windows-nt/Source/XPSP1/NT/base/ntos/ke/amd64/ctxswap.asm

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title "Context Swap"
;++
;
; Copyright (c) 2000 Microsoft Corporation
;
; Module Name:
;
; ctxswap.asm
;
; Abstract:
;
; This module implements the code necessary to field the dispatch interrupt
; and perform context switching.
;
; Author:
;
; David N. Cutler (davec) 26-Aug-2000
;
; Environment:
;
; Kernel mode only.
;
;--
include ksamd64.inc
extern KeAcquireQueuedSpinLockAtDpcLevel:proc
extern KeAcquireQueuedSpinLockRaiseToSynch:proc
extern KeBugCheck:proc
extern KeReleaseQueuedSpinLock:proc
extern KeReleaseQueuedSpinLockFromDpcLevel:proc
extern KiDeliverApc:proc
extern KiDispatcherLock:qword
extern KiQuantumEnd:proc
extern KiReadyThread:proc
extern KiRetireDpcList:proc
extern __imp_HalRequestSoftwareInterrupt:qword
subttl "Unlock Dispatcher Database"
;++
;
; VOID
; KiUnlockDispatcherDatabase (
; IN KIRQL OldIrql
; )
;
; Routine Description:
;
; This routine is entered at SYNCH_LEVEL with the dispatcher database
; locked. Its function is to either unlock the dispatcher database and
; return or initiate a context switch if another thread has been selected
; for execution.
;
; Arguments:
;
; OldIrql (cl) - Supplies the IRQL when the dispatcher database lock was
; acquired.
;
; Return Value:
;
; None.
;
;--
UdFrame struct
P1Home dq ? ; queued spin lock number parameter
P2Home dq ? ; previous IRQL paramater
SavedIrql db ? ; saved previous IRQL
Fill db 7 dup (?) ; fill to 8 mod 16
UdFrame ends
NESTED_ENTRY KiUnlockDispatcherDatabase, _TEXT$00
alloc_stack (sizeof UdFrame) ; allocate stack frame
END_PROLOGUE
;
; Check if a new thread is scheduled for execution.
;
cmp qword ptr gs:[PcNextThread], 0 ; check if thread scheduled
jne short KiUD30 ; if ne, new thread scheduled
;
; Release dispatcher database lock, lower IRQL to its previous level,
; and return.
;
ifndef NT_UP
KiUD10: mov dl, cl ; set old IRQL value
mov ecx, LockQueueDispatcherLock ; set lock queue number
call KeReleaseQueuedSpinLock ; release dispatcher lock
else
KiUD10: movzx ecx, cl ; set IRQL to previous level
SetIrql ;
endif
add rsp, sizeof UdFrame ; deallocate stack frame
ret ; return
;
; A new thread has been selected to run on the current processor, but the new
; IRQL is not below dispatch level. If the current processor is not executing
; a DPC, then request a dispatch interrupt on the current processor.
;
KiUD20: cmp qword ptr gs:[PcDpcRoutineActive], 0 ; check if DPC routine active
jne short KiUD10 ; if ne, DPC routine is active
mov UdFrame.SavedIrql[rsp], cl ; save previous IRQL
mov cl, DISPATCH_LEVEL ; request dispatch interrupt
call __imp_HalRequestSoftwareInterrupt ;
mov cl, UdFrame.SavedIrql[rsp] ; restore previous IRQL
jmp short KiUD10
;
; Check if the previous IRQL is less than dispatch level.
;
KiUD30: cmp cl, DISPATCH_LEVEL ; check if IRQL below dispatch level
jge short KiUD20 ; if ge, not below dispatch level
add rsp, sizeof UdFrame ; deallocate stack frame
jmp short KxUnlockDispatcherDatabase ; finish in common code
NESTED_END KiUnlockDispatcherDatabase, _TEXT$00
;
; There is a new thread scheduled for execution and the previous IRQL is
; less than dispatch level. Context switch to the new thread immediately.
