7127 remove -Wno-missing-braces from Makefile.uts
1 /*
2 * This file and its contents are supplied under the terms of the
3 * Common Development and Distribution License ("CDDL"), version 1.0.
4 * You may only use this file in accordance with the terms of version
5 * 1.0 of the CDDL.
6 *
7 * A full copy of the text of the CDDL should have accompanied this
8 * source. A copy of the CDDL is also available via the Internet at
9 * http://www.illumos.org/license/CDDL.
10 */
11
12 /*
13 * Copyright 2015 OmniTI Computer Consulting, Inc. All rights reserved.
14 * Copyright 2016 Joyent, Inc.
15 */
16
17 /*
18 * i40e - Intel 10/40 Gb Ethernet driver
19 *
20 * The i40e driver is the main software device driver for the Intel 40 Gb family
21 * of devices. Note that these devices come in many flavors with both 40 GbE
22 * ports and 10 GbE ports. This device is the successor to the 82599 family of
23 * devices (ixgbe).
24 *
25 * Unlike previous generations of Intel 1 GbE and 10 GbE devices, the 40 GbE
26 * devices defined in the XL710 controller (previously known as Fortville) are a
27 * rather different beast and have a small switch embedded inside of them. In
28 * addition, the way that most of the programming is done has been overhauled.
29 * As opposed to just using PCIe memory mapped registers, it also has an
30 * administrative queue which is used to communicate with firmware running on
31 * the chip.
32 *
33 * Each physical function in the hardware shows up as a device that this driver
34 * will bind to. The hardware splits many resources evenly across all of the
35 * physical functions present on the device, while other resources are instead
36 * shared across the entire card and its up to the device driver to
37 * intelligently partition them.
38 *
39 * ------------
40 * Organization
41 * ------------
42 *
43 * This driver is made up of several files which have their own theory
44 * statements spread across them. We'll touch on the high level purpose of each
45 * file here, and then we'll get into more discussion on how the device is
46 * generally modelled with respect to the interfaces in illumos.
47 *
48 * i40e_gld.c: This file contains all of the bindings to MAC and the networking
49 * stack.
50 *
51 * i40e_intr.c: This file contains all of the interrupt service routines and
52 * contains logic to enable and disable interrupts on the hardware.
53 * It also contains the logic to map hardware resources such as the
54 * rings to and from interrupts and controls their ability to fire.
55 *
56 * There is a big theory statement on interrupts present there.
57 *
58 * i40e_main.c: The file that you're currently in. It interfaces with the
59 * traditional OS DDI interfaces and is in charge of configuring
60 * the device.
61 *
62 * i40e_osdep.[ch]: These files contain interfaces and definitions needed to
63 * work with Intel's common code for the device.
64 *
65 * i40e_stats.c: This file contains the general work and logic around our
66 * kstats. A theory statement on their organization and use of the
67 * hardware exists there.
68 *
69 * i40e_sw.h: This header file contains all of the primary structure definitions
70 * and constants that are used across the entire driver.
71 *
72 * i40e_transceiver.c: This file contains all of the logic for sending and
73 * receiving data. It contains all of the ring and DMA
74 * allocation logic, as well as, the actual interfaces to
75 * send and receive data.
76 *
77 * A big theory statement on ring management, descriptors,
78 * and how it ties into the OS is present there.
79 *
80 * --------------
81 * General Design
82 * --------------
83 *
84 * Before we go too far into the general way we've laid out data structures and
85 * the like, it's worth taking some time to explain how the hardware is
86 * organized. This organization informs a lot of how we do things at this time
87 * in the driver.
88 *
89 * Each physical device consists of a number of one or more ports, which are
90 * considered physical functions in the PCI sense and thus each get enumerated
91 * by the system, resulting in an instance being created and attached to. While
92 * there are many resources that are unique to each physical function eg.
93 * instance of the device, there are many that are shared across all of them.
94 * Several resources have an amount reserved for each Virtual Station Interface
95 * (VSI) and then a static pool of resources, available for all functions on the
96 * card.
97 *
98 * The most important resource in hardware are its transmit and receive queue
99 * pairs (i40e_trqpair_t). These should be thought of as rings in GLDv3
100 * parlance. There are a set number of these on each device; however, they are
101 * statically partitioned among all of the different physical functions.
102 *
103 * 'Fortville' (the code name for this device family) is basically a switch. To
104 * map MAC addresses and other things to queues, we end up having to create
105 * Virtual Station Interfaces (VSIs) and establish forwarding rules that direct
106 * traffic to a queue. A VSI owns a collection of queues and has a series of
107 * forwarding rules that point to it. One way to think of this is to treat it
108 * like MAC does a VNIC. When MAC refers to a group, a collection of rings and
109 * classification resources, that is a VSI in i40e.
110 *
111 * The sets of VSIs is shared across the entire device, though there may be some
112 * amount that are reserved to each PF. Because the GLDv3 does not let us change
113 * the number of groups dynamically, we instead statically divide this amount
114 * evenly between all the functions that exist. In addition, we have the same
115 * problem with the mac address forwarding rules. There are a static number that
116 * exist shared across all the functions.
117 *
118 * To handle both of these resources, what we end up doing is going through and
119 * determining which functions belong to the same device. Nominally one might do
120 * this by having a nexus driver; however, a prime requirement for a nexus
121 * driver is identifying the various children and activating them. While it is
122 * possible to get this information from NVRAM, we would end up duplicating a
123 * lot of the PCI enumeration logic. Really, at the end of the day, the device
124 * doesn't give us the traditional identification properties we want from a
125 * nexus driver.
126 *
127 * Instead, we rely on some properties that are guaranteed to be unique. While
128 * it might be tempting to leverage the PBA or serial number of the device from
129 * NVRAM, there is nothing that says that two devices can't be mis-programmed to
130 * have the same values in NVRAM. Instead, we uniquely identify a group of
131 * functions based on their parent in the /devices tree, their PCI bus and PCI
132 * function identifiers. Using either on their own may not be sufficient.
133 *
134 * For each unique PCI device that we encounter, we'll create a i40e_device_t.
135 * From there, because we don't have a good way to tell the GLDv3 about sharing
136 * resources between everything, we'll end up just dividing the resources
137 * evenly between all of the functions. Longer term, if we don't have to declare
138 * to the GLDv3 that these resources are shared, then we'll maintain a pool and
139 * hae each PF allocate from the pool in the device, thus if only two of four
140 * ports are being used, for example, then all of the resources can still be
141 * used.
142 *
143 * -------------------------------------------
144 * Transmit and Receive Queue Pair Allocations
145 * -------------------------------------------
146 *
147 * NVRAM ends up assigning each PF its own share of the transmit and receive LAN
148 * queue pairs, we have no way of modifying it, only observing it. From there,
149 * it's up to us to map these queues to VSIs and VFs. Since we don't support any
150 * VFs at this time, we only focus on assignments to VSIs.
151 *
152 * At the moment, we used a static mapping of transmit/receive queue pairs to a
153 * given VSI (eg. rings to a group). Though in the fullness of time, we want to
154 * make this something which is fully dynamic and take advantage of documented,
155 * but not yet available functionality for adding filters based on VXLAN and
156 * other encapsulation technologies.
157 *
158 * -------------------------------------
159 * Broadcast, Multicast, and Promiscuous
160 * -------------------------------------
161 *
162 * As part of the GLDv3, we need to make sure that we can handle receiving
163 * broadcast and multicast traffic. As well as enabling promiscuous mode when
164 * requested. GLDv3 requires that all broadcast and multicast traffic be
165 * retrieved by the default group, eg. the first one. This is the same thing as
166 * the default VSI.
167 *
168 * To receieve broadcast traffic, we enable it through the admin queue, rather
169 * than use one of our filters for it. For multicast traffic, we reserve a
170 * certain number of the hash filters and assign them to a given PF. When we
171 * exceed those, we then switch to using promicuous mode for multicast traffic.
172 *
173 * More specifically, once we exceed the number of filters (indicated because
174 * the i40e_t`i40e_resources.ifr_nmcastfilt ==
175 * i40e_t`i40e_resources.ifr_nmcastfilt_used), we then instead need to toggle
176 * promiscuous mode. If promiscuous mode is toggled then we keep track of the
177 * number of MACs added to it by incrementing i40e_t`i40e_mcast_promisc_count.
178 * That will stay enabled until that count reaches zero indicating that we have
179 * only added multicast addresses that we have a corresponding entry for.
180 *
181 * Because MAC itself wants to toggle promiscuous mode, which includes both
182 * unicast and multicast traffic, we go through and keep track of that
183 * ourselves. That is maintained through the use of the i40e_t`i40e_promisc_on
184 * member.
185 *
186 * --------------
187 * VSI Management
188 * --------------
189 *
190 * At this time, we currently only support a single MAC group, and thus a single
191 * VSI. This VSI is considered the default VSI and should be the only one that
192 * exists after a reset. Currently it is stored as the member
193 * i40e_t`i40e_vsi_id. While this works for the moment and for an initial
194 * driver, it's not sufficient for the longer-term path of the driver. Instead,
195 * we'll want to actually have a unique i40e_vsi_t structure which is used
196 * everywhere. Note that this means that every place that uses the
197 * i40e_t`i40e_vsi_id will need to be refactored.
198 *
199 * ----------------
200 * Structure Layout
201 * ----------------
202 *
203 * The following images relates the core data structures together. The primary
204 * structure in the system is the i40e_t. It itself contains multiple rings,
205 * i40e_trqpair_t's which contain the various transmit and receive data. The
206 * receive data is stored outside of the i40e_trqpair_t and instead in the
207 * i40e_rx_data_t. The i40e_t has a corresponding i40e_device_t which keeps
208 * track of per-physical device state. Finally, for every active descriptor,
209 * there is a corresponding control block, which is where the
210 * i40e_rx_control_block_t and the i40e_tx_control_block_t come from.
211 *
212 * +-----------------------+ +-----------------------+
213 * | Global i40e_t list | | Global Device list |
214 * | | +--| |
215 * | i40e_glist | | | i40e_dlist |
216 * +-----------------------+ | +-----------------------+
217 * | v
218 * | +------------------------+ +-----------------------+
219 * | | Device-wide Structure |----->| Device-wide Structure |--> ...
220 * | | i40e_device_t | | i40e_device_t |
221 * | | | +-----------------------+
222 * | | dev_info_t * ------+--> Parent in devices tree.
223 * | | uint_t ------+--> PCI bus number
224 * | | uint_t ------+--> PCI device number
225 * | | uint_t ------+--> Number of functions
226 * | | i40e_switch_rsrcs_t ---+--> Captured total switch resources
227 * | | list_t ------+-------------+
228 * | +------------------------+ |
229 * | ^ |
230 * | +--------+ |
231 * | | v
232 * | +---------------------------+ | +-------------------+
233 * +->| GLDv3 Device, per PF |-----|-->| GLDv3 Device (PF) |--> ...
234 * | i40e_t | | | i40e_t |
235 * | **Primary Structure** | | +-------------------+
236 * | | |
237 * | i40e_device_t * --+-----+
238 * | i40e_state_t --+---> Device State
239 * | i40e_hw_t --+---> Intel common code structure
240 * | mac_handle_t --+---> GLDv3 handle to MAC
241 * | ddi_periodic_t --+---> Link activity timer
242 * | int (vsi_id) --+---> VSI ID, main identifier
243 * | i40e_func_rsrc_t --+---> Available hardware resources
244 * | i40e_switch_rsrc_t * --+---> Switch resource snapshot
245 * | i40e_sdu --+---> Current MTU
246 * | i40e_frame_max --+---> Current HW frame size
247 * | i40e_uaddr_t * --+---> Array of assigned unicast MACs
248 * | i40e_maddr_t * --+---> Array of assigned multicast MACs
249 * | i40e_mcast_promisccount --+---> Active multicast state
250 * | i40e_promisc_on --+---> Current promiscuous mode state
251 * | int --+---> Number of transmit/receive pairs
252 * | kstat_t * --+---> PF kstats
253 * | kstat_t * --+---> VSI kstats
254 * | i40e_pf_stats_t --+---> PF kstat backing data
255 * | i40e_vsi_stats_t --+---> VSI kstat backing data
256 * | i40e_trqpair_t * --+---------+
257 * +---------------------------+ |
258 * |
259 * v
260 * +-------------------------------+ +-----------------------------+
261 * | Transmit/Receive Queue Pair |-------| Transmit/Receive Queue Pair |->...
262 * | i40e_trqpair_t | | i40e_trqpair_t |
263 * + Ring Data Structure | +-----------------------------+
264 * | |
265 * | mac_ring_handle_t +--> MAC RX ring handle
266 * | mac_ring_handle_t +--> MAC TX ring handle
267 * | i40e_rxq_stat_t --+--> RX Queue stats
268 * | i40e_txq_stat_t --+--> TX Queue stats
269 * | uint32_t (tx ring size) +--> TX Ring Size
270 * | uint32_t (tx free list size) +--> TX Free List Size
271 * | i40e_dma_buffer_t --------+--> TX Descriptor ring DMA
272 * | i40e_tx_desc_t * --------+--> TX descriptor ring
273 * | volatile unt32_t * +--> TX Write back head
274 * | uint32_t -------+--> TX ring head
275 * | uint32_t -------+--> TX ring tail
276 * | uint32_t -------+--> Num TX desc free
277 * | i40e_tx_control_block_t * --+--> TX control block array ---+
278 * | i40e_tx_control_block_t ** --+--> TCB work list ----+
279 * | i40e_tx_control_block_t ** --+--> TCB free list ---+
280 * | uint32_t -------+--> Free TCB count |
281 * | i40e_rx_data_t * -------+--+ v
282 * +-------------------------------+ | +---------------------------+
283 * | | Per-TX Frame Metadata |
284 * | | i40e_tx_control_block_t |
285 * +--------------------+ | |
286 * | mblk to transmit <--+--- mblk_t * |
287 * | type of transmit <--+--- i40e_tx_type_t |
288 * | TX DMA handle <--+--- ddi_dma_handle_t |
289 * v TX DMA buffer <--+--- i40e_dma_buffer_t |
290 * +------------------------------+ +---------------------------+
291 * | Core Receive Data |
292 * | i40e_rx_data_t |
293 * | |
294 * | i40e_dma_buffer_t --+--> RX descriptor DMA Data
295 * | i40e_rx_desc_t --+--> RX descriptor ring
296 * | uint32_t --+--> Next free desc.
297 * | i40e_rx_control_block_t * --+--> RX Control Block Array ---+
298 * | i40e_rx_control_block_t ** --+--> RCB work list ---+
299 * | i40e_rx_control_block_t ** --+--> RCB free list ---+
300 * +------------------------------+ |
301 * ^ |
302 * | +---------------------------+ |
303 * | | Per-RX Frame Metadata |<---------------+
304 * | | i40e_rx_control_block_t |
305 * | | |
306 * | | mblk_t * ----+--> Received mblk_t data
307 * | | uint32_t ----+--> Reference count
308 * | | i40e_dma_buffer_t ----+--> Receive data DMA info
309 * | | frtn_t ----+--> mblk free function info
310 * +-----+-- i40e_rx_data_t * |
311 * +---------------------------+
312 *
313 * -------------
314 * Lock Ordering
315 * -------------
316 *
317 * In order to ensure that we don't deadlock, the following represents the
318 * lock order being used. When grabbing locks, follow the following order. Lower
319 * numbers are more important. Thus, the i40e_glock which is number 0, must be
320 * taken before any other locks in the driver. On the other hand, the
321 * i40e_t`i40e_stat_lock, has the highest number because it's the least
322 * important lock. Note, that just because one lock is higher than another does
323 * not mean that all intermediary locks are required.
