| blob | b31ee79c60b5e567f84f561cfb63849960648340 |
1 /*
2 * IGD device quirks
3 *
4 * Copyright Red Hat, Inc. 2016
5 *
6 * Authors:
7 * Alex Williamson <alex.williamson@redhat.com>
8 *
9 * This work is licensed under the terms of the GNU GPL, version 2. See
10 * the COPYING file in the top-level directory.
11 */
22 /*
23 * Intel IGD support
24 *
25 * Obviously IGD is not a discrete device, this is evidenced not only by it
26 * being integrated into the CPU, but by the various chipset and BIOS
27 * dependencies that it brings along with it. Intel is trying to move away
28 * from this and Broadwell and newer devices can run in what Intel calls
29 * "Universal Pass-Through" mode, or UPT. Theoretically in UPT mode, nothing
30 * more is required beyond assigning the IGD device to a VM. There are
31 * however support limitations to this mode. It only supports IGD as a
32 * secondary graphics device in the VM and it doesn't officially support any
33 * physical outputs.
34 *
35 * The code here attempts to enable what we'll call legacy mode assignment,
36 * IGD retains most of the capabilities we expect for it to have on bare
37 * metal. To enable this mode, the IGD device must be assigned to the VM
38 * at PCI address 00:02.0, it must have a ROM, it very likely needs VGA
39 * support, we must have VM BIOS support for reserving and populating some
40 * of the required tables, and we need to tweak the chipset with revisions
41 * and IDs and an LPC/ISA bridge device. The intention is to make all of
42 * this happen automatically by installing the device at the correct VM PCI
43 * bus address. If any of the conditions are not met, we cross our fingers
44 * and hope the user knows better.
45 *
46 * NB - It is possible to enable physical outputs in UPT mode by supplying
47 * an OpRegion table. We don't do this by default because the guest driver
48 * behaves differently if an OpRegion is provided and no monitor is attached
49 * vs no OpRegion and a monitor being attached or not. Effectively, if a
50 * headless setup is desired, the OpRegion gets in the way of that.
51 */
53 /*
54 * This presumes the device is already known to be an Intel VGA device, so we
55 * take liberties in which device ID bits match which generation. This should
56 * not be taken as an indication that all the devices are supported, or even
57 * supportable, some of them don't even support VT-d.
58 * See linux:include/drm/i915_pciids.h for IDs.
59 */
61 {
64 }
67 /* Old, untested, unavailable, unknown */
77 /* SandyBridge, IvyBridge, ValleyView, Haswell */
85 /* BroadWell, CherryView, SkyLake, KabyLake */
91 }
94 }
106 /*
107 * The rather short list of registers that we copy from the host devices.
108 * The LPC/ISA bridge values are definitely needed to support the vBIOS, the
109 * host bridge values may or may not be needed depending on the guest OS.
110 * Since we're only munging revision and subsystem values on the host bridge,
111 * we don't require our own device. The LPC/ISA bridge needs to be our very
112 * own though.
113 */
123 };
131 };
136 {
145 }
146 }
149 }
151 /*
152 * Stuff a few values into the host bridge.
153 */
156 {
167 }
173 }
176 }
178 /*
179 * IGD LPC/ISA bridge support code. The vBIOS needs this, but we can't write
180 * arbitrary values into just any bridge, so we must create our own. We try
181 * to handle if the user has created it for us, which they might want to do
182 * to enable multifunction so we don't occupy the whole PCI slot.
183 */
185 {
188 }
189 }
192 {
201 }
209 { },
210 },
211 };
214 {
216 }
222 {
231 }
237 }
240 }
242 /*
243 * IGD Gen8 and newer support up to 8MB for the GTT and use a 64bit PTE
244 * entry, older IGDs use 2MB and 32bit. Each PTE maps a 4k page. Therefore
245 * we either have 2M/4k * 4 = 2k or 8M/4k * 8 = 16k as the maximum iobar index
246 * for programming the GTT.
247 *
248 * See linux:include/drm/i915_drm.h for shift and mask values.
249 */
251 {
259 }
264 }
266 /*
267 * The IGD ROM will make use of stolen memory (GGMS) for support of VESA modes.
