kernel-fxtec-pro1x/arch/powerpc/mm/stab.c

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/*
* PowerPC64 Segment Translation Support.
*
* 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 <linux/memblock.h>
#include <asm/pgtable.h>
#include <asm/mmu.h>
#include <asm/mmu_context.h>
#include <asm/paca.h>
#include <asm/cputable.h>
#include <asm/prom.h>
#include <asm/abs_addr.h>
#include <asm/firmware.h>
#include <asm/iseries/hv_call.h>
struct stab_entry {
unsigned long esid_data;
unsigned long vsid_data;
};
#define NR_STAB_CACHE_ENTRIES 8
static DEFINE_PER_CPU(long, stab_cache_ptr);
static DEFINE_PER_CPU(long [NR_STAB_CACHE_ENTRIES], stab_cache);
/*
* Create a segment table entry for the given esid/vsid pair.
*/
static int make_ste(unsigned long stab, unsigned long esid, unsigned long vsid)
{
unsigned long esid_data, vsid_data;
unsigned long entry, group, old_esid, castout_entry, i;
unsigned int global_entry;
struct stab_entry *ste, *castout_ste;
unsigned long kernel_segment = (esid << SID_SHIFT) >= PAGE_OFFSET;
vsid_data = vsid << STE_VSID_SHIFT;
esid_data = esid << SID_SHIFT | STE_ESID_KP | STE_ESID_V;
if (! kernel_segment)
esid_data |= STE_ESID_KS;
/* Search the primary group first. */
global_entry = (esid & 0x1f) << 3;
ste = (struct stab_entry *)(stab | ((esid & 0x1f) << 7));
/* Find an empty entry, if one exists. */
for (group = 0; group < 2; group++) {
for (entry = 0; entry < 8; entry++, ste++) {
if (!(ste->esid_data & STE_ESID_V)) {
ste->vsid_data = vsid_data;
eieio();
ste->esid_data = esid_data;
return (global_entry | entry);
}
}
/* Now search the secondary group. */
global_entry = ((~esid) & 0x1f) << 3;
ste = (struct stab_entry *)(stab | (((~esid) & 0x1f) << 7));
}
/*
* Could not find empty entry, pick one with a round robin selection.
* Search all entries in the two groups.
*/
castout_entry = get_paca()->stab_rr;
for (i = 0; i < 16; i++) {
if (castout_entry < 8) {
global_entry = (esid & 0x1f) << 3;
ste = (struct stab_entry *)(stab | ((esid & 0x1f) << 7));
castout_ste = ste + castout_entry;
} else {
global_entry = ((~esid) & 0x1f) << 3;
ste = (struct stab_entry *)(stab | (((~esid) & 0x1f) << 7));
castout_ste = ste + (castout_entry - 8);
}
/* Dont cast out the first kernel segment */
if ((castout_ste->esid_data & ESID_MASK) != PAGE_OFFSET)
break;
castout_entry = (castout_entry + 1) & 0xf;
}
get_paca()->stab_rr = (castout_entry + 1) & 0xf;
/* Modify the old entry to the new value. */
/* Force previous translations to complete. DRENG */
asm volatile("isync" : : : "memory");
old_esid = castout_ste->esid_data >> SID_SHIFT;
castout_ste->esid_data = 0; /* Invalidate old entry */
asm volatile("sync" : : : "memory"); /* Order update */
castout_ste->vsid_data = vsid_data;
eieio(); /* Order update */
castout_ste->esid_data = esid_data;
asm volatile("slbie %0" : : "r" (old_esid << SID_SHIFT));
/* Ensure completion of slbie */
asm volatile("sync" : : : "memory");
return (global_entry | (castout_entry & 0x7));
}
/*
* Allocate a segment table entry for the given ea and mm
*/
static int __ste_allocate(unsigned long ea, struct mm_struct *mm)
{
unsigned long vsid;
unsigned char stab_entry;
unsigned long offset;
/* Kernel or user address? */
if (is_kernel_addr(ea)) {
vsid = get_kernel_vsid(ea, MMU_SEGSIZE_256M);
} else {
if ((ea >= TASK_SIZE_USER64) || (! mm))
return 1;
vsid = get_vsid(mm->context.id, ea, MMU_SEGSIZE_256M);
}
stab_entry = make_ste(get_paca()->stab_addr, GET_ESID(ea), vsid);
if (!is_kernel_addr(ea)) {
offset = __get_cpu_var(stab_cache_ptr);
if (offset < NR_STAB_CACHE_ENTRIES)
__get_cpu_var(stab_cache[offset++]) = stab_entry;
else
offset = NR_STAB_CACHE_ENTRIES+1;
__get_cpu_var(stab_cache_ptr) = offset;
/* Order update */
asm volatile("sync":::"memory");
}
return 0;
}
int ste_allocate(unsigned long ea)
{
return __ste_allocate(ea, current->mm);
}
/*
* Do the segment table work for a context switch: flush all user
* entries from the table, then preload some probably useful entries
* for the new task
*/
void switch_stab(struct task_struct *tsk, struct mm_struct *mm)
{
struct stab_entry *stab = (struct stab_entry *) get_paca()->stab_addr;
struct stab_entry *ste;
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>
2009-08-16 23:17:54 -06:00
unsigned long offset;
unsigned long pc = KSTK_EIP(tsk);
unsigned long stack = KSTK_ESP(tsk);
unsigned long unmapped_base;
/* Force previous translations to complete. DRENG */
asm volatile("isync" : : : "memory");
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>
2009-08-16 23:17:54 -06:00
/*
* 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 STAB miss
* which would update the stab_cache/stab_cache_ptr per-cpu variables.
