1 // SPDX-License-Identifier: GPL-2.0 2 /* 3 * Copyright (C) 1994 Linus Torvalds 4 * 5 * 29 dec 2001 - Fixed oopses caused by unchecked access to the vm86 6 * stack - Manfred Spraul <manfred@colorfullife.com> 7 * 8 * 22 mar 2002 - Manfred detected the stackfaults, but didn't handle 9 * them correctly. Now the emulation will be in a 10 * consistent state after stackfaults - Kasper Dupont 11 * <kasperd@daimi.au.dk> 12 * 13 * 22 mar 2002 - Added missing clear_IF in set_vflags_* Kasper Dupont 14 * <kasperd@daimi.au.dk> 15 * 16 * ?? ??? 2002 - Fixed premature returns from handle_vm86_fault 17 * caused by Kasper Dupont's changes - Stas Sergeev 18 * 19 * 4 apr 2002 - Fixed CHECK_IF_IN_TRAP broken by Stas' changes. 20 * Kasper Dupont <kasperd@daimi.au.dk> 21 * 22 * 9 apr 2002 - Changed syntax of macros in handle_vm86_fault. 23 * Kasper Dupont <kasperd@daimi.au.dk> 24 * 25 * 9 apr 2002 - Changed stack access macros to jump to a label 26 * instead of returning to userspace. This simplifies 27 * do_int, and is needed by handle_vm6_fault. Kasper 28 * Dupont <kasperd@daimi.au.dk> 29 * 30 */ 31 32 #define pr_fmt(fmt) KBUILD_MODNAME ": " fmt 33 34 #include <linux/capability.h> 35 #include <linux/errno.h> 36 #include <linux/interrupt.h> 37 #include <linux/syscalls.h> 38 #include <linux/sched.h> 39 #include <linux/sched/task_stack.h> 40 #include <linux/kernel.h> 41 #include <linux/signal.h> 42 #include <linux/string.h> 43 #include <linux/mm.h> 44 #include <linux/smp.h> 45 #include <linux/highmem.h> 46 #include <linux/ptrace.h> 47 #include <linux/audit.h> 48 #include <linux/stddef.h> 49 #include <linux/slab.h> 50 #include <linux/security.h> 51 52 #include <linux/uaccess.h> 53 #include <asm/io.h> 54 #include <asm/tlbflush.h> 55 #include <asm/irq.h> 56 #include <asm/traps.h> 57 #include <asm/vm86.h> 58 #include <asm/switch_to.h> 59 60 /* 61 * Known problems: 62 * 63 * Interrupt handling is not guaranteed: 64 * - a real x86 will disable all interrupts for one instruction 65 * after a "mov ss,xx" to make stack handling atomic even without 66 * the 'lss' instruction. We can't guarantee this in v86 mode, 67 * as the next instruction might result in a page fault or similar. 68 * - a real x86 will have interrupts disabled for one instruction 69 * past the 'sti' that enables them. We don't bother with all the 70 * details yet. 71 * 72 * Let's hope these problems do not actually matter for anything. 73 */ 74 75 76 /* 77 * 8- and 16-bit register defines.. 78 */ 79 #define AL(regs) (((unsigned char *)&((regs)->pt.ax))[0]) 80 #define AH(regs) (((unsigned char *)&((regs)->pt.ax))[1]) 81 #define IP(regs) (*(unsigned short *)&((regs)->pt.ip)) 82 #define SP(regs) (*(unsigned short *)&((regs)->pt.sp)) 83 84 /* 85 * virtual flags (16 and 32-bit versions) 86 */ 87 #define VFLAGS (*(unsigned short *)&(current->thread.vm86->veflags)) 88 #define VEFLAGS (current->thread.vm86->veflags) 89 90 #define set_flags(X, new, mask) \ 91 ((X) = ((X) & ~(mask)) | ((new) & (mask))) 92 93 #define SAFE_MASK (0xDD5) 94 #define RETURN_MASK (0xDFF) 95 96 void save_v86_state(struct kernel_vm86_regs *regs, int retval) 97 { 98 struct task_struct *tsk = current; 99 struct vm86plus_struct __user *user; 100 struct vm86 *vm86 = current->thread.vm86; 101 102 /* 103 * This gets called from entry.S with interrupts disabled, but 104 * from process context. Enable interrupts here, before trying 105 * to access user space. 