linux-sg2042/arch/ia64/kernel/ivt.S

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License cleanup: add SPDX GPL-2.0 license identifier to files with no license Many source files in the tree are missing licensing information, which makes it harder for compliance tools to determine the correct license. By default all files without license information are under the default license of the kernel, which is GPL version 2. Update the files which contain no license information with the 'GPL-2.0' SPDX license identifier. The SPDX identifier is a legally binding shorthand, which can be used instead of the full boiler plate text. This patch is based on work done by Thomas Gleixner and Kate Stewart and Philippe Ombredanne. How this work was done: Patches were generated and checked against linux-4.14-rc6 for a subset of the use cases: - file had no licensing information it it. - file was a */uapi/* one with no licensing information in it, - file was a */uapi/* one with existing licensing information, Further patches will be generated in subsequent months to fix up cases where non-standard license headers were used, and references to license had to be inferred by heuristics based on keywords. The analysis to determine which SPDX License Identifier to be applied to a file was done in a spreadsheet of side by side results from of the output of two independent scanners (ScanCode & Windriver) producing SPDX tag:value files created by Philippe Ombredanne. Philippe prepared the base worksheet, and did an initial spot review of a few 1000 files. The 4.13 kernel was the starting point of the analysis with 60,537 files assessed. Kate Stewart did a file by file comparison of the scanner results in the spreadsheet to determine which SPDX license identifier(s) to be applied to the file. She confirmed any determination that was not immediately clear with lawyers working with the Linux Foundation. Criteria used to select files for SPDX license identifier tagging was: - Files considered eligible had to be source code files. - Make and config files were included as candidates if they contained >5 lines of source - File already had some variant of a license header in it (even if <5 lines). All documentation files were explicitly excluded. The following heuristics were used to determine which SPDX license identifiers to apply. - when both scanners couldn't find any license traces, file was considered to have no license information in it, and the top level COPYING file license applied. For non */uapi/* files that summary was: SPDX license identifier # files ---------------------------------------------------|------- GPL-2.0 11139 and resulted in the first patch in this series. If that file was a */uapi/* path one, it was "GPL-2.0 WITH Linux-syscall-note" otherwise it was "GPL-2.0". Results of that was: SPDX license identifier # files ---------------------------------------------------|------- GPL-2.0 WITH Linux-syscall-note 930 and resulted in the second patch in this series. - if a file had some form of licensing information in it, and was one of the */uapi/* ones, it was denoted with the Linux-syscall-note if any GPL family license was found in the file or had no licensing in it (per prior point). Results summary: SPDX license identifier # files ---------------------------------------------------|------ GPL-2.0 WITH Linux-syscall-note 270 GPL-2.0+ WITH Linux-syscall-note 169 ((GPL-2.0 WITH Linux-syscall-note) OR BSD-2-Clause) 21 ((GPL-2.0 WITH Linux-syscall-note) OR BSD-3-Clause) 17 LGPL-2.1+ WITH Linux-syscall-note 15 GPL-1.0+ WITH Linux-syscall-note 14 ((GPL-2.0+ WITH Linux-syscall-note) OR BSD-3-Clause) 5 LGPL-2.0+ WITH Linux-syscall-note 4 LGPL-2.1 WITH Linux-syscall-note 3 ((GPL-2.0 WITH Linux-syscall-note) OR MIT) 3 ((GPL-2.0 WITH Linux-syscall-note) AND MIT) 1 and that resulted in the third patch in this series. - when the two scanners agreed on the detected license(s), that became the concluded license(s). - when there was disagreement between the two scanners (one detected a license but the other didn't, or they both detected different licenses) a manual inspection of the file occurred. - In most cases a manual inspection of the information in the file resulted in a clear resolution of the license that should apply (and which scanner probably needed to revisit its heuristics). - When it was not immediately clear, the license identifier was confirmed with lawyers working with the Linux Foundation. - If there was any question as to the appropriate license identifier, the file was flagged for further research and to be revisited later in time. In total, over 70 hours of logged manual review was done on the spreadsheet to determine the SPDX license identifiers to apply to the source files by Kate, Philippe, Thomas and, in some cases, confirmation by lawyers working with the Linux Foundation. Kate also obtained a third independent scan of the 4.13 code base from FOSSology, and compared selected files where the other two scanners disagreed against that SPDX file, to see if there was new insights. The Windriver scanner is based on an older version of FOSSology in part, so they are related. Thomas did random spot checks in about 500 files from the spreadsheets for the uapi headers and agreed with SPDX license identifier in the files he inspected. For the non-uapi files Thomas did random spot checks in about 15000 files. In initial set of patches against 4.14-rc6, 3 files were found to have copy/paste license identifier errors, and have been fixed to reflect the correct identifier. Additionally Philippe spent 10 hours this week doing a detailed manual inspection and review of the 12,461 patched files from the initial patch version early this week with: - a full scancode scan run, collecting the matched texts, detected license ids and scores - reviewing anything where there was a license detected (about 500+ files) to ensure that the applied SPDX license was correct - reviewing anything where there was no detection but the patch license was not GPL-2.0 WITH Linux-syscall-note to ensure that the applied SPDX license was correct This produced a worksheet with 20 files needing minor correction. This worksheet was then exported into 3 different .csv files for the different types of files to be modified. These .csv files were then reviewed by Greg. Thomas wrote a script to parse the csv files and add the proper SPDX tag to the file, in the format that the file expected. This script was further refined by Greg based on the output to detect more types of files automatically and to distinguish between header and source .c files (which need different comment types.) Finally Greg ran the script using the .csv files to generate the patches. Reviewed-by: Kate Stewart <kstewart@linuxfoundation.org> Reviewed-by: Philippe Ombredanne <pombredanne@nexb.com> Reviewed-by: Thomas Gleixner <tglx@linutronix.de> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2017-11-01 22:07:57 +08:00
/* SPDX-License-Identifier: GPL-2.0 */
/*
* arch/ia64/kernel/ivt.S
*
* Copyright (C) 1998-2001, 2003, 2005 Hewlett-Packard Co
* Stephane Eranian <eranian@hpl.hp.com>
* David Mosberger <davidm@hpl.hp.com>
* Copyright (C) 2000, 2002-2003 Intel Co
* Asit Mallick <asit.k.mallick@intel.com>
* Suresh Siddha <suresh.b.siddha@intel.com>
* Kenneth Chen <kenneth.w.chen@intel.com>
* Fenghua Yu <fenghua.yu@intel.com>
*
* 00/08/23 Asit Mallick <asit.k.mallick@intel.com> TLB handling for SMP
* 00/12/20 David Mosberger-Tang <davidm@hpl.hp.com> DTLB/ITLB handler now uses virtual PT.
*
* Copyright (C) 2005 Hewlett-Packard Co
* Dan Magenheimer <dan.magenheimer@hp.com>
* Xen paravirtualization
* Copyright (c) 2008 Isaku Yamahata <yamahata at valinux co jp>
* VA Linux Systems Japan K.K.
* pv_ops.
* Yaozu (Eddie) Dong <eddie.dong@intel.com>
*/
/*
* This file defines the interruption vector table used by the CPU.
* It does not include one entry per possible cause of interruption.
*
* The first 20 entries of the table contain 64 bundles each while the
* remaining 48 entries contain only 16 bundles each.
*
* The 64 bundles are used to allow inlining the whole handler for critical
* interruptions like TLB misses.
*
* For each entry, the comment is as follows:
*
* // 0x1c00 Entry 7 (size 64 bundles) Data Key Miss (12,51)
* entry offset ----/ / / / /
* entry number ---------/ / / /
* size of the entry -------------/ / /
* vector name -------------------------------------/ /
* interruptions triggering this vector ----------------------/
*
* The table is 32KB in size and must be aligned on 32KB boundary.
* (The CPU ignores the 15 lower bits of the address)
*
* Table is based upon EAS2.6 (Oct 1999)
*/
#include <asm/asmmacro.h>
#include <asm/break.h>
#include <asm/kregs.h>
#include <asm/asm-offsets.h>
#include <asm/pgtable.h>
#include <asm/processor.h>
#include <asm/ptrace.h>
#include <asm/thread_info.h>
#include <asm/unistd.h>
#include <asm/errno.h>
#include <asm/export.h>
[IA64] Change default PSR.ac from '1' to '0' (Fix erratum #237) April 2014 Itanium processor specification update: http://www.intel.com/content/www/us/en/processors/itanium/itanium-specification-update.html describes this erratum: ========================================================================= 237. Under a complex set of conditions, store to load forwarding for a sub 8-byte load may complete incorrectly Problem: A load instruction may complete incorrectly when a code sequence using 4-byte or smaller load and store operations to the same address is executed in combination with specific timing of all the following concurrent conditions: store to load forwarding, alignment checking enabled, a mis-predicted branch, and complex cache utilization activity. Implication: The affected sub 8-byte instruction may complete incorrectly resulting in unpredictable system behavior. There is an extremely low probability of exposure due to the significant number of complex microarchitectural concurrent conditions required to encounter the erratum. Workaround: Set PSR.ac = 0 to completely avoid the erratum. Disabling Hyper-Threading will significantly reduce exposure to the conditions that contribute to encountering the erratum. Status: See the Summary Table of Changes for the affected steppings. ========================================================================= [Table of changes essentially lists all models from McKinley to Tukwila] The PSR.ac bit controls whether the processor will always generate an unaligned reference trap (0x5a00) for a misaligned data access (when PSR.ac=1) or if it will let the access succeed when running on a cpu that implements logic to handle some unaligned accesses. Way back in 2008 in commit b704882e70d87d7f56db5ff17e2253f3fa90e4f3 [IA64] Rationalize kernel mode alignment checking we made the decision to always enable strict checking. We were already doing so in trap/interrupt context because the common preamble code set this bit - but the rest of supervisor code (and by inheritance user code) ran with PSR.ac=0. We now reverse that decision and set PSR.ac=0 everywhere in the kernel (also inherited by user processes). This will avoid the erratum using the method described in the Itanium specification update. Net effect for users is that the processor will handle unaligned access when it can (typically with a tiny performance bubble in the pipeline ... but much less invasive than taking a trap and having the OS perform the access). Signed-off-by: Tony Luck <tony.luck@intel.com>
2014-03-29 05:42:07 +08:00
#if 0
# define PSR_DEFAULT_BITS psr.ac
#else
# define PSR_DEFAULT_BITS 0
#endif
#if 0
/*
* This lets you track the last eight faults that occurred on the CPU. Make sure ar.k2 isn't
* needed for something else before enabling this...
