Linux 3.17-rc2
[linux/fpc-iii.git] / arch / tile / include / hv / iorpc.h
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1 /*
2 * Copyright 2012 Tilera Corporation. All Rights Reserved.
4 * This program is free software; you can redistribute it and/or
5 * modify it under the terms of the GNU General Public License
6 * as published by the Free Software Foundation, version 2.
8 * This program is distributed in the hope that it will be useful, but
9 * WITHOUT ANY WARRANTY; without even the implied warranty of
10 * MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE, GOOD TITLE or
11 * NON INFRINGEMENT. See the GNU General Public License for
12 * more details.
14 #ifndef _HV_IORPC_H_
15 #define _HV_IORPC_H_
17 /**
19 * Error codes and struct definitions for the IO RPC library.
21 * The hypervisor's IO RPC component provides a convenient way for
22 * driver authors to proxy system calls between user space, linux, and
23 * the hypervisor driver. The core of the system is a set of Python
24 * files that take ".idl" files as input and generates the following
25 * source code:
27 * - _rpc_call() routines for use in userspace IO libraries. These
28 * routines take an argument list specified in the .idl file, pack the
29 * arguments in to a buffer, and read or write that buffer via the
30 * Linux iorpc driver.
32 * - dispatch_read() and dispatch_write() routines that hypervisor
33 * drivers can use to implement most of their dev_pread() and
34 * dev_pwrite() methods. These routines decode the incoming parameter
35 * blob, permission check and translate parameters where appropriate,
36 * and then invoke a callback routine for whichever RPC call has
37 * arrived. The driver simply implements the set of callback
38 * routines.
40 * The IO RPC system also includes the Linux 'iorpc' driver, which
41 * proxies calls between the userspace library and the hypervisor
42 * driver. The Linux driver is almost entirely device agnostic; it
43 * watches for special flags indicating cases where a memory buffer
44 * address might need to be translated, etc. As a result, driver
45 * writers can avoid many of the problem cases related to registering
46 * hardware resources like memory pages or interrupts. However, the
47 * drivers must be careful to obey the conventions documented below in
48 * order to work properly with the generic Linux iorpc driver.
50 * @section iorpc_domains Service Domains
52 * All iorpc-based drivers must support a notion of service domains.
53 * A service domain is basically an application context - state
54 * indicating resources that are allocated to that particular app
55 * which it may access and (perhaps) other applications may not
56 * access. Drivers can support any number of service domains they
57 * choose. In some cases the design is limited by a number of service
58 * domains supported by the IO hardware; in other cases the service
59 * domains are a purely software concept and the driver chooses a
60 * maximum number of domains based on how much state memory it is
61 * willing to preallocate.
63 * For example, the mPIPE driver only supports as many service domains
64 * as are supported by the mPIPE hardware. This limitation is
65 * required because the hardware implements its own MMIO protection
66 * scheme to allow large MMIO mappings while still protecting small
67 * register ranges within the page that should only be accessed by the
68 * hypervisor.
70 * In contrast, drivers with no hardware service domain limitations
71 * (for instance the TRIO shim) can implement an arbitrary number of
72 * service domains. In these cases, each service domain is limited to
73 * a carefully restricted set of legal MMIO addresses if necessary to
74 * keep one application from corrupting another application's state.
76 * @section iorpc_conventions System Call Conventions
78 * The driver's open routine is responsible for allocating a new
79 * service domain for each hv_dev_open() call. By convention, the
80 * return value from open() should be the service domain number on
81 * success, or GXIO_ERR_NO_SVC_DOM if no more service domains are
82 * available.
84 * The implementations of hv_dev_pread() and hv_dev_pwrite() are
85 * responsible for validating the devhdl value passed up by the
86 * client. Since the device handle returned by hv_dev_open() should
87 * embed the positive service domain number, drivers should make sure
88 * that DRV_HDL2BITS(devhdl) is a legal service domain. If the client
89 * passes an illegal service domain number, the routine should return
90 * GXIO_ERR_INVAL_SVC_DOM. Once the service domain number has been
91 * validated, the driver can copy to/from the client buffer and call
92 * the dispatch_read() or dispatch_write() methods created by the RPC
93 * generator.