106 */ 107 local_irq_enable(); 108 109 BUG_ON(!vm86); 110 111 set_flags(regs->pt.flags, VEFLAGS, X86_EFLAGS_VIF | vm86->veflags_mask); 112 user = vm86->user_vm86; 113 114 if (!user_access_begin(user, vm86->vm86plus.is_vm86pus ? 115 sizeof(struct vm86plus_struct) : 116 sizeof(struct vm86_struct))) 117 goto Efault; 118 119 unsafe_put_user(regs->pt.bx, &user->regs.ebx, Efault_end); 120 unsafe_put_user(regs->pt.cx, &user->regs.ecx, Efault_end); 121 unsafe_put_user(regs->pt.dx, &user->regs.edx, Efault_end); 122 unsafe_put_user(regs->pt.si, &user->regs.esi, Efault_end); 123 unsafe_put_user(regs->pt.di, &user->regs.edi, Efault_end); 124 unsafe_put_user(regs->pt.bp, &user->regs.ebp, Efault_end); 125 unsafe_put_user(regs->pt.ax, &user->regs.eax, Efault_end); 126 unsafe_put_user(regs->pt.ip, &user->regs.eip, Efault_end); 127 unsafe_put_user(regs->pt.cs, &user->regs.cs, Efault_end); 128 unsafe_put_user(regs->pt.flags, &user->regs.eflags, Efault_end); 129 unsafe_put_user(regs->pt.sp, &user->regs.esp, Efault_end); 130 unsafe_put_user(regs->pt.ss, &user->regs.ss, Efault_end); 131 unsafe_put_user(regs->es, &user->regs.es, Efault_end); 132 unsafe_put_user(regs->ds, &user->regs.ds, Efault_end); 133 unsafe_put_user(regs->fs, &user->regs.fs, Efault_end); 134 unsafe_put_user(regs->gs, &user->regs.gs, Efault_end); 135 136 /* 137 * Don't write screen_bitmap in case some user had a value there 138 * and expected it to remain unchanged. 139 */ 140 141 user_access_end(); 142 143 exit_vm86: 144 preempt_disable(); 145 tsk->thread.sp0 = vm86->saved_sp0; 146 tsk->thread.sysenter_cs = __KERNEL_CS; 147 update_task_stack(tsk); 148 refresh_sysenter_cs(&tsk->thread); 149 vm86->saved_sp0 = 0; 150 preempt_enable(); 151 152 memcpy(®s->pt, &vm86->regs32, sizeof(struct pt_regs)); 153 154 loadsegment(gs, vm86->regs32.gs); 155 156 regs->pt.ax = retval; 157 return; 158 159 Efault_end: 160 user_access_end(); 161 Efault: 162 pr_alert("could not access userspace vm86 info\n"); 163 force_exit_sig(SIGSEGV); 164 goto exit_vm86; 165 } 166 167 static int do_vm86_irq_handling(int subfunction, int irqnumber); 168 static long do_sys_vm86(struct vm86plus_struct __user *user_vm86, bool plus); 169 170 SYSCALL_DEFINE1(vm86old, struct vm86_struct __user *, user_vm86) 171 { 172 return do_sys_vm86((struct vm86plus_struct __user *) user_vm86, false); 173 } 174 175 176 SYSCALL_DEFINE2(vm86, unsigned long, cmd, unsigned long, arg) 177 { 178 switch (cmd) { 179 case VM86_REQUEST_IRQ: 180 case VM86_FREE_IRQ: 181 case VM86_GET_IRQ_BITS: 182 case VM86_GET_AND_RESET_IRQ: 183 return do_vm86_irq_handling(cmd, (int)arg); 184 case VM86_PLUS_INSTALL_CHECK: 185 /* 186 * NOTE: on old vm86 stuff this will return the error 187 * from access_ok(), because the subfunction is 188 * interpreted as (invalid) address to vm86_struct. 