1 ;------------------------------------------------------------------------------ 2 ; 3 ; Copyright (c) 2013-2015 Intel Corporation. 4 ; 5 ; This program and the accompanying materials 6 ; are licensed and made available under the terms and conditions of the BSD License 7 ; which accompanies this distribution. The full text of the license may be found at 8 ; http://opensource.org/licenses/bsd-license.php 9 ; 10 ; THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS, 11 ; WITHOUT WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED. 12 ; 13 ; Module Name: 14 ; 15 ; Flat32.asm 16 ; 17 ; Abstract: 18 ; 19 ; This is the code that goes from real-mode to protected mode. 20 ; It consumes the reset vector, configures the stack. 21 ; 22 ; 23 ;------------------------------------------------------------------------------ 24 25 26 ; 27 ; Define assembler characteristics 28 ; 29 .586p 30 .model flat, c 31 32 ; 33 ; Include processor definitions 34 ; 35 36 INCLUDE Platform.inc 37 38 39 ; 40 ; CR0 cache control bit definition 41 ; 42 CR0_CACHE_DISABLE EQU 040000000h 43 CR0_NO_WRITE EQU 020000000h 44 45 ; 46 ; External and public declarations 47 ; TopOfStack is used by C code 48 ; SecStartup is the entry point to the C code 49 ; Neither of these names can be modified without 50 ; updating the C code. 51 ; 52 EXTRN PlatformSecLibStartup: NEAR 53 EXTERNDEF C PcdGet32 (PcdEsramStage1Base):DWORD 54 55 ; 56 ; Contrary to the name, this file contains 16 bit code as well. 57 ; 58 _TEXT_REALMODE SEGMENT PARA PUBLIC USE16 'CODE' 59 ASSUME CS:_TEXT_REALMODE, DS:_TEXT_REALMODE 60 61 ;---------------------------------------------------------------------------- 62 ; 63 ; Procedure: _ModuleEntryPoint 64 ; 65 ; Input: None 66 ; 67 ; Output: None 68 ; 69 ; Destroys: Assume all registers 70 ; 71 ; Description: 72 ; 73 ; Transition to non-paged flat-model protected mode from a 74 ; hard-coded GDT that provides exactly two descriptors. 75 ; This is a bare bones transition to protected mode only 76 ; used for a while in PEI and possibly DXE. 77 ; 78 ; After enabling protected mode, a far jump is executed to 79 ; transfer to PEI using the newly loaded GDT. 80 ; 81 ; Return: None 82 ; 83 ;---------------------------------------------------------------------------- 84 align 16 85 _ModuleEntryPoint PROC C PUBLIC 86 87 ; 88 ; Warm Reset (INIT#) check. 89 ; 90 mov si, 0F000h 91 mov ds, si 92 mov si, 0FFF0h 93 cmp BYTE PTR [si], 0EAh ; Is it warm reset ? 