#include "mem.h"
#include "/sys/src/boot/pc/x16.h"
#undef DELAY
#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 HLT BYTE $0xF4
#define INVLPG BYTE $0x0F; BYTE $0x01; BYTE $0x39 /* INVLPG (%ecx) */
#define WBINVD BYTE $0x0F; BYTE $0x09
/*
* 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 _startKADDR(SB), $0
MOVL $_startPADDR(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 $_startKADDR-KZERO(SB) /* load_addr */
LONG $edata-KZERO(SB) /* load_end_addr */
LONG $end-KZERO(SB) /* bss_end_addr */
LONG $_startKADDR-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 PADDR(entry), the physical address of the virtual kernel entry point of KADDR(entry)
* 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 _startPADDR(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 m0rgdtptr(SB), $0
WORD $(NGDT*8-1)
LONG $(CPU0GDT-KZERO)
TEXT m0gdtptr(SB), $0
WORD $(NGDT*8-1)
LONG $CPU0GDT
TEXT m0idtptr(SB), $0
WORD $(256*8-1)
LONG $IDTADDR
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 KZERO */
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
/*
* Save registers.
*/
TEXT saveregs(SB), $0
/* appease 8l */
SUBL $32, SP
POPL AX
POPL AX
POPL AX
POPL AX
POPL AX
POPL AX
POPL AX
POPL AX
PUSHL AX
PUSHL BX
PUSHL CX
PUSHL DX
PUSHL BP
PUSHL DI
PUSHL SI
PUSHFL
XCHGL 32(SP), AX /* swap return PC and saved flags */
XCHGL 0(SP), AX
XCHGL 32(SP), AX
RET
TEXT restoreregs(SB), $0
/* appease 8l */
PUSHL AX
PUSHL AX
PUSHL AX
PUSHL AX
PUSHL AX
PUSHL AX
PUSHL AX
PUSHL AX
ADDL $32, SP
XCHGL 32(SP), AX /* swap return PC and saved flags */
XCHGL 0(SP), AX
XCHGL 32(SP), AX
POPFL
POPL SI
POPL DI
POPL BP
POPL DX
POPL CX
POPL BX
POPL AX
RET
/*
* Assumed to be in protected mode at time of call.
* Switch to real mode, execute an interrupt, and
* then switch back to protected mode.
*
* Assumes:
*
* - no device interrupts are going to come in
* - 0-16MB is identity mapped in page tables
* - realmode() has copied us down from 0x100000 to 0x8000
* - can use code segment 0x0800 in real mode
* to get at l.s code
* - l.s code is less than 1 page
*/
#define RELOC (RMCODE-KTZERO)
TEXT realmodeidtptr(SB), $0
WORD $(4*256-1)
LONG $0
TEXT realmode0(SB), $0
CALL saveregs(SB)
/* switch to low code address */
LEAL physcode-KZERO(SB), AX
JMP *AX
TEXT physcode(SB), $0
/* switch to low stack */
MOVL SP, AX
MOVL $0x7C00, SP
PUSHL AX
/* change gdt to physical pointer */
MOVL m0rgdtptr-KZERO(SB), GDTR
/* load IDT with real-mode version*/
MOVL realmodeidtptr-KZERO(SB), IDTR
/* edit INT $0x00 instruction below */
MOVL $(RMUADDR-KZERO+48), AX /* &rmu.trap */
MOVL (AX), AX
MOVB AX, realmodeintrinst+(-KZERO+1+RELOC)(SB)
/* disable paging */
MOVL CR0, AX
ANDL $0x7FFFFFFF, AX
MOVL AX, CR0
/* JMP .+2 to clear prefetch queue*/
BYTE $0xEB; BYTE $0x00
/* jump to 16-bit code segment */
/* JMPFAR SELECTOR(KESEG16, SELGDT, 0):$again16bit(SB) /**/
BYTE $0xEA
LONG $again16bit-KZERO(SB)
WORD $SELECTOR(KESEG16, SELGDT, 0)
TEXT again16bit(SB), $0
/*
* Now in 16-bit compatibility mode.