189 * So the installation check works. 190 */ 191 return 0; 192 } 193 194 /* we come here only for functions VM86_ENTER, VM86_ENTER_NO_BYPASS */ 195 return do_sys_vm86((struct vm86plus_struct __user *) arg, true); 196 } 197 198 199 static long do_sys_vm86(struct vm86plus_struct __user *user_vm86, bool plus) 200 { 201 struct task_struct *tsk = current; 202 struct vm86 *vm86 = tsk->thread.vm86; 203 struct kernel_vm86_regs vm86regs; 204 struct pt_regs *regs = current_pt_regs(); 205 unsigned long err = 0; 206 struct vm86_struct v; 207 208 err = security_mmap_addr(0); 209 if (err) { 210 /* 211 * vm86 cannot virtualize the address space, so vm86 users 212 * need to manage the low 1MB themselves using mmap. Given 213 * that BIOS places important data in the first page, vm86 214 * is essentially useless if mmap_min_addr != 0. DOSEMU, 215 * for example, won't even bother trying to use vm86 if it 216 * can't map a page at virtual address 0. 217 * 218 * To reduce the available kernel attack surface, simply 219 * disallow vm86(old) for users who cannot mmap at va 0. 220 * 221 * The implementation of security_mmap_addr will allow 222 * suitably privileged users to map va 0 even if 223 * vm.mmap_min_addr is set above 0, and we want this 224 * behavior for vm86 as well, as it ensures that legacy 225 * tools like vbetool will not fail just because of 226 * vm.mmap_min_addr. 227 */ 228 pr_info_once("Denied a call to vm86(old) from %s[%d] (uid: %d). Set the vm.mmap_min_addr sysctl to 0 and/or adjust LSM mmap_min_addr policy to enable vm86 if you are using a vm86-based DOS emulator.\n", 229 current->comm, task_pid_nr(current), 230 from_kuid_munged(&init_user_ns, current_uid())); 231 return -EPERM; 232 } 233 234 if (!vm86) { 235 if (!(vm86 = kzalloc(sizeof(*vm86), GFP_KERNEL))) 236 return -ENOMEM; 237 tsk->thread.vm86 = vm86; 238 } 239 if (vm86->saved_sp0) 240 return -EPERM; 241 242 if (copy_from_user(&v, user_vm86, 243 offsetof(struct vm86_struct, int_revectored))) 244 return -EFAULT; 245 246 247 /* VM86_SCREEN_BITMAP had numerous bugs and appears to have no users. */ 248 if (v.flags & VM86_SCREEN_BITMAP) { 249 char comm[TASK_COMM_LEN]; 250 251 pr_info_once("vm86: '%s' uses VM86_SCREEN_BITMAP, which is no longer supported\n", get_task_comm(comm, current)); 252 return -EINVAL; 253 } 254 255 memset(&vm86regs, 0, sizeof(vm86regs)); 256 257 vm86regs.pt.bx = v.regs.ebx; 258 vm86regs.pt.cx = v.regs.ecx; 259 vm86regs.pt.dx = v.regs.edx; 260 vm86regs.pt.si = v.regs.esi; 261 vm86regs.pt.di = v.regs.edi; 262 vm86regs.pt.bp = v.regs.ebp; 263 vm86regs.pt.ax = v.regs.eax; 264 vm86regs.pt.ip = v.regs.eip; 265 vm86regs.pt.cs = v.regs.cs; 266 vm86regs.pt.flags = v.regs.eflags; 267 vm86regs.pt.sp = v.regs.esp; 268 vm86regs.pt.ss = v.regs.ss; 269 vm86regs.es = v.regs.es; 270 vm86regs.ds = v.regs.ds; 271 vm86regs.fs = v.regs.fs; 272 vm86regs.gs = v.regs.gs; 273 274 vm86->flags = v.flags; 275 vm86->cpu_type = v.cpu_type; 276 277 if (copy_from_user(&vm86->int_revectored, 278 &user_vm86->int_revectored, 279 sizeof(struct revectored_struct))) 280 return -EFAULT; 281 if (copy_from_user(&vm86->int21_revectored, 282 &user_vm86->int21_revectored, 283 sizeof(struct revectored_struct))) 284 return -EFAULT; 285 if (plus) { 286 if (copy_from_user(&vm86->vm86plus, &user_vm86->vm86plus, 287 sizeof(struct vm86plus_info_struct))) 288 return -EFAULT; 289 vm86->vm86plus.is_vm86pus = 1; 290 } else 291 memset(&vm86->vm86plus, 0, 292 sizeof(struct vm86plus_info_struct)); 293 294 memcpy(&vm86->regs32, regs, sizeof(struct pt_regs)); 295 vm86->user_vm86 = user_vm86; 296 297 /* 298 * The flags register is also special: we cannot trust that the user 299 * has set it up safely, so this makes sure interrupt etc flags are 300 * inherited from protected mode. 301 */ 302 VEFLAGS = vm86regs.pt.flags; 303 vm86regs.pt.flags &= SAFE_MASK; 304 vm86regs.pt.flags |= regs->flags & ~SAFE_MASK; 305 vm86regs.pt.flags |= X86_VM_MASK; 306 307 vm86regs.pt.orig_ax = regs->orig_ax; 308 309 switch (vm86->cpu_type) { 310 case CPU_286: 311 vm86->veflags_mask = 0; 312 break; 313 case CPU_386: 314 vm86->veflags_mask = X86_EFLAGS_NT | X86_EFLAGS_IOPL; 315 break; 316 case CPU_486: 317 vm86->veflags_mask = X86_EFLAGS_AC | X86_EFLAGS_NT | X86_EFLAGS_IOPL; 318 break; 319 default: 320 vm86->veflags_mask = X86_EFLAGS_ID | X86_EFLAGS_AC | X86_EFLAGS_NT | X86_EFLAGS_IOPL; 321 break; 322 } 323 324 /* 325 * Save old state 326 */ 327 vm86->saved_sp0 = tsk->thread.sp0; 328 savesegment(gs, vm86->regs32.gs); 329 330 /* make room for real-mode segments */ 331 preempt_disable(); 332 tsk->thread.sp0 += 16; 333 334 if (boot_cpu_has(X86_FEATURE_SEP)) { 335 tsk->thread.sysenter_cs = 0; 336 refresh_sysenter_cs(&tsk->thread); 337 } 338 339 update_task_stack(tsk); 340 preempt_enable(); 341 342 memcpy((struct kernel_vm86_regs *)regs, &vm86regs, sizeof(vm86regs)); 343 return regs->ax; 344 } 345 346 static inline void set_IF(struct kernel_vm86_regs *regs) 347 { 348 VEFLAGS |= X86_EFLAGS_VIF; 349 } 350 351 static inline void clear_IF(struct kernel_vm86_regs *regs) 352 { 353 VEFLAGS &= ~X86_EFLAGS_VIF; 354 } 355 356 static inline void clear_TF(struct kernel_vm86_regs *regs) 357 { 358 regs->pt.flags &= ~X86_EFLAGS_TF; 359 } 360 361 static inline void clear_AC(struct kernel_vm86_regs *regs) 362 { 363 regs->pt.flags &= ~X86_EFLAGS_AC; 364 } 365 366 /* 367 * It is correct to call set_IF(regs) from the set_vflags_* 368 * functions. However someone forgot to call clear_IF(regs) 369 * in the opposite case. 370 * After the command sequence CLI PUSHF STI POPF you should 371 * end up with interrupts disabled, but you ended up with 372 * interrupts enabled. 