ref: e81c54ba2ecc673a4d5f8aed0e9b52841fe07b0d
dir: /os/pc/l.s/
#include "mem.h" #define PADDR(a) ((a) & ~KZERO) #define KADDR(a) (KZERO|(a)) /* * Some machine instructions not handled by 8[al]. */ #define OP16 BYTE $0x66 #define DELAY BYTE $0xEB; BYTE $0x00 /* JMP .+2 */ #define CPUID BYTE $0x0F; BYTE $0xA2 /* CPUID, argument in AX */ #define WRMSR BYTE $0x0F; BYTE $0x30 /* WRMSR, argument in AX/DX (lo/hi) */ #define RDTSC BYTE $0x0F; BYTE $0x31 /* RDTSC, result in AX/DX (lo/hi) */ #define RDMSR BYTE $0x0F; BYTE $0x32 /* RDMSR, result in AX/DX (lo/hi) */ #define WBINVD BYTE $0x0F; BYTE $0x09 #define HLT BYTE $0xF4 /* * Macros for calculating offsets within the page directory base * and page tables. Note that these are assembler-specific hence * the '<<2'. */ #define PDO(a) (((((a))>>22) & 0x03FF)<<2) #define PTO(a) (((((a))>>12) & 0x03FF)<<2) /* * For backwards compatiblity with 9load - should go away when 9load is changed * 9load currently sets up the mmu, however the first 16MB of memory is identity * mapped, so behave as if the mmu was not setup */ TEXT _start0x80100020(SB), $0 MOVL $_start0x00100020(SB), AX ANDL $~KZERO, AX JMP* AX /* * Must be 4-byte aligned. */ TEXT _multibootheader(SB), $0 LONG $0x1BADB002 /* magic */ LONG $0x00010003 /* flags */ LONG $-(0x1BADB002 + 0x00010003) /* checksum */ LONG $_multibootheader-KZERO(SB) /* header_addr */ LONG $_start0x80100020-KZERO(SB) /* load_addr */ LONG $edata-KZERO(SB) /* load_end_addr */ LONG $end-KZERO(SB) /* bss_end_addr */ LONG $_start0x80100020-KZERO(SB) /* entry_addr */ LONG $0 /* mode_type */ LONG $0 /* width */ LONG $0 /* height */ LONG $0 /* depth */ /* * In protected mode with paging turned off and segment registers setup to linear map all memory. * Entered via a jump to 0x00100020, the physical address of the virtual kernel entry point of 0x80100020 * Make the basic page tables for processor 0. Four pages are needed for the basic set: * a page directory, a page table for mapping the first 4MB of physical memory to KZERO, * and virtual and physical pages for mapping the Mach structure. * The remaining PTEs will be allocated later when memory is sized. * An identity mmu map is also needed for the switch to virtual mode. This * identity mapping is removed once the MMU is going and the JMP has been made * to virtual memory. */ TEXT _start0x00100020(SB), $0 CLI /* make sure interrupts are off */ /* set up the gdt so we have sane plan 9 style gdts. */ MOVL $tgdtptr(SB), AX ANDL $~KZERO, AX MOVL (AX), GDTR MOVW $1, AX MOVW AX, MSW /* clear prefetch queue (weird code to avoid optimizations) */ DELAY /* set segs to something sane (avoid traps later) */ MOVW $(1<<3), AX MOVW AX, DS MOVW AX, SS MOVW AX, ES MOVW AX, FS MOVW AX, GS /* JMP $(2<<3):$mode32bit(SB) /**/ BYTE $0xEA LONG $mode32bit-KZERO(SB) WORD $(2<<3) /* * gdt to get us to 