* These are 32-bit instructions being interpreted
* as 16-bit instructions. I'm being lazy and
* not using the macros because I know when
* the 16- and 32-bit instructions look the same
* or close enough.
*/
/* disable protected mode and jump to real mode cs */
OPSIZE; MOVL CR0, AX
OPSIZE; XORL BX, BX
OPSIZE; INCL BX
OPSIZE; XORL BX, AX
OPSIZE; MOVL AX, CR0
/* JMPFAR 0x0800:now16real */
BYTE $0xEA
WORD $now16real-KZERO(SB)
WORD $0x0800
TEXT now16real(SB), $0
/* copy the registers for the bios call */
LWI(0x0000, rAX)
MOVW AX,SS
LWI(RMUADDR, rBP)
/* offsets are in Ureg */
LXW(44, xBP, rAX)
MOVW AX, DS
LXW(40, xBP, rAX)
MOVW AX, ES
OPSIZE; LXW(0, xBP, rDI)
OPSIZE; LXW(4, xBP, rSI)
OPSIZE; LXW(16, xBP, rBX)
OPSIZE; LXW(20, xBP, rDX)
OPSIZE; LXW(24, xBP, rCX)
OPSIZE; LXW(28, xBP, rAX)
CLC
TEXT realmodeintrinst(SB), $0
INT $0x00
/* save the registers after the call */
LWI(0x7bfc, rSP)
OPSIZE; PUSHFL
OPSIZE; PUSHL AX
LWI(0, rAX)
MOVW AX,SS
LWI(RMUADDR, rBP)
OPSIZE; SXW(rDI, 0, xBP)
OPSIZE; SXW(rSI, 4, xBP)
OPSIZE; SXW(rBX, 16, xBP)
OPSIZE; SXW(rDX, 20, xBP)
OPSIZE; SXW(rCX, 24, xBP)
OPSIZE; POPL AX
OPSIZE; SXW(rAX, 28, xBP)
MOVW DS, AX
OPSIZE; SXW(rAX, 44, xBP)
MOVW ES, AX
OPSIZE; SXW(rAX, 40, xBP)
OPSIZE; POPL AX
OPSIZE; SXW(rAX, 64, xBP) /* flags */
/* re-enter protected mode and jump to 32-bit code */
OPSIZE; MOVL $1, AX
OPSIZE; MOVL AX, CR0
/* JMPFAR SELECTOR(KESEG, SELGDT, 0):$again32bit(SB) /**/
OPSIZE
BYTE $0xEA
LONG $again32bit-KZERO(SB)
WORD $SELECTOR(KESEG, SELGDT, 0)
TEXT again32bit(SB), $0
MOVW $SELECTOR(KDSEG, SELGDT, 0),AX
MOVW AX,DS
MOVW AX,SS
MOVW AX,ES
MOVW AX,FS
MOVW AX,GS
/* enable paging and jump to kzero-address code */
MOVL CR0, AX
ORL $0x80010000, AX /* PG|WP */
MOVL AX, CR0
LEAL again32kzero(SB), AX
JMP* AX
TEXT again32kzero(SB), $0
/* breathe a sigh of relief - back in 32-bit protected mode */
/* switch to old stack */
PUSHL AX /* match popl below for 8l */
MOVL $0x7BFC, SP
POPL SP
/* restore idt */
MOVL m0idtptr(SB),IDTR
/* restore gdt */
MOVL m0gdtptr(SB), GDTR
CALL restoreregs(SB)
RET
/*
* BIOS32.