324 *
325 * 0) i40e_glock
326 * 1) i40e_t`i40e_general_lock
327 *
328 * 2) i40e_trqpair_t`itrq_rx_lock
329 * 3) i40e_trqpair_t`itrq_tx_lock
330 * 4) i40e_t`i40e_rx_pending_lock
331 * 5) i40e_trqpair_t`itrq_tcb_lock
332 *
333 * 6) i40e_t`i40e_stat_lock
334 *
335 * Rules and expectations:
336 *
337 * 1) A thread holding locks belong to one PF should not hold locks belonging to
338 * a second. If for some reason this becomes necessary, locks should be grabbed
339 * based on the list order in the i40e_device_t, which implies that the
340 * i40e_glock is held.
341 *
342 * 2) When grabbing locks between multiple transmit and receive queues, the
343 * locks for the lowest number transmit/receive queue should be grabbed first.
344 *
345 * 3) When grabbing both the transmit and receive lock for a given queue, always
346 * grab i40e_trqpair_t`itrq_rx_lock before the i40e_trqpair_t`itrq_tx_lock.
347 *
348 * 4) The following pairs of locks are not expected to be held at the same time:
349 *
350 * o i40e_t`i40e_rx_pending_lock and i40e_trqpair_t`itrq_tcb_lock
351 *
352 * -----------
353 * Future Work
354 * -----------
355 *
356 * At the moment the i40e_t driver is rather bare bones, allowing us to start
357 * getting data flowing and folks using it while we develop additional features.
358 * While bugs have been filed to cover this future work, the following gives an
359 * overview of expected work:
360 *
361 * o TSO support
362 * o RSS / multiple ring support
363 * o Multiple group support
364 * o DMA binding and breaking up the locking in ring recycling.
365 * o Enhanced detection of device errors
366 * o Participation in IRM
367 * o FMA device reset
368 * o Stall detection, temperature error detection, etc.
369 * o More dynamic resource pools
370 */
371
372 #include "i40e_sw.h"
373
374 static char i40e_ident[] = "Intel 10/40Gb Ethernet v1.0.0";
375
376 /*
377 * The i40e_glock primarily protects the lists below and the i40e_device_t
378 * structures.
379 */
380 static kmutex_t i40e_glock;
381 static list_t i40e_glist;
382 static list_t i40e_dlist;
383
384 /*
385 * Access attributes for register mapping.
386 */
387 static ddi_device_acc_attr_t i40e_regs_acc_attr = {
388 DDI_DEVICE_ATTR_V1,
389 DDI_STRUCTURE_LE_ACC,
390 DDI_STRICTORDER_ACC,
391 DDI_FLAGERR_ACC
392 };
393
394 /*
395 * Logging function for this driver.
396 */
397 static void
398 i40e_dev_err(i40e_t *i40e, int level, boolean_t console, const char *fmt,
399 va_list ap)
400 {
401 char buf[1024];
402
403 (void) vsnprintf(buf, sizeof (buf), fmt, ap);
404
405 if (i40e == NULL) {
406 cmn_err(level, (console) ? "%s: %s" : "!%s: %s",
407 I40E_MODULE_NAME, buf);
408 } else {
409 dev_err(i40e->i40e_dip, level, (console) ? "%s" : "!%s",
410 buf);
411 }
412 }
413
414 /*
415 * Because there's the stupid trailing-comma problem with the C preprocessor
416 * and variable arguments, I need to instantiate these. Pardon the redundant
417 * code.
418 */
419 /*PRINTFLIKE2*/
420 void
421 i40e_error(i40e_t *i40e, const char *fmt, ...)
422 {
423 va_list ap;
424
425 va_start(ap, fmt);
426 i40e_dev_err(i40e, CE_WARN, B_FALSE, fmt, ap);
427 va_end(ap);
428 }
429
430 /*PRINTFLIKE2*/
431 void
432 i40e_log(i40e_t *i40e, const char *fmt, ...)
433 {
434 va_list ap;
435
436 va_start(ap, fmt);
437 i40e_dev_err(i40e, CE_NOTE, B_FALSE, fmt, ap);
438 va_end(ap);
439 }
440
441 /*PRINTFLIKE2*/
442 void
443 i40e_notice(i40e_t *i40e, const char *fmt, ...)
444 {
445 va_list ap;
446
447 va_start(ap, fmt);
448 i40e_dev_err(i40e, CE_NOTE, B_TRUE, fmt, ap);
449 va_end(ap);
450 }
451
452 static void
453 i40e_device_rele(i40e_t *i40e)
454 {
455 i40e_device_t *idp = i40e->i40e_device;
456
457 if (idp == NULL)
458 return;
459
460 mutex_enter(&i40e_glock);
461 VERIFY(idp->id_nreg > 0);
462 list_remove(&idp->id_i40e_list, i40e);
463 idp->id_nreg--;
464 if (idp->id_nreg == 0) {
465 list_remove(&i40e_dlist, idp);
466 list_destroy(&idp->id_i40e_list);
467 kmem_free(idp->id_rsrcs, sizeof (i40e_switch_rsrc_t) *
468 idp->id_rsrcs_alloc);
469 kmem_free(idp, sizeof (i40e_device_t));
470 }
471 i40e->i40e_device = NULL;
472 mutex_exit(&i40e_glock);
473 }
474
475 static i40e_device_t *
476 i40e_device_find(i40e_t *i40e, dev_info_t *parent, uint_t bus, uint_t device)
477 {
478 i40e_device_t *idp;
479 mutex_enter(&i40e_glock);
480 for (idp = list_head(&i40e_dlist); idp != NULL;
481 idp = list_next(&i40e_dlist, idp)) {
482 if (idp->id_parent == parent && idp->id_pci_bus == bus &&
483 idp->id_pci_device == device) {
484 break;
485 }
486 }
487
488 if (idp != NULL) {
489 VERIFY(idp->id_nreg < idp->id_nfuncs);
490 idp->id_nreg++;
491 } else {
492 i40e_hw_t *hw = &i40e->i40e_hw_space;
493 ASSERT(hw->num_ports > 0);
494 ASSERT(hw->num_partitions > 0);
495
496 /*
497 * The Intel common code doesn't exactly keep the number of PCI
498 * functions. But it calculates it during discovery of
499 * partitions and ports. So what we do is undo the calculation
500 * that it does originally, as functions are evenly spread
501 * across ports in the rare case of partitions.
502 */
503 idp = kmem_alloc(sizeof (i40e_device_t), KM_SLEEP);
504 idp->id_parent = parent;
505 idp->id_pci_bus = bus;
506 idp->id_pci_device = device;
507 idp->id_nfuncs = hw->num_ports * hw->num_partitions;
508 idp->id_nreg = 1;
509 idp->id_rsrcs_alloc = i40e->i40e_switch_rsrc_alloc;
510 idp->id_rsrcs_act = i40e->i40e_switch_rsrc_actual;
511 idp->id_rsrcs = kmem_alloc(sizeof (i40e_switch_rsrc_t) *
512 idp->id_rsrcs_alloc, KM_SLEEP);
513 bcopy(i40e->i40e_switch_rsrcs, idp->id_rsrcs,
514 sizeof (i40e_switch_rsrc_t) * idp->id_rsrcs_alloc);
515 list_create(&idp->id_i40e_list, sizeof (i40e_t),
516 offsetof(i40e_t, i40e_dlink));
517
518 list_insert_tail(&i40e_dlist, idp);
519 }
520
521 list_insert_tail(&idp->id_i40e_list, i40e);
522 mutex_exit(&i40e_glock);
523
524 return (idp);
525 }
526
527 static void
528 i40e_link_state_set(i40e_t *i40e, link_state_t state)
529 {
530 if (i40e->i40e_link_state == state)
531 return;
532
533 i40e->i40e_link_state = state;
534 mac_link_update(i40e->i40e_mac_hdl, i40e->i40e_link_state);
535 }
536
537 /*
538 * This is a basic link check routine. Mostly we're using this just to see
539 * if we can get any accurate information about the state of the link being
540 * up or down, as well as updating the link state, speed, etc. information.
541 */
542 void
543 i40e_link_check(i40e_t *i40e)
544 {
545 i40e_hw_t *hw = &i40e->i40e_hw_space;
546 boolean_t ls;
547 int ret;
548
549 ASSERT(MUTEX_HELD(&i40e->i40e_general_lock));
550
551 hw->phy.get_link_info = B_TRUE;
552 if ((ret = i40e_get_link_status(hw, &ls)) != I40E_SUCCESS) {
553 i40e->i40e_s_link_status_errs++;
554 i40e->i40e_s_link_status_lasterr = ret;
555 return;
556 }
557
558 /*
559 * Firmware abstracts all of the mac and phy information for us, so we
560 * can use i40e_get_link_status to determine the current state.
561 */
562 if (ls == B_TRUE) {
563 enum i40e_aq_link_speed speed;
564
565 speed = i40e_get_link_speed(hw);
566
567 /*
568 * Translate from an i40e value to a value in Mbits/s.
569 */
570 switch (speed) {
571 case I40E_LINK_SPEED_100MB:
572 i40e->i40e_link_speed = 100;
573 break;
574 case I40E_LINK_SPEED_1GB:
575 i40e->i40e_link_speed = 1000;
576 break;
577 case I40E_LINK_SPEED_10GB:
578 i40e->i40e_link_speed = 10000;
579 break;
580 case I40E_LINK_SPEED_20GB:
581 i40e->i40e_link_speed = 20000;
582 break;
583 case I40E_LINK_SPEED_40GB:
584 i40e->i40e_link_speed = 40000;
585 break;
586 default:
587 i40e->i40e_link_speed = 0;
588 break;
589 }
590
591 /*
592 * At this time, hardware does not support half-duplex
593 * operation, hence why we don't ask the hardware about our
594 * current speed.
595 */
596 i40e->i40e_link_duplex = LINK_DUPLEX_FULL;
597 i40e_link_state_set(i40e, LINK_STATE_UP);
598 } else {
599 i40e->i40e_link_speed = 0;
600 i40e->i40e_link_duplex = 0;
601 i40e_link_state_set(i40e, LINK_STATE_DOWN);
602 }
603 }
604
605 static void
606 i40e_rem_intrs(i40e_t *i40e)
607 {
608 int i, rc;
609
610 for (i = 0; i < i40e->i40e_intr_count; i++) {
611 rc = ddi_intr_free(i40e->i40e_intr_handles[i]);
612 if (rc != DDI_SUCCESS) {
613 i40e_log(i40e, "failed to free interrupt %d: %d",
614 i, rc);
615 }
616 }
617
618 kmem_free(i40e->i40e_intr_handles, i40e->i40e_intr_size);
619 i40e->i40e_intr_handles = NULL;
620 }
621
622 static void
623 i40e_rem_intr_handlers(i40e_t *i40e)
624 {
625 int i, rc;
626
627 for (i = 0; i < i40e->i40e_intr_count; i++) {
628 rc = ddi_intr_remove_handler(i40e->i40e_intr_handles[i]);
629 if (rc != DDI_SUCCESS) {
630 i40e_log(i40e, "failed to remove interrupt %d: %d",
631 i, rc);
632 }
633 }
634 }
635
636 /*
637 * illumos Fault Management Architecture (FMA) support.
638 */
639
640 int
641 i40e_check_acc_handle(ddi_acc_handle_t handle)
642 {
643 ddi_fm_error_t de;
644
645 ddi_fm_acc_err_get(handle, &de, DDI_FME_VERSION);
646 ddi_fm_acc_err_clear(handle, DDI_FME_VERSION);
647 return (de.fme_status);
648 }
649
650 int
651 i40e_check_dma_handle(ddi_dma_handle_t handle)
652 {
653 ddi_fm_error_t de;
654
655 ddi_fm_dma_err_get(handle, &de, DDI_FME_VERSION);
656 return (de.fme_status);
657 }
658
659 /*
660 * Fault service error handling callback function.
661 */
662 /* ARGSUSED */
663 static int
664 i40e_fm_error_cb(dev_info_t *dip, ddi_fm_error_t *err, const void *impl_data)
665 {
666 pci_ereport_post(dip, err, NULL);
667 return (err->fme_status);
668 }
669
670 static void
671 i40e_fm_init(i40e_t *i40e)
672 {
673 ddi_iblock_cookie_t iblk;
674
675 i40e->i40e_fm_capabilities = ddi_prop_get_int(DDI_DEV_T_ANY,
676 i40e->i40e_dip, DDI_PROP_DONTPASS, "fm_capable",
677 DDI_FM_EREPORT_CAPABLE | DDI_FM_ACCCHK_CAPABLE |
678 DDI_FM_DMACHK_CAPABLE | DDI_FM_ERRCB_CAPABLE);
679
680 if (i40e->i40e_fm_capabilities < 0) {
681 i40e->i40e_fm_capabilities = 0;
682 } else if (i40e->i40e_fm_capabilities > 0xf) {
683 i40e->i40e_fm_capabilities = DDI_FM_EREPORT_CAPABLE |
684 DDI_FM_ACCCHK_CAPABLE | DDI_FM_DMACHK_CAPABLE |
685 DDI_FM_ERRCB_CAPABLE;
686 }
687
688 /*
689 * Only register with IO Fault Services if we have some capability
690 */
691 if (i40e->i40e_fm_capabilities & DDI_FM_ACCCHK_CAPABLE) {
692 i40e_regs_acc_attr.devacc_attr_access = DDI_FLAGERR_ACC;
693 } else {
694 i40e_regs_acc_attr.devacc_attr_access = DDI_DEFAULT_ACC;
695 }
696
697 if (i40e->i40e_fm_capabilities) {
698 ddi_fm_init(i40e->i40e_dip, &i40e->i40e_fm_capabilities, &iblk);
699
700 if (DDI_FM_EREPORT_CAP(i40e->i40e_fm_capabilities) ||
701 DDI_FM_ERRCB_CAP(i40e->i40e_fm_capabilities)) {
702 pci_ereport_setup(i40e->i40e_dip);
703 }
704
705 if (DDI_FM_ERRCB_CAP(i40e->i40e_fm_capabilities)) {
706 ddi_fm_handler_register(i40e->i40e_dip,
707 i40e_fm_error_cb, (void*)i40e);
708 }
709 }
710
711 if (i40e->i40e_fm_capabilities & DDI_FM_DMACHK_CAPABLE) {
712 i40e_init_dma_attrs(i40e, B_TRUE);
713 } else {
714 i40e_init_dma_attrs(i40e, B_FALSE);
715 }
716 }
717
718 static void
719 i40e_fm_fini(i40e_t *i40e)
720 {
721 if (i40e->i40e_fm_capabilities) {
722
723 if (DDI_FM_EREPORT_CAP(i40e->i40e_fm_capabilities) ||
724 DDI_FM_ERRCB_CAP(i40e->i40e_fm_capabilities))
725 pci_ereport_teardown(i40e->i40e_dip);
726
727 if (DDI_FM_ERRCB_CAP(i40e->i40e_fm_capabilities))
728 ddi_fm_handler_unregister(i40e->i40e_dip);
729
730 ddi_fm_fini(i40e->i40e_dip);
731 }
732 }
733
734 void
735 i40e_fm_ereport(i40e_t *i40e, char *detail)
736 {
737 uint64_t ena;
738 char buf[FM_MAX_CLASS];
739
740 (void) snprintf(buf, FM_MAX_CLASS, "%s.%s", DDI_FM_DEVICE, detail);
741 ena = fm_ena_generate(0, FM_ENA_FMT1);
742 if (DDI_FM_EREPORT_CAP(i40e->i40e_fm_capabilities)) {
743 ddi_fm_ereport_post(i40e->i40e_dip, buf, ena, DDI_NOSLEEP,
744 FM_VERSION, DATA_TYPE_UINT8, FM_EREPORT_VERS0, NULL);
745 }
746 }
747
748 /*
749 * Here we're trying to get the ID of the default VSI. In general, when we come
750 * through and look at this shortly after attach, we expect there to only be a
751 * single element present, which is the default VSI. Importantly, each PF seems
752 * to not see any other devices, in part because of the simple switch mode that
753 * we're using. If for some reason, we see more artifact, we'll need to revisit
754 * what we're doing here.
