sets
the mask. If the given string is shorter than the mask, it is padded
with 0s on the right; for example, specifying a mask value of 0x41 is
the same as specifying:
the same as specifying::
0x4100000000000000000000000000000000000000000000000000000000000000
......@@ -567,15 +593,17 @@ These are the steps:
the corresponding bit is to be switched on ('+') or off ('-'). Some
valid values are:
"+0" switches bit 0 on
"-13" switches bit 13 off
"+0x41" switches bit 65 on
"-0xff" switches bit 255 off
- "+0" switches bit 0 on
- "-13" switches bit 13 off
- "+0x41" switches bit 65 on
- "-0xff" switches bit 255 off
The following example:
+0,-6,+0x47,-0xf0
Switches bits 0 and 71 (0x47) on
Switches bits 6 and 240 (0xf0) off
Note that the bits not specified in the list remain as they were before
......@@ -586,7 +614,7 @@ These are the steps:
ap.apmask=0xffff ap.aqmask=0x40
This would create the following masks:
This would create the following masks::
apmask:
0xffff000000000000000000000000000000000000000000000000000000000000
......@@ -594,22 +622,22 @@ These are the steps:
aqmask:
0x4000000000000000000000000000000000000000000000000000000000000000
Resulting in these two pools:
Resulting in these two pools::
default drivers pool: adapter 0-15, domain 1
alternate drivers pool: adapter 16-255, domains 0, 2-255
Securing the APQNs for our example:
----------------------------------
Securing the APQNs for our example
----------------------------------
To secure the AP queues 05.0004, 05.0047, 05.00ab, 05.00ff, 06.0004, 06.0047,
06.00ab, and 06.00ff for use by the vfio_ap device driver, the corresponding
APQNs can either be removed from the default masks:
APQNs can either be removed from the default masks::
echo -5,-6 > /sys/bus/ap/apmask
echo -4,-0x47,-0xab,-0xff > /sys/bus/ap/aqmask
Or the masks can be set as follows:
Or the masks can be set as follows::
echo 0xf9ffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff \
> apmask
......@@ -620,7 +648,7 @@ These are the steps:
This will result in AP queues 05.0004, 05.0047, 05.00ab, 05.00ff, 06.0004,
06.0047, 06.00ab, and 06.00ff getting bound to the vfio_ap device driver. The
sysfs directory for the vfio_ap device driver will now contain symbolic links
to the AP queue devices bound to it:
to the AP queue devices bound to it::
/sys/bus/ap
... [drivers]
......@@ -652,7 +680,7 @@ These are the steps:
3. Create the mediated devices needed to configure the AP matrixes for the
three guests and to provide an interface to the vfio_ap driver for
use by the guests:
use by the guests::
/sys/devices/vfio_ap/matrix/
--- [mdev_supported_types]
......@@ -660,7 +688,7 @@ These are the steps:
--------- create
--------- [devices]
To create the mediated devices for the three guests:
To create the mediated devices for the three guests::
uuidgen > create
uuidgen > create
......@@ -674,7 +702,7 @@ These are the steps:
This will create three mediated devices in the [devices] subdirectory named
after the UUID written to the create attribute file. We call them $uuid1,
$uuid2 and $uuid3 and this is the sysfs directory structure after creation:
$uuid2 and $uuid3 and this is the sysfs directory structure after creation::
/sys/devices/vfio_ap/matrix/
--- [mdev_supported_types]
......@@ -710,7 +738,7 @@ These are the steps:
4. The administrator now needs to configure the matrixes for the mediated
devices $uuid1 (for Guest1), $uuid2 (for Guest2) and $uuid3 (for Guest3).
This is how the matrix is configured for Guest1:
This is how the matrix is configured for Guest1::
echo 5 > assign_adapter
echo 6 > assign_adapter
......@@ -724,17 +752,17 @@ These are the steps:
you can use the unassign_xxx files to unassign the adapter, domain or
control domain.
