WSL2-Linux-Kernel/arch/powerpc/mm/slb.c

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/*
* PowerPC64 SLB support.
*
* Copyright (C) 2004 David Gibson <dwg@au.ibm.com>, IBM
* Based on earlier code written by:
* Dave Engebretsen and Mike Corrigan {engebret|mikejc}@us.ibm.com
* Copyright (c) 2001 Dave Engebretsen
* Copyright (C) 2002 Anton Blanchard <anton@au.ibm.com>, IBM
*
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version
* 2 of the License, or (at your option) any later version.
*/
#include <asm/asm-prototypes.h>
#include <asm/pgtable.h>
#include <asm/mmu.h>
#include <asm/mmu_context.h>
#include <asm/paca.h>
#include <asm/cputable.h>
#include <asm/cacheflush.h>
#include <asm/smp.h>
#include <linux/compiler.h>
#include <linux/context_tracking.h>
#include <linux/mm_types.h>
#include <asm/udbg.h>
#include <asm/code-patching.h>
enum slb_index {
LINEAR_INDEX = 0, /* Kernel linear map (0xc000000000000000) */
KSTACK_INDEX = 1, /* Kernel stack map */
};
static long slb_allocate_user(struct mm_struct *mm, unsigned long ea);
[POWERPC] Bolt in SLB entry for kernel stack on secondary cpus This fixes a regression reported by Kamalesh Bulabel where a POWER4 machine would crash because of an SLB miss at a point where the SLB miss exception was unrecoverable. This regression is tracked at: http://bugzilla.kernel.org/show_bug.cgi?id=10082 SLB misses at such points shouldn't happen because the kernel stack is the only memory accessed other than things in the first segment of the linear mapping (which is mapped at all times by entry 0 of the SLB). The context switch code ensures that SLB entry 2 covers the kernel stack, if it is not already covered by entry 0. None of entries 0 to 2 are ever replaced by the SLB miss handler. Where this went wrong is that the context switch code assumes it doesn't have to write to SLB entry 2 if the new kernel stack is in the same segment as the old kernel stack, since entry 2 should already be correct. However, when we start up a secondary cpu, it calls slb_initialize, which doesn't set up entry 2. This is correct for the boot cpu, where we will be using a stack in the kernel BSS at this point (i.e. init_thread_union), but not necessarily for secondary cpus, whose initial stack can be allocated anywhere. This doesn't cause any immediate problem since the SLB miss handler will just create an SLB entry somewhere else to cover the initial stack. In fact it's possible for the cpu to go quite a long time without SLB entry 2 being valid. Eventually, though, the entry created by the SLB miss handler will get overwritten by some other entry, and if the next access to the stack is at an unrecoverable point, we get the crash. This fixes the problem by making slb_initialize create a suitable entry for the kernel stack, if we are on a secondary cpu and the stack isn't covered by SLB entry 0. This requires initializing the get_paca()->kstack field earlier, so I do that in smp_create_idle where the current field is initialized. This also abstracts a bit of the computation that mk_esid_data in slb.c does so that it can be used in slb_initialize. Signed-off-by: Paul Mackerras <paulus@samba.org>
2008-05-02 08:29:12 +04:00
#define slb_esid_mask(ssize) \
(((ssize) == MMU_SEGSIZE_256M)? ESID_MASK: ESID_MASK_1T)
static inline unsigned long mk_esid_data(unsigned long ea, int ssize,
enum slb_index index)
{
return (ea & slb_esid_mask(ssize)) | SLB_ESID_V | index;
}
static inline unsigned long __mk_vsid_data(unsigned long vsid, int ssize,
powerpc/64s/hash: convert SLB miss handlers to C This patch moves SLB miss handlers completely to C, using the standard exception handler macros to set up the stack and branch to C. This can be done because the segment containing the kernel stack is always bolted, so accessing it with relocation on will not cause an SLB exception. Arbitrary kernel memory may not be accessed when handling kernel space SLB misses, so care should be taken there. However user SLB misses can access any kernel memory, which can be used to move some fields out of the paca (in later patches). User SLB misses could quite easily reconcile IRQs and set up a first class kernel environment and exit via ret_from_except, however that doesn't seem to be necessary at the moment, so we only do that if a bad fault is encountered. [ Credit to Aneesh for bug fixes, error checks, and improvements to bad address handling, etc ] Signed-off-by: Nicholas Piggin <npiggin@gmail.com> Since RFC: - Added MSR[RI] handling - Fixed up a register loss bug exposed by irq tracing (Aneesh) - Reject misses outside the defined kernel regions (Aneesh) - Added several more sanity checks and error handling (Aneesh), we may look at consolidating these tests and tightenig up the code but for a first pass we decided it's better to check carefully. Since v1: - Fixed SLB cache corruption (Aneesh) - Fixed untidy SLBE allocation "leak" in get_vsid error case - Now survives some stress testing on real hardware Signed-off-by: Michael Ellerman <mpe@ellerman.id.au>
2018-09-14 18:30:51 +03:00
unsigned long flags)
{
return (vsid << slb_vsid_shift(ssize)) | flags |
((unsigned long) ssize << SLB_VSID_SSIZE_SHIFT);
powerpc/64s/hash: convert SLB miss handlers to C This patch moves SLB miss handlers completely to C, using the standard exception handler macros to set up the stack and branch to C. This can be done because the segment containing the kernel stack is always bolted, so accessing it with relocation on will not cause an SLB exception. Arbitrary kernel memory may not be accessed when handling kernel space SLB misses, so care should be taken there. However user SLB misses can access any kernel memory, which can be used to move some fields out of the paca (in later patches). User SLB misses could quite easily reconcile IRQs and set up a first class kernel environment and exit via ret_from_except, however that doesn't seem to be necessary at the moment, so we only do that if a bad fault is encountered. [ Credit to Aneesh for bug fixes, error checks, and improvements to bad address handling, etc ] Signed-off-by: Nicholas Piggin <npiggin@gmail.com> Since RFC: - Added MSR[RI] handling - Fixed up a register loss bug exposed by irq tracing (Aneesh) - Reject misses outside the defined kernel regions (Aneesh) - Added several more sanity checks and error handling (Aneesh), we may look at consolidating these tests and tightenig up the code but for a first pass we decided it's better to check carefully. Since v1: - Fixed SLB cache corruption (Aneesh) - Fixed untidy SLBE allocation "leak" in get_vsid error case - Now survives some stress testing on real hardware Signed-off-by: Michael Ellerman <mpe@ellerman.id.au>
2018-09-14 18:30:51 +03:00
}
static inline unsigned long mk_vsid_data(unsigned long ea, int ssize,
unsigned long flags)
{
return __mk_vsid_data(get_kernel_vsid(ea, ssize), ssize, flags);
}
static void assert_slb_exists(unsigned long ea)
{
#ifdef CONFIG_DEBUG_VM
unsigned long tmp;
WARN_ON_ONCE(mfmsr() & MSR_EE);
asm volatile("slbfee. %0, %1" : "=r"(tmp) : "r"(ea) : "cr0");
WARN_ON(tmp == 0);
#endif
}
static void assert_slb_notexists(unsigned long ea)
{
#ifdef CONFIG_DEBUG_VM
unsigned long tmp;
WARN_ON_ONCE(mfmsr() & MSR_EE);
asm volatile("slbfee. %0, %1" : "=r"(tmp) : "r"(ea) : "cr0");
WARN_ON(tmp != 0);
#endif
}
static inline void slb_shadow_update(unsigned long ea, int ssize,
unsigned long flags,
enum slb_index index)
{
struct slb_shadow *p = get_slb_shadow();
/*
* Clear the ESID first so the entry is not valid while we are
* updating it. No write barriers are needed here, provided
* we only update the current CPU's SLB shadow buffer.
