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PCI Library
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The eCos PCI Library
36
The PCI library is an optional part of eCos, and is only
37
        applicable to some platforms.
38
39
PCI Library
40
The eCos PCI library provides the following functionality:
41
42
Scan the PCI bus for specific devices or devices of a certain
43
class.
44
Read and change generic PCI information.
45
Read and change device-specific PCI information.
46
Allocate PCI memory and IO space to devices.
47
Translate a device's PCI interrupts to equivalent HAL
48
vectors.
49
50
Example code fragments are from the pci1 test (see io/pci/<release>/tests/pci1.c).
51
All of the functions described below are declared in the header
52
file <cyg/io/pci.h> which all
53
clients of the PCI library should include.
54
55
PCI Overview
56
The PCI bus supports several address spaces: memory, IO, and configuration. All PCI
57
devices must support mandatory configuration space registers. Some devices may also present
58
IO mapped and/or memory mapped resources. Before devices on the bus can be used, they must
59
be configured. Basically, configuration will assign PCI IO and/or memory address ranges to
60
each device and then enable that device. All PCI devices have a unique address in
61
configuration space. This address is comprised of a bus number, a device number, and a
62
function number. Special devices called bridges are used to connect two PCI busses together.
63
The PCI standard supports up to 255 busses with each bus having up to 32 devices and each
64
device having up to 8 functions.
65
66
The environment in which a platform operates will dictate if and how eCos should
67
configure devices on the PCI bus. If the platform acts as a host on a single PCI bus,
68
then devices may be configured individually from the relevant device driver. If the
69
platform is not the primary host, such as a PCI card plugged into a PC, configuration
70
of PCI devices may be left to the PC BIOS. If PCI-PCI bridges are involved, configuration
71
of all devices is best done all at once early in the boot process. This is because all
72
devices on the secondary side of a bridge must be evaluated for their IO and memory space
73
requirements before the bridge can be configured.
74
75
76
77
Initializing the bus
78
The PCI bus needs to be initialized before it can be used.
79
This only needs to be done once - some HALs may do it as part of
80
the platform initialization procedure, other HALs may leave it to
81
the application or device drivers to do it. The following function
82
will do the initialization only once, so it's safe to call from
83
multiple drivers:
84
void cyg_pci_init( void );
85
86
87
Scanning for devices
88
After the bus has been initialized, it is possible to scan
89
it for devices. This is done using the function:
90
cyg_bool cyg_pci_find_next(  cyg_pci_device_id cur_devid,
91
                             cyg_pci_device_id *next_devid );
92
93
It will scan the bus for devices starting at cur_devid
94
. If a device is found, its devid is stored in 
95
next_devid and the function returns true.
96
97
The pci1 test's outer loop looks like:
98
99
    cyg_pci_init();
100
    if (cyg_pci_find_next(CYG_PCI_NULL_DEVID, &devid)) {
101
        do {
102
             <use devid>
103
        } while (cyg_pci_find_next(devid, &devid));
104
    }
105
What happens is that the bus gets initialized and a scan is
106
started. CYG_PCI_NULL_DEVID causes 
107
cyg_pci_find_next() to restart its scan. If the bus does not
108
contain any devices, the first call to cyg_pci_find_next()
109
will return false.
110
If the call returns true, a loop is entered where
111
the found devid is used. After devid processing has completed, the next device
112
on the bus is searched for; cyg_pci_find_next()
113
continues its scan from the current devid. The loop terminates when
114
no more devices are found on the bus.
115
This is the generic way of scanning the bus, enumerating all
116
the devices on the bus. But if the application is looking for a
117
device of a given device class (e.g., a SCSI controller), or a specific
118
vendor device, these functions simplify the task a bit:
119
120
cyg_bool cyg_pci_find_class(  cyg_uint32 dev_class,
121
                              cyg_pci_device_id *devid );
122
cyg_bool cyg_pci_find_device(  cyg_uint16 vendor, cyg_uint16 device,
123
                               cyg_pci_device_id *devid );
124
They work just like cyg_pci_find_next(),
125
but only return true when the dev_class or vendor/device
126
qualifiers match those of a device on the bus. The devid serves
127
as both an input and an output operand: the scan starts at the given
128
device, and if a device is found devid is updated with the value
129
for the found device.
