version 1.11.2.4, 2004/09/03 12:44:47 |
version 1.74, 2008/06/01 15:54:02 |
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/* $NetBSD$ */ |
/* $NetBSD$ */ |
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/* |
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* Copyright-o-rama! |
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*/ |
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/* |
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* Copyright (c) 2006 Manuel Bouyer. |
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* |
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* Redistribution and use in source and binary forms, with or without |
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* modification, are permitted provided that the following conditions |
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* are met: |
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* 1. Redistributions of source code must retain the above copyright |
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* notice, this list of conditions and the following disclaimer. |
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* 2. Redistributions in binary form must reproduce the above copyright |
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* notice, this list of conditions and the following disclaimer in the |
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* documentation and/or other materials provided with the distribution. |
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* 3. All advertising materials mentioning features or use of this software |
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* must display the following acknowledgement: |
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* This product includes software developed by Manuel Bouyer. |
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* 4. The name of the author may not be used to endorse or promote products |
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* derived from this software without specific prior written permission. |
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* |
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* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR |
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* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES |
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* OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. |
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* IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, |
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* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT |
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* NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, |
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* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY |
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* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT |
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* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF |
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* THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. |
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* |
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*/ |
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/* |
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* Copyright (c) 2001 Wasabi Systems, Inc. |
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* All rights reserved. |
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* |
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* Written by Frank van der Linden for Wasabi Systems, Inc. |
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* |
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* Redistribution and use in source and binary forms, with or without |
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* modification, are permitted provided that the following conditions |
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* are met: |
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* 1. Redistributions of source code must retain the above copyright |
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* notice, this list of conditions and the following disclaimer. |
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* 2. Redistributions in binary form must reproduce the above copyright |
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* notice, this list of conditions and the following disclaimer in the |
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* documentation and/or other materials provided with the distribution. |
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* 3. All advertising materials mentioning features or use of this software |
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* must display the following acknowledgement: |
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* This product includes software developed for the NetBSD Project by |
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* Wasabi Systems, Inc. |
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* 4. The name of Wasabi Systems, Inc. may not be used to endorse |
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* or promote products derived from this software without specific prior |
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* written permission. |
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* |
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* THIS SOFTWARE IS PROVIDED BY WASABI SYSTEMS, INC. ``AS IS'' AND |
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* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED |
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* TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR |
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* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL WASABI SYSTEMS, INC |
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* BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR |
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* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF |
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* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS |
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* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN |
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* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) |
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* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE |
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* POSSIBILITY OF SUCH DAMAGE. |
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*/ |
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/*- |
/*- |
* Copyright (c) 1998, 2000 The NetBSD Foundation, Inc. |
* Copyright (c) 1998, 2000, 2004, 2006, 2007 The NetBSD Foundation, Inc. |
* All rights reserved. |
* All rights reserved. |
* |
* |
* This code is derived from software contributed to The NetBSD Foundation |
* This code is derived from software contributed to The NetBSD Foundation |
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* 2. Redistributions in binary form must reproduce the above copyright |
* 2. Redistributions in binary form must reproduce the above copyright |
* notice, this list of conditions and the following disclaimer in the |
* notice, this list of conditions and the following disclaimer in the |
* documentation and/or other materials provided with the distribution. |
* documentation and/or other materials provided with the distribution. |
* 3. All advertising materials mentioning features or use of this software |
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* must display the following acknowledgement: |
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* This product includes software developed by the NetBSD |
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* Foundation, Inc. and its contributors. |
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* 4. Neither the name of The NetBSD Foundation nor the names of its |
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* contributors may be used to endorse or promote products derived |
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* from this software without specific prior written permission. |
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* |
* |
* THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS |
* THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS |
* ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED |
* ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED |
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* @(#)locore.s 7.3 (Berkeley) 5/13/91 |
* @(#)locore.s 7.3 (Berkeley) 5/13/91 |
*/ |
*/ |
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#include "opt_compat_netbsd.h" |
#include <machine/asm.h> |
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__KERNEL_RCSID(0, "$NetBSD$"); |
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#include "opt_compat_oldboot.h" |
#include "opt_compat_oldboot.h" |
#include "opt_cputype.h" |
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#include "opt_ddb.h" |
#include "opt_ddb.h" |
#include "opt_ipkdb.h" |
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#include "opt_lockdebug.h" |
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#include "opt_multiprocessor.h" |
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#include "opt_realmem.h" |
#include "opt_realmem.h" |
#include "opt_user_ldt.h" |
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#include "opt_vm86.h" |
#include "opt_vm86.h" |
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#include "opt_xen.h" |
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#include "npx.h" |
#include "npx.h" |
#include "assym.h" |
#include "assym.h" |
#include "apm.h" |
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#include "lapic.h" |
#include "lapic.h" |
#include "ioapic.h" |
#include "ioapic.h" |
#include "ksyms.h" |
#include "ksyms.h" |
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#include <sys/syscall.h> |
#include <sys/syscall.h> |
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#include <machine/cputypes.h> |
#include <machine/cputypes.h> |
#include <machine/param.h> |
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#include <machine/pte.h> |
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#include <machine/segments.h> |
#include <machine/segments.h> |
#include <machine/specialreg.h> |
#include <machine/specialreg.h> |
#include <machine/trap.h> |
#include <machine/trap.h> |
#include <machine/bootinfo.h> |
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#if NLAPIC > 0 |
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#include <machine/i82489reg.h> |
#include <machine/i82489reg.h> |
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#include <machine/frameasm.h> |
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#include <machine/i82489reg.h> |