94 jne NotWarmReset ; JIf not. 95 96 mov al, 08 97 mov dx, 0cf9h 98 out dx, al 99 mov al, 055h 100 out 080h, al; 101 jmp $ 102 NotWarmReset: 103 104 ; 105 ; Load the GDT table in GdtDesc 106 ; 107 mov esi, OFFSET GdtDesc 108 db 66h 109 lgdt fword ptr cs:[si] 110 111 ; 112 ; Transition to 16 bit protected mode 113 ; 114 mov eax, cr0 ; Get control register 0 115 or eax, 00000003h ; Set PE bit (bit #0) & MP bit (bit #1) 116 mov cr0, eax ; Activate protected mode 117 118 ; 119 ; Now we're in 16 bit protected mode 120 ; Set up the selectors for 32 bit protected mode entry 121 ; 122 mov ax, SYS_DATA_SEL 123 mov ds, ax 124 mov es, ax 125 mov fs, ax 126 mov gs, ax 127 mov ss, ax 128 129 ; 130 ; Transition to Flat 32 bit protected mode 131 ; The jump to a far pointer causes the transition to 32 bit mode 132 ; 133 mov esi, offset ProtectedModeEntryLinearAddress 134 jmp fword ptr cs:[si] 135 136 _ModuleEntryPoint ENDP 137 138 _TEXT_REALMODE ENDS 139 140 .code 141 ; 142 ; Protected mode portion initializes stack, configures cache, and calls C entry point 143 ; 144 145 ;---------------------------------------------------------------------------- 146 ; 147 ; Procedure: ProtectedModeEntryPoint 148 ; 149 ; Input: Executing in 32 Bit Protected (flat) mode 150 ; cs: 0-4GB 151 ; ds: 0-4GB 152 ; es: 0-4GB 153 ; fs: 0-4GB 154 ; gs: 0-4GB 155 ; ss: 0-4GB 156 ; 157 ; Output: This function never returns 158 ; 159 ; Destroys: 160 ; ecx 161 ; edi 162 ; esi 163 ; esp 164 ; 165 ; Description: 166 ; Perform any essential early platform initilaisation 167 ; Setup a stack 168 ; Call the main EDKII Sec C code 169 ; 170 ;---------------------------------------------------------------------------- 171 172 ProtectedModeEntryPoint PROC NEAR C PUBLIC 173 174 JMP32 stackless_EarlyPlatformInit 175 176 ; 177 ; Set up stack pointer 178 ; 179 mov esp, PcdGet32(PcdEsramStage1Base) 180 mov esi, QUARK_ESRAM_MEM_SIZE_BYTES 181 add esp, esi ; ESP = top of stack (stack grows downwards). 182 183 ; 184 ; Store the the BIST value in EBP 185 ; 186 mov ebp, 00h ; No processor BIST on Quark 187 188 ; 189 ; Push processor count to stack first, then BIST status (AP then BSP) 190 ; 191 mov eax, 1 192 cpuid 193 shr ebx, 16 194 and ebx, 0000000FFh 195 cmp bl, 1 196 jae PushProcessorCount 197 198 ; 199 ; Some processors report 0 logical processors. Effectively 0 = 1. 200 ; So we fix up the processor count 201 ; 202 inc ebx 203 204 PushProcessorCount: 205 push ebx 206 207 ; 208 ; We need to implement a long-term solution for BIST capture. For now, we just copy BSP BIST 209 ; for all processor threads 210 ; 211 xor ecx, ecx 212 mov cl, bl 213 PushBist: 214 push ebp 215 loop PushBist 216 217 ; 218 ; Pass Control into the PEI Core 219 ; 220 call PlatformSecLibStartup 221 222 ; 223 ; PEI Core should never return to here, this is just to capture an invalid return. 