To display the matrix configuration for Guest1:
To display the matrix configuration for Guest1::
cat matrix
This is how the matrix is configured for Guest2:
This is how the matrix is configured for Guest2::
echo 5 > assign_adapter
echo 0x47 > assign_domain
echo 0xff > assign_domain
This is how the matrix is configured for Guest3:
This is how the matrix is configured for Guest3::
echo 6 > assign_adapter
echo 0x47 > assign_domain
......@@ -783,24 +811,24 @@ These are the steps:
configured for the system. If a control domain number higher than the maximum
is specified, the operation will terminate with an error (ENODEV).
5. Start Guest1:
5. Start Guest1::
/usr/bin/qemu-system-s390x ... -cpu host,ap=on,apqci=on,apft=on \
-device vfio-ap,sysfsdev=/sys/devices/vfio_ap/matrix/$uuid1 ...
7. Start Guest2:
7. Start Guest2::
/usr/bin/qemu-system-s390x ... -cpu host,ap=on,apqci=on,apft=on \
-device vfio-ap,sysfsdev=/sys/devices/vfio_ap/matrix/$uuid2 ...
7. Start Guest3:
7. Start Guest3::
/usr/bin/qemu-system-s390x ... -cpu host,ap=on,apqci=on,apft=on \
-device vfio-ap,sysfsdev=/sys/devices/vfio_ap/matrix/$uuid3 ...
When the guest is shut down, the mediated matrix devices may be removed.
Using our example again, to remove the mediated matrix device $uuid1:
Using our example again, to remove the mediated matrix device $uuid1::
/sys/devices/vfio_ap/matrix/
--- [mdev_supported_types]
......@@ -809,18 +837,19 @@ Using our example again, to remove the mediated matrix device $uuid1:
------------ [$uuid1]
--------------- remove
::
echo 1 > remove
This will remove all of the mdev matrix device's sysfs structures including
the mdev device itself. To recreate and reconfigure the mdev matrix device,
all of the steps starting with step 3 will have to be performed again. Note
that the remove will fail if a guest using the mdev is still running.
This will remove all of the mdev matrix device's sysfs structures including
the mdev device itself. To recreate and reconfigure the mdev matrix device,
all of the steps starting with step 3 will have to be performed again. Note
that the remove will fail if a guest using the mdev is still running.
It is not necessary to remove an mdev matrix device, but one may want to
remove it if no guest will use it during the remaining lifetime of the linux
host. If the mdev matrix device is removed, one may want to also reconfigure
the pool of adapters and queues reserved for use by the default drivers.
It is not necessary to remove an mdev matrix device, but one may want to
remove it if no guest will use it during the remaining lifetime of the linux
host. If the mdev matrix device is removed, one may want to also reconfigure
the pool of adapters and queues reserved for use by the default drivers.
Limitations
===========
......
==================================
vfio-ccw: the basic infrastructure
==================================
......@@ -11,9 +12,11 @@ virtual machine, while vfio is the means.
Different than other hardware architectures, s390 has defined a unified
I/O access method, which is so called Channel I/O. It has its own access
patterns:
- Channel programs run asynchronously on a separate (co)processor.
- The channel subsystem will access any memory designated by the caller
in the channel program directly, i.e. there is no iommu involved.
Thus when we introduce vfio support for these devices, we realize it
with a mediated device (mdev) implementation. The vfio mdev will be
added to an iommu group, so as to make itself able to be managed by the
......@@ -24,6 +27,7 @@ to perform I/O instructions.
This document does not intend to explain the s390 I/O architecture in
every detail. More information/reference could be found here:
- A good start to know Channel I/O in general:
https://en.wikipedia.org/wiki/Channel_I/O
- s390 architecture:
......@@ -80,6 +84,7 @@ until interrupted. The I/O completion result is received by the
interrupt handler in the form of interrupt response block (IRB).
Back to vfio-ccw, in short:
- ORBs and channel programs are built in guest kernel (with guest
physical addresses).
- ORBs and channel programs are passed to the host kernel.
......@@ -106,6 +111,7 @@ it gets sent to hardware.