755 */
756 static int
757 i40e_get_vsi_id(i40e_t *i40e)
758 {
759 i40e_hw_t *hw = &i40e->i40e_hw_space;
760 struct i40e_aqc_get_switch_config_resp *sw_config;
761 uint8_t aq_buf[I40E_AQ_LARGE_BUF];
762 uint16_t next = 0;
763 int rc;
764
765 /* LINTED: E_BAD_PTR_CAST_ALIGN */
766 sw_config = (struct i40e_aqc_get_switch_config_resp *)aq_buf;
767 rc = i40e_aq_get_switch_config(hw, sw_config, sizeof (aq_buf), &next,
768 NULL);
769 if (rc != I40E_SUCCESS) {
770 i40e_error(i40e, "i40e_aq_get_switch_config() failed %d: %d",
771 rc, hw->aq.asq_last_status);
772 return (-1);
773 }
774
775 if (LE_16(sw_config->header.num_reported) != 1) {
776 i40e_error(i40e, "encountered multiple (%d) switching units "
777 "during attach, not proceeding",
778 LE_16(sw_config->header.num_reported));
779 return (-1);
780 }
781
782 return (sw_config->element[0].seid);
783 }
784
785 /*
786 * We need to fill the i40e_hw_t structure with the capabilities of this PF. We
787 * must also provide the memory for it; however, we don't need to keep it around
788 * to the call to the common code. It takes it and parses it into an internal
789 * structure.
790 */
791 static boolean_t
792 i40e_get_hw_capabilities(i40e_t *i40e, i40e_hw_t *hw)
793 {
794 struct i40e_aqc_list_capabilities_element_resp *buf;
795 int rc;
796 size_t len;
797 uint16_t needed;
798 int nelems = I40E_HW_CAP_DEFAULT;
799
800 len = nelems * sizeof (*buf);
801
802 for (;;) {
803 ASSERT(len > 0);
804 buf = kmem_alloc(len, KM_SLEEP);
805 rc = i40e_aq_discover_capabilities(hw, buf, len,
806 &needed, i40e_aqc_opc_list_func_capabilities, NULL);
807 kmem_free(buf, len);
808
809 if (hw->aq.asq_last_status == I40E_AQ_RC_ENOMEM &&
810 nelems == I40E_HW_CAP_DEFAULT) {
811 if (nelems == needed) {
812 i40e_error(i40e, "Capability discovery failed "
813 "due to byzantine common code");
814 return (B_FALSE);
815 }
816 len = needed;
817 continue;
818 } else if (rc != I40E_SUCCESS ||
819 hw->aq.asq_last_status != I40E_AQ_RC_OK) {
820 i40e_error(i40e, "Capability discovery failed: %d", rc);
821 return (B_FALSE);
822 }
823
824 break;
825 }
826
827 return (B_TRUE);
828 }
829
830 /*
831 * Obtain the switch's capabilities as seen by this PF and keep it around for
832 * our later use.
833 */
834 static boolean_t
835 i40e_get_switch_resources(i40e_t *i40e)
836 {
837 i40e_hw_t *hw = &i40e->i40e_hw_space;
838 uint8_t cnt = 2;
839 uint8_t act;
840 size_t size;
841 i40e_switch_rsrc_t *buf;
842
843 for (;;) {
844 enum i40e_status_code ret;
845 size = cnt * sizeof (i40e_switch_rsrc_t);
846 ASSERT(size > 0);
847 if (size > UINT16_MAX)
848 return (B_FALSE);
849 buf = kmem_alloc(size, KM_SLEEP);
850
851 ret = i40e_aq_get_switch_resource_alloc(hw, &act, buf,
852 cnt, NULL);
853 if (ret == I40E_ERR_ADMIN_QUEUE_ERROR &&
854 hw->aq.asq_last_status == I40E_AQ_RC_EINVAL) {
855 kmem_free(buf, size);
856 cnt += I40E_SWITCH_CAP_DEFAULT;
857 continue;
858 } else if (ret != I40E_SUCCESS) {
859 kmem_free(buf, size);
860 i40e_error(i40e,
861 "failed to retrieve switch statistics: %d", ret);
862 return (B_FALSE);
863 }
864
865 break;
866 }
867
868 i40e->i40e_switch_rsrc_alloc = cnt;
869 i40e->i40e_switch_rsrc_actual = act;
870 i40e->i40e_switch_rsrcs = buf;
871
872 return (B_TRUE);
873 }
874
875 static void
876 i40e_cleanup_resources(i40e_t *i40e)
877 {
878 if (i40e->i40e_uaddrs != NULL) {
879 kmem_free(i40e->i40e_uaddrs, sizeof (i40e_uaddr_t) *
880 i40e->i40e_resources.ifr_nmacfilt);
881 i40e->i40e_uaddrs = NULL;
882 }
883
884 if (i40e->i40e_maddrs != NULL) {
885 kmem_free(i40e->i40e_maddrs, sizeof (i40e_maddr_t) *
886 i40e->i40e_resources.ifr_nmcastfilt);
887 i40e->i40e_maddrs = NULL;
888 }
889
890 if (i40e->i40e_switch_rsrcs != NULL) {
891 size_t sz = sizeof (i40e_switch_rsrc_t) *
892 i40e->i40e_switch_rsrc_alloc;
893 ASSERT(sz > 0);
894 kmem_free(i40e->i40e_switch_rsrcs, sz);
895 i40e->i40e_switch_rsrcs = NULL;
896 }
897
898 if (i40e->i40e_device != NULL)
899 i40e_device_rele(i40e);
900 }
901
902 static boolean_t
903 i40e_get_available_resources(i40e_t *i40e)
904 {
905 dev_info_t *parent;
906 uint16_t bus, device, func;
907 uint_t nregs;
908 int *regs, i;
909 i40e_device_t *idp;
910 i40e_hw_t *hw = &i40e->i40e_hw_space;
911
912 parent = ddi_get_parent(i40e->i40e_dip);
913
914 if (ddi_prop_lookup_int_array(DDI_DEV_T_ANY, i40e->i40e_dip, 0, "reg",
915 ®s, &nregs) != DDI_PROP_SUCCESS) {
916 return (B_FALSE);
917 }
918
919 if (nregs < 1) {
920 ddi_prop_free(regs);
921 return (B_FALSE);
922 }
923
924 bus = PCI_REG_BUS_G(regs[0]);
925 device = PCI_REG_DEV_G(regs[0]);
926 func = PCI_REG_FUNC_G(regs[0]);
927 ddi_prop_free(regs);
928
929 i40e->i40e_hw_space.bus.func = func;
930 i40e->i40e_hw_space.bus.device = device;
931
932 if (i40e_get_switch_resources(i40e) == B_FALSE) {
933 return (B_FALSE);
934 }
935
936 /*
937 * To calculate the total amount of a resource we have available, we
938 * need to add how many our i40e_t thinks it has guaranteed, if any, and
939 * then we need to go through and divide the number of available on the
940 * device, which was snapshotted before anyone should have allocated
941 * anything, and use that to derive how many are available from the
942 * pool. Longer term, we may want to turn this into something that's
943 * more of a pool-like resource that everything can share (though that
944 * may require some more assistance from MAC).
945 *
946 * Though for transmit and receive queue pairs, we just have to ask
947 * firmware instead.
948 */
949 idp = i40e_device_find(i40e, parent, bus, device);
950 i40e->i40e_device = idp;
951 i40e->i40e_resources.ifr_nvsis = 0;
952 i40e->i40e_resources.ifr_nvsis_used = 0;
953 i40e->i40e_resources.ifr_nmacfilt = 0;
954 i40e->i40e_resources.ifr_nmacfilt_used = 0;
955 i40e->i40e_resources.ifr_nmcastfilt = 0;
956 i40e->i40e_resources.ifr_nmcastfilt_used = 0;
957
958 for (i = 0; i < i40e->i40e_switch_rsrc_actual; i++) {
959 i40e_switch_rsrc_t *srp = &i40e->i40e_switch_rsrcs[i];
960
961 switch (srp->resource_type) {
962 case I40E_AQ_RESOURCE_TYPE_VSI:
963 i40e->i40e_resources.ifr_nvsis +=
964 LE_16(srp->guaranteed);
965 i40e->i40e_resources.ifr_nvsis_used = LE_16(srp->used);
966 break;
967 case I40E_AQ_RESOURCE_TYPE_MACADDR:
968 i40e->i40e_resources.ifr_nmacfilt +=
969 LE_16(srp->guaranteed);
970 i40e->i40e_resources.ifr_nmacfilt_used =
971 LE_16(srp->used);
972 break;
973 case I40E_AQ_RESOURCE_TYPE_MULTICAST_HASH:
974 i40e->i40e_resources.ifr_nmcastfilt +=
975 LE_16(srp->guaranteed);
976 i40e->i40e_resources.ifr_nmcastfilt_used =
977 LE_16(srp->used);
978 break;
979 default:
980 break;
981 }
982 }
983
984 for (i = 0; i < idp->id_rsrcs_act; i++) {
985 i40e_switch_rsrc_t *srp = &i40e->i40e_switch_rsrcs[i];
986 switch (srp->resource_type) {
987 case I40E_AQ_RESOURCE_TYPE_VSI:
988 i40e->i40e_resources.ifr_nvsis +=
989 LE_16(srp->total_unalloced) / idp->id_nfuncs;
990 break;
991 case I40E_AQ_RESOURCE_TYPE_MACADDR:
992 i40e->i40e_resources.ifr_nmacfilt +=
993 LE_16(srp->total_unalloced) / idp->id_nfuncs;
994 break;
995 case I40E_AQ_RESOURCE_TYPE_MULTICAST_HASH:
996 i40e->i40e_resources.ifr_nmcastfilt +=
997 LE_16(srp->total_unalloced) / idp->id_nfuncs;
998 default:
999 break;
1000 }
1001 }
1002
1003 i40e->i40e_resources.ifr_nrx_queue = hw->func_caps.num_rx_qp;
1004 i40e->i40e_resources.ifr_ntx_queue = hw->func_caps.num_tx_qp;
1005
1006 i40e->i40e_uaddrs = kmem_zalloc(sizeof (i40e_uaddr_t) *
1007 i40e->i40e_resources.ifr_nmacfilt, KM_SLEEP);
1008 i40e->i40e_maddrs = kmem_zalloc(sizeof (i40e_maddr_t) *
1009 i40e->i40e_resources.ifr_nmcastfilt, KM_SLEEP);
1010
1011 /*
1012 * Initialize these as multicast addresses to indicate it's invalid for
1013 * sanity purposes. Think of it like 0xdeadbeef.
1014 */
1015 for (i = 0; i < i40e->i40e_resources.ifr_nmacfilt; i++)
1016 i40e->i40e_uaddrs[i].iua_mac[0] = 0x01;
1017
1018 return (B_TRUE);
1019 }
1020
1021 static boolean_t
1022 i40e_enable_interrupts(i40e_t *i40e)
1023 {
1024 int i, rc;
1025
1026 if (i40e->i40e_intr_cap & DDI_INTR_FLAG_BLOCK) {
1027 rc = ddi_intr_block_enable(i40e->i40e_intr_handles,
1028 i40e->i40e_intr_count);
1029 if (rc != DDI_SUCCESS) {
1030 i40e_error(i40e, "Interrupt block-enable failed: %d",
1031 rc);
1032 return (B_FALSE);
1033 }
1034 } else {
1035 for (i = 0; i < i40e->i40e_intr_count; i++) {
1036 rc = ddi_intr_enable(i40e->i40e_intr_handles[i]);
1037 if (rc != DDI_SUCCESS) {
1038 i40e_error(i40e,
1039 "Failed to enable interrupt %d: %d", i, rc);
1040 while (--i >= 0) {
1041 (void) ddi_intr_disable(
1042 i40e->i40e_intr_handles[i]);
1043 }
1044 return (B_FALSE);
1045 }
1046 }
1047 }
1048
1049 return (B_TRUE);
1050 }
1051
1052 static boolean_t
1053 i40e_disable_interrupts(i40e_t *i40e)
1054 {
1055 int i, rc;
1056
1057 if (i40e->i40e_intr_cap & DDI_INTR_FLAG_BLOCK) {
1058 rc = ddi_intr_block_disable(i40e->i40e_intr_handles,
1059 i40e->i40e_intr_count);
1060 if (rc != DDI_SUCCESS) {
1061 i40e_error(i40e,
1062 "Interrupt block-disabled failed: %d", rc);
1063 return (B_FALSE);
1064 }
1065 } else {
1066 for (i = 0; i < i40e->i40e_intr_count; i++) {
1067 rc = ddi_intr_disable(i40e->i40e_intr_handles[i]);
1068 if (rc != DDI_SUCCESS) {
1069 i40e_error(i40e,
1070 "Failed to disable interrupt %d: %d",
1071 i, rc);
1072 return (B_FALSE);
1073 }
1074 }
1075 }
1076
1077 return (B_TRUE);
1078 }
1079
1080 /*
1081 * Free receive & transmit rings.
1082 */
1083 static void
1084 i40e_free_trqpairs(i40e_t *i40e)
1085 {
1086 int i;
1087 i40e_trqpair_t *itrq;
1088
1089 if (i40e->i40e_trqpairs != NULL) {
1090 for (i = 0; i < i40e->i40e_num_trqpairs; i++) {
1091 itrq = &i40e->i40e_trqpairs[i];
1092 mutex_destroy(&itrq->itrq_rx_lock);
1093 mutex_destroy(&itrq->itrq_tx_lock);
1094 mutex_destroy(&itrq->itrq_tcb_lock);
1095
1096 /*
1097 * Should have already been cleaned up by start/stop,
1098 * etc.
1099 */
1100 ASSERT(itrq->itrq_txkstat == NULL);
1101 ASSERT(itrq->itrq_rxkstat == NULL);
1102 }
1103
1104 kmem_free(i40e->i40e_trqpairs,
1105 sizeof (i40e_trqpair_t) * i40e->i40e_num_trqpairs);
1106 i40e->i40e_trqpairs = NULL;
1107 }
1108
1109 cv_destroy(&i40e->i40e_rx_pending_cv);
1110 mutex_destroy(&i40e->i40e_rx_pending_lock);
1111 mutex_destroy(&i40e->i40e_general_lock);
1112 }
1113
1114 /*
1115 * Allocate transmit and receive rings, as well as other data structures that we
1116 * need.