*/
WRITE_ONCE(p->save_area[index].esid, 0);
WRITE_ONCE(p->save_area[index].vsid, cpu_to_be64(mk_vsid_data(ea, ssize, flags)));
WRITE_ONCE(p->save_area[index].esid, cpu_to_be64(mk_esid_data(ea, ssize, index)));
}
static inline void slb_shadow_clear(enum slb_index index)
{
WRITE_ONCE(get_slb_shadow()->save_area[index].esid, cpu_to_be64(index));
}
static inline void create_shadowed_slbe(unsigned long ea, int ssize,
unsigned long flags,
enum slb_index index)
{
/*
* Updating the shadow buffer before writing the SLB ensures
* we don't get a stale entry here if we get preempted by PHYP
* between these two statements.
*/
slb_shadow_update(ea, ssize, flags, index);
assert_slb_notexists(ea);
asm volatile("slbmte %0,%1" :
: "r" (mk_vsid_data(ea, ssize, flags)),
"r" (mk_esid_data(ea, ssize, index))
: "memory" );
}
/*
* Insert bolted entries into SLB (which may not be empty, so don't clear
* slb_cache_ptr).
*/
void __slb_restore_bolted_realmode(void)
{
struct slb_shadow *p = get_slb_shadow();
enum slb_index index;
/* No isync needed because realmode. */
for (index = 0; index < SLB_NUM_BOLTED; index++) {
asm volatile("slbmte %0,%1" :
: "r" (be64_to_cpu(p->save_area[index].vsid)),
"r" (be64_to_cpu(p->save_area[index].esid)));
}
assert_slb_exists(local_paca->kstack);
}
/*
* Insert the bolted entries into an empty SLB.
*/
void slb_restore_bolted_realmode(void)
{
__slb_restore_bolted_realmode();
get_paca()->slb_cache_ptr = 0;
get_paca()->slb_kern_bitmap = (1U << SLB_NUM_BOLTED) - 1;
get_paca()->slb_used_bitmap = get_paca()->slb_kern_bitmap;
}
/*
* This flushes all SLB entries including 0, so it must be realmode.
*/
void slb_flush_all_realmode(void)
{
asm volatile("slbmte %0,%0; slbia" : : "r" (0));
}
/*
* This flushes non-bolted entries, it can be run in virtual mode. Must
* be called with interrupts disabled.
*/
void slb_flush_and_restore_bolted(void)
{
struct slb_shadow *p = get_slb_shadow();
BUILD_BUG_ON(SLB_NUM_BOLTED != 2);
WARN_ON(!irqs_disabled());
/*
* We can't take a PMU exception in the following code, so hard
* disable interrupts.
*/
hard_irq_disable();
asm volatile("isync\n"
"slbia\n"
"slbmte %0, %1\n"
"isync\n"
:: "r" (be64_to_cpu(p->save_area[KSTACK_INDEX].vsid)),
"r" (be64_to_cpu(p->save_area[KSTACK_INDEX].esid))
: "memory");
assert_slb_exists(get_paca()->kstack);
powerpc: Allow perf_counters to access user memory at interrupt time This provides a mechanism to allow the perf_counters code to access user memory in a PMU interrupt routine. Such an access can cause various kinds of interrupt: SLB miss, MMU hash table miss, segment table miss, or TLB miss, depending on the processor. This commit only deals with 64-bit classic/server processors, which use an MMU hash table. 32-bit processors are already able to access user memory at interrupt time. Since we don't soft-disable on 32-bit, we avoid the possibility of reentering hash_page or the TLB miss handlers, since they run with interrupts disabled. On 64-bit processors, an SLB miss interrupt on a user address will update the slb_cache and slb_cache_ptr fields in the paca. This is OK except in the case where a PMU interrupt occurs in switch_slb, which also accesses those fields. To prevent this, we hard-disable interrupts in switch_slb. Interrupts are already soft-disabled at this point, and will get hard-enabled when they get soft-enabled later. This also reworks slb_flush_and_rebolt: to avoid hard-disabling twice, and to make sure that it clears the slb_cache_ptr when called from other callers than switch_slb, the existing routine is renamed to __slb_flush_and_rebolt, which is called by switch_slb and the new version of slb_flush_and_rebolt. Similarly, switch_stab (used on POWER3 and RS64 processors) gets a hard_irq_disable() to protect the per-cpu variables used there and in ste_allocate. If a MMU hashtable miss interrupt occurs, normally we would call hash_page to look up the Linux PTE for the address and create a HPTE. However, hash_page is fairly complex and takes some locks, so to avoid the possibility of deadlock, we check the preemption count to see if we are in a (pseudo-)NMI handler, and if so, we don't call hash_page but instead treat it like a bad access that will get reported up through the exception table mechanism. An interrupt whose handler runs even though the interrupt occurred when soft-disabled (such as the PMU interrupt) is considered a pseudo-NMI handler, which should use nmi_enter()/nmi_exit() rather than irq_enter()/irq_exit(). Acked-by: Benjamin Herrenschmidt <benh@kernel.crashing.org> Signed-off-by: Paul Mackerras <paulus@samba.org>
2009-08-17 09:17:54 +04:00
get_paca()->slb_cache_ptr = 0;
get_paca()->slb_kern_bitmap = (1U << SLB_NUM_BOLTED) - 1;
get_paca()->slb_used_bitmap = get_paca()->slb_kern_bitmap;
powerpc: Allow perf_counters to access user memory at interrupt time This provides a mechanism to allow the perf_counters code to access user memory in a PMU interrupt routine. Such an access can cause various kinds of interrupt: SLB miss, MMU hash table miss, segment table miss, or TLB miss, depending on the processor. This commit only deals with 64-bit classic/server processors, which use an MMU hash table. 32-bit processors are already able to access user memory at interrupt time. Since we don't soft-disable on 32-bit, we avoid the possibility of reentering hash_page or the TLB miss handlers, since they run with interrupts disabled. On 64-bit processors, an SLB miss interrupt on a user address will update the slb_cache and slb_cache_ptr fields in the paca. This is OK except in the case where a PMU interrupt occurs in switch_slb, which also accesses those fields. To prevent this, we hard-disable interrupts in switch_slb. Interrupts are already soft-disabled at this point, and will get hard-enabled when they get soft-enabled later. This also reworks slb_flush_and_rebolt: to avoid hard-disabling twice, and to make sure that it clears the slb_cache_ptr when called from other callers than switch_slb, the existing routine is renamed to __slb_flush_and_rebolt, which is called by switch_slb and the new version of slb_flush_and_rebolt. Similarly, switch_stab (used on POWER3 and RS64 processors) gets a hard_irq_disable() to protect the per-cpu variables used there and in ste_allocate. If a MMU hashtable miss interrupt occurs, normally we would call hash_page to look up the Linux PTE for the address and create a HPTE. However, hash_page is fairly complex and takes some locks, so to avoid the possibility of deadlock, we check the preemption count to see if we are in a (pseudo-)NMI handler, and if so, we don't call hash_page but instead treat it like a bad access that will get reported up through the exception table mechanism. An interrupt whose handler runs even though the interrupt occurred when soft-disabled (such as the PMU interrupt) is considered a pseudo-NMI handler, which should use nmi_enter()/nmi_exit() rather than irq_enter()/irq_exit(). Acked-by: Benjamin Herrenschmidt <benh@kernel.crashing.org> Signed-off-by: Paul Mackerras <paulus@samba.org>
