cds.txt 21 KB

123456789101112131415161718192021222324252627282930313233343536373839404142434445464748495051525354555657585960616263646566676869707172737475767778798081828384858687888990919293949596979899100101102103104105106107108109110111112113114115116117118119120121122123124125126127128129130131132133134135136137138139140141142143144145146147148149150151152153154155156157158159160161162163164165166167168169170171172173174175176177178179180181182183184185186187188189190191192193194195196197198199200201202203204205206207208209210211212213214215216217218219220221222223224225226227228229230231232233234235236237238239240241242243244245246247248249250251252253254255256257258259260261262263264265266267268269270271272273274275276277278279280281282283284285286287288289290291292293294295296297298299300301302303304305306307308309310311312313314315316317318319320321322323324325326327328329330331332333334335336337338339340341342343344345346347348349350351352353354355356357358359360361362363364365366367368369370371372373374375376377378379380381382383384385386387388389390391392393394395396397398399400401402403404405406407408409410411412413414415416417418419420421422423424425426427428429430431432433434435436437438439440441442443444445446447448449450451452453454455456457458459460461462463464465466467468469470471472473
  1. Linux for S/390 and zSeries
  2. Common Device Support (CDS)
  3. Device Driver I/O Support Routines
  4. Authors : Ingo Adlung
  5. Cornelia Huck
  6. Copyright, IBM Corp. 1999-2002
  7. Introduction
  8. This document describes the common device support routines for Linux/390.
  9. Different than other hardware architectures, ESA/390 has defined a unified
  10. I/O access method. This gives relief to the device drivers as they don't
  11. have to deal with different bus types, polling versus interrupt
  12. processing, shared versus non-shared interrupt processing, DMA versus port
  13. I/O (PIO), and other hardware features more. However, this implies that
  14. either every single device driver needs to implement the hardware I/O
  15. attachment functionality itself, or the operating system provides for a
  16. unified method to access the hardware, providing all the functionality that
  17. every single device driver would have to provide itself.
  18. The document does not intend to explain the ESA/390 hardware architecture in
  19. every detail.This information can be obtained from the ESA/390 Principles of
  20. Operation manual (IBM Form. No. SA22-7201).
  21. In order to build common device support for ESA/390 I/O interfaces, a
  22. functional layer was introduced that provides generic I/O access methods to
  23. the hardware.
  24. The common device support layer comprises the I/O support routines defined
  25. below. Some of them implement common Linux device driver interfaces, while
  26. some of them are ESA/390 platform specific.
  27. Note:
  28. In order to write a driver for S/390, you also need to look into the interface
  29. described in Documentation/s390/driver-model.txt.
  30. Note for porting drivers from 2.4:
  31. The major changes are:
  32. * The functions use a ccw_device instead of an irq (subchannel).
  33. * All drivers must define a ccw_driver (see driver-model.txt) and the associated
  34. functions.
  35. * request_irq() and free_irq() are no longer done by the driver.
  36. * The oper_handler is (kindof) replaced by the probe() and set_online() functions
  37. of the ccw_driver.
  38. * The not_oper_handler is (kindof) replaced by the remove() and set_offline()
  39. functions of the ccw_driver.
  40. * The channel device layer is gone.
  41. * The interrupt handlers must be adapted to use a ccw_device as argument.
  42. Moreover, they don't return a devstat, but an irb.
  43. * Before initiating an io, the options must be set via ccw_device_set_options().
  44. * Instead of calling read_dev_chars()/read_conf_data(), the driver issues
  45. the channel program and handles the interrupt itself.
  46. ccw_device_get_ciw()
  47. get commands from extended sense data.
  48. ccw_device_start()
  49. ccw_device_start_timeout()
  50. ccw_device_start_key()
  51. ccw_device_start_key_timeout()
  52. initiate an I/O request.
  53. ccw_device_resume()
  54. resume channel program execution.
  55. ccw_device_halt()
  56. terminate the current I/O request processed on the device.
  57. do_IRQ()
  58. generic interrupt routine. This function is called by the interrupt entry
  59. routine whenever an I/O interrupt is presented to the system. The do_IRQ()
  60. routine determines the interrupt status and calls the device specific
  61. interrupt handler according to the rules (flags) defined during I/O request
  62. initiation with do_IO().
  63. The next chapters describe the functions other than do_IRQ() in more details.
  64. The do_IRQ() interface is not described, as it is called from the Linux/390
  65. first level interrupt handler only and does not comprise a device driver
  66. callable interface. Instead, the functional description of do_IO() also
  67. describes the input to the device specific interrupt handler.