95 * The hv_dev_close() implementation should reset all service domain
96 * state and put the service domain back on a free list for
97 * reallocation by a future application. In most cases, this will
98 * require executing a hardware reset or drain flow and denying any
99 * MMIO regions that were created for the service domain.
101 * @section iorpc_data Special Data Types
103 * The .idl file syntax allows the creation of syscalls with special
104 * parameters that require permission checks or translations as part
105 * of the system call path. Because of limitations in the code
106 * generator, APIs are generally limited to just one of these special
107 * parameters per system call, and they are sometimes required to be
108 * the first or last parameter to the call. Special parameters
109 * include:
111 * @subsection iorpc_mem_buffer MEM_BUFFER
113 * The MEM_BUFFER() datatype allows user space to "register" memory
114 * buffers with a device. Registering memory accomplishes two tasks:
115 * Linux keeps track of all buffers that might be modified by a
116 * hardware device, and the hardware device drivers bind registered
117 * buffers to particular hardware resources like ingress NotifRings.
118 * The MEM_BUFFER() idl syntax can take extra flags like ALIGN_64KB,
119 * ALIGN_SELF_SIZE, and FLAGS indicating that memory buffers must have
120 * certain alignment or that the user should be able to pass a "memory
121 * flags" word specifying attributes like nt_hint or IO cache pinning.
122 * The parser will accept multiple MEM_BUFFER() flags.
124 * Implementations must obey the following conventions when
125 * registering memory buffers via the iorpc flow. These rules are a
126 * result of the Linux driver implementation, which needs to keep
127 * track of how many times a particular page has been registered with
128 * the hardware so that it can release the page when all those
129 * registrations are cleared.
131 * - Memory registrations that refer to a resource which has already
132 * been bound must return GXIO_ERR_ALREADY_INIT. Thus, it is an
133 * error to register memory twice without resetting (i.e. closing) the
134 * resource in between. This convention keeps the Linux driver from
135 * having to track which particular devices a page is bound to.
137 * - At present, a memory registration is only cleared when the
138 * service domain is reset. In this case, the Linux driver simply
139 * closes the HV device file handle and then decrements the reference
140 * counts of all pages that were previously registered with the
141 * device.
143 * - In the future, we may add a mechanism for unregistering memory.
144 * One possible implementation would require that the user specify
145 * which buffer is currently registered. The HV would then verify
146 * that that page was actually the one currently mapped and return
147 * success or failure to Linux, which would then only decrement the
148 * page reference count if the addresses were mapped. Another scheme
149 * might allow Linux to pass a token to the HV to be returned when the
150 * resource is unmapped.
152 * @subsection iorpc_interrupt INTERRUPT
154 * The INTERRUPT .idl datatype allows the client to bind hardware
155 * interrupts to a particular combination of IPI parameters - CPU, IPI
156 * PL, and event bit number. This data is passed via a special
157 * datatype so that the Linux driver can validate the CPU and PL and
158 * the HV generic iorpc code can translate client CPUs to real CPUs.
160 * @subsection iorpc_pollfd_setup POLLFD_SETUP
162 * The POLLFD_SETUP .idl datatype allows the client to set up hardware
163 * interrupt bindings which are received by Linux but which are made
164 * visible to user processes as state transitions on a file descriptor;
165 * this allows user processes to use Linux primitives, such as poll(), to
166 * await particular hardware events. This data is passed via a special
167 * datatype so that the Linux driver may recognize the pollable file
168 * descriptor and translate it to a set of interrupt target information,
169 * and so that the HV generic iorpc code can translate client CPUs to real
170 * CPUs.