224 ; 225 jmp $ 226 227 ProtectedModeEntryPoint ENDP 228 229 ;---------------------------------------------------------------------------- 230 ; 231 ; Procedure: stackless_EarlyPlatformInit 232 ; 233 ; Input: esp - Return address 234 ; 235 ; Output: None 236 ; 237 ; Destroys: 238 ; eax 239 ; ecx 240 ; dx 241 ; ebp 242 ; 243 ; Description: 244 ; Any essential early platform initialisation required: 245 ; (1) Disable Cache 246 ; (2) Disable NMI's/SMI's 247 ; (3) Setup HMBOUND (defines what memory accesses go to MMIO/RAM) 248 ; (4) Setup eSRAM (provide early memory to the system) 249 ; (5) Setup PCIEXBAR access mechanism 250 ; (6) Open up full SPI flash decode 251 ; 252 ;---------------------------------------------------------------------------- 253 stackless_EarlyPlatformInit PROC NEAR C PUBLIC 254 255 ; 256 ; Save return address 257 ; 258 mov ebp, esp 259 260 ; 261 ; Ensure cache is disabled. 262 ; 263 mov eax, cr0 264 or eax, CR0_CACHE_DISABLE + CR0_NO_WRITE 265 invd 266 mov cr0, eax 267 268 ; 269 ; Disable NMI 270 ; Good convention suggests you should read back RTC data port after 271 ; accessing the RTC index port. 272 ; 273 mov al, NMI_DISABLE 274 mov dx, RTC_INDEX 275 out dx, al 276 mov dx, RTC_DATA 277 in al, dx 278 279 ; 280 ; Disable SMI (Disables SMI wire, not SMI messages) 281 ; 282 mov ecx, (OPCODE_SIDEBAND_REG_READ SHL SB_OPCODE_FIELD) OR (HOST_BRIDGE_PORT_ID SHL SB_PORT_FIELD) OR (HMISC2_OFFSET SHL SB_ADDR_FIELD) 283 JMP32 stackless_SideBand_Read 284 and eax, NOT (SMI_EN) 285 mov ecx, (OPCODE_SIDEBAND_REG_WRITE SHL SB_OPCODE_FIELD) OR (HOST_BRIDGE_PORT_ID SHL SB_PORT_FIELD) OR (HMISC2_OFFSET SHL SB_ADDR_FIELD) 286 JMP32 stackless_SideBand_Write 287 288 ; 289 ; Before we get going, check SOC Unit Registers to see if we are required to issue a warm/cold reset 290 ; 291 mov ecx, (OPCODE_SIDEBAND_ALT_REG_READ SHL SB_OPCODE_FIELD) OR (SOC_UNIT_PORT_ID SHL SB_PORT_FIELD) OR (CFGNONSTICKY_W1_OFFSET SHL SB_ADDR_FIELD) 292 JMP32 stackless_SideBand_Read 293 and eax, FORCE_WARM_RESET 294 jz TestForceColdReset ; Zero means bit clear, we're not requested to warm reset so continue as normal 295 jmp IssueWarmReset 296 297 TestForceColdReset: 298 mov ecx, (OPCODE_SIDEBAND_ALT_REG_READ SHL SB_OPCODE_FIELD) OR (SOC_UNIT_PORT_ID SHL SB_PORT_FIELD) OR (CFGSTICKY_W1_OFFSET SHL SB_ADDR_FIELD) 299 JMP32 stackless_SideBand_Read 300 and eax, FORCE_COLD_RESET 301 jz TestHmboundLock ; Zero means bit clear, we're not requested to cold reset so continue as normal 302 jmp IssueColdReset 303 304 ; 305 ; Before setting HMBOUND, check it's not locked 306 ; 307 TestHmboundLock: 308 mov ecx, (OPCODE_SIDEBAND_REG_READ SHL SB_OPCODE_FIELD) OR (HOST_BRIDGE_PORT_ID SHL SB_PORT_FIELD) OR (HMBOUND_OFFSET SHL SB_ADDR_FIELD) 309 JMP32 stackless_SideBand_Read 310 and eax, HMBOUND_LOCK 311 jz ConfigHmbound ; Zero means bit clear, we have the config we want so continue as