  68. Note: All explanations apply also to the 64 bit architecture s390x.
  69. Common Device Support (CDS) for Linux/390 Device Drivers
  70. General Information
  71. The following chapters describe the I/O related interface routines the
  72. Linux/390 common device support (CDS) provides to allow for device specific
  73. driver implementations on the IBM ESA/390 hardware platform. Those interfaces
  74. intend to provide the functionality required by every device driver
  75. implementation to allow to drive a specific hardware device on the ESA/390
  76. platform. Some of the interface routines are specific to Linux/390 and some
  77. of them can be found on other Linux platforms implementations too.
  78. Miscellaneous function prototypes, data declarations, and macro definitions
  79. can be found in the architecture specific C header file
  80. linux/arch/s390/include/asm/irq.h.
  81. Overview of CDS interface concepts
  82. Different to other hardware platforms, the ESA/390 architecture doesn't define
  83. interrupt lines managed by a specific interrupt controller and bus systems
  84. that may or may not allow for shared interrupts, DMA processing, etc.. Instead,
  85. the ESA/390 architecture has implemented a so called channel subsystem, that
  86. provides a unified view of the devices physically attached to the systems.
  87. Though the ESA/390 hardware platform knows about a huge variety of different
  88. peripheral attachments like disk devices (aka. DASDs), tapes, communication
  89. controllers, etc. they can all be accessed by a well defined access method and
  90. they are presenting I/O completion a unified way : I/O interruptions. Every
  91. single device is uniquely identified to the system by a so called subchannel,
  92. where the ESA/390 architecture allows for 64k devices be attached.
  93. Linux, however, was first built on the Intel PC architecture, with its two
  94. cascaded 8259 programmable interrupt controllers (PICs), that allow for a
  95. maximum of 15 different interrupt lines. All devices attached to such a system
  96. share those 15 interrupt levels. Devices attached to the ISA bus system must
  97. not share interrupt levels (aka. IRQs), as the ISA bus bases on edge triggered
  98. interrupts. MCA, EISA, PCI and other bus systems base on level triggered
  99. interrupts, and therewith allow for shared IRQs. However, if multiple devices
  100. present their hardware status by the same (shared) IRQ, the operating system
  101. has to call every single device driver registered on this IRQ in order to
  102. determine the device driver owning the device that raised the interrupt.
  103. Up to kernel 2.4, Linux/390 used to provide interfaces via the IRQ (subchannel).
  104. For internal use of the common I/O layer, these are still there. However,
  105. device drivers should use the new calling interface via the ccw_device only.
  106. During its startup the Linux/390 system checks for peripheral devices. Each
  107. of those devices is uniquely defined by a so called subchannel by the ESA/390
  108. channel subsystem. While the subchannel numbers are system generated, each
  109. subchannel also takes a user defined attribute, the so called device number.
  110. Both subchannel number and device number cannot exceed 65535. During sysfs
  111. initialisation, the information about control unit type and device types that
  112. imply specific I/O commands (channel command words - CCWs) in order to operate
  113. the device are gathered. Device drivers can retrieve this set of hardware
  114. information during their initialization step to recognize the devices they
  115. support using the information saved in the struct ccw_device given to them.
  116. This methods implies that Linux/390 doesn't require to probe for free (not
  117. armed) interrupt request lines (IRQs) to drive its devices with. Where
  118. applicable, the device drivers can use issue the READ DEVICE CHARACTERISTICS
  119. ccw to retrieve device characteristics in its online routine.
  120. In order to allow for easy I/O initiation the CDS layer provides a
  121. ccw_device_start() interface that takes a device specific channel program (one
  122. or more CCWs) as input sets up the required architecture specific control blocks
  123. and initiates an I/O request on behalf of the device driver. The
  124. ccw_device_start() routine allows to specify whether it expects the CDS layer
  125. to notify the device driver for every interrupt it observes, or with final status
  126. only. See ccw_device_start() for more details. A device driver must never issue
  127. ESA/390 I/O commands itself, but must use the Linux/390 CDS interfaces instead.
  128. For long running I/O request to be canceled, the CDS layer provides the
  129. ccw_device_halt() function. Some devices require to initially issue a HALT
  130. SUBCHANNEL (HSCH) command without having pending I/O requests. This function is
  131. also covered by ccw_device_halt().