172 * @subsection iorpc_pollfd POLLFD
174 * The POLLFD .idl datatype allows manipulation of hardware interrupt
175 * bindings set up via the POLLFD_SETUP datatype; common operations are
176 * resetting the state of the requested interrupt events, and unbinding any
177 * bound interrupts. This data is passed via a special datatype so that
178 * the Linux driver may recognize the pollable file descriptor and
179 * translate it to an interrupt identifier previously supplied by the
180 * hypervisor as the result of an earlier pollfd_setup operation.
182 * @subsection iorpc_blob BLOB
184 * The BLOB .idl datatype allows the client to write an arbitrary
185 * length string of bytes up to the hypervisor driver. This can be
186 * useful for passing up large, arbitrarily structured data like
187 * classifier programs. The iorpc stack takes care of validating the
188 * buffer VA and CPA as the data passes up to the hypervisor. Unlike
189 * MEM_BUFFER(), the buffer is not registered - Linux does not bump
190 * page refcounts and the HV driver should not reuse the buffer once
191 * the system call is complete.
193 * @section iorpc_translation Translating User Space Calls
195 * The ::iorpc_offset structure describes the formatting of the offset
196 * that is passed to pread() or pwrite() as part of the generated RPC code.
197 * When the user calls up to Linux, the rpc code fills in all the fields of
198 * the offset, including a 16-bit opcode, a 16 bit format indicator, and 32
199 * bits of user-specified "sub-offset". The opcode indicates which syscall
200 * is being requested. The format indicates whether there is a "prefix
201 * struct" at the start of the memory buffer passed to pwrite(), and if so
202 * what data is in that prefix struct. These prefix structs are used to
203 * implement special datatypes like MEM_BUFFER() and INTERRUPT - we arrange
204 * to put data that needs translation and permission checks at the start of
205 * the buffer so that the Linux driver and generic portions of the HV iorpc
206 * code can easily access the data. The 32 bits of user-specified
207 * "sub-offset" are most useful for pread() calls where the user needs to
208 * also pass in a few bits indicating which register to read, etc.
210 * The Linux iorpc driver watches for system calls that contain prefix
211 * structs so that it can translate parameters and bump reference
212 * counts as appropriate. It does not (currently) have any knowledge
213 * of the per-device opcodes - it doesn't care what operation you're
214 * doing to mPIPE, so long as it can do all the generic book-keeping.
215 * The hv/iorpc.h header file defines all of the generic encoding bits
216 * needed to translate iorpc calls without knowing which particular
217 * opcode is being issued.
219 * @section iorpc_globals Global iorpc Calls
221 * Implementing mmap() required adding some special iorpc syscalls
222 * that are only called by the Linux driver, never by userspace.
223 * These include get_mmio_base() and check_mmio_offset(). These
224 * routines are described in globals.idl and must be included in every
225 * iorpc driver. By providing these routines in every driver, Linux's
226 * mmap implementation can easily get the PTE bits it needs and
227 * validate the PA offset without needing to know the per-device
228 * opcodes to perform those tasks.
230 * @section iorpc_kernel Supporting gxio APIs in the Kernel
232 * The iorpc code generator also supports generation of kernel code
233 * implementing the gxio APIs. This capability is currently used by
234 * the mPIPE network driver, and will likely be used by the TRIO root
235 * complex and endpoint drivers and perhaps an in-kernel crypto
236 * driver. Each driver that wants to instantiate iorpc calls in the
237 * kernel needs to generate a kernel version of the generate rpc code
238 * and (probably) copy any related gxio source files into the kernel.
239 * The mPIPE driver provides a good example of this pattern.
242 #ifdef __KERNEL__
243 #include <linux/stddef.h>
244 #else
245 #include <stddef.h>
246 #endif
248 #if defined(__HV__)
249 #include <hv/hypervisor.h>
250 #elif defined(__KERNEL__)
251 #include <hv/hypervisor.h>
252 #include <linux/types.h>
253 #else
254 #include <stdint.h>
255 #endif
258 /** Code indicating translation services required within the RPC path.