130
The <cyg/io/pci_cfg.h> header
131
file (included by pci.h) contains definitions for PCI
132
class, vendor and device codes which can be used as arguments to the find
133
functions.
134
The list of vendor and device codes is not complete: add new codes
135
as necessary. If possible also register the codes at the PCI Code
136
List (http://www.yourvote.com/pci)
137
 which is where the eCos definitions are generated from.
138
139
140
Generic config information
141
When a valid device ID (devid) is found using one of the above
142
functions, the associated device can be queried and controlled using
143
the functions:
144
145
void cyg_pci_get_device_info (  cyg_pci_device_id devid,
146
                                cyg_pci_device *dev_info );
147
void cyg_pci_set_device_info (  cyg_pci_device_id devid,
148
                                cyg_pci_device *dev_info );
149
The cyg_pci_device structure (defined in
150
pci.h) primarily holds information as described by the PCI
151
 specification [1].
152
The pci1 test prints out some of this information:
153
            // Get device info
154
            cyg_pci_get_device_info(devid, &dev_info);
155
            diag_printf("\n Command   0x%04x, Status 0x%04x\n",
156
                        dev_info.command, dev_info.status);
157
The command register can also be written to, controlling (among
158
other things) whether the device responds to IO and memory access
159
from the bus. 
160
161
162
Specific config information
163
The above functions only allow access to generic PCI config
164
registers. A device can have extra config registers not specified
165
by the PCI specification. These can be accessed with these functions:
166
167
void cyg_pci_read_config_uint8(  cyg_pci_device_id devid,
168
                                 cyg_uint8 offset, cyg_uint8 *val);
169
void cyg_pci_read_config_uint16(  cyg_pci_device_id devid,
170
                                  cyg_uint8 offset, cyg_uint16 *val);
171
void cyg_pci_read_config_uint32(  cyg_pci_device_id devid,
172
                                  cyg_uint8 offset, cyg_uint32 *val);
173
void cyg_pci_write_config_uint8(  cyg_pci_device_id devid,
174
                                  cyg_uint8 offset, cyg_uint8 val);
175
void cyg_pci_write_config_uint16(  cyg_pci_device_id devid,
176
                                   cyg_uint8 offset, cyg_uint16 val);
177
void cyg_pci_write_config_uint32(  cyg_pci_device_id devid,
178
                                   cyg_uint8 offset, cyg_uint32 val);
179
180
The write functions should only be used for device-specific
181
config registers since using them on generic registers may invalidate
182
the contents of a previously fetched cyg_pci_device
183
structure.
184
185
186
Allocating memory
187
A PCI device ignores all IO and memory access from the PCI
188
bus until it has been activated. Activation cannot happen until
189
after device configuration. Configuration means telling the device
190
where it should map its IO and memory resources. This is done with
191
one of the following functions::
192
cyg_bool cyg_pci_configure_device( cyg_pci_device *dev_info );
193
cyg_bool cyg_pci_configure_bus( cyg_uint8 bus, cyg_uint8 *next_bus );
194
195
The cyg_pci_configure_device handles all IO
196
and memory regions that need configuration on non-bridge devices. On
197
platforms with multiple busses connected by bridges, the 
198
cyg_pci_configure_bus function should be used. It will recursively
199
configure all devices on the given bus and all
200
subordinate busses. cyg_pci_configure_bus will
201
use cyg_pci_configure_device to configure
202
individual non-bridge devices.
