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b9293d457f
At the time of authoring 7655abb953
("arm64: mm: Move ASID from TTBR0
to TTBR1"), the Arm ARM did not specify any ordering guarantees for
direct writes to TTBR0_ELx and TTBR1_ELx and so an ISB was required
after each write to ensure TLBs would only be populated from the
expected (or reserved tables).
In a recent update to the Arm ARM, the requirements have been relaxed to
reflect the implementation of current CPUs and required implementation
of future CPUs to read (RDYDPX in D8.2.3 Translation table base address
register):
Direct writes to TTBR0_ELx and TTBR1_ELx occur in program order
relative to one another, without the need for explicit
synchronization. For any one translation, all indirect reads of
TTBR0_ELx and TTBR1_ELx that are made as part of the translation
observe only one point in that order of direct writes.
Remove the superfluous ISBs to optimize uaccess helpers and context
switch.
Cc: Will Deacon <will@kernel.org>
Cc: Mark Rutland <mark.rutland@arm.com>
Signed-off-by: Jamie Iles <quic_jiles@quicinc.com>
Reviewed-by: Mark Rutland <mark.rutland@arm.com>
Link: https://lore.kernel.org/r/20230613141959.92697-1-quic_jiles@quicinc.com
[catalin.marinas@arm.com: rename __cpu_set_reserved_ttbr0 to ..._nosync]
[catalin.marinas@arm.com: move the cpu_set_reserved_ttbr0_nosync() call to cpu_do_switch_mm()]
Signed-off-by: Catalin Marinas <catalin.marinas@arm.com>
423 lines
11 KiB
C
423 lines
11 KiB
C
// SPDX-License-Identifier: GPL-2.0-only
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/*
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* Based on arch/arm/mm/context.c
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*
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* Copyright (C) 2002-2003 Deep Blue Solutions Ltd, all rights reserved.
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* Copyright (C) 2012 ARM Ltd.
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*/
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#include <linux/bitfield.h>
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#include <linux/bitops.h>
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#include <linux/sched.h>
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#include <linux/slab.h>
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#include <linux/mm.h>
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#include <asm/cpufeature.h>
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#include <asm/mmu_context.h>
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#include <asm/smp.h>
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#include <asm/tlbflush.h>
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static u32 asid_bits;
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static DEFINE_RAW_SPINLOCK(cpu_asid_lock);
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static atomic64_t asid_generation;
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static unsigned long *asid_map;
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static DEFINE_PER_CPU(atomic64_t, active_asids);
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static DEFINE_PER_CPU(u64, reserved_asids);
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static cpumask_t tlb_flush_pending;
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static unsigned long max_pinned_asids;
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static unsigned long nr_pinned_asids;
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static unsigned long *pinned_asid_map;
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#define ASID_MASK (~GENMASK(asid_bits - 1, 0))
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#define ASID_FIRST_VERSION (1UL << asid_bits)
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#define NUM_USER_ASIDS ASID_FIRST_VERSION
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#define ctxid2asid(asid) ((asid) & ~ASID_MASK)
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#define asid2ctxid(asid, genid) ((asid) | (genid))
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/* Get the ASIDBits supported by the current CPU */
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static u32 get_cpu_asid_bits(void)
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{
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u32 asid;
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int fld = cpuid_feature_extract_unsigned_field(read_cpuid(ID_AA64MMFR0_EL1),
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ID_AA64MMFR0_EL1_ASIDBITS_SHIFT);
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switch (fld) {
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default:
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pr_warn("CPU%d: Unknown ASID size (%d); assuming 8-bit\n",
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smp_processor_id(), fld);
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fallthrough;
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case ID_AA64MMFR0_EL1_ASIDBITS_8:
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asid = 8;
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break;
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case ID_AA64MMFR0_EL1_ASIDBITS_16:
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asid = 16;
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}
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return asid;
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}
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/* Check if the current cpu's ASIDBits is compatible with asid_bits */
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void verify_cpu_asid_bits(void)
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{
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u32 asid = get_cpu_asid_bits();
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if (asid < asid_bits) {
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/*
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* We cannot decrease the ASID size at runtime, so panic if we support
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* fewer ASID bits than the boot CPU.