259 * These indicate whether there is a translatable struct at the start
260 * of the RPC buffer and what information that struct contains.
262 enum iorpc_format_e
264 /** No translation required, no prefix struct. */
265 IORPC_FORMAT_NONE,
267 /** No translation required, no prefix struct, no access to this
268 * operation from user space. */
269 IORPC_FORMAT_NONE_NOUSER,
271 /** Prefix struct contains user VA and size. */
272 IORPC_FORMAT_USER_MEM,
274 /** Prefix struct contains CPA, size, and homing bits. */
275 IORPC_FORMAT_KERNEL_MEM,
277 /** Prefix struct contains interrupt. */
278 IORPC_FORMAT_KERNEL_INTERRUPT,
280 /** Prefix struct contains user-level interrupt. */
281 IORPC_FORMAT_USER_INTERRUPT,
283 /** Prefix struct contains pollfd_setup (interrupt information). */
284 IORPC_FORMAT_KERNEL_POLLFD_SETUP,
286 /** Prefix struct contains user-level pollfd_setup (file descriptor). */
287 IORPC_FORMAT_USER_POLLFD_SETUP,
289 /** Prefix struct contains pollfd (interrupt cookie). */
290 IORPC_FORMAT_KERNEL_POLLFD,
292 /** Prefix struct contains user-level pollfd (file descriptor). */
293 IORPC_FORMAT_USER_POLLFD,
297 /** Generate an opcode given format and code. */
298 #define IORPC_OPCODE(FORMAT, CODE) (((FORMAT) << 16) | (CODE))
300 /** The offset passed through the read() and write() system calls
301 combines an opcode with 32 bits of user-specified offset. */
302 union iorpc_offset
304 #ifndef __BIG_ENDIAN__
305 uint64_t offset; /**< All bits. */
307 struct
309 uint16_t code; /**< RPC code. */
310 uint16_t format; /**< iorpc_format_e */
311 uint32_t sub_offset; /**< caller-specified offset. */
314 uint32_t opcode; /**< Opcode combines code & format. */
315 #else
316 uint64_t offset; /**< All bits. */
318 struct
320 uint32_t sub_offset; /**< caller-specified offset. */
321 uint16_t format; /**< iorpc_format_e */
322 uint16_t code; /**< RPC code. */
325 struct
327 uint32_t padding;
328 uint32_t opcode; /**< Opcode combines code & format. */
330 #endif
334 /** Homing and cache hinting bits that can be used by IO devices. */
335 struct iorpc_mem_attr
337 unsigned int lotar_x:4; /**< lotar X bits (or Gx page_mask). */
338 unsigned int lotar_y:4; /**< lotar Y bits (or Gx page_offset). */
339 unsigned int hfh:1; /**< Uses hash-for-home. */
340 unsigned int nt_hint:1; /**< Non-temporal hint. */
341 unsigned int io_pin:1; /**< Only fill 'IO' cache ways. */
344 /** Set the nt_hint bit. */
345 #define IORPC_MEM_BUFFER_FLAG_NT_HINT (1 << 0)
347 /** Set the IO pin bit. */
348 #define IORPC_MEM_BUFFER_FLAG_IO_PIN (1 << 1)
351 /** A structure used to describe memory registration. Different
352 protection levels describe memory differently, so this union
353 contains all the different possible descriptions. As a request
354 moves up the call chain, each layer translates from one
355 description format to the next. In particular, the Linux iorpc
356 driver translates user VAs into CPAs and homing parameters. */
357 union iorpc_mem_buffer
359 struct
361 uint64_t va; /**< User virtual address. */
362 uint64_t size; /**< Buffer size. */
363 unsigned int flags; /**< nt_hint, IO pin. */