*/
# define DBG_FAULT(i) mov r16=ar.k2;; shl r16=r16,8;; add r16=(i),r16;;mov ar.k2=r16
#else
# define DBG_FAULT(i)
#endif
#include "minstate.h"
#define FAULT(n) \
mov r31=pr; \
mov r19=n;; /* prepare to save predicates */ \
br.sptk.many dispatch_to_fault_handler
.section .text..ivt,"ax"
.align 32768 // align on 32KB boundary
.global ia64_ivt
EXPORT_DATA_SYMBOL(ia64_ivt)
ia64_ivt:
/////////////////////////////////////////////////////////////////////////////////////////
// 0x0000 Entry 0 (size 64 bundles) VHPT Translation (8,20,47)
ENTRY(vhpt_miss)
DBG_FAULT(0)
/*
* The VHPT vector is invoked when the TLB entry for the virtual page table
* is missing. This happens only as a result of a previous
* (the "original") TLB miss, which may either be caused by an instruction
* fetch or a data access (or non-access).
*
* What we do here is normal TLB miss handing for the _original_ miss,
* followed by inserting the TLB entry for the virtual page table page
* that the VHPT walker was attempting to access. The latter gets
* inserted as long as page table entry above pte level have valid
* mappings for the faulting address. The TLB entry for the original
* miss gets inserted only if the pte entry indicates that the page is
* present.
*
* do_page_fault gets invoked in the following cases:
* - the faulting virtual address uses unimplemented address bits
* - the faulting virtual address has no valid page table mapping
*/
MOV_FROM_IFA(r16) // get address that caused the TLB miss
#ifdef CONFIG_HUGETLB_PAGE
movl r18=PAGE_SHIFT
MOV_FROM_ITIR(r25)
#endif
;;
RSM_PSR_DT // use physical addressing for data
mov r31=pr // save the predicate registers
mov r19=IA64_KR(PT_BASE) // get page table base address
shl r21=r16,3 // shift bit 60 into sign bit
shr.u r17=r16,61 // get the region number into r17
;;
shr.u r22=r21,3
#ifdef CONFIG_HUGETLB_PAGE
extr.u r26=r25,2,6
;;
cmp.ne p8,p0=r18,r26
sub r27=r26,r18
;;
(p8) dep r25=r18,r25,2,6
(p8) shr r22=r22,r27
#endif
;;
cmp.eq p6,p7=5,r17 // is IFA pointing into to region 5?
shr.u r18=r22,PGDIR_SHIFT // get bottom portion of pgd index bit
;;
(p7) dep r17=r17,r19,(PAGE_SHIFT-3),3 // put region number bits in place
srlz.d
LOAD_PHYSICAL(p6, r19, swapper_pg_dir) // region 5 is rooted at swapper_pg_dir
.pred.rel "mutex", p6, p7
(p6) shr.u r21=r21,PGDIR_SHIFT+PAGE_SHIFT
(p7) shr.u r21=r21,PGDIR_SHIFT+PAGE_SHIFT-3
;;
(p6) dep r17=r18,r19,3,(PAGE_SHIFT-3) // r17=pgd_offset for region 5
(p7) dep r17=r18,r17,3,(PAGE_SHIFT-6) // r17=pgd_offset for region[0-4]
cmp.eq p7,p6=0,r21 // unused address bits all zeroes?
#if CONFIG_PGTABLE_LEVELS == 4
shr.u r28=r22,PUD_SHIFT // shift pud index into position
#else
shr.u r18=r22,PMD_SHIFT // shift pmd index into position
#endif
;;
ld8 r17=[r17] // get *pgd (may be 0)
;;
(p7) cmp.eq p6,p7=r17,r0 // was pgd_present(*pgd) == NULL?
#if CONFIG_PGTABLE_LEVELS == 4
dep r28=r28,r17,3,(PAGE_SHIFT-3) // r28=pud_offset(pgd,addr)
;;
shr.u r18=r22,PMD_SHIFT // shift pmd index into position
(p7) ld8 r29=[r28] // get *pud (may be 0)
;;
(p7) cmp.eq.or.andcm p6,p7=r29,r0 // was pud_present(*pud) == NULL?
dep r17=r18,r29,3,(PAGE_SHIFT-3) // r17=pmd_offset(pud,addr)
#else
dep r17=r18,r17,3,(PAGE_SHIFT-3) // r17=pmd_offset(pgd,addr)
#endif
;;
(p7) ld8 r20=[r17] // get *pmd (may be 0)
shr.u r19=r22,PAGE_SHIFT // shift pte index into position
;;
(p7) cmp.eq.or.andcm p6,p7=r20,r0 // was pmd_present(*pmd) == NULL?
dep r21=r19,r20,3,(PAGE_SHIFT-3) // r21=pte_offset(pmd,addr)
;;
(p7) ld8 r18=[r21] // read *pte
MOV_FROM_ISR(r19) // cr.isr bit 32 tells us if this is an insn miss
;;
(p7) tbit.z p6,p7=r18,_PAGE_P_BIT // page present bit cleared?
MOV_FROM_IHA(r22) // get the VHPT address that caused the TLB miss
;; // avoid RAW on p7
(p7) tbit.nz.unc p10,p11=r19,32 // is it an instruction TLB miss?
dep r23=0,r20,0,PAGE_SHIFT // clear low bits to get page address
;;
ITC_I_AND_D(p10, p11, r18, r24) // insert the instruction TLB entry and
// insert the data TLB entry
(p6) br.cond.spnt.many page_fault // handle bad address/page not present (page fault)
MOV_TO_IFA(r22, r24)
#ifdef CONFIG_HUGETLB_PAGE
MOV_TO_ITIR(p8, r25, r24) // change to default page-size for VHPT
#endif
/*
* Now compute and insert the TLB entry for the virtual page table. We never
* execute in a page table page so there is no need to set the exception deferral
* bit.
*/
adds r24=__DIRTY_BITS_NO_ED|_PAGE_PL_0|_PAGE_AR_RW,r23
;;
ITC_D(p7, r24, r25)
;;
#ifdef CONFIG_SMP
/*
* Tell the assemblers dependency-violation checker that the above "itc" instructions
* cannot possibly affect the following loads:
*/
dv_serialize_data
/*
* Re-check pagetable entry. If they changed, we may have received a ptc.g
* between reading the pagetable and the "itc". If so, flush the entry we
* inserted and retry. At this point, we have:
*
* r28 = equivalent of pud_offset(pgd, ifa)
* r17 = equivalent of pmd_offset(pud, ifa)
* r21 = equivalent of pte_offset(pmd, ifa)
*
* r29 = *pud
* r20 = *pmd
* r18 = *pte
*/
ld8 r25=[r21] // read *pte again
ld8 r26=[r17] // read *pmd again
#if CONFIG_PGTABLE_LEVELS == 4
ld8 r19=[r28] // read *pud again
#endif
cmp.ne p6,p7=r0,r0
;;
cmp.ne.or.andcm p6,p7=r26,r20 // did *pmd change
#if CONFIG_PGTABLE_LEVELS == 4
cmp.ne.or.andcm p6,p7=r19,r29 // did *pud change
#endif
mov r27=PAGE_SHIFT<<2
;;
(p6) ptc.l r22,r27 // purge PTE page translation
(p7) cmp.ne.or.andcm p6,p7=r25,r18 // did *pte change
;;
(p6) ptc.l r16,r27 // purge translation
#endif
mov pr=r31,-1 // restore predicate registers
RFI
END(vhpt_miss)
.org ia64_ivt+0x400
/////////////////////////////////////////////////////////////////////////////////////////
// 0x0400 Entry 1 (size 64 bundles) ITLB (21)
ENTRY(itlb_miss)
DBG_FAULT(1)
/*
* The ITLB handler accesses the PTE via the virtually mapped linear
* page table. If a nested TLB miss occurs, we switch into physical
* mode, walk the page table, and then re-execute the PTE read and
* go on normally after that.
*/
MOV_FROM_IFA(r16) // get virtual address
mov r29=b0 // save b0
mov r31=pr // save predicates
.itlb_fault:
MOV_FROM_IHA(r17) // get virtual address of PTE
movl r30=1f // load nested fault continuation point
;;
1: ld8 r18=[r17] // read *pte
;;
mov b0=r29
tbit.z p6,p0=r18,_PAGE_P_BIT // page present bit cleared?
(p6) br.cond.spnt page_fault
;;
ITC_I(p0, r18, r19)
;;
#ifdef CONFIG_SMP
/*
* Tell the assemblers dependency-violation checker that the above "itc" instructions
* cannot possibly affect the following loads:
*/
dv_serialize_data
ld8 r19=[r17] // read *pte again and see if same
mov r20=PAGE_SHIFT<<2 // setup page size for purge
;;
cmp.ne p7,p0=r18,r19
;;
(p7) ptc.l r16,r20
#endif
mov pr=r31,-1
RFI
END(itlb_miss)
.org ia64_ivt+0x0800
/////////////////////////////////////////////////////////////////////////////////////////
// 0x0800 Entry 2 (size 64 bundles) DTLB (9,48)
ENTRY(dtlb_miss)
DBG_FAULT(2)
/*
* The DTLB handler accesses the PTE via the virtually mapped linear
* page table. If a nested TLB miss occurs, we switch into physical
* mode, walk the page table, and then re-execute the PTE read and
* go on normally after that.
*/
MOV_FROM_IFA(r16) // get virtual address
mov r29=b0 // save b0
mov r31=pr // save predicates
dtlb_fault:
MOV_FROM_IHA(r17) // get virtual address of PTE
movl r30=1f // load nested fault continuation point
;;
1: ld8 r18=[r17] // read *pte
;;
mov b0=r29
tbit.z p6,p0=r18,_PAGE_P_BIT // page present bit cleared?
