Documentation/powerpc/transactional_memory.txt - linux - Git at Google

 Transactional Memory support
 ============================

 POWER kernel support for this feature is currently limited to supporting
 its use by user programs.  It is not currently used by the kernel itself.

 This file aims to sum up how it is supported by Linux and what behaviour you
 can expect from your user programs.


 Basic overview
 ==============

 Hardware Transactional Memory is supported on POWER8 processors, and is a
 feature that enables a different form of atomic memory access.  Several new
 instructions are presented to delimit transactions; transactions are
 guaranteed to either complete atomically or roll back and undo any partial
 changes.

 A simple transaction looks like this:

 begin_move_money:
   tbegin
   beq   abort_handler

   ld    r4, SAVINGS_ACCT(r3)
   ld    r5, CURRENT_ACCT(r3)
   subi  r5, r5, 1
   addi  r4, r4, 1
   std   r4, SAVINGS_ACCT(r3)
   std   r5, CURRENT_ACCT(r3)

   tend

   b     continue

 abort_handler:
   ... test for odd failures ...

   /* Retry the transaction if it failed because it conflicted with
    * someone else: */
   b     begin_move_money


 The 'tbegin' instruction denotes the start point, and 'tend' the end point.
 Between these points the processor is in 'Transactional' state; any memory
 references will complete in one go if there are no conflicts with other
 transactional or non-transactional accesses within the system.  In this
 example, the transaction completes as though it were normal straight-line code
 IF no other processor has touched SAVINGS_ACCT(r3) or CURRENT_ACCT(r3); an
 atomic move of money from the current account to the savings account has been
 performed.  Even though the normal ld/std instructions are used (note no
 lwarx/stwcx), either *both* SAVINGS_ACCT(r3) and CURRENT_ACCT(r3) will be
 updated, or neither will be updated.

 If, in the meantime, there is a conflict with the locations accessed by the
 transaction, the transaction will be aborted by the CPU.  Register and memory
 state will roll back to that at the 'tbegin', and control will continue from
 'tbegin+4'.  The branch to abort_handler will be taken this second time; the
 abort handler can check the cause of the failure, and retry.

 Checkpointed registers include all GPRs, FPRs, VRs/VSRs, LR, CCR/CR, CTR, FPCSR
 and a few other status/flag regs; see the ISA for details.

 Causes of transaction aborts
 ============================

 - Conflicts with cache lines used by other processors
 - Signals
 - Context switches
 - See the ISA for full documentation of everything that will abort transactions.


 Syscalls
 ========

 Performing syscalls from within transaction is not recommended, and can lead
 to unpredictable results.

 Syscalls do not by design abort transactions, but beware: The kernel code will
 not be running in transactional state.  The effect of syscalls will always
 remain visible, but depending on the call they may abort your transaction as a
 side-effect, read soon-to-be-aborted transactional data that should not remain
 invisible, etc.  If you constantly retry a transaction that constantly aborts
 itself by calling a syscall, you'll have a livelock & make no progress.

 Simple syscalls (e.g. sigprocmask()) "could" be OK.  Even things like write()
 from, say, printf() should be OK as long as the kernel does not access any
 memory that was accessed transactionally.

 Consider any syscalls that happen to work as debug-only -- not recommended for
 production use.  Best to queue them up till after the transaction is over.


 Signals
 =======

 Delivery of signals (both sync and async) during transactions provides a second
 thread state (ucontext/mcontext) to represent the second transactional register
 state.  Signal delivery 'treclaim's to capture both register states, so signals
 abort transactions.  The usual ucontext_t passed to the signal handler
 represents the checkpointed/original register state; the signal appears to have
 arisen at 'tbegin+4'.

 If the sighandler ucontext has uc_link set, a second ucontext has been
 delivered.  For future compatibility the MSR.TS field should be checked to
 determine the transactional state -- if so, the second ucontext in uc->uc_link
 represents the active transactional registers at the point of the signal.

 For 64-bit processes, uc->uc_mcontext.regs->msr is a full 64-bit MSR and its TS
 field shows the transactional mode.

 For 32-bit processes, the mcontext's MSR register is only 32 bits; the top 32
 bits are stored in the MSR of the second ucontext, i.e. in
 uc->uc_link->uc_mcontext.regs->msr.  The top word contains the transactional
 state TS.

 However, basic signal handlers don't need to be aware of transactions
 and simply returning from the handler will deal with things correctly:

 Transaction-aware signal handlers can read the transactional register state
 from the second ucontext.  This will be necessary for crash handlers to
 determine, for example, the address of the instruction causing the SIGSEGV.