;
; N.B. The following routine is entered by falling through the from above
; code.
;
; N.B. The following routine is carefully written as a nested function that
; appears to have been called directly by the caller of the above
; function which unlocks the dispatcher database.
;
; Arguments:
;
; OldIrql (cl) - Supplies the IRQL when the dispatcher database lock was
; acquired.
;
NESTED_ENTRY KxUnlockDispatcherDatabase, _TEXT$00
GENERATE_EXCEPTION_FRAME ; generate exception frame
mov rbx, gs:[PcCurrentPrcb] ; get current PRCB address
mov rsi, PbNextThread[rbx] ; get next thread address
mov rdi, PbCurrentThread[rbx] ; get current thread address
and qword ptr PbNextThread[rbx], 0 ; clear next thread address
mov PbCurrentThread[rbx], rsi ; set current thread address
mov ThWaitIrql[rdi], cl ; save previous IRQL
ifndef NT_UP
mov byte ptr ThIdleSwapBlock[rdi], 1 ; block swap from idle
endif
mov rcx, rdi ; set address of current thread
call KiReadyThread ; reready thread for execution
xor eax, eax ; set NPX save false
mov cl, ThWaitIrql[rdi] ; set APC interrupt bypass disable
ifndef NT_UP
xor edx, edx ; set swap from idle false
endif
call SwapContext ; swap context
movzx ecx, byte ptr ThWaitIrql[rsi] ; get original wait IRQL
or al, al ; check if kernel APC pending
jz short KiXD10 ; if z, no kernel APC pending
mov ecx, APC_LEVEL ; set IRQL to APC level
SetIrql ;
xor ecx, ecx ; set previous mode to kernel
xor edx, edx ; clear exception frame address
xor r8, r8 ; clear trap frame address
call KiDeliverApc ; deliver kernel mode APC
xor ecx, ecx ; set original wait IRQL
KiXD10: ; reference label
SetIrql ; set IRQL to previous level
RESTORE_EXCEPTION_STATE ; restore exception state/deallocate
ret ; return
NESTED_END KxUnlockDispatcherDatabase, _TEXT$00
subttl "Swap Context"
;++
;
; BOOLEAN
; KiSwapContext (
; IN PKTHREAD Thread
; )
;
; Routine Description:
;
; This function is a small wrapper that marshalls arguments and calls the
; actual swap context routine.
;
; Arguments:
;
; Thread (rcx) - Supplies the address of the new thread.
;
; Return Value:
;
; If a kernel APC is pending, then a value of TRUE is returned. Otherwise,
; a value of FALSE is returned.
;
;--
NESTED_ENTRY KiSwapContext, _TEXT$00
GENERATE_EXCEPTION_FRAME ; generate exception frame
mov rbx, gs:[PcCurrentPrcb] ; get current PRCB address
mov rsi, rcx ; set next thread address
mov rdi, PbCurrentThread[rbx] ; get current thread address
mov PbCurrentThread[rbx], rsi ; set current thread address
xor eax, eax ; set NPX save false
mov cl, ThWaitIrql[rdi] ; set APC interrupt bypass disable
ifndef NT_UP
xor edx, edx ; set swap from idle false
endif
call SwapContext ; swap context
RESTORE_EXCEPTION_STATE ; restore exception state/deallocate
ret ; return
NESTED_END KiSwapContext, _TEXT$00
subttl "Dispatch Interrupt"
;++
;
; Routine Description:
;
; This routine is entered as the result of a software interrupt generated
; at DISPATCH_LEVEL. Its function is to process the DPC list, and then
; perform a context switch if a new thread has been selected for execution
; on the current processor.
;
; This routine is entered at DISPATCH_LEVEL with the dispatcher database
; unlocked.
;
; Arguments:
;
; None
;
; Return Value:
;
; None.