1117 */
1118 static boolean_t
1119 i40e_alloc_trqpairs(i40e_t *i40e)
1120 {
1121 int i;
1122 void *mutexpri = DDI_INTR_PRI(i40e->i40e_intr_pri);
1123
1124 /*
1125 * Now that we have the priority for the interrupts, initialize
1126 * all relevant locks.
1127 */
1128 mutex_init(&i40e->i40e_general_lock, NULL, MUTEX_DRIVER, mutexpri);
1129 mutex_init(&i40e->i40e_rx_pending_lock, NULL, MUTEX_DRIVER, mutexpri);
1130 cv_init(&i40e->i40e_rx_pending_cv, NULL, CV_DRIVER, NULL);
1131
1132 i40e->i40e_trqpairs = kmem_zalloc(sizeof (i40e_trqpair_t) *
1133 i40e->i40e_num_trqpairs, KM_SLEEP);
1134 for (i = 0; i < i40e->i40e_num_trqpairs; i++) {
1135 i40e_trqpair_t *itrq = &i40e->i40e_trqpairs[i];
1136
1137 itrq->itrq_i40e = i40e;
1138 mutex_init(&itrq->itrq_rx_lock, NULL, MUTEX_DRIVER, mutexpri);
1139 mutex_init(&itrq->itrq_tx_lock, NULL, MUTEX_DRIVER, mutexpri);
1140 mutex_init(&itrq->itrq_tcb_lock, NULL, MUTEX_DRIVER, mutexpri);
1141 itrq->itrq_index = i;
1142 }
1143
1144 return (B_TRUE);
1145 }
1146
1147
1148
1149 /*
1150 * Unless a .conf file already overrode i40e_t structure values, they will
1151 * be 0, and need to be set in conjunction with the now-available HW report.
1152 *
1153 * However, at the moment, we cap all of these resources as we only support a
1154 * single receive ring and a single group.
1155 */
1156 /* ARGSUSED */
1157 static void
1158 i40e_hw_to_instance(i40e_t *i40e, i40e_hw_t *hw)
1159 {
1160 if (i40e->i40e_num_trqpairs == 0) {
1161 i40e->i40e_num_trqpairs = I40E_TRQPAIR_MAX;
1162 }
1163
1164 if (i40e->i40e_num_rx_groups == 0) {
1165 i40e->i40e_num_rx_groups = I40E_GROUP_MAX;
1166 }
1167 }
1168
1169 /*
1170 * Free any resources required by, or setup by, the Intel common code.
1171 */
1172 static void
1173 i40e_common_code_fini(i40e_t *i40e)
1174 {
1175 i40e_hw_t *hw = &i40e->i40e_hw_space;
1176 int rc;
1177
1178 rc = i40e_shutdown_lan_hmc(hw);
1179 if (rc != I40E_SUCCESS)
1180 i40e_error(i40e, "failed to shutdown LAN hmc: %d", rc);
1181
1182 rc = i40e_shutdown_adminq(hw);
1183 if (rc != I40E_SUCCESS)
1184 i40e_error(i40e, "failed to shutdown admin queue: %d", rc);
1185 }
1186
1187 /*
1188 * Initialize and call Intel common-code routines, includes some setup
1189 * the common code expects from the driver. Also prints on failure, so
1190 * the caller doesn't have to.
1191 */
1192 static boolean_t
1193 i40e_common_code_init(i40e_t *i40e, i40e_hw_t *hw)
1194 {
1195 int rc;
1196
1197 i40e_clear_hw(hw);
1198 rc = i40e_pf_reset(hw);
1199 if (rc != 0) {
1200 i40e_error(i40e, "failed to reset hardware: %d", rc);
1201 i40e_fm_ereport(i40e, DDI_FM_DEVICE_NO_RESPONSE);
1202 return (B_FALSE);
1203 }
1204
1205 rc = i40e_init_shared_code(hw);
1206 if (rc != 0) {
1207 i40e_error(i40e, "failed to initialize i40e core: %d", rc);
1208 return (B_FALSE);
1209 }
1210
1211 hw->aq.num_arq_entries = I40E_DEF_ADMINQ_SIZE;
1212 hw->aq.num_asq_entries = I40E_DEF_ADMINQ_SIZE;
1213 hw->aq.arq_buf_size = I40E_ADMINQ_BUFSZ;
1214 hw->aq.asq_buf_size = I40E_ADMINQ_BUFSZ;
1215
1216 rc = i40e_init_adminq(hw);
1217 if (rc != 0) {
1218 i40e_error(i40e, "failed to initialize firmware admin queue: "
1219 "%d, potential firmware version mismatch", rc);
1220 i40e_fm_ereport(i40e, DDI_FM_DEVICE_INVAL_STATE);
1221 return (B_FALSE);
1222 }
1223
1224 if (hw->aq.api_maj_ver == I40E_FW_API_VERSION_MAJOR &&
1225 hw->aq.api_min_ver > I40E_FW_API_VERSION_MINOR) {
1226 i40e_notice(i40e, "The driver for the device detected a newer "
1227 "version of the NVM image (%d.%d) than expected (%d.%d).\n"
1228 "Please install the most recent version of the network "
1229 "driver.\n", hw->aq.api_maj_ver, hw->aq.api_min_ver,
1230 I40E_FW_API_VERSION_MAJOR, I40E_FW_API_VERSION_MINOR);
1231 } else if (hw->aq.api_maj_ver < I40E_FW_API_VERSION_MAJOR ||
1232 hw->aq.api_min_ver < (I40E_FW_API_VERSION_MINOR - 1)) {
1233 i40e_notice(i40e, "The driver for the device detected an older"
1234 " version of the NVM image (%d.%d) than expected (%d.%d)."
1235 "\nPlease update the NVM image.\n",
1236 hw->aq.api_maj_ver, hw->aq.api_min_ver,
1237 I40E_FW_API_VERSION_MAJOR, I40E_FW_API_VERSION_MINOR - 1);
1238 }
1239
1240 i40e_clear_pxe_mode(hw);
1241
1242 /*
1243 * We need to call this so that the common code can discover
1244 * capabilities of the hardware, which it uses throughout the rest.
1245 */
1246 if (!i40e_get_hw_capabilities(i40e, hw)) {
1247 i40e_error(i40e, "failed to obtain hardware capabilities");
1248 return (B_FALSE);
1249 }
1250
1251 if (i40e_get_available_resources(i40e) == B_FALSE) {
1252 i40e_error(i40e, "failed to obtain hardware resources");
1253 return (B_FALSE);
1254 }
1255
1256 i40e_hw_to_instance(i40e, hw);
1257
1258 rc = i40e_init_lan_hmc(hw, hw->func_caps.num_tx_qp,
1259 hw->func_caps.num_rx_qp, 0, 0);
1260 if (rc != 0) {
1261 i40e_error(i40e, "failed to initialize hardware memory cache: "
1262 "%d", rc);
1263 return (B_FALSE);
1264 }
1265
1266 rc = i40e_configure_lan_hmc(hw, I40E_HMC_MODEL_DIRECT_ONLY);
1267 if (rc != 0) {
1268 i40e_error(i40e, "failed to configure hardware memory cache: "
1269 "%d", rc);
1270 return (B_FALSE);
1271 }
1272
1273 (void) i40e_aq_stop_lldp(hw, TRUE, NULL);
1274
1275 rc = i40e_get_mac_addr(hw, hw->mac.addr);
1276 if (rc != I40E_SUCCESS) {
1277 i40e_error(i40e, "failed to retrieve hardware mac address: %d",
1278 rc);
1279 return (B_FALSE);
1280 }
1281
1282 rc = i40e_validate_mac_addr(hw->mac.addr);
1283 if (rc != 0) {
1284 i40e_error(i40e, "failed to validate internal mac address: "
1285 "%d", rc);
1286 return (B_FALSE);
1287 }
1288 bcopy(hw->mac.addr, hw->mac.perm_addr, ETHERADDRL);
1289 if ((rc = i40e_get_port_mac_addr(hw, hw->mac.port_addr)) !=
1290 I40E_SUCCESS) {
1291 i40e_error(i40e, "failed to retrieve port mac address: %d",
1292 rc);
1293 return (B_FALSE);
1294 }
1295
1296 /*
1297 * We need to obtain the Virtual Station ID (VSI) before we can
1298 * perform other operations on the device.
1299 */
1300 i40e->i40e_vsi_id = i40e_get_vsi_id(i40e);
1301 if (i40e->i40e_vsi_id == -1) {
1302 i40e_error(i40e, "failed to obtain VSI ID");
1303 return (B_FALSE);
1304 }
1305
1306 return (B_TRUE);
1307 }
1308
1309 static void
1310 i40e_unconfigure(dev_info_t *devinfo, i40e_t *i40e)
1311 {
1312 int rc;
1313
1314 if (i40e->i40e_attach_progress & I40E_ATTACH_ENABLE_INTR)
1315 (void) i40e_disable_interrupts(i40e);
1316
1317 if ((i40e->i40e_attach_progress & I40E_ATTACH_LINK_TIMER) &&
1318 i40e->i40e_periodic_id != 0) {
1319 ddi_periodic_delete(i40e->i40e_periodic_id);
1320 i40e->i40e_periodic_id = 0;
1321 }
1322
1323 if (i40e->i40e_attach_progress & I40E_ATTACH_MAC) {
1324 rc = mac_unregister(i40e->i40e_mac_hdl);
1325 if (rc != 0) {
1326 i40e_error(i40e, "failed to unregister from mac: %d",
1327 rc);
1328 }
1329 }
1330
1331 if (i40e->i40e_attach_progress & I40E_ATTACH_STATS) {
1332 i40e_stats_fini(i40e);
1333 }
1334
1335 if (i40e->i40e_attach_progress & I40E_ATTACH_ADD_INTR)
1336 i40e_rem_intr_handlers(i40e);
1337
1338 if (i40e->i40e_attach_progress & I40E_ATTACH_ALLOC_RINGSLOCKS)
1339 i40e_free_trqpairs(i40e);
1340
1341 if (i40e->i40e_attach_progress & I40E_ATTACH_ALLOC_INTR)
1342 i40e_rem_intrs(i40e);
1343
1344 if (i40e->i40e_attach_progress & I40E_ATTACH_COMMON_CODE)
1345 i40e_common_code_fini(i40e);
1346
1347 i40e_cleanup_resources(i40e);
1348
1349 if (i40e->i40e_attach_progress & I40E_ATTACH_PROPS)
1350 (void) ddi_prop_remove_all(devinfo);
1351
1352 if (i40e->i40e_attach_progress & I40E_ATTACH_REGS_MAP &&
1353 i40e->i40e_osdep_space.ios_reg_handle != NULL) {
1354 ddi_regs_map_free(&i40e->i40e_osdep_space.ios_reg_handle);
1355 i40e->i40e_osdep_space.ios_reg_handle = NULL;
1356 }
1357
1358 if ((i40e->i40e_attach_progress & I40E_ATTACH_PCI_CONFIG) &&
1359 i40e->i40e_osdep_space.ios_cfg_handle != NULL) {
1360 pci_config_teardown(&i40e->i40e_osdep_space.ios_cfg_handle);
1361 i40e->i40e_osdep_space.ios_cfg_handle = NULL;
1362 }
1363
1364 if (i40e->i40e_attach_progress & I40E_ATTACH_FM_INIT)
1365 i40e_fm_fini(i40e);
1366
1367 kmem_free(i40e->i40e_aqbuf, I40E_ADMINQ_BUFSZ);
1368 kmem_free(i40e, sizeof (i40e_t));
1369
1370 ddi_set_driver_private(devinfo, NULL);
1371 }
1372
1373 static boolean_t
1374 i40e_final_init(i40e_t *i40e)
1375 {
1376 i40e_hw_t *hw = &i40e->i40e_hw_space;
1377 struct i40e_osdep *osdep = OS_DEP(hw);
1378 uint8_t pbanum[I40E_PBANUM_STRLEN];
1379 enum i40e_status_code irc;
1380 char buf[I40E_DDI_PROP_LEN];
1381
1382 pbanum[0] = '\0';
1383 irc = i40e_read_pba_string(hw, pbanum, sizeof (pbanum));
1384 if (irc != I40E_SUCCESS) {
1385 i40e_log(i40e, "failed to read PBA string: %d", irc);
1386 } else {
1387 (void) ddi_prop_update_string(DDI_DEV_T_NONE, i40e->i40e_dip,
1388 "printed-board-assembly", (char *)pbanum);
1389 }
1390
1391 #ifdef DEBUG
1392 ASSERT(snprintf(NULL, 0, "%d.%d", hw->aq.fw_maj_ver,
1393 hw->aq.fw_min_ver) < sizeof (buf));
1394 ASSERT(snprintf(NULL, 0, "%x", hw->aq.fw_build) < sizeof (buf));
1395 ASSERT(snprintf(NULL, 0, "%d.%d", hw->aq.api_maj_ver,
1396 hw->aq.api_min_ver) < sizeof (buf));
1397 #endif
1398
1399 (void) snprintf(buf, sizeof (buf), "%d.%d", hw->aq.fw_maj_ver,
1400 hw->aq.fw_min_ver);
1401 (void) ddi_prop_update_string(DDI_DEV_T_NONE, i40e->i40e_dip,
1402 "firmware-version", buf);
1403 (void) snprintf(buf, sizeof (buf), "%x", hw->aq.fw_build);
1404 (void) ddi_prop_update_string(DDI_DEV_T_NONE, i40e->i40e_dip,
1405 "firmware-build", buf);
1406 (void) snprintf(buf, sizeof (buf), "%d.%d", hw->aq.api_maj_ver,
1407 hw->aq.api_min_ver);
1408 (void) ddi_prop_update_string(DDI_DEV_T_NONE, i40e->i40e_dip,
1409 "api-version", buf);
1410
1411 if (!i40e_set_hw_bus_info(hw))
1412 return (B_FALSE);
1413
1414 if (i40e_check_acc_handle(osdep->ios_reg_handle) != DDI_FM_OK) {
1415 ddi_fm_service_impact(i40e->i40e_dip, DDI_SERVICE_LOST);
1416 return (B_FALSE);
1417 }
1418
1419 return (B_TRUE);
1420 }
1421
1422 static boolean_t
1423 i40e_identify_hardware(i40e_t *i40e)
1424 {
1425 i40e_hw_t *hw = &i40e->i40e_hw_space;
1426 struct i40e_osdep *osdep = &i40e->i40e_osdep_space;
1427
1428 hw->vendor_id = pci_config_get16(osdep->ios_cfg_handle, PCI_CONF_VENID);
1429 hw->device_id = pci_config_get16(osdep->ios_cfg_handle, PCI_CONF_DEVID);
1430 hw->revision_id = pci_config_get8(osdep->ios_cfg_handle,
1431 PCI_CONF_REVID);
1432 hw->subsystem_device_id =
1433 pci_config_get16(osdep->ios_cfg_handle, PCI_CONF_SUBSYSID);
1434 hw->subsystem_vendor_id =
1435 pci_config_get16(osdep->ios_cfg_handle, PCI_CONF_SUBVENID);
1436
1437 /*
1438 * Note that we set the hardware's bus information later on, in
1439 * i40e_get_available_resources(). The common code doesn't seem to
1440 * require that it be set in any ways, it seems to be mostly for
1441 * book-keeping.