365 user; /**< Buffer as described by user apps. */
367 struct
369 unsigned long long cpa; /**< Client physical address. */
370 #if defined(__KERNEL__) || defined(__HV__)
371 size_t size; /**< Buffer size. */
372 HV_PTE pte; /**< PTE describing memory homing. */
373 #else
374 uint64_t size;
375 uint64_t pte;
376 #endif
377 unsigned int flags; /**< nt_hint, IO pin. */
379 kernel; /**< Buffer as described by kernel. */
381 struct
383 unsigned long long pa; /**< Physical address. */
384 size_t size; /**< Buffer size. */
385 struct iorpc_mem_attr attr; /**< Homing and locality hint bits. */
387 hv; /**< Buffer parameters for HV driver. */
391 /** A structure used to describe interrupts. The format differs slightly
392 * for user and kernel interrupts. As with the mem_buffer_t, translation
393 * between the formats is done at each level. */
394 union iorpc_interrupt
396 struct
398 int cpu; /**< CPU. */
399 int event; /**< evt_num */
401 user; /**< Interrupt as described by user applications. */
403 struct
405 int x; /**< X coord. */
406 int y; /**< Y coord. */
407 int ipi; /**< int_num */
408 int event; /**< evt_num */
410 kernel; /**< Interrupt as described by the kernel. */
415 /** A structure used to describe interrupts used with poll(). The format
416 * differs significantly for requests from user to kernel, and kernel to
417 * hypervisor. As with the mem_buffer_t, translation between the formats
418 * is done at each level. */
419 union iorpc_pollfd_setup
421 struct
423 int fd; /**< Pollable file descriptor. */
425 user; /**< pollfd_setup as described by user applications. */
427 struct
429 int x; /**< X coord. */
430 int y; /**< Y coord. */
431 int ipi; /**< int_num */
432 int event; /**< evt_num */
434 kernel; /**< pollfd_setup as described by the kernel. */
439 /** A structure used to describe previously set up interrupts used with
440 * poll(). The format differs significantly for requests from user to
441 * kernel, and kernel to hypervisor. As with the mem_buffer_t, translation
442 * between the formats is done at each level. */
443 union iorpc_pollfd
445 struct
447 int fd; /**< Pollable file descriptor. */
449 user; /**< pollfd as described by user applications. */
451 struct
453 int cookie; /**< hv cookie returned by the pollfd_setup operation. */
455 kernel; /**< pollfd as described by the kernel. */
460 /** The various iorpc devices use error codes from -1100 to -1299.
462 * This range is distinct from netio (-700 to -799), the hypervisor
463 * (-800 to -899), tilepci (-900 to -999), ilib (-1000 to -1099),
464 * gxcr (-1300 to -1399) and gxpci (-1400 to -1499).
466 enum gxio_err_e {
468 /** Largest iorpc error number. */
469 GXIO_ERR_MAX = -1101,
472 /********************************************************/
473 /* Generic Error Codes */
474 /********************************************************/
476 /** Bad RPC opcode - possible version incompatibility. */
477 GXIO_ERR_OPCODE = -1101,
479 /** Invalid parameter. */
480 GXIO_ERR_INVAL = -1102,
482 /** Memory buffer did not meet alignment requirements. */
483 GXIO_ERR_ALIGNMENT = -1103,
485 /** Memory buffers must be coherent and cacheable. */