203
204
 Each region is represented in the PCI device's config space by BARs
205
(Base Address Registers) and is handled individually according to type
206
using these functions:
207
cyg_bool cyg_pci_allocate_memory(  cyg_pci_device *dev_info,
208
                                   cyg_uint32 bar,
209
                                   CYG_PCI_ADDRESS64 *base );
210
cyg_bool cyg_pci_allocate_io(  cyg_pci_device *dev_info,
211
                               cyg_uint32 bar,
212
                               CYG_PCI_ADDRESS32 *base );
213
The memory bases (in two distinct address spaces) are increased
214
as memory regions are allocated to devices. Allocation will fail
215
(the function returns false) if the base exceeds the limits of the
216
address space (IO is 1MB, memory is 2^32 or 2^64 bytes).
217
These functions can also be called directly by the application/driver
218
if necessary, but this should not be necessary.
219
The bases are initialized with default values provided by
220
the HAL. It is possible for an application to override these using
221
the following functions: 
222
void cyg_pci_set_memory_base(  CYG_PCI_ADDRESS64 base );
223
void cyg_pci_set_io_base( CYG_PCI_ADDRESS32 base );
224
When a device has been configured, the cyg_pci_device
225
structure will contain the physical address in the CPU's
226
address space where the device's memory regions can be
227
accessed. 
228
This information is provided in base_map[] -
229
there is a 32 bit word for each of the device's BARs. For
230
32 bit PCI memory regions, each 32 bit word will be an actual pointer
231
that can be used immediately by the driver: the memory space will normally
232
be linearly addressable by the CPU.
233
However, for 64 bit PCI memory regions, some (or all) of the
234
region may be outside of the CPUs address space. In this case the
235
driver will need to know how to access the region in segments. This
236
functionality may be adopted by the eCos HAL if deemed useful in
237
the future. The 2GB available on many systems should suffice though.
238
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Interrupts
241
A device may generate interrupts. The HAL vector associated
242
with a given device on the bus is platform specific. This function
243
allows a driver to find the actual interrupt vector for a given
244
device:
245
cyg_bool cyg_pci_translate_interrupt(  cyg_pci_device *dev_info,
246
                                       CYG_ADDRWORD *vec );
247
If the function returns false, no interrupts will be generated
248
by the device. If it returns true, the CYG_ADDRWORD pointed
249
to by vec is updated with the HAL interrupt vector the device will
250
be using. This is how the function is used in the pci1
251
test:
252
            if (cyg_pci_translate_interrupt(&dev_info, &irq))
253
                diag_printf(" Wired to HAL vector %d\n", irq);
254
            else
255
                diag_printf(" Does not generate interrupts.\n");
256
The application/drive should attach an interrupt
257
handler to a device's interrupt before activating the device.
258
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Activating a device
261
When the device has been allocated memory space it can be
262
activated. This is not done by the library since a driver may have
263
to initialize more state on the device before it can be safely activated.
264
Activating the device is done by enabling flags in its command
265
word. As an example, see the pci1 test which can be
266
configured to enable the devices it finds. This allows these to be accessed from
267
GDB (if a breakpoint is set on cyg_test_exit):
268
#ifdef ENABLE_PCI_DEVICES
269
      {
270
          cyg_uint16 cmd;
271
 
272
          // Don't use cyg_pci_set_device_info since it clears
273
          // some of the fields we want to print out below.
274
          cyg_pci_read_config_uint16(dev_info.devid,
275
                                     CYG_PCI_CFG_COMMAND, &cmd);
276
          cmd |= CYG_PCI_CFG_COMMAND_IO|CYG_PCI_CFG_COMMAND_MEMORY;
277
          cyg_pci_write_config_uint16(dev_info.devid,
278
                                      CYG_PCI_CFG_COMMAND, cmd);
279
      }
280
      diag_printf(" **** Device IO and MEM access enabled\n");
281
#endif
282
NoteThe best way to activate a device is actually
283
through cyg_pci_set_device_info(),
284
but in this particular case the cyg_pci_device
285
structure contents from before the activation is required for printout
286
further down in the code.