(p6) br.cond.spnt page_fault
;;
ITC_D(p0, r18, r19)
;;
#ifdef CONFIG_SMP
/*
* Tell the assemblers dependency-violation checker that the above "itc" instructions
* cannot possibly affect the following loads:
*/
dv_serialize_data
ld8 r19=[r17] // read *pte again and see if same
mov r20=PAGE_SHIFT<<2 // setup page size for purge
;;
cmp.ne p7,p0=r18,r19
;;
(p7) ptc.l r16,r20
#endif
mov pr=r31,-1
RFI
END(dtlb_miss)
.org ia64_ivt+0x0c00
/////////////////////////////////////////////////////////////////////////////////////////
// 0x0c00 Entry 3 (size 64 bundles) Alt ITLB (19)
ENTRY(alt_itlb_miss)
DBG_FAULT(3)
MOV_FROM_IFA(r16) // get address that caused the TLB miss
movl r17=PAGE_KERNEL
MOV_FROM_IPSR(p0, r21)
movl r19=(((1 << IA64_MAX_PHYS_BITS) - 1) & ~0xfff)
mov r31=pr
;;
#ifdef CONFIG_DISABLE_VHPT
shr.u r22=r16,61 // get the region number into r21
;;
cmp.gt p8,p0=6,r22 // user mode
;;
THASH(p8, r17, r16, r23)
;;
MOV_TO_IHA(p8, r17, r23)
(p8) mov r29=b0 // save b0
(p8) br.cond.dptk .itlb_fault
#endif
extr.u r23=r21,IA64_PSR_CPL0_BIT,2 // extract psr.cpl
and r19=r19,r16 // clear ed, reserved bits, and PTE control bits
shr.u r18=r16,57 // move address bit 61 to bit 4
;;
andcm r18=0x10,r18 // bit 4=~address-bit(61)
cmp.ne p8,p0=r0,r23 // psr.cpl != 0?
or r19=r17,r19 // insert PTE control bits into r19
;;
or r19=r19,r18 // set bit 4 (uncached) if the access was to region 6
(p8) br.cond.spnt page_fault
;;
ITC_I(p0, r19, r18) // insert the TLB entry
mov pr=r31,-1
RFI
END(alt_itlb_miss)
.org ia64_ivt+0x1000
/////////////////////////////////////////////////////////////////////////////////////////
// 0x1000 Entry 4 (size 64 bundles) Alt DTLB (7,46)
ENTRY(alt_dtlb_miss)
DBG_FAULT(4)
MOV_FROM_IFA(r16) // get address that caused the TLB miss
movl r17=PAGE_KERNEL
MOV_FROM_ISR(r20)
movl r19=(((1 << IA64_MAX_PHYS_BITS) - 1) & ~0xfff)
MOV_FROM_IPSR(p0, r21)
mov r31=pr
mov r24=PERCPU_ADDR
;;
#ifdef CONFIG_DISABLE_VHPT
shr.u r22=r16,61 // get the region number into r21
;;
cmp.gt p8,p0=6,r22 // access to region 0-5
;;
THASH(p8, r17, r16, r25)
;;
MOV_TO_IHA(p8, r17, r25)
(p8) mov r29=b0 // save b0
(p8) br.cond.dptk dtlb_fault
#endif
cmp.ge p10,p11=r16,r24 // access to per_cpu_data?
tbit.z p12,p0=r16,61 // access to region 6?
mov r25=PERCPU_PAGE_SHIFT << 2
mov r26=PERCPU_PAGE_SIZE
nop.m 0
nop.b 0
;;
(p10) mov r19=IA64_KR(PER_CPU_DATA)
(p11) and r19=r19,r16 // clear non-ppn fields
extr.u r23=r21,IA64_PSR_CPL0_BIT,2 // extract psr.cpl
and r22=IA64_ISR_CODE_MASK,r20 // get the isr.code field
tbit.nz p6,p7=r20,IA64_ISR_SP_BIT // is speculation bit on?
tbit.nz p9,p0=r20,IA64_ISR_NA_BIT // is non-access bit on?
;;
(p10) sub r19=r19,r26
MOV_TO_ITIR(p10, r25, r24)
cmp.ne p8,p0=r0,r23
(p9) cmp.eq.or.andcm p6,p7=IA64_ISR_CODE_LFETCH,r22 // check isr.code field
(p12) dep r17=-1,r17,4,1 // set ma=UC for region 6 addr
(p8) br.cond.spnt page_fault
dep r21=-1,r21,IA64_PSR_ED_BIT,1
;;
or r19=r19,r17 // insert PTE control bits into r19
MOV_TO_IPSR(p6, r21, r24)
;;
ITC_D(p7, r19, r18) // insert the TLB entry
mov pr=r31,-1
RFI
END(alt_dtlb_miss)
.org ia64_ivt+0x1400
/////////////////////////////////////////////////////////////////////////////////////////
// 0x1400 Entry 5 (size 64 bundles) Data nested TLB (6,45)
ENTRY(nested_dtlb_miss)
/*
* In the absence of kernel bugs, we get here when the virtually mapped linear
* page table is accessed non-speculatively (e.g., in the Dirty-bit, Instruction
* Access-bit, or Data Access-bit faults). If the DTLB entry for the virtual page
* table is missing, a nested TLB miss fault is triggered and control is
* transferred to this point. When this happens, we lookup the pte for the
* faulting address by walking the page table in physical mode and return to the
* continuation point passed in register r30 (or call page_fault if the address is
* not mapped).
*
* Input: r16: faulting address
* r29: saved b0
* r30: continuation address
* r31: saved pr
*
* Output: r17: physical address of PTE of faulting address
* r29: saved b0
* r30: continuation address
* r31: saved pr
*
* Clobbered: b0, r18, r19, r21, r22, psr.dt (cleared)
*/
RSM_PSR_DT // switch to using physical data addressing
mov r19=IA64_KR(PT_BASE) // get the page table base address
shl r21=r16,3 // shift bit 60 into sign bit
MOV_FROM_ITIR(r18)
;;
shr.u r17=r16,61 // get the region number into r17
extr.u r18=r18,2,6 // get the faulting page size
;;
cmp.eq p6,p7=5,r17 // is faulting address in region 5?
add r22=-PAGE_SHIFT,r18 // adjustment for hugetlb address
add r18=PGDIR_SHIFT-PAGE_SHIFT,r18
;;
shr.u r22=r16,r22
shr.u r18=r16,r18
(p7) dep r17=r17,r19,(PAGE_SHIFT-3),3 // put region number bits in place
srlz.d
LOAD_PHYSICAL(p6, r19, swapper_pg_dir) // region 5 is rooted at swapper_pg_dir
.pred.rel "mutex", p6, p7
(p6) shr.u r21=r21,PGDIR_SHIFT+PAGE_SHIFT
(p7) shr.u r21=r21,PGDIR_SHIFT+PAGE_SHIFT-3
;;
(p6) dep r17=r18,r19,3,(PAGE_SHIFT-3) // r17=pgd_offset for region 5
(p7) dep r17=r18,r17,3,(PAGE_SHIFT-6) // r17=pgd_offset for region[0-4]
cmp.eq p7,p6=0,r21 // unused address bits all zeroes?
#if CONFIG_PGTABLE_LEVELS == 4
shr.u r18=r22,PUD_SHIFT // shift pud index into position
#else
shr.u r18=r22,PMD_SHIFT // shift pmd index into position
#endif
;;
ld8 r17=[r17] // get *pgd (may be 0)
;;
(p7) cmp.eq p6,p7=r17,r0 // was pgd_present(*pgd) == NULL?
dep r17=r18,r17,3,(PAGE_SHIFT-3) // r17=p[u|m]d_offset(pgd,addr)
;;
#if CONFIG_PGTABLE_LEVELS == 4
(p7) ld8 r17=[r17] // get *pud (may be 0)
shr.u r18=r22,PMD_SHIFT // shift pmd index into position
;;
(p7) cmp.eq.or.andcm p6,p7=r17,r0 // was pud_present(*pud) == NULL?
dep r17=r18,r17,3,(PAGE_SHIFT-3) // r17=pmd_offset(pud,addr)
;;
#endif
(p7) ld8 r17=[r17] // get *pmd (may be 0)
shr.u r19=r22,PAGE_SHIFT // shift pte index into position
;;
(p7) cmp.eq.or.andcm p6,p7=r17,r0 // was pmd_present(*pmd) == NULL?
dep r17=r19,r17,3,(PAGE_SHIFT-3) // r17=pte_offset(pmd,addr);
(p6) br.cond.spnt page_fault
mov b0=r30
br.sptk.many b0 // return to continuation point
END(nested_dtlb_miss)
.org ia64_ivt+0x1800
/////////////////////////////////////////////////////////////////////////////////////////
// 0x1800 Entry 6 (size 64 bundles) Instruction Key Miss (24)
ENTRY(ikey_miss)
DBG_FAULT(6)
FAULT(6)
END(ikey_miss)
.org ia64_ivt+0x1c00
/////////////////////////////////////////////////////////////////////////////////////////
// 0x1c00 Entry 7 (size 64 bundles) Data Key Miss (12,51)
ENTRY(dkey_miss)
DBG_FAULT(7)
FAULT(7)
END(dkey_miss)
.org ia64_ivt+0x2000
/////////////////////////////////////////////////////////////////////////////////////////
// 0x2000 Entry 8 (size 64 bundles) Dirty-bit (54)
ENTRY(dirty_bit)
DBG_FAULT(8)
/*
* What we do here is to simply turn on the dirty bit in the PTE. We need to
* update both the page-table and the TLB entry. To efficiently access the PTE,
* we address it through the virtual page table. Most likely, the TLB entry for
* the relevant virtual page table page is still present in the TLB so we can
* normally do this without additional TLB misses. In case the necessary virtual
* page table TLB entry isn't present, we take a nested TLB miss hit where we look
* up the physical address of the L3 PTE and then continue at label 1 below.