;
;--
DiFrame struct
P1Home dq ? ; PRCB address parameter
Fill dq ? ; fill to 8 mod 16
SavedRbx dq ? ; saved RBX
DiFrame ends
NESTED_ENTRY KiDispatchInterrupt, _TEXT$00
push_reg rbx ; save nonvolatile register
alloc_stack (sizeof DiFrame - 8) ; allocate stack frame
END_PROLOGUE
mov rbx, gs:[PcCurrentPrcb] ; get current PRCB address
and dword ptr PbDpcInterruptRequested[rbx], 0 ; clear request
;
; Check if the DPC queue has any entries to process.
;
KiDI10: cli ; disable interrupts
mov eax, PbDpcQueueDepth[rbx] ; get DPC queue depth
or eax, PbTimerHand[rbx] ; merge timer hand value
jz short KiDI20 ; if z, no DPCs to process
mov PbSavedRsp[rbx], rsp ; save current stack pointer
mov rsp, PbDpcStack[rbx] ; set DPC stack pointer
mov rcx, rbx ; set PRCB address parameter
call KiRetireDpcList ; process the DPC list
mov rsp, PbSavedRsp[rbx] ; restore current stack pointer
;
; Check to determine if quantum end is requested.
;
KiDI20: sti ; enable interrupts
cmp dword ptr PbQuantumEnd[rbx], 0 ; check if quantum end request
je short KiDI50 ; if e, quantum end not requested
;
; Process quantum end event.
;
; N.B. If a new thread is selected as a result of processing the quantum end
; request, then the new thread is returned with the dispatcher database
; locked. Otherwise, NULL is returned with the dispatcher database
; unlocked.
;
and dword ptr PbQuantumEnd[rbx], 0 ; clear quantum end indicator
call KiQuantumEnd ; process quantum end
test rax, rax ; test if new thread selected
jnz short KiDI60 ; if ne, new thread selected
;
; A new thread has not been selected for execution. Restore nonvolatile
; registers, deallocate stack frame, and return.
;
KiDI30: mov rbx, DiFrame.SavedRbx[rsp] ; restore nonvolatile register
add rsp, sizeof DiFrame ; deallocate stack frame
ret ; return
;
; The dispatch lock could not be acquired. Lower IRQL to dispatch level, and
; loop processing the DPC list and quantum end events.
;
KiDI40: mov ecx, DISPATCH_LEVEL ; set IRQL to DISPATCH_LEVEL
SetIrql ;
jmp short KiDI10 ; try again
;
; Check to determine if a new thread has been selected for execution on this
; processor.
;
KiDI50: cmp qword ptr PbNextThread[rbx], 0 ; check if new thread selected
je short KiDI30 ; if eq, then no new thread
ifndef NT_UP
mov ecx, SYNCH_LEVEL ; set IRQL to SYNCH_LEVEL
SetIrql ;
lea rcx, KiDispatcherLock ; get dispatcher database lock address
lea rdx, PbLockQueue + (16 * LockQueueDispatcherLock)[rbx] ; lock queue
xor eax, eax ; set comperand value to NULL
lock cmpxchg [rcx], rdx ; try to acquire dispatcher lock
jnz short KiDI40 ; if nz, dispatcher lock not acquired
endif
mov rax, PbNextThread[rbx] ; get next thread address
;
; Swap context to a new thread.
;
KiDI60: add rsp, sizeof DiFrame - 8 ; deallocate stack frame
pop rbx ; restore nonvolatile register
jmp short KxDispatchInterrupt ; finish in common code
NESTED_END KiDispatchInterrupt, _TEXT$00
;
; There is a new thread scheduled for execution and the dispatcher lock
; has been acquired. Context switch to the new thread immediately.
;
; N.B. The following routine is entered by falling through from the above
; routine.
;
; N.B. The following routine is carefully written as a nested function that
; appears to have been called directly by the caller of the above
; function which processes the dispatch interrupt.
;
; Arguments:
;
; Thread (rax) - Supplies the address of the next thread to run on the
; current processor.