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#ifndef XEN |
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#include <machine/multiboot.h> |
#endif |
#endif |
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/* LINTSTUB: include <sys/types.h> */ |
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/* LINTSTUB: include <machine/cpu.h> */ |
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/* LINTSTUB: include <sys/systm.h> */ |
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#include <machine/asm.h> |
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#if defined(MULTIPROCESSOR) |
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#define SET_CURLWP(lwp,cpu) \ |
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movl CPUVAR(SELF),cpu ; \ |
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movl lwp,CPUVAR(CURLWP) ; \ |
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movl cpu,L_CPU(lwp) |
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#else |
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#define SET_CURLWP(lwp,tcpu) movl lwp,CPUVAR(CURLWP) |
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#define GET_CURLWP(reg) movl CPUVAR(CURLWP),reg |
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#endif |
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#define GET_CURPCB(reg) movl CPUVAR(CURPCB),reg |
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#define SET_CURPCB(reg) movl reg,CPUVAR(CURPCB) |
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#define CLEAR_RESCHED(reg) movl reg,CPUVAR(RESCHED) |
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/* XXX temporary kluge; these should not be here */ |
/* XXX temporary kluge; these should not be here */ |
/* Get definitions for IOM_BEGIN, IOM_END, and IOM_SIZE */ |
/* Get definitions for IOM_BEGIN, IOM_END, and IOM_SIZE */ |
#include <dev/isa/isareg.h> |
#include <dev/isa/isareg.h> |
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#ifdef XEN |
/* Disallow old names for REALBASEMEM */ |
/* |
#ifdef BIOSBASEMEM |
* Xen guest identifier and loader selection |
#error BIOSBASEMEM option deprecated; use REALBASEMEM only if memory size reported by latest boot block is incorrect |
*/ |
#endif |
.section __xen_guest |
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#ifdef XEN3 |
/* Disallow old names for REALEXTMEM */ |
.ascii "GUEST_OS=netbsd,GUEST_VER=3.0,XEN_VER=xen-3.0" |
#ifdef EXTMEM_SIZE |
#if defined(DOM0OPS) || !defined(XEN_COMPAT_030001) |
#error EXTMEM_SIZE option deprecated; use REALEXTMEM only if memory size reported by latest boot block is incorrect |
.ascii ",VIRT_BASE=0xc0000000" /* KERNBASE */ |
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.ascii ",ELF_PADDR_OFFSET=0xc0000000" /* KERNBASE */ |
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#else |
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.ascii ",VIRT_BASE=0xc0100000" /* KERNTEXTOFF */ |
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.ascii ",ELF_PADDR_OFFSET=0xc0100000" /* KERNTEXTOFF */ |
#endif |
#endif |
#ifdef BIOSEXTMEM |
.ascii ",VIRT_ENTRY=0xc0100000" /* KERNTEXTOFF */ |
#error BIOSEXTMEM option deprecated; use REALEXTMEM only if memory size reported by latest boot block is incorrect |
#if !defined(XEN_COMPAT_030001) |
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.ascii ",HYPERCALL_PAGE=0x00000101" |
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/* (???+HYPERCALL_PAGE_OFFSET)/PAGE_SIZE) */ |
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#endif |
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#ifdef PAE |
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.ascii ",PAE=yes[extended-cr3]" |
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#endif |
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#else /* !XEN3 */ |
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.ascii "GUEST_OS=netbsd,GUEST_VER=2.0,XEN_VER=2.0" |
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#endif /* XEN3 */ |
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.ascii ",LOADER=generic" |
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#if (NKSYMS || defined(DDB) || defined(LKM)) && !defined(SYMTAB_SPACE) |
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.ascii ",BSD_SYMTAB=yes" |
#endif |
#endif |
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.byte 0 |
#include <machine/frameasm.h> |
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#ifdef MULTIPROCESSOR |
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#include <machine/i82489reg.h> |
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#endif |
#endif |
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/* This shouldn't conflict with a macro of the same name defined in pmap.h */ |
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#define PTE_BASE (PDSLOT_PTE << PDSHIFT) |
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/* |
/* |
* Initialization |
* Initialization |
*/ |
*/ |
.data |
.data |
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.globl _C_LABEL(cpu) |
.globl _C_LABEL(cpu) |
.globl _C_LABEL(esym),_C_LABEL(boothowto) |
.globl _C_LABEL(cpuid_level) |
.globl _C_LABEL(bootinfo),_C_LABEL(atdevbase) |
.globl _C_LABEL(esym) |
#ifdef COMPAT_OLDBOOT |
.globl _C_LABEL(eblob) |
.globl _C_LABEL(bootdev) |
.globl _C_LABEL(atdevbase) |
#endif |
.globl _C_LABEL(proc0uarea),_C_LABEL(PDPpaddr) |
.globl _C_LABEL(proc0paddr),_C_LABEL(PDPpaddr) |
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.globl _C_LABEL(biosbasemem),_C_LABEL(biosextmem) |
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.globl _C_LABEL(gdt) |
.globl _C_LABEL(gdt) |
#ifdef I586_CPU |
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.globl _C_LABEL(idt) |
.globl _C_LABEL(idt) |
#endif |
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.globl _C_LABEL(lapic_tpr) |
.globl _C_LABEL(lapic_tpr) |
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#if NLAPIC > 0 |
#if NLAPIC > 0 |
Line 198 _C_LABEL(lapic_tpr): |
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Line 236 _C_LABEL(lapic_tpr): |
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.long 0 |
.long 0 |
#endif |
#endif |
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_C_LABEL(cpu): .long 0 # are we 80486, Pentium, or.. |
_C_LABEL(cpu): .long 0 # are we 386, 386sx, or 486, |
_C_LABEL(cpuid_level): .long 0 |
# or Pentium, or.. |
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_C_LABEL(esym): .long 0 # ptr to end of syms |
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_C_LABEL(atdevbase): .long 0 # location of start of iomem in virtual |
_C_LABEL(atdevbase): .long 0 # location of start of iomem in virtual |
_C_LABEL(proc0paddr): .long 0 |
_C_LABEL(proc0uarea): .long 0 |
_C_LABEL(PDPpaddr): .long 0 # paddr of PDP, for libkvm |
_C_LABEL(PDPpaddr): .long 0 # paddr of PDP, for libkvm |
#ifndef REALBASEMEM |
_C_LABEL(tablesize): .long 0 |
_C_LABEL(biosbasemem): .long 0 # base memory reported by BIOS |
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#else |
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_C_LABEL(biosbasemem): .long REALBASEMEM |
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#endif |
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#ifndef REALEXTMEM |
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_C_LABEL(biosextmem): .long 0 # extended memory reported by BIOS |
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#else |
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_C_LABEL(biosextmem): .long REALEXTMEM |
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#endif |
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.space 512 |
.space 512 |
tmpstk: |
tmpstk: |
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#ifndef XEN |
#define _RELOC(x) ((x) - KERNBASE_LOCORE) |
#define _RELOC(x) ((x) - KERNBASE) |
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#else |
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#define _RELOC(x) ((x)) |
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#endif /* XEN */ |
#define RELOC(x) _RELOC(_C_LABEL(x)) |
#define RELOC(x) _RELOC(_C_LABEL(x)) |
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.text |
.text |
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.set _C_LABEL(kernel_text),KERNTEXTOFF |
.set _C_LABEL(kernel_text),KERNTEXTOFF |
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.globl start |
.globl start |
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#ifndef XEN |
start: movw $0x1234,0x472 # warm boot |
start: movw $0x1234,0x472 # warm boot |
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/* |
#if defined(MULTIBOOT) |
* Load parameters from stack |
jmp 1f |
* (howto, [bootdev], bootinfo, esym, basemem, extmem). |
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*/ |
.align 4 |
movl 4(%esp),%eax |
.globl Multiboot_Header |
movl %eax,RELOC(boothowto) |
_C_LABEL(Multiboot_Header): |
#ifdef COMPAT_OLDBOOT |
#define MULTIBOOT_HEADER_FLAGS (MULTIBOOT_HEADER_WANT_MEMORY) |
movl 8(%esp),%eax |
.long MULTIBOOT_HEADER_MAGIC |
movl %eax,RELOC(bootdev) |
.long MULTIBOOT_HEADER_FLAGS |
#endif |
.long -(MULTIBOOT_HEADER_MAGIC + MULTIBOOT_HEADER_FLAGS) |
movl 12(%esp),%eax |
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testl %eax, %eax |
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jz 1f |
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movl (%eax), %ebx /* number of entries */ |
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movl $RELOC(bootinfo), %edi |
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movl %ebx, (%edi) |
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addl $4, %edi |
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2: |
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testl %ebx, %ebx |
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jz 1f |
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addl $4, %eax |
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movl (%eax), %ecx /* address of entry */ |
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pushl %eax |
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pushl (%ecx) /* len */ |
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pushl %ecx |
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pushl %edi |
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addl (%ecx), %edi /* update dest pointer */ |
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cmpl $_RELOC(_C_LABEL(bootinfo) + BOOTINFO_MAXSIZE), %edi |
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jg 2f |
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call _C_LABEL(memcpy) |
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addl $12, %esp |
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popl %eax |
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subl $1, %ebx |
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jmp 2b |
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2: /* cleanup for overflow case */ |
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addl $16, %esp |
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movl $RELOC(bootinfo), %edi |