32-bit/segmented/unpaged mode */ TEXT tgdt(SB), $0 /* null descriptor */ LONG $0 LONG $0 /* data segment descriptor for 4 gigabytes (PL 0) */ LONG $(0xFFFF) LONG $(SEGG|SEGB|(0xF<<16)|SEGP|SEGPL(0)|SEGDATA|SEGW) /* exec segment descriptor for 4 gigabytes (PL 0) */ LONG $(0xFFFF) LONG $(SEGG|SEGD|(0xF<<16)|SEGP|SEGPL(0)|SEGEXEC|SEGR) /* * pointer to initial gdt * Note the -KZERO which puts the physical address in the gdtptr. * that's needed as we start executing in physical addresses. */ TEXT tgdtptr(SB), $0 WORD $(3*8) LONG $tgdt-KZERO(SB) TEXT mode32bit(SB), $0 /* At this point, the GDT setup is done. */ MOVL $PADDR(CPU0PDB), DI /* clear 4 pages for the tables etc. */ XORL AX, AX MOVL $(4*BY2PG), CX SHRL $2, CX CLD REP; STOSL MOVL $PADDR(CPU0PDB), AX ADDL $PDO(KZERO), AX /* page directory offset for KZERO */ MOVL $PADDR(CPU0PTE), (AX) /* PTE's for 0x80000000 */ MOVL $(PTEWRITE|PTEVALID), BX /* page permissions */ ORL BX, (AX) MOVL $PADDR(CPU0PTE), AX /* first page of page table */ MOVL $1024, CX /* 1024 pages in 4MB */ _setpte: MOVL BX, (AX) ADDL $(1<<PGSHIFT), BX ADDL $4, AX LOOP _setpte MOVL $PADDR(CPU0PTE), AX ADDL $PTO(MACHADDR), AX /* page table entry offset for MACHADDR */ MOVL $PADDR(CPU0MACH), (AX) /* PTE for Mach */ MOVL $(PTEWRITE|PTEVALID), BX /* page permissions */ ORL BX, (AX) /* * Now ready to use the new map. Make sure the processor options are what is wanted. * It is necessary on some processors to immediately follow mode switching with a JMP instruction * to clear the prefetch queues. */ MOVL $PADDR(CPU0PDB), CX /* load address of page directory */ MOVL (PDO(KZERO))(CX), DX /* double-map KZERO at 0 */ MOVL DX, (PDO(0))(CX) MOVL CX, CR3 DELAY /* JMP .+2 */ MOVL CR0, DX ORL $0x80010000, DX /* PG|WP */ ANDL $~0x6000000A, DX /* ~(CD|NW|TS|MP) */ MOVL $_startpg(SB), AX /* this is a virtual address */ MOVL DX, CR0 /* turn on paging */ JMP* AX /* jump to the virtual nirvana */ /* * Basic machine environment set, can clear BSS and create a stack. * The stack starts at the top of the page containing the Mach structure. * The x86 architecture forces the use of the same virtual address for * each processor's Mach structure, so the global Mach pointer 'm' can * be initialised here. */ TEXT _startpg(SB), $0 MOVL $0, (PDO(0))(CX) /* undo double-map of KZERO at 0 */ MOVL CX, CR3 /* load and flush the mmu */ _clearbss: MOVL $edata(SB), DI XORL AX, AX MOVL $end(SB), CX SUBL DI, CX /* end-edata bytes */ SHRL $2, CX /* end-edata doublewords */ CLD REP; STOSL /* clear BSS */ MOVL $MACHADDR, SP MOVL SP, m(SB) /* initialise global Mach pointer */ MOVL $0, 0(SP) /* initialise m->machno */ ADDL $(MACHSIZE-4), SP /* initialise stack */ /* * Need to do one final thing to ensure a clean machine environment, * clear the EFLAGS register, which can only be done once there is a stack. */ MOVL $0, AX