2009-08-17 09:17:54 +04:00
}
powerpc/pseries: Dump the SLB contents on SLB MCE errors. If we get a machine check exceptions due to SLB errors then dump the current SLB contents which will be very much helpful in debugging the root cause of SLB errors. Introduce an exclusive buffer per cpu to hold faulty SLB entries. In real mode mce handler saves the old SLB contents into this buffer accessible through paca and print it out later in virtual mode. With this patch the console will log SLB contents like below on SLB MCE errors: [ 507.297236] SLB contents of cpu 0x1 [ 507.297237] Last SLB entry inserted at slot 16 [ 507.297238] 00 c000000008000000 400ea1b217000500 [ 507.297239] 1T ESID= c00000 VSID= ea1b217 LLP:100 [ 507.297240] 01 d000000008000000 400d43642f000510 [ 507.297242] 1T ESID= d00000 VSID= d43642f LLP:110 [ 507.297243] 11 f000000008000000 400a86c85f000500 [ 507.297244] 1T ESID= f00000 VSID= a86c85f LLP:100 [ 507.297245] 12 00007f0008000000 4008119624000d90 [ 507.297246] 1T ESID= 7f VSID= 8119624 LLP:110 [ 507.297247] 13 0000000018000000 00092885f5150d90 [ 507.297247] 256M ESID= 1 VSID= 92885f5150 LLP:110 [ 507.297248] 14 0000010008000000 4009e7cb50000d90 [ 507.297249] 1T ESID= 1 VSID= 9e7cb50 LLP:110 [ 507.297250] 15 d000000008000000 400d43642f000510 [ 507.297251] 1T ESID= d00000 VSID= d43642f LLP:110 [ 507.297252] 16 d000000008000000 400d43642f000510 [ 507.297253] 1T ESID= d00000 VSID= d43642f LLP:110 [ 507.297253] ---------------------------------- [ 507.297254] SLB cache ptr value = 3 [ 507.297254] Valid SLB cache entries: [ 507.297255] 00 EA[0-35]= 7f000 [ 507.297256] 01 EA[0-35]= 1 [ 507.297257] 02 EA[0-35]= 1000 [ 507.297257] Rest of SLB cache entries: [ 507.297258] 03 EA[0-35]= 7f000 [ 507.297258] 04 EA[0-35]= 1 [ 507.297259] 05 EA[0-35]= 1000 [ 507.297260] 06 EA[0-35]= 12 [ 507.297260] 07 EA[0-35]= 7f000 Suggested-by: Aneesh Kumar K.V <aneesh.kumar@linux.vnet.ibm.com> Suggested-by: Michael Ellerman <mpe@ellerman.id.au> Signed-off-by: Mahesh Salgaonkar <mahesh@linux.vnet.ibm.com> Reviewed-by: Nicholas Piggin <npiggin@gmail.com> Signed-off-by: Michael Ellerman <mpe@ellerman.id.au>
2018-09-11 17:27:15 +03:00
void slb_save_contents(struct slb_entry *slb_ptr)
{
int i;
unsigned long e, v;
/* Save slb_cache_ptr value. */
get_paca()->slb_save_cache_ptr = get_paca()->slb_cache_ptr;
if (!slb_ptr)
return;
for (i = 0; i < mmu_slb_size; i++) {
asm volatile("slbmfee %0,%1" : "=r" (e) : "r" (i));
asm volatile("slbmfev %0,%1" : "=r" (v) : "r" (i));
slb_ptr->esid = e;
slb_ptr->vsid = v;
slb_ptr++;
}
}
void slb_dump_contents(struct slb_entry *slb_ptr)
{
int i, n;
unsigned long e, v;
unsigned long llp;
if (!slb_ptr)
return;
pr_err("SLB contents of cpu 0x%x\n", smp_processor_id());
pr_err("Last SLB entry inserted at slot %d\n", get_paca()->stab_rr);
powerpc/pseries: Dump the SLB contents on SLB MCE errors. If we get a machine check exceptions due to SLB errors then dump the current SLB contents which will be very much helpful in debugging the root cause of SLB errors. Introduce an exclusive buffer per cpu to hold faulty SLB entries. In real mode mce handler saves the old SLB contents into this buffer accessible through paca and print it out later in virtual mode. With this patch the console will log SLB contents like below on SLB MCE errors: [ 507.297236] SLB contents of cpu 0x1 [ 507.297237] Last SLB entry inserted at slot 16 [ 507.297238] 00 c000000008000000 400ea1b217000500 [ 507.297239] 1T ESID= c00000 VSID= ea1b217 LLP:100 [ 507.297240] 01 d000000008000000 400d43642f000510 [ 507.297242] 1T ESID= d00000 VSID= d43642f LLP:110 [ 507.297243] 11 f000000008000000 400a86c85f000500 [ 507.297244] 1T ESID= f00000 VSID= a86c85f LLP:100 [ 507.297245] 12 00007f0008000000 4008119624000d90 [ 507.297246] 1T ESID= 7f VSID= 8119624 LLP:110 [ 507.297247] 13 0000000018000000 00092885f5150d90 [ 507.297247] 256M ESID= 1 VSID= 92885f5150 LLP:110 [ 507.297248] 14 0000010008000000 4009e7cb50000d90 [ 507.297249] 1T ESID= 1 VSID= 9e7cb50 LLP:110 [ 507.297250] 15 d000000008000000 400d43642f000510 [ 507.297251] 1T ESID= d00000 VSID= d43642f LLP:110 [ 507.297252] 16 d000000008000000 400d43642f000510 [ 507.297253] 1T ESID= d00000 VSID= d43642f LLP:110 [ 507.297253] ---------------------------------- [ 507.297254] SLB cache ptr value = 3 [ 507.297254] Valid SLB cache entries: [ 507.297255] 00 EA[0-35]= 7f000 [ 507.297256] 01 EA[0-35]= 1 [ 507.297257] 02 EA[0-35]= 1000 [ 507.297257] Rest of SLB cache entries: [ 507.297258] 03 EA[0-35]= 7f000 [ 507.297258] 04 EA[0-35]= 1 [ 507.297259] 05 EA[0-35]= 1000 [ 507.297260] 06 EA[0-35]= 12 [ 507.297260] 07 EA[0-35]= 7f000 Suggested-by: Aneesh Kumar K.V <aneesh.kumar@linux.vnet.ibm.com> Suggested-by: Michael Ellerman <mpe@ellerman.id.au> Signed-off-by: Mahesh Salgaonkar <mahesh@linux.vnet.ibm.com> Reviewed-by: Nicholas Piggin <npiggin@gmail.com> Signed-off-by: Michael Ellerman <mpe@ellerman.id.au>
2018-09-11 17:27:15 +03:00
for (i = 0; i < mmu_slb_size; i++) {
e = slb_ptr->esid;
v = slb_ptr->vsid;
slb_ptr++;
if (!e && !v)
continue;
pr_err("%02d %016lx %016lx\n", i, e, v);
if (!(e & SLB_ESID_V)) {
pr_err("\n");
continue;
}
llp = v & SLB_VSID_LLP;
if (v & SLB_VSID_B_1T) {
pr_err(" 1T ESID=%9lx VSID=%13lx LLP:%3lx\n",
GET_ESID_1T(e),
(v & ~SLB_VSID_B) >> SLB_VSID_SHIFT_1T, llp);
} else {
pr_err(" 256M ESID=%9lx VSID=%13lx LLP:%3lx\n",
GET_ESID(e),
(v & ~SLB_VSID_B) >> SLB_VSID_SHIFT, llp);
}
}
pr_err("----------------------------------\n");
/* Dump slb cache entires as well. */
pr_err("SLB cache ptr value = %d\n", get_paca()->slb_save_cache_ptr);
pr_err("Valid SLB cache entries:\n");
n = min_t(int, get_paca()->slb_save_cache_ptr, SLB_CACHE_ENTRIES);
for (i = 0; i < n; i++)
pr_err("%02d EA[0-35]=%9x\n", i, get_paca()->slb_cache[i]);
pr_err("Rest of SLB cache entries:\n");
for (i = n; i < SLB_CACHE_ENTRIES; i++)
pr_err("%02d EA[0-35]=%9x\n", i, get_paca()->slb_cache[i]);
}
void slb_vmalloc_update(void)
{
/*
* vmalloc is not bolted, so just have to flush non-bolted.
