windows-nt/Source/XPSP1/NT/base/ntdll/alpha/critsect.s

425 lines
15 KiB
ArmAsm
Raw Permalink Normal View History

2020-09-26 03:20:57 -05:00
// TITLE("Enter and Leave Critical Section")
//++
//
// Copyright (c) 1991 Microsoft Corporation
// Copyright (c) 1992 Digital Equipment Corporation
//
// Module Name:
//
// critsect.s
//
// Abstract:
//
// This module implements functions to support user mode critical sections.
//
// Author:
//
// David N. Cutler 1-May-1992
//
// Environment:
//
// Any mode.
//
// Revision History:
//
// Thomas Van Baak (tvb) 21-May-1992
//
// Adapted for Alpha AXP.
//
//--
#include "ksalpha.h"
SBTTL("Enter Critical Section")
//++
//
// NTSTATUS
// RtlEnterCriticalSection (
// IN PRTL_CRITICAL_SECTION CriticalSection
// )
//
// Routine Description:
//
// This function enters a critical section.
//
// N.B. This function is duplicated in the runtime library.
//
// Arguments:
//
// CriticalSection (a0) - Supplies a pointer to a critical section.
//
// Return Value:
//
// STATUS_SUCCESS is returned as the function value.
//
//--
.struct 0
EcRa: .space 8 // saved return address
EcA0: .space 8 // saved critical section address
EcA1: .space 8 // saved unique thread id
.space 1 * 8 // required for 16-byte stack alignment
EcFrameLength: // length of stack frame
NESTED_ENTRY(RtlEnterCriticalSection, EcFrameLength, zero)
lda sp, -EcFrameLength(sp) // allocate stack frame
stq ra, EcRa(sp) // save return address
PROLOGUE_END
GET_THREAD_ENVIRONMENT_BLOCK // (PALcode) get TEB address in v0
ldl t3, CsSpinCount(a0) // check if spin count is zero
LDP a1, TeClientId + CidUniqueThread(v0) // get current thread id
bne t3, 50f // if ne, spin count specified
//
// Attempt to enter the critical section.
//
10: ldl_l t0, CsLockCount(a0) // get addend value - locked
addl t0, 1, t0 // increment addend value
mov t0, t1 //
stl_c t1, CsLockCount(a0) // store conditionally
beq t1, 40f // if eq, conditional store failed
mb // synchronize memory access
//
// If the critical section is not already owned, then initialize the owner
// thread id, initialize the recursion count, and return a success status.
// The updated lock value is now in t0.
//
bne t0, 20f // if ne, lock already owned
STP a1, CsOwningThread(a0) // set critical section owner
ldil v0, STATUS_SUCCESS // set return status
lda sp, EcFrameLength(sp) // deallocate stack frame
ret zero, (ra) // return
//
// The critical section is owned. If the current thread is the owner, then
// increment the recursion count, and return a success status. Otherwise,
// wait for critical section ownership.
// The current thread unique id is in a1.
//
20: LDP t0, CsOwningThread(a0) // get unique id of owner thread
cmpeq a1, t0, t1 // check if current thread is owner
beq t1, 30f // if eq, current thread not owner
ldl t0, CsRecursionCount(a0) // increment the recursion count
addl t0, 1, t2 //
stl t2, CsRecursionCount(a0) //
ldil v0, STATUS_SUCCESS // set return status
lda sp, EcFrameLength(sp) // deallocate stack frame
ret zero, (ra) // return
//
// The critical section is owned by a thread other than the current thread.
// Wait for ownership of the critical section.
// N.B. a1 is just a temp register below, not an argument to the function.
//
30: stq a0, EcA0(sp) // save address of critical section
stq a1, EcA1(sp) // save unique thread id
bsr ra, RtlpWaitForCriticalSection // wait for critical section
ldq a0, EcA0(sp) // restore address of critical section
ldq a1, EcA1(sp) // restore unique thread id
STP a1, CsOwningThread(a0) // set critical section owner
ldil v0, STATUS_SUCCESS // set return status
ldq ra, EcRa(sp) // restore return address
lda sp, EcFrameLength(sp) // deallocate stack frame
ret zero, (ra) // return
//
// We expect the store conditional will usually succeed the first time so it
// is faster to branch forward (predicted not taken) to here and then branch
// backward (predicted taken) to where we wanted to go.
//
40: br zero, 10b // go try lock again
//
// A nonzero spin count is specified
//
50: LDP t4, CsOwningThread(a0) // get owner thread id
cmpeq t4, a1, t5 // check if current thread is owner
beq t5, 60f // if eq, current thread not owner
//
// The critical section is owned by the current thread. Increment the lock
// count and the recursion count.
//
55: ldl_l t0, CsLockCount(a0) // get addend value - locked
addl t0, 1, t1 // increment addend value
stl_c t1, CsLockCount(a0) // store conditionally
beq t1, 59f // if lock-flag eq zero, store failed
mb // synchronize memory access
ldl t3, CsRecursionCount(a0) // increment recursion count
addl t3, 1, t4 //
stl t4, CsRecursionCount(a0) //
ldil v0, STATUS_SUCCESS // set return status
lda sp, EcFrameLength(sp) // deallocate stack frame
ret zero, (ra) // return
//
// Store conditional attempt failed.