1442 */
1443
1444 /* Call common code to set the MAC type for this adapter. */
1445 if (i40e_set_mac_type(hw) != I40E_SUCCESS)
1446 return (B_FALSE);
1447
1448 return (B_TRUE);
1449 }
1450
1451 static boolean_t
1452 i40e_regs_map(i40e_t *i40e)
1453 {
1454 dev_info_t *devinfo = i40e->i40e_dip;
1455 i40e_hw_t *hw = &i40e->i40e_hw_space;
1456 struct i40e_osdep *osdep = &i40e->i40e_osdep_space;
1457 off_t memsize;
1458 int ret;
1459
1460 if (ddi_dev_regsize(devinfo, I40E_ADAPTER_REGSET, &memsize) !=
1461 DDI_SUCCESS) {
1462 i40e_error(i40e, "Used invalid register set to map PCIe regs");
1463 return (B_FALSE);
1464 }
1465
1466 if ((ret = ddi_regs_map_setup(devinfo, I40E_ADAPTER_REGSET,
1467 (caddr_t *)&hw->hw_addr, 0, memsize, &i40e_regs_acc_attr,
1468 &osdep->ios_reg_handle)) != DDI_SUCCESS) {
1469 i40e_error(i40e, "failed to map device registers: %d", ret);
1470 return (B_FALSE);
1471 }
1472
1473 osdep->ios_reg_size = memsize;
1474 return (B_TRUE);
1475 }
1476
1477 /*
1478 * Update parameters required when a new MTU has been configured. Calculate the
1479 * maximum frame size, as well as, size our DMA buffers which we size in
1480 * increments of 1K.
1481 */
1482 void
1483 i40e_update_mtu(i40e_t *i40e)
1484 {
1485 uint32_t rx, tx;
1486
1487 i40e->i40e_frame_max = i40e->i40e_sdu +
1488 sizeof (struct ether_vlan_header) + ETHERFCSL;
1489
1490 rx = i40e->i40e_frame_max + I40E_BUF_IPHDR_ALIGNMENT;
1491 i40e->i40e_rx_buf_size = ((rx >> 10) +
1492 ((rx & (((uint32_t)1 << 10) -1)) > 0 ? 1 : 0)) << 10;
1493
1494 tx = i40e->i40e_frame_max;
1495 i40e->i40e_tx_buf_size = ((tx >> 10) +
1496 ((tx & (((uint32_t)1 << 10) -1)) > 0 ? 1 : 0)) << 10;
1497 }
1498
1499 static int
1500 i40e_get_prop(i40e_t *i40e, char *prop, int min, int max, int def)
1501 {
1502 int val;
1503
1504 val = ddi_prop_get_int(DDI_DEV_T_ANY, i40e->i40e_dip, DDI_PROP_DONTPASS,
1505 prop, def);
1506 if (val > max)
1507 val = max;
1508 if (val < min)
1509 val = min;
1510 return (val);
1511 }
1512
1513 static void
1514 i40e_init_properties(i40e_t *i40e)
1515 {
1516 i40e->i40e_sdu = i40e_get_prop(i40e, "default_mtu",
1517 I40E_MIN_MTU, I40E_MAX_MTU, I40E_DEF_MTU);
1518
1519 i40e->i40e_intr_force = i40e_get_prop(i40e, "intr_force",
1520 I40E_INTR_NONE, I40E_INTR_LEGACY, I40E_INTR_NONE);
1521
1522 i40e->i40e_mr_enable = i40e_get_prop(i40e, "mr_enable",
1523 B_FALSE, B_TRUE, B_TRUE);
1524
1525 i40e->i40e_tx_ring_size = i40e_get_prop(i40e, "tx_ring_size",
1526 I40E_MIN_TX_RING_SIZE, I40E_MAX_TX_RING_SIZE,
1527 I40E_DEF_TX_RING_SIZE);
1528 if ((i40e->i40e_tx_ring_size % I40E_DESC_ALIGN) != 0) {
1529 i40e->i40e_tx_ring_size = P2ROUNDUP(i40e->i40e_tx_ring_size,
1530 I40E_DESC_ALIGN);
1531 }
1532
1533 i40e->i40e_tx_block_thresh = i40e_get_prop(i40e, "tx_resched_threshold",
1534 I40E_MIN_TX_BLOCK_THRESH,
1535 i40e->i40e_tx_ring_size - I40E_TX_MAX_COOKIE,
1536 I40E_DEF_TX_BLOCK_THRESH);
1537
1538 i40e->i40e_rx_ring_size = i40e_get_prop(i40e, "rx_ring_size",
1539 I40E_MIN_RX_RING_SIZE, I40E_MAX_RX_RING_SIZE,
1540 I40E_DEF_RX_RING_SIZE);
1541 if ((i40e->i40e_rx_ring_size % I40E_DESC_ALIGN) != 0) {
1542 i40e->i40e_rx_ring_size = P2ROUNDUP(i40e->i40e_rx_ring_size,
1543 I40E_DESC_ALIGN);
1544 }
1545
1546 i40e->i40e_rx_limit_per_intr = i40e_get_prop(i40e, "rx_limit_per_intr",
1547 I40E_MIN_RX_LIMIT_PER_INTR, I40E_MAX_RX_LIMIT_PER_INTR,
1548 I40E_DEF_RX_LIMIT_PER_INTR);
1549
1550 i40e->i40e_tx_hcksum_enable = i40e_get_prop(i40e, "tx_hcksum_enable",
1551 B_FALSE, B_TRUE, B_TRUE);
1552
1553 i40e->i40e_rx_hcksum_enable = i40e_get_prop(i40e, "rx_hcksum_enable",
1554 B_FALSE, B_TRUE, B_TRUE);
1555
1556 i40e->i40e_rx_dma_min = i40e_get_prop(i40e, "rx_dma_threshold",
1557 I40E_MIN_RX_DMA_THRESH, I40E_MAX_RX_DMA_THRESH,
1558 I40E_DEF_RX_DMA_THRESH);
1559
1560 i40e->i40e_tx_dma_min = i40e_get_prop(i40e, "tx_dma_threshold",
1561 I40E_MIN_TX_DMA_THRESH, I40E_MAX_TX_DMA_THRESH,
1562 I40E_DEF_TX_DMA_THRESH);
1563
1564 i40e->i40e_tx_itr = i40e_get_prop(i40e, "tx_intr_throttle",
1565 I40E_MIN_ITR, I40E_MAX_ITR, I40E_DEF_TX_ITR);
1566
1567 i40e->i40e_rx_itr = i40e_get_prop(i40e, "rx_intr_throttle",
1568 I40E_MIN_ITR, I40E_MAX_ITR, I40E_DEF_RX_ITR);
1569
1570 i40e->i40e_other_itr = i40e_get_prop(i40e, "other_intr_throttle",
1571 I40E_MIN_ITR, I40E_MAX_ITR, I40E_DEF_OTHER_ITR);
1572
1573 if (!i40e->i40e_mr_enable) {
1574 i40e->i40e_num_trqpairs = I40E_TRQPAIR_NOMSIX;
1575 i40e->i40e_num_rx_groups = I40E_GROUP_NOMSIX;
1576 }
1577
1578 i40e_update_mtu(i40e);
1579 }
1580
1581 /*
1582 * There are a few constraints on interrupts that we're currently imposing, some
1583 * of which are restrictions from hardware. For a fuller treatment, see
1584 * i40e_intr.c.
1585 *
1586 * Currently, to use MSI-X we require two interrupts be available though in
1587 * theory we should participate in IRM and happily use more interrupts.
1588 *
1589 * Hardware only supports a single MSI being programmed and therefore if we
1590 * don't have MSI-X interrupts available at this time, then we ratchet down the
1591 * number of rings and groups available. Obviously, we only bother with a single
1592 * fixed interrupt.
1593 */
1594 static boolean_t
1595 i40e_alloc_intr_handles(i40e_t *i40e, dev_info_t *devinfo, int intr_type)
1596 {
1597 int request, count, actual, rc, min;
1598
1599 switch (intr_type) {
1600 case DDI_INTR_TYPE_FIXED:
1601 case DDI_INTR_TYPE_MSI:
1602 request = 1;
1603 min = 1;
1604 break;
1605 case DDI_INTR_TYPE_MSIX:
1606 /*
1607 * At the moment, we always request two MSI-X while we still
1608 * only support a single interrupt. The upper bound on what's
1609 * supported by a given device is defined by MSI_X_PF_N in
1610 * GLPCI_CNF2. When we evolve, we should read it to determine
1611 * what the real max is.
1612 */
1613 ASSERT(i40e->i40e_num_trqpairs == 1);
1614 request = 2;
1615 min = 2;
1616 break;
1617 default:
1618 panic("bad interrupt type passed to i40e_alloc_intr_handles: "
1619 "%d", intr_type);
1620 return (B_FALSE);
1621 }
1622
1623 rc = ddi_intr_get_nintrs(devinfo, intr_type, &count);
1624 if (rc != DDI_SUCCESS || count < min) {
1625 i40e_log(i40e, "Get interrupt number failed, "
1626 "returned %d, count %d", rc, count);
1627 return (B_FALSE);
1628 }
1629
1630 rc = ddi_intr_get_navail(devinfo, intr_type, &count);
1631 if (rc != DDI_SUCCESS || count < min) {
1632 i40e_log(i40e, "Get AVAILABLE interrupt number failed, "
1633 "returned %d, count %d", rc, count);
1634 return (B_FALSE);
1635 }
1636
1637 actual = 0;
1638 i40e->i40e_intr_count = 0;
1639 i40e->i40e_intr_count_max = 0;
1640 i40e->i40e_intr_count_min = 0;
1641
1642 i40e->i40e_intr_size = request * sizeof (ddi_intr_handle_t);
1643 ASSERT(i40e->i40e_intr_size != 0);
1644 i40e->i40e_intr_handles = kmem_alloc(i40e->i40e_intr_size, KM_SLEEP);
1645
1646 rc = ddi_intr_alloc(devinfo, i40e->i40e_intr_handles, intr_type, 0,
1647 min(request, count), &actual, DDI_INTR_ALLOC_NORMAL);
1648 if (rc != DDI_SUCCESS) {
1649 i40e_log(i40e, "Interrupt allocation failed with %d.", rc);
1650 goto alloc_handle_fail;
1651 }
1652
1653 i40e->i40e_intr_count = actual;
1654 i40e->i40e_intr_count_max = request;
1655 i40e->i40e_intr_count_min = min;
1656
1657 if (actual < min) {
1658 i40e_log(i40e, "actual (%d) is less than minimum (%d).",
1659 actual, min);
1660 goto alloc_handle_fail;
1661 }
1662
1663 /*
1664 * Record the priority and capabilities for our first vector. Once
1665 * we have it, that's our priority until detach time. Even if we
1666 * eventually participate in IRM, our priority shouldn't change.
1667 */
1668 rc = ddi_intr_get_pri(i40e->i40e_intr_handles[0], &i40e->i40e_intr_pri);
1669 if (rc != DDI_SUCCESS) {
1670 i40e_log(i40e,
1671 "Getting interrupt priority failed with %d.", rc);
1672 goto alloc_handle_fail;
1673 }
1674
1675 rc = ddi_intr_get_cap(i40e->i40e_intr_handles[0], &i40e->i40e_intr_cap);
1676 if (rc != DDI_SUCCESS) {
1677 i40e_log(i40e,
1678 "Getting interrupt capabilities failed with %d.", rc);
1679 goto alloc_handle_fail;
1680 }
1681
1682 i40e->i40e_intr_type = intr_type;
1683 return (B_TRUE);
1684
1685 alloc_handle_fail:
1686
1687 i40e_rem_intrs(i40e);
1688 return (B_FALSE);
1689 }
1690
1691 static boolean_t
1692 i40e_alloc_intrs(i40e_t *i40e, dev_info_t *devinfo)
1693 {
1694 int intr_types, rc;
1695
1696 rc = ddi_intr_get_supported_types(devinfo, &intr_types);
1697 if (rc != DDI_SUCCESS) {
1698 i40e_error(i40e, "failed to get supported interrupt types: %d",
1699 rc);
1700 return (B_FALSE);
1701 }
1702
1703 i40e->i40e_intr_type = 0;
1704
1705 if ((intr_types & DDI_INTR_TYPE_MSIX) &&
1706 i40e->i40e_intr_force <= I40E_INTR_MSIX) {
1707 if (i40e_alloc_intr_handles(i40e, devinfo, DDI_INTR_TYPE_MSIX))
1708 return (B_TRUE);
1709 }
1710
1711 /*
1712 * We only use multiple transmit/receive pairs when MSI-X interrupts are
1713 * available due to the fact that the device basically only supports a
1714 * single MSI interrupt.
1715 */
1716 i40e->i40e_num_trqpairs = I40E_TRQPAIR_NOMSIX;
1717 i40e->i40e_num_rx_groups = I40E_GROUP_NOMSIX;
1718
1719 if ((intr_types & DDI_INTR_TYPE_MSI) &&
1720 (i40e->i40e_intr_force <= I40E_INTR_MSI)) {
1721 if (i40e_alloc_intr_handles(i40e, devinfo, DDI_INTR_TYPE_MSI))
1722 return (B_TRUE);
1723 }
1724
1725 if (intr_types & DDI_INTR_TYPE_FIXED) {
1726 if (i40e_alloc_intr_handles(i40e, devinfo, DDI_INTR_TYPE_FIXED))
1727 return (B_TRUE);
1728 }
1729
1730 return (B_FALSE);
1731 }
1732
1733 /*
1734 * Map different interrupts to MSI-X vectors.
1735 */
1736 static boolean_t
1737 i40e_map_intrs_to_vectors(i40e_t *i40e)
1738 {
1739 if (i40e->i40e_intr_type != DDI_INTR_TYPE_MSIX) {
1740 return (B_TRUE);
1741 }
1742
1743 /*
1744 * At the moment, we only have one queue and one interrupt thus both are
1745 * on that one interrupt. However, longer term we need to go back to
1746 * using the ixgbe style map of queues to vectors or walk the linked
1747 * list from the device to know what to go handle. Therefore for the
1748 * moment, since we need to map our single set of rings to the one
1749 * I/O interrupt that exists for MSI-X.