;
NESTED_ENTRY KxDispatchInterrupt, _TEXT$00
GENERATE_EXCEPTION_FRAME ; generate exception frame
mov rbx, gs:[PcCurrentPrcb] ; get current PRCB address
mov rsi, rax ; set address of next thread
mov rdi, PbCurrentThread[rbx] ; get current thread address
and qword ptr PbNextThread[rbx], 0 ; clear next thread address
mov PbCurrentThread[rbx], rsi ; set current thread address
ifndef NT_UP
mov byte ptr ThIdleSwapBlock[rdi], 1 ; block swap from idle
endif
mov rcx, rdi ; set address of current thread
call KiReadyThread ; reready thread for execution
mov eax, TRUE ; set NPX save true
mov cl, APC_LEVEL ; set APC interrupt bypass disable
ifndef NT_UP
xor edx, edx ; set swap from idle false
endif
call SwapContext ; call context swap routine
RESTORE_EXCEPTION_STATE ; restore exception state/deallocate
ret ; return
NESTED_END KxDispatchInterrupt, _TEXT$00
subttl "Swap Context"
;++
;
; Routine Description:
;
; This routine is called to swap context from one thread to the next. It
; swaps context, flushes the translation buffer, swaps the process address
; space if necessary, and returns to its caller.
;
; N.B. This routine is only called by code within this module and the idle
; thread code and uses special register calling conventions.
;
; Arguments:
;
; al - Supplies a boolean value that determines whether the full legacy
; floating state needs to be saved.
;
; cl - Supplies the APC interrupt bypass disable IRQL value.
;
; edx - Supplies a logical value that specifies whether the context swap
; is being called from the idle thread (MP systems only).
;
; rbx - Supplies the address of the current PRCB.
;
; rdi - Supplies the address of previous thread.
;
; rsi - Supplies the address of next thread.
;
; Return value:
;
; al - Supplies the kernel APC pending flag.
;
; rbx - Supplies the address of the current PRCB.
;
; rsi - Supplies the address of current thread.
;
;--
NESTED_ENTRY SwapContext, _TEXT$00
push_reg rbp ; save nonvolatile register
alloc_stack (KSWITCH_FRAME_LENGTH - (2 * 8)) ; allocate stack frame
END_PROLOGUE
mov SwNpxSave[rsp], al ; save NPX save
mov SwApcBypass[rsp], cl ; save APC bypass disable
;
; Set the new thread state to running.
;
; N.B. The state of the new thread MUST be set to running before releasing
; the dispatcher lock.
;
mov byte ptr ThState[rsi], Running ; set thread state to running
;
; Acquire the context swap lock so the address space of the previous process
; cannot be deleted, then release the dispatcher database lock.
;
; N.B. The context swap lock is used to protect the address space until the
; context switch has sufficiently progressed to the point where the
; previous process address space is no longer needed. This lock is also
; acquired by the reaper thread before it finishes thread termination.
;
ifndef NT_UP
test edx, edx ; test if call from idle thread
jnz short KiSC05 ; if nz, call from idle thread
lea rcx, PbLockQueue + (16 * LockQueueContextSwapLock)[rbx] ; lock queue
call KeAcquireQueuedSpinLockAtDpcLevel ; acquire context swap lock
lea rcx, PbLockQueue + (16 * LockQueueDispatcherLock)[rbx] ; lock queue
call KeReleaseQueuedSpinLockFromDpcLevel ; release dispatcher lock
endif
;
; Check if an attempt is being made to context switch while in a DPC routine.
;
KiSC05: cmp dword ptr PbDpcRoutineActive[rbx], 0 ; check if DPC active
jne KiSC60 ; if ne, DPC is active
;
; Accumulate the total time spent in a thread.
