kfd_chardev.c 89 KB

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  1. // SPDX-License-Identifier: GPL-2.0 OR MIT
  2. /*
  3. * Copyright 2014-2022 Advanced Micro Devices, Inc.
  4. *
  5. * Permission is hereby granted, free of charge, to any person obtaining a
  6. * copy of this software and associated documentation files (the "Software"),
  7. * to deal in the Software without restriction, including without limitation
  8. * the rights to use, copy, modify, merge, publish, distribute, sublicense,
  9. * and/or sell copies of the Software, and to permit persons to whom the
  10. * Software is furnished to do so, subject to the following conditions:
  11. *
  12. * The above copyright notice and this permission notice shall be included in
  13. * all copies or substantial portions of the Software.
  14. *
  15. * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
  16. * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
  17. * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
  18. * THE COPYRIGHT HOLDER(S) OR AUTHOR(S) BE LIABLE FOR ANY CLAIM, DAMAGES OR
  19. * OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE,
  20. * ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR
  21. * OTHER DEALINGS IN THE SOFTWARE.
  22. */
  23. #include <linux/device.h>
  24. #include <linux/err.h>
  25. #include <linux/fs.h>
  26. #include <linux/file.h>
  27. #include <linux/sched.h>
  28. #include <linux/slab.h>
  29. #include <linux/uaccess.h>
  30. #include <linux/compat.h>
  31. #include <uapi/linux/kfd_ioctl.h>
  32. #include <linux/time.h>
  33. #include <linux/mm.h>
  34. #include <linux/mman.h>
  35. #include <linux/ptrace.h>
  36. #include <linux/dma-buf.h>
  37. #include <linux/processor.h>
  38. #include "kfd_priv.h"
  39. #include "kfd_device_queue_manager.h"
  40. #include "kfd_svm.h"
  41. #include "amdgpu_amdkfd.h"
  42. #include "kfd_smi_events.h"
  43. #include "amdgpu_dma_buf.h"
  44. #include "kfd_debug.h"
  45. static long kfd_ioctl(struct file *, unsigned int, unsigned long);
  46. static int kfd_open(struct inode *, struct file *);
  47. static int kfd_release(struct inode *, struct file *);
  48. static int kfd_mmap(struct file *, struct vm_area_struct *);
  49. static const char kfd_dev_name[] = "kfd";
  50. static const struct file_operations kfd_fops = {
  51. .owner = THIS_MODULE,
  52. .unlocked_ioctl = kfd_ioctl,
  53. .compat_ioctl = compat_ptr_ioctl,
  54. .open = kfd_open,
  55. .release = kfd_release,
  56. .mmap = kfd_mmap,
  57. };
  58. static int kfd_char_dev_major = -1;
  59. struct device *kfd_device;
  60. static const struct class kfd_class = {
  61. .name = kfd_dev_name,
  62. };
  63. static inline struct kfd_process_device *kfd_lock_pdd_by_id(struct kfd_process *p, __u32 gpu_id)
  64. {
  65. struct kfd_process_device *pdd;
  66. mutex_lock(&p->mutex);
  67. pdd = kfd_process_device_data_by_id(p, gpu_id);
  68. if (pdd)
  69. return pdd;
  70. mutex_unlock(&p->mutex);
  71. return NULL;
  72. }
  73. static inline void kfd_unlock_pdd(struct kfd_process_device *pdd)
  74. {
  75. mutex_unlock(&pdd->process->mutex);
  76. }
  77. int kfd_chardev_init(void)
  78. {
  79. int err = 0;
  80. kfd_char_dev_major = register_chrdev(0, kfd_dev_name, &kfd_fops);
  81. err = kfd_char_dev_major;
  82. if (err < 0)
  83. goto err_register_chrdev;
  84. err = class_register(&kfd_class);
  85. if (err)
  86. goto err_class_create;
  87. kfd_device = device_create(&kfd_class, NULL,
  88. MKDEV(kfd_char_dev_major, 0),
  89. NULL, kfd_dev_name);
  90. err = PTR_ERR(kfd_device);
  91. if (IS_ERR(kfd_device))
  92. goto err_device_create;
  93. return 0;
  94. err_device_create:
  95. class_unregister(&kfd_class);
  96. err_class_create:
  97. unregister_chrdev(kfd_char_dev_major, kfd_dev_name);
  98. err_register_chrdev:
  99. return err;
  100. }
  101. void kfd_chardev_exit(void)
  102. {
  103. device_destroy(&kfd_class, MKDEV(kfd_char_dev_major, 0));
  104. class_unregister(&kfd_class);
  105. unregister_chrdev(kfd_char_dev_major, kfd_dev_name);
  106. kfd_device = NULL;
  107. }
  108. static int kfd_open(struct inode *inode, struct file *filep)
  109. {
  110. struct kfd_process *process;
  111. bool is_32bit_user_mode;
  112. if (iminor(inode) != 0)
  113. return -ENODEV;
  114. is_32bit_user_mode = in_compat_syscall();
  115. if (is_32bit_user_mode) {
  116. dev_warn(kfd_device,
  117. "Process %d (32-bit) failed to open /dev/kfd\n"
  118. "32-bit processes are not supported by amdkfd\n",
  119. current->pid);
  120. return -EPERM;
  121. }
  122. process = kfd_create_process(current);
  123. if (IS_ERR(process))
  124. return PTR_ERR(process);
  125. if (kfd_process_init_cwsr_apu(process, filep)) {
  126. kfd_unref_process(process);
  127. return -EFAULT;
  128. }
  129. /* filep now owns the reference returned by kfd_create_process */
  130. filep->private_data = process;
  131. dev_dbg(kfd_device, "process pid %d opened kfd node, compat mode (32 bit) - %d\n",
  132. process->lead_thread->pid, process->is_32bit_user_mode);
  133. return 0;
  134. }
  135. static int kfd_release(struct inode *inode, struct file *filep)
  136. {
  137. struct kfd_process *process = filep->private_data;
  138. if (!process)
  139. return 0;
  140. if (process->context_id != KFD_CONTEXT_ID_PRIMARY)
  141. kfd_process_notifier_release_internal(process);
  142. kfd_unref_process(process);
  143. return 0;
  144. }
  145. static int kfd_ioctl_get_version(struct file *filep, struct kfd_process *p,
  146. void *data)
  147. {
  148. struct kfd_ioctl_get_version_args *args = data;
  149. args->major_version = KFD_IOCTL_MAJOR_VERSION;
  150. args->minor_version = KFD_IOCTL_MINOR_VERSION;
  151. return 0;
  152. }
  153. static int set_queue_properties_from_user(struct queue_properties *q_properties,
  154. struct kfd_ioctl_create_queue_args *args)
  155. {
  156. /*
  157. * Repurpose queue percentage to accommodate new features:
  158. * bit 0-7: queue percentage
  159. * bit 8-15: pm4_target_xcc
  160. */
  161. if ((args->queue_percentage & 0xFF) > KFD_MAX_QUEUE_PERCENTAGE) {
  162. pr_err("Queue percentage must be between 0 to KFD_MAX_QUEUE_PERCENTAGE\n");
  163. return -EINVAL;
  164. }
  165. if (args->queue_priority > KFD_MAX_QUEUE_PRIORITY) {
  166. pr_err("Queue priority must be between 0 to KFD_MAX_QUEUE_PRIORITY\n");
  167. return -EINVAL;
  168. }
  169. if ((args->ring_base_address) &&
  170. (!access_ok((const void __user *) args->ring_base_address,
  171. sizeof(uint64_t)))) {
  172. pr_err("Can't access ring base address\n");
  173. return -EFAULT;
  174. }
  175. if (!is_power_of_2(args->ring_size) && (args->ring_size != 0)) {
  176. pr_err("Ring size must be a power of 2 or 0\n");
  177. return -EINVAL;
  178. }
  179. if (args->ring_size < KFD_MIN_QUEUE_RING_SIZE) {
  180. args->ring_size = KFD_MIN_QUEUE_RING_SIZE;
  181. pr_debug("Size lower. clamped to KFD_MIN_QUEUE_RING_SIZE");
  182. }
  183. if ((args->metadata_ring_size != 0) && !is_power_of_2(args->metadata_ring_size)) {
  184. pr_err("Metadata ring size must be a power of 2 or 0\n");
  185. return -EINVAL;
  186. }
  187. if (!access_ok((const void __user *) args->read_pointer_address,
  188. sizeof(uint32_t))) {
  189. pr_err("Can't access read pointer\n");
  190. return -EFAULT;
  191. }
  192. if (!access_ok((const void __user *) args->write_pointer_address,
  193. sizeof(uint32_t))) {
  194. pr_err("Can't access write pointer\n");
  195. return -EFAULT;
  196. }
  197. if (args->eop_buffer_address &&
  198. !access_ok((const void __user *) args->eop_buffer_address,
  199. sizeof(uint32_t))) {
  200. pr_debug("Can't access eop buffer");
  201. return -EFAULT;
  202. }
  203. if (args->ctx_save_restore_address &&
  204. !access_ok((const void __user *) args->ctx_save_restore_address,
  205. sizeof(uint32_t))) {
  206. pr_debug("Can't access ctx save restore buffer");
  207. return -EFAULT;
  208. }
  209. q_properties->is_interop = false;
  210. q_properties->is_gws = false;
  211. q_properties->queue_percent = args->queue_percentage & 0xFF;
  212. /* bit 8-15 are repurposed to be PM4 target XCC */
  213. q_properties->pm4_target_xcc = (args->queue_percentage >> 8) & 0xFF;
  214. q_properties->priority = args->queue_priority;
  215. q_properties->queue_address = args->ring_base_address;
  216. q_properties->queue_size = args->ring_size;
  217. if (args->queue_type == KFD_IOC_QUEUE_TYPE_COMPUTE_AQL)
  218. q_properties->metadata_queue_size = args->metadata_ring_size;
  219. q_properties->read_ptr = (void __user *)args->read_pointer_address;
  220. q_properties->write_ptr = (void __user *)args->write_pointer_address;
  221. q_properties->eop_ring_buffer_address = args->eop_buffer_address;
  222. q_properties->eop_ring_buffer_size = args->eop_buffer_size;
  223. q_properties->ctx_save_restore_area_address =
  224. args->ctx_save_restore_address;
  225. q_properties->ctx_save_restore_area_size = args->ctx_save_restore_size;
  226. q_properties->ctl_stack_size = args->ctl_stack_size;
  227. q_properties->sdma_engine_id = args->sdma_engine_id;
  228. if (args->queue_type == KFD_IOC_QUEUE_TYPE_COMPUTE ||
  229. args->queue_type == KFD_IOC_QUEUE_TYPE_COMPUTE_AQL)
  230. q_properties->type = KFD_QUEUE_TYPE_COMPUTE;
  231. else if (args->queue_type == KFD_IOC_QUEUE_TYPE_SDMA)
  232. q_properties->type = KFD_QUEUE_TYPE_SDMA;
  233. else if (args->queue_type == KFD_IOC_QUEUE_TYPE_SDMA_XGMI)
  234. q_properties->type = KFD_QUEUE_TYPE_SDMA_XGMI;
  235. else if (args->queue_type == KFD_IOC_QUEUE_TYPE_SDMA_BY_ENG_ID)
  236. q_properties->type = KFD_QUEUE_TYPE_SDMA_BY_ENG_ID;
  237. else
  238. return -ENOTSUPP;
  239. if (args->queue_type == KFD_IOC_QUEUE_TYPE_COMPUTE_AQL)
  240. q_properties->format = KFD_QUEUE_FORMAT_AQL;
  241. else
  242. q_properties->format = KFD_QUEUE_FORMAT_PM4;
  243. pr_debug("Queue Percentage: %d, %d\n",
  244. q_properties->queue_percent, args->queue_percentage);
  245. pr_debug("Queue Priority: %d, %d\n",
  246. q_properties->priority, args->queue_priority);
  247. pr_debug("Queue Address: 0x%llX, 0x%llX\n",
  248. q_properties->queue_address, args->ring_base_address);
  249. pr_debug("Queue Size: 0x%llX, %u\n",
  250. q_properties->queue_size, args->ring_size);
  251. pr_debug("Queue r/w Pointers: %px, %px\n",
  252. q_properties->read_ptr,
  253. q_properties->write_ptr);
  254. pr_debug("Queue Format: %d\n", q_properties->format);
  255. pr_debug("Queue EOP: 0x%llX\n", q_properties->eop_ring_buffer_address);
  256. pr_debug("Queue CTX save area: 0x%llX\n",
  257. q_properties->ctx_save_restore_area_address);
  258. return 0;
  259. }
  260. static int kfd_ioctl_create_queue(struct file *filep, struct kfd_process *p,
  261. void *data)
  262. {
  263. struct kfd_ioctl_create_queue_args *args = data;
  264. struct kfd_node *dev;
  265. int err = 0;
  266. unsigned int queue_id;
  267. struct kfd_process_device *pdd;
  268. struct queue_properties q_properties;
  269. uint32_t doorbell_offset_in_process = 0;
  270. memset(&q_properties, 0, sizeof(struct queue_properties));
  271. pr_debug("Creating queue ioctl\n");
  272. err = set_queue_properties_from_user(&q_properties, args);
  273. if (err)
  274. return err;
  275. pr_debug("Looking for gpu id 0x%x\n", args->gpu_id);
  276. mutex_lock(&p->mutex);
  277. pdd = kfd_process_device_data_by_id(p, args->gpu_id);
  278. if (!pdd) {
  279. pr_debug("Could not find gpu id 0x%x\n", args->gpu_id);
  280. err = -EINVAL;
  281. goto err_pdd;
  282. }
  283. dev = pdd->dev;
  284. pdd = kfd_bind_process_to_device(dev, p);
  285. if (IS_ERR(pdd)) {
  286. err = -ESRCH;
  287. goto err_bind_process;
  288. }
  289. if (q_properties.type == KFD_QUEUE_TYPE_SDMA_BY_ENG_ID) {
  290. int max_sdma_eng_id = kfd_get_num_sdma_engines(dev) +
  291. kfd_get_num_xgmi_sdma_engines(dev) - 1;
  292. if (q_properties.sdma_engine_id > max_sdma_eng_id) {
  293. err = -EINVAL;
  294. pr_err("sdma_engine_id %i exceeds maximum id of %i\n",
  295. q_properties.sdma_engine_id, max_sdma_eng_id);
  296. goto err_sdma_engine_id;
  297. }
  298. }
  299. if (!pdd->qpd.proc_doorbells) {
  300. err = kfd_alloc_process_doorbells(dev->kfd, pdd);
  301. if (err) {
  302. pr_debug("failed to allocate process doorbells\n");
  303. goto err_bind_process;
  304. }
  305. }
  306. err = kfd_queue_acquire_buffers(pdd, &q_properties);
  307. if (err) {
  308. pr_debug("failed to acquire user queue buffers\n");
  309. goto err_acquire_queue_buf;
  310. }
  311. pr_debug("Creating queue for process pid %d on gpu 0x%x\n",
  312. p->lead_thread->pid,
  313. dev->id);
  314. err = pqm_create_queue(&p->pqm, dev, &q_properties, &queue_id,
  315. NULL, NULL, NULL, &doorbell_offset_in_process);
  316. if (err != 0)
  317. goto err_create_queue;
  318. args->queue_id = queue_id;
  319. /* Return gpu_id as doorbell offset for mmap usage */
  320. args->doorbell_offset = KFD_MMAP_TYPE_DOORBELL;
  321. args->doorbell_offset |= KFD_MMAP_GPU_ID(args->gpu_id);
  322. if (KFD_IS_SOC15(dev))
  323. /* On SOC15 ASICs, include the doorbell offset within the
  324. * process doorbell frame, which is 2 pages.