  132. get_ciw() - get command information word
  133. This call enables a device driver to get information about supported commands
  134. from the extended SenseID data.
  135. struct ciw *
  136. ccw_device_get_ciw(struct ccw_device *cdev, __u32 cmd);
  137. cdev - The ccw_device for which the command is to be retrieved.
  138. cmd - The command type to be retrieved.
  139. ccw_device_get_ciw() returns:
  140. NULL - No extended data available, invalid device or command not found.
  141. !NULL - The command requested.
  142. ccw_device_start() - Initiate I/O Request
  143. The ccw_device_start() routines is the I/O request front-end processor. All
  144. device driver I/O requests must be issued using this routine. A device driver
  145. must not issue ESA/390 I/O commands itself. Instead the ccw_device_start()
  146. routine provides all interfaces required to drive arbitrary devices.
  147. This description also covers the status information passed to the device
  148. driver's interrupt handler as this is related to the rules (flags) defined
  149. with the associated I/O request when calling ccw_device_start().
  150. int ccw_device_start(struct ccw_device *cdev,
  151. struct ccw1 *cpa,
  152. unsigned long intparm,
  153. __u8 lpm,
  154. unsigned long flags);
  155. int ccw_device_start_timeout(struct ccw_device *cdev,
  156. struct ccw1 *cpa,
  157. unsigned long intparm,
  158. __u8 lpm,
  159. unsigned long flags,
  160. int expires);
  161. int ccw_device_start_key(struct ccw_device *cdev,
  162. struct ccw1 *cpa,
  163. unsigned long intparm,
  164. __u8 lpm,
  165. __u8 key,
  166. unsigned long flags);
  167. int ccw_device_start_key_timeout(struct ccw_device *cdev,
  168. struct ccw1 *cpa,
  169. unsigned long intparm,
  170. __u8 lpm,
  171. __u8 key,
  172. unsigned long flags,
  173. int expires);
  174. cdev : ccw_device the I/O is destined for
  175. cpa : logical start address of channel program
  176. user_intparm : user specific interrupt information; will be presented
  177. back to the device driver's interrupt handler. Allows a
  178. device driver to associate the interrupt with a
  179. particular I/O request.
  180. lpm : defines the channel path to be used for a specific I/O
  181. request. A value of 0 will make cio use the opm.
  182. key : the storage key to use for the I/O (useful for operating on a
  183. storage with a storage key != default key)
  184. flag : defines the action to be performed for I/O processing
  185. expires : timeout value in jiffies. The common I/O layer will terminate
  186. the running program after this and call the interrupt handler
  187. with ERR_PTR(-ETIMEDOUT) as irb.
  188. Possible flag values are :
  189. DOIO_ALLOW_SUSPEND - channel program may become suspended
  190. DOIO_DENY_PREFETCH - don't allow for CCW prefetch; usually
  191. this implies the channel program might
  192. become modified
  193. DOIO_SUPPRESS_INTER - don't call the handler on intermediate status
  194. The cpa parameter points to the first format 1 CCW of a channel program :
  195. struct ccw1 {
  196. __u8 cmd_code;/* command code */
  197. __u8 flags; /* flags, like IDA addressing, etc. */
  198. __u16 count; /* byte count */
  199. __u32 cda; /* data address */
  200. } __attribute__ ((packed,aligned(8)));
  201. with the following CCW flags values defined :
  202. CCW_FLAG_DC - data chaining
  203. CCW_FLAG_CC - command chaining
  204. CCW_FLAG_SLI - suppress incorrect length
  205. CCW_FLAG_SKIP - skip
  206. CCW_FLAG_PCI - PCI
  207. CCW_FLAG_IDA - indirect addressing
  208. CCW_FLAG_SUSPEND - suspend
  209. Via ccw_device_set_options(), the device driver may specify the following
  210. options for the device:
  211. DOIO_EARLY_NOTIFICATION - allow for early interrupt notification
  212. DOIO_REPORT_ALL - report all interrupt conditions
  213. The ccw_device_start() function returns :
  214. 0 - successful completion or request successfully initiated
  215. -EBUSY - The device is currently processing a previous I/O request, or there is
  216. a status pending at the device.
  217. -ENODEV - cdev is invalid, the device is not operational or the ccw_device is
  218. not online.
  219. When the I/O request completes, the CDS first level interrupt handler will
  220. accumulate the status in a struct irb and then call the device interrupt handler.