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subl %ebx, (%edi) /* correct number of entries */ |
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1: |
1: |
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/* Check if we are being executed by a Multiboot-compliant boot |
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* loader. */ |
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cmpl $MULTIBOOT_INFO_MAGIC,%eax |
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jne 1f |
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movl 16(%esp),%eax |
/* |
testl %eax,%eax |
* Indeed, a multiboot-compliant boot loader executed us. We copy |
jz 1f |
* the received Multiboot information structure into kernel's data |
addl $KERNBASE_LOCORE,%eax |
* space to process it later -- after we are relocated. It will |
1: movl %eax,RELOC(esym) |
* be safer to run complex C code than doing it at this point. |
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*/ |
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pushl %ebx # Address of Multiboot information |
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call _C_LABEL(multiboot_pre_reloc) |
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addl $4,%esp |
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jmp 2f |
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#endif |
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movl RELOC(biosextmem),%eax |
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testl %eax,%eax |
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jnz 1f |
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movl 20(%esp),%eax |
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movl %eax,RELOC(biosextmem) |
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1: |
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movl RELOC(biosbasemem),%eax |
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testl %eax,%eax |
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jnz 1f |
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movl 24(%esp),%eax |
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movl %eax,RELOC(biosbasemem) |
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1: |
1: |
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/* |
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* At this point, we know that a NetBSD-specific boot loader |
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* booted this kernel. The stack carries the following parameters: |
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* (boothowto, [bootdev], bootinfo, esym, biosextmem, biosbasemem), |
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* 4 bytes each. |
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*/ |
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addl $4,%esp # Discard return address to boot loader |
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call _C_LABEL(native_loader) |
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addl $24,%esp |
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2: |
/* First, reset the PSL. */ |
/* First, reset the PSL. */ |
pushl $PSL_MBO |
pushl $PSL_MBO |
popfl |
popfl |
Line 299 start: movw $0x1234,0x472 # warm boot |
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Line 311 start: movw $0x1234,0x472 # warm boot |
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movw %ax,%fs |
movw %ax,%fs |
movw %ax,%gs |
movw %ax,%gs |
decl %eax |
decl %eax |
movl %eax,RELOC(cpu_info_primary)+CPU_INFO_LEVEL |
movl %eax,RELOC(cpuid_level) |
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/* Find out our CPU type. */ |
/* Find out our CPU type. */ |
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try586: /* Use the `cpuid' instruction. */ |
try586: /* Use the `cpuid' instruction. */ |
xorl %eax,%eax |
xorl %eax,%eax |
cpuid |
cpuid |
movl %eax,RELOC(cpu_info_primary)+CPU_INFO_LEVEL |
movl %eax,RELOC(cpuid_level) |
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2: |
2: |
/* |
/* |
Line 479 try586: /* Use the `cpuid' instruction. |
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Line 491 try586: /* Use the `cpuid' instruction. |
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/* |
/* |
* Virtual address space of kernel: |
* Virtual address space of kernel: |
* |
* |
* text | data | bss | [syms] | page dir | proc0 kstack |
* text | data | bss | [syms] | [blobs] | page dir | proc0 kstack | L1 ptp |
* 0 1 2 3 |
* 0 1 2 3 |
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*/ |
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#define PROC0_PDIR_OFF 0 |
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#define PROC0_STK_OFF (PROC0_PDIR_OFF + PAGE_SIZE) |
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#define PROC0_PTP1_OFF (PROC0_STK_OFF + UPAGES * PAGE_SIZE) |
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/* |
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* fillkpt |
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* eax = pte (page frame | control | status) |
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* ebx = page table address |
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* ecx = number of pages to map |
*/ |
*/ |
#define PROC0PDIR ((0) * PAGE_SIZE) |
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#define PROC0STACK ((1) * PAGE_SIZE) |
#define fillkpt \ |
#define SYSMAP ((1+UPAGES) * PAGE_SIZE) |
1: movl %eax,(%ebx) ; /* store phys addr */ \ |
#define TABLESIZE ((1+UPAGES) * PAGE_SIZE) /* + nkpde * PAGE_SIZE */ |
addl $4,%ebx ; /* next pte/pde */ \ |
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addl $PAGE_SIZE,%eax ; /* next phys page */ \ |
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loop 1b ; \ |
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/* Find end of kernel image. */ |
/* Find end of kernel image. */ |
movl $RELOC(end),%edi |
movl $RELOC(end),%edi |
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#if (NKSYMS || defined(DDB) || defined(LKM)) && !defined(SYMTAB_SPACE) |
#if (NKSYMS || defined(DDB) || defined(LKM)) && !defined(SYMTAB_SPACE) |
/* Save the symbols (if loaded). */ |
/* Save the symbols (if loaded). */ |
movl RELOC(esym),%eax |
movl RELOC(esym),%eax |
testl %eax,%eax |
testl %eax,%eax |
jz 1f |
jz 1f |
subl $KERNBASE_LOCORE,%eax |
subl $KERNBASE,%eax |
movl %eax,%edi |
movl %eax,%edi |
1: |
1: |
#endif |
#endif |
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/* Calculate where to start the bootstrap tables. */ |
/* Skip over any modules/blobs. */ |
movl %edi,%esi # edi = esym ? esym : end |
movl RELOC(eblob),%eax |
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testl %eax,%eax |
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jz 1f |
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subl $KERNBASE,%eax |
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movl %eax,%edi |
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1: |
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/* Compute sizes */ |
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movl %edi,%esi |
addl $PGOFSET,%esi # page align up |
addl $PGOFSET,%esi # page align up |
andl $~PGOFSET,%esi |
andl $~PGOFSET,%esi |
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/* |
/* nkptp[1] = (esi + ~L2_FRAME) >> L2_SHIFT + 1; */ |
* Calculate the size of the kernel page table directory, and |
movl %esi,%eax |
* how many entries it will have. Adjust nkpde to the actual |
addl $~L2_FRAME,%eax |
* kernel size automatically. Account for the bootstrap tables, |
shrl $L2_SHIFT,%eax |
* round up, and add an extra 4MB. |
incl %eax /* one more ptp for VAs stolen by bootstrap */ |
*/ |
1: movl %eax,RELOC(nkptp)+1*4 |
leal TABLESIZE+NBPD+PDOFSET(%edi),%eax |
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shrl $PDSHIFT,%eax |
/* tablesize = (1 + UPAGES + nkptp) << PGSHIFT; */ |
movl RELOC(nkpde),%ecx # get nkpde |
addl $(1+UPAGES),%eax |
cmpl %ecx,%eax |
shll $PGSHIFT,%eax |
jb 1f |
movl %eax,RELOC(tablesize) |
movl %eax,%ecx |
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1: cmpl $NKPTP_MIN,%ecx # larger than min? |
/* ensure that nkptp covers bootstrap tables */ |
jge 1f |
addl %esi,%eax |
movl $NKPTP_MIN,%ecx # set at min |
addl $~L2_FRAME,%eax |
jmp 2f |
shrl $L2_SHIFT,%eax |
1: cmpl $NKPTP_MAX,%ecx # larger than max? |
incl %eax |
jle 2f |
cmpl %eax,RELOC(nkptp)+1*4 |
movl $NKPTP_MAX,%ecx |
jnz 1b |
2: movl %ecx,RELOC(nkpde) |
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/* Clear tables */ |
/* Clear memory for bootstrap tables. */ |
movl %esi,%edi |
shll $PGSHIFT,%ecx |
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addl $TABLESIZE,%ecx |
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addl %esi,%ecx # end of tables |
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subl %edi,%ecx # size of tables |
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shrl $2,%ecx |
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xorl %eax,%eax |
xorl %eax,%eax |
cld |
cld |
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movl RELOC(tablesize),%ecx |
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shrl $2,%ecx |
rep |
rep |
stosl |
stosl |
|
|
/* |
leal (PROC0_PTP1_OFF)(%esi), %ebx |
* fillkpt |
|
* eax = pte (page frame | control | status) |
|
* ebx = page table address |
|
* ecx = number of pages to map |
|
*/ |
|
#define fillkpt \ |
|
1: movl %eax,(%ebx) ; \ |
|
addl $PAGE_SIZE,%eax ; /* increment physical address */ \ |
|
addl $4,%ebx ; /* next pte */ \ |
|
loop 1b ; |
|
|
|
/* |
/* |
* Build initial page tables. |
* Build initial page tables. |
*/ |
*/ |
/* Calculate end of text segment, rounded to a page. */ |
/* |
leal (RELOC(etext)+PGOFSET),%edx |
* Compute &__data_start - KERNBASE. This can't be > 4G, |
|
* or we can't deal with it anyway, since we can't load it in |
|
* 32 bit mode. So use the bottom 32 bits. |
|
*/ |
|
movl $RELOC(__data_start),%edx |
andl $~PGOFSET,%edx |
andl $~PGOFSET,%edx |
|
|
/* Skip over the first 1MB. */ |
/* |
|
* Skip the first MB. |
|
*/ |
movl $_RELOC(KERNTEXTOFF),%eax |
movl $_RELOC(KERNTEXTOFF),%eax |
movl %eax,%ecx |
movl %eax,%ecx |
shrl $PGSHIFT,%ecx |
shrl $(PGSHIFT-2),%ecx /* ((n >> PGSHIFT) << 2) for # pdes */ |
leal (SYSMAP)(%esi,%ecx,4),%ebx |
addl %ecx,%ebx |
|
|
/* Map the kernel text read-only. */ |
/* Map the kernel text read-only. */ |
movl %edx,%ecx |
movl %edx,%ecx |
Line 570 try586: /* Use the `cpuid' instruction. |
|
Line 597 try586: /* Use the `cpuid' instruction. |
|
|
|
/* Map the data, BSS, and bootstrap tables read-write. */ |
/* Map the data, BSS, and bootstrap tables read-write. */ |
leal (PG_V|PG_KW)(%edx),%eax |
leal (PG_V|PG_KW)(%edx),%eax |
movl RELOC(nkpde),%ecx |
movl RELOC(tablesize),%ecx |
shll $PGSHIFT,%ecx |
|
addl $TABLESIZE,%ecx |
|
addl %esi,%ecx # end of tables |
addl %esi,%ecx # end of tables |
subl %edx,%ecx # subtract end of text |
subl %edx,%ecx # subtract end of text |
shrl $PGSHIFT,%ecx |
shrl $PGSHIFT,%ecx |
fillkpt |
fillkpt |
|
|
/* Map ISA I/O memory. */ |
/* Map ISA I/O mem (later atdevbase) */ |
movl $(IOM_BEGIN|PG_V|PG_KW/*|PG_N*/),%eax # having these bits set |