  325. */
  326. args->doorbell_offset |= doorbell_offset_in_process;
  327. mutex_unlock(&p->mutex);
  328. pr_debug("Queue id %d was created successfully\n", args->queue_id);
  329. pr_debug("Ring buffer address == 0x%016llX\n",
  330. args->ring_base_address);
  331. pr_debug("Read ptr address == 0x%016llX\n",
  332. args->read_pointer_address);
  333. pr_debug("Write ptr address == 0x%016llX\n",
  334. args->write_pointer_address);
  335. kfd_dbg_ev_raise(KFD_EC_MASK(EC_QUEUE_NEW), p, dev, queue_id, false, NULL, 0);
  336. return 0;
  337. err_create_queue:
  338. kfd_queue_unref_bo_vas(pdd, &q_properties);
  339. kfd_queue_release_buffers(pdd, &q_properties);
  340. err_acquire_queue_buf:
  341. err_sdma_engine_id:
  342. err_bind_process:
  343. err_pdd:
  344. mutex_unlock(&p->mutex);
  345. return err;
  346. }
  347. static int kfd_ioctl_destroy_queue(struct file *filp, struct kfd_process *p,
  348. void *data)
  349. {
  350. int retval;
  351. struct kfd_ioctl_destroy_queue_args *args = data;
  352. pr_debug("Destroying queue id %d for process pid %d\n",
  353. args->queue_id,
  354. p->lead_thread->pid);
  355. mutex_lock(&p->mutex);
  356. retval = pqm_destroy_queue(&p->pqm, args->queue_id);
  357. mutex_unlock(&p->mutex);
  358. return retval;
  359. }
  360. static int kfd_ioctl_update_queue(struct file *filp, struct kfd_process *p,
  361. void *data)
  362. {
  363. int retval;
  364. struct kfd_ioctl_update_queue_args *args = data;
  365. struct queue_properties properties;
  366. /*
  367. * Repurpose queue percentage to accommodate new features:
  368. * bit 0-7: queue percentage
  369. * bit 8-15: pm4_target_xcc
  370. */
  371. if ((args->queue_percentage & 0xFF) > KFD_MAX_QUEUE_PERCENTAGE) {
  372. pr_err("Queue percentage must be between 0 to KFD_MAX_QUEUE_PERCENTAGE\n");
  373. return -EINVAL;
  374. }
  375. if (args->queue_priority > KFD_MAX_QUEUE_PRIORITY) {
  376. pr_err("Queue priority must be between 0 to KFD_MAX_QUEUE_PRIORITY\n");
  377. return -EINVAL;
  378. }
  379. if ((args->ring_base_address) &&
  380. (!access_ok((const void __user *) args->ring_base_address,
  381. sizeof(uint64_t)))) {
  382. pr_err("Can't access ring base address\n");
  383. return -EFAULT;
  384. }
  385. if (!is_power_of_2(args->ring_size) && (args->ring_size != 0)) {
  386. pr_err("Ring size must be a power of 2 or 0\n");
  387. return -EINVAL;
  388. }
  389. if (args->ring_size < KFD_MIN_QUEUE_RING_SIZE) {
  390. args->ring_size = KFD_MIN_QUEUE_RING_SIZE;
  391. pr_debug("Size lower. clamped to KFD_MIN_QUEUE_RING_SIZE");
  392. }
  393. properties.queue_address = args->ring_base_address;
  394. properties.queue_size = args->ring_size;
  395. properties.queue_percent = args->queue_percentage & 0xFF;
  396. /* bit 8-15 are repurposed to be PM4 target XCC */
  397. properties.pm4_target_xcc = (args->queue_percentage >> 8) & 0xFF;
  398. properties.priority = args->queue_priority;
  399. pr_debug("Updating queue id %d for process pid %d\n",
  400. args->queue_id, p->lead_thread->pid);
  401. mutex_lock(&p->mutex);
  402. retval = pqm_update_queue_properties(&p->pqm, args->queue_id, &properties);
  403. mutex_unlock(&p->mutex);
  404. return retval;
  405. }
  406. static int kfd_ioctl_set_cu_mask(struct file *filp, struct kfd_process *p,
  407. void *data)
  408. {
  409. int retval;
  410. const int max_num_cus = 1024;
  411. struct kfd_ioctl_set_cu_mask_args *args = data;
  412. struct mqd_update_info minfo = {0};
  413. uint32_t __user *cu_mask_ptr = (uint32_t __user *)args->cu_mask_ptr;
  414. size_t cu_mask_size = sizeof(uint32_t) * (args->num_cu_mask / 32);
  415. if ((args->num_cu_mask % 32) != 0) {
  416. pr_debug("num_cu_mask 0x%x must be a multiple of 32",
  417. args->num_cu_mask);
  418. return -EINVAL;
  419. }
  420. minfo.cu_mask.count = args->num_cu_mask;
  421. if (minfo.cu_mask.count == 0) {
  422. pr_debug("CU mask cannot be 0");
  423. return -EINVAL;
  424. }
  425. /* To prevent an unreasonably large CU mask size, set an arbitrary
  426. * limit of max_num_cus bits. We can then just drop any CU mask bits
  427. * past max_num_cus bits and just use the first max_num_cus bits.
  428. */
  429. if (minfo.cu_mask.count > max_num_cus) {
  430. pr_debug("CU mask cannot be greater than 1024 bits");
  431. minfo.cu_mask.count = max_num_cus;
  432. cu_mask_size = sizeof(uint32_t) * (max_num_cus/32);
  433. }
  434. minfo.cu_mask.ptr = memdup_user(cu_mask_ptr, cu_mask_size);
  435. if (IS_ERR(minfo.cu_mask.ptr)) {
  436. pr_debug("Could not copy CU mask from userspace");
  437. return PTR_ERR(minfo.cu_mask.ptr);
  438. }
  439. mutex_lock(&p->mutex);
  440. retval = pqm_update_mqd(&p->pqm, args->queue_id, &minfo);
  441. mutex_unlock(&p->mutex);
  442. kfree(minfo.cu_mask.ptr);
  443. return retval;
  444. }
  445. static int kfd_ioctl_get_queue_wave_state(struct file *filep,
  446. struct kfd_process *p, void *data)
  447. {
  448. struct kfd_ioctl_get_queue_wave_state_args *args = data;
  449. int r;
  450. mutex_lock(&p->mutex);
  451. r = pqm_get_wave_state(&p->pqm, args->queue_id,
  452. (void __user *)args->ctl_stack_address,
  453. &args->ctl_stack_used_size,
  454. &args->save_area_used_size);
  455. mutex_unlock(&p->mutex);
  456. return r;
  457. }
  458. static int kfd_ioctl_set_memory_policy(struct file *filep,
  459. struct kfd_process *p, void *data)
  460. {
  461. struct kfd_ioctl_set_memory_policy_args *args = data;
  462. int err = 0;
  463. struct kfd_process_device *pdd;
  464. enum cache_policy default_policy, alternate_policy;
  465. if (args->default_policy != KFD_IOC_CACHE_POLICY_COHERENT
  466. && args->default_policy != KFD_IOC_CACHE_POLICY_NONCOHERENT) {
  467. return -EINVAL;
  468. }
  469. if (args->alternate_policy != KFD_IOC_CACHE_POLICY_COHERENT
  470. && args->alternate_policy != KFD_IOC_CACHE_POLICY_NONCOHERENT) {
  471. return -EINVAL;
  472. }
  473. mutex_lock(&p->mutex);
  474. pdd = kfd_process_device_data_by_id(p, args->gpu_id);
  475. if (!pdd) {
  476. pr_debug("Could not find gpu id 0x%x\n", args->gpu_id);
  477. err = -EINVAL;
  478. goto err_pdd;
  479. }
  480. pdd = kfd_bind_process_to_device(pdd->dev, p);
  481. if (IS_ERR(pdd)) {
  482. err = -ESRCH;
  483. goto out;
  484. }
  485. default_policy = (args->default_policy == KFD_IOC_CACHE_POLICY_COHERENT)
  486. ? cache_policy_coherent : cache_policy_noncoherent;
  487. alternate_policy =
  488. (args->alternate_policy == KFD_IOC_CACHE_POLICY_COHERENT)
  489. ? cache_policy_coherent : cache_policy_noncoherent;
  490. if (!pdd->dev->dqm->ops.set_cache_memory_policy(pdd->dev->dqm,
  491. &pdd->qpd,
  492. default_policy,
  493. alternate_policy,
  494. (void __user *)args->alternate_aperture_base,
  495. args->alternate_aperture_size,
  496. args->misc_process_flag))
  497. err = -EINVAL;
  498. out:
  499. err_pdd:
  500. mutex_unlock(&p->mutex);
  501. return err;
  502. }
  503. static int kfd_ioctl_set_trap_handler(struct file *filep,
  504. struct kfd_process *p, void *data)
  505. {
  506. struct kfd_ioctl_set_trap_handler_args *args = data;
  507. int err = 0;
  508. struct kfd_process_device *pdd;
  509. mutex_lock(&p->mutex);
  510. pdd = kfd_process_device_data_by_id(p, args->gpu_id);
  511. if (!pdd) {
  512. err = -EINVAL;
  513. goto err_pdd;
  514. }
  515. pdd = kfd_bind_process_to_device(pdd->dev, p);
  516. if (IS_ERR(pdd)) {
  517. err = -ESRCH;
  518. goto out;
  519. }
  520. kfd_process_set_trap_handler(&pdd->qpd, args->tba_addr, args->tma_addr);
  521. out:
  522. err_pdd:
  523. mutex_unlock(&p->mutex);
  524. return err;
  525. }
  526. static int kfd_ioctl_dbg_register(struct file *filep,
  527. struct kfd_process *p, void *data)
  528. {
  529. return -EPERM;
  530. }
  531. static int kfd_ioctl_dbg_unregister(struct file *filep,
  532. struct kfd_process *p, void *data)
  533. {
  534. return -EPERM;
  535. }
  536. static int kfd_ioctl_dbg_address_watch(struct file *filep,
  537. struct kfd_process *p, void *data)
  538. {
  539. return -EPERM;
  540. }
  541. /* Parse and generate fixed size data structure for wave control */
  542. static int kfd_ioctl_dbg_wave_control(struct file *filep,
  543. struct kfd_process *p, void *data)
  544. {
  545. return -EPERM;
  546. }
  547. static int kfd_ioctl_get_clock_counters(struct file *filep,
  548. struct kfd_process *p, void *data)
  549. {
  550. struct kfd_ioctl_get_clock_counters_args *args = data;
  551. struct kfd_process_device *pdd;
  552. mutex_lock(&p->mutex);
  553. pdd = kfd_process_device_data_by_id(p, args->gpu_id);
  554. mutex_unlock(&p->mutex);
  555. if (pdd)
  556. /* Reading GPU clock counter from KGD */
  557. args->gpu_clock_counter = amdgpu_amdkfd_get_gpu_clock_counter(pdd->dev->adev);
  558. else
  559. /* Node without GPU resource */
  560. args->gpu_clock_counter = 0;
  561. /* No access to rdtsc. Using raw monotonic time */
  562. args->cpu_clock_counter = ktime_get_raw_ns();
  563. args->system_clock_counter = ktime_get_boottime_ns();
  564. /* Since the counter is in nano-seconds we use 1GHz frequency */
  565. args->system_clock_freq = 1000000000;
  566. return 0;
  567. }
  568. static int kfd_ioctl_get_process_apertures(struct file *filp,
  569. struct kfd_process *p, void *data)
  570. {
  571. struct kfd_ioctl_get_process_apertures_args *args = data;
  572. struct kfd_process_device_apertures *pAperture;
  573. int i;
  574. dev_dbg(kfd_device, "get apertures for process pid %d", p->lead_thread->pid);
  575. args->num_of_nodes = 0;
  576. mutex_lock(&p->mutex);
  577. /* Run over all pdd of the process */
  578. for (i = 0; i < p->n_pdds; i++) {
  579. struct kfd_process_device *pdd = p->pdds[i];
  580. pAperture =
  581. &args->process_apertures[args->num_of_nodes];
  582. pAperture->gpu_id = pdd->dev->id;
  583. pAperture->lds_base = pdd->lds_base;
  584. pAperture->lds_limit = pdd->lds_limit;
  585. pAperture->gpuvm_base = pdd->gpuvm_base;
  586. pAperture->gpuvm_limit = pdd->gpuvm_limit;
  587. pAperture->scratch_base = pdd->scratch_base;
  588. pAperture->scratch_limit = pdd->scratch_limit;
  589. dev_dbg(kfd_device,
  590. "node id %u\n", args->num_of_nodes);
  591. dev_dbg(kfd_device,
  592. "gpu id %u\n", pdd->dev->id);
  593. dev_dbg(kfd_device,
  594. "lds_base %llX\n", pdd->lds_base);
  595. dev_dbg(kfd_device,
  596. "lds_limit %llX\n", pdd->lds_limit);
  597. dev_dbg(kfd_device,
  598. "gpuvm_base %llX\n", pdd->gpuvm_base);
  599. dev_dbg(kfd_device,
  600. "gpuvm_limit %llX\n", pdd->gpuvm_limit);
  601. dev_dbg(kfd_device,
  602. "scratch_base %llX\n", pdd->scratch_base);
  603. dev_dbg(kfd_device,
  604. "scratch_limit %llX\n", pdd->scratch_limit);
  605. if (++args->num_of_nodes >= NUM_OF_SUPPORTED_GPUS)
  606. break;
  607. }
  608. mutex_unlock(&p->mutex);
  609. return 0;
  610. }
  611. static int kfd_ioctl_get_process_apertures_new(struct file *filp,
  612. struct kfd_process *p, void *data)
  613. {
  614. struct kfd_ioctl_get_process_apertures_new_args *args = data;
  615. struct kfd_process_device_apertures *pa;
  616. int ret;
  617. int i;
  618. dev_dbg(kfd_device, "get apertures for process pid %d",
  619. p->lead_thread->pid);
  620. if (args->num_of_nodes == 0) {
  621. /* Return number of nodes, so that user space can alloacate
  622. * sufficient memory
  623. */
  624. mutex_lock(&p->mutex);
  625. args->num_of_nodes = p->n_pdds;
  626. goto out_unlock;
  627. }
  628. /* Fill in process-aperture information for all available
  629. * nodes, but not more than args->num_of_nodes as that is
  630. * the amount of memory allocated by user
  631. */
  632. pa = kzalloc_objs(struct kfd_process_device_apertures,
  633. args->num_of_nodes);
  634. if (!pa)
  635. return -ENOMEM;
  636. mutex_lock(&p->mutex);
  637. if (!p->n_pdds) {
  638. args->num_of_nodes = 0;
  639. kfree(pa);
  640. goto out_unlock;
  641. }
  642. /* Run over all pdd of the process */
  643. for (i = 0; i < min(p->n_pdds, args->num_of_nodes); i++) {
  644. struct kfd_process_device *pdd = p->pdds[i];
  645. pa[i].gpu_id = pdd->dev->id;
  646. pa[i].lds_base = pdd->lds_base;
  647. pa[i].lds_limit = pdd->lds_limit;
  648. pa[i].gpuvm_base = pdd->gpuvm_base;
  649. pa[i].gpuvm_limit = pdd->gpuvm_limit;
  650. pa[i].scratch_base = pdd->scratch_base;
  651. pa[i].scratch_limit = pdd->scratch_limit;
  652. dev_dbg(kfd_device,
  653. "gpu id %u\n", pdd->dev->id);
  654. dev_dbg(kfd_device,
  655. "lds_base %llX\n", pdd->lds_base);
  656. dev_dbg(kfd_device,
  657. "lds_limit %llX\n", pdd->lds_limit);
  658. dev_dbg(kfd_device,
  659. "gpuvm_base %llX\n", pdd->gpuvm_base);
  660. dev_dbg(kfd_device,
  661. "gpuvm_limit %llX\n", pdd->gpuvm_limit);
  662. dev_dbg(kfd_device,
  663. "scratch_base %llX\n", pdd->scratch_base);
  664. dev_dbg(kfd_device,
  665. "scratch_limit %llX\n", pdd->scratch_limit);
  666. }
  667. mutex_unlock(&p->mutex);
  668. args->num_of_nodes = i;
  669. ret = copy_to_user(
  670. (void __user *)args->kfd_process_device_apertures_ptr,
  671. pa,
  672. (i * sizeof(struct kfd_process_device_apertures)));
  673. kfree(pa);
  674. return ret ? -EFAULT : 0;
  675. out_unlock:
  676. mutex_unlock(&p->mutex);
  677. return 0;
  678. }
  679. static int kfd_ioctl_create_event(struct file *filp, struct kfd_process *p,
  680. void *data)
  681. {
  682. struct kfd_ioctl_create_event_args *args = data;
  683. int err;
  684. /* For dGPUs the event page is allocated in user mode. The
  685. * handle is passed to KFD with the first call to this IOCTL
  686. * through the event_page_offset field.