486 GXIO_ERR_COHERENCE = -1104,
488 /** Resource already initialized. */
489 GXIO_ERR_ALREADY_INIT = -1105,
491 /** No service domains available. */
492 GXIO_ERR_NO_SVC_DOM = -1106,
494 /** Illegal service domain number. */
495 GXIO_ERR_INVAL_SVC_DOM = -1107,
497 /** Illegal MMIO address. */
498 GXIO_ERR_MMIO_ADDRESS = -1108,
500 /** Illegal interrupt binding. */
501 GXIO_ERR_INTERRUPT = -1109,
503 /** Unreasonable client memory. */
504 GXIO_ERR_CLIENT_MEMORY = -1110,
506 /** No more IOTLB entries. */
507 GXIO_ERR_IOTLB_ENTRY = -1111,
509 /** Invalid memory size. */
510 GXIO_ERR_INVAL_MEMORY_SIZE = -1112,
512 /** Unsupported operation. */
513 GXIO_ERR_UNSUPPORTED_OP = -1113,
515 /** Insufficient DMA credits. */
516 GXIO_ERR_DMA_CREDITS = -1114,
518 /** Operation timed out. */
519 GXIO_ERR_TIMEOUT = -1115,
521 /** No such device or object. */
522 GXIO_ERR_NO_DEVICE = -1116,
524 /** Device or resource busy. */
525 GXIO_ERR_BUSY = -1117,
527 /** I/O error. */
528 GXIO_ERR_IO = -1118,
530 /** Permissions error. */
531 GXIO_ERR_PERM = -1119,
535 /********************************************************/
536 /* Test Device Error Codes */
537 /********************************************************/
539 /** Illegal register number. */
540 GXIO_TEST_ERR_REG_NUMBER = -1120,
542 /** Illegal buffer slot. */
543 GXIO_TEST_ERR_BUFFER_SLOT = -1121,
546 /********************************************************/
547 /* MPIPE Error Codes */
548 /********************************************************/
551 /** Invalid buffer size. */
552 GXIO_MPIPE_ERR_INVAL_BUFFER_SIZE = -1131,
554 /** Cannot allocate buffer stack. */
555 GXIO_MPIPE_ERR_NO_BUFFER_STACK = -1140,
557 /** Invalid buffer stack number. */
558 GXIO_MPIPE_ERR_BAD_BUFFER_STACK = -1141,
560 /** Cannot allocate NotifRing. */
561 GXIO_MPIPE_ERR_NO_NOTIF_RING = -1142,
563 /** Invalid NotifRing number. */
564 GXIO_MPIPE_ERR_BAD_NOTIF_RING = -1143,
566 /** Cannot allocate NotifGroup. */
567 GXIO_MPIPE_ERR_NO_NOTIF_GROUP = -1144,
569 /** Invalid NotifGroup number. */
570 GXIO_MPIPE_ERR_BAD_NOTIF_GROUP = -1145,
572 /** Cannot allocate bucket. */
573 GXIO_MPIPE_ERR_NO_BUCKET = -1146,
575 /** Invalid bucket number. */
576 GXIO_MPIPE_ERR_BAD_BUCKET = -1147,
578 /** Cannot allocate eDMA ring. */
579 GXIO_MPIPE_ERR_NO_EDMA_RING = -1148,
581 /** Invalid eDMA ring number. */
582 GXIO_MPIPE_ERR_BAD_EDMA_RING = -1149,
584 /** Invalid channel number. */
585 GXIO_MPIPE_ERR_BAD_CHANNEL = -1150,
587 /** Bad configuration. */
588 GXIO_MPIPE_ERR_BAD_CONFIG = -1151,
590 /** Empty iqueue. */
591 GXIO_MPIPE_ERR_IQUEUE_EMPTY = -1152,
593 /** Empty rules. */
594 GXIO_MPIPE_ERR_RULES_EMPTY = -1160,
596 /** Full rules. */
597 GXIO_MPIPE_ERR_RULES_FULL = -1161,
599 /** Corrupt rules. */
600 GXIO_MPIPE_ERR_RULES_CORRUPT = -1162,
602 /** Invalid rules. */
603 GXIO_MPIPE_ERR_RULES_INVALID = -1163,
605 /** Classifier is too big. */
606 GXIO_MPIPE_ERR_CLASSIFIER_TOO_BIG = -1170,
608 /** Classifier is too complex. */
609 GXIO_MPIPE_ERR_CLASSIFIER_TOO_COMPLEX = -1171,
611 /** Classifier has bad header. */
612 GXIO_MPIPE_ERR_CLASSIFIER_BAD_HEADER = -1172,
614 /** Classifier has bad contents. */