movl $(IOM_BEGIN|PG_V|PG_KW/*|PG_N*/),%eax # having these bits set |
movl $(IOM_SIZE>>PGSHIFT),%ecx # for this many pte s, |
movl $(IOM_SIZE>>PGSHIFT),%ecx # for this many pte s, |
fillkpt |
fillkpt |
Line 586 try586: /* Use the `cpuid' instruction. |
|
Line 611 try586: /* Use the `cpuid' instruction. |
|
/* |
/* |
* Construct a page table directory. |
* Construct a page table directory. |
*/ |
*/ |
/* Install PDEs for temporary double map of kernel. */ |
/* Set up top level entries for identity mapping */ |
movl RELOC(nkpde),%ecx # for this many pde s, |
leal (PROC0_PDIR_OFF)(%esi),%ebx |
leal (PROC0PDIR+0*4)(%esi),%ebx # which is where temp maps! |
leal (PROC0_PTP1_OFF)(%esi),%eax |
leal (SYSMAP+PG_V|PG_KW)(%esi),%eax # pte for KPT in proc 0, |
orl $(PG_V|PG_KW), %eax |
|
movl RELOC(nkptp)+1*4,%ecx |
fillkpt |
fillkpt |
|
|
/* Map kernel PDEs. */ |
/* Set up top level entries for actual kernel mapping */ |
movl RELOC(nkpde),%ecx # for this many pde s, |
leal (PROC0_PDIR_OFF + L2_SLOT_KERNBASE*4)(%esi),%ebx |
leal (PROC0PDIR+PDSLOT_KERN*4)(%esi),%ebx # kernel pde offset |
leal (PROC0_PTP1_OFF)(%esi),%eax |
leal (SYSMAP+PG_V|PG_KW)(%esi),%eax # pte for KPT in proc 0, |
orl $(PG_V|PG_KW), %eax |
|
movl RELOC(nkptp)+1*4,%ecx |
fillkpt |
fillkpt |
|
|
/* Install a PDE recursively mapping page directory as a page table! */ |
/* Install a PDE recursively mapping page directory as a page table! */ |
leal (PROC0PDIR+PG_V|PG_KW)(%esi),%eax # pte for ptd |
leal (PROC0_PDIR_OFF + PDIR_SLOT_PTE*4)(%esi),%ebx |
movl %eax,(PROC0PDIR+PDSLOT_PTE*4)(%esi) # recursive PD slot |
leal (PROC0_PDIR_OFF)(%esi),%eax |
|
orl $(PG_V|PG_KW),%eax |
|
movl %eax,(%ebx) |
|
|
|
|
/* Save phys. addr of PDP, for libkvm. */ |
/* Save phys. addr of PDP, for libkvm. */ |
movl %esi,RELOC(PDPpaddr) |
movl %esi,RELOC(PDPpaddr) |
|
|
/* Load base of page directory and enable mapping. */ |
/* |
|
* Startup checklist: |
|
* 1. Load %cr3 with pointer to PDIR. |
|
*/ |
movl %esi,%eax # phys address of ptd in proc 0 |
movl %esi,%eax # phys address of ptd in proc 0 |
movl %eax,%cr3 # load ptd addr into mmu |
movl %eax,%cr3 # load ptd addr into mmu |
|
|
|
/* |
|
* 2. Enable paging and the rest of it. |
|
*/ |
movl %cr0,%eax # get control word |
movl %cr0,%eax # get control word |
# enable paging & NPX emulation |
# enable paging & NPX emulation |
orl $(CR0_PE|CR0_PG|CR0_NE|CR0_TS|CR0_EM|CR0_MP),%eax |
orl $(CR0_PE|CR0_PG|CR0_NE|CR0_TS|CR0_EM|CR0_MP),%eax |
Line 617 try586: /* Use the `cpuid' instruction. |
|
Line 654 try586: /* Use the `cpuid' instruction. |
|
ret |
ret |
|
|
begin: |
begin: |
/* Now running relocated at KERNBASE_LOCORE. Remove double mapping. */ |
/* |
movl _C_LABEL(nkpde),%ecx # for this many pde s, |
* We have arrived. |
leal (PROC0PDIR+0*4)(%esi),%ebx # which is where temp maps! |
* There's no need anymore for the identity mapping in low |
addl $(KERNBASE_LOCORE), %ebx # now use relocated address |
* memory, remove it. |
|
*/ |
|
movl _C_LABEL(nkptp)+1*4,%ecx |
|
leal (PROC0_PDIR_OFF)(%esi),%ebx # old, phys address of PDIR |
|
addl $(KERNBASE), %ebx # new, virtual address of PDIR |
1: movl $0,(%ebx) |
1: movl $0,(%ebx) |
addl $4,%ebx # next pde |
addl $4,%ebx |
loop 1b |
loop 1b |
|
|
/* Relocate atdevbase. */ |
/* Relocate atdevbase. */ |
movl _C_LABEL(nkpde),%edx |
movl $KERNBASE,%edx |
shll $PGSHIFT,%edx |
addl _C_LABEL(tablesize),%edx |
addl $(TABLESIZE+KERNBASE_LOCORE),%edx |
|
addl %esi,%edx |
addl %esi,%edx |
movl %edx,_C_LABEL(atdevbase) |
movl %edx,_C_LABEL(atdevbase) |
|
|
/* Set up bootstrap stack. */ |
/* Set up bootstrap stack. */ |
leal (PROC0STACK+KERNBASE_LOCORE)(%esi),%eax |
leal (PROC0_STK_OFF+KERNBASE)(%esi),%eax |
movl %eax,_C_LABEL(proc0paddr) |
movl %eax,_C_LABEL(proc0uarea) |
leal (USPACE-FRAMESIZE)(%eax),%esp |
leal (KSTACK_SIZE-FRAMESIZE)(%eax),%esp |
movl %esi,PCB_CR3(%eax) # pcb->pcb_cr3 |
movl %esi,(KSTACK_SIZE+PCB_CR3)(%eax) # pcb->pcb_cr3 |
xorl %ebp,%ebp # mark end of frames |
xorl %ebp,%ebp # mark end of frames |
|
|
|
#if defined(MULTIBOOT) |
|
/* It is now safe to parse the Multiboot information structure |
|
* we saved before from C code. Note that we cannot delay its |
|
* parsing any more because initgdt (called below) needs to make |
|
* use of this information. */ |
|
call _C_LABEL(multiboot_post_reloc) |
|
#endif |
|
|
subl $NGDT*8, %esp # space for temporary gdt |
subl $NGDT*8, %esp # space for temporary gdt |
pushl %esp |
pushl %esp |
call _C_LABEL(initgdt) |
call _C_LABEL(initgdt) |
addl $4,%esp |
addl $4,%esp |
|
|
movl _C_LABEL(nkpde),%eax |
movl _C_LABEL(tablesize),%eax |
shll $PGSHIFT,%eax |
|
addl $TABLESIZE,%eax |
|
addl %esi,%eax # skip past stack and page tables |
addl %esi,%eax # skip past stack and page tables |
|
|
pushl %eax |
pushl %eax |
|
|
#endif /* SAFARI_FIFO_HACK */ |
#endif /* SAFARI_FIFO_HACK */ |
|
|
call _C_LABEL(main) |
call _C_LABEL(main) |
|
#else /* XEN */ |
|
start: |
|
/* First, reset the PSL. */ |
|
pushl $PSL_MBO |
|
popfl |
|
|
|
cld |
|
#ifdef XEN3 |
|
movl %esp, %ebx # save start of available space |
|
#else |
|
movl %esi,%ebx # save start_info pointer |
|
#endif |
|
movl $_RELOC(tmpstk),%esp # bootstrap stack end location |
|
|
|
/* Clear BSS first so that there are no surprises... */ |
|
xorl %eax,%eax |
|
movl $RELOC(__bss_start),%edi |
|
movl $RELOC(_end),%ecx |
|
subl %edi,%ecx |
|
rep stosb |
|
|
|
/* Copy the necessary stuff from start_info structure. */ |
|
/* We need to copy shared_info early, so that sti/cli work */ |
|
movl $RELOC(start_info_union),%edi |
|
movl $128,%ecx |
|
rep movsl |
|
|
|
/* Clear segment registers; always null in proc0. */ |
|
xorl %eax,%eax |
|
movw %ax,%fs |
|
movw %ax,%gs |
|
decl %eax |
|
movl %eax,RELOC(cpuid_level) |
|
|
|
xorl %eax,%eax |
|
cpuid |
|
movl %eax,RELOC(cpuid_level) |
|
|
|
call xen_pmap_bootstrap |
|
/* |
|
* First avail returned by xen_pmap_bootstrap in %eax |
|
*/ |
|
movl %eax, %esi; |
|
movl %esi, _C_LABEL(proc0uarea) |
|
|
|
#define PROC0PDIR ((0) * PAGE_SIZE) |
|
#define PROC0STACK ((1) * PAGE_SIZE) |
|
|
|
/* Set up bootstrap stack. */ |
|
leal (KSTACK_SIZE-FRAMESIZE)(%eax),%esp |
|
xorl %ebp,%ebp # mark end of frames |
|
|
|
addl $USPACE, %esi |
|
subl $KERNBASE, %esi #init386 want a physical address |
|
pushl %esi |
|
call _C_LABEL(init386) # wire 386 chip for unix operation |
|
addl $4,%esp |
|
call _C_LABEL(main) |
|
|
|
#if defined(XEN3) && !defined(XEN_COMPAT_030001) |
|
/* space for the hypercall call page */ |
|
#define HYPERCALL_PAGE_OFFSET 0x1000 |
|
.org HYPERCALL_PAGE_OFFSET |
|
ENTRY(hypercall_page) |
|
.skip 0x1000 |
|
#endif /* defined(XEN3) && !defined(XEN_COMPAT_030001) */ |
|
|
|
/* |
|
* void lgdt_finish(void); |
|
* Finish load a new GDT pointer (do any necessary cleanup). |
|
* XXX It's somewhat questionable whether reloading all the segment registers |
|
* is necessary, since the actual descriptor data is not changed except by |
|
* process creation and exit, both of which clean up via task switches. OTOH, |
|
* this only happens at run time when the GDT is resized. |
|
*/ |
|
/* LINTSTUB: Func: void lgdt_finish(void) */ |
|
NENTRY(lgdt_finish) |
|
movl $GSEL(GDATA_SEL, SEL_KPL),%eax |
|
movw %ax,%ds |
|
movw %ax,%es |
|
movw %ax,%gs |
|
movw %ax,%ss |
|
movl $GSEL(GCPU_SEL, SEL_KPL),%eax |
|
movw %ax,%fs |
|
/* Reload code selector by doing intersegment return. */ |
|
popl %eax |
|
pushl $GSEL(GCODE_SEL, SEL_KPL) |
|
pushl %eax |
|
lret |
|
END(lgdt_finish) |
|
|
|
#endif /* XEN */ |
|
|
/* |
/* |
* void proc_trampoline(void); |
* void lwp_trampoline(void); |
|
* |
* This is a trampoline function pushed onto the stack of a newly created |
* This is a trampoline function pushed onto the stack of a newly created |
* process in order to do some additional setup. The trampoline is entered by |
* process in order to do some additional setup. The trampoline is entered by |
* cpu_switch()ing to the process, so we abuse the callee-saved registers used |
* cpu_switch()ing to the process, so we abuse the callee-saved registers used |
* by cpu_switch() to store the information about the stub to call. |
* by cpu_switch() to store the information about the stub to call. |
* NOTE: This function does not have a normal calling sequence! |
* NOTE: This function does not have a normal calling sequence! |
*/ |
*/ |
/* LINTSTUB: Func: void proc_trampoline(void) */ |
NENTRY(lwp_trampoline) |
NENTRY(proc_trampoline) |
movl %ebp,%edi /* for .Lsyscall_checkast */ |
#ifdef MULTIPROCESSOR |
xorl %ebp,%ebp |
call _C_LABEL(proc_trampoline_mp) |
pushl %edi |
#endif |
pushl %eax |
movl $IPL_NONE,CPUVAR(ILEVEL) |
call _C_LABEL(lwp_startup) |
|
addl $8,%esp |
pushl %ebx |
pushl %ebx |
call *%esi |
call *%esi |
addl $4,%esp |
addl $4,%esp |
DO_DEFERRED_SWITCH(%eax) |
jmp .Lsyscall_checkast |
INTRFASTEXIT |
|
/* NOTREACHED */ |
/* NOTREACHED */ |
|
END(lwp_trampoline) |
|
|
/*****************************************************************************/ |
|
#ifdef COMPAT_16 |
|
/* |
/* |
* Signal trampoline; copied to top of user stack. |
* sigcode() |
|
* |
|
* Signal trampoline; copied to top of user stack. Used only for |
|
* compatibility with old releases of NetBSD. |
*/ |
*/ |
/* LINTSTUB: Var: char sigcode[1], esigcode[1]; */ |
|
NENTRY(sigcode) |
NENTRY(sigcode) |
/* |
/* |
* Handler has returned here as if we called it. The sigcontext |
* Handler has returned here as if we called it. The sigcontext |
|
|
int $0x80 # exit if sigreturn fails |
int $0x80 # exit if sigreturn fails |
.globl _C_LABEL(esigcode) |
.globl _C_LABEL(esigcode) |
_C_LABEL(esigcode): |
_C_LABEL(esigcode): |
#endif |
END(sigcode) |
|
|
/*****************************************************************************/ |
|
|
|
/* |
/* |
* The following primitives are used to fill and copy regions of memory. |
* int setjmp(label_t *) |
|
* |
|
* Used primarily by DDB. |
*/ |
*/ |
|
ENTRY(setjmp) |
|
movl 4(%esp),%eax |
|
movl %ebx,(%eax) # save ebx |
|
movl %esp,4(%eax) # save esp |
|
movl %ebp,8(%eax) # save ebp |
|
movl %esi,12(%eax) # save esi |
|
movl %edi,16(%eax) # save edi |
|
movl (%esp),%edx # get rta |
|
movl %edx,20(%eax) # save eip |
|
xorl %eax,%eax # return 0 |
|
ret |
|
END(setjmp) |
|
|
/* |
/* |
* XXX No section 9 man page for fillw. |
* int longjmp(label_t *) |
* fillw seems to be very sparsely used (only in pccons it seems.) |
* |
* One wonders if it couldn't be done without. |
* Used primarily by DDB. |
* -- Perry Metzger, May 7, 2001 |
|
*/ |
*/ |
|
ENTRY(longjmp) |
|
movl 4(%esp),%eax |
|
movl (%eax),%ebx # restore ebx |
|
movl 4(%eax),%esp # restore esp |
|
movl 8(%eax),%ebp # restore ebp |
|
movl 12(%eax),%esi # restore esi |
|
movl 16(%eax),%edi # restore edi |
|
movl 20(%eax),%edx # get rta |
|
movl %edx,(%esp) # put in return frame |
|
movl $1,%eax # return 1 |
|
ret |
|
END(longjmp) |
|
|
/* |
/* |
* void fillw(short pattern, void *addr, size_t len); |
* void dumpsys(void) |
* Write len copies of pattern at addr. |
* |
|
* Mimic cpu_switchto() for postmortem debugging. |
*/ |
*/ |
/* LINTSTUB: Func: void fillw(short pattern, void *addr, size_t len) */ |
ENTRY(dumpsys) |
ENTRY(fillw) |
pushl %ebx # set up fake switchframe |
pushl %edi |