373 * ( I was testing my own changes, but the only bug I 374 * could find was in a function I had not changed. ) 375 * [KD] 376 */ 377 378 static inline void set_vflags_long(unsigned long flags, struct kernel_vm86_regs *regs) 379 { 380 set_flags(VEFLAGS, flags, current->thread.vm86->veflags_mask); 381 set_flags(regs->pt.flags, flags, SAFE_MASK); 382 if (flags & X86_EFLAGS_IF) 383 set_IF(regs); 384 else 385 clear_IF(regs); 386 } 387 388 static inline void set_vflags_short(unsigned short flags, struct kernel_vm86_regs *regs) 389 { 390 set_flags(VFLAGS, flags, current->thread.vm86->veflags_mask); 391 set_flags(regs->pt.flags, flags, SAFE_MASK); 392 if (flags & X86_EFLAGS_IF) 393 set_IF(regs); 394 else 395 clear_IF(regs); 396 } 397 398 static inline unsigned long get_vflags(struct kernel_vm86_regs *regs) 399 { 400 unsigned long flags = regs->pt.flags & RETURN_MASK; 401 402 if (VEFLAGS & X86_EFLAGS_VIF) 403 flags |= X86_EFLAGS_IF; 404 flags |= X86_EFLAGS_IOPL; 405 return flags | (VEFLAGS & current->thread.vm86->veflags_mask); 406 } 407 408 static inline int is_revectored(int nr, struct revectored_struct *bitmap) 409 { 410 return test_bit(nr, bitmap->__map); 411 } 412 413 #define val_byte(val, n) (((__u8 *)&val)[n]) 414 415 #define pushb(base, ptr, val, err_label) \ 416 do { \ 417 __u8 __val = val; \ 418 ptr--; \ 419 if (put_user(__val, base + ptr) < 0) \ 420 goto err_label; \ 421 } while (0) 422 423 #define pushw(base, ptr, val, err_label) \ 424 do { \ 425 __u16 __val = val; \ 426 ptr--; \ 427 if (put_user(val_byte(__val, 1), base + ptr) < 0) \ 428 goto err_label; \ 429 ptr--; \ 430 if (put_user(val_byte(__val, 0), base + ptr) < 0) \ 431 goto err_label; \ 432 } while (0) 433 434 #define pushl(base, ptr, val, err_label) \ 435 do { \ 436 __u32 __val = val; \ 437 ptr--; \ 438 if (put_user(val_byte(__val, 3), base + ptr) < 0) \ 439 goto err_label; \ 440 ptr--; \ 441 if (put_user(val_byte(__val, 2), base + ptr) < 0) \ 442 goto err_label; \ 443 ptr--; \ 444 if (put_user(val_byte(__val, 1), base + ptr) < 0) \ 445 goto err_label; \ 446 ptr--; \ 447 if (put_user(val_byte(__val, 0), base + ptr) < 0) \ 448 goto err_label; \ 449 } while (0) 450 451 #define popb(base, ptr, err_label) \ 452 ({ \ 453 __u8 __res; \ 454 if (get_user(__res, base + ptr) < 0) \ 455 goto err_label; \ 456 ptr++; \ 457 __res; \ 458 }) 459 460 #define popw(base, ptr, err_label) \ 461 ({ \ 462 __u16 __res; \ 463 if (get_user(val_byte(__res, 0), base + ptr) < 0) \ 464 goto err_label; \ 465 ptr++; \ 466 if (get_user(val_byte(__res, 1), base + ptr) < 0) \ 467 goto err_label; \ 468 ptr++; \ 469 __res; \ 470 }) 471 472 #define popl(base, ptr, err_label) \ 473 ({ \ 474 __u32 __res; \ 475 if (get_user(val_byte(__res, 0), base + ptr) < 0) \ 476 goto err_label; \ 477 ptr++; \ 478 if (get_user(val_byte(__res, 1), base + ptr) < 0) \ 479 goto err_label; \ 480 ptr++; \ 481 if (get_user(val_byte(__res, 2), base + ptr) < 0) \ 482 goto err_label; \ 483 ptr++; \ 484 if (get_user(val_byte(__res, 3), base + ptr) < 0) \ 485 goto err_label; \ 486 ptr++; \ 487 __res; \ 488 }) 489 490 /* There are so many possible reasons for this function to return 491 * VM86_INTx, so adding another doesn't bother me. We can expect 492 * userspace programs to be able to handle it. (Getting a problem 