Within this implementation, we have two drivers for two types of
devices:
- The vfio_ccw driver for the physical subchannel device.
This is an I/O subchannel driver for the real subchannel device. It
realizes a group of callbacks and registers to the mdev framework as a
......@@ -137,7 +143,7 @@ devices:
vfio_pin_pages and a vfio_unpin_pages interfaces from the vfio iommu
backend for the physical devices to pin and unpin pages by demand.
Below is a high Level block diagram.
Below is a high Level block diagram::
+-------------+
| |
......@@ -158,6 +164,7 @@ Below is a high Level block diagram.
+-------------+
The process of how these work together.
1. vfio_ccw.ko drives the physical I/O subchannel, and registers the
physical device (with callbacks) to mdev framework.
When vfio_ccw probing the subchannel device, it registers device
......@@ -178,17 +185,17 @@ vfio-ccw I/O region
An I/O region is used to accept channel program request from user
space and store I/O interrupt result for user space to retrieve. The
definition of the region is:
definition of the region is::
struct ccw_io_region {
#define ORB_AREA_SIZE 12
struct ccw_io_region {
#define ORB_AREA_SIZE 12
__u8 orb_area[ORB_AREA_SIZE];
#define SCSW_AREA_SIZE 12
#define SCSW_AREA_SIZE 12
__u8 scsw_area[SCSW_AREA_SIZE];
#define IRB_AREA_SIZE 96
#define IRB_AREA_SIZE 96
__u8 irb_area[IRB_AREA_SIZE];
__u32 ret_code;
} __packed;
} __packed;
While starting an I/O request, orb_area should be filled with the
guest ORB, and scsw_area should be filled with the SCSW of the Virtual
......@@ -205,7 +212,7 @@ vfio-ccw follows what vfio-pci did on the s390 platform and uses
vfio-iommu-type1 as the vfio iommu backend.
* CCW translation APIs
A group of APIs (start with 'cp_') to do CCW translation. The CCWs
A group of APIs (start with `cp_`) to do CCW translation. The CCWs
passed in by a user space program are organized with their guest
physical memory addresses. These APIs will copy the CCWs into kernel
space, and assemble a runnable kernel channel program by updating the
......@@ -217,12 +224,14 @@ vfio-iommu-type1 as the vfio iommu backend.
This driver utilizes the CCW translation APIs and introduces
vfio_ccw, which is the driver for the I/O subchannel devices you want
to pass through.
vfio_ccw implements the following vfio ioctls:
vfio_ccw implements the following vfio ioctls::
VFIO_DEVICE_GET_INFO
VFIO_DEVICE_GET_IRQ_INFO
VFIO_DEVICE_GET_REGION_INFO
VFIO_DEVICE_RESET
VFIO_DEVICE_SET_IRQS
This provides an I/O region, so that the user space program can pass a
channel program to the kernel, to do further CCW translation before
issuing them to a real device.
......@@ -236,32 +245,49 @@ bit more detail how an I/O request triggered by the QEMU guest will be
handled (without error handling).
Explanation:
Q1-Q7: QEMU side process.
K1-K5: Kernel side process.
Q1. Get I/O region info during initialization.
Q2. Setup event notifier and handler to handle I/O completion.
- Q1-Q7: QEMU side process.
- K1-K5: Kernel side process.
Q1.
Get I/O region info during initialization.
Q2.
Setup event notifier and handler to handle I/O completion.
... ...
Q3. Intercept a ssch instruction.
Q4. Write the guest channel program and ORB to the I/O region.
K1. Copy from guest to kernel.
K2. Translate the guest channel program to a host kernel space
Q3.
Intercept a ssch instruction.
Q4.
Write the guest channel program and ORB to the I/O region.
K1.
Copy from guest to kernel.
K2.
Translate the guest channel program to a host kernel space
channel program, which becomes runnable for a real device.
K3. With the necessary information contained in the orb passed in
K3.
With the necessary information contained in the orb passed in
by QEMU, issue the ccwchain to the device.
K4. Return the ssch CC code.
Q5. Return the CC code to the guest.