268 * Somehow the host stolen memory range is used for this, but how the ROM gets
269 * it is a mystery, perhaps it's hardcoded into the ROM. Thankfully though, it
270 * reprograms the GTT through the IOBAR where we can trap it and transpose the
271 * programming to the VM allocated buffer. That buffer gets reserved by the VM
272 * firmware via the fw_cfg entry added below. Here we're just monitoring the
273 * IOBAR address and data registers to detect a write sequence targeting the
274 * GTTADR. This code is developed by observed behavior and doesn't have a
275 * direct spec reference, unfortunately.
276 */
279 {
286 }
290 {
296 /*
297 * Programming the GGMS starts at index 0x1 and uses every 4th index (ie.
298 * 0x1, 0x5, 0x9, 0xd,...). For pre-Gen8 each 4-byte write is a whole PTE
299 * entry, with 0th bit enable set. For Gen8 and up, PTEs are 64bit, so
300 * entries 0x5 & 0xd are the high dword, in our case zero. Each PTE points
301 * to a 4k page, which we translate to a page from the VM allocated region,
302 * pointed to by the BDSM register. If this is not set, we fail.
303 *
304 * We trap writes to the full configured GTT size, but we typically only
305 * see the vBIOS writing up to (nearly) the 1MB barrier. In fact it often
306 * seems to miss the last entry for an even 1MB GTT. Doing a gratuitous
307 * write of that last entry does work, but is hopefully unnecessary since
308 * we clear the previous GTT on initialization.
309 */
318 }
323 }
327 }
332 }
338 };
342 {
349 }
353 {
360 }
366 };
369 {
381 /*
382 * This must be an Intel VGA device at address 00:02.0 for us to even
383 * consider enabling legacy mode. The vBIOS has dependencies on the
384 * PCI bus address.
385 */
391 }
393 /*
394 * We need to create an LPC/ISA bridge at PCI bus address 00:1f.0 that we
395 * can stuff host values into, so if there's already one there and it's not
396 * one we can hack on, legacy mode is no-go. Sorry Q35.
397 */
405 }
407 /*
408 * IGD is not a standard, they like to change their specs often. We
409 * only attempt to support back to SandBridge and we hope that newer
410 * devices maintain compatibility with generation 8.
411 */
417 }
419 /*
420 * Most of what we're doing here is to enable the ROM to run, so if
421 * there's no ROM, there's no point in setting up this quirk.
422 * NB. We only seem to get BIOS ROMs, so a UEFI VM would need CSM support.
423 */
430 }
432 /*
433 * Ignore the hotplug corner case, mark the ROM failed, we can't
434 * create the devices we need for legacy mode in the hotplug scenario.
435 */
441 }
443 /*
444 * Check whether we have all the vfio device specific regions to
445 * support legacy mode (added in Linux v4.6). If not, bail.
446 */
454 }
463 }
472 }
476 /*
477 * If IGD VGA Disable is clear (expected) and VGA is not already enabled,
478 * try to enable it. Probably shouldn't be using legacy mode without VGA,
479 * but also no point in us enabling VGA if disabled in hardware.
480 */
486 }
488 /* Create our LPC/ISA bridge */
494 }
496 /* Stuff some host values into the VM PCI host bridge */
502 }
504 /* Setup OpRegion access */
510 }
512 /* Setup our quirk to munge GTT addresses to the VM allocated buffer */
532 /* Determine the size of stolen memory needed for GTT */
536 }
538 /*
539 * Assume we have no GMS memory, but allow it to be overridden by device
540 * option (experimental). The spec doesn't actually allow zero GMS when
541 * when IVD (IGD VGA Disable) is clear, but the claim is that it's unused,
542 * so let's not waste VM memory for it.
543 */
553 }
554 }
556 /*
557 * Request reserved memory for stolen memory via fw_cfg. VM firmware
558 * must allocate a 1MB aligned reserved memory region below 4GB with
559 * the requested size (in bytes) for use by the Intel PCI class VGA
560 * device at VM address 00:02.0. The base address of this reserved
561 * memory region must be written to the device BDSM register at PCI
562 * config offset 0x5C.
563 */
569 /* GMCH is read-only, emulated */
574 /* BDSM is read-write, emulated. The BIOS needs to be able to write it */
579 /*
580 * This IOBAR gives us access to GTTADR, which allows us to write to
581 * the GTT itself. So let's go ahead and write zero to all the GTT
582 * entries to avoid spurious DMA faults. Be sure I/O access is enabled
583 * before talking to the device.
584 */
589 }
597 }
602 }
608 }
612 out:
617 }