pushl %esi # and save context |
movl 8(%esp),%eax |
pushl %edi |
movl 12(%esp),%edi |
movl %esp,_C_LABEL(dumppcb)+PCB_ESP |
movw %ax,%cx |
movl %ebp,_C_LABEL(dumppcb)+PCB_EBP |
rorl $16,%eax |
call _C_LABEL(dodumpsys) # dump! |
movw %cx,%ax |
addl $(3*4), %esp # unwind switchframe |
cld |
|
movl 16(%esp),%ecx |
|
shrl %ecx # do longwords |
|
rep |
|
stosl |
|
movl 16(%esp),%ecx |
|
andl $1,%ecx # do remainder |
|
rep |
|
stosw |
|
popl %edi |
|
ret |
ret |
|
END(dumpsys) |
|
|
/* |
/* |
* int kcopy(const void *from, void *to, size_t len); |
* struct lwp *cpu_switchto(struct lwp *oldlwp, struct newlwp, |
* Copy len bytes, abort on fault. |
* bool returning) |
|
* |
|
* 1. if (oldlwp != NULL), save its context. |
|
* 2. then, restore context of newlwp. |
|
* |
|
* Note that the stack frame layout is known to "struct switchframe" in |
|
* <machine/frame.h> and to the code in cpu_lwp_fork() which initializes |
|
* it for a new lwp. |
*/ |
*/ |
/* LINTSTUB: Func: int kcopy(const void *from, void *to, size_t len) */ |
ENTRY(cpu_switchto) |
ENTRY(kcopy) |
pushl %ebx |
pushl %esi |
pushl %esi |
pushl %edi |
pushl %edi |
GET_CURPCB(%eax) # load curpcb into eax and set on-fault |
|
pushl PCB_ONFAULT(%eax) |
|
movl $_C_LABEL(kcopy_fault), PCB_ONFAULT(%eax) |
|
|
|
movl 16(%esp),%esi |
|
movl 20(%esp),%edi |
|
movl 24(%esp),%ecx |
|
movl %edi,%eax |
|
subl %esi,%eax |
|
cmpl %ecx,%eax # overlapping? |
|
jb 1f |
|
cld # nope, copy forward |
|
shrl $2,%ecx # copy by 32-bit words |
|
rep |
|
movsl |
|
movl 24(%esp),%ecx |
|
andl $3,%ecx # any bytes left? |
|
rep |
|
movsb |
|
|
|
GET_CURPCB(%edx) # XXX save curpcb? |
#if defined(DIAGNOSTIC) && !defined(XEN) |
popl PCB_ONFAULT(%edx) |
cmpl $IPL_SCHED,CPUVAR(ILEVEL) |
popl %edi |
jbe 0f |
popl %esi |
pushl CPUVAR(ILEVEL) |
xorl %eax,%eax |
pushl $.Lstr |
ret |
call _C_LABEL(panic) |
|
addl $8,%esp |
|
.Lstr: .string "cpu_switchto: switching above IPL_SCHED (%d)\0" |
|
0: |
|
#endif |
|
|
ALIGN_TEXT |
movl 16(%esp),%esi # oldlwp |
1: addl %ecx,%edi # copy backward |
movl 20(%esp),%edi # newlwp |
addl %ecx,%esi |
movl 24(%esp),%edx # returning |
std |
testl %esi,%esi |
andl $3,%ecx # any fractional bytes? |
jz 1f |
decl %edi |
|
decl %esi |
|
rep |
|
movsb |
|
movl 24(%esp),%ecx # copy remainder by 32-bit words |
|
shrl $2,%ecx |
|
subl $3,%esi |
|
subl $3,%edi |
|
rep |
|
movsl |
|
cld |
|
|
|
GET_CURPCB(%edx) |
|
popl PCB_ONFAULT(%edx) |
|
popl %edi |
|
popl %esi |
|
xorl %eax,%eax |
|
ret |
|
|
|
/*****************************************************************************/ |
|
|
|
/* |
|
* The following primitives are used to copy data in and out of the user's |
|
* address space. |
|
*/ |
|
|
|
/* |
|
* Default to the lowest-common-denominator. We will improve it |
|
* later. |
|
*/ |
|
#if defined(I386_CPU) |
|
#define DEFAULT_COPYOUT _C_LABEL(i386_copyout) |
|
#define DEFAULT_COPYIN _C_LABEL(i386_copyin) |
|
#elif defined(I486_CPU) |
|
#define DEFAULT_COPYOUT _C_LABEL(i486_copyout) |
|
#define DEFAULT_COPYIN _C_LABEL(i386_copyin) |
|
#elif defined(I586_CPU) |
|
#define DEFAULT_COPYOUT _C_LABEL(i486_copyout) /* XXX */ |
|
#define DEFAULT_COPYIN _C_LABEL(i386_copyin) /* XXX */ |
|
#elif defined(I686_CPU) |
|
#define DEFAULT_COPYOUT _C_LABEL(i486_copyout) /* XXX */ |
|
#define DEFAULT_COPYIN _C_LABEL(i386_copyin) /* XXX */ |
|
#endif |
|
|
|
.data |
|
|
|
.globl _C_LABEL(copyout_func) |
|
_C_LABEL(copyout_func): |
|
.long DEFAULT_COPYOUT |
|
|
|
.globl _C_LABEL(copyin_func) |
|
_C_LABEL(copyin_func): |
|
.long DEFAULT_COPYIN |
|
|
|
.text |
|
|
|
/* |
|
* int copyout(const void *from, void *to, size_t len); |
|
* Copy len bytes into the user's address space. |
|
* see copyout(9) |
|
*/ |
|
/* LINTSTUB: Func: int copyout(const void *kaddr, void *uaddr, size_t len) */ |
|
ENTRY(copyout) |
|
DO_DEFERRED_SWITCH(%eax) |
|
jmp *_C_LABEL(copyout_func) |
|
|
|
#if defined(I386_CPU) |
|
/* LINTSTUB: Func: int i386_copyout(const void *kaddr, void *uaddr, size_t len) */ |
|
ENTRY(i386_copyout) |
|
pushl %esi |
|
pushl %edi |
|
pushl $0 |
|
|
|
movl 16(%esp),%esi |
|
movl 20(%esp),%edi |
|
movl 24(%esp),%eax |
|
|
|
/* |
|
* We check that the end of the destination buffer is not past the end |
|
* of the user's address space. If it's not, then we only need to |
|
* check that each page is writable. The 486 will do this for us; the |
|
* 386 will not. (We assume that pages in user space that are not |
|
* writable by the user are not writable by the kernel either.) |
|
*/ |
|
movl %edi,%edx |
|
addl %eax,%edx |
|
jc _C_LABEL(copy_efault) |
|
cmpl $VM_MAXUSER_ADDRESS,%edx |
|
ja _C_LABEL(copy_efault) |
|
|
|
testl %eax,%eax # anything to do? |
/* Save old context. */ |
jz 3f |
movl L_ADDR(%esi),%eax |
|
movl %esp,PCB_ESP(%eax) |
|
movl %ebp,PCB_EBP(%eax) |
|
|
|
/* Switch to newlwp's stack. */ |
|
1: movl L_ADDR(%edi),%ebx |
|
movl PCB_EBP(%ebx),%ebp |
|
movl PCB_ESP(%ebx),%esp |
|
|
/* |
/* |
* We have to check each PTE for (write) permission, since the CPU |
* Set curlwp. This must be globally visible in order to permit |
* doesn't do it for us. |
* non-interlocked mutex release. |
*/ |
*/ |
|
|
/* Compute number of pages. */ |
|
movl %edi,%ecx |
movl %edi,%ecx |
andl $PGOFSET,%ecx |
xchgl %ecx,CPUVAR(CURLWP) |
addl %eax,%ecx |
|
decl %ecx |
|
shrl $PGSHIFT,%ecx |
|
|
|
/* Compute PTE offset for start address. */ |
|
shrl $PGSHIFT,%edi |
|
|
|
GET_CURPCB(%edx) |
|
movl $2f,PCB_ONFAULT(%edx) |
|
|
|
1: /* Check PTE for each page. */ |
|
testb $PG_RW,PTE_BASE(,%edi,4) |
|
jz 2f |
|
|
|
4: incl %edi |
|
decl %ecx |
|
jns 1b |
|
|
|
movl 20(%esp),%edi |
|
movl 24(%esp),%eax |
|
jmp 3f |
|
|
|
2: /* Simulate a trap. */ |
|
pushl %ecx |
|
movl %edi,%eax |
|
shll $PGSHIFT,%eax |
|
pushl %eax |
|
call _C_LABEL(trapwrite) # trapwrite(addr) |
|
addl $4,%esp # pop argument |
|
popl %ecx |
|
testl %eax,%eax # if not ok, return EFAULT |
|
jz 4b |
|
jmp _C_LABEL(copy_efault) |
|
|
|
3: GET_CURPCB(%edx) |
|
movl $_C_LABEL(copy_fault),PCB_ONFAULT(%edx) |
|
|
|
/* bcopy(%esi, %edi, %eax); */ |
|
cld |
|
movl %eax,%ecx |
|
shrl $2,%ecx |
|
rep |
|
movsl |
|
movl %eax,%ecx |
|
andl $3,%ecx |
|
rep |
|
movsb |
|
|
|
popl PCB_ONFAULT(%edx) |
|
popl %edi |
|
popl %esi |
|
xorl %eax,%eax |
|
ret |
|
#endif /* I386_CPU */ |
|
|
|
#if defined(I486_CPU) || defined(I586_CPU) || defined(I686_CPU) |
|
/* LINTSTUB: Func: int i486_copyout(const void *kaddr, void *uaddr, size_t len) */ |
|
ENTRY(i486_copyout) |
|
pushl %esi |
|
pushl %edi |
|
pushl $0 |
|
|
|
movl 16(%esp),%esi |
|
movl 20(%esp),%edi |
|
movl 24(%esp),%eax |
|
|
|
/* |
|
* We check that the end of the destination buffer is not past the end |
|
* of the user's address space. |
|
*/ |
|
movl %edi,%edx |
|
addl %eax,%edx |
|
jc _C_LABEL(copy_efault) |
|
cmpl $VM_MAXUSER_ADDRESS,%edx |
|
ja _C_LABEL(copy_efault) |
|
|
|
GET_CURPCB(%edx) |
|
movl $_C_LABEL(copy_fault),PCB_ONFAULT(%edx) |
|
|
|
/* bcopy(%esi, %edi, %eax); */ |
|
cld |
|
movl %eax,%ecx |
|
shrl $2,%ecx |
|
rep |
|
movsl |
|
movl %eax,%ecx |
|
andl $3,%ecx |
|
rep |
|
movsb |
|
|
|
popl PCB_ONFAULT(%edx) |
|
popl %edi |
|
popl %esi |
|
xorl %eax,%eax |
|
ret |
|
#endif /* I486_CPU || I586_CPU || I686_CPU */ |
|
|
|
/* |
|
* int copyin(const void *from, void *to, size_t len); |
|
* Copy len bytes from the user's address space. |
|
* see copyin(9) |
|
*/ |
|
/* LINTSTUB: Func: int copyin(const void *uaddr, void *kaddr, size_t len) */ |
|
ENTRY(copyin) |
|
DO_DEFERRED_SWITCH(%eax) |
|
jmp *_C_LABEL(copyin_func) |
|
|
|
#if defined(I386_CPU) || defined(I486_CPU) || defined(I586_CPU) || \ |
|
defined(I686_CPU) |
|
/* LINTSTUB: Func: int i386_copyin(const void *uaddr, void *kaddr, size_t len) */ |
|
ENTRY(i386_copyin) |
|
pushl %esi |
|
pushl %edi |
|
GET_CURPCB(%eax) |
|
pushl $0 |
|
movl $_C_LABEL(copy_fault),PCB_ONFAULT(%eax) |
|
|
|
movl 16(%esp),%esi |
|
movl 20(%esp),%edi |
|
movl 24(%esp),%eax |
|
|
|
/* |
|
* We check that the end of the destination buffer is not past the end |
|
* of the user's address space. If it's not, then we only need to |
|
* check that each page is readable, and the CPU will do that for us. |
|
*/ |
|
movl %esi,%edx |
|
addl %eax,%edx |
|
jc _C_LABEL(copy_efault) |
|
cmpl $VM_MAXUSER_ADDRESS,%edx |
|
ja _C_LABEL(copy_efault) |
|
|
|
/* bcopy(%esi, %edi, %eax); */ |
|
cld |
|
movl %eax,%ecx |
|
shrl $2,%ecx |
|
rep |
|
movsl |
|
movl %eax,%ecx |
|
andl $3,%ecx |
|
rep |
|
movsb |
|
|
|
GET_CURPCB(%edx) |
|
popl PCB_ONFAULT(%edx) |
|
popl %edi |
|
popl %esi |
|
xorl %eax,%eax |
|
ret |
|
#endif /* I386_CPU || I486_CPU || I586_CPU || I686_CPU */ |
|
|
|
/* LINTSTUB: Ignore */ |
|
NENTRY(copy_efault) |
|
movl $EFAULT,%eax |
|
|
|
/* |
|
* kcopy_fault is used by kcopy and copy_fault is used by copyin/out. |
|
* |
|
* they're distinguished for lazy pmap switching. see trap(). |
|
*/ |
|
/* LINTSTUB: Ignore */ |
|
NENTRY(kcopy_fault) |
|
GET_CURPCB(%edx) |
|
popl PCB_ONFAULT(%edx) |
|
popl %edi |
|
popl %esi |
|
ret |
|
|
|
/* LINTSTUB: Ignore */ |
|
NENTRY(copy_fault) |
|
GET_CURPCB(%edx) |
|
popl PCB_ONFAULT(%edx) |
|
popl %edi |
|
popl %esi |
|
ret |
|
|
|
/* |
|
* int copyoutstr(const void *from, void *to, size_t maxlen, size_t *lencopied); |
|
* Copy a NUL-terminated string, at most maxlen characters long, into the |
|
* user's address space. Return the number of characters copied (including the |
|
* NUL) in *lencopied. If the string is too long, return ENAMETOOLONG; else |
|
* return 0 or EFAULT. |
|
* see copyoutstr(9) |
|
*/ |
|
/* LINTSTUB: Func: int copyoutstr(const void *kaddr, void *uaddr, size_t len, size_t *done) */ |
|
ENTRY(copyoutstr) |
|
pushl %esi |
|
pushl %edi |
|
|
|
DO_DEFERRED_SWITCH(%eax) |
|
|
|
movl 12(%esp),%esi # esi = from |
|
movl 16(%esp),%edi # edi = to |
|
movl 20(%esp),%edx # edx = maxlen |
|
|
|
#if defined(I386_CPU) |
|
#if defined(I486_CPU) || defined(I586_CPU) || defined(I686_CPU) |
|
cmpl $CPUCLASS_386,_C_LABEL(cpu_class) |
|
jne 5f |
|
#endif /* I486_CPU || I586_CPU || I686_CPU */ |
|
|
|
/* Compute number of bytes in first page. */ |
|
movl %edi,%eax |
|
andl $PGOFSET,%eax |
|
movl $PAGE_SIZE,%ecx |
|
subl %eax,%ecx # ecx = PAGE_SIZE - (src % PAGE_SIZE) |
|
|
|
GET_CURPCB(%eax) |
|
movl $6f,PCB_ONFAULT(%eax) |
|
|
|
1: /* |
|
* Once per page, check that we are still within the bounds of user |
|
* space, and check for a write fault. |
|
*/ |
|
cmpl $VM_MAXUSER_ADDRESS,%edi |
|
jae _C_LABEL(copystr_efault) |
|
|
|
/* Compute PTE offset. */ |
|
movl %edi,%eax |
|
shrl $PGSHIFT,%eax # calculate pte address |
|
|
|
testb $PG_RW,PTE_BASE(,%eax,4) |
|
jnz 2f |
|
|
|
6: /* Simulate a trap. */ |
|
pushl %edx |
|
pushl %edi |
|
call _C_LABEL(trapwrite) # trapwrite(addr) |
|
addl $4,%esp # clear argument from stack |
|
popl %edx |
|
testl %eax,%eax |
|
jnz _C_LABEL(copystr_efault) |
|
|
|
2: /* Copy up to end of this page. */ |
/* Skip the rest if returning to a pinned LWP. */ |
subl %ecx,%edx # predecrement total count |
|
jnc 3f |
|
addl %edx,%ecx # ecx += (edx - ecx) = edx |
|
xorl %edx,%edx |
|
|
|
3: decl %ecx |
|
js 4f |
|
lodsb |
|
stosb |
|
testb %al,%al |
|
jnz 3b |
|
|
|
/* Success -- 0 byte reached. */ |
|
addl %ecx,%edx # add back residual for this page |
|
xorl %eax,%eax |
|
jmp copystr_return |
|
|
|