287
288
289
Links
290
See these links for more information about PCI:
291
292
293
http://www.pcisig.com/ - information on the PCI specifications
294
295
296
http://www.yourvote.com/pci/
297
 - list of vendor and device IDs
298
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300
http://www.picmg.org/
301
 - PCI Industrial Computer Manufacturers Group
302
303
304
305
306
307
PCI Library reference
308
This document defines the PCI Support Library for eCos.
309
The PCI support library provides a set of routines for accessing
310
the PCI bus configuration space in a portable manner. This is provided
311
by two APIs. The high level API is used by device drivers, or other
312
code, to access the PCI configuration space portably. The low level
313
API is used by the PCI library itself to access the hardware in
314
a platform-specific manner, and may also be used by device drivers
315
to access the PCI configuration space directly.
316
Underlying the low-level API is HAL support for the basic
317
configuration space operations. These should not generally be used
318
by any code other than the PCI library, and are present in the HAL
319
to allow low level initialization of the PCI bus and devices to
320
take place if necessary.
321
322
PCI Library API
323
The PCI library provides the following routines and types
324
for accessing the PCI configuration space.
325
The API for the PCI library is found in the header file
326
<cyg/io/pci.h>.
327
328
329
Definitions
330
The header file contains definitions for the common configuration
331
structure offsets and specimen values for device, vendor and class
332
code.
333
334
335
Types and data structures
336
The following types are defined:
337
typedef CYG_WORD32 cyg_pci_device_id;
338
This is comprised of the bus number, device number and functional
339
unit numbers packed into a single word. The macro CYG_PCI_DEV_MAKE_ID()
340
, in conjunction with the CYG_PCI_DEV_MAKE_DEVFN()
341
macro, may be used to construct a device id from the bus, device and functional
342
unit numbers. Similarly the macros CYG_PCI_DEV_GET_BUS(),
343
CYG_PCI_DEV_GET_DEVFN(),
344
CYG_PCI_DEV_GET_DEV(), and
345
CYG_PCI_DEV_GET_FN() may be used to extract the
346
constituent parts of a device id. It should not be necessary to use these
347
macros under normal circumstances. The following code fragment demonstrates
348
how these macros may be used:
349
350
  // Create a packed representation of device 1, function 0
351
  cyg_uint8 devfn = CYG_PCI_DEV_MAKE_DEVFN(1,0);
352
 
353
  // Create a packed devid for that device on bus 2
354
  cyg_pci_device_id devid = CYG_PCI_DEV_MAKE_ID(2, devfn);
355
 
356
  diag_printf("bus %d, dev %d, func %d\n",
357
              CYG_PCI_DEV_GET_BUS(devid),
358
              CYG_PCI_DEV_GET_DEV(CYG_PCI_DEV_GET_DEVFN(devid)),
359
              CYG_PCI_DEV_GET_FN(CYG_PCI_DEV_GET_DEVFN(devid));
360
361
typedef struct cyg_pci_device;
362
This structure is used to contain data read from a PCI device's
363
configuration header by cyg_pci_get_device_info().
364
It is also used to record the resource allocations made to the device.
365
typedef CYG_WORD64 CYG_PCI_ADDRESS64;
366
typedef CYG_WORD32 CYG_PCI_ADDRESS32;
367
Pointers in the PCI address space are 32 bit (IO space) or
368
32/64 bit (memory space). In most platform and device configurations
369
all of PCI memory will be linearly addressable using only 32 bit
370
pointers as read from base_map[].
371
The 64 bit type is used to allow handling 64 bit devices in
372
the future, should it be necessary, without changing the library's
373
API.
374
375
376
Functions
377
void cyg_pci_init(void);
378
Initialize the PCI library and establish contact with the
379
hardware. This function is idempotent and can be called either by
380
all drivers in the system, or just from an application initialization
381
function.