493 * in userspace is always better than an Oops anyway.) [KD] 494 */ 495 static void do_int(struct kernel_vm86_regs *regs, int i, 496 unsigned char __user *ssp, unsigned short sp) 497 { 498 unsigned long __user *intr_ptr; 499 unsigned long segoffs; 500 struct vm86 *vm86 = current->thread.vm86; 501 502 if (regs->pt.cs == BIOSSEG) 503 goto cannot_handle; 504 if (is_revectored(i, &vm86->int_revectored)) 505 goto cannot_handle; 506 if (i == 0x21 && is_revectored(AH(regs), &vm86->int21_revectored)) 507 goto cannot_handle; 508 intr_ptr = (unsigned long __user *) (i << 2); 509 if (get_user(segoffs, intr_ptr)) 510 goto cannot_handle; 511 if ((segoffs >> 16) == BIOSSEG) 512 goto cannot_handle; 513 pushw(ssp, sp, get_vflags(regs), cannot_handle); 514 pushw(ssp, sp, regs->pt.cs, cannot_handle); 515 pushw(ssp, sp, IP(regs), cannot_handle); 516 regs->pt.cs = segoffs >> 16; 517 SP(regs) -= 6; 518 IP(regs) = segoffs & 0xffff; 519 clear_TF(regs); 520 clear_IF(regs); 521 clear_AC(regs); 522 return; 523 524 cannot_handle: 525 save_v86_state(regs, VM86_INTx + (i << 8)); 526 } 527 528 int handle_vm86_trap(struct kernel_vm86_regs *regs, long error_code, int trapno) 529 { 530 struct vm86 *vm86 = current->thread.vm86; 531 532 if (vm86->vm86plus.is_vm86pus) { 533 if ((trapno == 3) || (trapno == 1)) { 534 save_v86_state(regs, VM86_TRAP + (trapno << 8)); 535 return 0; 536 } 537 do_int(regs, trapno, (unsigned char __user *) (regs->pt.ss << 4), SP(regs)); 538 return 0; 539 } 540 if (trapno != 1) 541 return 1; /* we let this handle by the calling routine */ 542 current->thread.trap_nr = trapno; 543 current->thread.error_code = error_code; 544 force_sig(SIGTRAP); 545 return 0; 546 } 547 548 void handle_vm86_fault(struct kernel_vm86_regs *regs, long error_code) 549 { 550 unsigned char opcode; 551 unsigned char __user *csp; 552 unsigned char __user *ssp; 553 unsigned short ip, sp, orig_flags; 554 int data32, pref_done; 555 struct vm86plus_info_struct *vmpi = ¤t->thread.vm86->vm86plus; 556 557 #define CHECK_IF_IN_TRAP \ 558 if (vmpi->vm86dbg_active && vmpi->vm86dbg_TFpendig) \ 559 newflags |= X86_EFLAGS_TF 560 561 orig_flags = *(unsigned short *)®s->pt.flags; 562 563 csp = (unsigned char __user *) (regs->pt.cs << 4); 564 ssp = (unsigned char __user *) (regs->pt.ss << 4); 565 sp = SP(regs); 566 ip = IP(regs); 567 568 data32 = 0; 569 pref_done = 0; 570 do { 571 switch (opcode = popb(csp, ip, simulate_sigsegv)) { 572 case 0x66: /* 32-bit data */ data32 = 1; break; 573 case 0x67: /* 32-bit address */ break; 574 case 0x2e: /* CS */ break; 575 case 0x3e: /* DS */ break; 576 case 0x26: /* ES */ break; 577 case 0x36: /* SS */ break; 578 case 0x65: /* GS */ break; 579 case 0x64: /* FS */ break; 580 case 0xf2: /* repnz */ break; 581 case 0xf3: /* rep */ break; 582 default: pref_done = 1; 583 } 584 } while (!pref_done); 585 586 switch (opcode) { 587 588 /* pushf */ 589 case 0x9c: 590 if (data32) { 591 pushl(ssp, sp, get_vflags(regs), simulate_sigsegv); 592 SP(regs) -= 4; 593 } else { 594 