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*/
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pr_crit("CPU%d: smaller ASID size(%u) than boot CPU (%u)\n",
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smp_processor_id(), asid, asid_bits);
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cpu_panic_kernel();
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}
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}
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static void set_kpti_asid_bits(unsigned long *map)
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{
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unsigned int len = BITS_TO_LONGS(NUM_USER_ASIDS) * sizeof(unsigned long);
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/*
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* In case of KPTI kernel/user ASIDs are allocated in
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* pairs, the bottom bit distinguishes the two: if it
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* is set, then the ASID will map only userspace. Thus
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* mark even as reserved for kernel.
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*/
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memset(map, 0xaa, len);
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}
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static void set_reserved_asid_bits(void)
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{
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if (pinned_asid_map)
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bitmap_copy(asid_map, pinned_asid_map, NUM_USER_ASIDS);
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else if (arm64_kernel_unmapped_at_el0())
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set_kpti_asid_bits(asid_map);
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else
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bitmap_clear(asid_map, 0, NUM_USER_ASIDS);
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}
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#define asid_gen_match(asid) \
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(!(((asid) ^ atomic64_read(&asid_generation)) >> asid_bits))
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static void flush_context(void)
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{
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int i;
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u64 asid;
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/* Update the list of reserved ASIDs and the ASID bitmap. */
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set_reserved_asid_bits();
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for_each_possible_cpu(i) {
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asid = atomic64_xchg_relaxed(&per_cpu(active_asids, i), 0);
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/*
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* If this CPU has already been through a
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* rollover, but hasn't run another task in
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* the meantime, we must preserve its reserved
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* ASID, as this is the only trace we have of
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* the process it is still running.
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*/
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if (asid == 0)
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asid = per_cpu(reserved_asids, i);
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__set_bit(ctxid2asid(asid), asid_map);
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per_cpu(reserved_asids, i) = asid;
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}
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/*
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* Queue a TLB invalidation for each CPU to perform on next
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* context-switch
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*/
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cpumask_setall(&tlb_flush_pending);
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}
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static bool check_update_reserved_asid(u64 asid, u64 newasid)
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{
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int cpu;
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bool hit = false;
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/*
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* Iterate over the set of reserved ASIDs looking for a match.
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* If we find one, then we can update our mm to use newasid
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* (i.e. the same ASID in the current generation) but we can't
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* exit the loop early, since we need to ensure that all copies
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* of the old ASID are updated to reflect the mm. Failure to do
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* so could result in us missing the reserved ASID in a future
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* generation.
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*/
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for_each_possible_cpu(cpu) {
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if (per_cpu(reserved_asids, cpu) == asid) {
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hit = true;
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per_cpu(reserved_asids, cpu) = newasid;
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}
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}
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return hit;
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}
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static u64 new_context(struct mm_struct *mm)
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{
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static u32 cur_idx = 1;
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u64 asid = atomic64_read(&mm->context.id);
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u64 generation = atomic64_read(&asid_generation);
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if (asid != 0) {
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u64 newasid = asid2ctxid(ctxid2asid(asid), generation);
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/*
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* If our current ASID was active during a rollover, we
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* can continue to use it and this was just a false alarm.
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*/
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if (check_update_reserved_asid(asid, newasid))
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return newasid;
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/*
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* If it is pinned, we can keep using it. Note that reserved
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* takes priority, because even if it is also pinned, we need to
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* update the generation into the reserved_asids.
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*/
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if (refcount_read(&mm->context.pinned))
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return newasid;
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/*
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* We had a valid ASID in a previous life, so try to re-use
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* it if possible.
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*/
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if (!__test_and_set_bit(ctxid2asid(asid), asid_map))
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return newasid;
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}
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/*
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* Allocate a free ASID. If we can't find one, take a note of the
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* currently active ASIDs and mark the TLBs as requiring flushes. We
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* always count from ASID #2 (index 1), as we use ASID #0 when setting
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* a reserved TTBR0 for the init_mm and we allocate ASIDs in even/odd
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* pairs.