*/
slb_flush_and_restore_bolted();
}
static bool preload_hit(struct thread_info *ti, unsigned long esid)
{
unsigned char i;
for (i = 0; i < ti->slb_preload_nr; i++) {
unsigned char idx;
idx = (ti->slb_preload_tail + i) % SLB_PRELOAD_NR;
if (esid == ti->slb_preload_esid[idx])
return true;
}
return false;
}
static bool preload_add(struct thread_info *ti, unsigned long ea)
{
unsigned char idx;
unsigned long esid;
if (mmu_has_feature(MMU_FTR_1T_SEGMENT)) {
/* EAs are stored >> 28 so 256MB segments don't need clearing */
if (ea & ESID_MASK_1T)
ea &= ESID_MASK_1T;
}
esid = ea >> SID_SHIFT;
if (preload_hit(ti, esid))
return false;
idx = (ti->slb_preload_tail + ti->slb_preload_nr) % SLB_PRELOAD_NR;
ti->slb_preload_esid[idx] = esid;
if (ti->slb_preload_nr == SLB_PRELOAD_NR)
ti->slb_preload_tail = (ti->slb_preload_tail + 1) % SLB_PRELOAD_NR;
else
ti->slb_preload_nr++;
return true;
}
static void preload_age(struct thread_info *ti)
{
if (!ti->slb_preload_nr)
return;
ti->slb_preload_nr--;
ti->slb_preload_tail = (ti->slb_preload_tail + 1) % SLB_PRELOAD_NR;
}
void slb_setup_new_exec(void)
{
struct thread_info *ti = current_thread_info();
struct mm_struct *mm = current->mm;
unsigned long exec = 0x10000000;
WARN_ON(irqs_disabled());
/*
* preload cache can only be used to determine whether a SLB
* entry exists if it does not start to overflow.
*/
if (ti->slb_preload_nr + 2 > SLB_PRELOAD_NR)
return;
hard_irq_disable();
/*
* We have no good place to clear the slb preload cache on exec,
* flush_thread is about the earliest arch hook but that happens
* after we switch to the mm and have aleady preloaded the SLBEs.
*
* For the most part that's probably okay to use entries from the
* previous exec, they will age out if unused. It may turn out to
* be an advantage to clear the cache before switching to it,
* however.
*/
/*
* preload some userspace segments into the SLB.
* Almost all 32 and 64bit PowerPC executables are linked at
* 0x10000000 so it makes sense to preload this segment.
*/
if (!is_kernel_addr(exec)) {
if (preload_add(ti, exec))
slb_allocate_user(mm, exec);
}
/* Libraries and mmaps. */
if (!is_kernel_addr(mm->mmap_base)) {
if (preload_add(ti, mm->mmap_base))
slb_allocate_user(mm, mm->mmap_base);
}
/* see switch_slb */
asm volatile("isync" : : : "memory");
local_irq_enable();
}
void preload_new_slb_context(unsigned long start, unsigned long sp)
{
struct thread_info *ti = current_thread_info();
struct mm_struct *mm = current->mm;
unsigned long heap = mm->start_brk;
WARN_ON(irqs_disabled());
/* see above */
if (ti->slb_preload_nr + 3 > SLB_PRELOAD_NR)
return;
hard_irq_disable();
/* Userspace entry address. */
if (!is_kernel_addr(start)) {
if (preload_add(ti, start))
slb_allocate_user(mm, start);
}
/* Top of stack, grows down. */
if (!is_kernel_addr(sp)) {
if (preload_add(ti, sp))
slb_allocate_user(mm, sp);
}
/* Bottom of heap, grows up. */
if (heap && !is_kernel_addr(heap)) {
if (preload_add(ti, heap))
slb_allocate_user(mm, heap);
}
/* see switch_slb */
asm volatile("isync" : : : "memory");
local_irq_enable();
}
/* Flush all user entries from the segment table of the current processor. */
void switch_slb(struct task_struct *tsk, struct mm_struct *mm)
{
struct thread_info *ti = task_thread_info(tsk);
unsigned char i;
powerpc: Allow perf_counters to access user memory at interrupt time This provides a mechanism to allow the perf_counters code to access user memory in a PMU interrupt routine. Such an access can cause various kinds of interrupt: SLB miss, MMU hash table miss, segment table miss, or TLB miss, depending on the processor. This commit only deals with 64-bit classic/server processors, which use an MMU hash table. 32-bit processors are already able to access user memory at interrupt time. Since we don't soft-disable on 32-bit, we avoid the possibility of reentering hash_page or the TLB miss handlers, since they run with interrupts disabled. On 64-bit processors, an SLB miss interrupt on a user address will update the slb_cache and slb_cache_ptr fields in the paca. This is OK except in the case where a PMU interrupt occurs in switch_slb, which also accesses those fields. To prevent this, we hard-disable interrupts in switch_slb. Interrupts are already soft-disabled at this point, and will get hard-enabled when they get soft-enabled later. This also reworks slb_flush_and_rebolt: to avoid hard-disabling twice, and to make sure that it clears the slb_cache_ptr when called from other callers than switch_slb, the existing routine is renamed to __slb_flush_and_rebolt, which is called by switch_slb and the new version of slb_flush_and_rebolt. Similarly, switch_stab (used on POWER3 and RS64 processors) gets a hard_irq_disable() to protect the per-cpu variables used there and in ste_allocate. If a MMU hashtable miss interrupt occurs, normally we would call hash_page to look up the Linux PTE for the address and create a HPTE. However, hash_page is fairly complex and takes some locks, so to avoid the possibility of deadlock, we check the preemption count to see if we are in a (pseudo-)NMI handler, and if so, we don't call hash_page but instead treat it like a bad access that will get reported up through the exception table mechanism. An interrupt whose handler runs even though the interrupt occurred when soft-disabled (such as the PMU interrupt) is considered a pseudo-NMI handler, which should use nmi_enter()/nmi_exit() rather than irq_enter()/irq_exit(). Acked-by: Benjamin Herrenschmidt <benh@kernel.crashing.org> Signed-off-by: Paul Mackerras <paulus@samba.org>
2009-08-17 09:17:54 +04:00
/*
* We need interrupts hard-disabled here, not just soft-disabled,
* so that a PMU interrupt can't occur, which might try to access
* user memory (to get a stack trace) and possible cause an SLB miss
* which would update the slb_cache/slb_cache_ptr fields in the PACA.
