1 // SPDX-License-Identifier: GPL-2.0+ 2 /* 3 * VAS Fault handling. 4 * Copyright 2019, IBM Corporation 5 */ 6 7 #define pr_fmt(fmt) "vas: " fmt 8 9 #include <linux/kernel.h> 10 #include <linux/types.h> 11 #include <linux/slab.h> 12 #include <linux/uaccess.h> 13 #include <linux/kthread.h> 14 #include <linux/sched/signal.h> 15 #include <linux/mmu_context.h> 16 #include <asm/icswx.h> 17 18 #include "vas.h" 19 20 /* 21 * The maximum FIFO size for fault window can be 8MB 22 * (VAS_RX_FIFO_SIZE_MAX). Using 4MB FIFO since each VAS 23 * instance will be having fault window. 24 * 8MB FIFO can be used if expects more faults for each VAS 25 * instance. 26 */ 27 #define VAS_FAULT_WIN_FIFO_SIZE (4 << 20) 28 29 static void dump_crb(struct coprocessor_request_block *crb) 30 { 31 struct data_descriptor_entry *dde; 32 struct nx_fault_stamp *nx; 33 34 dde = &crb->source; 35 pr_devel("SrcDDE: addr 0x%llx, len %d, count %d, idx %d, flags %d\n", 36 be64_to_cpu(dde->address), be32_to_cpu(dde->length), 37 dde->count, dde->index, dde->flags); 38 39 dde = &crb->target; 40 pr_devel("TgtDDE: addr 0x%llx, len %d, count %d, idx %d, flags %d\n", 41 be64_to_cpu(dde->address), be32_to_cpu(dde->length), 42 dde->count, dde->index, dde->flags); 43 44 nx = &crb->stamp.nx; 45 pr_devel("NX Stamp: PSWID 0x%x, FSA 0x%llx, flags 0x%x, FS 0x%x\n", 46 be32_to_cpu(nx->pswid), 47 be64_to_cpu(crb->stamp.nx.fault_storage_addr), 48 nx->flags, nx->fault_status); 49 } 50 51 /* 52 * Update the CSB to indicate a translation error. 53 * 54 * User space will be polling on CSB after the request is issued. 55 * If NX can handle the request without any issues, it updates CSB. 56 * Whereas if NX encounters page fault, the kernel will handle the 57 * fault and update CSB with translation error. 58 * 59 * If we are unable to update the CSB means copy_to_user failed due to 60 * invalid csb_addr, send a signal to the process. 61 */ 62 static void update_csb(struct vas_window *window, 63 struct coprocessor_request_block *crb) 64 { 65 struct coprocessor_status_block csb; 66 struct kernel_siginfo info; 67 struct task_struct *tsk; 68 void __user *csb_addr; 69 struct pid *pid; 70 int rc; 71 72 /* 73 * NX user space windows can not be opened for task->mm=NULL 74 * and faults will not be generated for kernel requests. 75 */ 76 if (WARN_ON_ONCE(!window->mm || !window->user_win)) 77 return; 78 79 csb_addr = (void __user *)be64_to_cpu(crb->csb_addr); 80 81 memset(&csb, 0, sizeof(csb)); 82 csb.cc = CSB_CC_TRANSLATION; 83 csb.ce = CSB_CE_TERMINATION; 84 csb.cs = 0; 85 csb.count = 0; 86 87 /* 88 * NX operates and returns in BE format as defined CRB struct. 89 * So saves fault_storage_addr in BE as NX pastes in FIFO and 90 * expects user space to convert to CPU format. 