;
ifdef PERF_DATA
rdtsc ; read cycle counter
sub eax, PbThreadStartCount + 0[rbx] ; sub out thread start time
sbb edx, PbThreadStartCount + 4[rbx] ;
add EtPerformanceCountLow[rdi], eax ; accumlate thread run time
adc EtPerformanceCountHigh[rdi], edx ;
add PbThreadStartCount + 4[rbx], eax ; set new thread start time
adc PbThreadStartCount + 8[rbx], edx ;
endif
;
; Save the kernel mode XMM control/status register. If the current thread
; executes in user mode, then also save the legacy floating point state.
;
stmxcsr SwMxCsr[rsp] ; save kernel mode XMM control/status
cmp byte ptr ThNpxState[rdi], UserMode ; check if user mode thread
jne short KiSC10 ; if ne, not user mode thread
mov rbp, ThInitialStack[rdi] ; get previous thread initial stack
cmp byte ptr SwNpxSave[rsp], TRUE ; check if full save required
jne short KiSC07 ; if ne, full save not required
fnsaved [rbp] ; save full legacy floating point state
jmp short KiSC10 ;
;
; Full floating save not required.
;
KiSC07: fnstenvd [rbp] ; save legacy floating environment
;
; Switch kernel stacks.
;
KiSC10: mov ThKernelStack[rdi], rsp ; save old kernel stack pointer
mov rsp, ThKernelStack[rsi] ; get new kernel stack pointer
;
; Swap the process address space if the new process is not the same as the
; previous process.
;
mov rax, ThApcState + AsProcess[rdi] ; get previous process address
cmp rax, ThApcState + AsProcess[rsi] ; check if process address match
je short KiSC20 ; if e, process addresses match
mov r14, ThApcState + AsProcess[rsi] ; get new process address
;
; Update the processor set masks.
;
ifndef NT_UP
mov rcx, PbSetMember[rbx] ; get processor set member
xor PrActiveProcessors[rax], rcx ; clear bit in previous set
xor PrActiveProcessors[r14], rcx ; set bit in new set
if DBG
test PrActiveProcessors[rax], rcx ; test if bit clear in previous set
jnz short @f ; if nz, bit not clear in previous set
test PrActiveProcessors[r14], rcx ; test if bit set in new set
jnz short KiSC15 ; if nz, bit set in new set
@@: int 3 ; debug break - incorrect active mask
endif
endif
;
; Load new CR3 value which will flush the TB and set the IOPM map offset in
; the TSS.
;
KiSC15: mov r15, gs:[PcTss] ; get processor TSS address
mov cx, PrIopmOffset[r14] ; get process IOPM offset
mov TssIoMapBase[r15], cx ; set TSS IOPM offset
mov rax, PrDirectoryTableBase[r14] ; get new directory base
mov cr3, rax ; flush TLB and set new directory base
;
; Release the context swap lock.
;
KiSC20: mov byte ptr ThIdleSwapBlock[rdi], 0 ; unblock swap from idle
ifndef NT_UP
lea rcx, PbLockQueue + (16 * LockQueueContextSwapLock)[rbx] ; lock queue
call KeReleaseQueuedSpinLockFromDpcLevel ; release context swap lock
endif
;
; Set the new kernel stack base in the TSS.
;
mov r15, gs:[PcTss] ; get processor TSS address
mov rbp, ThInitialStack[rsi] ; get new stack base address
mov TssRsp0[r15], rbp ; set stack base address in TSS
;
; If the new thread executes in user mode, then restore the legacy floating
; state, load the compatibility mode TEB address, load the native user mode
; TEB address, and reload the segment registers if needed.
;
; N.B. The upper 32-bits of the compatibility mode TEB address are always
; zero.
;
cmp byte ptr ThNpxState[rsi], UserMode ; check if user mode thread
jne KiSC30 ; if ne, not user mode thread
cmp byte ptr SwNpxSave[rsp], TRUE ; check if full restore required
jne short KiSC22 ; if ne, full restore not required
mov cx, LfControlWord[rbp] ; save current control word
mov word ptr LfControlWord[rbp], 03fh ; set to mask all exceptions
frstord [rbp] ; restore legacy floating point state
mov LfControlWord[rbp], cx ; restore control word
fldcw word ptr LfControlWord[rbp] ; load legacy control word
jmp short KiSC24 ;
;
; Full legacy floating restore not required.