615 GXIO_MPIPE_ERR_CLASSIFIER_BAD_CONTENTS = -1173,
617 /** Classifier encountered invalid symbol. */
618 GXIO_MPIPE_ERR_CLASSIFIER_INVAL_SYMBOL = -1174,
620 /** Classifier encountered invalid bounds. */
621 GXIO_MPIPE_ERR_CLASSIFIER_INVAL_BOUNDS = -1175,
623 /** Classifier encountered invalid relocation. */
624 GXIO_MPIPE_ERR_CLASSIFIER_INVAL_RELOCATION = -1176,
626 /** Classifier encountered undefined symbol. */
627 GXIO_MPIPE_ERR_CLASSIFIER_UNDEF_SYMBOL = -1177,
630 /********************************************************/
631 /* TRIO Error Codes */
632 /********************************************************/
634 /** Cannot allocate memory map region. */
635 GXIO_TRIO_ERR_NO_MEMORY_MAP = -1180,
637 /** Invalid memory map region number. */
638 GXIO_TRIO_ERR_BAD_MEMORY_MAP = -1181,
640 /** Cannot allocate scatter queue. */
641 GXIO_TRIO_ERR_NO_SCATTER_QUEUE = -1182,
643 /** Invalid scatter queue number. */
644 GXIO_TRIO_ERR_BAD_SCATTER_QUEUE = -1183,
646 /** Cannot allocate push DMA ring. */
647 GXIO_TRIO_ERR_NO_PUSH_DMA_RING = -1184,
649 /** Invalid push DMA ring index. */
650 GXIO_TRIO_ERR_BAD_PUSH_DMA_RING = -1185,
652 /** Cannot allocate pull DMA ring. */
653 GXIO_TRIO_ERR_NO_PULL_DMA_RING = -1186,
655 /** Invalid pull DMA ring index. */
656 GXIO_TRIO_ERR_BAD_PULL_DMA_RING = -1187,
658 /** Cannot allocate PIO region. */
659 GXIO_TRIO_ERR_NO_PIO = -1188,
661 /** Invalid PIO region index. */
662 GXIO_TRIO_ERR_BAD_PIO = -1189,
664 /** Cannot allocate ASID. */
665 GXIO_TRIO_ERR_NO_ASID = -1190,
667 /** Invalid ASID. */
668 GXIO_TRIO_ERR_BAD_ASID = -1191,
671 /********************************************************/
672 /* MICA Error Codes */
673 /********************************************************/
675 /** No such accelerator type. */
676 GXIO_MICA_ERR_BAD_ACCEL_TYPE = -1220,
678 /** Cannot allocate context. */
679 GXIO_MICA_ERR_NO_CONTEXT = -1221,
681 /** PKA command queue is full, can't add another command. */
682 GXIO_MICA_ERR_PKA_CMD_QUEUE_FULL = -1222,
684 /** PKA result queue is empty, can't get a result from the queue. */
685 GXIO_MICA_ERR_PKA_RESULT_QUEUE_EMPTY = -1223,
687 /********************************************************/
688 /* GPIO Error Codes */
689 /********************************************************/
691 /** Pin not available. Either the physical pin does not exist, or
692 * it is reserved by the hypervisor for system usage. */
693 GXIO_GPIO_ERR_PIN_UNAVAILABLE = -1240,
695 /** Pin busy. The pin exists, and is available for use via GXIO, but
696 * it has been attached by some other process or driver. */
697 GXIO_GPIO_ERR_PIN_BUSY = -1241,
699 /** Cannot access unattached pin. One or more of the pins being
700 * manipulated by this call are not attached to the requesting
701 * context. */
702 GXIO_GPIO_ERR_PIN_UNATTACHED = -1242,
704 /** Invalid I/O mode for pin. The wiring of the pin in the system
705 * is such that the I/O mode or electrical control parameters
706 * requested could cause damage. */
707 GXIO_GPIO_ERR_PIN_INVALID_MODE = -1243,
709 /** Smallest iorpc error number. */
710 GXIO_ERR_MIN = -1299
714 #endif /* !_HV_IORPC_H_ */