*/
MOV_FROM_IFA(r16) // get the address that caused the fault
movl r30=1f // load continuation point in case of nested fault
;;
THASH(p0, r17, r16, r18) // compute virtual address of L3 PTE
mov r29=b0 // save b0 in case of nested fault
mov r31=pr // save pr
#ifdef CONFIG_SMP
mov r28=ar.ccv // save ar.ccv
;;
1: ld8 r18=[r17]
;; // avoid RAW on r18
mov ar.ccv=r18 // set compare value for cmpxchg
or r25=_PAGE_D|_PAGE_A,r18 // set the dirty and accessed bits
tbit.z p7,p6 = r18,_PAGE_P_BIT // Check present bit
;;
(p6) cmpxchg8.acq r26=[r17],r25,ar.ccv // Only update if page is present
mov r24=PAGE_SHIFT<<2
;;
(p6) cmp.eq p6,p7=r26,r18 // Only compare if page is present
;;
ITC_D(p6, r25, r18) // install updated PTE
;;
/*
* Tell the assemblers dependency-violation checker that the above "itc" instructions
* cannot possibly affect the following loads:
*/
dv_serialize_data
ld8 r18=[r17] // read PTE again
;;
cmp.eq p6,p7=r18,r25 // is it same as the newly installed
;;
(p7) ptc.l r16,r24
mov b0=r29 // restore b0
mov ar.ccv=r28
#else
;;
1: ld8 r18=[r17]
;; // avoid RAW on r18
or r18=_PAGE_D|_PAGE_A,r18 // set the dirty and accessed bits
mov b0=r29 // restore b0
;;
st8 [r17]=r18 // store back updated PTE
ITC_D(p0, r18, r16) // install updated PTE
#endif
mov pr=r31,-1 // restore pr
RFI
END(dirty_bit)
.org ia64_ivt+0x2400
/////////////////////////////////////////////////////////////////////////////////////////
// 0x2400 Entry 9 (size 64 bundles) Instruction Access-bit (27)
ENTRY(iaccess_bit)
DBG_FAULT(9)
// Like Entry 8, except for instruction access
MOV_FROM_IFA(r16) // get the address that caused the fault
movl r30=1f // load continuation point in case of nested fault
mov r31=pr // save predicates
#ifdef CONFIG_ITANIUM
/*
* Erratum 10 (IFA may contain incorrect address) has "NoFix" status.
*/
MOV_FROM_IPSR(p0, r17)
;;
MOV_FROM_IIP(r18)
tbit.z p6,p0=r17,IA64_PSR_IS_BIT // IA64 instruction set?
;;
(p6) mov r16=r18 // if so, use cr.iip instead of cr.ifa
#endif /* CONFIG_ITANIUM */
;;
THASH(p0, r17, r16, r18) // compute virtual address of L3 PTE
mov r29=b0 // save b0 in case of nested fault)
#ifdef CONFIG_SMP
mov r28=ar.ccv // save ar.ccv
;;
1: ld8 r18=[r17]
;;
mov ar.ccv=r18 // set compare value for cmpxchg
or r25=_PAGE_A,r18 // set the accessed bit
tbit.z p7,p6 = r18,_PAGE_P_BIT // Check present bit
;;
(p6) cmpxchg8.acq r26=[r17],r25,ar.ccv // Only if page present
mov r24=PAGE_SHIFT<<2
;;
(p6) cmp.eq p6,p7=r26,r18 // Only if page present
;;
ITC_I(p6, r25, r26) // install updated PTE
;;
/*
* Tell the assemblers dependency-violation checker that the above "itc" instructions
* cannot possibly affect the following loads:
*/
dv_serialize_data
ld8 r18=[r17] // read PTE again
;;
cmp.eq p6,p7=r18,r25 // is it same as the newly installed
;;
(p7) ptc.l r16,r24
mov b0=r29 // restore b0
mov ar.ccv=r28
#else /* !CONFIG_SMP */
;;
1: ld8 r18=[r17]
;;
or r18=_PAGE_A,r18 // set the accessed bit
mov b0=r29 // restore b0
;;
st8 [r17]=r18 // store back updated PTE
ITC_I(p0, r18, r16) // install updated PTE
#endif /* !CONFIG_SMP */
mov pr=r31,-1
RFI
END(iaccess_bit)
.org ia64_ivt+0x2800
/////////////////////////////////////////////////////////////////////////////////////////
// 0x2800 Entry 10 (size 64 bundles) Data Access-bit (15,55)
ENTRY(daccess_bit)
DBG_FAULT(10)
// Like Entry 8, except for data access
MOV_FROM_IFA(r16) // get the address that caused the fault
movl r30=1f // load continuation point in case of nested fault
;;
THASH(p0, r17, r16, r18) // compute virtual address of L3 PTE
mov r31=pr
mov r29=b0 // save b0 in case of nested fault)
#ifdef CONFIG_SMP
mov r28=ar.ccv // save ar.ccv
;;
1: ld8 r18=[r17]
;; // avoid RAW on r18
mov ar.ccv=r18 // set compare value for cmpxchg
or r25=_PAGE_A,r18 // set the dirty bit
tbit.z p7,p6 = r18,_PAGE_P_BIT // Check present bit
;;
(p6) cmpxchg8.acq r26=[r17],r25,ar.ccv // Only if page is present
mov r24=PAGE_SHIFT<<2
;;
(p6) cmp.eq p6,p7=r26,r18 // Only if page is present
;;
ITC_D(p6, r25, r26) // install updated PTE
/*
* Tell the assemblers dependency-violation checker that the above "itc" instructions
* cannot possibly affect the following loads:
*/
dv_serialize_data
;;
ld8 r18=[r17] // read PTE again
;;
cmp.eq p6,p7=r18,r25 // is it same as the newly installed
;;
(p7) ptc.l r16,r24
mov ar.ccv=r28
#else
;;
1: ld8 r18=[r17]
;; // avoid RAW on r18
or r18=_PAGE_A,r18 // set the accessed bit
;;
st8 [r17]=r18 // store back updated PTE
ITC_D(p0, r18, r16) // install updated PTE
#endif
mov b0=r29 // restore b0
mov pr=r31,-1
RFI
END(daccess_bit)
.org ia64_ivt+0x2c00
/////////////////////////////////////////////////////////////////////////////////////////
// 0x2c00 Entry 11 (size 64 bundles) Break instruction (33)
ENTRY(break_fault)
/*
* The streamlined system call entry/exit paths only save/restore the initial part
* of pt_regs. This implies that the callers of system-calls must adhere to the
* normal procedure calling conventions.
*
* Registers to be saved & restored:
* CR registers: cr.ipsr, cr.iip, cr.ifs
* AR registers: ar.unat, ar.pfs, ar.rsc, ar.rnat, ar.bspstore, ar.fpsr
* others: pr, b0, b6, loadrs, r1, r11, r12, r13, r15
* Registers to be restored only:
* r8-r11: output value from the system call.
*
* During system call exit, scratch registers (including r15) are modified/cleared
* to prevent leaking bits from kernel to user level.
*/
DBG_FAULT(11)
mov.m r16=IA64_KR(CURRENT) // M2 r16 <- current task (12 cyc)
MOV_FROM_IPSR(p0, r29) // M2 (12 cyc)
mov r31=pr // I0 (2 cyc)
MOV_FROM_IIM(r17) // M2 (2 cyc)
mov.m r27=ar.rsc // M2 (12 cyc)
mov r18=__IA64_BREAK_SYSCALL // A
mov.m ar.rsc=0 // M2
mov.m r21=ar.fpsr // M2 (12 cyc)
mov r19=b6 // I0 (2 cyc)
;;
mov.m r23=ar.bspstore // M2 (12 cyc)
mov.m r24=ar.rnat // M2 (5 cyc)
mov.i r26=ar.pfs // I0 (2 cyc)
invala // M0|1
nop.m 0 // M
mov r20=r1 // A save r1
nop.m 0
movl r30=sys_call_table // X
MOV_FROM_IIP(r28) // M2 (2 cyc)
cmp.eq p0,p7=r18,r17 // I0 is this a system call?
(p7) br.cond.spnt non_syscall // B no ->
//
// From this point on, we are definitely on the syscall-path
// and we can use (non-banked) scratch registers.
//
///////////////////////////////////////////////////////////////////////
mov r1=r16 // A move task-pointer to "addl"-addressable reg
mov r2=r16 // A setup r2 for ia64_syscall_setup
add r9=TI_FLAGS+IA64_TASK_SIZE,r16 // A r9 = &current_thread_info()->flags
adds r16=IA64_TASK_THREAD_ON_USTACK_OFFSET,r16
adds r15=-1024,r15 // A subtract 1024 from syscall number
mov r3=NR_syscalls - 1
;;
ld1.bias r17=[r16] // M0|1 r17 = current->thread.on_ustack flag
ld4 r9=[r9] // M0|1 r9 = current_thread_info()->flags
extr.u r8=r29,41,2 // I0 extract ei field from cr.ipsr
shladd r30=r15,3,r30 // A r30 = sys_call_table + 8*(syscall-1024)
addl r22=IA64_RBS_OFFSET,r1 // A compute base of RBS
cmp.leu p6,p7=r15,r3 // A syscall number in range?
;;
lfetch.fault.excl.nt1 [r22] // M0|1 prefetch RBS
(p6) ld8 r30=[r30] // M0|1 load address of syscall entry point
tnat.nz.or p7,p0=r15 // I0 is syscall nr a NaT?
mov.m ar.bspstore=r22 // M2 switch to kernel RBS
cmp.eq p8,p9=2,r8 // A isr.ei==2?
;;
(p8) mov r8=0 // A clear ei to 0
(p7) movl r30=sys_ni_syscall // X
(p8) adds r28=16,r28 // A switch cr.iip to next bundle
(p9) adds r8=1,r8 // A increment ei to next slot
cputime: Generic on-demand virtual cputime accounting If we want to stop the tick further idle, we need to be able to account the cputime without using the tick. Virtual based cputime accounting solves that problem by hooking into kernel/user boundaries. However implementing CONFIG_VIRT_CPU_ACCOUNTING require low level hooks and involves more overhead. But we already have a generic context tracking subsystem that is required for RCU needs by archs which plan to shut down the tick outside idle. This patch implements a generic virtual based cputime accounting that relies on these generic kernel/user hooks. There are some upsides of doing this: - This requires no arch code to implement CONFIG_VIRT_CPU_ACCOUNTING if context tracking is already built (already necessary for RCU in full tickless mode). - We can rely on the generic context tracking subsystem to dynamically (de)activate the hooks, so that we can switch anytime between virtual and tick based accounting. This way we don't have the overhead of the virtual accounting when the tick is running periodically. And one downside: - There is probably more overhead than a native virtual based cputime accounting. But this relies on hooks that are already set anyway. Signed-off-by: Frederic Weisbecker <fweisbec@gmail.com> Cc: Andrew Morton <akpm@linux-foundation.org> Cc: Ingo Molnar <mingo@kernel.org> Cc: Li Zhong <zhong@linux.vnet.ibm.com> Cc: Namhyung Kim <namhyung.kim@lge.com> Cc: Paul E. McKenney <paulmck@linux.vnet.ibm.com> Cc: Paul Gortmaker <paul.gortmaker@windriver.com> Cc: Peter Zijlstra <peterz@infradead.org> Cc: Steven Rostedt <rostedt@goodmis.org> Cc: Thomas Gleixner <tglx@linutronix.de>
2012-07-25 13:56:04 +08:00
#ifdef CONFIG_VIRT_CPU_ACCOUNTING_NATIVE
;;
mov b6=r30 // I0 setup syscall handler branch reg early
#else
nop.i 0
;;
#endif
mov.m r25=ar.unat // M2 (5 cyc)
dep r29=r8,r29,41,2 // I0 insert new ei into cr.ipsr
adds r15=1024,r15 // A restore original syscall number
//
// If any of the above loads miss in L1D, we'll stall here until
// the data arrives.