  221. The intparm field will contain the value the device driver has associated with a
  222. particular I/O request. If a pending device status was recognized,
  223. intparm will be set to 0 (zero). This may happen during I/O initiation or delayed
  224. by an alert status notification. In any case this status is not related to the
  225. current (last) I/O request. In case of a delayed status notification no special
  226. interrupt will be presented to indicate I/O completion as the I/O request was
  227. never started, even though ccw_device_start() returned with successful completion.
  228. The irb may contain an error value, and the device driver should check for this
  229. first:
  230. -ETIMEDOUT: the common I/O layer terminated the request after the specified
  231. timeout value
  232. -EIO: the common I/O layer terminated the request due to an error state
  233. If the concurrent sense flag in the extended status word (esw) in the irb is
  234. set, the field erw.scnt in the esw describes the number of device specific
  235. sense bytes available in the extended control word irb->scsw.ecw[]. No device
  236. sensing by the device driver itself is required.
  237. The device interrupt handler can use the following definitions to investigate
  238. the primary unit check source coded in sense byte 0 :
  239. SNS0_CMD_REJECT 0x80
  240. SNS0_INTERVENTION_REQ 0x40
  241. SNS0_BUS_OUT_CHECK 0x20
  242. SNS0_EQUIPMENT_CHECK 0x10
  243. SNS0_DATA_CHECK 0x08
  244. SNS0_OVERRUN 0x04
  245. SNS0_INCOMPL_DOMAIN 0x01
  246. Depending on the device status, multiple of those values may be set together.
  247. Please refer to the device specific documentation for details.
  248. The irb->scsw.cstat field provides the (accumulated) subchannel status :
  249. SCHN_STAT_PCI - program controlled interrupt
  250. SCHN_STAT_INCORR_LEN - incorrect length
  251. SCHN_STAT_PROG_CHECK - program check
  252. SCHN_STAT_PROT_CHECK - protection check
  253. SCHN_STAT_CHN_DATA_CHK - channel data check
  254. SCHN_STAT_CHN_CTRL_CHK - channel control check
  255. SCHN_STAT_INTF_CTRL_CHK - interface control check
  256. SCHN_STAT_CHAIN_CHECK - chaining check
  257. The irb->scsw.dstat field provides the (accumulated) device status :
  258. DEV_STAT_ATTENTION - attention
  259. DEV_STAT_STAT_MOD - status modifier
  260. DEV_STAT_CU_END - control unit end
  261. DEV_STAT_BUSY - busy
  262. DEV_STAT_CHN_END - channel end
  263. DEV_STAT_DEV_END - device end
  264. DEV_STAT_UNIT_CHECK - unit check
  265. DEV_STAT_UNIT_EXCEP - unit exception
  266. Please see the ESA/390 Principles of Operation manual for details on the
  267. individual flag meanings.
  268. Usage Notes :
  269. ccw_device_start() must be called disabled and with the ccw device lock held.
  270. The device driver is allowed to issue the next ccw_device_start() call from
  271. within its interrupt handler already. It is not required to schedule a
  272. bottom-half, unless a non deterministically long running error recovery procedure
  273. or similar needs to be scheduled. During I/O processing the Linux/390 generic
  274. I/O device driver support has already obtained the IRQ lock, i.e. the handler
  275. must not try to obtain it again when calling ccw_device_start() or we end in a
  276. deadlock situation!
  277. If a device driver relies on an I/O request to be completed prior to start the
  278. next it can reduce I/O processing overhead by chaining a NoOp I/O command
  279. CCW_CMD_NOOP to the end of the submitted CCW chain. This will force Channel-End
  280. and Device-End status to be presented together, with a single interrupt.
  281. However, this should be used with care as it implies the channel will remain
  282. busy, not being able to process I/O requests for other devices on the same
  283. channel. Therefore e.g. read commands should never use this technique, as the
  284. result will be presented by a single interrupt anyway.
  285. In order to minimize I/O overhead, a device driver should use the
  286. DOIO_REPORT_ALL only if the device can report intermediate interrupt
  287. information prior to device-end the device driver urgently relies on. In this
  288. case all I/O interruptions are presented to the device driver until final
  289. status is recognized.
  290. If a device is able to recover from asynchronously presented I/O errors, it can
  291. perform overlapping I/O using the DOIO_EARLY_NOTIFICATION flag. While some
  292. devices always report channel-end and device-end together, with a single
  293. interrupt, others present primary status (channel-end) when the channel is
  294. ready for the next I/O request and secondary status (device-end) when the data
  295. transmission has been completed at the device.