PUSHL AX POPFL CALL main(SB) /* * Park a processor. Should never fall through a return from main to here, * should only be called by application processors when shutting down. */ TEXT idle(SB), $0 _idle: STI HLT JMP _idle /* * Port I/O. * in[bsl] input a byte|short|long * ins[bsl] input a string of bytes|shorts|longs * out[bsl] output a byte|short|long * outs[bsl] output a string of bytes|shorts|longs */ TEXT inb(SB), $0 MOVL port+0(FP), DX XORL AX, AX INB RET TEXT insb(SB), $0 MOVL port+0(FP), DX MOVL address+4(FP), DI MOVL count+8(FP), CX CLD REP; INSB RET TEXT ins(SB), $0 MOVL port+0(FP), DX XORL AX, AX OP16; INL RET TEXT inss(SB), $0 MOVL port+0(FP), DX MOVL address+4(FP), DI MOVL count+8(FP), CX CLD REP; OP16; INSL RET TEXT inl(SB), $0 MOVL port+0(FP), DX INL RET TEXT insl(SB), $0 MOVL port+0(FP), DX MOVL address+4(FP), DI MOVL count+8(FP), CX CLD REP; INSL RET TEXT outb(SB), $0 MOVL port+0(FP), DX MOVL byte+4(FP), AX OUTB RET TEXT outsb(SB), $0 MOVL port+0(FP), DX MOVL address+4(FP), SI MOVL count+8(FP), CX CLD REP; OUTSB RET TEXT outs(SB), $0 MOVL port+0(FP), DX MOVL short+4(FP), AX OP16; OUTL RET TEXT outss(SB), $0 MOVL port+0(FP), DX MOVL address+4(FP), SI MOVL count+8(FP), CX CLD REP; OP16; OUTSL RET TEXT outl(SB), $0 MOVL port+0(FP), DX MOVL long+4(FP), AX OUTL RET TEXT outsl(SB), $0 MOVL port+0(FP), DX MOVL address+4(FP), SI MOVL count+8(FP), CX CLD REP; OUTSL RET /* there's a macro in fns.h but libinterp can't see it */ TEXT getcallerpc(SB), $0 MOVL a+0(FP), AX RET /* * Read/write various system registers. * CR4 and the 'model specific registers' should only be read/written * after it has been determined the processor supports them */ TEXT lgdt(SB), $0 /* GDTR - global descriptor table */ MOVL gdtptr+0(FP), AX MOVL (AX), GDTR RET TEXT lidt(SB), $0 /* IDTR - interrupt descriptor table */ MOVL idtptr+0(FP), AX MOVL (AX), IDTR RET TEXT ltr(SB), $0 /* TR - task register */ MOVL tptr+0(FP), AX MOVW AX, TASK RET TEXT getcr0(SB), $0 /* CR0 - processor control */ MOVL CR0, AX RET TEXT getcr2(SB), $0 /* CR2 - page fault linear address */ MOVL CR2, AX RET TEXT getcr3(SB), $0 /* CR3 - page directory base */ MOVL CR3, AX RET TEXT putcr3(SB), $0 MOVL cr3+0(FP), AX MOVL AX, CR3 RET TEXT getcr4(SB), $0 /* CR4 - extensions */ MOVL CR4, AX RET TEXT putcr4(SB), $0 MOVL cr4+0(FP), AX MOVL AX, CR4 RET TEXT _cycles(SB), $0 /* time stamp counter; cycles since power up */ RDTSC MOVL vlong+0(FP), CX /* &vlong */ MOVL AX, 0(CX) /* lo */ MOVL DX, 4(CX) /* hi */ RET TEXT rdmsr(SB), $0 /* model-specific register */ MOVL index+0(FP), CX RDMSR MOVL vlong+4(FP), CX /* &vlong */ MOVL AX, 0(CX) /* lo */ MOVL DX, 4(CX) /* hi */ RET TEXT wrmsr(SB), $0 MOVL index+0(FP), CX MOVL lo+4(FP), AX MOVL hi+8(FP), DX WRMSR RET TEXT wbinvd(SB), $0 WBINVD RET TEXT rdtsc32(SB), $0 CPUID RDTSC RET /* * Try to determine