91 */ 92 csb.address = crb->stamp.nx.fault_storage_addr; 93 csb.flags = 0; 94 95 pid = window->pid; 96 tsk = get_pid_task(pid, PIDTYPE_PID); 97 /* 98 * Process closes send window after all pending NX requests are 99 * completed. In multi-thread applications, a child thread can 100 * open a window and can exit without closing it. May be some 101 * requests are pending or this window can be used by other 102 * threads later. We should handle faults if NX encounters 103 * pages faults on these requests. Update CSB with translation 104 * error and fault address. If csb_addr passed by user space is 105 * invalid, send SEGV signal to pid saved in window. If the 106 * child thread is not running, send the signal to tgid. 107 * Parent thread (tgid) will close this window upon its exit. 108 * 109 * pid and mm references are taken when window is opened by 110 * process (pid). So tgid is used only when child thread opens 111 * a window and exits without closing it. 112 */ 113 if (!tsk) { 114 pid = window->tgid; 115 tsk = get_pid_task(pid, PIDTYPE_PID); 116 /* 117 * Parent thread (tgid) will be closing window when it 118 * exits. So should not get here. 119 */ 120 if (WARN_ON_ONCE(!tsk)) 121 return; 122 } 123 124 /* Return if the task is exiting. */ 125 if (tsk->flags & PF_EXITING) { 126 put_task_struct(tsk); 127 return; 128 } 129 130 kthread_use_mm(window->mm); 131 rc = copy_to_user(csb_addr, &csb, sizeof(csb)); 132 /* 133 * User space polls on csb.flags (first byte). So add barrier 134 * then copy first byte with csb flags update. 135 */ 136 if (!rc) { 137 csb.flags = CSB_V; 138 /* Make sure update to csb.flags is visible now */ 139 smp_mb(); 140 rc = copy_to_user(csb_addr, &csb, sizeof(u8)); 141 } 142 kthread_unuse_mm(window->mm); 143 put_task_struct(tsk); 144 145 /* Success */ 146 if (!rc) 147 return; 148 149 pr_debug("Invalid CSB address 0x%p signalling pid(%d)\n", 150 csb_addr, pid_vnr(pid)); 151 152 clear_siginfo(&info); 153 info.si_signo = SIGSEGV; 154 info.si_errno = EFAULT; 155 info.si_code = SEGV_MAPERR; 156 info.si_addr = csb_addr; 157 158 /* 159 * process will be polling on csb.flags after request is sent to 160 * NX. So generally CSB update should not fail except when an 161 * application passes invalid csb_addr. So an error message will 162 * be displayed and leave it to user space whether to ignore or 163 * handle this signal. 164 */ 165 rcu_read_lock(); 166 rc = kill_pid_info(SIGSEGV, &info, pid); 167 rcu_read_unlock(); 168 169 pr_devel("%s(): pid %d kill_proc_info() rc %d\n", __func__, 170 pid_vnr(pid), rc); 171 } 172 173 static void dump_fifo(struct vas_instance *vinst, void *entry) 174 { 175 unsigned long *end = vinst->fault_fifo + vinst->fault_fifo_size; 176 unsigned long *fifo = entry; 177 int i; 178 179 pr_err("Fault fifo size %d, Max crbs %d\n", vinst->fault_fifo_size, 180 vinst->fault_fifo_size / CRB_SIZE); 181 182 /* Dump 10 CRB entries or until end of FIFO */ 183 pr_err("Fault FIFO Dump:\n"); 184 for (i = 0; i < 10*(CRB_SIZE/8) && fifo < end; i += 4, fifo += 4) { 185 pr_err("[%.3d, %p]: 0x%.16lx 0x%.16lx 0x%.16lx 0x%.16lx\n", 186 i, fifo, *fifo, *(fifo+1), *(fifo+2), *(fifo+3)); 187 } 188 } 189 190 /* 191 * Process valid CRBs in fault FIFO. 192 * NX process user space requests, return credit and update the status 193 * in CRB. If it encounters transalation error when accessing CRB or 194 * request buffers, raises interrupt on the CPU to handle the fault. 