382
cyg_bool cyg_pci_find_device( cyg_uint16 vendor,
383
                              cyg_uint16 device,
384
                              cyg_pci_device_id *devid );
385
Searches the PCI bus configuration space for a device with
386
the given vendor and device
387
ids. The search starts at the device pointed to by devid,
388
or at the first slot if it contains CYG_PCI_NULL_DEVID.
389
*devid will be updated with the ID of the next device
390
found. Returns true if one is found and false
391
 if not.
392
cyg_bool cyg_pci_find_class( cyg_uint32 dev_class,
393
                             cyg_pci_device_id *devid );
394
Searches the PCI bus configuration space for a device with
395
the given dev_class class code.  The search starts at the
396
device pointed to by devid, or at the first slot if it
397
contains CYG_PCI_NULL_DEVID.
398
*devid will be updated with the ID of the next
399
device found. Returns true if one is found and
400
false if not.
401
cyg_bool cyg_pci_find_next( cyg_pci_device_id cur_devid,
402
                            cyg_pci_device_id *next_devid );
403
Searches the PCI configuration space for the next valid device
404
after cur_devid. If cur_devid
405
is given the value CYG_PCI_NULL_DEVID, then the search starts
406
at the first slot. It is permitted for next_devid to
407
point to cur_devid.  Returns true
408
if another device is found and false if not.
409
410
cyg_bool cyg_pci_find_matching( cyg_pci_match_func *matchp,
411
                                void * match_callback_data,
412
                                cyg_pci_device_id *devid );
413
414
Searches the PCI bus configuration space for a device whose properties
415
match those required by the caller supplied cyg_pci_match_func.
416
The search starts at the device pointed to by devid, or
417
at the first slot if it contains CYG_PCI_NULL_DEVID. The
418
devid will be updated with the ID of the next device found.
419
This function returns true if a matching device is found
420
and false if not.
421
422
The match_func has a type declared as:
423
424
typedef cyg_bool (cyg_pci_match_func)( cyg_uint16 vendor,
425
                                       cyg_uint16 device,
426
                                       cyg_uint32 class,
427
                                       void *     user_data);
428
429
The vendor, device, and
430
class are from the device configuration space. The
431
user_data is the callback data passed to 
432
cyg_pci_find_matching.
433
434
void cyg_pci_get_device_info ( cyg_pci_device_id devid,
435
                               cyg_pci_device *dev_info );
436
This function gets the PCI configuration information for the
437
device indicated in devid. The common fields of the
438
cyg_pci_device structure, and the appropriate fields
439
of the relevant header union member are filled in from the device's
440
configuration space.
441
If the device has not been enabled, then this function will also fetch
442
the size and type information from the base address registers and
443
place it in the base_size[] array.
444
void cyg_pci_set_device_info ( cyg_pci_device_id devid,
445
                               cyg_pci_device *dev_info );
446
This function sets the PCI configuration information for the
447
device indicated in devid. Only the configuration space
448
registers that are writable are actually written. Once all the fields have
449
been written, the device info will be read back into *dev_info
450
, so that it reflects the true state of the hardware.
451
452
void cyg_pci_read_config_uint8(  cyg_pci_device_id devid,
453
                                 cyg_uint8 offset, cyg_uint8 *val );
454
void cyg_pci_read_config_uint16( cyg_pci_device_id devid,
455
                                 cyg_uint8 offset, cyg_uint16 *val );
456
void cyg_pci_read_config_uint32( cyg_pci_device_id devid,
457
                                 cyg_uint8 offset, cyg_uint32 *val );
458
459
These functions read registers of the appropriate size from
460
the configuration space of the given device. They should mainly
461
be used to access registers that are device specific. General PCI
462
registers are best accessed through cyg_pci_get_device_info()
463
.