the CPU type which requires fiddling with EFLAGS. * If the Id bit can be toggled then the CPUID instruction can be used * to determine CPU identity and features. First have to check if it's * a 386 (Ac bit can't be set). If it's not a 386 and the Id bit can't be * toggled then it's an older 486 of some kind. * * cpuid(id[], &ax, &dx); */ TEXT cpuid(SB), $0 MOVL $0x240000, AX PUSHL AX POPFL /* set Id|Ac */ PUSHFL POPL BX /* retrieve value */ MOVL $0, AX PUSHL AX POPFL /* clear Id|Ac, EFLAGS initialised */ PUSHFL POPL AX /* retrieve value */ XORL BX, AX TESTL $0x040000, AX /* Ac */ JZ _cpu386 /* can't set this bit on 386 */ TESTL $0x200000, AX /* Id */ JZ _cpu486 /* can't toggle this bit on some 486 */ MOVL $0, AX CPUID MOVL id+0(FP), BP MOVL BX, 0(BP) /* "Genu" "Auth" "Cyri" */ MOVL DX, 4(BP) /* "ineI" "enti" "xIns" */ MOVL CX, 8(BP) /* "ntel" "cAMD" "tead" */ MOVL $1, AX CPUID JMP _cpuid _cpu486: MOVL $0x400, AX MOVL $0, DX JMP _cpuid _cpu386: MOVL $0x300, AX MOVL $0, DX _cpuid: MOVL ax+4(FP), BP MOVL AX, 0(BP) MOVL dx+8(FP), BP MOVL DX, 0(BP) RET /* * Basic timing loop to determine CPU frequency. */ TEXT aamloop(SB), $0 MOVL count+0(FP), CX _aamloop: AAM LOOP _aamloop RET /* * Floating point. * Note: the encodings for the FCLEX, FINIT, FSAVE, FSTCW, FSENV and FSTSW * instructions do NOT have the WAIT prefix byte (i.e. they act like their * FNxxx variations) so WAIT instructions must be explicitly placed in the * code as necessary. */ #define FPOFF(l) ;\ MOVL CR0, AX ;\ ANDL $0xC, AX /* EM, TS */ ;\ CMPL AX, $0x8 ;\ JEQ l ;\ WAIT ;\ l: ;\ MOVL CR0, AX ;\ ANDL $~0x4, AX /* EM=0 */ ;\ ORL $0x28, AX /* NE=1, TS=1 */ ;\ MOVL AX, CR0 #define FPON ;\ MOVL CR0, AX ;\ ANDL $~0xC, AX /* EM=0, TS=0 */ ;\ MOVL AX, CR0 TEXT fpoff(SB), $0 /* disable */ FPOFF(l1) RET TEXT fpinit(SB), $0 /* enable and init */ FPON FINIT WAIT /* setfcr(FPPDBL|FPRNR|FPINVAL|FPZDIV|FPOVFL) */ /* note that low 6 bits are masks, not enables, on this chip */ PUSHW $0x0232 FLDCW 0(SP) POPW AX WAIT RET TEXT fpsave(SB), $0 /* save state and disable */ MOVL p+0(FP), AX FSAVE 0(AX) /* no WAIT */ FPOFF(l2) RET TEXT fprestore(SB), $0 /* enable and restore state */ FPON MOVL p+0(FP), AX FRSTOR 0(AX) WAIT RET TEXT fpstatus(SB), $0 /* get floating point status */ FSTSW AX RET TEXT fpenv(SB), $0 /* save state without waiting */ MOVL p+0(FP), AX FSTENV 0(AX) RET TEXT fpclear(SB), $0 /* clear pending exceptions */ FPON FCLEX /* no WAIT */ FPOFF(l3) RET /* */ TEXT splhi(SB), $0 MOVL $(MACHADDR+0x04), AX /* save PC in m->splpc */ MOVL (SP), BX MOVL BX, (AX) PUSHFL POPL AX CLI RET TEXT spllo(SB), $0 PUSHFL POPL AX STI RET TEXT splx(SB), $0 MOVL $(MACHADDR+0x04), AX /* save PC in m->splpc */ MOVL (SP), BX MOVL BX, (AX) /*FALLTHROUGH*/ TEXT splxpc(SB), $0 /* for iunlock */ MOVL s+0(FP), AX PUSHL AX POPFL RET TEXT spldone(SB), $0 RET TEXT