1750 */
1751 ASSERT(i40e->i40e_intr_count == 2);
1752 ASSERT(i40e->i40e_num_trqpairs == 1);
1753
1754 i40e->i40e_trqpairs[0].itrq_rx_intrvec = 1;
1755 i40e->i40e_trqpairs[0].itrq_tx_intrvec = 1;
1756
1757 return (B_TRUE);
1758 }
1759
1760 static boolean_t
1761 i40e_add_intr_handlers(i40e_t *i40e)
1762 {
1763 int rc, vector;
1764
1765 switch (i40e->i40e_intr_type) {
1766 case DDI_INTR_TYPE_MSIX:
1767 for (vector = 0; vector < i40e->i40e_intr_count; vector++) {
1768 rc = ddi_intr_add_handler(
1769 i40e->i40e_intr_handles[vector],
1770 (ddi_intr_handler_t *)i40e_intr_msix, i40e,
1771 (void *)(uintptr_t)vector);
1772 if (rc != DDI_SUCCESS) {
1773 i40e_log(i40e, "Add interrupt handler (MSI-X) "
1774 "failed: return %d, vector %d", rc, vector);
1775 for (vector--; vector >= 0; vector--) {
1776 (void) ddi_intr_remove_handler(
1777 i40e->i40e_intr_handles[vector]);
1778 }
1779 return (B_FALSE);
1780 }
1781 }
1782 break;
1783 case DDI_INTR_TYPE_MSI:
1784 rc = ddi_intr_add_handler(i40e->i40e_intr_handles[0],
1785 (ddi_intr_handler_t *)i40e_intr_msi, i40e, NULL);
1786 if (rc != DDI_SUCCESS) {
1787 i40e_log(i40e, "Add interrupt handler (MSI) failed: "
1788 "return %d", rc);
1789 return (B_FALSE);
1790 }
1791 break;
1792 case DDI_INTR_TYPE_FIXED:
1793 rc = ddi_intr_add_handler(i40e->i40e_intr_handles[0],
1794 (ddi_intr_handler_t *)i40e_intr_legacy, i40e, NULL);
1795 if (rc != DDI_SUCCESS) {
1796 i40e_log(i40e, "Add interrupt handler (legacy) failed:"
1797 " return %d", rc);
1798 return (B_FALSE);
1799 }
1800 break;
1801 default:
1802 /* Cast to pacify lint */
1803 panic("i40e_intr_type %p contains an unknown type: %d",
1804 (void *)i40e, i40e->i40e_intr_type);
1805 }
1806
1807 return (B_TRUE);
1808 }
1809
1810 /*
1811 * Perform periodic checks. Longer term, we should be thinking about additional
1812 * things here:
1813 *
1814 * o Stall Detection
1815 * o Temperature sensor detection
1816 * o Device resetting
1817 * o Statistics updating to avoid wraparound
1818 */
1819 static void
1820 i40e_timer(void *arg)
1821 {
1822 i40e_t *i40e = arg;
1823
1824 mutex_enter(&i40e->i40e_general_lock);
1825 i40e_link_check(i40e);
1826 mutex_exit(&i40e->i40e_general_lock);
1827 }
1828
1829 /*
1830 * Get the hardware state, and scribble away anything that needs scribbling.
1831 */
1832 static void
1833 i40e_get_hw_state(i40e_t *i40e, i40e_hw_t *hw)
1834 {
1835 int rc;
1836
1837 ASSERT(MUTEX_HELD(&i40e->i40e_general_lock));
1838
1839 (void) i40e_aq_get_link_info(hw, TRUE, NULL, NULL);
1840 i40e_link_check(i40e);
1841
1842 /*
1843 * Try and determine our PHY. Note that we may have to retry to and
1844 * delay to detect fiber correctly.
1845 */
1846 rc = i40e_aq_get_phy_capabilities(hw, B_FALSE, B_TRUE, &i40e->i40e_phy,
1847 NULL);
1848 if (rc == I40E_ERR_UNKNOWN_PHY) {
1849 i40e_msec_delay(200);
1850 rc = i40e_aq_get_phy_capabilities(hw, B_FALSE, B_TRUE,
1851 &i40e->i40e_phy, NULL);
1852 }
1853
1854 if (rc != I40E_SUCCESS) {
1855 if (rc == I40E_ERR_UNKNOWN_PHY) {
1856 i40e_error(i40e, "encountered unknown PHY type, "
1857 "not attaching.");
1858 } else {
1859 i40e_error(i40e, "error getting physical capabilities: "
1860 "%d, %d", rc, hw->aq.asq_last_status);
1861 }
1862 }
1863
1864 rc = i40e_update_link_info(hw);
1865 if (rc != I40E_SUCCESS) {
1866 i40e_error(i40e, "failed to update link information: %d", rc);
1867 }
1868
1869 /*
1870 * In general, we don't want to mask off (as in stop from being a cause)
1871 * any of the interrupts that the phy might be able to generate.
1872 */
1873 rc = i40e_aq_set_phy_int_mask(hw, 0, NULL);
1874 if (rc != I40E_SUCCESS) {
1875 i40e_error(i40e, "failed to update phy link mask: %d", rc);
1876 }
1877 }
1878
1879 /*
1880 * Go through and re-initialize any existing filters that we may have set up for
1881 * this device. Note that we would only expect them to exist if hardware had
1882 * already been initialized and we had just reset it. While we're not
1883 * implementing this yet, we're keeping this around for when we add reset
1884 * capabilities, so this isn't forgotten.
1885 */
1886 /* ARGSUSED */
1887 static void
1888 i40e_init_macaddrs(i40e_t *i40e, i40e_hw_t *hw)
1889 {
1890 }
1891
1892 /*
1893 * Configure the hardware for the Virtual Station Interface (VSI). Currently
1894 * we only support one, but in the future we could instantiate more than one
1895 * per attach-point.
1896 */
1897 static boolean_t
1898 i40e_config_vsi(i40e_t *i40e, i40e_hw_t *hw)
1899 {
1900 struct i40e_vsi_context context;
1901 int err;
1902
1903 bzero(&context, sizeof (struct i40e_vsi_context));
1904 context.seid = i40e->i40e_vsi_id;
1905 context.pf_num = hw->pf_id;
1906 err = i40e_aq_get_vsi_params(hw, &context, NULL);
1907 if (err != I40E_SUCCESS) {
1908 i40e_error(i40e, "get VSI params failed with %d", err);
1909 return (B_FALSE);
1910 }
1911
1912 /*
1913 * Set the queue and traffic class bits. Keep it simple for now.
1914 */
1915 context.info.valid_sections = I40E_AQ_VSI_PROP_QUEUE_MAP_VALID;
1916 context.info.mapping_flags = I40E_AQ_VSI_QUE_MAP_CONTIG;
1917 context.info.queue_mapping[0] = I40E_ASSIGN_ALL_QUEUES;
1918 context.info.tc_mapping[0] = I40E_TRAFFIC_CLASS_NO_QUEUES;
1919
1920 context.info.valid_sections |= I40E_AQ_VSI_PROP_VLAN_VALID;
1921 context.info.port_vlan_flags = I40E_AQ_VSI_PVLAN_MODE_ALL |
1922 I40E_AQ_VSI_PVLAN_EMOD_NOTHING;
1923
1924 context.flags = LE16_TO_CPU(I40E_AQ_VSI_TYPE_PF);
1925
1926 i40e->i40e_vsi_stat_id = LE16_TO_CPU(context.info.stat_counter_idx);
1927 if (i40e_stat_vsi_init(i40e) == B_FALSE)
1928 return (B_FALSE);
1929
1930 err = i40e_aq_update_vsi_params(hw, &context, NULL);
1931 if (err != I40E_SUCCESS) {
1932 i40e_error(i40e, "Update VSI params failed with %d", err);
1933 return (B_FALSE);
1934 }
1935
1936
1937 return (B_TRUE);
1938 }
1939
1940 /*
1941 * Wrapper to kick the chipset on.
1942 */
1943 static boolean_t
1944 i40e_chip_start(i40e_t *i40e)
1945 {
1946 i40e_hw_t *hw = &i40e->i40e_hw_space;
1947 struct i40e_filter_control_settings filter;
1948 int rc;
1949
1950 if (((hw->aq.fw_maj_ver == 4) && (hw->aq.fw_min_ver < 33)) ||
1951 (hw->aq.fw_maj_ver < 4)) {
1952 i40e_msec_delay(75);
1953 if (i40e_aq_set_link_restart_an(hw, TRUE, NULL) !=
1954 I40E_SUCCESS) {
1955 i40e_error(i40e, "failed to restart link: admin queue "
1956 "error: %d", hw->aq.asq_last_status);
1957 return (B_FALSE);
1958 }
1959 }
1960
1961 /* Determine hardware state */
1962 i40e_get_hw_state(i40e, hw);
1963
1964 /* Initialize mac addresses. */
1965 i40e_init_macaddrs(i40e, hw);
1966
1967 /*
1968 * Set up the filter control.
1969 */
1970 bzero(&filter, sizeof (filter));
1971 filter.enable_ethtype = TRUE;
1972 filter.enable_macvlan = TRUE;
1973
1974 rc = i40e_set_filter_control(hw, &filter);
1975 if (rc != I40E_SUCCESS) {
1976 i40e_error(i40e, "i40e_set_filter_control() returned %d", rc);
1977 return (B_FALSE);
1978 }
1979
1980 i40e_intr_chip_init(i40e);
1981
1982 if (!i40e_config_vsi(i40e, hw))
1983 return (B_FALSE);
1984
1985 i40e_flush(hw);
1986
1987 return (B_TRUE);
1988 }
1989
1990 /*
1991 * Take care of tearing down the rx ring. See 8.3.3.1.2 for more information.
1992 */
1993 static void
1994 i40e_shutdown_rx_rings(i40e_t *i40e)
1995 {
1996 int i;
1997 uint32_t reg;
1998
1999 i40e_hw_t *hw = &i40e->i40e_hw_space;
2000
2001 /*
2002 * Step 1. The interrupt linked list (see i40e_intr.c for more
2003 * information) should have already been cleared before calling this
2004 * function.
2005 */
2006 #ifdef DEBUG
2007 if (i40e->i40e_intr_type == DDI_INTR_TYPE_MSIX) {
2008 for (i = 1; i < i40e->i40e_intr_count; i++) {
2009 reg = I40E_READ_REG(hw, I40E_PFINT_LNKLSTN(i - 1));
2010 VERIFY3U(reg, ==, I40E_QUEUE_TYPE_EOL);
2011 }
2012 } else {
2013 reg = I40E_READ_REG(hw, I40E_PFINT_LNKLST0);
2014 VERIFY3U(reg, ==, I40E_QUEUE_TYPE_EOL);
2015 }
2016
2017 #endif /* DEBUG */
2018
2019 for (i = 0; i < i40e->i40e_num_trqpairs; i++) {
2020 /*
2021 * Step 1. Request the queue by clearing QENA_REQ. It may not be
2022 * set due to unwinding from failures and a partially enabled
2023 * ring set.
2024 */
2025 reg = I40E_READ_REG(hw, I40E_QRX_ENA(i));
2026 if (!(reg & I40E_QRX_ENA_QENA_REQ_MASK))
2027 continue;
2028 VERIFY((reg & I40E_QRX_ENA_QENA_REQ_MASK) ==
2029 I40E_QRX_ENA_QENA_REQ_MASK);
2030 reg &= ~I40E_QRX_ENA_QENA_REQ_MASK;
2031 I40E_WRITE_REG(hw, I40E_QRX_ENA(i), reg);
2032 }
2033
2034 /*
2035 * Step 2. Wait for the disable to take, by having QENA_STAT in the FPM
2036 * be cleared. Note that we could still receive data in the queue during
2037 * this time. We don't actually wait for this now and instead defer this
2038 * to i40e_shutdown_rings_wait(), after we've interleaved disabling the
2039 * TX queues as well.
2040 */
2041 }
2042
2043 static void
2044 i40e_shutdown_tx_rings(i40e_t *i40e)
2045 {
2046 int i;
2047 uint32_t reg;
2048
2049 i40e_hw_t *hw = &i40e->i40e_hw_space;
2050
2051 /*
2052 * Step 1. The interrupt linked list should already have been cleared.
2053 */
2054 #ifdef DEBUG
2055 if (i40e->i40e_intr_type == DDI_INTR_TYPE_MSIX) {
2056 for (i = 1; i < i40e->i40e_intr_count; i++) {
2057 reg = I40E_READ_REG(hw, I40E_PFINT_LNKLSTN(i - 1));
2058 VERIFY3U(reg, ==, I40E_QUEUE_TYPE_EOL);
2059 }
2060 } else {
2061 reg = I40E_READ_REG(hw, I40E_PFINT_LNKLST0);
2062 VERIFY3U(reg, ==, I40E_QUEUE_TYPE_EOL);
2063
2064 }
2065 #endif /* DEBUG */
2066
2067 for (i = 0; i < i40e->i40e_num_trqpairs; i++) {
2068 /*
2069 * Step 2. Set the SET_QDIS flag for every queue.
2070 */
2071 i40e_pre_tx_queue_cfg(hw, i, B_FALSE);
2072 }
2073
2074 /*
2075 * Step 3. Wait at least 400 usec (can be done once for all queues).
2076 */
2077 drv_usecwait(500);
2078
2079 for (i = 0; i < i40e->i40e_num_trqpairs; i++) {
2080 /*
2081 * Step 4. Clear the QENA_REQ flag which tells hardware to
2082 * quiesce. If QENA_REQ is not already set then that means that
2083 * we likely already tried to disable this queue.
2084 */
2085 reg = I40E_READ_REG(hw, I40E_QTX_ENA(i));
2086 if (!(reg & I40E_QTX_ENA_QENA_REQ_MASK))
2087 continue;
2088 reg &= ~I40E_QTX_ENA_QENA_REQ_MASK;
2089 I40E_WRITE_REG(hw, I40E_QTX_ENA(i), reg);
2090 }
2091
2092 /*
2093 * Step 5. Wait for all drains to finish. This will be done by the
2094 * hardware removing the QENA_STAT flag from the queue. Rather than
2095 * waiting here, we interleave it with all the others in
2096 * i40e_shutdown_rings_wait().
2097 */
2098 }
2099
2100 /*
2101 * Wait for all the rings to be shut down. e.g. Steps 2 and 5 from the above
2102 * functions.