//
///////////////////////////////////////////////////////////////////////
st1 [r16]=r0 // M2|3 clear current->thread.on_ustack flag
cputime: Generic on-demand virtual cputime accounting If we want to stop the tick further idle, we need to be able to account the cputime without using the tick. Virtual based cputime accounting solves that problem by hooking into kernel/user boundaries. However implementing CONFIG_VIRT_CPU_ACCOUNTING require low level hooks and involves more overhead. But we already have a generic context tracking subsystem that is required for RCU needs by archs which plan to shut down the tick outside idle. This patch implements a generic virtual based cputime accounting that relies on these generic kernel/user hooks. There are some upsides of doing this: - This requires no arch code to implement CONFIG_VIRT_CPU_ACCOUNTING if context tracking is already built (already necessary for RCU in full tickless mode). - We can rely on the generic context tracking subsystem to dynamically (de)activate the hooks, so that we can switch anytime between virtual and tick based accounting. This way we don't have the overhead of the virtual accounting when the tick is running periodically. And one downside: - There is probably more overhead than a native virtual based cputime accounting. But this relies on hooks that are already set anyway. Signed-off-by: Frederic Weisbecker <fweisbec@gmail.com> Cc: Andrew Morton <akpm@linux-foundation.org> Cc: Ingo Molnar <mingo@kernel.org> Cc: Li Zhong <zhong@linux.vnet.ibm.com> Cc: Namhyung Kim <namhyung.kim@lge.com> Cc: Paul E. McKenney <paulmck@linux.vnet.ibm.com> Cc: Paul Gortmaker <paul.gortmaker@windriver.com> Cc: Peter Zijlstra <peterz@infradead.org> Cc: Steven Rostedt <rostedt@goodmis.org> Cc: Thomas Gleixner <tglx@linutronix.de>
2012-07-25 13:56:04 +08:00
#ifdef CONFIG_VIRT_CPU_ACCOUNTING_NATIVE
MOV_FROM_ITC(p0, p14, r30, r18) // M get cycle for accounting
#else
mov b6=r30 // I0 setup syscall handler branch reg early
#endif
cmp.eq pKStk,pUStk=r0,r17 // A were we on kernel stacks already?
and r9=_TIF_SYSCALL_TRACEAUDIT,r9 // A mask trace or audit
mov r18=ar.bsp // M2 (12 cyc)
(pKStk) br.cond.spnt .break_fixup // B we're already in kernel-mode -- fix up RBS
;;
.back_from_break_fixup:
(pUStk) addl r1=IA64_STK_OFFSET-IA64_PT_REGS_SIZE,r1 // A compute base of memory stack
cmp.eq p14,p0=r9,r0 // A are syscalls being traced/audited?
br.call.sptk.many b7=ia64_syscall_setup // B
1:
cputime: Generic on-demand virtual cputime accounting If we want to stop the tick further idle, we need to be able to account the cputime without using the tick. Virtual based cputime accounting solves that problem by hooking into kernel/user boundaries. However implementing CONFIG_VIRT_CPU_ACCOUNTING require low level hooks and involves more overhead. But we already have a generic context tracking subsystem that is required for RCU needs by archs which plan to shut down the tick outside idle. This patch implements a generic virtual based cputime accounting that relies on these generic kernel/user hooks. There are some upsides of doing this: - This requires no arch code to implement CONFIG_VIRT_CPU_ACCOUNTING if context tracking is already built (already necessary for RCU in full tickless mode). - We can rely on the generic context tracking subsystem to dynamically (de)activate the hooks, so that we can switch anytime between virtual and tick based accounting. This way we don't have the overhead of the virtual accounting when the tick is running periodically. And one downside: - There is probably more overhead than a native virtual based cputime accounting. But this relies on hooks that are already set anyway. Signed-off-by: Frederic Weisbecker <fweisbec@gmail.com> Cc: Andrew Morton <akpm@linux-foundation.org> Cc: Ingo Molnar <mingo@kernel.org> Cc: Li Zhong <zhong@linux.vnet.ibm.com> Cc: Namhyung Kim <namhyung.kim@lge.com> Cc: Paul E. McKenney <paulmck@linux.vnet.ibm.com> Cc: Paul Gortmaker <paul.gortmaker@windriver.com> Cc: Peter Zijlstra <peterz@infradead.org> Cc: Steven Rostedt <rostedt@goodmis.org> Cc: Thomas Gleixner <tglx@linutronix.de>
2012-07-25 13:56:04 +08:00
#ifdef CONFIG_VIRT_CPU_ACCOUNTING_NATIVE
// mov.m r30=ar.itc is called in advance, and r13 is current
add r16=TI_AC_STAMP+IA64_TASK_SIZE,r13 // A
add r17=TI_AC_LEAVE+IA64_TASK_SIZE,r13 // A
(pKStk) br.cond.spnt .skip_accounting // B unlikely skip
;;
ld8 r18=[r16],TI_AC_STIME-TI_AC_STAMP // M get last stamp
ld8 r19=[r17],TI_AC_UTIME-TI_AC_LEAVE // M time at leave
;;
ld8 r20=[r16],TI_AC_STAMP-TI_AC_STIME // M cumulated stime
ld8 r21=[r17] // M cumulated utime
sub r22=r19,r18 // A stime before leave
;;
st8 [r16]=r30,TI_AC_STIME-TI_AC_STAMP // M update stamp
sub r18=r30,r19 // A elapsed time in user
;;
add r20=r20,r22 // A sum stime
add r21=r21,r18 // A sum utime
;;
st8 [r16]=r20 // M update stime
st8 [r17]=r21 // M update utime
;;
.skip_accounting:
#endif
mov ar.rsc=0x3 // M2 set eager mode, pl 0, LE, loadrs=0
nop 0
BSW_1(r2, r14) // B (6 cyc) regs are saved, switch to bank 1
;;
SSM_PSR_IC_AND_DEFAULT_BITS_AND_SRLZ_I(r3, r16) // M2 now it's safe to re-enable intr.-collection
// M0 ensure interruption collection is on
movl r3=ia64_ret_from_syscall // X
;;
mov rp=r3 // I0 set the real return addr
(p10) br.cond.spnt.many ia64_ret_from_syscall // B return if bad call-frame or r15 is a NaT
SSM_PSR_I(p15, p15, r16) // M2 restore psr.i
(p14) br.call.sptk.many b6=b6 // B invoke syscall-handker (ignore return addr)
br.cond.spnt.many ia64_trace_syscall // B do syscall-tracing thingamagic
// NOT REACHED
///////////////////////////////////////////////////////////////////////
// On entry, we optimistically assumed that we're coming from user-space.
// For the rare cases where a system-call is done from within the kernel,
// we fix things up at this point:
.break_fixup:
add r1=-IA64_PT_REGS_SIZE,sp // A allocate space for pt_regs structure
mov ar.rnat=r24 // M2 restore kernel's AR.RNAT
;;
mov ar.bspstore=r23 // M2 restore kernel's AR.BSPSTORE
br.cond.sptk .back_from_break_fixup
END(break_fault)
.org ia64_ivt+0x3000
/////////////////////////////////////////////////////////////////////////////////////////
// 0x3000 Entry 12 (size 64 bundles) External Interrupt (4)
ENTRY(interrupt)
/* interrupt handler has become too big to fit this area. */
br.sptk.many __interrupt
END(interrupt)
.org ia64_ivt+0x3400
/////////////////////////////////////////////////////////////////////////////////////////
// 0x3400 Entry 13 (size 64 bundles) Reserved
DBG_FAULT(13)
FAULT(13)
.org ia64_ivt+0x3800
/////////////////////////////////////////////////////////////////////////////////////////
// 0x3800 Entry 14 (size 64 bundles) Reserved
DBG_FAULT(14)
FAULT(14)
/*
* There is no particular reason for this code to be here, other than that
* there happens to be space here that would go unused otherwise. If this
* fault ever gets "unreserved", simply moved the following code to a more
* suitable spot...
*
* ia64_syscall_setup() is a separate subroutine so that it can
* allocate stacked registers so it can safely demine any
* potential NaT values from the input registers.
*
* On entry:
* - executing on bank 0 or bank 1 register set (doesn't matter)
* - r1: stack pointer
* - r2: current task pointer
* - r3: preserved
* - r11: original contents (saved ar.pfs to be saved)
* - r12: original contents (sp to be saved)
* - r13: original contents (tp to be saved)
* - r15: original contents (syscall # to be saved)
* - r18: saved bsp (after switching to kernel stack)
* - r19: saved b6
* - r20: saved r1 (gp)
* - r21: saved ar.fpsr
* - r22: kernel's register backing store base (krbs_base)
* - r23: saved ar.bspstore
* - r24: saved ar.rnat
* - r25: saved ar.unat
* - r26: saved ar.pfs
* - r27: saved ar.rsc
* - r28: saved cr.iip
* - r29: saved cr.ipsr
* - r30: ar.itc for accounting (don't touch)
* - r31: saved pr
* - b0: original contents (to be saved)
* On exit:
* - p10: TRUE if syscall is invoked with more than 8 out
* registers or r15's Nat is true
* - r1: kernel's gp
* - r3: preserved (same as on entry)
* - r8: -EINVAL if p10 is true
* - r12: points to kernel stack
* - r13: points to current task
* - r14: preserved (same as on entry)
* - p13: preserved
* - p15: TRUE if interrupts need to be re-enabled
* - ar.fpsr: set to kernel settings
* - b6: preserved (same as on entry)
*/
GLOBAL_ENTRY(ia64_syscall_setup)