464
465
void cyg_pci_write_config_uint8(  cyg_pci_device_id devid,
466
                                  cyg_uint8 offset, cyg_uint8 val );
467
void cyg_pci_write_config_uint16( cyg_pci_device_id devid,
468
                                  cyg_uint8 offset, cyg_uint16 val );
469
void cyg_pci_write_config_uint32( cyg_pci_device_id devid,
470
                                  cyg_uint8 offset, cyg_uint32 val );
471
472
These functions write registers of the appropriate size to
473
the configuration space of the given device. They should mainly
474
be used to access registers that are device specific. General PCI
475
registers are best accessed through cyg_pci_get_device_info()
476
. Writing the general registers this way may render the contents of
477
a cyg_pci_device structure invalid.
478
479
480
Resource allocation
481
These routines allocate memory and I/O space to PCI devices.
482
cyg_bool cyg_pci_configure_device( cyg_pci_device *dev_info )
483
Allocate memory and IO space to all base address registers
484
using the current memory and IO base addresses in the library. The
485
allocated base addresses, translated into directly usable values,
486
will be put into the matching base_map[] entries
487
in *dev_info. If *dev_info does
488
not contain valid base_size[] entries, then the result is
489
false. This function will also call 
490
cyg_pci_translate_interrupt() to put the interrupt vector into the
491
HAL vector entry.
492
cyg_bool cyg_pci_configure_bus( cyg_uint8 bus, cyg_uint8 *next_bus )
493
494
Allocate memory and IO space to all base address registers on all devices
495
on the given bus and all subordinate busses. If a PCI-PCI bridge is found on
496
bus, this function will call itself recursively in order
497
to configure the bus on the other side of the bridge. Because of the nature of
498
bridge devices, all devices on the secondary side of a bridge must be allocated
499
memory and IO space before the memory and IO windows on the bridge device can be
500
properly configured. The next_bus argument points to the
501
bus number to assign to the next subordinate bus found. The number will be
502
incremented as new busses are discovered. If successful, true
503
is returned. Otherwise, false is returned.
504
505
506
cyg_bool cyg_pci_translate_interrupt( cyg_pci_device *dev_info,
507
                                      CYG_ADDRWORD *vec );
508
509
Translate the device's PCI interrupt (INTA#-INTD#)
510
to the associated HAL vector. This may also depend on which slot
511
the device occupies. If the device may generate interrupts, the
512
translated vector number will be stored in vec and the
513
result is true. Otherwise the result is false
514
.
515
516
cyg_bool cyg_pci_allocate_memory( cyg_pci_device *dev_info,
517
                                  cyg_uint32 bar,
518
                                  CYG_PCI_ADDRESS64 *base );
519
cyg_bool cyg_pci_allocate_io( cyg_pci_device *dev_info,
520
                              cyg_uint32 bar,
521
                              CYG_PCI_ADDRESS32 *base );
522
523
These routines allocate memory or I/O space to the base address
524
register indicated by bar. The base address in
525
*base will be correctly aligned and the address of the
526
next free location will be written back into it if the allocation succeeds. If
527
the base address register is of the wrong type for this allocation, or
528
dev_info does not contain valid base_size[]
529
 entries, the result is false. These functions
530
allow a device driver to set up its own mappings if it wants. Most devices
531
should probably use cyg_pci_configure_device().
532
void cyg_pci_set_memory_base( CYG_PCI_ADDRESS64 base );
533
void cyg_pci_set_io_base( CYG_PCI_ADDRESS32 base );
534
These routines set the base addresses for memory and I/O mappings
535
to be used by the memory allocation routines. Normally these base
536
addresses will be set to default values based on the platform. These
537
routines allow these to be changed by application code if necessary.
538
539
540
PCI Library Hardware API
541
This API is used by the PCI library to access the PCI bus
542
configuration space. Although it should not normally be necessary,
543
this API may also be used by device driver or application code to
544
perform PCI bus operations not supported by the PCI library.
545
void cyg_pcihw_init(void);
546
Initialize the PCI hardware so that the configuration space
547
may be accessed.