normal 312 ; 313 ; Failed to config - store sticky bit debug 314 ; 315 mov ecx, (OPCODE_SIDEBAND_ALT_REG_READ SHL SB_OPCODE_FIELD) OR (SOC_UNIT_PORT_ID SHL SB_PORT_FIELD) OR (CFGSTICKY_RW_OFFSET SHL SB_ADDR_FIELD) 316 JMP32 stackless_SideBand_Read 317 or eax, RESET_FOR_HMBOUND_LOCK ; Set the bit we're interested in 318 mov ecx, (OPCODE_SIDEBAND_ALT_REG_WRITE SHL SB_OPCODE_FIELD) OR (SOC_UNIT_PORT_ID SHL SB_PORT_FIELD) OR (CFGSTICKY_RW_OFFSET SHL SB_ADDR_FIELD) 319 JMP32 stackless_SideBand_Write 320 jmp IssueWarmReset 321 322 ; 323 ; Set up the HMBOUND register 324 ; 325 ConfigHmbound: 326 mov eax, HMBOUND_ADDRESS ; Data (Set HMBOUND location) 327 mov ecx, (OPCODE_SIDEBAND_REG_WRITE SHL SB_OPCODE_FIELD) OR (HOST_BRIDGE_PORT_ID SHL SB_PORT_FIELD) OR (HMBOUND_OFFSET SHL SB_ADDR_FIELD) 328 JMP32 stackless_SideBand_Write 329 330 ; 331 ; Enable interrupts to Remote Management Unit when a IMR/SMM/HMBOUND violation occurs. 332 ; 333 mov eax, ENABLE_IMR_INTERRUPT ; Data (Set interrupt enable mask) 334 mov ecx, (OPCODE_SIDEBAND_REG_WRITE SHL SB_OPCODE_FIELD) OR (MEMORY_MANAGER_PORT_ID SHL SB_PORT_FIELD) OR (BIMRVCTL_OFFSET SHL SB_ADDR_FIELD) 335 JMP32 stackless_SideBand_Write 336 337 ; 338 ; Set eSRAM address 339 ; 340 mov eax, PcdGet32 (PcdEsramStage1Base) ; Data (Set eSRAM location) 341 shr eax, 18h ; Data (Set eSRAM location) 342 add eax, BLOCK_ENABLE_PG 343 mov ecx, (OPCODE_SIDEBAND_REG_WRITE SHL SB_OPCODE_FIELD) OR (MEMORY_MANAGER_PORT_ID SHL SB_PORT_FIELD) OR (ESRAMPGCTRL_BLOCK_OFFSET SHL SB_ADDR_FIELD) 344 JMP32 stackless_SideBand_Write 345 ; 346 ; Check that we're not blocked from setting the config that we want. 347 ; 348 mov ecx, (OPCODE_SIDEBAND_REG_READ SHL SB_OPCODE_FIELD) OR (MEMORY_MANAGER_PORT_ID SHL SB_PORT_FIELD) OR (ESRAMPGCTRL_BLOCK_OFFSET SHL SB_ADDR_FIELD) 349 JMP32 stackless_SideBand_Read 350 and eax, BLOCK_ENABLE_PG 351 jnz ConfigPci ; Non-zero means bit set, we have the config we want so continue as normal 352 ; 353 ; Failed to config - store sticky bit debug 354 ; 355 mov ecx, (OPCODE_SIDEBAND_ALT_REG_READ SHL SB_OPCODE_FIELD) OR (SOC_UNIT_PORT_ID SHL SB_PORT_FIELD) OR (CFGSTICKY_RW_OFFSET SHL SB_ADDR_FIELD) 356 JMP32 stackless_SideBand_Read 357 or eax, RESET_FOR_ESRAM_LOCK ; Set the bit we're interested in 358 mov ecx, (OPCODE_SIDEBAND_ALT_REG_WRITE SHL SB_OPCODE_FIELD) OR (SOC_UNIT_PORT_ID SHL SB_PORT_FIELD) OR (CFGSTICKY_RW_OFFSET SHL SB_ADDR_FIELD) 359 JMP32 stackless_SideBand_Write 360 jmp IssueWarmReset 361 362 ; 363 ; Enable PCIEXBAR 364 ; 365 ConfigPci: 366 mov eax, (EC_BASE + EC_ENABLE) ; Data 367 mov ecx, (OPCODE_SIDEBAND_REG_WRITE SHL SB_OPCODE_FIELD) OR (MEMORY_ARBITER_PORT_ID SHL SB_PORT_FIELD) OR (AEC_CTRL_OFFSET SHL SB_ADDR_FIELD) 368 JMP32 stackless_SideBand_Write 