#if PT(B6) != 0
# error This code assumes that b6 is the first field in pt_regs.
#endif
st8 [r1]=r19 // save b6
add r16=PT(CR_IPSR),r1 // initialize first base pointer
add r17=PT(R11),r1 // initialize second base pointer
;;
alloc r19=ar.pfs,8,0,0,0 // ensure in0-in7 are writable
st8 [r16]=r29,PT(AR_PFS)-PT(CR_IPSR) // save cr.ipsr
tnat.nz p8,p0=in0
st8.spill [r17]=r11,PT(CR_IIP)-PT(R11) // save r11
tnat.nz p9,p0=in1
(pKStk) mov r18=r0 // make sure r18 isn't NaT
;;
st8 [r16]=r26,PT(CR_IFS)-PT(AR_PFS) // save ar.pfs
st8 [r17]=r28,PT(AR_UNAT)-PT(CR_IIP) // save cr.iip
mov r28=b0 // save b0 (2 cyc)
;;
st8 [r17]=r25,PT(AR_RSC)-PT(AR_UNAT) // save ar.unat
dep r19=0,r19,38,26 // clear all bits but 0..37 [I0]
(p8) mov in0=-1
;;
st8 [r16]=r19,PT(AR_RNAT)-PT(CR_IFS) // store ar.pfs.pfm in cr.ifs
extr.u r11=r19,7,7 // I0 // get sol of ar.pfs
and r8=0x7f,r19 // A // get sof of ar.pfs
st8 [r17]=r27,PT(AR_BSPSTORE)-PT(AR_RSC)// save ar.rsc
tbit.nz p15,p0=r29,IA64_PSR_I_BIT // I0
(p9) mov in1=-1
;;
(pUStk) sub r18=r18,r22 // r18=RSE.ndirty*8
tnat.nz p10,p0=in2
add r11=8,r11
;;
(pKStk) adds r16=PT(PR)-PT(AR_RNAT),r16 // skip over ar_rnat field
(pKStk) adds r17=PT(B0)-PT(AR_BSPSTORE),r17 // skip over ar_bspstore field
tnat.nz p11,p0=in3
;;
(p10) mov in2=-1
tnat.nz p12,p0=in4 // [I0]
(p11) mov in3=-1
;;
(pUStk) st8 [r16]=r24,PT(PR)-PT(AR_RNAT) // save ar.rnat
(pUStk) st8 [r17]=r23,PT(B0)-PT(AR_BSPSTORE) // save ar.bspstore
shl r18=r18,16 // compute ar.rsc to be used for "loadrs"
;;
st8 [r16]=r31,PT(LOADRS)-PT(PR) // save predicates
st8 [r17]=r28,PT(R1)-PT(B0) // save b0
tnat.nz p13,p0=in5 // [I0]
;;
st8 [r16]=r18,PT(R12)-PT(LOADRS) // save ar.rsc value for "loadrs"
st8.spill [r17]=r20,PT(R13)-PT(R1) // save original r1
(p12) mov in4=-1
;;
.mem.offset 0,0; st8.spill [r16]=r12,PT(AR_FPSR)-PT(R12) // save r12
.mem.offset 8,0; st8.spill [r17]=r13,PT(R15)-PT(R13) // save r13
(p13) mov in5=-1
;;
st8 [r16]=r21,PT(R8)-PT(AR_FPSR) // save ar.fpsr
tnat.nz p13,p0=in6
cmp.lt p10,p9=r11,r8 // frame size can't be more than local+8
;;
mov r8=1
(p9) tnat.nz p10,p0=r15
adds r12=-16,r1 // switch to kernel memory stack (with 16 bytes of scratch)
st8.spill [r17]=r15 // save r15
tnat.nz p8,p0=in7
nop.i 0
mov r13=r2 // establish `current'
movl r1=__gp // establish kernel global pointer
;;
st8 [r16]=r8 // ensure pt_regs.r8 != 0 (see handle_syscall_error)
(p13) mov in6=-1
(p8) mov in7=-1
cmp.eq pSys,pNonSys=r0,r0 // set pSys=1, pNonSys=0
movl r17=FPSR_DEFAULT
;;
mov.m ar.fpsr=r17 // set ar.fpsr to kernel default value
(p10) mov r8=-EINVAL
br.ret.sptk.many b7
END(ia64_syscall_setup)
.org ia64_ivt+0x3c00
/////////////////////////////////////////////////////////////////////////////////////////
// 0x3c00 Entry 15 (size 64 bundles) Reserved
DBG_FAULT(15)
FAULT(15)
.org ia64_ivt+0x4000
/////////////////////////////////////////////////////////////////////////////////////////
// 0x4000 Entry 16 (size 64 bundles) Reserved
DBG_FAULT(16)
FAULT(16)
#if defined(CONFIG_VIRT_CPU_ACCOUNTING_NATIVE)
/*
* There is no particular reason for this code to be here, other than
* that there happens to be space here that would go unused otherwise.
* If this fault ever gets "unreserved", simply moved the following
* code to a more suitable spot...
*
* account_sys_enter is called from SAVE_MIN* macros if accounting is
* enabled and if the macro is entered from user mode.
*/
GLOBAL_ENTRY(account_sys_enter)
// mov.m r20=ar.itc is called in advance, and r13 is current
add r16=TI_AC_STAMP+IA64_TASK_SIZE,r13
add r17=TI_AC_LEAVE+IA64_TASK_SIZE,r13
;;
ld8 r18=[r16],TI_AC_STIME-TI_AC_STAMP // time at last check in kernel
ld8 r19=[r17],TI_AC_UTIME-TI_AC_LEAVE // time at left from kernel
;;
ld8 r23=[r16],TI_AC_STAMP-TI_AC_STIME // cumulated stime
ld8 r21=[r17] // cumulated utime
sub r22=r19,r18 // stime before leave kernel
;;
st8 [r16]=r20,TI_AC_STIME-TI_AC_STAMP // update stamp
sub r18=r20,r19 // elapsed time in user mode
;;
add r23=r23,r22 // sum stime
add r21=r21,r18 // sum utime
;;
st8 [r16]=r23 // update stime
st8 [r17]=r21 // update utime
;;
br.ret.sptk.many rp
END(account_sys_enter)
#endif
.org ia64_ivt+0x4400
/////////////////////////////////////////////////////////////////////////////////////////
// 0x4400 Entry 17 (size 64 bundles) Reserved
DBG_FAULT(17)
FAULT(17)
.org ia64_ivt+0x4800
/////////////////////////////////////////////////////////////////////////////////////////
// 0x4800 Entry 18 (size 64 bundles) Reserved
DBG_FAULT(18)
FAULT(18)
.org ia64_ivt+0x4c00
/////////////////////////////////////////////////////////////////////////////////////////
// 0x4c00 Entry 19 (size 64 bundles) Reserved
DBG_FAULT(19)
FAULT(19)
//
// --- End of long entries, Beginning of short entries
//
.org ia64_ivt+0x5000
/////////////////////////////////////////////////////////////////////////////////////////
// 0x5000 Entry 20 (size 16 bundles) Page Not Present (10,22,49)
ENTRY(page_not_present)
DBG_FAULT(20)
MOV_FROM_IFA(r16)
RSM_PSR_DT
/*
* The Linux page fault handler doesn't expect non-present pages to be in
* the TLB. Flush the existing entry now, so we meet that expectation.
*/
mov r17=PAGE_SHIFT<<2
;;
ptc.l r16,r17
;;
mov r31=pr
srlz.d
br.sptk.many page_fault
END(page_not_present)
.org ia64_ivt+0x5100
/////////////////////////////////////////////////////////////////////////////////////////
// 0x5100 Entry 21 (size 16 bundles) Key Permission (13,25,52)
ENTRY(key_permission)
DBG_FAULT(21)
MOV_FROM_IFA(r16)
RSM_PSR_DT
mov r31=pr
;;
srlz.d
br.sptk.many page_fault
END(key_permission)
.org ia64_ivt+0x5200
/////////////////////////////////////////////////////////////////////////////////////////
// 0x5200 Entry 22 (size 16 bundles) Instruction Access Rights (26)
ENTRY(iaccess_rights)
DBG_FAULT(22)
MOV_FROM_IFA(r16)
RSM_PSR_DT
mov r31=pr
;;
srlz.d
br.sptk.many page_fault
END(iaccess_rights)
.org ia64_ivt+0x5300
/////////////////////////////////////////////////////////////////////////////////////////
// 0x5300 Entry 23 (size 16 bundles) Data Access Rights (14,53)
ENTRY(daccess_rights)
DBG_FAULT(23)
MOV_FROM_IFA(r16)
RSM_PSR_DT
mov r31=pr
;;
srlz.d
br.sptk.many page_fault
END(daccess_rights)
.org ia64_ivt+0x5400
/////////////////////////////////////////////////////////////////////////////////////////
// 0x5400 Entry 24 (size 16 bundles) General Exception (5,32,34,36,38,39)
ENTRY(general_exception)
DBG_FAULT(24)
MOV_FROM_ISR(r16)
mov r31=pr
;;
cmp4.eq p6,p0=0,r16
(p6) br.sptk.many dispatch_illegal_op_fault
;;
mov r19=24 // fault number
br.sptk.many dispatch_to_fault_handler
END(general_exception)
.org ia64_ivt+0x5500
/////////////////////////////////////////////////////////////////////////////////////////
// 0x5500 Entry 25 (size 16 bundles) Disabled FP-Register (35)
ENTRY(disabled_fp_reg)
DBG_FAULT(25)
rsm psr.dfh // ensure we can access fph
;;
srlz.d
mov r31=pr
mov r19=25
br.sptk.many dispatch_to_fault_handler
END(disabled_fp_reg)
.org ia64_ivt+0x5600
/////////////////////////////////////////////////////////////////////////////////////////
// 0x5600 Entry 26 (size 16 bundles) Nat Consumption (11,23,37,50)
ENTRY(nat_consumption)
DBG_FAULT(26)
MOV_FROM_IPSR(p0, r16)
MOV_FROM_ISR(r17)
mov r31=pr // save PR
;;
and r18=0xf,r17 // r18 = cr.ipsr.code{3:0}
tbit.z p6,p0=r17,IA64_ISR_NA_BIT
;;
cmp.ne.or p6,p0=IA64_ISR_CODE_LFETCH,r18
dep r16=-1,r16,IA64_PSR_ED_BIT,1
(p6) br.cond.spnt 1f // branch if (cr.ispr.na == 0 || cr.ipsr.code{3:0} != LFETCH)
;;
MOV_TO_IPSR(p0, r16, r18)
mov pr=r31,-1
;;
RFI
1: mov pr=r31,-1
;;
FAULT(26)
END(nat_consumption)
.org ia64_ivt+0x5700
/////////////////////////////////////////////////////////////////////////////////////////
// 0x5700 Entry 27 (size 16 bundles) Speculation (40)
ENTRY(speculation_vector)
DBG_FAULT(27)
/*
* A [f]chk.[as] instruction needs to take the branch to the recovery code but
* this part of the architecture is not implemented in hardware on some CPUs, such
* as Itanium. Thus, in general we need to emulate the behavior. IIM contains
* the relative target (not yet sign extended). So after sign extending it we
* simply add it to IIP. We also need to reset the EI field of the IPSR to zero,
* i.e., the slot to restart into.