*/
TEXT bios32call(SB), $0
MOVL ci+0(FP), BP
MOVL 0(BP), AX
MOVL 4(BP), BX
MOVL 8(BP), CX
MOVL 12(BP), DX
MOVL 16(BP), SI
MOVL 20(BP), DI
PUSHL BP
MOVL 12(SP), BP /* ptr */
BYTE $0xFF; BYTE $0x5D; BYTE $0x00 /* CALL FAR 0(BP) */
POPL BP
MOVL DI, 20(BP)
MOVL SI, 16(BP)
MOVL DX, 12(BP)
MOVL CX, 8(BP)
MOVL BX, 4(BP)
MOVL AX, 0(BP)
XORL AX, AX
JCC _bios32xxret
INCL AX
_bios32xxret:
RET
/*
* 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
/*
* 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 putcr0(SB), $0
MOVL cr0+0(FP), AX
MOVL AX, CR0
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 invlpg(SB), $0
/* 486+ only */
MOVL va+0(FP), CX
INVLPG
RET
TEXT wbinvd(SB), $0
WBINVD
RET
TEXT _cycles(SB), $0 /* time stamp counter */
RDTSC
MOVL vlong+0(FP), CX /* &vlong */
MOVL AX, 0(CX) /* lo */
MOVL DX, 4(CX) /* hi */
RET
/*
* stub for:
* time stamp counter; low-order 32 bits of 64-bit cycle counter
* Runs at fasthz/4 cycles per second (m->clkin>>3)
*/
TEXT lcycles(SB),1,$0
RDTSC
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
/*
* 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(fun, &ax, &bx, &cx, &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 fn+0(FP), AX
CPUID
JMP _cpuid
_cpu486:
MOVL $0x400, AX
JMP _maybezapax
_cpu386:
MOVL $0x300, AX
_maybezapax:
CMPL fn+0(FP), $1
JE _zaprest
XORL AX, AX
_zaprest:
XORL BX, BX
XORL CX, CX
XORL DX, DX
_cpuid:
MOVL axp+4(FP), BP
CMPL BP, $0
JE _bx
MOVL AX, (BP)
_bx:
MOVL bxp+8(FP), BP
CMPL BP, $0
JE _cx
MOVL BX, (BP)
_cx:
MOVL cxp+12(FP), BP
CMPL BP, $0
JE _dx
MOVL CX, (BP)
_dx:
MOVL dxp+16(FP), BP
CMPL BP, $0
JE _out
MOVL DX, (BP)
_out:
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
shi:
PUSHFL
POPL AX
TESTL $0x200, AX
JZ alreadyhi
MOVL $(MACHADDR+0x04), CX /* save PC in m->splpc */
MOVL (SP), BX
MOVL BX, (CX)
alreadyhi:
CLI
RET
TEXT spllo(SB), $0
slo:
PUSHFL
POPL AX
TESTL $0x200, AX
JNZ alreadylo
MOVL $(MACHADDR+0x04), CX /* clear m->splpc */
MOVL $0, (CX)
alreadylo:
STI
RET
TEXT splx(SB), $0
MOVL s+0(FP), AX
TESTL $0x200, AX
JNZ slo
JMP shi
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 sfence(SB), $0
BYTE $0x0f
BYTE $0xae
BYTE $0xf8
RET
TEXT lfence(SB), $0
BYTE $0x0f
BYTE $0xae
BYTE $0xe8
RET
TEXT mfence(SB), $0
BYTE $0x0f
BYTE $0xae
BYTE $0xf0
RET
TEXT xchgw(SB), $0
MOVL v+4(FP), AX
MOVL p+0(FP), BX
XCHGW AX, (BX)
RET
TEXT cmpswap486(SB), $0
MOVL addr+0(FP), BX
MOVL old+4(FP), AX
MOVL new+8(FP), CX
LOCK
BYTE $0x0F; BYTE $0xB1; BYTE $0x0B /* CMPXCHGL CX, (BX) */
JNZ didnt
MOVL $1, AX
RET
didnt:
XORL AX,AX
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
/*
* Attempt at power saving. -rsc
*/
TEXT halt(SB), $0
CLI
CMPL nrdy(SB), $0
JEQ _nothingready
STI
RET
_nothingready:
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) /* swap AX with vectortable CALL PC */
intrcommon:
PUSHL DS /* save DS */
PUSHL $(KDSEL)
POPL DS /* fix up DS */
MOVBLZX (AX), AX /* trap type -> AX */
XCHGL AX, 4(SP) /* exchange trap type with saved AX */
PUSHL ES /* save ES */
PUSHL $(KDSEL)
POPL ES /* fix up ES */
PUSHL FS /* save the rest of the Ureg struct */
PUSHL GS
PUSHAL
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 _syscallintr(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
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