  687. */
  688. if (args->event_page_offset) {
  689. mutex_lock(&p->mutex);
  690. err = kfd_kmap_event_page(p, args->event_page_offset);
  691. mutex_unlock(&p->mutex);
  692. if (err)
  693. return err;
  694. }
  695. err = kfd_event_create(filp, p, args->event_type,
  696. args->auto_reset != 0, args->node_id,
  697. &args->event_id, &args->event_trigger_data,
  698. &args->event_page_offset,
  699. &args->event_slot_index);
  700. pr_debug("Created event (id:0x%08x) (%s)\n", args->event_id, __func__);
  701. return err;
  702. }
  703. static int kfd_ioctl_destroy_event(struct file *filp, struct kfd_process *p,
  704. void *data)
  705. {
  706. struct kfd_ioctl_destroy_event_args *args = data;
  707. return kfd_event_destroy(p, args->event_id);
  708. }
  709. static int kfd_ioctl_set_event(struct file *filp, struct kfd_process *p,
  710. void *data)
  711. {
  712. struct kfd_ioctl_set_event_args *args = data;
  713. return kfd_set_event(p, args->event_id);
  714. }
  715. static int kfd_ioctl_reset_event(struct file *filp, struct kfd_process *p,
  716. void *data)
  717. {
  718. struct kfd_ioctl_reset_event_args *args = data;
  719. return kfd_reset_event(p, args->event_id);
  720. }
  721. static int kfd_ioctl_wait_events(struct file *filp, struct kfd_process *p,
  722. void *data)
  723. {
  724. struct kfd_ioctl_wait_events_args *args = data;
  725. return kfd_wait_on_events(p, args->num_events,
  726. (void __user *)args->events_ptr,
  727. (args->wait_for_all != 0),
  728. &args->timeout, &args->wait_result);
  729. }
  730. static int kfd_ioctl_set_scratch_backing_va(struct file *filep,
  731. struct kfd_process *p, void *data)
  732. {
  733. struct kfd_ioctl_set_scratch_backing_va_args *args = data;
  734. struct kfd_process_device *pdd;
  735. struct kfd_node *dev;
  736. long err;
  737. mutex_lock(&p->mutex);
  738. pdd = kfd_process_device_data_by_id(p, args->gpu_id);
  739. if (!pdd) {
  740. err = -EINVAL;
  741. goto err_pdd;
  742. }
  743. dev = pdd->dev;
  744. pdd = kfd_bind_process_to_device(dev, p);
  745. if (IS_ERR(pdd)) {
  746. err = PTR_ERR(pdd);
  747. goto bind_process_to_device_fail;
  748. }
  749. pdd->qpd.sh_hidden_private_base = args->va_addr;
  750. mutex_unlock(&p->mutex);
  751. if (dev->dqm->sched_policy == KFD_SCHED_POLICY_NO_HWS &&
  752. pdd->qpd.vmid != 0 && dev->kfd2kgd->set_scratch_backing_va)
  753. dev->kfd2kgd->set_scratch_backing_va(
  754. dev->adev, args->va_addr, pdd->qpd.vmid);
  755. return 0;
  756. bind_process_to_device_fail:
  757. err_pdd:
  758. mutex_unlock(&p->mutex);
  759. return err;
  760. }
  761. static int kfd_ioctl_get_tile_config(struct file *filep,
  762. struct kfd_process *p, void *data)
  763. {
  764. struct kfd_ioctl_get_tile_config_args *args = data;
  765. struct kfd_process_device *pdd;
  766. struct tile_config config;
  767. int err = 0;
  768. mutex_lock(&p->mutex);
  769. pdd = kfd_process_device_data_by_id(p, args->gpu_id);
  770. mutex_unlock(&p->mutex);
  771. if (!pdd)
  772. return -EINVAL;
  773. amdgpu_amdkfd_get_tile_config(pdd->dev->adev, &config);
  774. args->gb_addr_config = config.gb_addr_config;
  775. args->num_banks = config.num_banks;
  776. args->num_ranks = config.num_ranks;
  777. if (args->num_tile_configs > config.num_tile_configs)
  778. args->num_tile_configs = config.num_tile_configs;
  779. err = copy_to_user((void __user *)args->tile_config_ptr,
  780. config.tile_config_ptr,
  781. args->num_tile_configs * sizeof(uint32_t));
  782. if (err) {
  783. args->num_tile_configs = 0;
  784. return -EFAULT;
  785. }
  786. if (args->num_macro_tile_configs > config.num_macro_tile_configs)
  787. args->num_macro_tile_configs =
  788. config.num_macro_tile_configs;
  789. err = copy_to_user((void __user *)args->macro_tile_config_ptr,
  790. config.macro_tile_config_ptr,
  791. args->num_macro_tile_configs * sizeof(uint32_t));
  792. if (err) {
  793. args->num_macro_tile_configs = 0;
  794. return -EFAULT;
  795. }
  796. return 0;
  797. }
  798. static int kfd_ioctl_acquire_vm(struct file *filep, struct kfd_process *p,
  799. void *data)
  800. {
  801. struct kfd_ioctl_acquire_vm_args *args = data;
  802. struct kfd_process_device *pdd;
  803. struct file *drm_file;
  804. int ret;
  805. drm_file = fget(args->drm_fd);
  806. if (!drm_file)
  807. return -EINVAL;
  808. mutex_lock(&p->mutex);
  809. pdd = kfd_process_device_data_by_id(p, args->gpu_id);
  810. if (!pdd) {
  811. ret = -EINVAL;
  812. goto err_pdd;
  813. }
  814. if (pdd->drm_file) {
  815. ret = pdd->drm_file == drm_file ? 0 : -EBUSY;
  816. goto err_drm_file;
  817. }
  818. ret = kfd_process_device_init_vm(pdd, drm_file);
  819. if (ret)
  820. goto err_unlock;
  821. /* On success, the PDD keeps the drm_file reference */
  822. mutex_unlock(&p->mutex);
  823. return 0;
  824. err_unlock:
  825. err_pdd:
  826. err_drm_file:
  827. mutex_unlock(&p->mutex);
  828. fput(drm_file);
  829. return ret;
  830. }
  831. bool kfd_dev_is_large_bar(struct kfd_node *dev)
  832. {
  833. if (dev->kfd->adev->debug_largebar) {
  834. pr_debug("Simulate large-bar allocation on non large-bar machine\n");
  835. return true;
  836. }
  837. if (dev->local_mem_info.local_mem_size_private == 0 &&
  838. dev->local_mem_info.local_mem_size_public > 0)
  839. return true;
  840. if (dev->local_mem_info.local_mem_size_public == 0 &&
  841. dev->kfd->adev->gmc.is_app_apu) {
  842. pr_debug("APP APU, Consider like a large bar system\n");
  843. return true;
  844. }
  845. return false;
  846. }
  847. static int kfd_ioctl_get_available_memory(struct file *filep,
  848. struct kfd_process *p, void *data)
  849. {
  850. struct kfd_ioctl_get_available_memory_args *args = data;
  851. struct kfd_process_device *pdd = kfd_lock_pdd_by_id(p, args->gpu_id);
  852. if (!pdd)
  853. return -EINVAL;
  854. args->available = amdgpu_amdkfd_get_available_memory(pdd->dev->adev,
  855. pdd->dev->node_id);
  856. kfd_unlock_pdd(pdd);
  857. return 0;
  858. }
  859. static int kfd_ioctl_alloc_memory_of_gpu(struct file *filep,
  860. struct kfd_process *p, void *data)
  861. {
  862. struct kfd_ioctl_alloc_memory_of_gpu_args *args = data;
  863. struct kfd_process_device *pdd;
  864. void *mem;
  865. struct kfd_node *dev;
  866. int idr_handle;
  867. long err;
  868. uint64_t offset = args->mmap_offset;
  869. uint32_t flags = args->flags;
  870. if (args->size == 0)
  871. return -EINVAL;
  872. if (p->context_id != KFD_CONTEXT_ID_PRIMARY && (flags & KFD_IOC_ALLOC_MEM_FLAGS_USERPTR)) {
  873. pr_debug("USERPTR is not supported on non-primary kfd_process\n");
  874. return -EOPNOTSUPP;
  875. }
  876. #if IS_ENABLED(CONFIG_HSA_AMD_SVM)
  877. /* Flush pending deferred work to avoid racing with deferred actions
  878. * from previous memory map changes (e.g. munmap).
  879. */
  880. svm_range_list_lock_and_flush_work(&p->svms, current->mm);
  881. mutex_lock(&p->svms.lock);
  882. mmap_write_unlock(current->mm);
  883. /* Skip a special case that allocates VRAM without VA,
  884. * VA will be invalid of 0.
  885. */
  886. if (!(!args->va_addr && (flags & KFD_IOC_ALLOC_MEM_FLAGS_VRAM)) &&
  887. interval_tree_iter_first(&p->svms.objects,
  888. args->va_addr >> PAGE_SHIFT,
  889. (args->va_addr + args->size - 1) >> PAGE_SHIFT)) {
  890. pr_err("Address: 0x%llx already allocated by SVM\n",
  891. args->va_addr);
  892. mutex_unlock(&p->svms.lock);
  893. return -EADDRINUSE;
  894. }
  895. /* When register user buffer check if it has been registered by svm by
  896. * buffer cpu virtual address.
  897. */
  898. if ((flags & KFD_IOC_ALLOC_MEM_FLAGS_USERPTR) &&
  899. interval_tree_iter_first(&p->svms.objects,
  900. args->mmap_offset >> PAGE_SHIFT,
  901. (args->mmap_offset + args->size - 1) >> PAGE_SHIFT)) {
  902. pr_err("User Buffer Address: 0x%llx already allocated by SVM\n",
  903. args->mmap_offset);
  904. mutex_unlock(&p->svms.lock);
  905. return -EADDRINUSE;
  906. }
  907. mutex_unlock(&p->svms.lock);
  908. #endif
  909. mutex_lock(&p->mutex);
  910. pdd = kfd_process_device_data_by_id(p, args->gpu_id);
  911. if (!pdd) {
  912. err = -EINVAL;
  913. goto err_pdd;
  914. }
  915. dev = pdd->dev;
  916. if ((flags & KFD_IOC_ALLOC_MEM_FLAGS_PUBLIC) &&
  917. (flags & KFD_IOC_ALLOC_MEM_FLAGS_VRAM) &&
  918. !kfd_dev_is_large_bar(dev)) {
  919. pr_err("Alloc host visible vram on small bar is not allowed\n");
  920. err = -EINVAL;
  921. goto err_large_bar;
  922. }
  923. pdd = kfd_bind_process_to_device(dev, p);
  924. if (IS_ERR(pdd)) {
  925. err = PTR_ERR(pdd);
  926. goto err_unlock;
  927. }
  928. if (flags & KFD_IOC_ALLOC_MEM_FLAGS_DOORBELL) {
  929. if (args->size != kfd_doorbell_process_slice(dev->kfd)) {
  930. err = -EINVAL;
  931. goto err_unlock;
  932. }
  933. offset = kfd_get_process_doorbells(pdd);
  934. if (!offset) {
  935. err = -ENOMEM;
  936. goto err_unlock;
  937. }
  938. } else if (flags & KFD_IOC_ALLOC_MEM_FLAGS_MMIO_REMAP) {
  939. if (args->size != PAGE_SIZE) {
  940. err = -EINVAL;
  941. goto err_unlock;
  942. }
  943. offset = dev->adev->rmmio_remap.bus_addr;
  944. if (!offset || (PAGE_SIZE > 4096)) {
  945. err = -ENOMEM;
  946. goto err_unlock;
  947. }
  948. }
  949. err = amdgpu_amdkfd_gpuvm_alloc_memory_of_gpu(
  950. dev->adev, args->va_addr, args->size,
  951. pdd->drm_priv, (struct kgd_mem **) &mem, &offset,
  952. flags, false);
  953. if (err)
  954. goto err_unlock;
  955. idr_handle = kfd_process_device_create_obj_handle(pdd, mem);
  956. if (idr_handle < 0) {
  957. err = -EFAULT;
  958. goto err_free;
  959. }
  960. /* Update the VRAM usage count */
  961. if (flags & KFD_IOC_ALLOC_MEM_FLAGS_VRAM) {
  962. uint64_t size = args->size;
  963. if (flags & KFD_IOC_ALLOC_MEM_FLAGS_AQL_QUEUE_MEM)
  964. size >>= 1;
  965. atomic64_add(PAGE_ALIGN(size), &pdd->vram_usage);
  966. }
  967. mutex_unlock(&p->mutex);
  968. args->handle = MAKE_HANDLE(args->gpu_id, idr_handle);
  969. args->mmap_offset = offset;
  970. /* MMIO is mapped through kfd device
  971. * Generate a kfd mmap offset
  972. */
  973. if (flags & KFD_IOC_ALLOC_MEM_FLAGS_MMIO_REMAP)
  974. args->mmap_offset = KFD_MMAP_TYPE_MMIO
  975. | KFD_MMAP_GPU_ID(args->gpu_id);
  976. return 0;
  977. err_free:
  978. amdgpu_amdkfd_gpuvm_free_memory_of_gpu(dev->adev, (struct kgd_mem *)mem,
  979. pdd->drm_priv, NULL);
  980. err_unlock:
  981. err_pdd:
  982. err_large_bar:
  983. mutex_unlock(&p->mutex);
  984. return err;
  985. }
  986. static int kfd_ioctl_free_memory_of_gpu(struct file *filep,
  987. struct kfd_process *p, void *data)
  988. {
  989. struct kfd_ioctl_free_memory_of_gpu_args *args = data;
  990. struct kfd_process_device *pdd;
  991. void *mem;
  992. int ret;
  993. uint64_t size = 0;
  994. mutex_lock(&p->mutex);
  995. /*
  996. * Safeguard to prevent user space from freeing signal BO.
  997. * It will be freed at process termination.
  998. */
  999. if (p->signal_handle && (p->signal_handle == args->handle)) {
  1000. pr_err("Free signal BO is not allowed\n");
  1001. ret = -EPERM;
  1002. goto err_unlock;
  1003. }
  1004. pdd = kfd_process_device_data_by_id(p, GET_GPU_ID(args->handle));
  1005. if (!pdd) {
  1006. pr_err("Process device data doesn't exist\n");
  1007. ret = -EINVAL;
  1008. goto err_pdd;
  1009. }
  1010. mem = kfd_process_device_translate_handle(
  1011. pdd, GET_IDR_HANDLE(args->handle));
  1012. if (!mem) {
  1013. ret = -EINVAL;
  1014. goto err_unlock;
  1015. }
  1016. ret = amdgpu_amdkfd_gpuvm_free_memory_of_gpu(pdd->dev->adev,
  1017. (struct kgd_mem *)mem, pdd->drm_priv, &size);
  1018. /* If freeing the buffer failed, leave the handle in place for
  1019. * clean-up during process tear-down.