369 370 mov eax, (EC_BASE + EC_ENABLE) ; Data 371 mov ecx, (OPCODE_SIDEBAND_REG_WRITE SHL SB_OPCODE_FIELD) OR (HOST_BRIDGE_PORT_ID SHL SB_PORT_FIELD) OR (HECREG_OFFSET SHL SB_ADDR_FIELD) 372 JMP32 stackless_SideBand_Write 373 374 ; 375 ; Open up full 8MB SPI decode 376 ; 377 mov ebx, PCI_CFG OR (ILB_PFA SHL 8) OR BDE ; PCI Configuration address 378 mov eax, DECODE_ALL_REGIONS_ENABLE 379 JMP32 stackless_PCIConfig_Write 380 381 ; 382 ; Enable NMI operation 383 ; Good convention suggests you should read back RTC data port after 384 ; accessing the RTC index port. 385 ; 386 mov al, NMI_ENABLE 387 mov dx, RTC_INDEX 388 out dx, al 389 mov dx, RTC_DATA 390 in al, dx 391 392 ; 393 ; Clear Host Bridge SMI, NMI, INTR fields 394 ; 395 mov ecx, (OPCODE_SIDEBAND_REG_READ SHL SB_OPCODE_FIELD) OR (HOST_BRIDGE_PORT_ID SHL SB_PORT_FIELD) OR (HLEGACY_OFFSET SHL SB_ADDR_FIELD) 396 JMP32 stackless_SideBand_Read 397 and eax, NOT(NMI + SMI + INTR) ; Clear NMI, SMI, INTR fields 398 mov ecx, (OPCODE_SIDEBAND_REG_WRITE SHL SB_OPCODE_FIELD) OR (HOST_BRIDGE_PORT_ID SHL SB_PORT_FIELD) OR (HLEGACY_OFFSET SHL SB_ADDR_FIELD) 399 JMP32 stackless_SideBand_Write 400 401 ; 402 ; Restore return address 403 ; 404 mov esp, ebp 405 RET32 406 407 IssueWarmReset: 408 ; 409 ; Issue Warm Reset request to Remote Management Unit via iLB 410 ; 411 mov ax, CF9_WARM_RESET 412 mov dx, ILB_RESET_REG 413 out dx, ax 414 jmp $ ; Stay here until we are reset. 415 416 IssueColdReset: 417 ; 418 ; Issue Cold Reset request to Remote Management Unit via iLB 419 ; 420 mov ax, CF9_COLD_RESET 421 mov dx, ILB_RESET_REG 422 out dx, ax 423 jmp $ ; Stay here until we are reset. 424 425 stackless_EarlyPlatformInit ENDP 426 427 ;---------------------------------------------------------------------------- 428 ; 429 ; Procedure: stackless_SideBand_Read 430 ; 431 ; Input: esp - return address 432 ; ecx[15:8] - Register offset 433 ; ecx[23:16] - Port ID 434 ; ecx[31:24] - Opcode 435 ; 436 ; Output: eax - Data read 437 ; 438 ; Destroys: 439 ; eax 440 ; ebx 441 ; cl 442 ; esi 443 ; 444 ; Description: 445 ; Perform requested sideband read 446 ; 447 ;---------------------------------------------------------------------------- 448 stackless_SideBand_Read PROC NEAR C PUBLIC 449 450 mov esi, esp ; Save the return address 451 452 ; 453 ; Load the SideBand Packet Register to generate the transaction 454 ; 455 mov ebx, PCI_CFG OR (HOST_BRIDGE_PFA SHL 8) OR MESSAGE_BUS_CONTROL_REG ; PCI Configuration address 456 mov cl, (ALL_BYTE_EN SHL SB_BE_FIELD) ; Set all Byte Enable bits 457 xchg eax, ecx 458 JMP32 stackless_PCIConfig_Write 459 xchg eax, ecx 460 461 ; 462 ; Read the SideBand Data Register 463 ; 464 mov ebx, PCI_CFG OR (HOST_BRIDGE_PFA SHL 8) OR MESSAGE_DATA_REG ; PCI Configuration address 465 JMP32 stackless_PCIConfig_Read 466 467 mov esp, esi ; Restore the return address 468 RET32 469 470 stackless_SideBand_Read ENDP 471 472 ;---------------------------------------------------------------------------- 473 ; 474 ; Procedure: stackless_SideBand_Write 475 ; 476 ; Input: esp - return address 477 ; eax - Data 478 ; ecx[15:8] - Register offset 479 ; ecx[23:16] - Port ID 480 ; ecx[31:24] - Opcode 481 ; 482 ; Output: None 483 ; 484 ; Destroys: 485 ; ebx 486 ; cl 487 ; esi 488 ; 489 ; Description: 490 ; Perform requested sideband write 491 ; 492 ; 493 ;---------------------------------------------------------------------------- 494 stackless_SideBand_Write PROC NEAR C PUBLIC 495 496 mov esi, esp ; Save the return address 497 498 ; 499 ; Load the SideBand Data Register with the data 500 ; 501 mov ebx, PCI_CFG OR (HOST_BRIDGE_PFA SHL 8) OR MESSAGE_DATA_REG ; PCI Configuration address 502 JMP32 stackless_PCIConfig_Write 503 504 ; 505 ; Load the SideBand Packet Register to generate the transaction 506 ; 507 mov ebx, PCI_CFG OR (HOST_BRIDGE_PFA SHL 8) OR MESSAGE_BUS_CONTROL_REG ; PCI Configuration address 508 mov cl, (ALL_BYTE_EN SHL SB_BE_FIELD) ; Set all Byte Enable bits 509 xchg eax, ecx 510 JMP32 stackless_PCIConfig_Write 511 xchg eax, ecx 512 513 mov esp, esi ; Restore the return address 514 RET32 515 516 stackless_SideBand_Write ENDP 517 518 ;---------------------------------------------------------------------------- 519 ; 520 ; Procedure: stackless_PCIConfig_Write 521 ; 522 ; Input: esp - return address 523 ; eax - Data to write 524 ; ebx - PCI Config Address 525 ; 526 ; Output: None 527 ; 528 ; Destroys: 529 ; dx 530 ; 531 ; Description: 532 ; Perform a DWORD PCI Configuration write 533 ; 534 ;---------------------------------------------------------------------------- 535 stackless_PCIConfig_Write PROC NEAR C PUBLIC 536 537 ; 538 ; Write the PCI Config Address to the address port 539 ; 540 xchg eax, ebx 541 mov dx, PCI_ADDRESS_PORT 542 out dx, eax 543 xchg eax, ebx 544 545 ; 546 ; Write the PCI DWORD Data to the data port 547 ; 548 mov dx, PCI_DATA_PORT 549 out dx, eax 550 551 RET32 552 553 stackless_PCIConfig_Write ENDP 554 555 ;---------------------------------------------------------------------------- 556 ; 557 ; Procedure: stackless_PCIConfig_Read 558 ; 559 ; Input: esp - return address 560 ; ebx - PCI Config Address 561 ; 562 ; Output: eax - Data read 563 ; 564 ; Destroys: 565 ; eax 566 ; dx 567 ; 568 ; Description: 569 ; Perform a DWORD PCI Configuration read 570 ; 571 ;---------------------------------------------------------------------------- 572 stackless_PCIConfig_Read PROC NEAR C PUBLIC 573 574 ; 575 ; Write the PCI Config Address