195 * It takes credit on fault window, updates nx_fault_stamp in CRB with 196 * the following information and pastes CRB in fault FIFO. 197 * 198 * pswid - window ID of the window on which the request is sent. 199 * fault_storage_addr - fault address 200 * 201 * It can raise a single interrupt for multiple faults. Expects OS to 202 * process all valid faults and return credit for each fault on user 203 * space and fault windows. This fault FIFO control will be done with 204 * credit mechanism. NX can continuously paste CRBs until credits are not 205 * available on fault window. Otherwise, returns with RMA_reject. 206 * 207 * Total credits available on fault window: FIFO_SIZE(4MB)/CRBS_SIZE(128) 208 * 209 */ 210 irqreturn_t vas_fault_thread_fn(int irq, void *data) 211 { 212 struct vas_instance *vinst = data; 213 struct coprocessor_request_block *crb, *entry; 214 struct coprocessor_request_block buf; 215 struct vas_window *window; 216 unsigned long flags; 217 void *fifo; 218 219 crb = &buf; 220 221 /* 222 * VAS can interrupt with multiple page faults. So process all 223 * valid CRBs within fault FIFO until reaches invalid CRB. 224 * We use CCW[0] and pswid to validate validate CRBs: 225 * 226 * CCW[0] Reserved bit. When NX pastes CRB, CCW[0]=0 227 * OS sets this bit to 1 after reading CRB. 228 * pswid NX assigns window ID. Set pswid to -1 after 229 * reading CRB from fault FIFO. 230 * 231 * We exit this function if no valid CRBs are available to process. 232 * So acquire fault_lock and reset fifo_in_progress to 0 before 233 * exit. 234 * In case kernel receives another interrupt with different page 235 * fault, interrupt handler returns with IRQ_HANDLED if 236 * fifo_in_progress is set. Means these new faults will be 237 * handled by the current thread. Otherwise set fifo_in_progress 238 * and return IRQ_WAKE_THREAD to wake up thread. 239 */ 240 while (true) { 241 spin_lock_irqsave(&vinst->fault_lock, flags); 242 /* 243 * Advance the fault fifo pointer to next CRB. 244 * Use CRB_SIZE rather than sizeof(*crb) since the latter is 245 * aligned to CRB_ALIGN (256) but the CRB written to by VAS is 246 * only CRB_SIZE in len. 247 */ 248 fifo = vinst->fault_fifo + (vinst->fault_crbs * CRB_SIZE); 249 entry = fifo; 250 251 if ((entry->stamp.nx.pswid == cpu_to_be32(FIFO_INVALID_ENTRY)) 252 || (entry->ccw & cpu_to_be32(CCW0_INVALID))) { 253 vinst->fifo_in_progress = 0; 254 spin_unlock_irqrestore(&vinst->fault_lock, flags); 255 return IRQ_HANDLED; 256 } 257 258 spin_unlock_irqrestore(&vinst->fault_lock, flags); 259 vinst->fault_crbs++; 260 if (vinst->fault_crbs == (vinst->fault_fifo_size / CRB_SIZE)) 261 vinst->fault_crbs = 0; 262 263 memcpy(crb, fifo, CRB_SIZE); 264 entry->stamp.nx.pswid = cpu_to_be32(FIFO_INVALID_ENTRY); 265 entry->ccw |= cpu_to_be32(CCW0_INVALID); 266 /* 267 * Return credit for the fault window. 268 */ 269 vas_return_credit(vinst->fault_win, false); 270 271 pr_devel("VAS[%d] fault_fifo %p, fifo %p, fault_crbs %d\n", 272 vinst->vas_id, vinst->fault_fifo, fifo, 273 vinst->fault_crbs); 274 275 dump_crb(crb); 276 window = vas_pswid_to_window(vinst, 277 be32_to_cpu(crb->stamp.nx.pswid)); 278 279 if (IS_ERR(window)) { 280 /* 281 * We got an interrupt about a specific send 282 * window but we can't find that window and we can't 283 * even clean it up (return credit on user space 284 * window). 