  1020. */
  1021. if (!ret)
  1022. kfd_process_device_remove_obj_handle(
  1023. pdd, GET_IDR_HANDLE(args->handle));
  1024. atomic64_sub(size, &pdd->vram_usage);
  1025. err_unlock:
  1026. err_pdd:
  1027. mutex_unlock(&p->mutex);
  1028. return ret;
  1029. }
  1030. static int kfd_ioctl_map_memory_to_gpu(struct file *filep,
  1031. struct kfd_process *p, void *data)
  1032. {
  1033. struct kfd_ioctl_map_memory_to_gpu_args *args = data;
  1034. struct kfd_process_device *pdd, *peer_pdd;
  1035. void *mem;
  1036. struct kfd_node *dev;
  1037. long err = 0;
  1038. int i;
  1039. uint32_t *devices_arr = NULL;
  1040. if (!args->n_devices) {
  1041. pr_debug("Device IDs array empty\n");
  1042. return -EINVAL;
  1043. }
  1044. if (args->n_success > args->n_devices) {
  1045. pr_debug("n_success exceeds n_devices\n");
  1046. return -EINVAL;
  1047. }
  1048. devices_arr = kmalloc_array(args->n_devices, sizeof(*devices_arr),
  1049. GFP_KERNEL);
  1050. if (!devices_arr)
  1051. return -ENOMEM;
  1052. err = copy_from_user(devices_arr,
  1053. (void __user *)args->device_ids_array_ptr,
  1054. args->n_devices * sizeof(*devices_arr));
  1055. if (err != 0) {
  1056. err = -EFAULT;
  1057. goto copy_from_user_failed;
  1058. }
  1059. mutex_lock(&p->mutex);
  1060. pdd = kfd_process_device_data_by_id(p, GET_GPU_ID(args->handle));
  1061. if (!pdd) {
  1062. err = -EINVAL;
  1063. goto get_process_device_data_failed;
  1064. }
  1065. dev = pdd->dev;
  1066. pdd = kfd_bind_process_to_device(dev, p);
  1067. if (IS_ERR(pdd)) {
  1068. err = PTR_ERR(pdd);
  1069. goto bind_process_to_device_failed;
  1070. }
  1071. mem = kfd_process_device_translate_handle(pdd,
  1072. GET_IDR_HANDLE(args->handle));
  1073. if (!mem) {
  1074. err = -ENOMEM;
  1075. goto get_mem_obj_from_handle_failed;
  1076. }
  1077. for (i = args->n_success; i < args->n_devices; i++) {
  1078. peer_pdd = kfd_process_device_data_by_id(p, devices_arr[i]);
  1079. if (!peer_pdd) {
  1080. pr_debug("Getting device by id failed for 0x%x\n",
  1081. devices_arr[i]);
  1082. err = -EINVAL;
  1083. goto get_mem_obj_from_handle_failed;
  1084. }
  1085. peer_pdd = kfd_bind_process_to_device(peer_pdd->dev, p);
  1086. if (IS_ERR(peer_pdd)) {
  1087. err = PTR_ERR(peer_pdd);
  1088. goto get_mem_obj_from_handle_failed;
  1089. }
  1090. err = amdgpu_amdkfd_gpuvm_map_memory_to_gpu(
  1091. peer_pdd->dev->adev, (struct kgd_mem *)mem,
  1092. peer_pdd->drm_priv);
  1093. if (err) {
  1094. struct pci_dev *pdev = peer_pdd->dev->adev->pdev;
  1095. dev_err(dev->adev->dev,
  1096. "Failed to map peer:%04x:%02x:%02x.%d mem_domain:%d\n",
  1097. pci_domain_nr(pdev->bus),
  1098. pdev->bus->number,
  1099. PCI_SLOT(pdev->devfn),
  1100. PCI_FUNC(pdev->devfn),
  1101. ((struct kgd_mem *)mem)->domain);
  1102. goto map_memory_to_gpu_failed;
  1103. }
  1104. args->n_success = i+1;
  1105. }
  1106. err = amdgpu_amdkfd_gpuvm_sync_memory(dev->adev, (struct kgd_mem *) mem, true);
  1107. if (err) {
  1108. pr_debug("Sync memory failed, wait interrupted by user signal\n");
  1109. goto sync_memory_failed;
  1110. }
  1111. mutex_unlock(&p->mutex);
  1112. /* Flush TLBs after waiting for the page table updates to complete */
  1113. for (i = 0; i < args->n_devices; i++) {
  1114. peer_pdd = kfd_process_device_data_by_id(p, devices_arr[i]);
  1115. if (WARN_ON_ONCE(!peer_pdd))
  1116. continue;
  1117. kfd_flush_tlb(peer_pdd, TLB_FLUSH_LEGACY);
  1118. }
  1119. kfree(devices_arr);
  1120. return err;
  1121. get_process_device_data_failed:
  1122. bind_process_to_device_failed:
  1123. get_mem_obj_from_handle_failed:
  1124. map_memory_to_gpu_failed:
  1125. sync_memory_failed:
  1126. mutex_unlock(&p->mutex);
  1127. copy_from_user_failed:
  1128. kfree(devices_arr);
  1129. return err;
  1130. }
  1131. static int kfd_ioctl_unmap_memory_from_gpu(struct file *filep,
  1132. struct kfd_process *p, void *data)
  1133. {
  1134. struct kfd_ioctl_unmap_memory_from_gpu_args *args = data;
  1135. struct kfd_process_device *pdd, *peer_pdd;
  1136. void *mem;
  1137. long err = 0;
  1138. uint32_t *devices_arr = NULL, i;
  1139. bool flush_tlb;
  1140. if (!args->n_devices) {
  1141. pr_debug("Device IDs array empty\n");
  1142. return -EINVAL;
  1143. }
  1144. if (args->n_success > args->n_devices) {
  1145. pr_debug("n_success exceeds n_devices\n");
  1146. return -EINVAL;
  1147. }
  1148. devices_arr = kmalloc_array(args->n_devices, sizeof(*devices_arr),
  1149. GFP_KERNEL);
  1150. if (!devices_arr)
  1151. return -ENOMEM;
  1152. err = copy_from_user(devices_arr,
  1153. (void __user *)args->device_ids_array_ptr,
  1154. args->n_devices * sizeof(*devices_arr));
  1155. if (err != 0) {
  1156. err = -EFAULT;
  1157. goto copy_from_user_failed;
  1158. }
  1159. mutex_lock(&p->mutex);
  1160. pdd = kfd_process_device_data_by_id(p, GET_GPU_ID(args->handle));
  1161. if (!pdd) {
  1162. err = -EINVAL;
  1163. goto bind_process_to_device_failed;
  1164. }
  1165. mem = kfd_process_device_translate_handle(pdd,
  1166. GET_IDR_HANDLE(args->handle));
  1167. if (!mem) {
  1168. err = -ENOMEM;
  1169. goto get_mem_obj_from_handle_failed;
  1170. }
  1171. for (i = args->n_success; i < args->n_devices; i++) {
  1172. peer_pdd = kfd_process_device_data_by_id(p, devices_arr[i]);
  1173. if (!peer_pdd) {
  1174. err = -EINVAL;
  1175. goto get_mem_obj_from_handle_failed;
  1176. }
  1177. err = amdgpu_amdkfd_gpuvm_unmap_memory_from_gpu(
  1178. peer_pdd->dev->adev, (struct kgd_mem *)mem, peer_pdd->drm_priv);
  1179. if (err) {
  1180. pr_debug("Failed to unmap from gpu %d/%d\n", i, args->n_devices);
  1181. goto unmap_memory_from_gpu_failed;
  1182. }
  1183. args->n_success = i+1;
  1184. }
  1185. flush_tlb = kfd_flush_tlb_after_unmap(pdd->dev->kfd);
  1186. if (flush_tlb) {
  1187. err = amdgpu_amdkfd_gpuvm_sync_memory(pdd->dev->adev,
  1188. (struct kgd_mem *) mem, true);
  1189. if (err) {
  1190. pr_debug("Sync memory failed, wait interrupted by user signal\n");
  1191. goto sync_memory_failed;
  1192. }
  1193. }
  1194. /* Flush TLBs after waiting for the page table updates to complete */
  1195. for (i = 0; i < args->n_devices; i++) {
  1196. peer_pdd = kfd_process_device_data_by_id(p, devices_arr[i]);
  1197. if (WARN_ON_ONCE(!peer_pdd))
  1198. continue;
  1199. if (flush_tlb)
  1200. kfd_flush_tlb(peer_pdd, TLB_FLUSH_HEAVYWEIGHT);
  1201. /* Remove dma mapping after tlb flush to avoid IO_PAGE_FAULT */
  1202. err = amdgpu_amdkfd_gpuvm_dmaunmap_mem(mem, peer_pdd->drm_priv);
  1203. if (err)
  1204. goto sync_memory_failed;
  1205. }
  1206. mutex_unlock(&p->mutex);
  1207. kfree(devices_arr);
  1208. return 0;
  1209. bind_process_to_device_failed:
  1210. get_mem_obj_from_handle_failed:
  1211. unmap_memory_from_gpu_failed:
  1212. sync_memory_failed:
  1213. mutex_unlock(&p->mutex);
  1214. copy_from_user_failed:
  1215. kfree(devices_arr);
  1216. return err;
  1217. }
  1218. static int kfd_ioctl_alloc_queue_gws(struct file *filep,
  1219. struct kfd_process *p, void *data)
  1220. {
  1221. int retval;
  1222. struct kfd_ioctl_alloc_queue_gws_args *args = data;
  1223. struct queue *q;
  1224. struct kfd_node *dev;
  1225. mutex_lock(&p->mutex);
  1226. q = pqm_get_user_queue(&p->pqm, args->queue_id);
  1227. if (q) {
  1228. dev = q->device;
  1229. } else {
  1230. retval = -EINVAL;
  1231. goto out_unlock;
  1232. }
  1233. if (!dev->gws) {
  1234. retval = -ENODEV;
  1235. goto out_unlock;
  1236. }
  1237. if (dev->dqm->sched_policy == KFD_SCHED_POLICY_NO_HWS) {
  1238. retval = -ENODEV;
  1239. goto out_unlock;
  1240. }
  1241. if (p->debug_trap_enabled && (!kfd_dbg_has_gws_support(dev) ||
  1242. kfd_dbg_has_cwsr_workaround(dev))) {
  1243. retval = -EBUSY;
  1244. goto out_unlock;
  1245. }
  1246. retval = pqm_set_gws(&p->pqm, args->queue_id, args->num_gws ? dev->gws : NULL);
  1247. mutex_unlock(&p->mutex);
  1248. args->first_gws = 0;
  1249. return retval;
  1250. out_unlock:
  1251. mutex_unlock(&p->mutex);
  1252. return retval;
  1253. }
  1254. static int kfd_ioctl_get_dmabuf_info(struct file *filep,
  1255. struct kfd_process *p, void *data)
  1256. {
  1257. struct kfd_ioctl_get_dmabuf_info_args *args = data;
  1258. struct kfd_node *dev = NULL;
  1259. struct amdgpu_device *dmabuf_adev;
  1260. void *metadata_buffer = NULL;
  1261. uint32_t flags;
  1262. int8_t xcp_id;
  1263. unsigned int i;
  1264. int r;
  1265. /* Find a KFD GPU device that supports the get_dmabuf_info query */
  1266. for (i = 0; kfd_topology_enum_kfd_devices(i, &dev) == 0; i++)
  1267. if (dev && !kfd_devcgroup_check_permission(dev))
  1268. break;
  1269. if (!dev)
  1270. return -EINVAL;
  1271. if (args->metadata_ptr) {
  1272. metadata_buffer = kzalloc(args->metadata_size, GFP_KERNEL);
  1273. if (!metadata_buffer)
  1274. return -ENOMEM;
  1275. }
  1276. /* Get dmabuf info from KGD */
  1277. r = amdgpu_amdkfd_get_dmabuf_info(dev->adev, args->dmabuf_fd,
  1278. &dmabuf_adev, &args->size,
  1279. metadata_buffer, args->metadata_size,
  1280. &args->metadata_size, &flags, &xcp_id);
  1281. if (r)
  1282. goto exit;
  1283. if (xcp_id >= 0)
  1284. args->gpu_id = dmabuf_adev->kfd.dev->nodes[xcp_id]->id;
  1285. else
  1286. args->gpu_id = dev->id;
  1287. args->flags = flags;
  1288. /* Copy metadata buffer to user mode */
  1289. if (metadata_buffer) {
  1290. r = copy_to_user((void __user *)args->metadata_ptr,
  1291. metadata_buffer, args->metadata_size);
  1292. if (r != 0)
  1293. r = -EFAULT;
  1294. }
  1295. exit:
  1296. kfree(metadata_buffer);
  1297. return r;
  1298. }
  1299. static int kfd_ioctl_import_dmabuf(struct file *filep,
  1300. struct kfd_process *p, void *data)
  1301. {
  1302. struct kfd_ioctl_import_dmabuf_args *args = data;
  1303. struct kfd_process_device *pdd;
  1304. int idr_handle;
  1305. uint64_t size;
  1306. void *mem;
  1307. int r;
  1308. mutex_lock(&p->mutex);
  1309. pdd = kfd_process_device_data_by_id(p, args->gpu_id);
  1310. if (!pdd) {
  1311. r = -EINVAL;
  1312. goto err_unlock;
  1313. }
  1314. pdd = kfd_bind_process_to_device(pdd->dev, p);
  1315. if (IS_ERR(pdd)) {
  1316. r = PTR_ERR(pdd);
  1317. goto err_unlock;
  1318. }
  1319. r = amdgpu_amdkfd_gpuvm_import_dmabuf_fd(pdd->dev->adev, args->dmabuf_fd,
  1320. args->va_addr, pdd->drm_priv,
  1321. (struct kgd_mem **)&mem, &size,
  1322. NULL);
  1323. if (r)
  1324. goto err_unlock;
  1325. idr_handle = kfd_process_device_create_obj_handle(pdd, mem);
  1326. if (idr_handle < 0) {
  1327. r = -EFAULT;
  1328. goto err_free;
  1329. }
  1330. mutex_unlock(&p->mutex);
  1331. args->handle = MAKE_HANDLE(args->gpu_id, idr_handle);
  1332. return 0;
  1333. err_free:
  1334. amdgpu_amdkfd_gpuvm_free_memory_of_gpu(pdd->dev->adev, (struct kgd_mem *)mem,
  1335. pdd->drm_priv, NULL);
  1336. err_unlock:
  1337. mutex_unlock(&p->mutex);
  1338. return r;
  1339. }
  1340. static int kfd_ioctl_export_dmabuf(struct file *filep,
  1341. struct kfd_process *p, void *data)
  1342. {
  1343. struct kfd_ioctl_export_dmabuf_args *args = data;
  1344. struct kfd_process_device *pdd;
  1345. struct dma_buf *dmabuf;
  1346. struct kfd_node *dev;
  1347. void *mem;
  1348. int ret = 0;
  1349. dev = kfd_device_by_id(GET_GPU_ID(args->handle));
  1350. if (!dev)
  1351. return -EINVAL;
  1352. mutex_lock(&p->mutex);
  1353. pdd = kfd_get_process_device_data(dev, p);
  1354. if (!pdd) {
  1355. ret = -EINVAL;
  1356. goto err_unlock;
  1357. }
  1358. mem = kfd_process_device_translate_handle(pdd,
  1359. GET_IDR_HANDLE(args->handle));
  1360. if (!mem) {
  1361. ret = -EINVAL;
  1362. goto err_unlock;
  1363. }
  1364. ret = amdgpu_amdkfd_gpuvm_export_dmabuf(mem, &dmabuf);
  1365. mutex_unlock(&p->mutex);
  1366. if (ret)
  1367. goto err_out;
  1368. ret = dma_buf_fd(dmabuf, args->flags);
  1369. if (ret < 0) {
  1370. dma_buf_put(dmabuf);
  1371. goto err_out;
  1372. }
  1373. /* dma_buf_fd assigns the reference count to the fd, no need to
  1374. * put the reference here.
  1375. */
  1376. args->dmabuf_fd = ret;
  1377. return 0;
  1378. err_unlock:
  1379. mutex_unlock(&p->mutex);
  1380. err_out:
  1381. return ret;
  1382. }
  1383. /* Handle requests for watching SMI events */
  1384. static int kfd_ioctl_smi_events(struct file *filep,
  1385. struct kfd_process *p, void *data)
  1386. {
  1387. struct kfd_ioctl_smi_events_args *args = data;
  1388. struct kfd_process_device *pdd;
  1389. mutex_lock(&p->mutex);
  1390. pdd = kfd_process_device_data_by_id(p, args->gpuid);
  1391. mutex_unlock(&p->mutex);
  1392. if (!pdd)
  1393. return -EINVAL;
  1394. return kfd_smi_event_open(pdd->dev, &args->anon_fd);
  1395. }
  1396. #if IS_ENABLED(CONFIG_HSA_AMD_SVM)
  1397. static int kfd_ioctl_set_xnack_mode(struct file *filep,
  1398. struct kfd_process *p, void *data)
  1399. {
  1400. struct kfd_ioctl_set_xnack_mode_args *args = data;
  1401. int r = 0;
  1402. mutex_lock(&p->mutex);
  1403. if (args->xnack_enabled >= 0) {
  1404. if (!list_empty(&p->pqm.queues)) {
  1405. pr_debug("Process has user queues running\n");
  1406. r = -EBUSY;
  1407. goto out_unlock;
  1408. }
  1409. if (p->xnack_enabled == args->xnack_enabled)
  1410. goto out_unlock;
  1411. if (args->xnack_enabled && !kfd_process_xnack_mode(p, true)) {
  1412. r = -EPERM;
  1413. goto out_unlock;
  1414. }
  1415. r = svm_range_switch_xnack_reserve_mem(p, args->xnack_enabled);
  1416. } else {
  1417. args->xnack_enabled = p->xnack_enabled;
  1418. }
  1419. out_unlock:
  1420. mutex_unlock(&p->mutex);
  1421. return r;
  1422. }
  1423. static int kfd_ioctl_svm(struct file *filep, struct kfd_process *p, void *data)
  1424. {
  1425. struct kfd_ioctl_svm_args *args = data;
  1426. int r = 0;
  1427. if (p->context_id != KFD_CONTEXT_ID_PRIMARY) {
  1428. pr_debug("SVM ioctl not supported on non-primary kfd process\n");
  1429. return -EOPNOTSUPP;
  1430. }
  1431. pr_debug("start 0x%llx size 0x%llx op 0x%x nattr 0x%x\n",
  1432. args->start_addr, args->size, args->op, args->nattr);
  1433. if ((args->start_addr & ~PAGE_MASK) || (args->size & ~PAGE_MASK))
  1434. return -EINVAL;
  1435. if (!args->start_addr || !args->size)
  1436. return -EINVAL;
  1437. r = svm_ioctl(p, args->op, args->start_addr, args->size, args->nattr,
  1438. args->attrs);
  1439. return r;
  1440. }
  1441. #else
  1442. static int kfd_ioctl_set_xnack_mode(struct file *filep,
  1443. struct kfd_process *p, void *data)
  1444. {
  1445. return -EPERM;
  1446. }
  1447. static int kfd_ioctl_svm(struct file *filep, struct kfd_process *p, void *data)
  1448. {
  1449. return -EPERM;
  1450. }
  1451. #endif
  1452. static int criu_checkpoint_process(struct kfd_process *p,
  1453. uint8_t __user *user_priv_data,
  1454. uint64_t *priv_offset)
  1455. {
  1456. struct kfd_criu_process_priv_data process_priv;
  1457. int ret;
  1458. memset(&process_priv, 0, sizeof(process_priv));
  1459. process_priv.version = KFD_CRIU_PRIV_VERSION;
  1460. /* For CR, we don't consider negative xnack mode which is used for
  1461. * querying without changing it, here 0 simply means disabled and 1
  1462. * means enabled so retry for finding a valid PTE.
  1463. */
  1464. process_priv.xnack_mode = p->xnack_enabled ? 1 : 0;
  1465. ret = copy_to_user(user_priv_data + *priv_offset,
  1466. &process_priv, sizeof(process_priv));
  1467. if (ret) {
  1468. pr_err("Failed to copy process information to user\n");
  1469. ret = -EFAULT;
  1470. }
  1471. *priv_offset += sizeof(process_priv);
  1472. return ret;
  1473. }
  1474. static int criu_checkpoint_devices(struct kfd_process *p,
  1475. uint32_t num_devices,
  1476. uint8_t __user *user_addr,
  1477. uint8_t __user *user_priv_data,
  1478. uint64_t *priv_offset)
  1479. {
  1480. struct kfd_criu_device_priv_data *device_priv = NULL;
  1481. struct kfd_criu_device_bucket *device_buckets = NULL;
  1482. int ret = 0, i;
  1483. device_buckets = kvzalloc(num_devices * sizeof(*device_buckets), GFP_KERNEL);
  1484. if (!device_buckets) {
  1485. ret = -ENOMEM;
  1486. goto exit;
  1487. }
  1488. device_priv = kvzalloc(num_devices * sizeof(*device_priv), GFP_KERNEL);
  1489. if (!device_priv) {
  1490. ret = -ENOMEM;
  1491. goto exit;
  1492. }
  1493. for (i = 0; i < num_devices; i++) {
  1494. struct kfd_process_device *pdd = p->pdds[i];
  1495. device_buckets[i].user_gpu_id = pdd->user_gpu_id;
  1496. device_buckets[i].actual_gpu_id = pdd->dev->id;
  1497. /*
  1498. * priv_data does not contain useful information for now and is reserved for
  1499. * future use, so we do not set its contents.
