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Reported-by: Hulk Robot <hulkci@huawei.com> Signed-off-by: He Ying <heying24@huawei.com> Acked-by: Michael Ellerman <mpe@ellerman.id.au> Link: https://lore.kernel.org/r/20210326100853.173586-1-heying24@huawei.com Signed-off-by: Jonathan Corbet <corbet@lwn.net>
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275 lines
11 KiB
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============================
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Transactional Memory support
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============================
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POWER kernel support for this feature is currently limited to supporting
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its use by user programs. It is not currently used by the kernel itself.
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This file aims to sum up how it is supported by Linux and what behaviour you
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can expect from your user programs.
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Basic overview
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==============
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Hardware Transactional Memory is supported on POWER8 processors, and is a
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feature that enables a different form of atomic memory access. Several new
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instructions are presented to delimit transactions; transactions are
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guaranteed to either complete atomically or roll back and undo any partial
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changes.
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A simple transaction looks like this::
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begin_move_money:
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tbegin
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beq abort_handler
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ld r4, SAVINGS_ACCT(r3)
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ld r5, CURRENT_ACCT(r3)
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subi r5, r5, 1
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addi r4, r4, 1
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std r4, SAVINGS_ACCT(r3)
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std r5, CURRENT_ACCT(r3)
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tend
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b continue
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abort_handler:
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... test for odd failures ...
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/* Retry the transaction if it failed because it conflicted with
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* someone else: */
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b begin_move_money
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The 'tbegin' instruction denotes the start point, and 'tend' the end point.
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Between these points the processor is in 'Transactional' state; any memory
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references will complete in one go if there are no conflicts with other
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transactional or non-transactional accesses within the system. In this
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example, the transaction completes as though it were normal straight-line code
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IF no other processor has touched SAVINGS_ACCT(r3) or CURRENT_ACCT(r3); an
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atomic move of money from the current account to the savings account has been
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performed. Even though the normal ld/std instructions are used (note no
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lwarx/stwcx), either *both* SAVINGS_ACCT(r3) and CURRENT_ACCT(r3) will be
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updated, or neither will be updated.
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If, in the meantime, there is a conflict with the locations accessed by the
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transaction, the transaction will be aborted by the CPU. Register and memory
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state will roll back to that at the 'tbegin', and control will continue from
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'tbegin+4'. The branch to abort_handler will be taken this second time; the
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abort handler can check the cause of the failure, and retry.
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Checkpointed registers include all GPRs, FPRs, VRs/VSRs, LR, CCR/CR, CTR, FPCSR
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and a few other status/flag regs; see the ISA for details.
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Causes of transaction aborts
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============================
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- Conflicts with cache lines used by other processors
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- Signals
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- Context switches
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- See the ISA for full documentation of everything that will abort transactions.
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Syscalls
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========
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Syscalls made from within an active transaction will not be performed and the
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transaction will be doomed by the kernel with the failure code TM_CAUSE_SYSCALL
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| TM_CAUSE_PERSISTENT.
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Syscalls made from within a suspended transaction are performed as normal and
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the transaction is not explicitly doomed by the kernel. However, what the
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kernel does to perform the syscall may result in the transaction being doomed
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by the hardware. The syscall is performed in suspended mode so any side
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effects will be persistent, independent of transaction success or failure. No
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guarantees are provided by the kernel about which syscalls will affect
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transaction success.
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Care must be taken when relying on syscalls to abort during active transactions
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if the calls are made via a library. Libraries may cache values (which may
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give the appearance of success) or perform operations that cause transaction
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failure before entering the kernel (which may produce different failure codes).
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Examples are glibc's getpid() and lazy symbol resolution.
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Signals
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=======
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Delivery of signals (both sync and async) during transactions provides a second
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thread state (ucontext/mcontext) to represent the second transactional register
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state. Signal delivery 'treclaim's to capture both register states, so signals
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abort transactions. The usual ucontext_t passed to the signal handler
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represents the checkpointed/original register state; the signal appears to have
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arisen at 'tbegin+4'.
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If the sighandler ucontext has uc_link set, a second ucontext has been
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delivered. For future compatibility the MSR.TS field should be checked to
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determine the transactional state -- if so, the second ucontext in uc->uc_link
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represents the active transactional registers at the point of the signal.
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For 64-bit processes, uc->uc_mcontext.regs->msr is a full 64-bit MSR and its TS
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field shows the transactional mode.
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For 32-bit processes, the mcontext's MSR register is only 32 bits; the top 32
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bits are stored in the MSR of the second ucontext, i.e. in
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uc->uc_link->uc_mcontext.regs->msr. The top word contains the transactional
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state TS.
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However, basic signal handlers don't need to be aware of transactions
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and simply returning from the handler will deal with things correctly:
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Transaction-aware signal handlers can read the transactional register state
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from the second ucontext. This will be necessary for crash handlers to
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determine, for example, the address of the instruction causing the SIGSEGV.
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Example signal handler::
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void crash_handler(int sig, siginfo_t *si, void *uc)
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{
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ucontext_t *ucp = uc;
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ucontext_t *transactional_ucp = ucp->uc_link;
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if (ucp_link) {
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u64 msr = ucp->uc_mcontext.regs->msr;
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/* May have transactional ucontext! */
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#ifndef __powerpc64__
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msr |= ((u64)transactional_ucp->uc_mcontext.regs->msr) << 32;
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#endif
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if (MSR_TM_ACTIVE(msr)) {
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/* Yes, we crashed during a transaction. Oops. */
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fprintf(stderr, "Transaction to be restarted at 0x%llx, but "
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"crashy instruction was at 0x%llx\n",
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ucp->uc_mcontext.regs->nip,
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transactional_ucp->uc_mcontext.regs->nip);
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}
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}
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fix_the_problem(ucp->dar);
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}
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When in an active transaction that takes a signal, we need to be careful with
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the stack. It's possible that the stack has moved back up after the tbegin.