2103 */
2104 static boolean_t
2105 i40e_shutdown_rings_wait(i40e_t *i40e)
2106 {
2107 int i, try;
2108 i40e_hw_t *hw = &i40e->i40e_hw_space;
2109
2110 for (i = 0; i < i40e->i40e_num_trqpairs; i++) {
2111 uint32_t reg;
2112
2113 for (try = 0; try < I40E_RING_WAIT_NTRIES; try++) {
2114 reg = I40E_READ_REG(hw, I40E_QRX_ENA(i));
2115 if ((reg & I40E_QRX_ENA_QENA_STAT_MASK) == 0)
2116 break;
2117 i40e_msec_delay(I40E_RING_WAIT_PAUSE);
2118 }
2119
2120 if ((reg & I40E_QRX_ENA_QENA_STAT_MASK) != 0) {
2121 i40e_error(i40e, "timed out disabling rx queue %d",
2122 i);
2123 return (B_FALSE);
2124 }
2125
2126 for (try = 0; try < I40E_RING_WAIT_NTRIES; try++) {
2127 reg = I40E_READ_REG(hw, I40E_QTX_ENA(i));
2128 if ((reg & I40E_QTX_ENA_QENA_STAT_MASK) == 0)
2129 break;
2130 i40e_msec_delay(I40E_RING_WAIT_PAUSE);
2131 }
2132
2133 if ((reg & I40E_QTX_ENA_QENA_STAT_MASK) != 0) {
2134 i40e_error(i40e, "timed out disabling tx queue %d",
2135 i);
2136 return (B_FALSE);
2137 }
2138 }
2139
2140 return (B_TRUE);
2141 }
2142
2143 static boolean_t
2144 i40e_shutdown_rings(i40e_t *i40e)
2145 {
2146 i40e_shutdown_rx_rings(i40e);
2147 i40e_shutdown_tx_rings(i40e);
2148 return (i40e_shutdown_rings_wait(i40e));
2149 }
2150
2151 static void
2152 i40e_setup_rx_descs(i40e_trqpair_t *itrq)
2153 {
2154 int i;
2155 i40e_rx_data_t *rxd = itrq->itrq_rxdata;
2156
2157 for (i = 0; i < rxd->rxd_ring_size; i++) {
2158 i40e_rx_control_block_t *rcb;
2159 i40e_rx_desc_t *rdesc;
2160
2161 rcb = rxd->rxd_work_list[i];
2162 rdesc = &rxd->rxd_desc_ring[i];
2163
2164 rdesc->read.pkt_addr =
2165 CPU_TO_LE64((uintptr_t)rcb->rcb_dma.dmab_dma_address);
2166 rdesc->read.hdr_addr = 0;
2167 }
2168 }
2169
2170 static boolean_t
2171 i40e_setup_rx_hmc(i40e_trqpair_t *itrq)
2172 {
2173 i40e_rx_data_t *rxd = itrq->itrq_rxdata;
2174 i40e_t *i40e = itrq->itrq_i40e;
2175 i40e_hw_t *hw = &i40e->i40e_hw_space;
2176
2177 struct i40e_hmc_obj_rxq rctx;
2178 int err;
2179
2180 bzero(&rctx, sizeof (struct i40e_hmc_obj_rxq));
2181 rctx.base = rxd->rxd_desc_area.dmab_dma_address /
2182 I40E_HMC_RX_CTX_UNIT;
2183 rctx.qlen = rxd->rxd_ring_size;
2184 VERIFY(i40e->i40e_rx_buf_size >= I40E_HMC_RX_DBUFF_MIN);
2185 VERIFY(i40e->i40e_rx_buf_size <= I40E_HMC_RX_DBUFF_MAX);
2186 rctx.dbuff = i40e->i40e_rx_buf_size >> I40E_RXQ_CTX_DBUFF_SHIFT;
2187 rctx.hbuff = 0 >> I40E_RXQ_CTX_HBUFF_SHIFT;
2188 rctx.dtype = I40E_HMC_RX_DTYPE_NOSPLIT;
2189 rctx.dsize = I40E_HMC_RX_DSIZE_32BYTE;
2190 rctx.crcstrip = I40E_HMC_RX_CRCSTRIP_ENABLE;
2191 rctx.fc_ena = I40E_HMC_RX_FC_DISABLE;
2192 rctx.l2tsel = I40E_HMC_RX_L2TAGORDER;
2193 rctx.hsplit_0 = I40E_HMC_RX_HDRSPLIT_DISABLE;
2194 rctx.hsplit_1 = I40E_HMC_RX_HDRSPLIT_DISABLE;
2195 rctx.showiv = I40E_HMC_RX_INVLAN_DONTSTRIP;
2196 rctx.rxmax = i40e->i40e_frame_max;
2197 rctx.tphrdesc_ena = I40E_HMC_RX_TPH_DISABLE;
2198 rctx.tphwdesc_ena = I40E_HMC_RX_TPH_DISABLE;
2199 rctx.tphdata_ena = I40E_HMC_RX_TPH_DISABLE;
2200 rctx.tphhead_ena = I40E_HMC_RX_TPH_DISABLE;
2201 rctx.lrxqthresh = I40E_HMC_RX_LOWRXQ_NOINTR;
2202
2203 /*
2204 * This must be set to 0x1, see Table 8-12 in section 8.3.3.2.2.
2205 */
2206 rctx.prefena = I40E_HMC_RX_PREFENA;
2207
2208 err = i40e_clear_lan_rx_queue_context(hw, itrq->itrq_index);
2209 if (err != I40E_SUCCESS) {
2210 i40e_error(i40e, "failed to clear rx queue %d context: %d",
2211 itrq->itrq_index, err);
2212 return (B_FALSE);
2213 }
2214
2215 err = i40e_set_lan_rx_queue_context(hw, itrq->itrq_index, &rctx);
2216 if (err != I40E_SUCCESS) {
2217 i40e_error(i40e, "failed to set rx queue %d context: %d",
2218 itrq->itrq_index, err);
2219 return (B_FALSE);
2220 }
2221
2222 return (B_TRUE);
2223 }
2224
2225 /*
2226 * Take care of setting up the descriptor rings and actually programming the
2227 * device. See 8.3.3.1.1 for the full list of steps we need to do to enable the
2228 * rx rings.
2229 */
2230 static boolean_t
2231 i40e_setup_rx_rings(i40e_t *i40e)
2232 {
2233 int i;
2234 i40e_hw_t *hw = &i40e->i40e_hw_space;
2235
2236 for (i = 0; i < i40e->i40e_num_trqpairs; i++) {
2237 i40e_trqpair_t *itrq = &i40e->i40e_trqpairs[i];
2238 i40e_rx_data_t *rxd = itrq->itrq_rxdata;
2239 uint32_t reg;
2240
2241 /*
2242 * Step 1. Program all receive ring descriptors.
2243 */
2244 i40e_setup_rx_descs(itrq);
2245
2246 /*
2247 * Step 2. Program the queue's FPM/HMC context.
2248 */
2249 if (i40e_setup_rx_hmc(itrq) == B_FALSE)
2250 return (B_FALSE);
2251
2252 /*
2253 * Step 3. Clear the queue's tail pointer and set it to the end
2254 * of the space.
2255 */
2256 I40E_WRITE_REG(hw, I40E_QRX_TAIL(i), 0);
2257 I40E_WRITE_REG(hw, I40E_QRX_TAIL(i), rxd->rxd_ring_size - 1);
2258
2259 /*
2260 * Step 4. Enable the queue via the QENA_REQ.
2261 */
2262 reg = I40E_READ_REG(hw, I40E_QRX_ENA(i));
2263 VERIFY0(reg & (I40E_QRX_ENA_QENA_REQ_MASK |
2264 I40E_QRX_ENA_QENA_STAT_MASK));
2265 reg |= I40E_QRX_ENA_QENA_REQ_MASK;
2266 I40E_WRITE_REG(hw, I40E_QRX_ENA(i), reg);
2267 }
2268
2269 /*
2270 * Note, we wait for every queue to be enabled before we start checking.
2271 * This will hopefully cause most queues to be enabled at this point.
2272 */
2273 for (i = 0; i < i40e->i40e_num_trqpairs; i++) {
2274 uint32_t j, reg;
2275
2276 /*
2277 * Step 5. Verify that QENA_STAT has been set. It's promised
2278 * that this should occur within about 10 us, but like other
2279 * systems, we give the card a bit more time.
2280 */
2281 for (j = 0; j < I40E_RING_WAIT_NTRIES; j++) {
2282 reg = I40E_READ_REG(hw, I40E_QRX_ENA(i));
2283
2284 if (reg & I40E_QRX_ENA_QENA_STAT_MASK)
2285 break;
2286 i40e_msec_delay(I40E_RING_WAIT_PAUSE);
2287 }
2288
2289 if ((reg & I40E_QRX_ENA_QENA_STAT_MASK) == 0) {
2290 i40e_error(i40e, "failed to enable rx queue %d, timed "
2291 "out.", i);
2292 return (B_FALSE);
2293 }
2294 }
2295
2296 return (B_TRUE);
2297 }
2298
2299 static boolean_t
2300 i40e_setup_tx_hmc(i40e_trqpair_t *itrq)
2301 {
2302 i40e_t *i40e = itrq->itrq_i40e;
2303 i40e_hw_t *hw = &i40e->i40e_hw_space;
2304
2305 struct i40e_hmc_obj_txq tctx;
2306 struct i40e_vsi_context context;
2307 int err;
2308
2309 bzero(&tctx, sizeof (struct i40e_hmc_obj_txq));
2310 tctx.new_context = I40E_HMC_TX_NEW_CONTEXT;
2311 tctx.base = itrq->itrq_desc_area.dmab_dma_address /
2312 I40E_HMC_TX_CTX_UNIT;
2313 tctx.fc_ena = I40E_HMC_TX_FC_DISABLE;
2314 tctx.timesync_ena = I40E_HMC_TX_TS_DISABLE;
2315 tctx.fd_ena = I40E_HMC_TX_FD_DISABLE;
2316 tctx.alt_vlan_ena = I40E_HMC_TX_ALT_VLAN_DISABLE;
2317 tctx.head_wb_ena = I40E_HMC_TX_WB_ENABLE;
2318 tctx.qlen = itrq->itrq_tx_ring_size;
2319 tctx.tphrdesc_ena = I40E_HMC_TX_TPH_DISABLE;
2320 tctx.tphrpacket_ena = I40E_HMC_TX_TPH_DISABLE;
2321 tctx.tphwdesc_ena = I40E_HMC_TX_TPH_DISABLE;
2322 tctx.head_wb_addr = itrq->itrq_desc_area.dmab_dma_address +
2323 sizeof (i40e_tx_desc_t) * itrq->itrq_tx_ring_size;
2324
2325 /*
2326 * This field isn't actually documented, like crc, but it suggests that
2327 * it should be zeroed. We leave both of these here because of that for
2328 * now. We should check with Intel on why these are here even.
2329 */
2330 tctx.crc = 0;
2331 tctx.rdylist_act = 0;
2332
2333 /*
2334 * We're supposed to assign the rdylist field with the value of the
2335 * traffic class index for the first device. We query the VSI parameters
2336 * again to get what the handle is. Note that every queue is always
2337 * assigned to traffic class zero, because we don't actually use them.
2338 */
2339 bzero(&context, sizeof (struct i40e_vsi_context));
2340 context.seid = i40e->i40e_vsi_id;
2341 context.pf_num = hw->pf_id;
2342 err = i40e_aq_get_vsi_params(hw, &context, NULL);
2343 if (err != I40E_SUCCESS) {
2344 i40e_error(i40e, "get VSI params failed with %d", err);
2345 return (B_FALSE);
2346 }
2347 tctx.rdylist = LE_16(context.info.qs_handle[0]);
2348
2349 err = i40e_clear_lan_tx_queue_context(hw, itrq->itrq_index);
2350 if (err != I40E_SUCCESS) {
2351 i40e_error(i40e, "failed to clear tx queue %d context: %d",
2352 itrq->itrq_index, err);
2353 return (B_FALSE);
2354 }
2355
2356 err = i40e_set_lan_tx_queue_context(hw, itrq->itrq_index, &tctx);
2357 if (err != I40E_SUCCESS) {
2358 i40e_error(i40e, "failed to set tx queue %d context: %d",
2359 itrq->itrq_index, err);
2360 return (B_FALSE);
2361 }
2362
2363 return (B_TRUE);
2364 }
2365
2366 /*
2367 * Take care of setting up the descriptor rings and actually programming the
2368 * device. See 8.4.3.1.1 for what we need to do here.
2369 */
2370 static boolean_t
2371 i40e_setup_tx_rings(i40e_t *i40e)
2372 {
2373 int i;
2374 i40e_hw_t *hw = &i40e->i40e_hw_space;
2375
2376 for (i = 0; i < i40e->i40e_num_trqpairs; i++) {
2377 i40e_trqpair_t *itrq = &i40e->i40e_trqpairs[i];
2378 uint32_t reg;
2379
2380 /*
2381 * Step 1. Clear the queue disable flag and verify that the
2382 * index is set correctly.
2383 */
2384 i40e_pre_tx_queue_cfg(hw, i, B_TRUE);
2385
2386 /*
2387 * Step 2. Prepare the queue's FPM/HMC context.
2388 */
2389 if (i40e_setup_tx_hmc(itrq) == B_FALSE)
2390 return (B_FALSE);
2391
2392 /*
2393 * Step 3. Verify that it's clear that this PF owns this queue.
2394 */
2395 reg = I40E_QTX_CTL_PF_QUEUE;
2396 reg |= (hw->pf_id << I40E_QTX_CTL_PF_INDX_SHIFT) &
2397 I40E_QTX_CTL_PF_INDX_MASK;
2398 I40E_WRITE_REG(hw, I40E_QTX_CTL(itrq->itrq_index), reg);
2399 i40e_flush(hw);
2400
2401 /*
2402 * Step 4. Set the QENA_REQ flag.
2403 */
2404 reg = I40E_READ_REG(hw, I40E_QTX_ENA(i));
2405 VERIFY0(reg & (I40E_QTX_ENA_QENA_REQ_MASK |
2406 I40E_QTX_ENA_QENA_STAT_MASK));
2407 reg |= I40E_QTX_ENA_QENA_REQ_MASK;
2408 I40E_WRITE_REG(hw, I40E_QTX_ENA(i), reg);
2409 }
2410
2411 /*
2412 * Note, we wait for every queue to be enabled before we start checking.
2413 * This will hopefully cause most queues to be enabled at this point.
2414 */
2415 for (i = 0; i < i40e->i40e_num_trqpairs; i++) {
2416 uint32_t j, reg;
2417
2418 /*
2419 * Step 5. Verify that QENA_STAT has been set. It's promised
2420 * that this should occur within about 10 us, but like BSD,
2421 * we'll try for up to 100 ms for this queue.
2422 */
2423 for (j = 0; j < I40E_RING_WAIT_NTRIES; j++) {
2424 reg = I40E_READ_REG(hw, I40E_QTX_ENA(i));
2425
2426 if (reg & I40E_QTX_ENA_QENA_STAT_MASK)
2427 break;
2428 i40e_msec_delay(I40E_RING_WAIT_PAUSE);
2429 }
2430
2431 if ((reg & I40E_QTX_ENA_QENA_STAT_MASK) == 0) {
2432 i40e_error(i40e, "failed to enable tx queue %d, timed "
2433 "out", i);
2434 return (B_FALSE);
2435 }
2436 }
2437
2438 return (B_TRUE);
2439 }
2440
2441 void
2442 i40e_stop(i40e_t *i40e, boolean_t free_allocations)
2443 {
2444 int i;
2445
2446 ASSERT(MUTEX_HELD(&i40e->i40e_general_lock));
2447
2448 /*
2449 * Shutdown and drain the tx and rx pipeline. We do this using the
2450 * following steps.
2451 *
2452 * 1) Shutdown interrupts to all the queues (trying to keep the admin
2453 * queue alive).
2454 *
2455 * 2) Remove all of the interrupt tx and rx causes by setting the
2456 * interrupt linked lists to zero.
2457 *
2458 * 2) Shutdown the tx and rx rings. Because i40e_shutdown_rings() should
2459 * wait for all the queues to be disabled, once we reach that point
2460 * it should be safe to free associated data.
2461 *
2462 * 4) Wait 50ms after all that is done. This ensures that the rings are
2463 * ready for programming again and we don't have to think about this
2464 * in other parts of the driver.
2465 *
2466 * 5) Disable remaining chip interrupts, (admin queue, etc.)
2467 *
2468 * 6) Verify that FM is happy with all the register accesses we
2469 * performed.
2470 */
2471 i40e_intr_io_disable_all(i40e);
2472 i40e_intr_io_clear_cause(i40e);
2473
2474 if (i40e_shutdown_rings(i40e) == B_FALSE) {
2475 ddi_fm_service_impact(i40e->i40e_dip, DDI_SERVICE_LOST);
2476 }
2477
2478 delay(50 * drv_usectohz(1000));
2479
2480 i40e_intr_chip_fini(i40e);
2481
2482 for (i = 0; i < i40e->i40e_num_trqpairs; i++) {
2483 mutex_enter(&i40e->i40e_trqpairs[i].itrq_rx_lock);
2484 mutex_enter(&i40e->i40e_trqpairs[i].itrq_tx_lock);
2485 }
2486
2487 /*
2488 * We should consider refactoring this to be part of the ring start /
2489 * stop routines at some point.