  1500. */
  1501. }
  1502. ret = copy_to_user(user_addr, device_buckets, num_devices * sizeof(*device_buckets));
  1503. if (ret) {
  1504. pr_err("Failed to copy device information to user\n");
  1505. ret = -EFAULT;
  1506. goto exit;
  1507. }
  1508. ret = copy_to_user(user_priv_data + *priv_offset,
  1509. device_priv,
  1510. num_devices * sizeof(*device_priv));
  1511. if (ret) {
  1512. pr_err("Failed to copy device information to user\n");
  1513. ret = -EFAULT;
  1514. }
  1515. *priv_offset += num_devices * sizeof(*device_priv);
  1516. exit:
  1517. kvfree(device_buckets);
  1518. kvfree(device_priv);
  1519. return ret;
  1520. }
  1521. static uint32_t get_process_num_bos(struct kfd_process *p)
  1522. {
  1523. uint32_t num_of_bos = 0;
  1524. int i;
  1525. /* Run over all PDDs of the process */
  1526. for (i = 0; i < p->n_pdds; i++) {
  1527. struct kfd_process_device *pdd = p->pdds[i];
  1528. void *mem;
  1529. int id;
  1530. idr_for_each_entry(&pdd->alloc_idr, mem, id) {
  1531. struct kgd_mem *kgd_mem = (struct kgd_mem *)mem;
  1532. if (!kgd_mem->va || kgd_mem->va > pdd->gpuvm_base)
  1533. num_of_bos++;
  1534. }
  1535. }
  1536. return num_of_bos;
  1537. }
  1538. static int criu_get_prime_handle(struct kgd_mem *mem,
  1539. int flags, u32 *shared_fd,
  1540. struct file **file)
  1541. {
  1542. struct dma_buf *dmabuf;
  1543. int ret;
  1544. ret = amdgpu_amdkfd_gpuvm_export_dmabuf(mem, &dmabuf);
  1545. if (ret) {
  1546. pr_err("dmabuf export failed for the BO\n");
  1547. return ret;
  1548. }
  1549. ret = get_unused_fd_flags(flags);
  1550. if (ret < 0) {
  1551. pr_err("dmabuf create fd failed, ret:%d\n", ret);
  1552. goto out_free_dmabuf;
  1553. }
  1554. *shared_fd = ret;
  1555. *file = dmabuf->file;
  1556. return 0;
  1557. out_free_dmabuf:
  1558. dma_buf_put(dmabuf);
  1559. return ret;
  1560. }
  1561. static void commit_files(struct file **files,
  1562. struct kfd_criu_bo_bucket *bo_buckets,
  1563. unsigned int count,
  1564. int err)
  1565. {
  1566. while (count--) {
  1567. struct file *file = files[count];
  1568. if (!file)
  1569. continue;
  1570. if (err) {
  1571. fput(file);
  1572. put_unused_fd(bo_buckets[count].dmabuf_fd);
  1573. } else {
  1574. fd_install(bo_buckets[count].dmabuf_fd, file);
  1575. }
  1576. }
  1577. }
  1578. static int criu_checkpoint_bos(struct kfd_process *p,
  1579. uint32_t num_bos,
  1580. uint8_t __user *user_bos,
  1581. uint8_t __user *user_priv_data,
  1582. uint64_t *priv_offset)
  1583. {
  1584. struct kfd_criu_bo_bucket *bo_buckets;
  1585. struct kfd_criu_bo_priv_data *bo_privs;
  1586. struct file **files = NULL;
  1587. int ret = 0, pdd_index, bo_index = 0, id;
  1588. void *mem;
  1589. bo_buckets = kvzalloc(num_bos * sizeof(*bo_buckets), GFP_KERNEL);
  1590. if (!bo_buckets)
  1591. return -ENOMEM;
  1592. bo_privs = kvzalloc(num_bos * sizeof(*bo_privs), GFP_KERNEL);
  1593. if (!bo_privs) {
  1594. ret = -ENOMEM;
  1595. goto exit;
  1596. }
  1597. files = kvzalloc(num_bos * sizeof(struct file *), GFP_KERNEL);
  1598. if (!files) {
  1599. ret = -ENOMEM;
  1600. goto exit;
  1601. }
  1602. for (pdd_index = 0; pdd_index < p->n_pdds; pdd_index++) {
  1603. struct kfd_process_device *pdd = p->pdds[pdd_index];
  1604. struct amdgpu_bo *dumper_bo;
  1605. struct kgd_mem *kgd_mem;
  1606. idr_for_each_entry(&pdd->alloc_idr, mem, id) {
  1607. struct kfd_criu_bo_bucket *bo_bucket;
  1608. struct kfd_criu_bo_priv_data *bo_priv;
  1609. int i, dev_idx = 0;
  1610. kgd_mem = (struct kgd_mem *)mem;
  1611. dumper_bo = kgd_mem->bo;
  1612. /* Skip checkpointing BOs that are used for Trap handler
  1613. * code and state. Currently, these BOs have a VA that
  1614. * is less GPUVM Base
  1615. */
  1616. if (kgd_mem->va && kgd_mem->va <= pdd->gpuvm_base)
  1617. continue;
  1618. bo_bucket = &bo_buckets[bo_index];
  1619. bo_priv = &bo_privs[bo_index];
  1620. bo_bucket->gpu_id = pdd->user_gpu_id;
  1621. bo_bucket->addr = (uint64_t)kgd_mem->va;
  1622. bo_bucket->size = amdgpu_bo_size(dumper_bo);
  1623. bo_bucket->alloc_flags = (uint32_t)kgd_mem->alloc_flags;
  1624. bo_priv->idr_handle = id;
  1625. if (bo_bucket->alloc_flags & KFD_IOC_ALLOC_MEM_FLAGS_USERPTR) {
  1626. ret = amdgpu_ttm_tt_get_userptr(&dumper_bo->tbo,
  1627. &bo_priv->user_addr);
  1628. if (ret) {
  1629. pr_err("Failed to obtain user address for user-pointer bo\n");
  1630. goto exit;
  1631. }
  1632. }
  1633. if (bo_bucket->alloc_flags
  1634. & (KFD_IOC_ALLOC_MEM_FLAGS_VRAM | KFD_IOC_ALLOC_MEM_FLAGS_GTT)) {
  1635. ret = criu_get_prime_handle(kgd_mem,
  1636. bo_bucket->alloc_flags &
  1637. KFD_IOC_ALLOC_MEM_FLAGS_WRITABLE ? DRM_RDWR : 0,
  1638. &bo_bucket->dmabuf_fd, &files[bo_index]);
  1639. if (ret)
  1640. goto exit;
  1641. } else {
  1642. bo_bucket->dmabuf_fd = KFD_INVALID_FD;
  1643. }
  1644. if (bo_bucket->alloc_flags & KFD_IOC_ALLOC_MEM_FLAGS_DOORBELL)
  1645. bo_bucket->offset = KFD_MMAP_TYPE_DOORBELL |
  1646. KFD_MMAP_GPU_ID(pdd->dev->id);
  1647. else if (bo_bucket->alloc_flags &
  1648. KFD_IOC_ALLOC_MEM_FLAGS_MMIO_REMAP)
  1649. bo_bucket->offset = KFD_MMAP_TYPE_MMIO |
  1650. KFD_MMAP_GPU_ID(pdd->dev->id);
  1651. else
  1652. bo_bucket->offset = amdgpu_bo_mmap_offset(dumper_bo);
  1653. for (i = 0; i < p->n_pdds; i++) {
  1654. if (amdgpu_amdkfd_bo_mapped_to_dev(p->pdds[i]->drm_priv, kgd_mem))
  1655. bo_priv->mapped_gpuids[dev_idx++] = p->pdds[i]->user_gpu_id;
  1656. }
  1657. pr_debug("bo_size = 0x%llx, bo_addr = 0x%llx bo_offset = 0x%llx\n"
  1658. "gpu_id = 0x%x alloc_flags = 0x%x idr_handle = 0x%x",
  1659. bo_bucket->size,
  1660. bo_bucket->addr,
  1661. bo_bucket->offset,
  1662. bo_bucket->gpu_id,
  1663. bo_bucket->alloc_flags,
  1664. bo_priv->idr_handle);
  1665. bo_index++;
  1666. }
  1667. }
  1668. ret = copy_to_user(user_bos, bo_buckets, num_bos * sizeof(*bo_buckets));
  1669. if (ret) {
  1670. pr_err("Failed to copy BO information to user\n");
  1671. ret = -EFAULT;
  1672. goto exit;
  1673. }
  1674. ret = copy_to_user(user_priv_data + *priv_offset, bo_privs, num_bos * sizeof(*bo_privs));
  1675. if (ret) {
  1676. pr_err("Failed to copy BO priv information to user\n");
  1677. ret = -EFAULT;
  1678. goto exit;
  1679. }
  1680. *priv_offset += num_bos * sizeof(*bo_privs);
  1681. exit:
  1682. commit_files(files, bo_buckets, bo_index, ret);
  1683. kvfree(files);
  1684. kvfree(bo_buckets);
  1685. kvfree(bo_privs);
  1686. return ret;
  1687. }
  1688. static int criu_get_process_object_info(struct kfd_process *p,
  1689. uint32_t *num_devices,
  1690. uint32_t *num_bos,
  1691. uint32_t *num_objects,
  1692. uint64_t *objs_priv_size)
  1693. {
  1694. uint64_t queues_priv_data_size, svm_priv_data_size, priv_size;
  1695. uint32_t num_queues, num_events, num_svm_ranges;
  1696. int ret;
  1697. *num_devices = p->n_pdds;
  1698. *num_bos = get_process_num_bos(p);
  1699. ret = kfd_process_get_queue_info(p, &num_queues, &queues_priv_data_size);
  1700. if (ret)
  1701. return ret;
  1702. num_events = kfd_get_num_events(p);
  1703. svm_range_get_info(p, &num_svm_ranges, &svm_priv_data_size);
  1704. *num_objects = num_queues + num_events + num_svm_ranges;
  1705. if (objs_priv_size) {
  1706. priv_size = sizeof(struct kfd_criu_process_priv_data);
  1707. priv_size += *num_devices * sizeof(struct kfd_criu_device_priv_data);
  1708. priv_size += *num_bos * sizeof(struct kfd_criu_bo_priv_data);
  1709. priv_size += queues_priv_data_size;
  1710. priv_size += num_events * sizeof(struct kfd_criu_event_priv_data);
  1711. priv_size += svm_priv_data_size;
  1712. *objs_priv_size = priv_size;
  1713. }
  1714. return 0;
  1715. }
  1716. static int criu_checkpoint(struct file *filep,
  1717. struct kfd_process *p,
  1718. struct kfd_ioctl_criu_args *args)
  1719. {
  1720. int ret;
  1721. uint32_t num_devices, num_bos, num_objects;
  1722. uint64_t priv_size, priv_offset = 0, bo_priv_offset;
  1723. if (!args->devices || !args->bos || !args->priv_data)
  1724. return -EINVAL;
  1725. mutex_lock(&p->mutex);
  1726. if (!p->n_pdds) {
  1727. pr_err("No pdd for given process\n");
  1728. ret = -ENODEV;
  1729. goto exit_unlock;
  1730. }
  1731. /* Confirm all process queues are evicted */
  1732. if (!p->queues_paused) {
  1733. pr_err("Cannot dump process when queues are not in evicted state\n");
  1734. /* CRIU plugin did not call op PROCESS_INFO before checkpointing */
  1735. ret = -EINVAL;
  1736. goto exit_unlock;
  1737. }
  1738. ret = criu_get_process_object_info(p, &num_devices, &num_bos, &num_objects, &priv_size);
  1739. if (ret)
  1740. goto exit_unlock;
  1741. if (num_devices != args->num_devices ||
  1742. num_bos != args->num_bos ||
  1743. num_objects != args->num_objects ||
  1744. priv_size != args->priv_data_size) {
  1745. ret = -EINVAL;
  1746. goto exit_unlock;
  1747. }
  1748. /* each function will store private data inside priv_data and adjust priv_offset */
  1749. ret = criu_checkpoint_process(p, (uint8_t __user *)args->priv_data, &priv_offset);
  1750. if (ret)
  1751. goto exit_unlock;
  1752. ret = criu_checkpoint_devices(p, num_devices, (uint8_t __user *)args->devices,
  1753. (uint8_t __user *)args->priv_data, &priv_offset);
  1754. if (ret)
  1755. goto exit_unlock;
  1756. /* Leave room for BOs in the private data. They need to be restored
  1757. * before events, but we checkpoint them last to simplify the error
  1758. * handling.
  1759. */
  1760. bo_priv_offset = priv_offset;
  1761. priv_offset += num_bos * sizeof(struct kfd_criu_bo_priv_data);
  1762. if (num_objects) {
  1763. ret = kfd_criu_checkpoint_queues(p, (uint8_t __user *)args->priv_data,
  1764. &priv_offset);
  1765. if (ret)
  1766. goto exit_unlock;
  1767. ret = kfd_criu_checkpoint_events(p, (uint8_t __user *)args->priv_data,
  1768. &priv_offset);
  1769. if (ret)
  1770. goto exit_unlock;
  1771. ret = kfd_criu_checkpoint_svm(p, (uint8_t __user *)args->priv_data, &priv_offset);
  1772. if (ret)
  1773. goto exit_unlock;
  1774. }
  1775. /* This must be the last thing in this function that can fail.
  1776. * Otherwise we leak dmabuf file descriptors.
  1777. */
  1778. ret = criu_checkpoint_bos(p, num_bos, (uint8_t __user *)args->bos,
  1779. (uint8_t __user *)args->priv_data, &bo_priv_offset);
  1780. exit_unlock:
  1781. mutex_unlock(&p->mutex);
  1782. if (ret)
  1783. pr_err("Failed to dump CRIU ret:%d\n", ret);
  1784. else
  1785. pr_debug("CRIU dump ret:%d\n", ret);
  1786. return ret;
  1787. }
  1788. static int criu_restore_process(struct kfd_process *p,
  1789. struct kfd_ioctl_criu_args *args,
  1790. uint64_t *priv_offset,
  1791. uint64_t max_priv_data_size)
  1792. {
  1793. int ret = 0;
  1794. struct kfd_criu_process_priv_data process_priv;
  1795. if (*priv_offset + sizeof(process_priv) > max_priv_data_size)
  1796. return -EINVAL;
  1797. ret = copy_from_user(&process_priv,
  1798. (void __user *)(args->priv_data + *priv_offset),
  1799. sizeof(process_priv));
  1800. if (ret) {
  1801. pr_err("Failed to copy process private information from user\n");
  1802. ret = -EFAULT;
  1803. goto exit;
  1804. }
  1805. *priv_offset += sizeof(process_priv);
  1806. if (process_priv.version != KFD_CRIU_PRIV_VERSION) {
  1807. pr_err("Invalid CRIU API version (checkpointed:%d current:%d)\n",
  1808. process_priv.version, KFD_CRIU_PRIV_VERSION);
  1809. return -EINVAL;
  1810. }
  1811. pr_debug("Setting XNACK mode\n");
  1812. if (process_priv.xnack_mode && !kfd_process_xnack_mode(p, true)) {
  1813. pr_err("xnack mode cannot be set\n");
  1814. ret = -EPERM;
  1815. goto exit;
  1816. } else {
  1817. pr_debug("set xnack mode: %d\n", process_priv.xnack_mode);
  1818. p->xnack_enabled = process_priv.xnack_mode;
  1819. }
  1820. exit:
  1821. return ret;
  1822. }
  1823. static int criu_restore_devices(struct kfd_process *p,
  1824. struct kfd_ioctl_criu_args *args,
  1825. uint64_t *priv_offset,
  1826. uint64_t max_priv_data_size)
  1827. {
  1828. struct kfd_criu_device_bucket *device_buckets;
  1829. struct kfd_criu_device_priv_data *device_privs;
  1830. int ret = 0;
  1831. uint32_t i;
  1832. if (args->num_devices != p->n_pdds)
  1833. return -EINVAL;
  1834. if (*priv_offset + (args->num_devices * sizeof(*device_privs)) > max_priv_data_size)
  1835. return -EINVAL;
  1836. device_buckets = kmalloc_objs(*device_buckets, args->num_devices);
  1837. if (!device_buckets)
  1838. return -ENOMEM;
  1839. ret = copy_from_user(device_buckets, (void __user *)args->devices,
  1840. args->num_devices * sizeof(*device_buckets));
  1841. if (ret) {
  1842. pr_err("Failed to copy devices buckets from user\n");
  1843. ret = -EFAULT;
  1844. goto exit;
  1845. }
  1846. for (i = 0; i < args->num_devices; i++) {
  1847. struct kfd_node *dev;
  1848. struct kfd_process_device *pdd;
  1849. struct file *drm_file;
  1850. /* device private data is not currently used */
  1851. if (!device_buckets[i].user_gpu_id) {
  1852. pr_err("Invalid user gpu_id\n");
  1853. ret = -EINVAL;
  1854. goto exit;
  1855. }
  1856. dev = kfd_device_by_id(device_buckets[i].actual_gpu_id);
  1857. if (!dev) {
  1858. pr_err("Failed to find device with gpu_id = %x\n",
  1859. device_buckets[i].actual_gpu_id);
  1860. ret = -EINVAL;
  1861. goto exit;
  1862. }
  1863. pdd = kfd_get_process_device_data(dev, p);
  1864. if (!pdd) {
  1865. pr_err("Failed to get pdd for gpu_id = %x\n",
  1866. device_buckets[i].actual_gpu_id);
  1867. ret = -EINVAL;
  1868. goto exit;
  1869. }
  1870. pdd->user_gpu_id = device_buckets[i].user_gpu_id;
  1871. drm_file = fget(device_buckets[i].drm_fd);
  1872. if (!drm_file) {
  1873. pr_err("Invalid render node file descriptor sent from plugin (%d)\n",
  1874. device_buckets[i].drm_fd);
  1875. ret = -EINVAL;
  1876. goto exit;
  1877. }
  1878. if (pdd->drm_file) {
  1879. ret = -EINVAL;
  1880. goto exit;
  1881. }
  1882. /* create the vm using render nodes for kfd pdd */
  1883. if (kfd_process_device_init_vm(pdd, drm_file)) {
  1884. pr_err("could not init vm for given pdd\n");
  1885. /* On success, the PDD keeps the drm_file reference */
  1886. fput(drm_file);
  1887. ret = -EINVAL;
  1888. goto exit;
  1889. }
  1890. /*
  1891. * pdd now already has the vm bound to render node so below api won't create a new
  1892. * exclusive kfd mapping but use existing one with renderDXXX but is still needed
  1893. * for iommu v2 binding and runtime pm.