285 * But we should not get here. 286 * TODO: Disable IRQ. 287 */ 288 dump_fifo(vinst, (void *)entry); 289 pr_err("VAS[%d] fault_fifo %p, fifo %p, pswid 0x%x, fault_crbs %d bad CRB?\n", 290 vinst->vas_id, vinst->fault_fifo, fifo, 291 be32_to_cpu(crb->stamp.nx.pswid), 292 vinst->fault_crbs); 293 294 WARN_ON_ONCE(1); 295 } else { 296 update_csb(window, crb); 297 /* 298 * Return credit for send window after processing 299 * fault CRB. 300 */ 301 vas_return_credit(window, true); 302 } 303 } 304 } 305 306 irqreturn_t vas_fault_handler(int irq, void *dev_id) 307 { 308 struct vas_instance *vinst = dev_id; 309 irqreturn_t ret = IRQ_WAKE_THREAD; 310 unsigned long flags; 311 312 /* 313 * NX can generate an interrupt for multiple faults. So the 314 * fault handler thread process all CRBs until finds invalid 315 * entry. In case if NX sees continuous faults, it is possible 316 * that the thread function entered with the first interrupt 317 * can execute and process all valid CRBs. 318 * So wake up thread only if the fault thread is not in progress. 319 */ 320 spin_lock_irqsave(&vinst->fault_lock, flags); 321 322 if (vinst->fifo_in_progress) 323 ret = IRQ_HANDLED; 324 else 325 vinst->fifo_in_progress = 1; 326 327 spin_unlock_irqrestore(&vinst->fault_lock, flags); 328 329 return ret; 330 } 331 332 /* 333 * Fault window is opened per VAS instance. NX pastes fault CRB in fault 334 * FIFO upon page faults. 335 */ 336 int vas_setup_fault_window(struct vas_instance *vinst) 337 { 338 struct vas_rx_win_attr attr; 339 340 vinst->fault_fifo_size = VAS_FAULT_WIN_FIFO_SIZE; 341 vinst->fault_fifo = kzalloc(vinst->fault_fifo_size, GFP_KERNEL); 342 if (!vinst->fault_fifo) { 343 pr_err("Unable to alloc %d bytes for fault_fifo\n", 344 vinst->fault_fifo_size); 345 return -ENOMEM; 346 } 347 348 /* 349 * Invalidate all CRB entries. NX pastes valid entry for each fault. 350 */ 351 memset(vinst->fault_fifo, FIFO_INVALID_ENTRY, vinst->fault_fifo_size); 352 vas_init_rx_win_attr(&attr, VAS_COP_TYPE_FAULT); 353 354 attr.rx_fifo_size = vinst->fault_fifo_size; 355 attr.rx_fifo = vinst->fault_fifo; 356 357 /* 358 * Max creds is based on number of CRBs can fit in the FIFO. 359 * (fault_fifo_size/CRB_SIZE). If 8MB FIFO is used, max creds 360 * will be 0xffff since the receive creds field is 16bits wide. 361 */ 362 attr.wcreds_max = vinst->fault_fifo_size / CRB_SIZE; 363 attr.lnotify_lpid = 0; 364 attr.lnotify_pid = mfspr(SPRN_PID); 365 attr.lnotify_tid = mfspr(SPRN_PID); 366 367 vinst->fault_win = vas_rx_win_open(vinst->vas_id, VAS_COP_TYPE_FAULT, 368 &attr); 369 370 if (IS_ERR(vinst->fault_win)) { 371 pr_err("VAS: Error %ld opening FaultWin\n", 372 PTR_ERR(vinst->fault_win)); 373 kfree(vinst->fault_fifo); 374 return PTR_ERR(vinst->fault_win); 375 } 376 377 pr_devel("VAS: Created FaultWin %d, LPID/PID/TID [%d/%d/%d]\n", 378 vinst->fault_win->winid, attr.lnotify_lpid, 379 attr.lnotify_pid, attr.lnotify_tid); 380 381 return 0; 382 } 383