4: /* Go to next page, if any. */ |
|
movl $PAGE_SIZE,%ecx |
|
testl %edx,%edx |
|
jnz 1b |
|
|
|
/* edx is zero -- return ENAMETOOLONG. */ |
|
movl $ENAMETOOLONG,%eax |
|
jmp copystr_return |
|
#endif /* I386_CPU */ |
|
|
|
#if defined(I486_CPU) || defined(I586_CPU) || defined(I686_CPU) |
|
5: GET_CURPCB(%eax) |
|
movl $_C_LABEL(copystr_fault),PCB_ONFAULT(%eax) |
|
/* |
|
* Get min(%edx, VM_MAXUSER_ADDRESS-%edi). |
|
*/ |
|
movl $VM_MAXUSER_ADDRESS,%eax |
|
subl %edi,%eax |
|
cmpl %edx,%eax |
|
jae 1f |
|
movl %eax,%edx |
|
movl %eax,20(%esp) |
|
|
|
1: incl %edx |
|
cld |
|
|
|
1: decl %edx |
|
jz 2f |
|
lodsb |
|
stosb |
|
testb %al,%al |
|
jnz 1b |
|
|
|
/* Success -- 0 byte reached. */ |
|
decl %edx |
|
xorl %eax,%eax |
|
jmp copystr_return |
|
|
|
2: /* edx is zero -- return EFAULT or ENAMETOOLONG. */ |
|
cmpl $VM_MAXUSER_ADDRESS,%edi |
|
jae _C_LABEL(copystr_efault) |
|
movl $ENAMETOOLONG,%eax |
|
jmp copystr_return |
|
#endif /* I486_CPU || I586_CPU || I686_CPU */ |
|
|
|
/* |
|
* int copyinstr(const void *from, void *to, size_t maxlen, size_t *lencopied); |
|
* Copy a NUL-terminated string, at most maxlen characters long, from the |
|
* user's address space. Return the number of characters copied (including the |
|
* NUL) in *lencopied. If the string is too long, return ENAMETOOLONG; else |
|
* return 0 or EFAULT. |
|
* see copyinstr(9) |
|
*/ |
|
/* LINTSTUB: Func: int copyinstr(const void *uaddr, void *kaddr, size_t len, size_t *done) */ |
|
ENTRY(copyinstr) |
|
pushl %esi |
|
pushl %edi |
|
|
|
DO_DEFERRED_SWITCH(%eax) |
|
|
|
GET_CURPCB(%ecx) |
|
movl $_C_LABEL(copystr_fault),PCB_ONFAULT(%ecx) |
|
|
|
movl 12(%esp),%esi # %esi = from |
|
movl 16(%esp),%edi # %edi = to |
|
movl 20(%esp),%edx # %edx = maxlen |
|
|
|
/* |
|
* Get min(%edx, VM_MAXUSER_ADDRESS-%esi). |
|
*/ |
|
movl $VM_MAXUSER_ADDRESS,%eax |
|
subl %esi,%eax |
|
cmpl %edx,%eax |
|
jae 1f |
|
movl %eax,%edx |
|
movl %eax,20(%esp) |
|
|
|
1: incl %edx |
|
cld |
|
|
|
1: decl %edx |
|
jz 2f |
|
lodsb |
|
stosb |
|
testb %al,%al |
|
jnz 1b |
|
|
|
/* Success -- 0 byte reached. */ |
|
decl %edx |
|
xorl %eax,%eax |
|
jmp copystr_return |
|
|
|
2: /* edx is zero -- return EFAULT or ENAMETOOLONG. */ |
|
cmpl $VM_MAXUSER_ADDRESS,%esi |
|
jae _C_LABEL(copystr_efault) |
|
movl $ENAMETOOLONG,%eax |
|
jmp copystr_return |
|
|
|
/* LINTSTUB: Ignore */ |
|
NENTRY(copystr_efault) |
|
movl $EFAULT,%eax |
|
|
|
/* LINTSTUB: Ignore */ |
|
NENTRY(copystr_fault) |
|
copystr_return: |
|
/* Set *lencopied and return %eax. */ |
|
GET_CURPCB(%ecx) |
|
movl $0,PCB_ONFAULT(%ecx) |
|
movl 20(%esp),%ecx |
|
subl %edx,%ecx |
|
movl 24(%esp),%edx |
|
testl %edx,%edx |
testl %edx,%edx |
jz 8f |
jnz 4f |
movl %ecx,(%edx) |
|
|
|
8: popl %edi |
|
popl %esi |
|
ret |
|
|
|
/* |
#ifdef XEN |
* int copystr(const void *from, void *to, size_t maxlen, size_t *lencopied); |
|
* Copy a NUL-terminated string, at most maxlen characters long. Return the |
|
* number of characters copied (including the NUL) in *lencopied. If the |
|
* string is too long, return ENAMETOOLONG; else return 0. |
|
* see copystr(9) |
|
*/ |
|
/* LINTSTUB: Func: int copystr(const void *kfaddr, void *kdaddr, size_t len, size_t *done) */ |
|
ENTRY(copystr) |
|
pushl %esi |
|
pushl %edi |
pushl %edi |
|
call _C_LABEL(i386_switch_context) |
movl 12(%esp),%esi # esi = from |
|
movl 16(%esp),%edi # edi = to |
|
movl 20(%esp),%edx # edx = maxlen |
|
incl %edx |
|
cld |
|
|
|
1: decl %edx |
|
jz 4f |
|
lodsb |
|
stosb |
|
testb %al,%al |
|
jnz 1b |
|
|
|
/* Success -- 0 byte reached. */ |
|
decl %edx |
|
xorl %eax,%eax |
|
jmp 6f |
|
|
|
4: /* edx is zero -- return ENAMETOOLONG. */ |
|
movl $ENAMETOOLONG,%eax |
|
|
|
6: /* Set *lencopied and return %eax. */ |
|
movl 20(%esp),%ecx |
|
subl %edx,%ecx |
|
movl 24(%esp),%edx |
|
testl %edx,%edx |
|
jz 7f |
|
movl %ecx,(%edx) |
|
|
|
7: popl %edi |
|
popl %esi |
|
ret |
|
|
|
/* |
|
* long fuword(const void *uaddr); |
|
* Fetch an int from the user's address space. |
|
* see fuword(9) |
|
*/ |
|
/* LINTSTUB: Func: long fuword(const void *base) */ |
|
ENTRY(fuword) |
|
DO_DEFERRED_SWITCH(%eax) |
|
movl 4(%esp),%edx |
|
cmpl $VM_MAXUSER_ADDRESS-4,%edx |
|
ja _C_LABEL(fusuaddrfault) |
|
GET_CURPCB(%ecx) |
|
movl $_C_LABEL(fusufault),PCB_ONFAULT(%ecx) |
|
movl (%edx),%eax |
|
movl $0,PCB_ONFAULT(%ecx) |
|
ret |
|
|
|
/* |
|
* int fusword(const void *uaddr); |
|
* Fetch a short from the user's address space. |
|
* see fusword(9) |
|
*/ |
|
/* LINTSTUB: Func: int fusword(const void *base) */ |
|
ENTRY(fusword) |
|
DO_DEFERRED_SWITCH(%eax) |
|
movl 4(%esp),%edx |
|
cmpl $VM_MAXUSER_ADDRESS-2,%edx |
|
ja _C_LABEL(fusuaddrfault) |
|
GET_CURPCB(%ecx) |
|
movl $_C_LABEL(fusufault),PCB_ONFAULT(%ecx) |
|
movzwl (%edx),%eax |
|
movl $0,PCB_ONFAULT(%ecx) |
|
ret |
|
|
|
/* |
|
* int fuswintr(const void *uaddr); |
|
* Fetch a short from the user's address space. Can be called during an |
|
* interrupt. |
|
* see fuswintr(9) |
|
*/ |
|
/* LINTSTUB: Func: int fuswintr(const void *base) */ |
|
ENTRY(fuswintr) |
|
cmpl $TLBSTATE_VALID, CPUVAR(TLBSTATE) |
|
jnz _C_LABEL(fusuaddrfault) |
|
movl 4(%esp),%edx |
|
cmpl $VM_MAXUSER_ADDRESS-2,%edx |
|
ja _C_LABEL(fusuaddrfault) |
|
movl CPUVAR(CURLWP),%ecx |
|
movl L_ADDR(%ecx),%ecx |
|
movl $_C_LABEL(fusubail),PCB_ONFAULT(%ecx) |
|
movzwl (%edx),%eax |
|
movl $0,PCB_ONFAULT(%ecx) |
|
ret |
|
|
|
/* |
|
* int fubyte(const void *uaddr); |
|
* Fetch a byte from the user's address space. |
|
* see fubyte(9) |
|
*/ |
|
/* LINTSTUB: Func: int fubyte(const void *base) */ |
|
ENTRY(fubyte) |
|
DO_DEFERRED_SWITCH(%eax) |
|
movl 4(%esp),%edx |
|
cmpl $VM_MAXUSER_ADDRESS-1,%edx |
|
ja _C_LABEL(fusuaddrfault) |
|
GET_CURPCB(%ecx) |
|
movl $_C_LABEL(fusufault),PCB_ONFAULT(%ecx) |
|
movzbl (%edx),%eax |
|
movl $0,PCB_ONFAULT(%ecx) |
|
ret |
|
|
|
/* |
|
* Handle faults from [fs]u*(). Clean up and return -1. |
|
*/ |
|
/* LINTSTUB: Ignore */ |
|
NENTRY(fusufault) |
|
movl $0,PCB_ONFAULT(%ecx) |
|
movl $-1,%eax |
|
ret |
|
|
|
/* |
|
* Handle faults from [fs]u*(). Clean up and return -1. This differs from |
|
* fusufault() in that trap() will recognize it and return immediately rather |
|
* than trying to page fault. |
|
*/ |
|
/* LINTSTUB: Ignore */ |
|
NENTRY(fusubail) |
|
movl $0,PCB_ONFAULT(%ecx) |
|
movl $-1,%eax |
|
ret |
|
|
|
/* |
|
* Handle earlier faults from [fs]u*(), due to our of range addresses. |
|
*/ |
|
/* LINTSTUB: Ignore */ |
|
NENTRY(fusuaddrfault) |
|
movl $-1,%eax |
|
ret |
|
|
|
/* |
|
* int suword(void *uaddr, long x); |
|
* Store an int in the user's address space. |
|
* see suword(9) |
|
*/ |
|
/* LINTSTUB: Func: int suword(void *base, long c) */ |
|
ENTRY(suword) |
|
DO_DEFERRED_SWITCH(%eax) |
|
movl 4(%esp),%edx |
|
cmpl $VM_MAXUSER_ADDRESS-4,%edx |
|
ja _C_LABEL(fusuaddrfault) |
|
|
|
#if defined(I386_CPU) |
|
#if defined(I486_CPU) || defined(I586_CPU) || defined(I686_CPU) |
|
cmpl $CPUCLASS_386,_C_LABEL(cpu_class) |
|
jne 2f |
|
#endif /* I486_CPU || I586_CPU || I686_CPU */ |
|
|
|
GET_CURPCB(%eax) |
|
movl $3f,PCB_ONFAULT(%eax) |
|
|
|
movl %edx,%eax |
|
shrl $PGSHIFT,%eax # calculate pte address |
|
testb $PG_RW,PTE_BASE(,%eax,4) |
|
jnz 1f |
|
|
|
3: /* Simulate a trap. */ |
|
pushl %edx |
|
pushl %edx |
|
call _C_LABEL(trapwrite) # trapwrite(addr) |
|
addl $4,%esp # clear parameter from the stack |
|
popl %edx |
|
GET_CURPCB(%ecx) |
|
testl %eax,%eax |
|
jnz _C_LABEL(fusufault) |
|
|
|
1: /* XXX also need to check the following 3 bytes for validity! */ |
|
#endif |
|
|
|
2: GET_CURPCB(%ecx) |
|
movl $_C_LABEL(fusufault),PCB_ONFAULT(%ecx) |
|
|
|
movl 8(%esp),%eax |
|
movl %eax,(%edx) |
|
xorl %eax,%eax |
|
movl %eax,PCB_ONFAULT(%ecx) |
|
ret |
|
|
|
/* |
|
* int susword(void *uaddr, short x); |
|
* Store a short in the user's address space. |
|
* see susword(9) |
|
*/ |
|
/* LINTSTUB: Func: int susword(void *base, short c) */ |
|
ENTRY(susword) |
|
DO_DEFERRED_SWITCH(%eax) |
|
movl 4(%esp),%edx |
|
cmpl $VM_MAXUSER_ADDRESS-2,%edx |
|
ja _C_LABEL(fusuaddrfault) |
|
|
|
#if defined(I386_CPU) |
|
#if defined(I486_CPU) || defined(I586_CPU) || defined(I686_CPU) |
|
cmpl $CPUCLASS_386,_C_LABEL(cpu_class) |
|
jne 2f |
|
#endif /* I486_CPU || I586_CPU || I686_CPU */ |
|
|
|
GET_CURPCB(%eax) |
|
movl $3f,PCB_ONFAULT(%eax) |
|
|
|
movl %edx,%eax |
|
shrl $PGSHIFT,%eax # calculate pte address |
|
testb $PG_RW,PTE_BASE(,%eax,4) |
|
jnz 1f |
|
|
|
3: /* Simulate a trap. */ |
|
pushl %edx |
|
pushl %edx |
|
call _C_LABEL(trapwrite) # trapwrite(addr) |
|
addl $4,%esp # clear parameter from the stack |
|
popl %edx |
|
GET_CURPCB(%ecx) |
|
testl %eax,%eax |
|
jnz _C_LABEL(fusufault) |
|
|
|
1: /* XXX also need to check the following byte for validity! */ |
|
#endif |
|
|
|
2: GET_CURPCB(%ecx) |
|
movl $_C_LABEL(fusufault),PCB_ONFAULT(%ecx) |
|
|
|
movl 8(%esp),%eax |
|
movw %ax,(%edx) |
|
xorl %eax,%eax |
|
movl %eax,PCB_ONFAULT(%ecx) |
|
ret |
|
|
|
/* |
|
* int suswintr(void *uaddr, short x); |
|
* Store a short in the user's address space. Can be called during an |
|
* interrupt. |
|
* see suswintr(9) |
|
*/ |
|
/* LINTSTUB: Func: int suswintr(void *base, short c) */ |
|
ENTRY(suswintr) |
|
cmpl $TLBSTATE_VALID, CPUVAR(TLBSTATE) |
|
jnz _C_LABEL(fusuaddrfault) |
|
movl 4(%esp),%edx |
|
cmpl $VM_MAXUSER_ADDRESS-2,%edx |
|
ja _C_LABEL(fusuaddrfault) |
|
movl CPUVAR(CURLWP),%ecx |
|
movl L_ADDR(%ecx),%ecx |
|
movl $_C_LABEL(fusubail),PCB_ONFAULT(%ecx) |
|
|
|
#if defined(I386_CPU) |
|
#if defined(I486_CPU) || defined(I586_CPU) || defined(I686_CPU) |
|
cmpl $CPUCLASS_386,_C_LABEL(cpu_class) |
|
jne 2f |
|
#endif /* I486_CPU || I586_CPU || I686_CPU */ |
|
|
|
movl %edx,%eax |
|
shrl $PGSHIFT,%eax # calculate pte address |
|
testb $PG_RW,PTE_BASE(,%eax,4) |
|
jnz 1f |
|
|
|
/* Simulate a trap. */ |
|
jmp _C_LABEL(fusubail) |
|
|
|
1: /* XXX also need to check the following byte for validity! */ |
|
#endif |
|
|
|
2: movl 8(%esp),%eax |
|
movw %ax,(%edx) |
|
xorl %eax,%eax |
|
movl %eax,PCB_ONFAULT(%ecx) |
|
ret |
|
|
|
/* |
|
* int subyte(void *uaddr, char x); |
|
* Store a byte in the user's address space. |
|
* see subyte(9) |
|
*/ |
|
/* LINTSTUB: Func: int subyte(void *base, int c) */ |
|
ENTRY(subyte) |
|
DO_DEFERRED_SWITCH(%eax) |
|
movl 4(%esp),%edx |
|
cmpl $VM_MAXUSER_ADDRESS-1,%edx |
|
ja _C_LABEL(fusuaddrfault) |
|
|
|
#if defined(I386_CPU) |
|
#if defined(I486_CPU) || defined(I586_CPU) || defined(I686_CPU) |
|
cmpl $CPUCLASS_386,_C_LABEL(cpu_class) |
|
jne 2f |
|
#endif /* I486_CPU || I586_CPU || I686_CPU */ |
|
|
|
GET_CURPCB(%eax) |
|
movl $3f,PCB_ONFAULT(%eax) |
|
|
|
movl %edx,%eax |
|
shrl $PGSHIFT,%eax # calculate pte address |
|
testb $PG_RW,PTE_BASE(,%eax,4) |
|
jnz 1f |
|
|
|
3: /* Simulate a trap. */ |
|
pushl %edx |
|
pushl %edx |
|
call _C_LABEL(trapwrite) # trapwrite(addr) |
|
addl $4,%esp # clear parameter from the stack |
|
popl %edx |
|
GET_CURPCB(%ecx) |
|
testl %eax,%eax |
|
jnz _C_LABEL(fusufault) |
|
|
|
1: |
|
#endif |
|
|
|
2: GET_CURPCB(%ecx) |
|
movl $_C_LABEL(fusufault),PCB_ONFAULT(%ecx) |
|
|
|
movb 8(%esp),%al |
|
movb %al,(%edx) |
|
xorl %eax,%eax |
|
movl %eax,PCB_ONFAULT(%ecx) |
|
ret |
|
|
|
/*****************************************************************************/ |