  1894. */
  1895. pdd = kfd_bind_process_to_device(dev, p);
  1896. if (IS_ERR(pdd)) {
  1897. ret = PTR_ERR(pdd);
  1898. goto exit;
  1899. }
  1900. if (!pdd->qpd.proc_doorbells) {
  1901. ret = kfd_alloc_process_doorbells(dev->kfd, pdd);
  1902. if (ret)
  1903. goto exit;
  1904. }
  1905. }
  1906. /*
  1907. * We are not copying device private data from user as we are not using the data for now,
  1908. * but we still adjust for its private data.
  1909. */
  1910. *priv_offset += args->num_devices * sizeof(*device_privs);
  1911. exit:
  1912. kfree(device_buckets);
  1913. return ret;
  1914. }
  1915. static int criu_restore_memory_of_gpu(struct kfd_process_device *pdd,
  1916. struct kfd_criu_bo_bucket *bo_bucket,
  1917. struct kfd_criu_bo_priv_data *bo_priv,
  1918. struct kgd_mem **kgd_mem)
  1919. {
  1920. int idr_handle;
  1921. int ret;
  1922. const bool criu_resume = true;
  1923. u64 offset;
  1924. if (bo_bucket->alloc_flags & KFD_IOC_ALLOC_MEM_FLAGS_DOORBELL) {
  1925. if (bo_bucket->size !=
  1926. kfd_doorbell_process_slice(pdd->dev->kfd))
  1927. return -EINVAL;
  1928. offset = kfd_get_process_doorbells(pdd);
  1929. if (!offset)
  1930. return -ENOMEM;
  1931. } else if (bo_bucket->alloc_flags & KFD_IOC_ALLOC_MEM_FLAGS_MMIO_REMAP) {
  1932. /* MMIO BOs need remapped bus address */
  1933. if (bo_bucket->size != PAGE_SIZE) {
  1934. pr_err("Invalid page size\n");
  1935. return -EINVAL;
  1936. }
  1937. offset = pdd->dev->adev->rmmio_remap.bus_addr;
  1938. if (!offset || (PAGE_SIZE > 4096)) {
  1939. pr_err("amdgpu_amdkfd_get_mmio_remap_phys_addr failed\n");
  1940. return -ENOMEM;
  1941. }
  1942. } else if (bo_bucket->alloc_flags & KFD_IOC_ALLOC_MEM_FLAGS_USERPTR) {
  1943. offset = bo_priv->user_addr;
  1944. }
  1945. /* Create the BO */
  1946. ret = amdgpu_amdkfd_gpuvm_alloc_memory_of_gpu(pdd->dev->adev, bo_bucket->addr,
  1947. bo_bucket->size, pdd->drm_priv, kgd_mem,
  1948. &offset, bo_bucket->alloc_flags, criu_resume);
  1949. if (ret) {
  1950. pr_err("Could not create the BO\n");
  1951. return ret;
  1952. }
  1953. pr_debug("New BO created: size:0x%llx addr:0x%llx offset:0x%llx\n",
  1954. bo_bucket->size, bo_bucket->addr, offset);
  1955. /* Restore previous IDR handle */
  1956. pr_debug("Restoring old IDR handle for the BO");
  1957. idr_handle = idr_alloc(&pdd->alloc_idr, *kgd_mem, bo_priv->idr_handle,
  1958. bo_priv->idr_handle + 1, GFP_KERNEL);
  1959. if (idr_handle < 0) {
  1960. pr_err("Could not allocate idr\n");
  1961. amdgpu_amdkfd_gpuvm_free_memory_of_gpu(pdd->dev->adev, *kgd_mem, pdd->drm_priv,
  1962. NULL);
  1963. return -ENOMEM;
  1964. }
  1965. if (bo_bucket->alloc_flags & KFD_IOC_ALLOC_MEM_FLAGS_DOORBELL)
  1966. bo_bucket->restored_offset = KFD_MMAP_TYPE_DOORBELL | KFD_MMAP_GPU_ID(pdd->dev->id);
  1967. if (bo_bucket->alloc_flags & KFD_IOC_ALLOC_MEM_FLAGS_MMIO_REMAP) {
  1968. bo_bucket->restored_offset = KFD_MMAP_TYPE_MMIO | KFD_MMAP_GPU_ID(pdd->dev->id);
  1969. } else if (bo_bucket->alloc_flags & KFD_IOC_ALLOC_MEM_FLAGS_GTT) {
  1970. bo_bucket->restored_offset = offset;
  1971. } else if (bo_bucket->alloc_flags & KFD_IOC_ALLOC_MEM_FLAGS_VRAM) {
  1972. bo_bucket->restored_offset = offset;
  1973. /* Update the VRAM usage count */
  1974. atomic64_add(bo_bucket->size, &pdd->vram_usage);
  1975. }
  1976. return 0;
  1977. }
  1978. static int criu_restore_bo(struct kfd_process *p,
  1979. struct kfd_criu_bo_bucket *bo_bucket,
  1980. struct kfd_criu_bo_priv_data *bo_priv,
  1981. struct file **file)
  1982. {
  1983. struct kfd_process_device *pdd;
  1984. struct kgd_mem *kgd_mem;
  1985. int ret;
  1986. int j;
  1987. pr_debug("Restoring BO size:0x%llx addr:0x%llx gpu_id:0x%x flags:0x%x idr_handle:0x%x\n",
  1988. bo_bucket->size, bo_bucket->addr, bo_bucket->gpu_id, bo_bucket->alloc_flags,
  1989. bo_priv->idr_handle);
  1990. pdd = kfd_process_device_data_by_id(p, bo_bucket->gpu_id);
  1991. if (!pdd) {
  1992. pr_err("Failed to get pdd\n");
  1993. return -ENODEV;
  1994. }
  1995. ret = criu_restore_memory_of_gpu(pdd, bo_bucket, bo_priv, &kgd_mem);
  1996. if (ret)
  1997. return ret;
  1998. /* now map these BOs to GPU/s */
  1999. for (j = 0; j < p->n_pdds; j++) {
  2000. struct kfd_node *peer;
  2001. struct kfd_process_device *peer_pdd;
  2002. if (!bo_priv->mapped_gpuids[j])
  2003. break;
  2004. peer_pdd = kfd_process_device_data_by_id(p, bo_priv->mapped_gpuids[j]);
  2005. if (!peer_pdd)
  2006. return -EINVAL;
  2007. peer = peer_pdd->dev;
  2008. peer_pdd = kfd_bind_process_to_device(peer, p);
  2009. if (IS_ERR(peer_pdd))
  2010. return PTR_ERR(peer_pdd);
  2011. ret = amdgpu_amdkfd_gpuvm_map_memory_to_gpu(peer->adev, kgd_mem,
  2012. peer_pdd->drm_priv);
  2013. if (ret) {
  2014. pr_err("Failed to map to gpu %d/%d\n", j, p->n_pdds);
  2015. return ret;
  2016. }
  2017. }
  2018. pr_debug("map memory was successful for the BO\n");
  2019. /* create the dmabuf object and export the bo */
  2020. if (bo_bucket->alloc_flags
  2021. & (KFD_IOC_ALLOC_MEM_FLAGS_VRAM | KFD_IOC_ALLOC_MEM_FLAGS_GTT)) {
  2022. ret = criu_get_prime_handle(kgd_mem, DRM_RDWR,
  2023. &bo_bucket->dmabuf_fd, file);
  2024. if (ret)
  2025. return ret;
  2026. } else {
  2027. bo_bucket->dmabuf_fd = KFD_INVALID_FD;
  2028. }
  2029. return 0;
  2030. }
  2031. static int criu_restore_bos(struct kfd_process *p,
  2032. struct kfd_ioctl_criu_args *args,
  2033. uint64_t *priv_offset,
  2034. uint64_t max_priv_data_size)
  2035. {
  2036. struct kfd_criu_bo_bucket *bo_buckets = NULL;
  2037. struct kfd_criu_bo_priv_data *bo_privs = NULL;
  2038. struct file **files = NULL;
  2039. int ret = 0;
  2040. uint32_t i = 0;
  2041. if (*priv_offset + (args->num_bos * sizeof(*bo_privs)) > max_priv_data_size)
  2042. return -EINVAL;
  2043. /* Prevent MMU notifications until stage-4 IOCTL (CRIU_RESUME) is received */
  2044. amdgpu_amdkfd_block_mmu_notifications(p->kgd_process_info);
  2045. bo_buckets = kvmalloc_objs(*bo_buckets, args->num_bos);
  2046. if (!bo_buckets)
  2047. return -ENOMEM;
  2048. files = kvzalloc(args->num_bos * sizeof(struct file *), GFP_KERNEL);
  2049. if (!files) {
  2050. ret = -ENOMEM;
  2051. goto exit;
  2052. }
  2053. ret = copy_from_user(bo_buckets, (void __user *)args->bos,
  2054. args->num_bos * sizeof(*bo_buckets));
  2055. if (ret) {
  2056. pr_err("Failed to copy BOs information from user\n");
  2057. ret = -EFAULT;
  2058. goto exit;
  2059. }
  2060. bo_privs = kvmalloc_objs(*bo_privs, args->num_bos);
  2061. if (!bo_privs) {
  2062. ret = -ENOMEM;
  2063. goto exit;
  2064. }
  2065. ret = copy_from_user(bo_privs, (void __user *)args->priv_data + *priv_offset,
  2066. args->num_bos * sizeof(*bo_privs));
  2067. if (ret) {
  2068. pr_err("Failed to copy BOs information from user\n");
  2069. ret = -EFAULT;
  2070. goto exit;
  2071. }
  2072. *priv_offset += args->num_bos * sizeof(*bo_privs);
  2073. /* Create and map new BOs */
  2074. for (; i < args->num_bos; i++) {
  2075. ret = criu_restore_bo(p, &bo_buckets[i], &bo_privs[i], &files[i]);
  2076. if (ret) {
  2077. pr_debug("Failed to restore BO[%d] ret%d\n", i, ret);
  2078. goto exit;
  2079. }
  2080. } /* done */
  2081. /* Copy only the buckets back so user can read bo_buckets[N].restored_offset */
  2082. ret = copy_to_user((void __user *)args->bos,
  2083. bo_buckets,
  2084. (args->num_bos * sizeof(*bo_buckets)));
  2085. if (ret)
  2086. ret = -EFAULT;
  2087. exit:
  2088. commit_files(files, bo_buckets, i, ret);
  2089. kvfree(files);
  2090. kvfree(bo_buckets);
  2091. kvfree(bo_privs);
  2092. return ret;
  2093. }
  2094. static int criu_restore_objects(struct file *filep,
  2095. struct kfd_process *p,
  2096. struct kfd_ioctl_criu_args *args,
  2097. uint64_t *priv_offset,
  2098. uint64_t max_priv_data_size)
  2099. {
  2100. int ret = 0;
  2101. uint32_t i;
  2102. BUILD_BUG_ON(offsetof(struct kfd_criu_queue_priv_data, object_type));
  2103. BUILD_BUG_ON(offsetof(struct kfd_criu_event_priv_data, object_type));
  2104. BUILD_BUG_ON(offsetof(struct kfd_criu_svm_range_priv_data, object_type));
  2105. for (i = 0; i < args->num_objects; i++) {
  2106. uint32_t object_type;
  2107. if (*priv_offset + sizeof(object_type) > max_priv_data_size) {
  2108. pr_err("Invalid private data size\n");
  2109. return -EINVAL;
  2110. }
  2111. ret = get_user(object_type, (uint32_t __user *)(args->priv_data + *priv_offset));
  2112. if (ret) {
  2113. pr_err("Failed to copy private information from user\n");
  2114. goto exit;
  2115. }
  2116. switch (object_type) {
  2117. case KFD_CRIU_OBJECT_TYPE_QUEUE:
  2118. ret = kfd_criu_restore_queue(p, (uint8_t __user *)args->priv_data,
  2119. priv_offset, max_priv_data_size);
  2120. if (ret)
  2121. goto exit;
  2122. break;
  2123. case KFD_CRIU_OBJECT_TYPE_EVENT:
  2124. ret = kfd_criu_restore_event(filep, p, (uint8_t __user *)args->priv_data,
  2125. priv_offset, max_priv_data_size);
  2126. if (ret)
  2127. goto exit;
  2128. break;
  2129. case KFD_CRIU_OBJECT_TYPE_SVM_RANGE:
  2130. ret = kfd_criu_restore_svm(p, (uint8_t __user *)args->priv_data,
  2131. priv_offset, max_priv_data_size);
  2132. if (ret)
  2133. goto exit;
  2134. break;
  2135. default:
  2136. pr_err("Invalid object type:%u at index:%d\n", object_type, i);
  2137. ret = -EINVAL;
  2138. goto exit;
  2139. }
  2140. }
  2141. exit:
  2142. return ret;
  2143. }
  2144. static int criu_restore(struct file *filep,
  2145. struct kfd_process *p,
  2146. struct kfd_ioctl_criu_args *args)
  2147. {
  2148. uint64_t priv_offset = 0;
  2149. int ret = 0;
  2150. pr_debug("CRIU restore (num_devices:%u num_bos:%u num_objects:%u priv_data_size:%llu)\n",
  2151. args->num_devices, args->num_bos, args->num_objects, args->priv_data_size);
  2152. if ((args->num_bos > 0 && !args->bos) || !args->devices || !args->priv_data ||
  2153. !args->priv_data_size || !args->num_devices)
  2154. return -EINVAL;
  2155. mutex_lock(&p->mutex);
  2156. /*
  2157. * Set the process to evicted state to avoid running any new queues before all the memory
  2158. * mappings are ready.
  2159. */
  2160. ret = kfd_process_evict_queues(p, KFD_QUEUE_EVICTION_CRIU_RESTORE);
  2161. if (ret)
  2162. goto exit_unlock;
  2163. /* Each function will adjust priv_offset based on how many bytes they consumed */
  2164. ret = criu_restore_process(p, args, &priv_offset, args->priv_data_size);
  2165. if (ret)
  2166. goto exit_unlock;
  2167. ret = criu_restore_devices(p, args, &priv_offset, args->priv_data_size);
  2168. if (ret)
  2169. goto exit_unlock;
  2170. ret = criu_restore_bos(p, args, &priv_offset, args->priv_data_size);
  2171. if (ret)
  2172. goto exit_unlock;
  2173. ret = criu_restore_objects(filep, p, args, &priv_offset, args->priv_data_size);
  2174. if (ret)
  2175. goto exit_unlock;
  2176. if (priv_offset != args->priv_data_size) {
  2177. pr_err("Invalid private data size\n");
  2178. ret = -EINVAL;
  2179. }
  2180. exit_unlock:
  2181. mutex_unlock(&p->mutex);
  2182. if (ret)
  2183. pr_err("Failed to restore CRIU ret:%d\n", ret);
  2184. else
  2185. pr_debug("CRIU restore successful\n");
  2186. return ret;
  2187. }
  2188. static int criu_unpause(struct file *filep,
  2189. struct kfd_process *p,
  2190. struct kfd_ioctl_criu_args *args)
  2191. {
  2192. int ret;
  2193. mutex_lock(&p->mutex);
  2194. if (!p->queues_paused) {
  2195. mutex_unlock(&p->mutex);
  2196. return -EINVAL;
  2197. }
  2198. ret = kfd_process_restore_queues(p);
  2199. if (ret)
  2200. pr_err("Failed to unpause queues ret:%d\n", ret);
  2201. else
  2202. p->queues_paused = false;
  2203. mutex_unlock(&p->mutex);
  2204. return ret;
  2205. }
  2206. static int criu_resume(struct file *filep,
  2207. struct kfd_process *p,
  2208. struct kfd_ioctl_criu_args *args)
  2209. {
  2210. struct kfd_process *target = NULL;
  2211. struct pid *pid = NULL;
  2212. int ret = 0;
  2213. pr_debug("Inside %s, target pid for criu restore: %d\n", __func__,
  2214. args->pid);
  2215. pid = find_get_pid(args->pid);
  2216. if (!pid) {
  2217. pr_err("Cannot find pid info for %i\n", args->pid);
  2218. return -ESRCH;
  2219. }
  2220. pr_debug("calling kfd_lookup_process_by_pid\n");
  2221. target = kfd_lookup_process_by_pid(pid);
  2222. put_pid(pid);
  2223. if (!target) {
  2224. pr_debug("Cannot find process info for %i\n", args->pid);
  2225. return -ESRCH;
  2226. }
  2227. mutex_lock(&target->mutex);
  2228. ret = kfd_criu_resume_svm(target);
  2229. if (ret) {
  2230. pr_err("kfd_criu_resume_svm failed for %i\n", args->pid);
  2231. goto exit;
  2232. }
  2233. ret = amdgpu_amdkfd_criu_resume(target->kgd_process_info);
  2234. if (ret)
  2235. pr_err("amdgpu_amdkfd_criu_resume failed for %i\n", args->pid);
  2236. exit:
  2237. mutex_unlock(&target->mutex);
  2238. kfd_unref_process(target);
  2239. return ret;
  2240. }
  2241. static int criu_process_info(struct file *filep,
  2242. struct kfd_process *p,
  2243. struct kfd_ioctl_criu_args *args)
  2244. {
  2245. int ret = 0;
  2246. mutex_lock(&p->mutex);
  2247. if (!p->n_pdds) {
  2248. pr_err("No pdd for given process\n");
  2249. ret = -ENODEV;
  2250. goto err_unlock;
  2251. }
  2252. ret = kfd_process_evict_queues(p, KFD_QUEUE_EVICTION_CRIU_CHECKPOINT);
  2253. if (ret)
  2254. goto err_unlock;
  2255. p->queues_paused = true;
  2256. args->pid = task_pid_nr_ns(p->lead_thread,
  2257. task_active_pid_ns(p->lead_thread));
  2258. ret = criu_get_process_object_info(p, &args->num_devices, &args->num_bos,
  2259. &args->num_objects, &args->priv_data_size);
  2260. if (ret)
  2261. goto err_unlock;
  2262. dev_dbg(kfd_device, "Num of devices:%u bos:%u objects:%u priv_data_size:%lld\n",
  2263. args->num_devices, args->num_bos, args->num_objects,
  2264. args->priv_data_size);
  2265. err_unlock:
  2266. if (ret) {
  2267. kfd_process_restore_queues(p);
  2268. p->queues_paused = false;
  2269. }
  2270. mutex_unlock(&p->mutex);
  2271. return ret;
  2272. }
  2273. static int kfd_ioctl_criu(struct file *filep, struct kfd_process *p, void *data)
  2274. {
  2275. struct kfd_ioctl_criu_args *args = data;
  2276. int ret;
  2277. dev_dbg(kfd_device, "CRIU operation: %d\n", args->op);
  2278. switch (args->op) {
  2279. case KFD_CRIU_OP_PROCESS_INFO:
  2280. ret = criu_process_info(filep, p, args);
  2281. break;
  2282. case KFD_CRIU_OP_CHECKPOINT:
  2283. ret = criu_checkpoint(filep, p, args);
  2284. break;
  2285. case KFD_CRIU_OP_UNPAUSE:
  2286. ret = criu_unpause(filep, p, args);
  2287. break;
  2288. case KFD_CRIU_OP_RESTORE:
  2289. ret = criu_restore(filep, p, args);
  2290. break;
  2291. case KFD_CRIU_OP_RESUME:
  2292. ret = criu_resume(filep, p, args);
  2293. break;
  2294. default:
  2295. dev_dbg(kfd_device, "Unsupported CRIU operation:%d\n", args->op);
  2296. ret = -EINVAL;
  2297. break;
  2298. }
  2299. if (ret)
  2300. dev_dbg(kfd_device, "CRIU operation:%d err:%d\n", args->op, ret);
  2301. return ret;
  2302. }
  2303. static int runtime_enable(struct kfd_process *p, uint64_t r_debug,
  2304. bool enable_ttmp_setup)
  2305. {
  2306. int i = 0, ret = 0;
  2307. if (p->is_runtime_retry)
  2308. goto retry;
  2309. if (p->runtime_info.runtime_state != DEBUG_RUNTIME_STATE_DISABLED)
  2310. return -EBUSY;
  2311. for (i = 0; i < p->n_pdds; i++) {
  2312. struct kfd_process_device *pdd = p->pdds[i];
  2313. if (pdd->qpd.queue_count)
  2314. return -EEXIST;
  2315. /*
  2316. * Setup TTMPs by default.