*/
hard_irq_disable();
asm volatile("isync" : : : "memory");
if (cpu_has_feature(CPU_FTR_ARCH_300)) {
/*
* SLBIA IH=3 invalidates all Class=1 SLBEs and their
* associated lookaside structures, which matches what
* switch_slb wants. So ARCH_300 does not use the slb
* cache.
*/
asm volatile(PPC_SLBIA(3));
} else {
unsigned long offset = get_paca()->slb_cache_ptr;
if (!mmu_has_feature(MMU_FTR_NO_SLBIE_B) &&
offset <= SLB_CACHE_ENTRIES) {
unsigned long slbie_data = 0;
for (i = 0; i < offset; i++) {
unsigned long ea;
ea = (unsigned long)
get_paca()->slb_cache[i] << SID_SHIFT;
/*
* Could assert_slb_exists here, but hypervisor
* or machine check could have come in and
* removed the entry at this point.
*/
slbie_data = ea;
slbie_data |= user_segment_size(slbie_data)
<< SLBIE_SSIZE_SHIFT;
slbie_data |= SLBIE_C; /* user slbs have C=1 */
asm volatile("slbie %0" : : "r" (slbie_data));
}
/* Workaround POWER5 < DD2.1 issue */
if (!cpu_has_feature(CPU_FTR_ARCH_207S) && offset == 1)
asm volatile("slbie %0" : : "r" (slbie_data));
} else {
struct slb_shadow *p = get_slb_shadow();
unsigned long ksp_esid_data =
be64_to_cpu(p->save_area[KSTACK_INDEX].esid);
unsigned long ksp_vsid_data =
be64_to_cpu(p->save_area[KSTACK_INDEX].vsid);
asm volatile(PPC_SLBIA(1) "\n"
"slbmte %0,%1\n"
"isync"
:: "r"(ksp_vsid_data),
"r"(ksp_esid_data));
get_paca()->slb_kern_bitmap = (1U << SLB_NUM_BOLTED) - 1;
}
get_paca()->slb_cache_ptr = 0;
}
get_paca()->slb_used_bitmap = get_paca()->slb_kern_bitmap;
copy_mm_to_paca(mm);
/*
* We gradually age out SLBs after a number of context switches to
* reduce reload overhead of unused entries (like we do with FP/VEC
* reload). Each time we wrap 256 switches, take an entry out of the
* SLB preload cache.
*/
tsk->thread.load_slb++;
if (!tsk->thread.load_slb) {
unsigned long pc = KSTK_EIP(tsk);
preload_age(ti);
preload_add(ti, pc);
}
for (i = 0; i < ti->slb_preload_nr; i++) {
unsigned char idx;
unsigned long ea;
idx = (ti->slb_preload_tail + i) % SLB_PRELOAD_NR;
ea = (unsigned long)ti->slb_preload_esid[idx] << SID_SHIFT;
slb_allocate_user(mm, ea);
}
/*
* Synchronize slbmte preloads with possible subsequent user memory
* address accesses by the kernel (user mode won't happen until
* rfid, which is safe).
*/
asm volatile("isync" : : : "memory");
}
void slb_set_size(u16 size)
{
mmu_slb_size = size;
}
void slb_initialize(void)
{
powerpc: Use 64k pages without needing cache-inhibited large pages Some POWER5+ machines can do 64k hardware pages for normal memory but not for cache-inhibited pages. This patch lets us use 64k hardware pages for most user processes on such machines (assuming the kernel has been configured with CONFIG_PPC_64K_PAGES=y). User processes start out using 64k pages and get switched to 4k pages if they use any non-cacheable mappings. With this, we use 64k pages for the vmalloc region and 4k pages for the imalloc region. If anything creates a non-cacheable mapping in the vmalloc region, the vmalloc region will get switched to 4k pages. I don't know of any driver other than the DRM that would do this, though, and these machines don't have AGP. When a region gets switched from 64k pages to 4k pages, we do not have to clear out all the 64k HPTEs from the hash table immediately. We use the _PAGE_COMBO bit in the Linux PTE to indicate whether the page was hashed in as a 64k page or a set of 4k pages. If hash_page is trying to insert a 4k page for a Linux PTE and it sees that it has already been inserted as a 64k page, it first invalidates the 64k HPTE before inserting the 4k HPTE. The hash invalidation routines also use the _PAGE_COMBO bit, to determine whether to look for a 64k HPTE or a set of 4k HPTEs to remove. With those two changes, we can tolerate a mix of 4k and 64k HPTEs in the hash table, and they will all get removed when the address space is torn down. Signed-off-by: Paul Mackerras <paulus@samba.org>
2006-06-15 04:45:18 +04:00
unsigned long linear_llp, vmalloc_llp, io_llp;
unsigned long lflags;
static int slb_encoding_inited;
#ifdef CONFIG_SPARSEMEM_VMEMMAP
unsigned long vmemmap_llp;
#endif
/* Prepare our SLB miss handler based on our page size */
linear_llp = mmu_psize_defs[mmu_linear_psize].sllp;
powerpc: Use 64k pages without needing cache-inhibited large pages Some POWER5+ machines can do 64k hardware pages for normal memory but not for cache-inhibited pages. This patch lets us use 64k hardware pages for most user processes on such machines (assuming the kernel has been configured with CONFIG_PPC_64K_PAGES=y). User processes start out using 64k pages and get switched to 4k pages if they use any non-cacheable mappings. With this, we use 64k pages for the vmalloc region and 4k pages for the imalloc region. If anything creates a non-cacheable mapping in the vmalloc region, the vmalloc region will get switched to 4k pages. I don't know of any driver other than the DRM that would do this, though, and these machines don't have AGP. When a region gets switched from 64k pages to 4k pages, we do not have to clear out all the 64k HPTEs from the hash table immediately. We use the _PAGE_COMBO bit in the Linux PTE to indicate whether the page was hashed in as a 64k page or a set of 4k pages. If hash_page is trying to insert a 4k page for a Linux PTE and it sees that it has already been inserted as a 64k page, it first invalidates the 64k HPTE before inserting the 4k HPTE. The hash invalidation routines also use the _PAGE_COMBO bit, to determine whether to look for a 64k HPTE or a set of 4k HPTEs to remove. With those two changes, we can tolerate a mix of 4k and 64k HPTEs in the hash table, and they will all get removed when the address space is torn down. Signed-off-by: Paul Mackerras <paulus@samba.org>
2006-06-15 04:45:18 +04:00
io_llp = mmu_psize_defs[mmu_io_psize].sllp;
vmalloc_llp = mmu_psize_defs[mmu_vmalloc_psize].sllp;
get_paca()->vmalloc_sllp = SLB_VSID_KERNEL | vmalloc_llp;
#ifdef CONFIG_SPARSEMEM_VMEMMAP