|
|
|
/* |
|
* The following is i386-specific nonsense. |
|
*/ |
|
|
|
/* |
|
* void lgdt(struct region_descriptor *rdp); |
|
* Load a new GDT pointer (and do any necessary cleanup). |
|
* XXX It's somewhat questionable whether reloading all the segment registers |
|
* is necessary, since the actual descriptor data is not changed except by |
|
* process creation and exit, both of which clean up via task switches. OTOH, |
|
* this only happens at run time when the GDT is resized. |
|
*/ |
|
/* LINTSTUB: Func: void lgdt(struct region_descriptor *rdp) */ |
|
NENTRY(lgdt) |
|
/* Reload the descriptor table. */ |
|
movl 4(%esp),%eax |
|
lgdt (%eax) |
|
/* Flush the prefetch queue. */ |
|
jmp 1f |
|
nop |
|
1: /* Reload "stale" selectors. */ |
|
movl $GSEL(GDATA_SEL, SEL_KPL),%eax |
|
movw %ax,%ds |
|
movw %ax,%es |
|
movw %ax,%gs |
|
movw %ax,%ss |
|
movl $GSEL(GCPU_SEL, SEL_KPL),%eax |
|
movw %ax,%fs |
|
/* Reload code selector by doing intersegment return. */ |
|
popl %eax |
|
pushl $GSEL(GCODE_SEL, SEL_KPL) |
|
pushl %eax |
|
lret |
|
|
|
/*****************************************************************************/ |
|
|
|
/* |
|
* These functions are primarily used by DDB. |
|
*/ |
|
|
|
/* LINTSTUB: Func: int setjmp (label_t *l) */ |
|
ENTRY(setjmp) |
|
movl 4(%esp),%eax |
|
movl %ebx,(%eax) # save ebx |
|
movl %esp,4(%eax) # save esp |
|
movl %ebp,8(%eax) # save ebp |
|
movl %esi,12(%eax) # save esi |
|
movl %edi,16(%eax) # save edi |
|
movl (%esp),%edx # get rta |
|
movl %edx,20(%eax) # save eip |
|
xorl %eax,%eax # return (0); |
|
ret |
|
|
|
/* LINTSTUB: Func: void longjmp (label_t *l) */ |
|
ENTRY(longjmp) |
|
movl 4(%esp),%eax |
|
movl (%eax),%ebx # restore ebx |
|
movl 4(%eax),%esp # restore esp |
|
movl 8(%eax),%ebp # restore ebp |
|
movl 12(%eax),%esi # restore esi |
|
movl 16(%eax),%edi # restore edi |
|
movl 20(%eax),%edx # get rta |
|
movl %edx,(%esp) # put in return frame |
|
xorl %eax,%eax # return (1); |
|
incl %eax |
|
ret |
|
|
|
/*****************************************************************************/ |
|
|
|
.globl _C_LABEL(sched_whichqs),_C_LABEL(sched_qs) |
|
.globl _C_LABEL(uvmexp),_C_LABEL(panic) |
|
|
|
#ifdef DIAGNOSTIC |
|
NENTRY(switch_error) |
|
pushl $1f |
|
call _C_LABEL(panic) |
|
/* NOTREACHED */ |
|
1: .asciz "cpu_switch" |
|
#endif /* DIAGNOSTIC */ |
|
|
|
/* |
|
* void cpu_switch(struct lwp *) |
|
* Find a runnable process and switch to it. Wait if necessary. If the new |
|
* process is the same as the old one, we short-circuit the context save and |
|
* restore. |
|
* |
|
* Note that the stack frame layout is known to "struct switchframe" |
|
* in <machine/frame.h> and to the code in cpu_fork() which initializes |
|
* it for a new lwp. |
|
*/ |
|
ENTRY(cpu_switch) |
|
pushl %ebx |
|
pushl %esi |
|
pushl %edi |
|
|
|
#ifdef DEBUG |
|
cmpl $IPL_SCHED,CPUVAR(ILEVEL) |
|
jae 1f |
|
pushl $2f |
|
call _C_LABEL(panic) |
|
/* NOTREACHED */ |
|
2: .asciz "not splsched() in cpu_switch!" |
|
1: |
|
#endif /* DEBUG */ |
|
|
|
movl 16(%esp),%esi # current |
|
|
|
/* |
|
* Clear curlwp so that we don't accumulate system time while idle. |
|
* This also insures that schedcpu() will move the old lwp to |
|
* the correct queue if it happens to get called from the spllower() |
|
* below and changes the priority. (See corresponding comment in |
|
* userret()). |
|
*/ |
|
movl $0,CPUVAR(CURLWP) |
|
/* |
|
* First phase: find new lwp. |
|
* |
|
* Registers: |
|
* %eax - queue head, scratch, then zero |
|
* %ebx - queue number |
|
* %ecx - cached value of whichqs |
|
* %edx - next lwp in queue |
|
* %esi - old lwp |
|
* %edi - new lwp |
|
*/ |
|
|
|
/* Look for new lwp. */ |
|
cli # splhigh doesn't do a cli |
|
movl _C_LABEL(sched_whichqs),%ecx |
|
bsfl %ecx,%ebx # find a full q |
|
jnz switch_dequeue |
|
|
|
/* |
|
* idling: save old context. |
|
* |
|
* Registers: |
|
* %eax, %ecx - scratch |
|
* %esi - old lwp, then old pcb |
|
* %edi - idle pcb |
|
*/ |
|
|
|
pushl %esi |
|
call _C_LABEL(pmap_deactivate2) # pmap_deactivate(oldproc) |
|
addl $4,%esp |
|
|
|
movl L_ADDR(%esi),%esi |
|
|
|
/* Save stack pointers. */ |
|
movl %esp,PCB_ESP(%esi) |
|
movl %ebp,PCB_EBP(%esi) |
|
|
|
/* Find idle PCB for this CPU */ |
|
#ifndef MULTIPROCESSOR |
|
movl $_C_LABEL(lwp0),%ebx |
|
movl L_ADDR(%ebx),%edi |
|
movl L_MD_TSS_SEL(%ebx),%edx |
|
#else |
|
movl CPUVAR(IDLE_PCB),%edi |
|
movl CPUVAR(IDLE_TSS_SEL),%edx |
|
#endif |
|
movl $0,CPUVAR(CURLWP) /* In case we fault... */ |
|
|
|
/* Restore the idle context (avoid interrupts) */ |
|
cli |
|
|
|
/* Restore stack pointers. */ |
|
movl PCB_ESP(%edi),%esp |
|
movl PCB_EBP(%edi),%ebp |
|
|
|
/* Switch TSS. Reset "task busy" flag before loading. */ |
|
movl %cr3,%eax |
|
movl %eax,PCB_CR3(%edi) |
|
#ifdef MULTIPROCESSOR |
|
movl CPUVAR(GDT),%eax |
|
#else |
|
movl _C_LABEL(gdt),%eax |
|
#endif |
|
andl $~0x0200,4-SEL_KPL(%eax,%edx,1) |
|
ltr %dx |
|
|
|
/* We're always in the kernel, so we don't need the LDT. */ |
|
|
|
/* Restore cr0 (including FPU state). */ |
|
movl PCB_CR0(%edi),%ecx |
|
movl %ecx,%cr0 |
|
|
|
/* Record new pcb. */ |
|
SET_CURPCB(%edi) |
|
|
|
xorl %esi,%esi |
|
sti |
|
idle_unlock: |
|
#if defined(MULTIPROCESSOR) || defined(LOCKDEBUG) |
|
call _C_LABEL(sched_unlock_idle) |
|
#endif |
|
/* Interrupts are okay again. */ |
|
pushl $IPL_NONE # spl0() |
|
call _C_LABEL(Xspllower) # process pending interrupts |
|
addl $4,%esp |
|
jmp idle_start |
|
idle_zero: |
|
sti |
|
call _C_LABEL(uvm_pageidlezero) |
|
cli |
|
cmpl $0,_C_LABEL(sched_whichqs) |
|
jnz idle_exit |
|
idle_loop: |
|
/* Try to zero some pages. */ |
|
movl _C_LABEL(uvm)+UVM_PAGE_IDLE_ZERO,%ecx |
|
testl %ecx,%ecx |
|
jnz idle_zero |
|
sti |
|
hlt |
|
NENTRY(mpidle) |
|
idle_start: |
|
cli |
|
cmpl $0,_C_LABEL(sched_whichqs) |
|
jz idle_loop |
|
idle_exit: |
|
movl $IPL_HIGH,CPUVAR(ILEVEL) # splhigh |
|
sti |
|
#if defined(MULTIPROCESSOR) || defined(LOCKDEBUG) |
|
call _C_LABEL(sched_lock_idle) |
|
#endif |
|
movl _C_LABEL(sched_whichqs),%ecx |
|
bsfl %ecx,%ebx |
|
jz idle_unlock |
|
|
|
switch_dequeue: |
|
/* |
|
* we're running at splhigh(), but it's otherwise okay to take |
|
* interrupts here. |
|
*/ |
|
sti |
|
leal _C_LABEL(sched_qs)(,%ebx,8),%eax # select q |
|
|
|
movl L_FORW(%eax),%edi # unlink from front of process q |
|
#ifdef DIAGNOSTIC |
|
cmpl %edi,%eax # linked to self (i.e. nothing queued)? |
|
je _C_LABEL(switch_error) # not possible |
|
#endif /* DIAGNOSTIC */ |
|
movl L_FORW(%edi),%edx |
|
movl %edx,L_FORW(%eax) |
|
movl %eax,L_BACK(%edx) |
|
|
|
cmpl %edx,%eax # q empty? |
|
jne 3f |
|
|
|
btrl %ebx,%ecx # yes, clear to indicate empty |
|
movl %ecx,_C_LABEL(sched_whichqs) # update q status |
|
|
|
3: /* We just did it. */ |
|
xorl %eax,%eax |
|
CLEAR_RESCHED(%eax) |
|
|
|
switch_resume: |
|
#ifdef DIAGNOSTIC |
|
cmpl %eax,L_WCHAN(%edi) # Waiting for something? |
|
jne _C_LABEL(switch_error) # Yes; shouldn't be queued. |
|
cmpb $LSRUN,L_STAT(%edi) # In run state? |
|
jne _C_LABEL(switch_error) # No; shouldn't be queued. |
|
#endif /* DIAGNOSTIC */ |
|
|
|
/* Isolate lwp. XXX Is this necessary? */ |
|
movl %eax,L_BACK(%edi) |
|
|
|
/* Record new lwp. */ |
|
movb $LSONPROC,L_STAT(%edi) # l->l_stat = LSONPROC |
|
SET_CURLWP(%edi,%ecx) |
|
|
|
/* Skip context switch if same lwp. */ |
|
xorl %ebx,%ebx |
|
cmpl %edi,%esi |
|
je switch_return |
|
|
|
/* If old lwp exited, don't bother. */ |
|
testl %esi,%esi |
|
jz switch_exited |
|
|
|
/* |
|
* Second phase: save old context. |
|
* |
|
* Registers: |
|
* %eax, %ecx - scratch |
|
* %esi - old lwp, then old pcb |
|
* %edi - new lwp |
|
*/ |
|
|
|
pushl %esi |
|
call _C_LABEL(pmap_deactivate2) # pmap_deactivate(oldproc) |
|
addl $4,%esp |
addl $4,%esp |
|
#else /* XEN */ |
|
/* Switch ring0 esp */ |
|
movl PCB_ESP0(%ebx),%eax |
|
movl %eax,CPUVAR(ESP0) |
|
|
movl L_ADDR(%esi),%esi |
/* Don't bother with the rest if switching to a system process. */ |
|
testl $LW_SYSTEM,L_FLAG(%edi) |
|
jnz 4f |
|
|
/* Save stack pointers. */ |
/* Restore thread-private %fs/%gs descriptors. */ |
movl %esp,PCB_ESP(%esi) |
movl CPUVAR(GDT),%ecx |
movl %ebp,PCB_EBP(%esi) |
movl PCB_FSD(%ebx), %eax |
|
movl PCB_FSD+4(%ebx), %edx |
|
movl %eax, (GUFS_SEL*8)(%ecx) |
|
movl %edx, (GUFS_SEL*8+4)(%ecx) |
|
movl PCB_GSD(%ebx), %eax |
|
movl PCB_GSD+4(%ebx), %edx |
|
movl %eax, (GUGS_SEL*8)(%ecx) |
|
movl %edx, (GUGS_SEL*8+4)(%ecx) |
|
#endif /* XEN */ |
|
|
|
/* Switch I/O bitmap */ |
|
movl PCB_IOMAP(%ebx),%eax |
|
orl %eax,%eax |
|
jnz,pn .Lcopy_iobitmap |
|
movl $(IOMAP_INVALOFF << 16),CPUVAR(IOBASE) |
|
.Liobitmap_done: |
|
|
|
/* Is this process using RAS (restartable atomic sequences)? */ |
|
movl L_PROC(%edi),%eax |
|
cmpl $0,P_RASLIST(%eax) |
|
jne 5f |
|
|
switch_exited: |
|
/* |
/* |
* Third phase: restore saved context. |
* Restore cr0 (including FPU state). Raise the IPL to IPL_IPI. |
* |
* FPU IPIs can alter the LWP's saved cr0. Dropping the priority |
* Registers: |
* is deferred until mi_switch(), when cpu_switchto() returns. |
* %eax, %ebx, %ecx, %edx - scratch |
|
* %esi - new pcb |
|
* %edi - new lwp |
|
*/ |
*/ |
|
2: |
|
#ifndef XEN |
|
movl $IPL_IPI,CPUVAR(ILEVEL) |
|
movl PCB_CR0(%ebx),%ecx |
|
movl %cr0,%edx |
|
|
/* No interrupts while loading new state. */ |
|
cli |
|
movl L_ADDR(%edi),%esi |
|
|
|
/* Restore stack pointers. */ |
|
movl PCB_ESP(%esi),%esp |
|
movl PCB_EBP(%esi),%ebp |
|
|
|
#if 0 |
|
/* Don't bother with the rest if switching to a system process. */ |
|
testl $P_SYSTEM,L_FLAG(%edi); XXX NJWLWP lwp's don't have P_SYSTEM! |
|
jnz switch_restored |
|
#endif |
|
|
|
/* Switch TSS. Reset "task busy" flag before loading. */ |
|
movl %cr3,%eax |
|
movl %eax,PCB_CR3(%esi) /* XXX should be done by pmap_activate? */ |
|
#ifdef MULTIPROCESSOR |
|
movl CPUVAR(GDT),%eax |
|
#else |
|
/* Load TSS info. */ |
|
movl _C_LABEL(gdt),%eax |
|
#endif |
|
movl L_MD_TSS_SEL(%edi),%edx |
|
|
|
andl $~0x0200,4(%eax,%edx, 1) |
|
ltr %dx |
|
|
|
pushl %edi |
|
call _C_LABEL(pmap_activate) # pmap_activate(p) |
|
addl $4,%esp |
|
|
|
#if 0 |
|
switch_restored: |
|
#endif |
|
/* Restore cr0 (including FPU state). */ |
|
movl PCB_CR0(%esi),%ecx |
|
#ifdef MULTIPROCESSOR |
|
/* |
/* |
* If our floating point registers are on a different CPU, |
* If our floating point registers are on a different CPU, |
* clear CR0_TS so we'll trap rather than reuse bogus state. |
* set CR0_TS so we'll trap rather than reuse bogus state. |
*/ |
*/ |
movl PCB_FPCPU(%esi),%ebx |
movl PCB_FPCPU(%ebx),%eax |
cmpl CPUVAR(SELF),%ebx |
cmpl CPUVAR(SELF),%eax |
jz 1f |
je 3f |
orl $CR0_TS,%ecx |
orl $CR0_TS,%ecx |
1: |
|
#endif |
|
movl %ecx,%cr0 |
|
|
|
/* Record new pcb. */ |
|
SET_CURPCB(%esi) |
|
|
|
/* Interrupts are okay again. */ |
|
sti |
|
|
|
/* |
/* Reloading CR0 is very expensive - avoid if possible. */ |
* Check for restartable atomic sequences (RAS) |
3: cmpl %edx,%ecx |
*/ |
je 4f |
movl CPUVAR(CURLWP),%edi |
movl %ecx,%cr0 |
movl L_PROC(%edi),%esi |
#endif /* XEN */ |
cmpl $0,P_RASLIST(%esi) |
|
jne 2f |
|
1: |
|
movl $1,%ebx |
|
|
|
switch_return: |
|
#if defined(MULTIPROCESSOR) || defined(LOCKDEBUG) |
|
call _C_LABEL(sched_unlock_idle) |
|
#endif |
|
cmpl $0,CPUVAR(IPENDING) |
|
jz 3f |
|