  2317. * Note that this call must remain here for MES ADD QUEUE to
  2318. * skip_process_ctx_clear unconditionally as the first call to
  2319. * SET_SHADER_DEBUGGER clears any stale process context data
  2320. * saved in MES.
  2321. */
  2322. if (pdd->dev->kfd->shared_resources.enable_mes) {
  2323. ret = kfd_dbg_set_mes_debug_mode(
  2324. pdd, !kfd_dbg_has_cwsr_workaround(pdd->dev));
  2325. if (ret)
  2326. return ret;
  2327. }
  2328. }
  2329. p->runtime_info.runtime_state = DEBUG_RUNTIME_STATE_ENABLED;
  2330. p->runtime_info.r_debug = r_debug;
  2331. p->runtime_info.ttmp_setup = enable_ttmp_setup;
  2332. if (p->runtime_info.ttmp_setup) {
  2333. for (i = 0; i < p->n_pdds; i++) {
  2334. struct kfd_process_device *pdd = p->pdds[i];
  2335. if (!kfd_dbg_is_rlc_restore_supported(pdd->dev)) {
  2336. amdgpu_gfx_off_ctrl(pdd->dev->adev, false);
  2337. pdd->dev->kfd2kgd->enable_debug_trap(
  2338. pdd->dev->adev,
  2339. true,
  2340. pdd->dev->vm_info.last_vmid_kfd);
  2341. } else if (kfd_dbg_is_per_vmid_supported(pdd->dev)) {
  2342. pdd->spi_dbg_override = pdd->dev->kfd2kgd->enable_debug_trap(
  2343. pdd->dev->adev,
  2344. false,
  2345. 0);
  2346. }
  2347. }
  2348. }
  2349. retry:
  2350. if (p->debug_trap_enabled) {
  2351. if (!p->is_runtime_retry) {
  2352. kfd_dbg_trap_activate(p);
  2353. kfd_dbg_ev_raise(KFD_EC_MASK(EC_PROCESS_RUNTIME),
  2354. p, NULL, 0, false, NULL, 0);
  2355. }
  2356. mutex_unlock(&p->mutex);
  2357. ret = down_interruptible(&p->runtime_enable_sema);
  2358. mutex_lock(&p->mutex);
  2359. p->is_runtime_retry = !!ret;
  2360. }
  2361. return ret;
  2362. }
  2363. static int runtime_disable(struct kfd_process *p)
  2364. {
  2365. int i = 0, ret = 0;
  2366. bool was_enabled = p->runtime_info.runtime_state == DEBUG_RUNTIME_STATE_ENABLED;
  2367. p->runtime_info.runtime_state = DEBUG_RUNTIME_STATE_DISABLED;
  2368. p->runtime_info.r_debug = 0;
  2369. if (p->debug_trap_enabled) {
  2370. if (was_enabled)
  2371. kfd_dbg_trap_deactivate(p, false, 0);
  2372. if (!p->is_runtime_retry)
  2373. kfd_dbg_ev_raise(KFD_EC_MASK(EC_PROCESS_RUNTIME),
  2374. p, NULL, 0, false, NULL, 0);
  2375. mutex_unlock(&p->mutex);
  2376. ret = down_interruptible(&p->runtime_enable_sema);
  2377. mutex_lock(&p->mutex);
  2378. p->is_runtime_retry = !!ret;
  2379. if (ret)
  2380. return ret;
  2381. }
  2382. if (was_enabled && p->runtime_info.ttmp_setup) {
  2383. for (i = 0; i < p->n_pdds; i++) {
  2384. struct kfd_process_device *pdd = p->pdds[i];
  2385. if (!kfd_dbg_is_rlc_restore_supported(pdd->dev))
  2386. amdgpu_gfx_off_ctrl(pdd->dev->adev, true);
  2387. }
  2388. }
  2389. p->runtime_info.ttmp_setup = false;
  2390. /* disable ttmp setup */
  2391. for (i = 0; i < p->n_pdds; i++) {
  2392. struct kfd_process_device *pdd = p->pdds[i];
  2393. int last_err = 0;
  2394. if (kfd_dbg_is_per_vmid_supported(pdd->dev)) {
  2395. pdd->spi_dbg_override =
  2396. pdd->dev->kfd2kgd->disable_debug_trap(
  2397. pdd->dev->adev,
  2398. false,
  2399. pdd->dev->vm_info.last_vmid_kfd);
  2400. if (!pdd->dev->kfd->shared_resources.enable_mes)
  2401. last_err = debug_refresh_runlist(pdd->dev->dqm);
  2402. else
  2403. last_err = kfd_dbg_set_mes_debug_mode(pdd,
  2404. !kfd_dbg_has_cwsr_workaround(pdd->dev));
  2405. if (last_err)
  2406. ret = last_err;
  2407. }
  2408. }
  2409. return ret;
  2410. }
  2411. static int kfd_ioctl_runtime_enable(struct file *filep, struct kfd_process *p, void *data)
  2412. {
  2413. struct kfd_ioctl_runtime_enable_args *args = data;
  2414. int r;
  2415. mutex_lock(&p->mutex);
  2416. if (args->mode_mask & KFD_RUNTIME_ENABLE_MODE_ENABLE_MASK)
  2417. r = runtime_enable(p, args->r_debug,
  2418. !!(args->mode_mask & KFD_RUNTIME_ENABLE_MODE_TTMP_SAVE_MASK));
  2419. else
  2420. r = runtime_disable(p);
  2421. mutex_unlock(&p->mutex);
  2422. return r;
  2423. }
  2424. static int kfd_ioctl_set_debug_trap(struct file *filep, struct kfd_process *p, void *data)
  2425. {
  2426. struct kfd_ioctl_dbg_trap_args *args = data;
  2427. struct task_struct *thread = NULL;
  2428. struct mm_struct *mm = NULL;
  2429. struct pid *pid = NULL;
  2430. struct kfd_process *target = NULL;
  2431. struct kfd_process_device *pdd = NULL;
  2432. int r = 0;
  2433. if (p->context_id != KFD_CONTEXT_ID_PRIMARY) {
  2434. pr_debug("Set debug trap ioctl can not be invoked on non-primary kfd process\n");
  2435. return -EOPNOTSUPP;
  2436. }
  2437. if (sched_policy == KFD_SCHED_POLICY_NO_HWS) {
  2438. pr_err("Debugging does not support sched_policy %i", sched_policy);
  2439. return -EINVAL;
  2440. }
  2441. pid = find_get_pid(args->pid);
  2442. if (!pid) {
  2443. pr_debug("Cannot find pid info for %i\n", args->pid);
  2444. r = -ESRCH;
  2445. goto out;
  2446. }
  2447. thread = get_pid_task(pid, PIDTYPE_PID);
  2448. if (!thread) {
  2449. r = -ESRCH;
  2450. goto out;
  2451. }
  2452. mm = get_task_mm(thread);
  2453. if (!mm) {
  2454. r = -ESRCH;
  2455. goto out;
  2456. }
  2457. if (args->op == KFD_IOC_DBG_TRAP_ENABLE) {
  2458. bool create_process;
  2459. rcu_read_lock();
  2460. create_process = thread && thread != current && ptrace_parent(thread) == current;
  2461. rcu_read_unlock();
  2462. target = create_process ? kfd_create_process(thread) :
  2463. kfd_lookup_process_by_pid(pid);
  2464. } else {
  2465. target = kfd_lookup_process_by_pid(pid);
  2466. }
  2467. if (IS_ERR_OR_NULL(target)) {
  2468. pr_debug("Cannot find process PID %i to debug\n", args->pid);
  2469. r = target ? PTR_ERR(target) : -ESRCH;
  2470. target = NULL;
  2471. goto out;
  2472. }
  2473. if (target->context_id != KFD_CONTEXT_ID_PRIMARY) {
  2474. pr_debug("Set debug trap ioctl not supported on non-primary kfd process\n");
  2475. r = -EOPNOTSUPP;
  2476. goto out;
  2477. }
  2478. /* Check if target is still PTRACED. */
  2479. rcu_read_lock();
  2480. if (target != p && args->op != KFD_IOC_DBG_TRAP_DISABLE
  2481. && ptrace_parent(target->lead_thread) != current) {
  2482. pr_err("PID %i is not PTRACED and cannot be debugged\n", args->pid);
  2483. r = -EPERM;
  2484. }
  2485. rcu_read_unlock();
  2486. if (r)
  2487. goto out;
  2488. mutex_lock(&target->mutex);
  2489. if (args->op != KFD_IOC_DBG_TRAP_ENABLE && !target->debug_trap_enabled) {
  2490. pr_err("PID %i not debug enabled for op %i\n", args->pid, args->op);
  2491. r = -EINVAL;
  2492. goto unlock_out;
  2493. }
  2494. if (target->runtime_info.runtime_state != DEBUG_RUNTIME_STATE_ENABLED &&
  2495. (args->op == KFD_IOC_DBG_TRAP_SET_WAVE_LAUNCH_OVERRIDE ||
  2496. args->op == KFD_IOC_DBG_TRAP_SET_WAVE_LAUNCH_MODE ||
  2497. args->op == KFD_IOC_DBG_TRAP_SUSPEND_QUEUES ||
  2498. args->op == KFD_IOC_DBG_TRAP_RESUME_QUEUES ||
  2499. args->op == KFD_IOC_DBG_TRAP_SET_NODE_ADDRESS_WATCH ||
  2500. args->op == KFD_IOC_DBG_TRAP_CLEAR_NODE_ADDRESS_WATCH ||
  2501. args->op == KFD_IOC_DBG_TRAP_SET_FLAGS)) {
  2502. r = -EPERM;
  2503. goto unlock_out;
  2504. }
  2505. if (args->op == KFD_IOC_DBG_TRAP_SET_NODE_ADDRESS_WATCH ||
  2506. args->op == KFD_IOC_DBG_TRAP_CLEAR_NODE_ADDRESS_WATCH) {
  2507. int user_gpu_id = kfd_process_get_user_gpu_id(target,
  2508. args->op == KFD_IOC_DBG_TRAP_SET_NODE_ADDRESS_WATCH ?