2490 */
2491 for (i = 0; i < i40e->i40e_num_trqpairs; i++) {
2492 i40e_stats_trqpair_fini(&i40e->i40e_trqpairs[i]);
2493 }
2494
2495 if (i40e_check_acc_handle(i40e->i40e_osdep_space.ios_cfg_handle) !=
2496 DDI_FM_OK) {
2497 ddi_fm_service_impact(i40e->i40e_dip, DDI_SERVICE_LOST);
2498 }
2499
2500 for (i = 0; i < i40e->i40e_num_trqpairs; i++) {
2501 i40e_tx_cleanup_ring(&i40e->i40e_trqpairs[i]);
2502 }
2503
2504 for (i = 0; i < i40e->i40e_num_trqpairs; i++) {
2505 mutex_exit(&i40e->i40e_trqpairs[i].itrq_rx_lock);
2506 mutex_exit(&i40e->i40e_trqpairs[i].itrq_tx_lock);
2507 }
2508
2509 i40e_stat_vsi_fini(i40e);
2510
2511 i40e->i40e_link_speed = 0;
2512 i40e->i40e_link_duplex = 0;
2513 i40e_link_state_set(i40e, LINK_STATE_UNKNOWN);
2514
2515 if (free_allocations) {
2516 i40e_free_ring_mem(i40e, B_FALSE);
2517 }
2518 }
2519
2520 boolean_t
2521 i40e_start(i40e_t *i40e, boolean_t alloc)
2522 {
2523 i40e_hw_t *hw = &i40e->i40e_hw_space;
2524 boolean_t rc = B_TRUE;
2525 int i, err;
2526
2527 ASSERT(MUTEX_HELD(&i40e->i40e_general_lock));
2528
2529 if (alloc) {
2530 if (i40e_alloc_ring_mem(i40e) == B_FALSE) {
2531 i40e_error(i40e,
2532 "Failed to allocate ring memory");
2533 return (B_FALSE);
2534 }
2535 }
2536
2537 /*
2538 * This should get refactored to be part of ring start and stop at
2539 * some point, along with most of the logic here.
2540 */
2541 for (i = 0; i < i40e->i40e_num_trqpairs; i++) {
2542 if (i40e_stats_trqpair_init(&i40e->i40e_trqpairs[i]) ==
2543 B_FALSE) {
2544 int j;
2545
2546 for (j = 0; j < i; j++) {
2547 i40e_trqpair_t *itrq = &i40e->i40e_trqpairs[j];
2548 i40e_stats_trqpair_fini(itrq);
2549 }
2550 return (B_FALSE);
2551 }
2552 }
2553
2554 if (!i40e_chip_start(i40e)) {
2555 i40e_fm_ereport(i40e, DDI_FM_DEVICE_INVAL_STATE);
2556 rc = B_FALSE;
2557 goto done;
2558 }
2559
2560 if (i40e_setup_rx_rings(i40e) == B_FALSE) {
2561 rc = B_FALSE;
2562 goto done;
2563 }
2564
2565 if (i40e_setup_tx_rings(i40e) == B_FALSE) {
2566 rc = B_FALSE;
2567 goto done;
2568 }
2569
2570 /*
2571 * Enable broadcast traffic; however, do not enable multicast traffic.
2572 * That's handle exclusively through MAC's mc_multicst routines.
2573 */
2574 err = i40e_aq_set_vsi_broadcast(hw, i40e->i40e_vsi_id, B_TRUE, NULL);
2575 if (err != I40E_SUCCESS) {
2576 i40e_error(i40e, "failed to set default VSI: %d", err);
2577 rc = B_FALSE;
2578 goto done;
2579 }
2580
2581 err = i40e_aq_set_mac_config(hw, i40e->i40e_frame_max, B_TRUE, 0, NULL);
2582 if (err != I40E_SUCCESS) {
2583 i40e_error(i40e, "failed to set MAC config: %d", err);
2584 rc = B_FALSE;
2585 goto done;
2586 }
2587
2588 /*
2589 * Finally, make sure that we're happy from an FM perspective.
2590 */
2591 if (i40e_check_acc_handle(i40e->i40e_osdep_space.ios_reg_handle) !=
2592 DDI_FM_OK) {
2593 rc = B_FALSE;
2594 goto done;
2595 }
2596
2597 /* Clear state bits prior to final interrupt enabling. */
2598 atomic_and_32(&i40e->i40e_state,
2599 ~(I40E_ERROR | I40E_STALL | I40E_OVERTEMP));
2600
2601 i40e_intr_io_enable_all(i40e);
2602
2603 done:
2604 if (rc == B_FALSE) {
2605 i40e_stop(i40e, B_FALSE);
2606 if (alloc == B_TRUE) {
2607 i40e_free_ring_mem(i40e, B_TRUE);
2608 }
2609 ddi_fm_service_impact(i40e->i40e_dip, DDI_SERVICE_LOST);
2610 }
2611
2612 return (rc);
2613 }
2614
2615 /*
2616 * We may have loaned up descriptors to the stack. As such, if we still have
2617 * them outstanding, then we will not continue with detach.
2618 */
2619 static boolean_t
2620 i40e_drain_rx(i40e_t *i40e)
2621 {
2622 mutex_enter(&i40e->i40e_rx_pending_lock);
2623 while (i40e->i40e_rx_pending > 0) {
2624 if (cv_reltimedwait(&i40e->i40e_rx_pending_cv,
2625 &i40e->i40e_rx_pending_lock,
2626 drv_usectohz(I40E_DRAIN_RX_WAIT), TR_CLOCK_TICK) == -1) {
2627 mutex_exit(&i40e->i40e_rx_pending_lock);
2628 return (B_FALSE);
2629 }
2630 }
2631 mutex_exit(&i40e->i40e_rx_pending_lock);
2632
2633 return (B_TRUE);
2634 }
2635
2636 static int
2637 i40e_attach(dev_info_t *devinfo, ddi_attach_cmd_t cmd)
2638 {
2639 i40e_t *i40e;
2640 struct i40e_osdep *osdep;
2641 i40e_hw_t *hw;
2642 int instance;
2643
2644 if (cmd != DDI_ATTACH)
2645 return (DDI_FAILURE);
2646
2647 instance = ddi_get_instance(devinfo);
2648 i40e = kmem_zalloc(sizeof (i40e_t), KM_SLEEP);
2649
2650 i40e->i40e_aqbuf = kmem_zalloc(I40E_ADMINQ_BUFSZ, KM_SLEEP);
2651 i40e->i40e_instance = instance;
2652 i40e->i40e_dip = devinfo;
2653
2654 hw = &i40e->i40e_hw_space;
2655 osdep = &i40e->i40e_osdep_space;
2656 hw->back = osdep;
2657 osdep->ios_i40e = i40e;
2658
2659 ddi_set_driver_private(devinfo, i40e);
2660
2661 i40e_fm_init(i40e);
2662 i40e->i40e_attach_progress |= I40E_ATTACH_FM_INIT;
2663
2664 if (pci_config_setup(devinfo, &osdep->ios_cfg_handle) != DDI_SUCCESS) {
2665 i40e_error(i40e, "Failed to map PCI configurations.");
2666 goto attach_fail;
2667 }
2668 i40e->i40e_attach_progress |= I40E_ATTACH_PCI_CONFIG;
2669
2670 if (!i40e_identify_hardware(i40e)) {
2671 i40e_error(i40e, "Failed to identify hardware");
2672 goto attach_fail;
2673 }
2674
2675 if (!i40e_regs_map(i40e)) {
2676 i40e_error(i40e, "Failed to map device registers.");
2677 goto attach_fail;
2678 }
2679 i40e->i40e_attach_progress |= I40E_ATTACH_REGS_MAP;
2680
2681 i40e_init_properties(i40e);
2682 i40e->i40e_attach_progress |= I40E_ATTACH_PROPS;
2683
2684 if (!i40e_common_code_init(i40e, hw))
2685 goto attach_fail;
2686 i40e->i40e_attach_progress |= I40E_ATTACH_COMMON_CODE;
2687
2688 /*
2689 * When we participate in IRM, we should make sure that we register
2690 * ourselves with it before callbacks.
2691 */
2692 if (!i40e_alloc_intrs(i40e, devinfo)) {
2693 i40e_error(i40e, "Failed to allocate interrupts.");
2694 goto attach_fail;
2695 }
2696 i40e->i40e_attach_progress |= I40E_ATTACH_ALLOC_INTR;
2697
2698 if (!i40e_alloc_trqpairs(i40e)) {
2699 i40e_error(i40e,
2700 "Failed to allocate receive & transmit rings.");
2701 goto attach_fail;
2702 }
2703 i40e->i40e_attach_progress |= I40E_ATTACH_ALLOC_RINGSLOCKS;
2704
2705 if (!i40e_map_intrs_to_vectors(i40e)) {
2706 i40e_error(i40e, "Failed to map interrupts to vectors.");
2707 goto attach_fail;
2708 }
2709
2710 if (!i40e_add_intr_handlers(i40e)) {
2711 i40e_error(i40e, "Failed to add the interrupt handlers.");
2712 goto attach_fail;
2713 }
2714 i40e->i40e_attach_progress |= I40E_ATTACH_ADD_INTR;
2715
2716 if (!i40e_final_init(i40e)) {
2717 i40e_error(i40e, "Final initialization failed.");
2718 goto attach_fail;
2719 }
2720 i40e->i40e_attach_progress |= I40E_ATTACH_INIT;
2721
2722 if (i40e_check_acc_handle(i40e->i40e_osdep_space.ios_cfg_handle) !=
2723 DDI_FM_OK) {
2724 ddi_fm_service_impact(i40e->i40e_dip, DDI_SERVICE_LOST);
2725 goto attach_fail;
2726 }
2727
2728 if (!i40e_stats_init(i40e)) {
2729 i40e_error(i40e, "Stats initialization failed.");
2730 goto attach_fail;
2731 }
2732 i40e->i40e_attach_progress |= I40E_ATTACH_STATS;
2733
2734 if (!i40e_register_mac(i40e)) {
2735 i40e_error(i40e, "Failed to register to MAC/GLDv3");
2736 goto attach_fail;
2737 }
2738 i40e->i40e_attach_progress |= I40E_ATTACH_MAC;
2739
2740 i40e->i40e_periodic_id = ddi_periodic_add(i40e_timer, i40e,
2741 I40E_CYCLIC_PERIOD, DDI_IPL_0);
2742 if (i40e->i40e_periodic_id == 0) {
2743 i40e_error(i40e, "Failed to add the link-check timer");
2744 goto attach_fail;
2745 }
2746 i40e->i40e_attach_progress |= I40E_ATTACH_LINK_TIMER;
2747
2748 if (!i40e_enable_interrupts(i40e)) {
2749 i40e_error(i40e, "Failed to enable DDI interrupts");
2750 goto attach_fail;
2751 }
2752 i40e->i40e_attach_progress |= I40E_ATTACH_ENABLE_INTR;
2753
2754 atomic_or_32(&i40e->i40e_state, I40E_INITIALIZED);
2755
2756 mutex_enter(&i40e_glock);
2757 list_insert_tail(&i40e_glist, i40e);
2758 mutex_exit(&i40e_glock);
2759
2760 return (DDI_SUCCESS);
2761
2762 attach_fail:
2763 i40e_unconfigure(devinfo, i40e);
2764 return (DDI_FAILURE);
2765 }
2766
2767 static int
2768 i40e_detach(dev_info_t *devinfo, ddi_detach_cmd_t cmd)
2769 {
2770 i40e_t *i40e;
2771
2772 if (cmd != DDI_DETACH)
2773 return (DDI_FAILURE);
2774
2775 i40e = (i40e_t *)ddi_get_driver_private(devinfo);
2776 if (i40e == NULL) {
2777 i40e_log(NULL, "i40e_detach() called with no i40e pointer!");
2778 return (DDI_FAILURE);
2779 }
2780
2781 if (i40e_drain_rx(i40e) == B_FALSE) {
2782 i40e_log(i40e, "timed out draining DMA resources, %d buffers "
2783 "remain", i40e->i40e_rx_pending);
2784 return (DDI_FAILURE);
2785 }
2786
2787 mutex_enter(&i40e_glock);
2788 list_remove(&i40e_glist, i40e);
2789 mutex_exit(&i40e_glock);
2790
2791 i40e_unconfigure(devinfo, i40e);
2792
2793 return (DDI_SUCCESS);
2794 }
2795
2796 static struct cb_ops i40e_cb_ops = {
2797 nulldev, /* cb_open */
2798 nulldev, /* cb_close */
2799 nodev, /* cb_strategy */
2800 nodev, /* cb_print */
2801 nodev, /* cb_dump */
2802 nodev, /* cb_read */
2803 nodev, /* cb_write */
2804 nodev, /* cb_ioctl */
2805 nodev, /* cb_devmap */
2806 nodev, /* cb_mmap */
2807 nodev, /* cb_segmap */
2808 nochpoll, /* cb_chpoll */
2809 ddi_prop_op, /* cb_prop_op */
2810 NULL, /* cb_stream */
2811 D_MP | D_HOTPLUG, /* cb_flag */
2812 CB_REV, /* cb_rev */
2813 nodev, /* cb_aread */
2814 nodev /* cb_awrite */
2815 };
2816
2817 static struct dev_ops i40e_dev_ops = {
2818 DEVO_REV, /* devo_rev */
2819 0, /* devo_refcnt */
2820 NULL, /* devo_getinfo */
2821 nulldev, /* devo_identify */
2822 nulldev, /* devo_probe */
2823 i40e_attach, /* devo_attach */
2824 i40e_detach, /* devo_detach */
2825 nodev, /* devo_reset */
2826 &i40e_cb_ops, /* devo_cb_ops */
2827 NULL, /* devo_bus_ops */
2828 ddi_power, /* devo_power */
2829 ddi_quiesce_not_supported /* devo_quiesce */
2830 };
2831
2832 static struct modldrv i40e_modldrv = {
2833 &mod_driverops,
2834 i40e_ident,
2835 &i40e_dev_ops
2836 };
2837
2838 static struct modlinkage i40e_modlinkage = {
2839 MODREV_1,
2840 { &i40e_modldrv, NULL }
2841 };
2842
2843 /*
2844 * Module Initialization Functions.
2845 */
2846 int
2847 _init(void)
2848 {
2849 int status;
2850
2851 list_create(&i40e_glist, sizeof (i40e_t), offsetof(i40e_t, i40e_glink));
2852 list_create(&i40e_dlist, sizeof (i40e_device_t),
2853 offsetof(i40e_device_t, id_link));
2854 mutex_init(&i40e_glock, NULL, MUTEX_DRIVER, NULL);
2855 mac_init_ops(&i40e_dev_ops, I40E_MODULE_NAME);
2856
2857 status = mod_install(&i40e_modlinkage);
2858 if (status != DDI_SUCCESS) {
2859 mac_fini_ops(&i40e_dev_ops);
2860 mutex_destroy(&i40e_glock);
2861 list_destroy(&i40e_dlist);
2862 list_destroy(&i40e_glist);
2863 }
2864
2865 return (status);
2866 }
2867
2868 int
2869 _info(struct modinfo *modinfop)
2870 {
2871 return (mod_info(&i40e_modlinkage, modinfop));
2872 }
2873
2874 int
2875 _fini(void)
2876 {
2877 int status;
2878
2879 status = mod_remove(&i40e_modlinkage);
2880 if (status == DDI_SUCCESS) {
2881 mac_fini_ops(&i40e_dev_ops);
2882 mutex_destroy(&i40e_glock);
2883 list_destroy(&i40e_dlist);
2884 list_destroy(&i40e_glist);
2885 }
2886
2887 return (status);
2888 }
--- EOF ---