vmemmap_llp = mmu_psize_defs[mmu_vmemmap_psize].sllp;
#endif
if (!slb_encoding_inited) {
slb_encoding_inited = 1;
pr_devel("SLB: linear LLP = %04lx\n", linear_llp);
pr_devel("SLB: io LLP = %04lx\n", io_llp);
#ifdef CONFIG_SPARSEMEM_VMEMMAP
pr_devel("SLB: vmemmap LLP = %04lx\n", vmemmap_llp);
#endif
}
get_paca()->stab_rr = SLB_NUM_BOLTED - 1;
get_paca()->slb_kern_bitmap = (1U << SLB_NUM_BOLTED) - 1;
get_paca()->slb_used_bitmap = get_paca()->slb_kern_bitmap;
lflags = SLB_VSID_KERNEL | linear_llp;
/* Invalidate the entire SLB (even entry 0) & all the ERATS */
asm volatile("isync":::"memory");
asm volatile("slbmte %0,%0"::"r" (0) : "memory");
asm volatile("isync; slbia; isync":::"memory");
create_shadowed_slbe(PAGE_OFFSET, mmu_kernel_ssize, lflags, LINEAR_INDEX);
[POWERPC] Bolt in SLB entry for kernel stack on secondary cpus This fixes a regression reported by Kamalesh Bulabel where a POWER4 machine would crash because of an SLB miss at a point where the SLB miss exception was unrecoverable. This regression is tracked at: http://bugzilla.kernel.org/show_bug.cgi?id=10082 SLB misses at such points shouldn't happen because the kernel stack is the only memory accessed other than things in the first segment of the linear mapping (which is mapped at all times by entry 0 of the SLB). The context switch code ensures that SLB entry 2 covers the kernel stack, if it is not already covered by entry 0. None of entries 0 to 2 are ever replaced by the SLB miss handler. Where this went wrong is that the context switch code assumes it doesn't have to write to SLB entry 2 if the new kernel stack is in the same segment as the old kernel stack, since entry 2 should already be correct. However, when we start up a secondary cpu, it calls slb_initialize, which doesn't set up entry 2. This is correct for the boot cpu, where we will be using a stack in the kernel BSS at this point (i.e. init_thread_union), but not necessarily for secondary cpus, whose initial stack can be allocated anywhere. This doesn't cause any immediate problem since the SLB miss handler will just create an SLB entry somewhere else to cover the initial stack. In fact it's possible for the cpu to go quite a long time without SLB entry 2 being valid. Eventually, though, the entry created by the SLB miss handler will get overwritten by some other entry, and if the next access to the stack is at an unrecoverable point, we get the crash. This fixes the problem by making slb_initialize create a suitable entry for the kernel stack, if we are on a secondary cpu and the stack isn't covered by SLB entry 0. This requires initializing the get_paca()->kstack field earlier, so I do that in smp_create_idle where the current field is initialized. This also abstracts a bit of the computation that mk_esid_data in slb.c does so that it can be used in slb_initialize. Signed-off-by: Paul Mackerras <paulus@samba.org>
2008-05-02 08:29:12 +04:00
/* For the boot cpu, we're running on the stack in init_thread_union,
* which is in the first segment of the linear mapping, and also
* get_paca()->kstack hasn't been initialized yet.
* For secondary cpus, we need to bolt the kernel stack entry now.
*/
slb_shadow_clear(KSTACK_INDEX);
[POWERPC] Bolt in SLB entry for kernel stack on secondary cpus This fixes a regression reported by Kamalesh Bulabel where a POWER4 machine would crash because of an SLB miss at a point where the SLB miss exception was unrecoverable. This regression is tracked at: http://bugzilla.kernel.org/show_bug.cgi?id=10082 SLB misses at such points shouldn't happen because the kernel stack is the only memory accessed other than things in the first segment of the linear mapping (which is mapped at all times by entry 0 of the SLB). The context switch code ensures that SLB entry 2 covers the kernel stack, if it is not already covered by entry 0. None of entries 0 to 2 are ever replaced by the SLB miss handler. Where this went wrong is that the context switch code assumes it doesn't have to write to SLB entry 2 if the new kernel stack is in the same segment as the old kernel stack, since entry 2 should already be correct. However, when we start up a secondary cpu, it calls slb_initialize, which doesn't set up entry 2. This is correct for the boot cpu, where we will be using a stack in the kernel BSS at this point (i.e. init_thread_union), but not necessarily for secondary cpus, whose initial stack can be allocated anywhere. This doesn't cause any immediate problem since the SLB miss handler will just create an SLB entry somewhere else to cover the initial stack. In fact it's possible for the cpu to go quite a long time without SLB entry 2 being valid. Eventually, though, the entry created by the SLB miss handler will get overwritten by some other entry, and if the next access to the stack is at an unrecoverable point, we get the crash. This fixes the problem by making slb_initialize create a suitable entry for the kernel stack, if we are on a secondary cpu and the stack isn't covered by SLB entry 0. This requires initializing the get_paca()->kstack field earlier, so I do that in smp_create_idle where the current field is initialized. This also abstracts a bit of the computation that mk_esid_data in slb.c does so that it can be used in slb_initialize. Signed-off-by: Paul Mackerras <paulus@samba.org>
2008-05-02 08:29:12 +04:00
if (raw_smp_processor_id() != boot_cpuid &&
(get_paca()->kstack & slb_esid_mask(mmu_kernel_ssize)) > PAGE_OFFSET)
create_shadowed_slbe(get_paca()->kstack,
mmu_kernel_ssize, lflags, KSTACK_INDEX);
asm volatile("isync":::"memory");
}
static void slb_cache_update(unsigned long esid_data)
{
int slb_cache_index;
if (cpu_has_feature(CPU_FTR_ARCH_300))
return; /* ISAv3.0B and later does not use slb_cache */
/*
* Now update slb cache entries
*/
slb_cache_index = local_paca->slb_cache_ptr;
if (slb_cache_index < SLB_CACHE_ENTRIES) {
/*
* We have space in slb cache for optimized switch_slb().