*
* cr.imm contains zero_ext(imm21)
*/
MOV_FROM_IIM(r18)
;;
MOV_FROM_IIP(r17)
shl r18=r18,43 // put sign bit in position (43=64-21)
;;
MOV_FROM_IPSR(p0, r16)
shr r18=r18,39 // sign extend (39=43-4)
;;
add r17=r17,r18 // now add the offset
;;
MOV_TO_IIP(r17, r19)
dep r16=0,r16,41,2 // clear EI
;;
MOV_TO_IPSR(p0, r16, r19)
;;
RFI
END(speculation_vector)
.org ia64_ivt+0x5800
/////////////////////////////////////////////////////////////////////////////////////////
// 0x5800 Entry 28 (size 16 bundles) Reserved
DBG_FAULT(28)
FAULT(28)
.org ia64_ivt+0x5900
/////////////////////////////////////////////////////////////////////////////////////////
// 0x5900 Entry 29 (size 16 bundles) Debug (16,28,56)
ENTRY(debug_vector)
DBG_FAULT(29)
FAULT(29)
END(debug_vector)
.org ia64_ivt+0x5a00
/////////////////////////////////////////////////////////////////////////////////////////
// 0x5a00 Entry 30 (size 16 bundles) Unaligned Reference (57)
ENTRY(unaligned_access)
DBG_FAULT(30)
mov r31=pr // prepare to save predicates
;;
br.sptk.many dispatch_unaligned_handler
END(unaligned_access)
.org ia64_ivt+0x5b00
/////////////////////////////////////////////////////////////////////////////////////////
// 0x5b00 Entry 31 (size 16 bundles) Unsupported Data Reference (57)
ENTRY(unsupported_data_reference)
DBG_FAULT(31)
FAULT(31)
END(unsupported_data_reference)
.org ia64_ivt+0x5c00
/////////////////////////////////////////////////////////////////////////////////////////
// 0x5c00 Entry 32 (size 16 bundles) Floating-Point Fault (64)
ENTRY(floating_point_fault)
DBG_FAULT(32)
FAULT(32)
END(floating_point_fault)
.org ia64_ivt+0x5d00
/////////////////////////////////////////////////////////////////////////////////////////
// 0x5d00 Entry 33 (size 16 bundles) Floating Point Trap (66)
ENTRY(floating_point_trap)
DBG_FAULT(33)
FAULT(33)
END(floating_point_trap)
.org ia64_ivt+0x5e00
/////////////////////////////////////////////////////////////////////////////////////////
// 0x5e00 Entry 34 (size 16 bundles) Lower Privilege Transfer Trap (66)
ENTRY(lower_privilege_trap)
DBG_FAULT(34)
FAULT(34)
END(lower_privilege_trap)
.org ia64_ivt+0x5f00
/////////////////////////////////////////////////////////////////////////////////////////
// 0x5f00 Entry 35 (size 16 bundles) Taken Branch Trap (68)
ENTRY(taken_branch_trap)
DBG_FAULT(35)
FAULT(35)
END(taken_branch_trap)
.org ia64_ivt+0x6000
/////////////////////////////////////////////////////////////////////////////////////////
// 0x6000 Entry 36 (size 16 bundles) Single Step Trap (69)
ENTRY(single_step_trap)
DBG_FAULT(36)
FAULT(36)
END(single_step_trap)
.org ia64_ivt+0x6100
/////////////////////////////////////////////////////////////////////////////////////////
// 0x6100 Entry 37 (size 16 bundles) Reserved
DBG_FAULT(37)
FAULT(37)
.org ia64_ivt+0x6200
/////////////////////////////////////////////////////////////////////////////////////////
// 0x6200 Entry 38 (size 16 bundles) Reserved
DBG_FAULT(38)
FAULT(38)
.org ia64_ivt+0x6300
/////////////////////////////////////////////////////////////////////////////////////////
// 0x6300 Entry 39 (size 16 bundles) Reserved
DBG_FAULT(39)
FAULT(39)
.org ia64_ivt+0x6400
/////////////////////////////////////////////////////////////////////////////////////////
// 0x6400 Entry 40 (size 16 bundles) Reserved
DBG_FAULT(40)
FAULT(40)
.org ia64_ivt+0x6500
/////////////////////////////////////////////////////////////////////////////////////////
// 0x6500 Entry 41 (size 16 bundles) Reserved
DBG_FAULT(41)
FAULT(41)
.org ia64_ivt+0x6600
/////////////////////////////////////////////////////////////////////////////////////////
// 0x6600 Entry 42 (size 16 bundles) Reserved
DBG_FAULT(42)
FAULT(42)
.org ia64_ivt+0x6700
/////////////////////////////////////////////////////////////////////////////////////////
// 0x6700 Entry 43 (size 16 bundles) Reserved
DBG_FAULT(43)
FAULT(43)
.org ia64_ivt+0x6800
/////////////////////////////////////////////////////////////////////////////////////////
// 0x6800 Entry 44 (size 16 bundles) Reserved
DBG_FAULT(44)
FAULT(44)
.org ia64_ivt+0x6900
/////////////////////////////////////////////////////////////////////////////////////////
// 0x6900 Entry 45 (size 16 bundles) IA-32 Exeception (17,18,29,41,42,43,44,58,60,61,62,72,73,75,76,77)
ENTRY(ia32_exception)
DBG_FAULT(45)
FAULT(45)
END(ia32_exception)
.org ia64_ivt+0x6a00
/////////////////////////////////////////////////////////////////////////////////////////
// 0x6a00 Entry 46 (size 16 bundles) IA-32 Intercept (30,31,59,70,71)
ENTRY(ia32_intercept)
DBG_FAULT(46)
FAULT(46)
END(ia32_intercept)
.org ia64_ivt+0x6b00
/////////////////////////////////////////////////////////////////////////////////////////
// 0x6b00 Entry 47 (size 16 bundles) IA-32 Interrupt (74)
ENTRY(ia32_interrupt)
DBG_FAULT(47)
FAULT(47)
END(ia32_interrupt)
.org ia64_ivt+0x6c00
/////////////////////////////////////////////////////////////////////////////////////////
// 0x6c00 Entry 48 (size 16 bundles) Reserved
DBG_FAULT(48)
FAULT(48)
.org ia64_ivt+0x6d00
/////////////////////////////////////////////////////////////////////////////////////////
// 0x6d00 Entry 49 (size 16 bundles) Reserved
DBG_FAULT(49)
FAULT(49)
.org ia64_ivt+0x6e00
/////////////////////////////////////////////////////////////////////////////////////////
// 0x6e00 Entry 50 (size 16 bundles) Reserved
DBG_FAULT(50)
FAULT(50)
.org ia64_ivt+0x6f00
/////////////////////////////////////////////////////////////////////////////////////////
// 0x6f00 Entry 51 (size 16 bundles) Reserved
DBG_FAULT(51)
FAULT(51)
.org ia64_ivt+0x7000
/////////////////////////////////////////////////////////////////////////////////////////
// 0x7000 Entry 52 (size 16 bundles) Reserved
DBG_FAULT(52)
FAULT(52)
.org ia64_ivt+0x7100
/////////////////////////////////////////////////////////////////////////////////////////
// 0x7100 Entry 53 (size 16 bundles) Reserved
DBG_FAULT(53)
FAULT(53)
.org ia64_ivt+0x7200
/////////////////////////////////////////////////////////////////////////////////////////
// 0x7200 Entry 54 (size 16 bundles) Reserved
DBG_FAULT(54)
FAULT(54)
.org ia64_ivt+0x7300
/////////////////////////////////////////////////////////////////////////////////////////
// 0x7300 Entry 55 (size 16 bundles) Reserved
DBG_FAULT(55)
FAULT(55)
.org ia64_ivt+0x7400
/////////////////////////////////////////////////////////////////////////////////////////
// 0x7400 Entry 56 (size 16 bundles) Reserved
DBG_FAULT(56)
FAULT(56)
.org ia64_ivt+0x7500
/////////////////////////////////////////////////////////////////////////////////////////
// 0x7500 Entry 57 (size 16 bundles) Reserved
DBG_FAULT(57)
FAULT(57)
.org ia64_ivt+0x7600
/////////////////////////////////////////////////////////////////////////////////////////
// 0x7600 Entry 58 (size 16 bundles) Reserved
DBG_FAULT(58)
FAULT(58)
.org ia64_ivt+0x7700
/////////////////////////////////////////////////////////////////////////////////////////
// 0x7700 Entry 59 (size 16 bundles) Reserved
DBG_FAULT(59)
FAULT(59)
.org ia64_ivt+0x7800
/////////////////////////////////////////////////////////////////////////////////////////
// 0x7800 Entry 60 (size 16 bundles) Reserved
DBG_FAULT(60)
FAULT(60)
.org ia64_ivt+0x7900
/////////////////////////////////////////////////////////////////////////////////////////
// 0x7900 Entry 61 (size 16 bundles) Reserved
DBG_FAULT(61)
FAULT(61)
.org ia64_ivt+0x7a00
/////////////////////////////////////////////////////////////////////////////////////////
// 0x7a00 Entry 62 (size 16 bundles) Reserved
DBG_FAULT(62)
FAULT(62)
.org ia64_ivt+0x7b00
/////////////////////////////////////////////////////////////////////////////////////////
// 0x7b00 Entry 63 (size 16 bundles) Reserved
DBG_FAULT(63)
FAULT(63)
.org ia64_ivt+0x7c00
/////////////////////////////////////////////////////////////////////////////////////////
// 0x7c00 Entry 64 (size 16 bundles) Reserved
DBG_FAULT(64)
FAULT(64)
.org ia64_ivt+0x7d00
/////////////////////////////////////////////////////////////////////////////////////////
// 0x7d00 Entry 65 (size 16 bundles) Reserved
DBG_FAULT(65)
FAULT(65)
.org ia64_ivt+0x7e00
/////////////////////////////////////////////////////////////////////////////////////////
// 0x7e00 Entry 66 (size 16 bundles) Reserved
DBG_FAULT(66)
FAULT(66)
.org ia64_ivt+0x7f00
/////////////////////////////////////////////////////////////////////////////////////////
// 0x7f00 Entry 67 (size 16 bundles) Reserved
DBG_FAULT(67)
FAULT(67)
//-----------------------------------------------------------------------------------
// call do_page_fault (predicates are in r31, psr.dt may be off, r16 is faulting address)
ENTRY(page_fault)
SSM_PSR_DT_AND_SRLZ_I
;;
SAVE_MIN_WITH_COVER
alloc r15=ar.pfs,0,0,3,0
MOV_FROM_IFA(out0)
MOV_FROM_ISR(out1)
SSM_PSR_IC_AND_DEFAULT_BITS_AND_SRLZ_I(r14, r3)
adds r3=8,r2 // set up second base pointer
SSM_PSR_I(p15, p15, r14) // restore psr.i
movl r14=ia64_leave_kernel
;;
SAVE_REST
mov rp=r14
;;
adds out2=16,r12 // out2 = pointer to pt_regs
br.call.sptk.many b6=ia64_do_page_fault // ignore return address
END(page_fault)
ENTRY(non_syscall)
mov ar.rsc=r27 // restore ar.rsc before SAVE_MIN_WITH_COVER
;;
SAVE_MIN_WITH_COVER
// There is no particular reason for this code to be here, other than that
// there happens to be space here that would go unused otherwise. If this
// fault ever gets "unreserved", simply moved the following code to a more
// suitable spot...