 Example signal handler:

     void crash_handler(int sig, siginfo_t *si, void *uc)
     {
       ucontext_t *ucp = uc;
       ucontext_t *transactional_ucp = ucp->uc_link;

       if (ucp_link) {
         u64 msr = ucp->uc_mcontext.regs->msr;
         /* May have transactional ucontext! */
 #ifndef __powerpc64__
         msr |= ((u64)transactional_ucp->uc_mcontext.regs->msr) << 32;
 #endif
         if (MSR_TM_ACTIVE(msr)) {
            /* Yes, we crashed during a transaction.  Oops. */
    fprintf(stderr, "Transaction to be restarted at 0x%llx, but "
                            "crashy instruction was at 0x%llx\n",
                            ucp->uc_mcontext.regs->nip,
                            transactional_ucp->uc_mcontext.regs->nip);
         }
       }

       fix_the_problem(ucp->dar);
     }

 When in an active transaction that takes a signal, we need to be careful with
 the stack.  It's possible that the stack has moved back up after the tbegin.
 The obvious case here is when the tbegin is called inside a function that
 returns before a tend.  In this case, the stack is part of the checkpointed
 transactional memory state.  If we write over this non transactionally or in
 suspend, we are in trouble because if we get a tm abort, the program counter and
 stack pointer will be back at the tbegin but our in memory stack won't be valid
 anymore.

 To avoid this, when taking a signal in an active transaction, we need to use
 the stack pointer from the checkpointed state, rather than the speculated
 state.  This ensures that the signal context (written tm suspended) will be
 written below the stack required for the rollback.  The transaction is aborted
 because of the treclaim, so any memory written between the tbegin and the
 signal will be rolled back anyway.

 For signals taken in non-TM or suspended mode, we use the
 normal/non-checkpointed stack pointer.


 Failure cause codes used by kernel
 ==================================

 These are defined in <asm/reg.h>, and distinguish different reasons why the
 kernel aborted a transaction:

  TM_CAUSE_RESCHED       Thread was rescheduled.
  TM_CAUSE_TLBI          Software TLB invalide.
  TM_CAUSE_FAC_UNAV      FP/VEC/VSX unavailable trap.
  TM_CAUSE_SYSCALL       Currently unused; future syscalls that must abort
                         transactions for consistency will use this.
  TM_CAUSE_SIGNAL        Signal delivered.
  TM_CAUSE_MISC          Currently unused.
  TM_CAUSE_ALIGNMENT     Alignment fault.
  TM_CAUSE_EMULATE       Emulation that touched memory.

 These can be checked by the user program's abort handler as TEXASR[0:7].  If
 bit 7 is set, it indicates that the error is consider persistent.  For example
 a TM_CAUSE_ALIGNMENT will be persistent while a TM_CAUSE_RESCHED will not.q

 GDB
 ===

 GDB and ptrace are not currently TM-aware.  If one stops during a transaction,
 it looks like the transaction has just started (the checkpointed state is
 presented).  The transaction cannot then be continued and will take the failure
 handler route.  Furthermore, the transactional 2nd register state will be
 inaccessible.  GDB can currently be used on programs using TM, but not sensibly
 in parts within transactions.
	Transactional Memory support
	============================

	POWER kernel support for this feature is currently limited to supporting
	its use by user programs. It is not currently used by the kernel itself.

	This file aims to sum up how it is supported by Linux and what behaviour you
	can expect from your user programs.


	Basic overview
	==============

	Hardware Transactional Memory is supported on POWER8 processors, and is a
	feature that enables a different form of atomic memory access. Several new
	instructions are presented to delimit transactions; transactions are
	guaranteed to either complete atomically or roll back and undo any partial
	changes.

	A simple transaction looks like this:

	begin_move_money:
	tbegin
	beq abort_handler

	ld r4, SAVINGS_ACCT(r3)
	ld r5, CURRENT_ACCT(r3)
	subi r5, r5, 1
	addi r4, r4, 1
	std r4, SAVINGS_ACCT(r3)
	std r5, CURRENT_ACCT(r3)

	tend

	b continue

	abort_handler:
	... test for odd failures ...

	/* Retry the transaction if it failed because it conflicted with
	* someone else: */
	b begin_move_money


	The 'tbegin' instruction denotes the start point, and 'tend' the end point.
	Between these points the processor is in 'Transactional' state; any memory
	references will complete in one go if there are no conflicts with other
	transactional or non-transactional accesses within the system. In this
	example, the transaction completes as though it were normal straight-line code
	IF no other processor has touched SAVINGS_ACCT(r3) or CURRENT_ACCT(r3); an
	atomic move of money from the current account to the savings account has been
	performed. Even though the normal ld/std instructions are used (note no
	lwarx/stwcx), either both SAVINGS_ACCT(r3) and CURRENT_ACCT(r3) will be
	updated, or neither will be updated.

	If, in the meantime, there is a conflict with the locations accessed by the
	transaction, the transaction will be aborted by the CPU. Register and memory
	state will roll back to that at the 'tbegin', and control will continue from
	'tbegin+4'. The branch to abort_handler will be taken this second time; the
	abort handler can check the cause of the failure, and retry.

	Checkpointed registers include all GPRs, FPRs, VRs/VSRs, LR, CCR/CR, CTR, FPCSR
	and a few other status/flag regs; see the ISA for details.

	Causes of transaction aborts
	============================

	- Conflicts with cache lines used by other processors
	- Signals
	- Context switches
	- See the ISA for full documentation of everything that will abort transactions.


	Syscalls
	========

	Performing syscalls from within transaction is not recommended, and can lead
	to unpredictable results.