  296. Above flag allows to exploit this feature, e.g. for communication devices that
  297. can handle lost data on the network to allow for enhanced I/O processing.
  298. Unless the channel subsystem at any time presents a secondary status interrupt,
  299. exploiting this feature will cause only primary status interrupts to be
  300. presented to the device driver while overlapping I/O is performed. When a
  301. secondary status without error (alert status) is presented, this indicates
  302. successful completion for all overlapping ccw_device_start() requests that have
  303. been issued since the last secondary (final) status.
  304. Channel programs that intend to set the suspend flag on a channel command word
  305. (CCW) must start the I/O operation with the DOIO_ALLOW_SUSPEND option or the
  306. suspend flag will cause a channel program check. At the time the channel program
  307. becomes suspended an intermediate interrupt will be generated by the channel
  308. subsystem.
  309. ccw_device_resume() - Resume Channel Program Execution
  310. If a device driver chooses to suspend the current channel program execution by
  311. setting the CCW suspend flag on a particular CCW, the channel program execution
  312. is suspended. In order to resume channel program execution the CIO layer
  313. provides the ccw_device_resume() routine.
  314. int ccw_device_resume(struct ccw_device *cdev);
  315. cdev - ccw_device the resume operation is requested for
  316. The ccw_device_resume() function returns:
  317. 0 - suspended channel program is resumed
  318. -EBUSY - status pending
  319. -ENODEV - cdev invalid or not-operational subchannel
  320. -EINVAL - resume function not applicable
  321. -ENOTCONN - there is no I/O request pending for completion
  322. Usage Notes:
  323. Please have a look at the ccw_device_start() usage notes for more details on
  324. suspended channel programs.
  325. ccw_device_halt() - Halt I/O Request Processing
  326. Sometimes a device driver might need a possibility to stop the processing of
  327. a long-running channel program or the device might require to initially issue
  328. a halt subchannel (HSCH) I/O command. For those purposes the ccw_device_halt()
  329. command is provided.
  330. ccw_device_halt() must be called disabled and with the ccw device lock held.
  331. int ccw_device_halt(struct ccw_device *cdev,
  332. unsigned long intparm);
  333. cdev : ccw_device the halt operation is requested for
  334. intparm : interruption parameter; value is only used if no I/O
  335. is outstanding, otherwise the intparm associated with
  336. the I/O request is returned
  337. The ccw_device_halt() function returns :
  338. 0 - request successfully initiated
  339. -EBUSY - the device is currently busy, or status pending.
  340. -ENODEV - cdev invalid.
  341. -EINVAL - The device is not operational or the ccw device is not online.
  342. Usage Notes :
  343. A device driver may write a never-ending channel program by writing a channel
  344. program that at its end loops back to its beginning by means of a transfer in
  345. channel (TIC) command (CCW_CMD_TIC). Usually this is performed by network
  346. device drivers by setting the PCI CCW flag (CCW_FLAG_PCI). Once this CCW is
  347. executed a program controlled interrupt (PCI) is generated. The device driver
  348. can then perform an appropriate action. Prior to interrupt of an outstanding
  349. read to a network device (with or without PCI flag) a ccw_device_halt()
  350. is required to end the pending operation.
  351. ccw_device_clear() - Terminage I/O Request Processing
  352. In order to terminate all I/O processing at the subchannel, the clear subchannel
  353. (CSCH) command is used. It can be issued via ccw_device_clear().
  354. ccw_device_clear() must be called disabled and with the ccw device lock held.
  355. int ccw_device_clear(struct ccw_device *cdev, unsigned long intparm);
  356. cdev: ccw_device the clear operation is requested for
  357. intparm: interruption parameter (see ccw_device_halt())
  358. The ccw_device_clear() function returns:
  359. 0 - request successfully initiated
  360. -ENODEV - cdev invalid
  361. -EINVAL - The device is not operational or the ccw device is not online.
  362. Miscellaneous Support Routines
  363. This chapter describes various routines to be used in a Linux/390 device
  364. driver programming environment.
  365. get_ccwdev_lock()
  366. Get the address of the device specific lock. This is then used in
  367. spin_lock() / spin_unlock() calls.
  368. __u8 ccw_device_get_path_mask(struct ccw_device *cdev);
  369. Get the mask of the path currently available for cdev.