pushw(ssp, sp, get_vflags(regs), simulate_sigsegv); 595 SP(regs) -= 2; 596 } 597 IP(regs) = ip; 598 goto vm86_fault_return; 599 600 /* popf */ 601 case 0x9d: 602 { 603 unsigned long newflags; 604 if (data32) { 605 newflags = popl(ssp, sp, simulate_sigsegv); 606 SP(regs) += 4; 607 } else { 608 newflags = popw(ssp, sp, simulate_sigsegv); 609 SP(regs) += 2; 610 } 611 IP(regs) = ip; 612 CHECK_IF_IN_TRAP; 613 if (data32) 614 set_vflags_long(newflags, regs); 615 else 616 set_vflags_short(newflags, regs); 617 618 goto check_vip; 619 } 620 621 /* int xx */ 622 case 0xcd: { 623 int intno = popb(csp, ip, simulate_sigsegv); 624 IP(regs) = ip; 625 if (vmpi->vm86dbg_active) { 626 if ((1 << (intno & 7)) & vmpi->vm86dbg_intxxtab[intno >> 3]) { 627 save_v86_state(regs, VM86_INTx + (intno << 8)); 628 return; 629 } 630 } 631 do_int(regs, intno, ssp, sp); 632 return; 633 } 634 635 /* iret */ 636 case 0xcf: 637 { 638 unsigned long newip; 639 unsigned long newcs; 640 unsigned long newflags; 641 if (data32) { 642 newip = popl(ssp, sp, simulate_sigsegv); 643 newcs = popl(ssp, sp, simulate_sigsegv); 644 newflags = popl(ssp, sp, simulate_sigsegv); 645 SP(regs) += 12; 646 } else { 647 newip = popw(ssp, sp, simulate_sigsegv); 648 newcs = popw(ssp, sp, simulate_sigsegv); 649 newflags = popw(ssp, sp, simulate_sigsegv); 650 SP(regs) += 6; 651 } 652 IP(regs) = newip; 653 regs->pt.cs = newcs; 654 CHECK_IF_IN_TRAP; 655 if (data32) { 656 set_vflags_long(newflags, regs); 657 } else { 658 set_vflags_short(newflags, regs); 659 } 660 goto check_vip; 661 } 662 663 /* cli */ 664 case 0xfa: 665 IP(regs) = ip; 666 clear_IF(regs); 667 goto vm86_fault_return; 668 669 /* sti */ 670 /* 671 * Damn. This is incorrect: the 'sti' instruction should actually 672 * enable interrupts after the /next/ instruction. Not good. 673 * 674 * Probably needs some horsing around with the TF flag. Aiee.. 675 */ 676 case 0xfb: 677 IP(regs) = ip; 678 set_IF(regs); 679 goto check_vip; 680 681 default: 682 save_v86_state(regs, VM86_UNKNOWN); 683 } 684 685 return; 686 687 check_vip: 688 if ((VEFLAGS & (X86_EFLAGS_VIP | X86_EFLAGS_VIF)) == 689 (X86_EFLAGS_VIP | X86_EFLAGS_VIF)) { 690 save_v86_state(regs, VM86_STI); 691 return; 692 } 693 694 vm86_fault_return: 695 if (vmpi->force_return_for_pic && (VEFLAGS & (X86_EFLAGS_IF | X86_EFLAGS_VIF))) { 696 save_v86_state(regs, VM86_PICRETURN); 697 return; 698 } 699 if (orig_flags & X86_EFLAGS_TF) 700 handle_vm86_trap(regs, 0, X86_TRAP_DB); 701 return; 702 703 simulate_sigsegv: 704 /* FIXME: After a long discussion with Stas we finally 705 * agreed, that this is wrong. Here we should 706 * really send a SIGSEGV to the user program. 707 * But how do we create the correct context? We 708 * are inside a general protection fault handler 709 * and has just returned from a page fault handler. 