pushl $IPL_NONE # spl0() |
|
call _C_LABEL(Xspllower) # process pending interrupts |
|
addl $4,%esp |
|
3: |
|
movl $IPL_HIGH,CPUVAR(ILEVEL) # splhigh() |
|
|
|
movl %ebx,%eax |
|
|
|
|
/* Return to the new LWP, returning 'oldlwp' in %eax. */ |
|
4: movl %esi,%eax |
popl %edi |
popl %edi |
popl %esi |
popl %esi |
popl %ebx |
popl %ebx |
ret |
ret |
|
|
2: # check RAS list |
/* Check for restartable atomic sequences (RAS). */ |
movl L_MD_REGS(%edi),%ebx |
5: movl L_MD_REGS(%edi),%ecx |
movl TF_EIP(%ebx),%eax |
pushl TF_EIP(%ecx) |
pushl %eax |
pushl %eax |
pushl %esi |
|
call _C_LABEL(ras_lookup) |
call _C_LABEL(ras_lookup) |
addl $8,%esp |
addl $8,%esp |
cmpl $-1,%eax |
cmpl $-1,%eax |
je 1b |
je 2b |
movl %eax,TF_EIP(%ebx) |
movl L_MD_REGS(%edi),%ecx |
jmp 1b |
movl %eax,TF_EIP(%ecx) |
|
jmp 2b |
|
|
/* |
.Lcopy_iobitmap: |
* void cpu_switchto(struct lwp *current, struct lwp *next) |
/* Copy I/O bitmap. */ |
* Switch to the specified next LWP. |
movl $(IOMAPSIZE/4),%ecx |
*/ |
|
ENTRY(cpu_switchto) |
|
pushl %ebx |
|
pushl %esi |
pushl %esi |
pushl %edi |
pushl %edi |
|
movl %eax,%esi /* pcb_iomap */ |
#ifdef DEBUG |
movl CPUVAR(SELF),%edi |
cmpl $IPL_SCHED,CPUVAR(ILEVEL) |
leal CPU_INFO_IOMAP(%edi),%edi |
jae 1f |
rep |
pushl $2f |
movsl |
call _C_LABEL(panic) |
popl %edi |
/* NOTREACHED */ |
popl %esi |
2: .asciz "not splsched() in cpu_switchto!" |
movl $((CPU_INFO_IOMAP - CPU_INFO_TSS) << 16),CPUVAR(IOBASE) |
1: |
jmp .Liobitmap_done |
#endif /* DEBUG */ |
END(cpu_switchto) |
|
|
movl 16(%esp),%esi # current |
|
movl 20(%esp),%edi # next |
|
|
|
/* |
|
* Clear curlwp so that we don't accumulate system time while idle. |
|
* This also insures that schedcpu() will move the old process to |
|
* the correct queue if it happens to get called from the spllower() |
|
* below and changes the priority. (See corresponding comment in |
|
* usrret()). |
|
* |
|
* XXX Is this necessary? We know we won't go idle. |
|
*/ |
|
movl $0,CPUVAR(CURLWP) |
|
|
|
/* |
|
* We're running at splhigh(), but it's otherwise okay to take |
|
* interrupts here. |
|
*/ |
|
sti |
|
|
|
/* Jump into the middle of cpu_switch */ |
|
xorl %eax,%eax |
|
jmp switch_resume |
|
|
|
/* |
|
* void cpu_exit(struct lwp *l) |
|
* Switch to the appropriate idle context (lwp0's if uniprocessor; the CPU's |
|
* if multiprocessor) and deallocate the address space and kernel stack for p. |
|
* Then jump into cpu_switch(), as if we were in the idle proc all along. |
|
*/ |
|
#ifndef MULTIPROCESSOR |
|
.globl _C_LABEL(lwp0) |
|
#endif |
|
.globl _C_LABEL(uvmspace_free),_C_LABEL(kernel_map) |
|
.globl _C_LABEL(uvm_km_free),_C_LABEL(tss_free) |
|
/* LINTSTUB: Func: void cpu_exit(struct lwp *l) */ |
|
ENTRY(cpu_exit) |
|
movl 4(%esp),%edi # old process |
|
#ifndef MULTIPROCESSOR |
|
movl $_C_LABEL(lwp0),%ebx |
|
movl L_ADDR(%ebx),%esi |
|
movl L_MD_TSS_SEL(%ebx),%edx |
|
#else |
|
movl CPUVAR(IDLE_PCB),%esi |
|
movl CPUVAR(IDLE_TSS_SEL),%edx |
|
#endif |
|
/* In case we fault... */ |
|
movl $0,CPUVAR(CURLWP) |
|
|
|
/* Restore the idle context. */ |
|
cli |
|
|
|
/* Restore stack pointers. */ |
|
movl PCB_ESP(%esi),%esp |
|
movl PCB_EBP(%esi),%ebp |
|
|
|
/* Switch TSS. Reset "task busy" flag before loading. */ |
|
movl %cr3,%eax |
|
movl %eax,PCB_CR3(%esi) |
|
#ifdef MULTIPROCESSOR |
|
movl CPUVAR(GDT),%eax |
|
#else |
|
/* Load TSS info. */ |
|
movl _C_LABEL(gdt),%eax |
|
#endif |
|
|
|
andl $~0x0200,4-SEL_KPL(%eax,%edx,1) |
|
ltr %dx |
|
|
|
/* We're always in the kernel, so we don't need the LDT. */ |
|
|
|
/* Restore cr0 (including FPU state). */ |
|
movl PCB_CR0(%esi),%ecx |
|
movl %ecx,%cr0 |
|
|
|
/* Record new pcb. */ |
|
SET_CURPCB(%esi) |
|
|
|
/* Interrupts are okay again. */ |
|
sti |
|
|
|
/* |
|
* Schedule the dead LWP's stack to be freed. |
|
*/ |
|
pushl %edi |
|
call _C_LABEL(lwp_exit2) |
|
addl $4,%esp |
|
|
|
/* Jump into cpu_switch() with the right state. */ |
|
xorl %esi,%esi |
|
movl %esi,CPUVAR(CURLWP) |
|
jmp idle_start |
|
|
|
/* |
/* |
* void savectx(struct pcb *pcb); |
* void savectx(struct pcb *pcb); |
|
* |
* Update pcb, saving current processor state. |
* Update pcb, saving current processor state. |
*/ |
*/ |
/* LINTSTUB: Func: void savectx(struct pcb *pcb) */ |
|
ENTRY(savectx) |
ENTRY(savectx) |
movl 4(%esp),%edx # edx = p->p_addr |
movl 4(%esp),%edx # edx = pcb |
|
|
/* Save stack pointers. */ |
|
movl %esp,PCB_ESP(%edx) |
movl %esp,PCB_ESP(%edx) |
movl %ebp,PCB_EBP(%edx) |
movl %ebp,PCB_EBP(%edx) |
|
|
ret |
ret |
|
END(savectx) |
|
|
/* |
/* |
|
* osyscall() |
|
* |
* Old call gate entry for syscall |
* Old call gate entry for syscall |
*/ |
*/ |
/* LINTSTUB: Var: char Xosyscall[1]; */ |
|
IDTVEC(osyscall) |
IDTVEC(osyscall) |
/* Set eflags in trap frame. */ |
pushfl # set eflags in trap frame |
pushfl |
|
popl 8(%esp) |
popl 8(%esp) |
pushl $7 # size of instruction for restart |
pushl $7 # size of instruction for restart |
jmp syscall1 |
jmp syscall1 |
|
IDTVEC_END(osyscall) |
|
|
/* |
/* |
|
* syscall() |
|
* |
* Trap gate entry for syscall |
* Trap gate entry for syscall |
*/ |
*/ |
/* LINTSTUB: Var: char Xsyscall[1]; */ |
|
IDTVEC(syscall) |
IDTVEC(syscall) |
pushl $2 # size of instruction for restart |
pushl $2 # size of instruction for restart |
syscall1: |
syscall1: |
pushl $T_ASTFLT # trap # for doing ASTs |
pushl $T_ASTFLT # trap # for doing ASTs |
INTRENTRY |
INTRENTRY |
|
|
#ifdef DIAGNOSTIC |
#ifdef DIAGNOSTIC |
cmpl $0, CPUVAR(WANT_PMAPLOAD) |
|
jz 1f |
|
pushl $6f |
|
call _C_LABEL(printf) |
|
addl $4, %esp |
|
1: |
|
movl CPUVAR(ILEVEL),%ebx |
movl CPUVAR(ILEVEL),%ebx |
testl %ebx,%ebx |
testl %ebx,%ebx |
jz 1f |
jz 1f |
|
|
#endif |
#endif |
1: |
1: |
#endif /* DIAGNOSTIC */ |
#endif /* DIAGNOSTIC */ |
movl CPUVAR(CURLWP),%edx |
incl CPUVAR(NSYSCALL) # count it atomically |
movl %esp,L_MD_REGS(%edx) # save pointer to frame |
movl CPUVAR(CURLWP),%edi |
movl L_PROC(%edx),%edx |
movl L_PROC(%edi),%edx |
|
movl %esp,L_MD_REGS(%edi) # save pointer to frame |
pushl %esp |
pushl %esp |
call *P_MD_SYSCALL(%edx) # get pointer to syscall() function |
call *P_MD_SYSCALL(%edx) # get pointer to syscall() function |
addl $4,%esp |
addl $4,%esp |
.Lsyscall_checkast: |
.Lsyscall_checkast: |
/* Check for ASTs on exit to user mode. */ |
/* Check for ASTs on exit to user mode. */ |
cli |
CLI(%eax) |
CHECK_ASTPENDING(%eax) |
movl L_MD_ASTPENDING(%edi), %eax |
je 1f |
orl CPUVAR(WANT_PMAPLOAD), %eax |
/* Always returning to user mode here. */ |
|
CLEAR_ASTPENDING(%eax) |
|
sti |
|
/* Pushed T_ASTFLT into tf_trapno on entry. */ |
|
pushl %esp |
|
call _C_LABEL(trap) |
|
addl $4,%esp |
|
jmp .Lsyscall_checkast /* re-check ASTs */ |
|
1: CHECK_DEFERRED_SWITCH(%eax) |
|
jnz 9f |
jnz 9f |
|
#ifdef XEN |
|
STIC(%eax) |
|
jz 14f |
|
call _C_LABEL(stipending) |
|
testl %eax,%eax |
|
jz 14f |
|
/* process pending interrupts */ |
|
CLI(%eax) |
|
movl CPUVAR(ILEVEL), %ebx |
|
movl $.Lsyscall_resume, %esi # address to resume loop at |
|
.Lsyscall_resume: |
|
movl %ebx,%eax # get cpl |
|
movl CPUVAR(IUNMASK)(,%eax,4),%eax |
|
andl CPUVAR(IPENDING),%eax # any non-masked bits left? |
|
jz 17f |
|
bsrl %eax,%eax |
|
btrl %eax,CPUVAR(IPENDING) |
|
movl CPUVAR(ISOURCES)(,%eax,4),%eax |
|
jmp *IS_RESUME(%eax) |
|
17: movl %ebx, CPUVAR(ILEVEL) #restore cpl |
|
jmp .Lsyscall_checkast |
|
14: |
|
#endif /* XEN */ |
#ifndef DIAGNOSTIC |
#ifndef DIAGNOSTIC |
INTRFASTEXIT |
INTRFASTEXIT |
#else /* DIAGNOSTIC */ |
#else /* DIAGNOSTIC */ |
cmpl $IPL_NONE,CPUVAR(ILEVEL) |
cmpl $IPL_NONE,CPUVAR(ILEVEL) |
jne 3f |
jne 3f |
INTRFASTEXIT |
INTRFASTEXIT |
3: sti |
3: STI(%eax) |
pushl $4f |
pushl $4f |
call _C_LABEL(printf) |
call _C_LABEL(printf) |
addl $4,%esp |
addl $4,%esp |
#ifdef DDB |
pushl $IPL_NONE |
int $3 |
call _C_LABEL(spllower) |
#endif /* DDB */ |
addl $4,%esp |
movl $IPL_NONE,CPUVAR(ILEVEL) |
jmp .Lsyscall_checkast |
jmp 2b |
|
4: .asciz "WARNING: SPL NOT LOWERED ON SYSCALL EXIT\n" |
4: .asciz "WARNING: SPL NOT LOWERED ON SYSCALL EXIT\n" |
5: .asciz "WARNING: SPL NOT ZERO ON SYSCALL ENTRY\n" |
5: .asciz "WARNING: SPL NOT ZERO ON SYSCALL ENTRY\n" |
6: .asciz "WARNING: WANT PMAPLOAD ON SYSCALL ENTRY\n" |
|
#endif /* DIAGNOSTIC */ |
#endif /* DIAGNOSTIC */ |
9: sti |
9: |
|
cmpl $0, CPUVAR(WANT_PMAPLOAD) |
|
jz 10f |
|
STI(%eax) |
call _C_LABEL(pmap_load) |
call _C_LABEL(pmap_load) |
jmp .Lsyscall_checkast /* re-check ASTs */ |
jmp .Lsyscall_checkast /* re-check ASTs */ |
|
10: |
|
/* Always returning to user mode here. */ |
|
movl $0, L_MD_ASTPENDING(%edi) |
|
STI(%eax) |
|
/* Pushed T_ASTFLT into tf_trapno on entry. */ |
|
pushl %esp |
|
call _C_LABEL(trap) |
|
addl $4,%esp |
|
jmp .Lsyscall_checkast /* re-check ASTs */ |
|
IDTVEC_END(syscall) |
|
|
#if NNPX > 0 |
#if NNPX > 0 |
/* |
/* |
|
|
* latch stuff in probintr() can be moved to npxprobe(). |
* latch stuff in probintr() can be moved to npxprobe(). |
*/ |
*/ |
|
|
/* LINTSTUB: Func: void probeintr(void) */ |
/* |
|
* void probeintr(void) |
|
*/ |
NENTRY(probeintr) |
NENTRY(probeintr) |
ss |
ss |
incl _C_LABEL(npx_intrs_while_probing) |
incl _C_LABEL(npx_intrs_while_probing) |
Line 2227 NENTRY(probeintr) |
|
Line 1197 NENTRY(probeintr) |
|
outb %al,$0xf0 # clear BUSY# latch |
outb %al,$0xf0 # clear BUSY# latch |
popl %eax |
popl %eax |
iret |
iret |
|
END(probeintr) |
|
|
/* LINTSTUB: Func: void probetrap(void) */ |
/* |
|
* void probetrap(void) |
|
*/ |
NENTRY(probetrap) |
NENTRY(probetrap) |
ss |
ss |
incl _C_LABEL(npx_traps_while_probing) |
incl _C_LABEL(npx_traps_while_probing) |
fnclex |
fnclex |
iret |
iret |
|
END(probetrap) |
|
|
/* LINTSTUB: Func: int npx586bug1(int a, int b) */ |
/* |
|
* int npx586bug1(int a, int b) |
|
*/ |
NENTRY(npx586bug1) |
NENTRY(npx586bug1) |
fildl 4(%esp) # x |
fildl 4(%esp) # x |
fildl 8(%esp) # y |
fildl 8(%esp) # y |
Line 2247 NENTRY(npx586bug1) |
|
Line 1223 NENTRY(npx586bug1) |
|
fistpl (%esp) |
fistpl (%esp) |
popl %eax |
popl %eax |
ret |
ret |
|
END(npx586bug1) |
#endif /* NNPX > 0 */ |
#endif /* NNPX > 0 */ |
|
|
|
/* |
|
* void sse2_zero_page(void *pg) |
|
* |
|
* Zero a page without polluting the cache. |
|
*/ |
|
ENTRY(sse2_zero_page) |
|
pushl %ebp |
|
movl %esp,%ebp |
|
movl 8(%esp), %edx |
|
movl $PAGE_SIZE, %ecx |
|
xorl %eax, %eax |
|
.align 16 |
|
1: |
|
movnti %eax, 0(%edx) |
|
movnti %eax, 4(%edx) |
|
movnti %eax, 8(%edx) |
|
movnti %eax, 12(%edx) |
|
movnti %eax, 16(%edx) |
|
movnti %eax, 20(%edx) |
|
movnti %eax, 24(%edx) |
|
movnti %eax, 28(%edx) |
|
subl $32, %ecx |
|
leal 32(%edx), %edx |
|
jnz 1b |
|
sfence |
|
pop %ebp |
|
ret |
|
END(sse2_zero_page) |
|
|
|
/* |
|
* void sse2_copy_page(void *src, void *dst) |
|
* |
|
* Copy a page without polluting the cache. |
|
*/ |
|
ENTRY(sse2_copy_page) |
|
pushl %ebp |
|
pushl %ebx |
|
pushl %esi |
|
pushl %edi |
|
movl 20(%esp), %esi |
|
movl 24(%esp), %edi |
|
movl $PAGE_SIZE, %ebp |
|
.align 16 |
|
1: |
|
movl 0(%esi), %eax |
|
movl 4(%esi), %ebx |
|
movl 8(%esi), %ecx |
|
movl 12(%esi), %edx |
|
movnti %eax, 0(%edi) |
|
movnti %ebx, 4(%edi) |
|
movnti %ecx, 8(%edi) |
|
movnti %edx, 12(%edi) |
|
subl $16, %ebp |
|
leal 16(%esi), %esi |
|
leal 16(%edi), %edi |
|
jnz 1b |
|
sfence |
|
popl %edi |
|
popl %esi |
|
popl %ebx |
|
popl %ebp |
|
ret |
|
END(sse2_copy_page) |