* Top 36 bits from esid_data as per ISA
*/
local_paca->slb_cache[slb_cache_index++] = esid_data >> 28;
local_paca->slb_cache_ptr++;
} else {
/*
* Our cache is full and the current cache content strictly
* doesn't indicate the active SLB conents. Bump the ptr
* so that switch_slb() will ignore the cache.
*/
local_paca->slb_cache_ptr = SLB_CACHE_ENTRIES + 1;
}
}
static enum slb_index alloc_slb_index(bool kernel)
{
enum slb_index index;
/*
* The allocation bitmaps can become out of synch with the SLB
* when the _switch code does slbie when bolting a new stack
* segment and it must not be anywhere else in the SLB. This leaves
* a kernel allocated entry that is unused in the SLB. With very
* large systems or small segment sizes, the bitmaps could slowly
* fill with these entries. They will eventually be cleared out
* by the round robin allocator in that case, so it's probably not
* worth accounting for.
*/
/*
* SLBs beyond 32 entries are allocated with stab_rr only
* POWER7/8/9 have 32 SLB entries, this could be expanded if a
* future CPU has more.
*/
if (local_paca->slb_used_bitmap != U32_MAX) {
index = ffz(local_paca->slb_used_bitmap);
local_paca->slb_used_bitmap |= 1U << index;
if (kernel)
local_paca->slb_kern_bitmap |= 1U << index;
} else {
/* round-robin replacement of slb starting at SLB_NUM_BOLTED. */
index = local_paca->stab_rr;
if (index < (mmu_slb_size - 1))
index++;
else
index = SLB_NUM_BOLTED;
local_paca->stab_rr = index;
if (index < 32) {
if (kernel)
local_paca->slb_kern_bitmap |= 1U << index;
else
local_paca->slb_kern_bitmap &= ~(1U << index);
}
}
BUG_ON(index < SLB_NUM_BOLTED);
return index;
}
static long slb_insert_entry(unsigned long ea, unsigned long context,
unsigned long flags, int ssize, bool kernel)
{
unsigned long vsid;
unsigned long vsid_data, esid_data;
enum slb_index index;
vsid = get_vsid(context, ea, ssize);
if (!vsid)
return -EFAULT;
/*
* There must not be a kernel SLB fault in alloc_slb_index or before
* slbmte here or the allocation bitmaps could get out of whack with
* the SLB.
*
* User SLB faults or preloads take this path which might get inlined
* into the caller, so add compiler barriers here to ensure unsafe
* memory accesses do not come between.
*/
barrier();
index = alloc_slb_index(kernel);
vsid_data = __mk_vsid_data(vsid, ssize, flags);
esid_data = mk_esid_data(ea, ssize, index);
/*
* No need for an isync before or after this slbmte. The exception
* we enter with and the rfid we exit with are context synchronizing.
* User preloads should add isync afterwards in case the kernel
* accesses user memory before it returns to userspace with rfid.
*/
assert_slb_notexists(ea);
asm volatile("slbmte %0, %1" : : "r" (vsid_data), "r" (esid_data));
barrier();
if (!kernel)
slb_cache_update(esid_data);
return 0;
}
static long slb_allocate_kernel(unsigned long ea, unsigned long id)
{
unsigned long context;
unsigned long flags;
int ssize;
if (id == KERNEL_REGION_ID) {
/* We only support upto MAX_PHYSMEM_BITS */
if ((ea & ~REGION_MASK) > (1UL << MAX_PHYSMEM_BITS))
return -EFAULT;
flags = SLB_VSID_KERNEL | mmu_psize_defs[mmu_linear_psize].sllp;
#ifdef CONFIG_SPARSEMEM_VMEMMAP
} else if (id == VMEMMAP_REGION_ID) {
if ((ea & ~REGION_MASK) >= (1ULL << MAX_EA_BITS_PER_CONTEXT))
return -EFAULT;
flags = SLB_VSID_KERNEL | mmu_psize_defs[mmu_vmemmap_psize].sllp;
#endif
} else if (id == VMALLOC_REGION_ID) {
if ((ea & ~REGION_MASK) >= (1ULL << MAX_EA_BITS_PER_CONTEXT))
return -EFAULT;
if (ea < H_VMALLOC_END)
flags = get_paca()->vmalloc_sllp;
else
flags = SLB_VSID_KERNEL | mmu_psize_defs[mmu_io_psize].sllp;
} else {
return -EFAULT;
}
ssize = MMU_SEGSIZE_1T;
if (!mmu_has_feature(MMU_FTR_1T_SEGMENT))
ssize = MMU_SEGSIZE_256M;
context = get_kernel_context(ea);
return slb_insert_entry(ea, context, flags, ssize, true);
}
static long slb_allocate_user(struct mm_struct *mm, unsigned long ea)
powerpc/64s/hash: convert SLB miss handlers to C This patch moves SLB miss handlers completely to C, using the standard exception handler macros to set up the stack and branch to C. This can be done because the segment containing the kernel stack is always bolted, so accessing it with relocation on will not cause an SLB exception. Arbitrary kernel memory may not be accessed when handling kernel space SLB misses, so care should be taken there. However user SLB misses can access any kernel memory, which can be used to move some fields out of the paca (in later patches). User SLB misses could quite easily reconcile IRQs and set up a first class kernel environment and exit via ret_from_except, however that doesn't seem to be necessary at the moment, so we only do that if a bad fault is encountered. [ Credit to Aneesh for bug fixes, error checks, and improvements to bad address handling, etc ] Signed-off-by: Nicholas Piggin <npiggin@gmail.com> Since RFC: - Added MSR[RI] handling - Fixed up a register loss bug exposed by irq tracing (Aneesh) - Reject misses outside the defined kernel regions (Aneesh) - Added several more sanity checks and error handling (Aneesh), we may look at consolidating these tests and tightenig up the code but for a first pass we decided it's better to check carefully. Since v1: - Fixed SLB cache corruption (Aneesh) - Fixed untidy SLBE allocation "leak" in get_vsid error case - Now survives some stress testing on real hardware Signed-off-by: Michael Ellerman <mpe@ellerman.id.au>
2018-09-14 18:30:51 +03:00
{
unsigned long context;
unsigned long flags;
int bpsize;
int ssize;
/*
* consider this as bad access if we take a SLB miss
* on an address above addr limit.