K4.
Return the ssch CC code.
Q5.
Return the CC code to the guest.
... ...
K5. Interrupt handler gets the I/O result and write the result to
K5.
Interrupt handler gets the I/O result and write the result to
the I/O region.
K6. Signal QEMU to retrieve the result.
Q6. Get the signal and event handler reads out the result from the I/O
K6.
Signal QEMU to retrieve the result.
Q6.
Get the signal and event handler reads out the result from the I/O
region.
Q7. Update the irb for the guest.
Q7.
Update the irb for the guest.
Limitations
-----------
......@@ -295,6 +321,6 @@ Reference
1. ESA/s390 Principles of Operation manual (IBM Form. No. SA22-7832)
2. ESA/390 Common I/O Device Commands manual (IBM Form. No. SA22-7204)
3. https://en.wikipedia.org/wiki/Channel_I/O
4. Documentation/s390/cds.txt
4. Documentation/s390/cds.rst
5. Documentation/vfio.txt
6. Documentation/vfio-mediated-device.txt
==================================
The s390 SCSI dump tool (zfcpdump)
==================================
System z machines (z900 or higher) provide hardware support for creating system
dumps on SCSI disks. The dump process is initiated by booting a dump tool, which
......
......@@ -13703,7 +13703,7 @@ L: linux-s390@vger.kernel.org
L: kvm@vger.kernel.org
S: Supported
F: drivers/s390/cio/vfio_ccw*
F: Documentation/s390/vfio-ccw.txt
F: Documentation/s390/vfio-ccw.rst
F: include/uapi/linux/vfio_ccw.h
S390 ZCRYPT DRIVER
......@@ -13723,7 +13723,7 @@ S: Supported
F: drivers/s390/crypto/vfio_ap_drv.c
F: drivers/s390/crypto/vfio_ap_private.h
F: drivers/s390/crypto/vfio_ap_ops.c
F: Documentation/s390/vfio-ap.txt
F: Documentation/s390/vfio-ap.rst
S390 ZFCP DRIVER
M: Steffen Maier <maier@linux.ibm.com>
......
......@@ -810,9 +810,9 @@ config CRASH_DUMP
Crash dump kernels are loaded in the main kernel with kexec-tools
into a specially reserved region and then later executed after
a crash by kdump/kexec.
Refer to <file:Documentation/s390/zfcpdump.txt> for more details on this.
Refer to <file:Documentation/s390/zfcpdump.rst> for more details on this.
This option also enables s390 zfcpdump.
See also <file:Documentation/s390/zfcpdump.txt>
See also <file:Documentation/s390/zfcpdump.rst>
endmenu
......
......@@ -152,7 +152,7 @@ static inline debug_entry_t *debug_text_event(debug_info_t *id, int level,
/*
* IMPORTANT: Use "%s" in sprintf format strings with care! Only pointers are
* stored in the s390dbf. See Documentation/s390/s390dbf.txt for more details!
* stored in the s390dbf. See Documentation/s390/s390dbf.rst for more details!
*/
extern debug_entry_t *
__debug_sprintf_event(debug_info_t *id, int level, char *string, ...)
......@@ -210,7 +210,7 @@ static inline debug_entry_t *debug_text_exception(debug_info_t *id, int level,
/*
* IMPORTANT: Use "%s" in sprintf format strings with care! Only pointers are
* stored in the s390dbf. See Documentation/s390/s390dbf.txt for more details!
* stored in the s390dbf. See Documentation/s390/s390dbf.rst for more details!
*/
extern debug_entry_t *
__debug_sprintf_exception(debug_info_t *id, int level, char *string, ...)
......
......@@ -4,7 +4,7 @@
* dumps on SCSI disks (zfcpdump). The "zcore/mem" debugfs file shows the same
* dump format as s390 standalone dumps.
*
* For more information please refer to Documentation/s390/zfcpdump.txt
* For more information please refer to Documentation/s390/zfcpdump.rst
*
* Copyright IBM Corp. 2003, 2008
* Author(s): Michael Holzheu
......
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