*/
hard_irq_disable();
offset = __get_cpu_var(stab_cache_ptr);
if (offset <= NR_STAB_CACHE_ENTRIES) {
int i;
for (i = 0; i < offset; i++) {
ste = stab + __get_cpu_var(stab_cache[i]);
ste->esid_data = 0; /* invalidate entry */
}
} else {
unsigned long entry;
/* Invalidate all entries. */
ste = stab;
/* Never flush the first entry. */
ste += 1;
for (entry = 1;
entry < (HW_PAGE_SIZE / sizeof(struct stab_entry));
entry++, ste++) {
unsigned long ea;
ea = ste->esid_data & ESID_MASK;
if (!is_kernel_addr(ea)) {
ste->esid_data = 0;
}
}
}
asm volatile("sync; slbia; sync":::"memory");
__get_cpu_var(stab_cache_ptr) = 0;
/* Now preload some entries for the new task */
if (test_tsk_thread_flag(tsk, TIF_32BIT))
unmapped_base = TASK_UNMAPPED_BASE_USER32;
else
unmapped_base = TASK_UNMAPPED_BASE_USER64;
__ste_allocate(pc, mm);
if (GET_ESID(pc) == GET_ESID(stack))
return;
__ste_allocate(stack, mm);
if ((GET_ESID(pc) == GET_ESID(unmapped_base))
|| (GET_ESID(stack) == GET_ESID(unmapped_base)))
return;
__ste_allocate(unmapped_base, mm);
/* Order update */
asm volatile("sync" : : : "memory");
}
/*
* Allocate segment tables for secondary CPUs. These must all go in
* the first (bolted) segment, so that do_stab_bolted won't get a
* recursive segment miss on the segment table itself.
*/
void __init stabs_alloc(void)
{
int cpu;
if (cpu_has_feature(CPU_FTR_SLB))
return;
for_each_possible_cpu(cpu) {
unsigned long newstab;
if (cpu == 0)
continue; /* stab for CPU 0 is statically allocated */
newstab = memblock_alloc_base(HW_PAGE_SIZE, HW_PAGE_SIZE,
1<<SID_SHIFT);
newstab = (unsigned long)__va(newstab);
memset((void *)newstab, 0, HW_PAGE_SIZE);
paca[cpu].stab_addr = newstab;
paca[cpu].stab_real = virt_to_abs(newstab);
printk(KERN_INFO "Segment table for CPU %d at 0x%llx "
"virtual, 0x%llx absolute\n",
cpu, paca[cpu].stab_addr, paca[cpu].stab_real);
}
}
/*
* Build an entry for the base kernel segment and put it into
* the segment table or SLB. All other segment table or SLB
* entries are faulted in.
*/
void stab_initialize(unsigned long stab)
{
unsigned long vsid = get_kernel_vsid(PAGE_OFFSET, MMU_SEGSIZE_256M);
unsigned long stabreal;
asm volatile("isync; slbia; isync":::"memory");
make_ste(stab, GET_ESID(PAGE_OFFSET), vsid);
/* Order update */
asm volatile("sync":::"memory");
/* Set ASR */
stabreal = get_paca()->stab_real | 0x1ul;
#ifdef CONFIG_PPC_ISERIES
if (firmware_has_feature(FW_FEATURE_ISERIES)) {
HvCall1(HvCallBaseSetASR, stabreal);
return;
}
#endif /* CONFIG_PPC_ISERIES */
mtspr(SPRN_ASR, stabreal);
}