*/
if (ea >= mm->context.slb_addr_limit)
return -EFAULT;
context = get_user_context(&mm->context, ea);
if (!context)
return -EFAULT;
if (unlikely(ea >= H_PGTABLE_RANGE)) {
WARN_ON(1);
return -EFAULT;
}
ssize = user_segment_size(ea);
bpsize = get_slice_psize(mm, ea);
flags = SLB_VSID_USER | mmu_psize_defs[bpsize].sllp;
return slb_insert_entry(ea, context, flags, ssize, false);
powerpc/64s/hash: convert SLB miss handlers to C This patch moves SLB miss handlers completely to C, using the standard exception handler macros to set up the stack and branch to C. This can be done because the segment containing the kernel stack is always bolted, so accessing it with relocation on will not cause an SLB exception. Arbitrary kernel memory may not be accessed when handling kernel space SLB misses, so care should be taken there. However user SLB misses can access any kernel memory, which can be used to move some fields out of the paca (in later patches). User SLB misses could quite easily reconcile IRQs and set up a first class kernel environment and exit via ret_from_except, however that doesn't seem to be necessary at the moment, so we only do that if a bad fault is encountered. [ Credit to Aneesh for bug fixes, error checks, and improvements to bad address handling, etc ] Signed-off-by: Nicholas Piggin <npiggin@gmail.com> Since RFC: - Added MSR[RI] handling - Fixed up a register loss bug exposed by irq tracing (Aneesh) - Reject misses outside the defined kernel regions (Aneesh) - Added several more sanity checks and error handling (Aneesh), we may look at consolidating these tests and tightenig up the code but for a first pass we decided it's better to check carefully. Since v1: - Fixed SLB cache corruption (Aneesh) - Fixed untidy SLBE allocation "leak" in get_vsid error case - Now survives some stress testing on real hardware Signed-off-by: Michael Ellerman <mpe@ellerman.id.au>
2018-09-14 18:30:51 +03:00
}
long do_slb_fault(struct pt_regs *regs, unsigned long ea)
{
unsigned long id = REGION_ID(ea);
powerpc/64s/hash: convert SLB miss handlers to C This patch moves SLB miss handlers completely to C, using the standard exception handler macros to set up the stack and branch to C. This can be done because the segment containing the kernel stack is always bolted, so accessing it with relocation on will not cause an SLB exception. Arbitrary kernel memory may not be accessed when handling kernel space SLB misses, so care should be taken there. However user SLB misses can access any kernel memory, which can be used to move some fields out of the paca (in later patches). User SLB misses could quite easily reconcile IRQs and set up a first class kernel environment and exit via ret_from_except, however that doesn't seem to be necessary at the moment, so we only do that if a bad fault is encountered. [ Credit to Aneesh for bug fixes, error checks, and improvements to bad address handling, etc ] Signed-off-by: Nicholas Piggin <npiggin@gmail.com> Since RFC: - Added MSR[RI] handling - Fixed up a register loss bug exposed by irq tracing (Aneesh) - Reject misses outside the defined kernel regions (Aneesh) - Added several more sanity checks and error handling (Aneesh), we may look at consolidating these tests and tightenig up the code but for a first pass we decided it's better to check carefully. Since v1: - Fixed SLB cache corruption (Aneesh) - Fixed untidy SLBE allocation "leak" in get_vsid error case - Now survives some stress testing on real hardware Signed-off-by: Michael Ellerman <mpe@ellerman.id.au>
2018-09-14 18:30:51 +03:00
/* IRQs are not reconciled here, so can't check irqs_disabled */
VM_WARN_ON(mfmsr() & MSR_EE);
if (unlikely(!(regs->msr & MSR_RI)))
return -EINVAL;
/*
* SLB kernel faults must be very careful not to touch anything
* that is not bolted. E.g., PACA and global variables are okay,
* mm->context stuff is not.
*
* SLB user faults can access all of kernel memory, but must be
* careful not to touch things like IRQ state because it is not
* "reconciled" here. The difficulty is that we must use
* fast_exception_return to return from kernel SLB faults without
* looking at possible non-bolted memory. We could test user vs
* kernel faults in the interrupt handler asm and do a full fault,
* reconcile, ret_from_except for user faults which would make them
* first class kernel code. But for performance it's probably nicer
* if they go via fast_exception_return too.
*/
if (id >= KERNEL_REGION_ID) {
long err;
#ifdef CONFIG_DEBUG_VM
/* Catch recursive kernel SLB faults. */
BUG_ON(local_paca->in_kernel_slb_handler);
local_paca->in_kernel_slb_handler = 1;
#endif
err = slb_allocate_kernel(ea, id);
#ifdef CONFIG_DEBUG_VM
local_paca->in_kernel_slb_handler = 0;
#endif
return err;
} else {
struct mm_struct *mm = current->mm;
long err;
if (unlikely(!mm))
return -EFAULT;
powerpc/64s/hash: convert SLB miss handlers to C This patch moves SLB miss handlers completely to C, using the standard exception handler macros to set up the stack and branch to C. This can be done because the segment containing the kernel stack is always bolted, so accessing it with relocation on will not cause an SLB exception. Arbitrary kernel memory may not be accessed when handling kernel space SLB misses, so care should be taken there. However user SLB misses can access any kernel memory, which can be used to move some fields out of the paca (in later patches). User SLB misses could quite easily reconcile IRQs and set up a first class kernel environment and exit via ret_from_except, however that doesn't seem to be necessary at the moment, so we only do that if a bad fault is encountered. [ Credit to Aneesh for bug fixes, error checks, and improvements to bad address handling, etc ] Signed-off-by: Nicholas Piggin <npiggin@gmail.com> Since RFC: - Added MSR[RI] handling - Fixed up a register loss bug exposed by irq tracing (Aneesh) - Reject misses outside the defined kernel regions (Aneesh) - Added several more sanity checks and error handling (Aneesh), we may look at consolidating these tests and tightenig up the code but for a first pass we decided it's better to check carefully. Since v1: - Fixed SLB cache corruption (Aneesh) - Fixed untidy SLBE allocation "leak" in get_vsid error case - Now survives some stress testing on real hardware Signed-off-by: Michael Ellerman <mpe@ellerman.id.au>
2018-09-14 18:30:51 +03:00
err = slb_allocate_user(mm, ea);
if (!err)
preload_add(current_thread_info(), ea);
return err;
}
}
powerpc/64s/hash: convert SLB miss handlers to C This patch moves SLB miss handlers completely to C, using the standard exception handler macros to set up the stack and branch to C. This can be done because the segment containing the kernel stack is always bolted, so accessing it with relocation on will not cause an SLB exception. Arbitrary kernel memory may not be accessed when handling kernel space SLB misses, so care should be taken there. However user SLB misses can access any kernel memory, which can be used to move some fields out of the paca (in later patches). User SLB misses could quite easily reconcile IRQs and set up a first class kernel environment and exit via ret_from_except, however that doesn't seem to be necessary at the moment, so we only do that if a bad fault is encountered. [ Credit to Aneesh for bug fixes, error checks, and improvements to bad address handling, etc ] Signed-off-by: Nicholas Piggin <npiggin@gmail.com> Since RFC: - Added MSR[RI] handling - Fixed up a register loss bug exposed by irq tracing (Aneesh) - Reject misses outside the defined kernel regions (Aneesh) - Added several more sanity checks and error handling (Aneesh), we may look at consolidating these tests and tightenig up the code but for a first pass we decided it's better to check carefully. Since v1: - Fixed SLB cache corruption (Aneesh) - Fixed untidy SLBE allocation "leak" in get_vsid error case - Now survives some stress testing on real hardware Signed-off-by: Michael Ellerman <mpe@ellerman.id.au>
2018-09-14 18:30:51 +03:00
void do_bad_slb_fault(struct pt_regs *regs, unsigned long ea, long err)
{
if (err == -EFAULT) {
if (user_mode(regs))
_exception(SIGSEGV, regs, SEGV_BNDERR, ea);
else
bad_page_fault(regs, ea, SIGSEGV);
} else if (err == -EINVAL) {
unrecoverable_exception(regs);
} else {
BUG();
}
}