alloc r14=ar.pfs,0,0,2,0
MOV_FROM_IIM(out0)
add out1=16,sp
adds r3=8,r2 // set up second base pointer for SAVE_REST
SSM_PSR_IC_AND_DEFAULT_BITS_AND_SRLZ_I(r15, r24)
// guarantee that interruption collection is on
SSM_PSR_I(p15, p15, r15) // restore psr.i
movl r15=ia64_leave_kernel
;;
SAVE_REST
mov rp=r15
;;
br.call.sptk.many b6=ia64_bad_break // avoid WAW on CFM and ignore return addr
END(non_syscall)
ENTRY(__interrupt)
DBG_FAULT(12)
mov r31=pr // prepare to save predicates
;;
SAVE_MIN_WITH_COVER // uses r31; defines r2 and r3
SSM_PSR_IC_AND_DEFAULT_BITS_AND_SRLZ_I(r3, r14)
// ensure everybody knows psr.ic is back on
adds r3=8,r2 // set up second base pointer for SAVE_REST
;;
SAVE_REST
;;
MCA_RECOVER_RANGE(interrupt)
alloc r14=ar.pfs,0,0,2,0 // must be first in an insn group
MOV_FROM_IVR(out0, r8) // pass cr.ivr as first arg
add out1=16,sp // pass pointer to pt_regs as second arg
;;
srlz.d // make sure we see the effect of cr.ivr
movl r14=ia64_leave_kernel
;;
mov rp=r14
br.call.sptk.many b6=ia64_handle_irq
END(__interrupt)
/*
* There is no particular reason for this code to be here, other than that
* there happens to be space here that would go unused otherwise. If this
* fault ever gets "unreserved", simply moved the following code to a more
* suitable spot...
*/
ENTRY(dispatch_unaligned_handler)
SAVE_MIN_WITH_COVER
;;
alloc r14=ar.pfs,0,0,2,0 // now it's safe (must be first in insn group!)
MOV_FROM_IFA(out0)
adds out1=16,sp
SSM_PSR_IC_AND_DEFAULT_BITS_AND_SRLZ_I(r3, r24)
// guarantee that interruption collection is on
SSM_PSR_I(p15, p15, r3) // restore psr.i
adds r3=8,r2 // set up second base pointer
;;
SAVE_REST
movl r14=ia64_leave_kernel
;;
mov rp=r14
br.sptk.many ia64_prepare_handle_unaligned
END(dispatch_unaligned_handler)
/*
* There is no particular reason for this code to be here, other than that
* there happens to be space here that would go unused otherwise. If this
* fault ever gets "unreserved", simply moved the following code to a more
* suitable spot...
*/
ENTRY(dispatch_to_fault_handler)
/*
* Input:
* psr.ic: off
* r19: fault vector number (e.g., 24 for General Exception)
* r31: contains saved predicates (pr)
*/
SAVE_MIN_WITH_COVER_R19
alloc r14=ar.pfs,0,0,5,0
MOV_FROM_ISR(out1)
MOV_FROM_IFA(out2)
MOV_FROM_IIM(out3)
MOV_FROM_ITIR(out4)
;;
SSM_PSR_IC_AND_DEFAULT_BITS_AND_SRLZ_I(r3, out0)
// guarantee that interruption collection is on
mov out0=r15
;;
SSM_PSR_I(p15, p15, r3) // restore psr.i
adds r3=8,r2 // set up second base pointer for SAVE_REST
;;
SAVE_REST
movl r14=ia64_leave_kernel
;;
mov rp=r14
br.call.sptk.many b6=ia64_fault
END(dispatch_to_fault_handler)
[IA64] Workaround for RSE issue Problem: An application violating the architectural rules regarding operation dependencies and having specific Register Stack Engine (RSE) state at the time of the violation, may result in an illegal operation fault and invalid RSE state. Such faults may initiate a cascade of repeated illegal operation faults within OS interruption handlers. The specific behavior is OS dependent. Implication: An application causing an illegal operation fault with specific RSE state may result in a series of illegal operation faults and an eventual OS stack overflow condition. Workaround: OS interruption handlers that switch to kernel backing store implement a check for invalid RSE state to avoid the series of illegal operation faults. The core of the workaround is the RSE_WORKAROUND code sequence inserted into each invocation of the SAVE_MIN_WITH_COVER and SAVE_MIN_WITH_COVER_R19 macros. This sequence includes hard-coded constants that depend on the number of stacked physical registers being 96. The rest of this patch consists of code to disable this workaround should this not be the case (with the presumption that if a future Itanium processor increases the number of registers, it would also remove the need for this patch). Move the start of the RBS up to a mod32 boundary to avoid some corner cases. The dispatch_illegal_op_fault code outgrew the spot it was squatting in when built with this patch and CONFIG_VIRT_CPU_ACCOUNTING=y Move it out to the end of the ivt. Signed-off-by: Tony Luck <tony.luck@intel.com>
2008-05-28 04:23:16 +08:00
/*
* Squatting in this space ...
*
* This special case dispatcher for illegal operation faults allows preserved
* registers to be modified through a callback function (asm only) that is handed
* back from the fault handler in r8. Up to three arguments can be passed to the
* callback function by returning an aggregate with the callback as its first
* element, followed by the arguments.
*/
ENTRY(dispatch_illegal_op_fault)
.prologue
.body
SAVE_MIN_WITH_COVER
SSM_PSR_IC_AND_DEFAULT_BITS_AND_SRLZ_I(r3, r24)
// guarantee that interruption collection is on
[IA64] Workaround for RSE issue Problem: An application violating the architectural rules regarding operation dependencies and having specific Register Stack Engine (RSE) state at the time of the violation, may result in an illegal operation fault and invalid RSE state. Such faults may initiate a cascade of repeated illegal operation faults within OS interruption handlers. The specific behavior is OS dependent. Implication: An application causing an illegal operation fault with specific RSE state may result in a series of illegal operation faults and an eventual OS stack overflow condition. Workaround: OS interruption handlers that switch to kernel backing store implement a check for invalid RSE state to avoid the series of illegal operation faults. The core of the workaround is the RSE_WORKAROUND code sequence inserted into each invocation of the SAVE_MIN_WITH_COVER and SAVE_MIN_WITH_COVER_R19 macros. This sequence includes hard-coded constants that depend on the number of stacked physical registers being 96. The rest of this patch consists of code to disable this workaround should this not be the case (with the presumption that if a future Itanium processor increases the number of registers, it would also remove the need for this patch). Move the start of the RBS up to a mod32 boundary to avoid some corner cases. The dispatch_illegal_op_fault code outgrew the spot it was squatting in when built with this patch and CONFIG_VIRT_CPU_ACCOUNTING=y Move it out to the end of the ivt. Signed-off-by: Tony Luck <tony.luck@intel.com>
2008-05-28 04:23:16 +08:00
;;
SSM_PSR_I(p15, p15, r3) // restore psr.i
[IA64] Workaround for RSE issue Problem: An application violating the architectural rules regarding operation dependencies and having specific Register Stack Engine (RSE) state at the time of the violation, may result in an illegal operation fault and invalid RSE state. Such faults may initiate a cascade of repeated illegal operation faults within OS interruption handlers. The specific behavior is OS dependent. Implication: An application causing an illegal operation fault with specific RSE state may result in a series of illegal operation faults and an eventual OS stack overflow condition. Workaround: OS interruption handlers that switch to kernel backing store implement a check for invalid RSE state to avoid the series of illegal operation faults. The core of the workaround is the RSE_WORKAROUND code sequence inserted into each invocation of the SAVE_MIN_WITH_COVER and SAVE_MIN_WITH_COVER_R19 macros. This sequence includes hard-coded constants that depend on the number of stacked physical registers being 96. The rest of this patch consists of code to disable this workaround should this not be the case (with the presumption that if a future Itanium processor increases the number of registers, it would also remove the need for this patch). Move the start of the RBS up to a mod32 boundary to avoid some corner cases. The dispatch_illegal_op_fault code outgrew the spot it was squatting in when built with this patch and CONFIG_VIRT_CPU_ACCOUNTING=y Move it out to the end of the ivt. Signed-off-by: Tony Luck <tony.luck@intel.com>
2008-05-28 04:23:16 +08:00
adds r3=8,r2 // set up second base pointer for SAVE_REST
;;
alloc r14=ar.pfs,0,0,1,0 // must be first in insn group
mov out0=ar.ec
;;
SAVE_REST
PT_REGS_UNWIND_INFO(0)
;;
br.call.sptk.many rp=ia64_illegal_op_fault
.ret0: ;;
alloc r14=ar.pfs,0,0,3,0 // must be first in insn group
mov out0=r9
mov out1=r10
mov out2=r11
movl r15=ia64_leave_kernel
;;
mov rp=r15
mov b6=r8
;;
cmp.ne p6,p0=0,r8
(p6) br.call.dpnt.many b6=b6 // call returns to ia64_leave_kernel
br.sptk.many ia64_leave_kernel
END(dispatch_illegal_op_fault)