548
549
void cyg_pcihw_read_config_uint8(  cyg_uint8 bus,
550
               cyg_uint8 devfn, cyg_uint8 offset, cyg_uint8 *val);
551
void cyg_pcihw_read_config_uint16( cyg_uint8 bus,
552
               cyg_uint8 devfn, cyg_uint8 offset, cyg_uint16 *val);
553
void cyg_pcihw_read_config_uint32( cyg_uint8 bus,
554
               cyg_uint8 devfn, cyg_uint8 offset, cyg_uint32 *val);
555
556
These functions read a register of the appropriate size from
557
the PCI configuration space at an address composed from the bus
558
, devfn and offset
559
arguments.
560
561
void cyg_pcihw_write_config_uint8(  cyg_uint8 bus,
562
                cyg_uint8 devfn, cyg_uint8 offset, cyg_uint8 val);
563
void cyg_pcihw_write_config_uint16( cyg_uint8 bus,
564
                cyg_uint8 devfn, cyg_uint8 offset, cyg_uint16 val);
565
void cyg_pcihw_write_config_uint32( cyg_uint8 bus,
566
                cyg_uint8 devfn, cyg_uint8 offset, cyg_uint32 val);
567
568
These functions write a register of the appropriate size to
569
the PCI configuration space at an address composed from the
570
bus, devfn and
571
offset arguments.
572
573
cyg_bool cyg_pcihw_translate_interrupt( cyg_uint8 bus,
574
                                        cyg_uint8 devfn,
575
                                        CYG_ADDRWORD *vec);
576
577
This function interrogates the device and determines which
578
HAL interrupt vector it is connected to.
579
580
581
HAL PCI support
582
HAL support consists of a set of C macros that provide the
583
implementation of the low level PCI API.
584
HAL_PCI_INIT()
585
Initialize the PCI bus.
586
HAL_PCI_READ_UINT8( bus, devfn, offset, val )
587
HAL_PCI_READ_UINT16( bus, devfn, offset, val )
588
HAL_PCI_READ_UINT32( bus, devfn, offset, val )
589
Read a value from the PCI configuration space of the appropriate
590
size at an address composed from the bus, 
591
devfn and offset.
592
HAL_PCI_WRITE_UINT8( bus, devfn, offset, val )
593
HAL_PCI_WRITE_UINT16( bus, devfn, offset, val )
594
HAL_PCI_WRITE_UINT32( bus, devfn, offset, val )
595
Write a value to the PCI configuration space of the appropriate
596
size at an address composed from the bus, 
597
devfn and offset.
598
HAL_PCI_TRANSLATE_INTERRUPT( bus, devfn, *vec, valid )
599
Translate the device's interrupt line into a HAL
600
interrupt vector.
601
HAL_PCI_ALLOC_BASE_MEMORY
602
HAL_PCI_ALLOC_BASE_IO
603
These macros define the default base addresses used to initialize
604
the memory and I/O allocation pointers.
605
HAL_PCI_PHYSICAL_MEMORY_BASE
606
HAL_PCI_PHYSICAL_IO_BASE
607
PCI memory and IO range do not always correspond directly
608
to physical memory or IO addresses. Frequently the PCI address spaces
609
are windowed into the processor's address range at some
610
offset. These macros define offsets to be added to the PCI base
611
addresses to translate PCI bus addresses into physical memory addresses
612
that can be used to access the allocated memory or IO space.
613
614
The chunk of PCI memory space directly addressable though
615
the window by the CPU may be smaller than the amount of PCI memory
616
actually provided. In that case drivers will have to access PCI
617
memory space in segments. Doing this will be platform specific and
618
is currently beyond the scope of the HAL.
619
620
HAL_PCI_IGNORE_DEVICE( bus, dev, fn )
621
This macro, if defined, may be used to limit the devices which are
622
found by the bus scanning functions. This is sometimes necessary for
623
devices which need special handling. If this macro evaluates to true
624
, the given device will not be found by cyg_pci_find_next
625
 or other bus scanning functions.
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