  2509. args->set_node_address_watch.gpu_id :
  2510. args->clear_node_address_watch.gpu_id);
  2511. pdd = kfd_process_device_data_by_id(target, user_gpu_id);
  2512. if (user_gpu_id == -EINVAL || !pdd) {
  2513. r = -ENODEV;
  2514. goto unlock_out;
  2515. }
  2516. }
  2517. switch (args->op) {
  2518. case KFD_IOC_DBG_TRAP_ENABLE:
  2519. if (target != p)
  2520. target->debugger_process = p;
  2521. r = kfd_dbg_trap_enable(target,
  2522. args->enable.dbg_fd,
  2523. (void __user *)args->enable.rinfo_ptr,
  2524. &args->enable.rinfo_size);
  2525. if (!r)
  2526. target->exception_enable_mask = args->enable.exception_mask;
  2527. break;
  2528. case KFD_IOC_DBG_TRAP_DISABLE:
  2529. r = kfd_dbg_trap_disable(target);
  2530. break;
  2531. case KFD_IOC_DBG_TRAP_SEND_RUNTIME_EVENT:
  2532. r = kfd_dbg_send_exception_to_runtime(target,
  2533. args->send_runtime_event.gpu_id,
  2534. args->send_runtime_event.queue_id,
  2535. args->send_runtime_event.exception_mask);
  2536. break;
  2537. case KFD_IOC_DBG_TRAP_SET_EXCEPTIONS_ENABLED:
  2538. kfd_dbg_set_enabled_debug_exception_mask(target,
  2539. args->set_exceptions_enabled.exception_mask);
  2540. break;
  2541. case KFD_IOC_DBG_TRAP_SET_WAVE_LAUNCH_OVERRIDE:
  2542. r = kfd_dbg_trap_set_wave_launch_override(target,
  2543. args->launch_override.override_mode,
  2544. args->launch_override.enable_mask,
  2545. args->launch_override.support_request_mask,
  2546. &args->launch_override.enable_mask,
  2547. &args->launch_override.support_request_mask);
  2548. break;
  2549. case KFD_IOC_DBG_TRAP_SET_WAVE_LAUNCH_MODE:
  2550. r = kfd_dbg_trap_set_wave_launch_mode(target,
  2551. args->launch_mode.launch_mode);
  2552. break;
  2553. case KFD_IOC_DBG_TRAP_SUSPEND_QUEUES:
  2554. r = suspend_queues(target,
  2555. args->suspend_queues.num_queues,
  2556. args->suspend_queues.grace_period,
  2557. args->suspend_queues.exception_mask,
  2558. (uint32_t *)args->suspend_queues.queue_array_ptr);
  2559. break;
  2560. case KFD_IOC_DBG_TRAP_RESUME_QUEUES:
  2561. r = resume_queues(target, args->resume_queues.num_queues,
  2562. (uint32_t *)args->resume_queues.queue_array_ptr);
  2563. break;
  2564. case KFD_IOC_DBG_TRAP_SET_NODE_ADDRESS_WATCH:
  2565. r = kfd_dbg_trap_set_dev_address_watch(pdd,
  2566. args->set_node_address_watch.address,
  2567. args->set_node_address_watch.mask,
  2568. &args->set_node_address_watch.id,
  2569. args->set_node_address_watch.mode);
  2570. break;
  2571. case KFD_IOC_DBG_TRAP_CLEAR_NODE_ADDRESS_WATCH:
  2572. r = kfd_dbg_trap_clear_dev_address_watch(pdd,
  2573. args->clear_node_address_watch.id);
  2574. break;
  2575. case KFD_IOC_DBG_TRAP_SET_FLAGS:
  2576. r = kfd_dbg_trap_set_flags(target, &args->set_flags.flags);
  2577. break;
  2578. case KFD_IOC_DBG_TRAP_QUERY_DEBUG_EVENT:
  2579. r = kfd_dbg_ev_query_debug_event(target,
  2580. &args->query_debug_event.queue_id,
  2581. &args->query_debug_event.gpu_id,
  2582. args->query_debug_event.exception_mask,
  2583. &args->query_debug_event.exception_mask);
  2584. break;
  2585. case KFD_IOC_DBG_TRAP_QUERY_EXCEPTION_INFO:
  2586. r = kfd_dbg_trap_query_exception_info(target,
  2587. args->query_exception_info.source_id,
  2588. args->query_exception_info.exception_code,
  2589. args->query_exception_info.clear_exception,
  2590. (void __user *)args->query_exception_info.info_ptr,
  2591. &args->query_exception_info.info_size);
  2592. break;
  2593. case KFD_IOC_DBG_TRAP_GET_QUEUE_SNAPSHOT:
  2594. r = pqm_get_queue_snapshot(&target->pqm,
  2595. args->queue_snapshot.exception_mask,
  2596. (void __user *)args->queue_snapshot.snapshot_buf_ptr,
  2597. &args->queue_snapshot.num_queues,
  2598. &args->queue_snapshot.entry_size);
  2599. break;
  2600. case KFD_IOC_DBG_TRAP_GET_DEVICE_SNAPSHOT:
  2601. r = kfd_dbg_trap_device_snapshot(target,
  2602. args->device_snapshot.exception_mask,
  2603. (void __user *)args->device_snapshot.snapshot_buf_ptr,
  2604. &args->device_snapshot.num_devices,
  2605. &args->device_snapshot.entry_size);
  2606. break;
  2607. default:
  2608. pr_err("Invalid option: %i\n", args->op);
  2609. r = -EINVAL;
  2610. }
  2611. unlock_out:
  2612. mutex_unlock(&target->mutex);
  2613. out:
  2614. if (thread)
  2615. put_task_struct(thread);
  2616. if (mm)
  2617. mmput(mm);
  2618. if (pid)
  2619. put_pid(pid);
  2620. if (target)
  2621. kfd_unref_process(target);
  2622. return r;
  2623. }
  2624. /* userspace programs need to invoke this ioctl explicitly on a FD to
  2625. * create a secondary kfd_process which replacing its primary kfd_process
  2626. */
  2627. static int kfd_ioctl_create_process(struct file *filep, struct kfd_process *p, void *data)
  2628. {
  2629. struct kfd_process *process;
  2630. int ret;
  2631. if (!filep->private_data || !p)
  2632. return -EINVAL;
  2633. /* Each FD owns only one kfd_process */
  2634. if (p->context_id != KFD_CONTEXT_ID_PRIMARY)
  2635. return -EINVAL;
  2636. mutex_lock(&kfd_processes_mutex);
  2637. if (p != filep->private_data) {
  2638. mutex_unlock(&kfd_processes_mutex);
  2639. return -EINVAL;
  2640. }
  2641. process = create_process(current, false);
  2642. if (IS_ERR(process)) {
  2643. mutex_unlock(&kfd_processes_mutex);
  2644. return PTR_ERR(process);
  2645. }
  2646. filep->private_data = process;
  2647. mutex_unlock(&kfd_processes_mutex);
  2648. ret = kfd_create_process_sysfs(process);
  2649. if (ret)
  2650. pr_warn("Failed to create sysfs entry for the kfd_process");
  2651. /* Each open() increases kref of the primary kfd_process,
  2652. * so we need to reduce it here when we create a new secondary process replacing it
  2653. */
  2654. kfd_unref_process(p);
  2655. return 0;
  2656. }
  2657. #define AMDKFD_IOCTL_DEF(ioctl, _func, _flags) \
  2658. [_IOC_NR(ioctl)] = {.cmd = ioctl, .func = _func, .flags = _flags, \
  2659. .cmd_drv = 0, .name = #ioctl}
  2660. /** Ioctl table */
  2661. static const struct amdkfd_ioctl_desc amdkfd_ioctls[] = {
  2662. AMDKFD_IOCTL_DEF(AMDKFD_IOC_GET_VERSION,
  2663. kfd_ioctl_get_version, 0),
  2664. AMDKFD_IOCTL_DEF(AMDKFD_IOC_CREATE_QUEUE,
  2665. kfd_ioctl_create_queue, 0),
  2666. AMDKFD_IOCTL_DEF(AMDKFD_IOC_DESTROY_QUEUE,
  2667. kfd_ioctl_destroy_queue, 0),
  2668. AMDKFD_IOCTL_DEF(AMDKFD_IOC_SET_MEMORY_POLICY,
  2669. kfd_ioctl_set_memory_policy, 0),
  2670. AMDKFD_IOCTL_DEF(AMDKFD_IOC_GET_CLOCK_COUNTERS,
  2671. kfd_ioctl_get_clock_counters, 0),
  2672. AMDKFD_IOCTL_DEF(AMDKFD_IOC_GET_PROCESS_APERTURES,
  2673. kfd_ioctl_get_process_apertures, 0),
  2674. AMDKFD_IOCTL_DEF(AMDKFD_IOC_UPDATE_QUEUE,
  2675. kfd_ioctl_update_queue, 0),
  2676. AMDKFD_IOCTL_DEF(AMDKFD_IOC_CREATE_EVENT,
  2677. kfd_ioctl_create_event, 0),
  2678. AMDKFD_IOCTL_DEF(AMDKFD_IOC_DESTROY_EVENT,
  2679. kfd_ioctl_destroy_event, 0),
  2680. AMDKFD_IOCTL_DEF(AMDKFD_IOC_SET_EVENT,
  2681. kfd_ioctl_set_event, 0),
  2682. AMDKFD_IOCTL_DEF(AMDKFD_IOC_RESET_EVENT,
  2683. kfd_ioctl_reset_event, 0),
  2684. AMDKFD_IOCTL_DEF(AMDKFD_IOC_WAIT_EVENTS,
  2685. kfd_ioctl_wait_events, 0),
  2686. AMDKFD_IOCTL_DEF(AMDKFD_IOC_DBG_REGISTER_DEPRECATED,
  2687. kfd_ioctl_dbg_register, 0),
  2688. AMDKFD_IOCTL_DEF(AMDKFD_IOC_DBG_UNREGISTER_DEPRECATED,
  2689. kfd_ioctl_dbg_unregister, 0),
  2690. AMDKFD_IOCTL_DEF(AMDKFD_IOC_DBG_ADDRESS_WATCH_DEPRECATED,
  2691. kfd_ioctl_dbg_address_watch, 0),
  2692. AMDKFD_IOCTL_DEF(AMDKFD_IOC_DBG_WAVE_CONTROL_DEPRECATED,
  2693. kfd_ioctl_dbg_wave_control, 0),
  2694. AMDKFD_IOCTL_DEF(AMDKFD_IOC_SET_SCRATCH_BACKING_VA,
  2695. kfd_ioctl_set_scratch_backing_va, 0),
  2696. AMDKFD_IOCTL_DEF(AMDKFD_IOC_GET_TILE_CONFIG,
  2697. kfd_ioctl_get_tile_config, 0),
  2698. AMDKFD_IOCTL_DEF(AMDKFD_IOC_SET_TRAP_HANDLER,
  2699. kfd_ioctl_set_trap_handler, 0),
  2700. AMDKFD_IOCTL_DEF(AMDKFD_IOC_GET_PROCESS_APERTURES_NEW,
  2701. kfd_ioctl_get_process_apertures_new, 0),
  2702. AMDKFD_IOCTL_DEF(AMDKFD_IOC_ACQUIRE_VM,
  2703. kfd_ioctl_acquire_vm, 0),
  2704. AMDKFD_IOCTL_DEF(AMDKFD_IOC_ALLOC_MEMORY_OF_GPU,
  2705. kfd_ioctl_alloc_memory_of_gpu, 0),
  2706. AMDKFD_IOCTL_DEF(AMDKFD_IOC_FREE_MEMORY_OF_GPU,
  2707. kfd_ioctl_free_memory_of_gpu, 0),
  2708. AMDKFD_IOCTL_DEF(AMDKFD_IOC_MAP_MEMORY_TO_GPU,
  2709. kfd_ioctl_map_memory_to_gpu, 0),
  2710. AMDKFD_IOCTL_DEF(AMDKFD_IOC_UNMAP_MEMORY_FROM_GPU,
  2711. kfd_ioctl_unmap_memory_from_gpu, 0),
  2712. AMDKFD_IOCTL_DEF(AMDKFD_IOC_SET_CU_MASK,
  2713. kfd_ioctl_set_cu_mask, 0),
  2714. AMDKFD_IOCTL_DEF(AMDKFD_IOC_GET_QUEUE_WAVE_STATE,
  2715. kfd_ioctl_get_queue_wave_state, 0),
  2716. AMDKFD_IOCTL_DEF(AMDKFD_IOC_GET_DMABUF_INFO,
  2717. kfd_ioctl_get_dmabuf_info, 0),
  2718. AMDKFD_IOCTL_DEF(AMDKFD_IOC_IMPORT_DMABUF,
  2719. kfd_ioctl_import_dmabuf, 0),
  2720. AMDKFD_IOCTL_DEF(AMDKFD_IOC_ALLOC_QUEUE_GWS,
  2721. kfd_ioctl_alloc_queue_gws, 0),
  2722. AMDKFD_IOCTL_DEF(AMDKFD_IOC_SMI_EVENTS,
  2723. kfd_ioctl_smi_events, 0),
  2724. AMDKFD_IOCTL_DEF(AMDKFD_IOC_SVM, kfd_ioctl_svm, 0),
  2725. AMDKFD_IOCTL_DEF(AMDKFD_IOC_SET_XNACK_MODE,
  2726. kfd_ioctl_set_xnack_mode, 0),
  2727. AMDKFD_IOCTL_DEF(AMDKFD_IOC_CRIU_OP,
  2728. kfd_ioctl_criu, KFD_IOC_FLAG_CHECKPOINT_RESTORE),
  2729. AMDKFD_IOCTL_DEF(AMDKFD_IOC_AVAILABLE_MEMORY,
  2730. kfd_ioctl_get_available_memory, 0),
  2731. AMDKFD_IOCTL_DEF(AMDKFD_IOC_EXPORT_DMABUF,
  2732. kfd_ioctl_export_dmabuf, 0),
  2733. AMDKFD_IOCTL_DEF(AMDKFD_IOC_RUNTIME_ENABLE,
  2734. kfd_ioctl_runtime_enable, 0),
  2735. AMDKFD_IOCTL_DEF(AMDKFD_IOC_DBG_TRAP,
  2736. kfd_ioctl_set_debug_trap, 0),
  2737. AMDKFD_IOCTL_DEF(AMDKFD_IOC_CREATE_PROCESS,
  2738. kfd_ioctl_create_process, 0),
  2739. };
  2740. #define AMDKFD_CORE_IOCTL_COUNT ARRAY_SIZE(amdkfd_ioctls)
  2741. static long kfd_ioctl(struct file *filep, unsigned int cmd, unsigned long arg)
  2742. {
  2743. struct kfd_process *process;
  2744. amdkfd_ioctl_t *func;
  2745. const struct amdkfd_ioctl_desc *ioctl = NULL;
  2746. unsigned int nr = _IOC_NR(cmd);
  2747. char stack_kdata[128];
  2748. char *kdata = NULL;
  2749. unsigned int usize, asize;
  2750. int retcode = -EINVAL;
  2751. bool ptrace_attached = false;
  2752. if (nr >= AMDKFD_CORE_IOCTL_COUNT) {
  2753. retcode = -ENOTTY;
  2754. goto err_i1;
  2755. }
  2756. if ((nr >= AMDKFD_COMMAND_START) && (nr < AMDKFD_COMMAND_END)) {
  2757. u32 amdkfd_size;
  2758. ioctl = &amdkfd_ioctls[nr];
  2759. amdkfd_size = _IOC_SIZE(ioctl->cmd);
  2760. usize = asize = _IOC_SIZE(cmd);
  2761. if (amdkfd_size > asize)
  2762. asize = amdkfd_size;
  2763. cmd = ioctl->cmd;
  2764. } else {
  2765. retcode = -ENOTTY;
  2766. goto err_i1;
  2767. }
  2768. dev_dbg(kfd_device, "ioctl cmd 0x%x (#0x%x), arg 0x%lx\n", cmd, nr, arg);
  2769. /* Get the process struct from the filep. Only the process
  2770. * that opened /dev/kfd can use the file descriptor. Child
  2771. * processes need to create their own KFD device context.
  2772. */
  2773. process = filep->private_data;
  2774. rcu_read_lock();
  2775. if ((ioctl->flags & KFD_IOC_FLAG_CHECKPOINT_RESTORE) &&
  2776. ptrace_parent(process->lead_thread) == current)
  2777. ptrace_attached = true;
  2778. rcu_read_unlock();
  2779. if (process->lead_thread != current->group_leader
  2780. && !ptrace_attached) {
  2781. dev_dbg(kfd_device, "Using KFD FD in wrong process\n");
  2782. retcode = -EBADF;
  2783. goto err_i1;
  2784. }
  2785. /* Do not trust userspace, use our own definition */
  2786. func = ioctl->func;
  2787. if (unlikely(!func)) {
  2788. dev_dbg(kfd_device, "no function\n");
  2789. retcode = -EINVAL;
  2790. goto err_i1;
  2791. }
  2792. /*
  2793. * Versions of docker shipped in Ubuntu 18.xx and 20.xx do not support
  2794. * CAP_CHECKPOINT_RESTORE, so we also allow access if CAP_SYS_ADMIN as CAP_SYS_ADMIN is a
  2795. * more priviledged access.
  2796. */
  2797. if (unlikely(ioctl->flags & KFD_IOC_FLAG_CHECKPOINT_RESTORE)) {
  2798. if (!capable(CAP_CHECKPOINT_RESTORE) &&
  2799. !capable(CAP_SYS_ADMIN)) {
  2800. retcode = -EACCES;
  2801. goto err_i1;
  2802. }
  2803. }
  2804. if (cmd & (IOC_IN | IOC_OUT)) {
  2805. if (asize <= sizeof(stack_kdata)) {
  2806. kdata = stack_kdata;
  2807. } else {
  2808. kdata = kmalloc(asize, GFP_KERNEL);
  2809. if (!kdata) {
  2810. retcode = -ENOMEM;
  2811. goto err_i1;
  2812. }
  2813. }
  2814. if (asize > usize)
  2815. memset(kdata + usize, 0, asize - usize);
  2816. }
  2817. if (cmd & IOC_IN) {
  2818. if (copy_from_user(kdata, (void __user *)arg, usize) != 0) {
  2819. retcode = -EFAULT;
  2820. goto err_i1;
  2821. }
  2822. } else if (cmd & IOC_OUT) {
  2823. memset(kdata, 0, usize);
  2824. }
  2825. retcode = func(filep, process, kdata);
  2826. if (cmd & IOC_OUT)
  2827. if (copy_to_user((void __user *)arg, kdata, usize) != 0)
  2828. retcode = -EFAULT;
  2829. err_i1:
  2830. if (!ioctl)
  2831. dev_dbg(kfd_device, "invalid ioctl: pid=%d, cmd=0x%02x, nr=0x%02x\n",
  2832. task_pid_nr(current), cmd, nr);
  2833. if (kdata != stack_kdata)
  2834. kfree(kdata);
  2835. if (retcode)
  2836. dev_dbg(kfd_device, "ioctl cmd (#0x%x), arg 0x%lx, ret = %d\n",
  2837. nr, arg, retcode);
  2838. return retcode;
  2839. }
  2840. static int kfd_mmio_mmap(struct kfd_node *dev, struct kfd_process *process,
  2841. struct vm_area_struct *vma)
  2842. {
  2843. phys_addr_t address;
  2844. if (vma->vm_end - vma->vm_start != PAGE_SIZE)
  2845. return -EINVAL;
  2846. if (PAGE_SIZE > 4096)
  2847. return -EINVAL;
  2848. address = dev->adev->rmmio_remap.bus_addr;
  2849. vm_flags_set(vma, VM_IO | VM_DONTCOPY | VM_DONTEXPAND | VM_NORESERVE |
  2850. VM_DONTDUMP | VM_PFNMAP);
  2851. vma->vm_page_prot = pgprot_noncached(vma->vm_page_prot);
  2852. pr_debug("process pid %d mapping mmio page\n"
  2853. " target user address == 0x%08llX\n"
  2854. " physical address == 0x%08llX\n"
  2855. " vm_flags == 0x%04lX\n"
  2856. " size == 0x%04lX\n",
  2857. process->lead_thread->pid, (unsigned long long) vma->vm_start,
  2858. address, vma->vm_flags, PAGE_SIZE);
  2859. return io_remap_pfn_range(vma,
  2860. vma->vm_start,
  2861. address >> PAGE_SHIFT,
  2862. PAGE_SIZE,
  2863. vma->vm_page_prot);
  2864. }
  2865. static int kfd_mmap(struct file *filep, struct vm_area_struct *vma)
  2866. {
  2867. struct kfd_process *process;
  2868. struct kfd_node *dev = NULL;
  2869. unsigned long mmap_offset;
  2870. unsigned int gpu_id;
  2871. process = filep->private_data;
  2872. if (!process)
  2873. return -ESRCH;
  2874. if (process->lead_thread != current->group_leader)
  2875. return -EBADF;
  2876. mmap_offset = vma->vm_pgoff << PAGE_SHIFT;
  2877. gpu_id = KFD_MMAP_GET_GPU_ID(mmap_offset);
  2878. if (gpu_id)
  2879. dev = kfd_device_by_id(gpu_id);
  2880. switch (mmap_offset & KFD_MMAP_TYPE_MASK) {
  2881. case KFD_MMAP_TYPE_DOORBELL:
  2882. if (!dev)
  2883. return -ENODEV;
  2884. return kfd_doorbell_mmap(dev, process, vma);
  2885. case KFD_MMAP_TYPE_EVENTS:
  2886. return kfd_event_mmap(process, vma);
  2887. case KFD_MMAP_TYPE_RESERVED_MEM:
  2888. if (!dev)
  2889. return -ENODEV;
  2890. return kfd_reserved_mem_mmap(dev, process, vma);
  2891. case KFD_MMAP_TYPE_MMIO:
  2892. if (!dev)
  2893. return -ENODEV;
  2894. return kfd_mmio_mmap(dev, process, vma);
  2895. }
  2896. return -EFAULT;
  2897. }