to the address port 576 ; 577 xchg eax, ebx 578 mov dx, PCI_ADDRESS_PORT 579 out dx, eax 580 xchg eax, ebx 581 582 ; 583 ; Read the PCI DWORD Data from the data port 584 ; 585 mov dx, PCI_DATA_PORT 586 in eax, dx 587 588 RET32 589 590 stackless_PCIConfig_Read ENDP 591 592 ; 593 ; ROM-based Global-Descriptor Table for the Tiano PEI Phase 594 ; 595 align 16 596 PUBLIC BootGdtTable 597 598 ; 599 ; GDT[0]: 0x00: Null entry, never used. 600 ; 601 NULL_SEL equ $ - GDT_BASE ; Selector [0] 602 GDT_BASE: 603 BootGdtTable DD 0 604 DD 0 605 ; 606 ; Linear data segment descriptor 607 ; 608 LINEAR_SEL equ $ - GDT_BASE ; Selector [0x8] 609 DW 0FFFFh ; limit 0xFFFF 610 DW 0 ; base 0 611 DB 0 612 DB 092h ; present, ring 0, data, expand-up, writable 613 DB 0CFh ; page-granular, 32-bit 614 DB 0 615 ; 616 ; Linear code segment descriptor 617 ; 618 LINEAR_CODE_SEL equ $ - GDT_BASE ; Selector [0x10] 619 DW 0FFFFh ; limit 0xFFFF 620 DW 0 ; base 0 621 DB 0 622 DB 09Bh ; present, ring 0, data, expand-up, not-writable 623 DB 0CFh ; page-granular, 32-bit 624 DB 0 625 ; 626 ; System data segment descriptor 627 ; 628 SYS_DATA_SEL equ $ - GDT_BASE ; Selector [0x18] 629 DW 0FFFFh ; limit 0xFFFF 630 DW 0 ; base 0 631 DB 0 632 DB 093h ; present, ring 0, data, expand-up, not-writable 633 DB 0CFh ; page-granular, 32-bit 634 DB 0 635 636 ; 637 ; System code segment descriptor 638 ; 639 SYS_CODE_SEL equ $ - GDT_BASE ; Selector [0x20] 640 DW 0FFFFh ; limit 0xFFFF 641 DW 0 ; base 0 642 DB 0 643 DB 09Ah ; present, ring 0, data, expand-up, writable 644 DB 0CFh ; page-granular, 32-bit 645 DB 0 646 ; 647 ; Spare segment descriptor 648 ; 649 SYS16_CODE_SEL equ $ - GDT_BASE ; Selector [0x28] 650 DW 0FFFFh ; limit 0xFFFF 651 DW 0 ; base 0 652 DB 0Fh 653 DB 09Bh ; present, ring 0, code, expand-up, writable 654 DB 00h ; byte-granular, 16-bit 655 DB 0 656 ; 657 ; Spare segment descriptor 658 ; 659 SYS16_DATA_SEL equ $ - GDT_BASE ; Selector [0x30] 660 DW 0FFFFh ; limit 0xFFFF 661 DW 0 ; base 0 662 DB 0 663 DB 093h ; present, ring 0, data, expand-up, not-writable 664 DB 00h ; byte-granular, 16-bit 665 DB 0 666 667 ; 668 ; Spare segment descriptor 669 ; 670 SPARE5_SEL equ $ - GDT_BASE ; Selector [0x38] 671 DW 0 ; limit 0xFFFF 672 DW 0 ; base 0 673 DB 0 674 DB 0 ; present, ring 0, data, expand-up, writable 675 DB 0 ; page-granular, 32-bit 676 DB 0 677 GDT_SIZE EQU $ - BootGDTtable ; Size, in bytes 678 679 ; 680 ; GDT Descriptor 681 ; 682 GdtDesc: ; GDT descriptor 683 DW GDT_SIZE - 1 ; GDT limit 684 DD OFFSET BootGdtTable ; GDT base address 685 686 ProtectedModeEntryLinearAddress LABEL FWORD 687 ProtectedModeEntryLinearOffset LABEL DWORD 688 DD OFFSET ProtectedModeEntryPoint ; Offset of our 32 bit code 689 DW LINEAR_CODE_SEL 690 691 END 692