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The obvious case here is when the tbegin is called inside a function that
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returns before a tend. In this case, the stack is part of the checkpointed
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transactional memory state. If we write over this non transactionally or in
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suspend, we are in trouble because if we get a tm abort, the program counter and
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stack pointer will be back at the tbegin but our in memory stack won't be valid
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anymore.
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To avoid this, when taking a signal in an active transaction, we need to use
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the stack pointer from the checkpointed state, rather than the speculated
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state. This ensures that the signal context (written tm suspended) will be
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written below the stack required for the rollback. The transaction is aborted
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because of the treclaim, so any memory written between the tbegin and the
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signal will be rolled back anyway.
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For signals taken in non-TM or suspended mode, we use the
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normal/non-checkpointed stack pointer.
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Any transaction initiated inside a sighandler and suspended on return
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from the sighandler to the kernel will get reclaimed and discarded.
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Failure cause codes used by kernel
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==================================
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These are defined in <asm/reg.h>, and distinguish different reasons why the
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kernel aborted a transaction:
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====================== ================================
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TM_CAUSE_RESCHED Thread was rescheduled.
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TM_CAUSE_TLBI Software TLB invalid.
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TM_CAUSE_FAC_UNAV FP/VEC/VSX unavailable trap.
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TM_CAUSE_SYSCALL Syscall from active transaction.
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TM_CAUSE_SIGNAL Signal delivered.
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TM_CAUSE_MISC Currently unused.
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TM_CAUSE_ALIGNMENT Alignment fault.
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TM_CAUSE_EMULATE Emulation that touched memory.
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====================== ================================
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These can be checked by the user program's abort handler as TEXASR[0:7]. If
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bit 7 is set, it indicates that the error is considered persistent. For example
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a TM_CAUSE_ALIGNMENT will be persistent while a TM_CAUSE_RESCHED will not.
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GDB
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===
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GDB and ptrace are not currently TM-aware. If one stops during a transaction,
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it looks like the transaction has just started (the checkpointed state is
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presented). The transaction cannot then be continued and will take the failure
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handler route. Furthermore, the transactional 2nd register state will be
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inaccessible. GDB can currently be used on programs using TM, but not sensibly
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in parts within transactions.
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POWER9
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======
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TM on POWER9 has issues with storing the complete register state. This
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is described in this commit::
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commit 4bb3c7a0208fc13ca70598efd109901a7cd45ae7
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Author: Paul Mackerras <paulus@ozlabs.org>
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Date: Wed Mar 21 21:32:01 2018 +1100
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KVM: PPC: Book3S HV: Work around transactional memory bugs in POWER9
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To account for this different POWER9 chips have TM enabled in
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different ways.
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On POWER9N DD2.01 and below, TM is disabled. ie
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HWCAP2[PPC_FEATURE2_HTM] is not set.
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On POWER9N DD2.1 TM is configured by firmware to always abort a
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transaction when tm suspend occurs. So tsuspend will cause a
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transaction to be aborted and rolled back. Kernel exceptions will also
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cause the transaction to be aborted and rolled back and the exception
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will not occur. If userspace constructs a sigcontext that enables TM
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suspend, the sigcontext will be rejected by the kernel. This mode is
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advertised to users with HWCAP2[PPC_FEATURE2_HTM_NO_SUSPEND] set.
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HWCAP2[PPC_FEATURE2_HTM] is not set in this mode.
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On POWER9N DD2.2 and above, KVM and POWERVM emulate TM for guests (as
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described in commit 4bb3c7a0208f), hence TM is enabled for guests
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ie. HWCAP2[PPC_FEATURE2_HTM] is set for guest userspace. Guests that
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makes heavy use of TM suspend (tsuspend or kernel suspend) will result
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in traps into the hypervisor and hence will suffer a performance
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degradation. Host userspace has TM disabled
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ie. HWCAP2[PPC_FEATURE2_HTM] is not set. (although we make enable it
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at some point in the future if we bring the emulation into host
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userspace context switching).
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POWER9C DD1.2 and above are only available with POWERVM and hence
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Linux only runs as a guest. On these systems TM is emulated like on
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POWER9N DD2.2.
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Guest migration from POWER8 to POWER9 will work with POWER9N DD2.2 and
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POWER9C DD1.2. Since earlier POWER9 processors don't support TM
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emulation, migration from POWER8 to POWER9 is not supported there.
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Kernel implementation
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=====================
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h/rfid mtmsrd quirk
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-------------------
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As defined in the ISA, rfid has a quirk which is useful in early
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exception handling. When in a userspace transaction and we enter the
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kernel via some exception, MSR will end up as TM=0 and TS=01 (ie. TM
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off but TM suspended). Regularly the kernel will want change bits in
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the MSR and will perform an rfid to do this. In this case rfid can
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have SRR0 TM = 0 and TS = 00 (ie. TM off and non transaction) and the
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resulting MSR will retain TM = 0 and TS=01 from before (ie. stay in
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suspend). This is a quirk in the architecture as this would normally
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be a transition from TS=01 to TS=00 (ie. suspend -> non transactional)
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which is an illegal transition.
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This quirk is described the architecture in the definition of rfid
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with these lines:
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if (MSR 29:31 ¬ = 0b010 | SRR1 29:31 ¬ = 0b000) then
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MSR 29:31 <- SRR1 29:31
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hrfid and mtmsrd have the same quirk.
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The Linux kernel uses this quirk in its early exception handling.
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