islo(SB), $0 PUSHFL POPL AX ANDL $0x200, AX /* interrupt enable flag */ RET /* * Test-And-Set */ TEXT _tas(SB), $0 MOVL $0xDEADDEAD, AX MOVL lock+0(FP), BX XCHGL AX, (BX) /* lock->key */ RET TEXT _xinc(SB), $0 /* void _xinc(long*); */ MOVL l+0(FP), AX LOCK; INCL 0(AX) RET TEXT _xdec(SB), $0 /* long _xdec(long*); */ MOVL l+0(FP), BX XORL AX, AX LOCK; DECL 0(BX) JLT _xdeclt JGT _xdecgt RET _xdecgt: INCL AX RET _xdeclt: DECL AX RET TEXT mb386(SB), $0 POPL AX /* return PC */ PUSHFL PUSHL CS PUSHL AX IRETL TEXT mb586(SB), $0 XORL AX, AX CPUID RET TEXT xchgw(SB), $0 MOVL v+4(FP), AX MOVL p+0(FP), BX XCHGW AX, (BX) RET TEXT mul64fract(SB), $0 /* * Multiply two 64-bit number s and keep the middle 64 bits from the 128-bit result * See ../port/tod.c for motivation. */ MOVL r+0(FP), CX XORL BX, BX /* BX = 0 */ MOVL a+8(FP), AX MULL b+16(FP) /* a1*b1 */ MOVL AX, 4(CX) /* r2 = lo(a1*b1) */ MOVL a+8(FP), AX MULL b+12(FP) /* a1*b0 */ MOVL AX, 0(CX) /* r1 = lo(a1*b0) */ ADDL DX, 4(CX) /* r2 += hi(a1*b0) */ MOVL a+4(FP), AX MULL b+16(FP) /* a0*b1 */ ADDL AX, 0(CX) /* r1 += lo(a0*b1) */ ADCL DX, 4(CX) /* r2 += hi(a0*b1) + carry */ MOVL a+4(FP), AX MULL b+12(FP) /* a0*b0 */ ADDL DX, 0(CX) /* r1 += hi(a0*b0) */ ADCL BX, 4(CX) /* r2 += carry */ RET /* * label consists of a stack pointer and a PC */ TEXT gotolabel(SB), $0 MOVL label+0(FP), AX MOVL 0(AX), SP /* restore sp */ MOVL 4(AX), AX /* put return pc on the stack */ MOVL AX, 0(SP) MOVL $1, AX /* return 1 */ RET TEXT setlabel(SB), $0 MOVL label+0(FP), AX MOVL SP, 0(AX) /* store sp */ MOVL 0(SP), BX /* store return pc */ MOVL BX, 4(AX) MOVL $0, AX /* return 0 */ RET TEXT halt(SB), $0 STI HLT RET /* * Interrupt/exception handling. * Each entry in the vector table calls either _strayintr or _strayintrx depending * on whether an error code has been automatically pushed onto the stack * (_strayintrx) or not, in which case a dummy entry must be pushed before retrieving * the trap type from the vector table entry and placing it on the stack as part * of the Ureg structure. * The size of each entry in the vector table (6 bytes) is known in trapinit(). */ TEXT _strayintr(SB), $0 PUSHL AX /* save AX */ MOVL 4(SP), AX /* return PC from vectortable(SB) */ JMP intrcommon TEXT _strayintrx(SB), $0 XCHGL AX, (SP) /* exchange AX with pointer to trap type */ intrcommon: PUSHL DS MOVBLZX (AX), AX /* trap type -> AX */ XCHGL AX, 4(SP) /* exchange trap type with AX */ PUSHL ES PUSHL FS PUSHL GS PUSHAL MOVL $(KDSEL), AX MOVW AX, DS MOVW AX, ES PUSHL SP /* Ureg* argument to trap */ CALL trap(SB) TEXT forkret(SB), $0 POPL AX POPAL POPL GS POPL FS POPL ES POPL DS ADDL $8, SP /* pop error code and trap type */ IRETL TEXT vectortable(SB), $0 CALL _strayintr(SB); BYTE $0x00 /* divide error */ CALL _strayintr(SB); BYTE $0x01 /* debug exception */ CALL _strayintr(SB); BYTE $0x02 /* NMI