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*/
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asid = find_next_zero_bit(asid_map, NUM_USER_ASIDS, cur_idx);
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if (asid != NUM_USER_ASIDS)
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goto set_asid;
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/* We're out of ASIDs, so increment the global generation count */
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generation = atomic64_add_return_relaxed(ASID_FIRST_VERSION,
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&asid_generation);
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flush_context();
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/* We have more ASIDs than CPUs, so this will always succeed */
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asid = find_next_zero_bit(asid_map, NUM_USER_ASIDS, 1);
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set_asid:
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__set_bit(asid, asid_map);
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cur_idx = asid;
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return asid2ctxid(asid, generation);
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}
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void check_and_switch_context(struct mm_struct *mm)
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{
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unsigned long flags;
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unsigned int cpu;
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u64 asid, old_active_asid;
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if (system_supports_cnp())
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cpu_set_reserved_ttbr0();
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asid = atomic64_read(&mm->context.id);
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/*
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* The memory ordering here is subtle.
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* If our active_asids is non-zero and the ASID matches the current
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* generation, then we update the active_asids entry with a relaxed
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* cmpxchg. Racing with a concurrent rollover means that either:
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*
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* - We get a zero back from the cmpxchg and end up waiting on the
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* lock. Taking the lock synchronises with the rollover and so
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* we are forced to see the updated generation.
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*
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* - We get a valid ASID back from the cmpxchg, which means the
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* relaxed xchg in flush_context will treat us as reserved
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* because atomic RmWs are totally ordered for a given location.
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*/
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old_active_asid = atomic64_read(this_cpu_ptr(&active_asids));
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if (old_active_asid && asid_gen_match(asid) &&
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atomic64_cmpxchg_relaxed(this_cpu_ptr(&active_asids),
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old_active_asid, asid))
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goto switch_mm_fastpath;
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raw_spin_lock_irqsave(&cpu_asid_lock, flags);
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/* Check that our ASID belongs to the current generation. */
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asid = atomic64_read(&mm->context.id);
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if (!asid_gen_match(asid)) {
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asid = new_context(mm);
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atomic64_set(&mm->context.id, asid);
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}
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cpu = smp_processor_id();
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if (cpumask_test_and_clear_cpu(cpu, &tlb_flush_pending))
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local_flush_tlb_all();
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atomic64_set(this_cpu_ptr(&active_asids), asid);
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raw_spin_unlock_irqrestore(&cpu_asid_lock, flags);
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switch_mm_fastpath:
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arm64_apply_bp_hardening();
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/*
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* Defer TTBR0_EL1 setting for user threads to uaccess_enable() when
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* emulating PAN.
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*/
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if (!system_uses_ttbr0_pan())
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cpu_switch_mm(mm->pgd, mm);
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}
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unsigned long arm64_mm_context_get(struct mm_struct *mm)
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{
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unsigned long flags;
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u64 asid;
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if (!pinned_asid_map)
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return 0;
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raw_spin_lock_irqsave(&cpu_asid_lock, flags);
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asid = atomic64_read(&mm->context.id);
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if (refcount_inc_not_zero(&mm->context.pinned))
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goto out_unlock;
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if (nr_pinned_asids >= max_pinned_asids) {
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asid = 0;
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goto out_unlock;
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}
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if (!asid_gen_match(asid)) {
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/*
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* We went through one or more rollover since that ASID was
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* used. Ensure that it is still valid, or generate a new one.