	Syscalls do not by design abort transactions, but beware: The kernel code will
	not be running in transactional state. The effect of syscalls will always
	remain visible, but depending on the call they may abort your transaction as a
	side-effect, read soon-to-be-aborted transactional data that should not remain
	invisible, etc. If you constantly retry a transaction that constantly aborts
	itself by calling a syscall, you'll have a livelock & make no progress.

	Simple syscalls (e.g. sigprocmask()) "could" be OK. Even things like write()
	from, say, printf() should be OK as long as the kernel does not access any
	memory that was accessed transactionally.

	Consider any syscalls that happen to work as debug-only -- not recommended for
	production use. Best to queue them up till after the transaction is over.


	Signals
	=======

	Delivery of signals (both sync and async) during transactions provides a second
	thread state (ucontext/mcontext) to represent the second transactional register
	state. Signal delivery 'treclaim's to capture both register states, so signals
	abort transactions. The usual ucontext_t passed to the signal handler
	represents the checkpointed/original register state; the signal appears to have
	arisen at 'tbegin+4'.

	If the sighandler ucontext has uc_link set, a second ucontext has been
	delivered. For future compatibility the MSR.TS field should be checked to
	determine the transactional state -- if so, the second ucontext in uc->uc_link
	represents the active transactional registers at the point of the signal.

	For 64-bit processes, uc->uc_mcontext.regs->msr is a full 64-bit MSR and its TS
	field shows the transactional mode.

	For 32-bit processes, the mcontext's MSR register is only 32 bits; the top 32
	bits are stored in the MSR of the second ucontext, i.e. in
	uc->uc_link->uc_mcontext.regs->msr. The top word contains the transactional
	state TS.

	However, basic signal handlers don't need to be aware of transactions
	and simply returning from the handler will deal with things correctly:

	Transaction-aware signal handlers can read the transactional register state
	from the second ucontext. This will be necessary for crash handlers to
	determine, for example, the address of the instruction causing the SIGSEGV.

	Example signal handler:

	void crash_handler(int sig, siginfo_t si, void uc)
	{
	ucontext_t *ucp = uc;
	ucontext_t *transactional_ucp = ucp->uc_link;

	if (ucp_link) {
	u64 msr = ucp->uc_mcontext.regs->msr;
	/* May have transactional ucontext! */
	#ifndef __powerpc64__
	msr \|= ((u64)transactional_ucp->uc_mcontext.regs->msr) << 32;
	#endif
	if (MSR_TM_ACTIVE(msr)) {
	/* Yes, we crashed during a transaction. Oops. */
	fprintf(stderr, "Transaction to be restarted at 0x%llx, but "
	"crashy instruction was at 0x%llx\n",
	ucp->uc_mcontext.regs->nip,
	transactional_ucp->uc_mcontext.regs->nip);
	}
	}

	fix_the_problem(ucp->dar);
	}

	When in an active transaction that takes a signal, we need to be careful with
	the stack. It's possible that the stack has moved back up after the tbegin.
	The obvious case here is when the tbegin is called inside a function that
	returns before a tend. In this case, the stack is part of the checkpointed
	transactional memory state. If we write over this non transactionally or in
	suspend, we are in trouble because if we get a tm abort, the program counter and
	stack pointer will be back at the tbegin but our in memory stack won't be valid
	anymore.

	To avoid this, when taking a signal in an active transaction, we need to use
	the stack pointer from the checkpointed state, rather than the speculated
	state. This ensures that the signal context (written tm suspended) will be
	written below the stack required for the rollback. The transaction is aborted
	because of the treclaim, so any memory written between the tbegin and the
	signal will be rolled back anyway.

	For signals taken in non-TM or suspended mode, we use the
	normal/non-checkpointed stack pointer.


	Failure cause codes used by kernel
	==================================

	These are defined in <asm/reg.h>, and distinguish different reasons why the
	kernel aborted a transaction:

	TM_CAUSE_RESCHED Thread was rescheduled.
	TM_CAUSE_TLBI Software TLB invalide.
	TM_CAUSE_FAC_UNAV FP/VEC/VSX unavailable trap.
	TM_CAUSE_SYSCALL Currently unused; future syscalls that must abort
	transactions for consistency will use this.
	TM_CAUSE_SIGNAL Signal delivered.
	TM_CAUSE_MISC Currently unused.
	TM_CAUSE_ALIGNMENT Alignment fault.
	TM_CAUSE_EMULATE Emulation that touched memory.

	These can be checked by the user program's abort handler as TEXASR[0:7]. If
	bit 7 is set, it indicates that the error is consider persistent. For example
	a TM_CAUSE_ALIGNMENT will be persistent while a TM_CAUSE_RESCHED will not.q

	GDB
	===

	GDB and ptrace are not currently TM-aware. If one stops during a transaction,
	it looks like the transaction has just started (the checkpointed state is
	presented). The transaction cannot then be continued and will take the failure
	handler route. Furthermore, the transactional 2nd register state will be
	inaccessible. GDB can currently be used on programs using TM, but not sensibly
	in parts within transactions.