;
KiSC22: fldenv [rbp] ; restore legacy floating environment
;
; Set base of compatibility mode TEB.
;
KiSC24: mov eax, ThTeb[rsi] ; compute compatibility mode TEB address
add eax, CmThreadEnvironmentBlockOffset ;
mov rcx, gs:[PcGdt] ; get GDT base address
mov KgdtBaseLow + KGDT64_R3_CMTEB[rcx], ax ; set CMTEB base address
shr eax, 16 ;
mov KgdtBaseMiddle + KGDT64_R3_CMTEB[rcx], al ;
mov KgdtBaseHigh + KGDT64_R3_CMTEB[rcx], ah ;
;
; If the user segment selectors have been changed, then reload them with
; their cannonical values.
;
mov ax, ds ; compute sum of segment selectors
mov cx, es ;
add ax, cx ;
mov cx, gs ;
add ax, cx ;
cmp ax, ((KGDT64_R3_DATA or RPL_MASK) * 3) ; check if sum matches
je short KiSC25 ; if e, sum matches expected value
mov cx, KGDT64_R3_DATA or RPL_MASK ; reload user segment selectors
mov ds, cx ;
mov es, cx ;
;
; N.B. The following reload of the GS selector destroys the system MSR_GS_BASE
; register. Thus this sequence must be done with interrupt off.
;
mov eax, gs:[PcSelf] ; get current PCR address
mov edx, gs:[PcSelf + 4] ;
cli ; disable interrupts
mov gs, cx ; reload GS segment selector
mov ecx, MSR_GS_BASE ; get GS base MSR number
wrmsr ; write system PCR base address
sti ; enable interrupts
KiSC25: mov ax, KGDT64_R3_CMTEB or RPL_MASK ; reload FS segment selector
mov fs, ax ;
mov eax, ThTeb[rsi] ; get low part of user TEB address
mov edx, ThTeb + 4[rsi] ; get high part of user TEB address
mov gs:[PcTeb], eax ; set user TEB address in PCR
mov gs:[PcTeb + 4], edx ;
mov ecx, MSR_GS_SWAP ; get GS base swap MSR number
wrmsr ; write user TEB base address
;
; Restore kernel mode XMM control/status and update context switch counters.
;
KiSC30: ldmxcsr SwMxCsr[rsp] ; kernel mode XMM control/status
inc dword ptr ThContextSwitches[rsi] ; thread count
inc dword ptr PbContextSwitches[rbx] ; processor count
;
; If the new thread has a kernel mode APC pending, then request an APC
; interrupt if APC bypass is disabled.
;
mov al, ThApcState + AsKernelApcPending[rsi] ; get APC pending
test al, al ; test if kernel APC pending
jz short KiSC50 ; if z, kernel APC not pending
cmp byte ptr SwApcBypass[rsp], APC_LEVEL ; check if APC bypass enabled
jb short KiSC40 ; if b, APC bypass is enabled
mov cl, APC_LEVEL ; request APC interrupt
call __imp_HalRequestSoftwareInterrupt ;
clc ; clear carry flag
KiSC40: setb al ; set return value
KiSC50: add rsp, KSWITCH_FRAME_LENGTH - (2 * 8) ; deallocate stack frame
pop rbp ; restore nonvolatile register
ret ; return
;
; An attempt is being made to context switch while in a DPC routine. This is
; most likely caused by a DPC routine calling one of the wait functions.
;
KiSC60: mov ecx, ATTEMPTED_SWITCH_FROM_DPC ; set bug check code
call KeBugCheck ; bug check system - no return
ret ; return
NESTED_END SwapContext, _TEXT$00
end