710 * The correct context for the signal handler 711 * should be a mixture of the two, but how do we 712 * get the information? [KD] 713 */ 714 save_v86_state(regs, VM86_UNKNOWN); 715 } 716 717 /* ---------------- vm86 special IRQ passing stuff ----------------- */ 718 719 #define VM86_IRQNAME "vm86irq" 720 721 static struct vm86_irqs { 722 struct task_struct *tsk; 723 int sig; 724 } vm86_irqs[16]; 725 726 static DEFINE_SPINLOCK(irqbits_lock); 727 static int irqbits; 728 729 #define ALLOWED_SIGS (1 /* 0 = don't send a signal */ \ 730 | (1 << SIGUSR1) | (1 << SIGUSR2) | (1 << SIGIO) | (1 << SIGURG) \ 731 | (1 << SIGUNUSED)) 732 733 static irqreturn_t irq_handler(int intno, void *dev_id) 734 { 735 int irq_bit; 736 unsigned long flags; 737 738 spin_lock_irqsave(&irqbits_lock, flags); 739 irq_bit = 1 << intno; 740 if ((irqbits & irq_bit) || !vm86_irqs[intno].tsk) 741 goto out; 742 irqbits |= irq_bit; 743 if (vm86_irqs[intno].sig) 744 send_sig(vm86_irqs[intno].sig, vm86_irqs[intno].tsk, 1); 745 /* 746 * IRQ will be re-enabled when user asks for the irq (whether 747 * polling or as a result of the signal) 748 */ 749 disable_irq_nosync(intno); 750 spin_unlock_irqrestore(&irqbits_lock, flags); 751 return IRQ_HANDLED; 752 753 out: 754 spin_unlock_irqrestore(&irqbits_lock, flags); 755 return IRQ_NONE; 756 } 757 758 static inline void free_vm86_irq(int irqnumber) 759 { 760 unsigned long flags; 761 762 free_irq(irqnumber, NULL); 763 vm86_irqs[irqnumber].tsk = NULL; 764 765 spin_lock_irqsave(&irqbits_lock, flags); 766 irqbits &= ~(1 << irqnumber); 767 spin_unlock_irqrestore(&irqbits_lock, flags); 768 } 769 770 void release_vm86_irqs(struct task_struct *task) 771 { 772 int i; 773 for (i = FIRST_VM86_IRQ ; i <= LAST_VM86_IRQ; i++) 774 if (vm86_irqs[i].tsk == task) 775 free_vm86_irq(i); 776 } 777 778 static inline int get_and_reset_irq(int irqnumber) 779 { 780 int bit; 781 unsigned long flags; 782 int ret = 0; 783 784 if (invalid_vm86_irq(irqnumber)) return 0; 785 if (vm86_irqs[irqnumber].tsk != current) return 0; 786 spin_lock_irqsave(&irqbits_lock, flags); 787 bit = irqbits & (1 << irqnumber); 788 irqbits &= ~bit; 789 if (bit) { 790 enable_irq(irqnumber); 791 ret = 1; 792 } 793 794 spin_unlock_irqrestore(&irqbits_lock, flags); 795 return ret; 796 } 797 798 799 static int do_vm86_irq_handling(int subfunction, int irqnumber) 800 { 801 int ret; 802 switch (subfunction) { 803 case VM86_GET_AND_RESET_IRQ: { 804 return get_and_reset_irq(irqnumber); 805 } 806 case VM86_GET_IRQ_BITS: { 807 return irqbits; 808 } 809 case VM86_REQUEST_IRQ: { 810 int sig = irqnumber >> 8; 811 int irq = irqnumber & 255; 812 if (!capable(CAP_SYS_ADMIN)) return -EPERM; 813 if (!((1 << sig) & ALLOWED_SIGS)) return -EPERM; 814 if (invalid_vm86_irq(irq)) return -EPERM; 815 if (vm86_irqs[irq].tsk) return -EPERM; 816 ret = request_irq(irq, &irq_handler, 0, VM86_IRQNAME, NULL); 817 if (ret) return ret; 818 vm86_irqs[irq].sig = sig; 819 vm86_irqs[irq].tsk = current; 820 return irq; 821 } 822 case VM86_FREE_IRQ: { 823 if (invalid_vm86_irq(irqnumber)) return -EPERM; 824 if (!vm86_irqs[irqnumber].tsk) return 0; 825 if (vm86_irqs[irqnumber].tsk != current) return -EPERM; 826 free_vm86_irq(irqnumber); 827 return 0; 828 } 829 } 830 return -EINVAL; 831 } 832 833