| blob | b6d27762c6f8cc35ff698ae96005100d55748206 |
1 // SPDX-License-Identifier: GPL-2.0-only
2 /*
3 * Copyright 2010
4 * by Konrad Rzeszutek Wilk <konrad.wilk@oracle.com>
5 *
6 * This code provides a IOMMU for Xen PV guests with PCI passthrough.
7 *
8 * PV guests under Xen are running in an non-contiguous memory architecture.
9 *
10 * When PCI pass-through is utilized, this necessitates an IOMMU for
11 * translating bus (DMA) to virtual and vice-versa and also providing a
12 * mechanism to have contiguous pages for device drivers operations (say DMA
13 * operations).
14 *
15 * Specifically, under Xen the Linux idea of pages is an illusion. It
16 * assumes that pages start at zero and go up to the available memory. To
17 * help with that, the Linux Xen MMU provides a lookup mechanism to
18 * translate the page frame numbers (PFN) to machine frame numbers (MFN)
19 * and vice-versa. The MFN are the "real" frame numbers. Furthermore
20 * memory is not contiguous. Xen hypervisor stitches memory for guests
21 * from different pools, which means there is no guarantee that PFN==MFN
22 * and PFN+1==MFN+1. Lastly with Xen 4.0, pages (in debug mode) are
23 * allocated in descending order (high to low), meaning the guest might
24 * never get any MFN's under the 4GB mark.
25 */
29 #include <linux/memblock.h>
30 #include <linux/dma-direct.h>
31 #include <linux/dma-noncoherent.h>
32 #include <linux/export.h>
33 #include <xen/swiotlb-xen.h>
34 #include <xen/page.h>
35 #include <xen/xen-ops.h>
36 #include <xen/hvc-console.h>
38 #include <asm/dma-mapping.h>
39 #include <asm/xen/page-coherent.h>
41 #include <trace/events/swiotlb.h>
42 #define MAX_DMA_BITS 32
43 /*
44 * Used to do a quick range check in swiotlb_tbl_unmap_single and
45 * swiotlb_tbl_sync_single_*, to see if the memory was in fact allocated by this
46 * API.
47 */
51 /*
52 * Quick lookup value of the bus address of the IOTLB.
53 */
57 /*
58 * Both of these functions should avoid XEN_PFN_PHYS because phys_addr_t
59 * can be 32bit when dma_addr_t is 64bit leading to a loss in
60 * information if the shift is done before casting to 64bit.
61 */
63 {
70 }
73 {
81 }
84 {
86 }
89 {
100 }
103 {
108 /* If the address is outside our domain, it CAN
109 * have the same virtual address as another address
110 * in our domain. Therefore _only_ check address within our domain.
111 */
115 }
117 }
119 static int
121 {
124 dma_addr_t dma_handle;
145 }
147 {
155 }
159 XEN_SWIOTLB_ENOMEM,
160 XEN_SWIOTLB_EFIXUP
161 };
164 {
170 "You either: don't have the permissions, do not have"\
171 " enough free memory under 4GB, or the hypervisor memory"\
175 }
177 }
179 {
186 retry:
190 /*
191 * IO TLB memory already allocated. Just use it.
192 */
196 }
198 /*
199 * Get IO TLB memory from any location.
200 */
203 PAGE_SIZE);
208 #define SLABS_PER_PAGE (1 << (PAGE_SHIFT - IO_TLB_SHIFT))
209 #define IO_TLB_MIN_SLABS ((1<<20) >> IO_TLB_SHIFT)
214 order--;
215 }
221 }
222 }
226 }
227 /*
228 * And replace that memory with pages under 4GB.
229 */
231 bytes,
232 xen_io_tlb_nslabs);
240 }
243 }
247 verbose))
253 end:
259 error:
266 }
270 else
273 }
279 {
283 phys_addr_t phys;
284 dma_addr_t dev_addr;
286 /*
287 * Ignore region specifiers - the kernel's ideas of
288 * pseudo-phys memory layout has nothing to do with the
289 * machine physical layout. We can't allocate highmem
290 * because we can't return a pointer to it.
291 */
294 /* Convert the size to actually allocated. */
297 /* On ARM this function returns an ioremap'ped virtual address for
298 * which virt_to_phys doesn't return the corresponding physical
299 * address. In fact on ARM virt_to_phys only works for kernel direct
300 * mapped RAM memory. Also see comment below.
301 */
310 /* At this point dma_handle is the physical address, next we are
311 * going to set it to the machine address.
312 * Do not use virt_to_phys(ret) because on ARM it doesn't correspond
313 * to *dma_handle. */
324 }
326 }
329 }
331 static void
334 {
336 phys_addr_t phys;
342 /* do not use virt_to_phys because on ARM it doesn't return you the
343 * physical address */
346 /* Convert the size to actually allocated. */
355 }
357 /*
358 * Map a single buffer of the indicated size for DMA in streaming mode. The
359 * physical address to use is returned.
360 *
361 * Once the device is given the dma address, the device owns this memory until
362 * either xen_swiotlb_unmap_page or xen_swiotlb_dma_sync_single is performed.
363 */
368 {
373 /*
374 * If the address happens to be in the device's DMA window,
375 * we can safely return the device addr and not worry about bounce
376 * buffering it.
377 */
384 /*
385 * Oh well, have to allocate and map a bounce buffer.
386 */
397 /*
398 * Ensure that the address returned is DMA'ble
399 */
404 }
406 done:
410 }
412 /*
413 * Unmap a single streaming mode DMA translation. The dma_addr and size must
414 * match what was provided for in a previous xen_swiotlb_map_page call. All
415 * other usages are undefined.
416 *
417 * After this call, reads by the cpu to the buffer are guaranteed to see
418 * whatever the device wrote there.
419 */
422 {
430 /* NOTE: We use dev_addr here, not paddr! */
433 }
435 static void
438 {
446 }
448 static void
451 {
459 }
461 /*
462 * Unmap a set of streaming mode DMA translations. Again, cpu read rules
463 * concerning calls here are the same as for swiotlb_unmap_page() above.
464 */
465 static void
468 {
478 }
480 static int
483 {
495 }
498 out_unmap:
502 }
504 static void
507 {
514 }
515 }
517 static void
520 {
527 }
528 }
530 /*
531 * Return whether the given device DMA address mask can be supported
532 * properly. For example, if your device can only drive the low 24-bits
533 * during bus mastering, then you would pass 0x00ffffff as the mask to
534 * this function.
535 */
536 static int
538 {
540 }
556 };