interrupt */ CALL _strayintr(SB); BYTE $0x03 /* breakpoint */ CALL _strayintr(SB); BYTE $0x04 /* overflow */ CALL _strayintr(SB); BYTE $0x05 /* bound */ CALL _strayintr(SB); BYTE $0x06 /* invalid opcode */ CALL _strayintr(SB); BYTE $0x07 /* no coprocessor available */ CALL _strayintrx(SB); BYTE $0x08 /* double fault */ CALL _strayintr(SB); BYTE $0x09 /* coprocessor segment overflow */ CALL _strayintrx(SB); BYTE $0x0A /* invalid TSS */ CALL _strayintrx(SB); BYTE $0x0B /* segment not available */ CALL _strayintrx(SB); BYTE $0x0C /* stack exception */ CALL _strayintrx(SB); BYTE $0x0D /* general protection error */ CALL _strayintrx(SB); BYTE $0x0E /* page fault */ CALL _strayintr(SB); BYTE $0x0F /* */ CALL _strayintr(SB); BYTE $0x10 /* coprocessor error */ CALL _strayintrx(SB); BYTE $0x11 /* alignment check */ CALL _strayintr(SB); BYTE $0x12 /* machine check */ CALL _strayintr(SB); BYTE $0x13 CALL _strayintr(SB); BYTE $0x14 CALL _strayintr(SB); BYTE $0x15 CALL _strayintr(SB); BYTE $0x16 CALL _strayintr(SB); BYTE $0x17 CALL _strayintr(SB); BYTE $0x18 CALL _strayintr(SB); BYTE $0x19 CALL _strayintr(SB); BYTE $0x1A CALL _strayintr(SB); BYTE $0x1B CALL _strayintr(SB); BYTE $0x1C CALL _strayintr(SB); BYTE $0x1D CALL _strayintr(SB); BYTE $0x1E CALL _strayintr(SB); BYTE $0x1F CALL _strayintr(SB); BYTE $0x20 /* VectorLAPIC */ CALL _strayintr(SB); BYTE $0x21 CALL _strayintr(SB); BYTE $0x22 CALL _strayintr(SB); BYTE $0x23 CALL _strayintr(SB); BYTE $0x24 CALL _strayintr(SB); BYTE $0x25 CALL _strayintr(SB); BYTE $0x26 CALL _strayintr(SB); BYTE $0x27 CALL _strayintr(SB); BYTE $0x28 CALL _strayintr(SB); BYTE $0x29 CALL _strayintr(SB); BYTE $0x2A CALL _strayintr(SB); BYTE $0x2B CALL _strayintr(SB); BYTE $0x2C CALL _strayintr(SB); BYTE $0x2D CALL _strayintr(SB); BYTE $0x2E CALL _strayintr(SB); BYTE $0x2F CALL _strayintr(SB); BYTE $0x30 CALL _strayintr(SB); BYTE $0x31 CALL _strayintr(SB); BYTE $0x32 CALL _strayintr(SB); BYTE $0x33 CALL _strayintr(SB); BYTE $0x34 CALL _strayintr(SB); BYTE $0x35 CALL _strayintr(SB); BYTE $0x36 CALL _strayintr(SB); BYTE $0x37 CALL _strayintr(SB); BYTE $0x38 CALL _strayintr(SB); BYTE $0x39 CALL _strayintr(SB); BYTE $0x3A CALL _strayintr(SB); BYTE $0x3B CALL _strayintr(SB); BYTE $0x3C CALL _strayintr(SB); BYTE $0x3D CALL _strayintr(SB); BYTE $0x3E CALL _strayintr(SB); BYTE $0x3F CALL _strayintr(SB); BYTE $0x40 /* VectorSYSCALL */ CALL _strayintr(SB); BYTE $0x41 CALL _strayintr(SB); BYTE $0x42 CALL _strayintr(SB); BYTE $0x43 CALL _strayintr(SB); BYTE $0x44 CALL _strayintr(SB); BYTE $0x45 CALL _strayintr(SB); BYTE $0x46 CALL _strayintr(SB); BYTE $0x47 CALL _strayintr(SB); BYTE $0x48 CALL _strayintr(SB); BYTE $0x49 CALL _strayintr(SB); BYTE $0x4A CALL _strayintr(SB); BYTE $0x4B CALL _strayintr(SB); BYTE $0x4C CALL _strayintr(SB); BYTE $0x4D CALL _strayintr(SB); BYTE $0x4E CALL _strayintr(SB); BYTE $0x4F CALL _strayintr(SB); BYTE $0x50 CALL _strayintr(SB); BYTE $0x51 CALL _strayintr(SB); BYTE $0x52 CALL _strayintr(SB); BYTE $0x53 CALL _strayintr(SB); BYTE $0x54 CALL _strayintr(SB); BYTE $0x55 CALL _strayintr(SB); BYTE $0x56 CALL _strayintr(SB); BYTE $0x57 CALL _strayintr(SB); BYTE $0x58 CALL _strayintr(SB); BYTE $0x59 CALL _strayintr(SB); BYTE $0x5A CALL _strayintr(SB); BYTE $0x5B CALL _strayintr(SB); BYTE $0x5C CALL _strayintr(SB); BYTE $0x5D CALL _strayintr(SB); BYTE $0x5E CALL _strayintr(SB); BYTE $0x5F CALL _strayintr(SB); BYTE $0x60 CALL _strayintr(SB); BYTE $0x61 CALL _strayintr(SB); BYTE $0x62 CALL _strayintr(SB); BYTE $0x63 CALL _strayintr(SB); BYTE $0x64 CALL _strayintr(SB); BYTE $0x65 CALL _strayintr(SB); BYTE $0x66 CALL _strayintr(SB); BYTE $0x67 CALL _strayintr(SB); BYTE $0x68 CALL _strayintr(SB); BYTE $0x69 CALL _strayintr(SB); BYTE $0x6A CALL _strayintr(SB); BYTE $0x6B CALL _strayintr(SB); BYTE $0x6C CALL _strayintr(SB); BYTE $0x6D CALL _strayintr(SB); BYTE $0x6E CALL _strayintr(SB); BYTE $0x6F CALL _strayintr(SB); BYTE $0x70 CALL _strayintr(SB); BYTE $0x71 CALL _strayintr(SB); BYTE $0x72 CALL _strayintr(SB); BYTE $0x73 CALL _strayintr(SB); BYTE $0x74 CALL _strayintr(SB); BYTE $0x75 CALL _strayintr(SB); BYTE $0x76 CALL _strayintr(SB); BYTE $0x77 CALL _strayintr(SB); BYTE $0x78 CALL _strayintr(SB); BYTE $0x79 CALL _strayintr(SB); BYTE $0x7A CALL _strayintr(SB); BYTE $0x7B CALL _strayintr(SB); BYTE $0x7C CALL _strayintr(SB); BYTE $0x7D CALL _strayintr(SB); BYTE $0x7E CALL _strayintr(SB); BYTE $0x7F CALL _strayintr(SB); BYTE $0x80 /* Vector[A]PIC */ CALL _strayintr(SB); BYTE $0x81 CALL _strayintr(SB); BYTE $0x82 CALL _strayintr(SB); BYTE $0x83 CALL _strayintr(SB); BYTE $0x84 CALL _strayintr(SB); BYTE $0x85 CALL _strayintr(SB); BYTE $0x86 CALL _strayintr(SB); BYTE $0x87 CALL _strayintr(SB); BYTE $0x88 CALL _strayintr(SB); BYTE $0x89 CALL _strayintr(SB); BYTE $0x8A CALL _strayintr(SB); BYTE $0x8B CALL _strayintr(SB); BYTE $0x8C CALL _strayintr(SB); BYTE $0x8D CALL _strayintr(SB); BYTE $0x8E CALL _strayintr(SB); BYTE $0x8F CALL _strayintr(SB); BYTE $0x90 CALL _strayintr(SB); BYTE $0x91 CALL _strayintr(SB); BYTE $0x92 CALL _strayintr(SB); BYTE $0x93 CALL _strayintr(SB); BYTE $0x94 CALL _strayintr(SB); BYTE $0x95 CALL _strayintr(SB); BYTE $0x96 CALL _strayintr(SB); BYTE $0x97 CALL _strayintr(SB); BYTE $0x98 CALL _strayintr(SB); BYTE $0x99 CALL _strayintr(SB); BYTE $0x9A CALL _strayintr(SB); BYTE $0x9B CALL _strayintr(SB); BYTE $0x9C CALL _strayintr(SB); BYTE $0x9D CALL _strayintr(SB); BYTE $0x9E CALL _strayintr(SB); BYTE $0x9F CALL _strayintr(SB); BYTE $0xA0 CALL _strayintr(SB); BYTE $0xA1 CALL _strayintr(SB); BYTE $0xA2 CALL _strayintr(SB); BYTE $0xA3 CALL _strayintr(SB); BYTE $0xA4 CALL _strayintr(SB); BYTE $0xA5 CALL _strayintr(SB); BYTE $0xA6 CALL _strayintr(SB); BYTE $0xA7 CALL _strayintr(SB); BYTE $0xA8 CALL _strayintr(SB); BYTE $0xA9 CALL _strayintr(SB); BYTE $0xAA CALL _strayintr(SB); BYTE $0xAB CALL _strayintr(SB); BYTE $0xAC CALL _strayintr(SB); BYTE $0xAD CALL _strayintr(SB); BYTE $0xAE CALL _strayintr(SB); BYTE $0xAF CALL _strayintr(SB); BYTE $0xB0 CALL _strayintr(SB); BYTE $0xB1 CALL _strayintr(SB); BYTE $0xB2 CALL _strayintr(SB); BYTE $0xB3 CALL _strayintr(SB); BYTE $0xB4 CALL _strayintr(SB); BYTE $0xB5 CALL _strayintr(SB); BYTE $0xB6 CALL _strayintr(SB); BYTE $0xB7 CALL _strayintr(SB); BYTE $0xB8 CALL _strayintr(SB); BYTE $0xB9 CALL _strayintr(SB); BYTE $0xBA CALL _strayintr(SB); BYTE $0xBB CALL _strayintr(SB); BYTE $0xBC CALL _strayintr(SB); BYTE $0xBD CALL _strayintr(SB); BYTE $0xBE CALL _strayintr(SB); BYTE $0xBF CALL _strayintr(SB); BYTE $0xC0 CALL _strayintr(SB); BYTE $0xC1 CALL _strayintr(SB); BYTE $0xC2 CALL _strayintr(SB); BYTE $0xC3 CALL _strayintr(SB); BYTE $0xC4 CALL _strayintr(SB); BYTE $0xC5 CALL _strayintr(SB); BYTE $0xC6 CALL _strayintr(SB); BYTE $0xC7 CALL _strayintr(SB); BYTE $0xC8 CALL _strayintr(SB); BYTE $0xC9 CALL _strayintr(SB); BYTE $0xCA CALL _strayintr(SB); BYTE $0xCB CALL _strayintr(SB); BYTE $0xCC CALL _strayintr(SB); BYTE $0xCD CALL _strayintr(SB); BYTE $0xCE CALL _strayintr(SB); BYTE $0xCF CALL _strayintr(SB); BYTE $0xD0 CALL _strayintr(SB); BYTE $0xD1 CALL _strayintr(SB); BYTE $0xD2 CALL _strayintr(SB); BYTE $0xD3 CALL _strayintr(SB); BYTE $0xD4 CALL _strayintr(SB); BYTE $0xD5 CALL _strayintr(SB); BYTE $0xD6 CALL _strayintr(SB); BYTE $0xD7 CALL _strayintr(SB); BYTE $0xD8 CALL _strayintr(SB); BYTE $0xD9 CALL _strayintr(SB); BYTE $0xDA CALL _strayintr(SB); BYTE $0xDB CALL _strayintr(SB); BYTE $0xDC CALL _strayintr(SB); BYTE $0xDD CALL _strayintr(SB); BYTE $0xDE CALL _strayintr(SB); BYTE $0xDF CALL _strayintr(SB); BYTE $0xE0 CALL _strayintr(SB); BYTE $0xE1 CALL _strayintr(SB); BYTE $0xE2 CALL _strayintr(SB); BYTE $0xE3 CALL _strayintr(SB); BYTE $0xE4 CALL _strayintr(SB); BYTE $0xE5 CALL _strayintr(SB); BYTE $0xE6 CALL _strayintr(SB); BYTE $0xE7 CALL _strayintr(SB); BYTE $0xE8 CALL _strayintr(SB); BYTE $0xE9 CALL _strayintr(SB); BYTE $0xEA CALL _strayintr(SB); BYTE $0xEB CALL _strayintr(SB); BYTE $0xEC CALL _strayintr(SB); BYTE $0xED CALL _strayintr(SB); BYTE $0xEE CALL _strayintr(SB); BYTE $0xEF CALL _strayintr(SB); BYTE $0xF0 CALL _strayintr(SB); BYTE $0xF1 CALL _strayintr(SB); BYTE $0xF2 CALL _strayintr(SB); BYTE $0xF3 CALL _strayintr(SB); BYTE $0xF4 CALL _strayintr(SB); BYTE $0xF5 CALL _strayintr(SB); BYTE $0xF6 CALL _strayintr(SB); BYTE $0xF7 CALL _strayintr(SB); BYTE $0xF8 CALL _strayintr(SB); BYTE $0xF9 CALL _strayintr(SB); BYTE $0xFA CALL _strayintr(SB); BYTE $0xFB CALL _strayintr(SB); BYTE $0xFC CALL _strayintr(SB); BYTE $0xFD CALL _strayintr(SB); BYTE $0xFE CALL _strayintr(SB); BYTE $0xFF