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*/
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asid = new_context(mm);
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atomic64_set(&mm->context.id, asid);
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}
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nr_pinned_asids++;
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__set_bit(ctxid2asid(asid), pinned_asid_map);
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refcount_set(&mm->context.pinned, 1);
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out_unlock:
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raw_spin_unlock_irqrestore(&cpu_asid_lock, flags);
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asid = ctxid2asid(asid);
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/* Set the equivalent of USER_ASID_BIT */
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if (asid && arm64_kernel_unmapped_at_el0())
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asid |= 1;
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return asid;
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}
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EXPORT_SYMBOL_GPL(arm64_mm_context_get);
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void arm64_mm_context_put(struct mm_struct *mm)
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{
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unsigned long flags;
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u64 asid = atomic64_read(&mm->context.id);
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if (!pinned_asid_map)
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return;
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raw_spin_lock_irqsave(&cpu_asid_lock, flags);
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if (refcount_dec_and_test(&mm->context.pinned)) {
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__clear_bit(ctxid2asid(asid), pinned_asid_map);
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nr_pinned_asids--;
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}
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raw_spin_unlock_irqrestore(&cpu_asid_lock, flags);
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}
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EXPORT_SYMBOL_GPL(arm64_mm_context_put);
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/* Errata workaround post TTBRx_EL1 update. */
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asmlinkage void post_ttbr_update_workaround(void)
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{
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if (!IS_ENABLED(CONFIG_CAVIUM_ERRATUM_27456))
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return;
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asm(ALTERNATIVE("nop; nop; nop",
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"ic iallu; dsb nsh; isb",
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ARM64_WORKAROUND_CAVIUM_27456));
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}
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void cpu_do_switch_mm(phys_addr_t pgd_phys, struct mm_struct *mm)
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{
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unsigned long ttbr1 = read_sysreg(ttbr1_el1);
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unsigned long asid = ASID(mm);
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unsigned long ttbr0 = phys_to_ttbr(pgd_phys);
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/* Skip CNP for the reserved ASID */
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if (system_supports_cnp() && asid)
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ttbr0 |= TTBR_CNP_BIT;
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/* SW PAN needs a copy of the ASID in TTBR0 for entry */
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if (IS_ENABLED(CONFIG_ARM64_SW_TTBR0_PAN))
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ttbr0 |= FIELD_PREP(TTBR_ASID_MASK, asid);
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/* Set ASID in TTBR1 since TCR.A1 is set */
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ttbr1 &= ~TTBR_ASID_MASK;
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ttbr1 |= FIELD_PREP(TTBR_ASID_MASK, asid);
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cpu_set_reserved_ttbr0_nosync();
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write_sysreg(ttbr1, ttbr1_el1);
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write_sysreg(ttbr0, ttbr0_el1);
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isb();
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post_ttbr_update_workaround();
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}
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static int asids_update_limit(void)
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{
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unsigned long num_available_asids = NUM_USER_ASIDS;
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if (arm64_kernel_unmapped_at_el0()) {
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num_available_asids /= 2;
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if (pinned_asid_map)
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set_kpti_asid_bits(pinned_asid_map);
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}
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/*
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* Expect allocation after rollover to fail if we don't have at least
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* one more ASID than CPUs. ASID #0 is reserved for init_mm.
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*/
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WARN_ON(num_available_asids - 1 <= num_possible_cpus());
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pr_info("ASID allocator initialised with %lu entries\n",
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num_available_asids);
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/*
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* There must always be an ASID available after rollover. Ensure that,
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* even if all CPUs have a reserved ASID and the maximum number of ASIDs
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* are pinned, there still is at least one empty slot in the ASID map.
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*/
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max_pinned_asids = num_available_asids - num_possible_cpus() - 2;
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return 0;
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}
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arch_initcall(asids_update_limit);
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static int asids_init(void)
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{
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asid_bits = get_cpu_asid_bits();
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atomic64_set(&asid_generation, ASID_FIRST_VERSION);
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asid_map = bitmap_zalloc(NUM_USER_ASIDS, GFP_KERNEL);
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if (!asid_map)
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panic("Failed to allocate bitmap for %lu ASIDs\n",
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NUM_USER_ASIDS);
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pinned_asid_map = bitmap_zalloc(NUM_USER_ASIDS, GFP_KERNEL);
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nr_pinned_asids = 0;
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/*
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* We cannot call set_reserved_asid_bits() here because CPU
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* caps are not finalized yet, so it is safer to assume KPTI
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* and reserve kernel ASID's from beginning.
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*/
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if (IS_ENABLED(CONFIG_UNMAP_KERNEL_AT_EL0))
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set_kpti_asid_bits(asid_map);
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return 0;
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}
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early_initcall(asids_init);
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