//
59: br zero, 55b // go try lock again
//
// A nonzero spin count is specified and the current thread is not the owner.
//
60: ldl_l t0, CsLockCount(a0) // get addend value - locked
addl t0, 1, t1 // increment addend value
bne t1, 70f // if ne, critical section is owned
stl_c t1, CsLockCount(a0) // set new lock count
beq t1, 69f // if eq, conditional store failed
mb // synchronize memory access
//
// The critical section has been acquired. Set the owning thread and the initial
// recursion count.
//
STP a1, CsOwningThread(a0) // set critical section owner
ldil v0, STATUS_SUCCESS // set return status
lda sp, EcFrameLength(sp) // deallocate stack frame
ret zero, (ra) // return
//
// Store conditional attempt failed.
//
69: br zero, 60b //
//
// The critical section is currently owned. Spin until it is either unowned
// or the spin count has reached zero. Spin count is in t3
//
// If waiters are present, don't spin on the lock since we will never see it
// go free.
//
70: ldl t0, CsLockCount(a0) // check if lock is owned
addl t0, 1, t1 //
bgt t0, 10b // if >=, then do not spin
beq t1, 60b // if eq, lock is not owned
subl t3, 1, t3 // decrement spin count
bne t3, 70b // if nz, continue spinning
br 10b // spin expired, go wait for lock
.end RtlEnterCriticalSection
SBTTL("Leave Critical Section")
//++
//
// NTSTATUS
// RtlLeaveCriticalSection (
// IN PRTL_CRITICAL_SECTION CriticalSection
// )
//
// Routine Description:
//
// This function leaves a critical section.
//
// N.B. This function is duplicated in the runtime library.
//
// Arguments:
//
// CriticalSection (a0) - Supplies a pointer to a critical section.
//
// Return Value:
//
// STATUS_SUCCESS is returned as the function value.
//
//--
.struct 0
LcRa: .space 8 // saved return address
.space 1 * 8 // required for 16-byte stack alignment
LcFrameLength: // length of stack frame
NESTED_ENTRY(RtlLeaveCriticalSection, LcFrameLength, zero)
lda sp, -LcFrameLength(sp) // allocate stack frame
stq ra, LcRa(sp) // save return address
PROLOGUE_END
//
// If the current thread is not the owner of the critical section, then
// raise an exception.
//
#if DBG
GET_THREAD_ENVIRONMENT_BLOCK // (PALcode) get TEB address in v0
LDP a1, TeClientId + CidUniqueThread(v0) // get current thread id
LDP t0, CsOwningThread(a0) // get owner thread id
cmpeq a1, t0, t1 // check if current thread owner
bne t1, 10f // if ne, current thread is owner
bsr ra, RtlpNotOwnerCriticalSection // raise exception
ldil v0, STATUS_INVALID_OWNER // set completion status
ldq ra, LcRa(sp) // restore return address
lda sp, LcFrameLength(sp) // deallocate stack frame
ret zero, (ra) // return
#endif
//
// Decrement the recursion count. If the result is zero, then the lock
// is no longer owned.
//
10: ldl t0, CsRecursionCount(a0) // decrement recursion count
subl t0, 1, t0 //
bge t0, 30f // if ge, lock still owned
STP zero, CsOwningThread(a0) // clear owner thread id
//
// Decrement the lock count and check if a waiter should be continued.
//
//
20: mb // synchronize memory access
ldl_l t0, CsLockCount(a0) // get addend value - locked
subl t0, 1, t0 // decrement addend value
mov t0, t1 // copy updated value to t1 for store
stl_c t1, CsLockCount(a0) // store conditionally
beq t1, 60f // if eq, conditional store failed
blt t0, 50f // if lt, no waiter present
bsr ra, RtlpUnWaitCriticalSection // unwait thread
ldil v0, STATUS_SUCCESS // set completion status
ldq ra, LcRa(sp) // restore return address
lda sp, LcFrameLength(sp) // deallocate stack frame
ret zero, (ra) // return
//
// Decrement the lock count and return a success status since the lock
// is still owned.
//
30: stl t0, CsRecursionCount(a0) // store updated recursion count
40: ldl_l t0, CsLockCount(a0) // get addend value - locked
subl t0, 1, t0 // decrement addend value
stl_c t0, CsLockCount(a0) // store conditionally
beq t0, 70f // if lock-flag eq zero, store failed
50: ldil v0, STATUS_SUCCESS // set completion status
lda sp, LcFrameLength(sp) // deallocate stack frame
ret zero, (ra) // return
//
// We expect the store conditional will usually succeed the first time so it
// is faster to branch forward (predicted not taken) to here and then branch
// backward (predicted taken) to where we wanted to go.
//
60: br zero, 20b // go try lock again
70: br zero, 40b // go try lock again
.end RtlLeaveCriticalSection
SBTTL("Try to Enter Critical Section")
//++
//
// BOOLEAN
// RtlTryEnterCriticalSection(
// IN PRTL_CRITICAL_SECTION CriticalSection
// )
//
// Routine Description:
//
// This function attempts to enter a critical section without blocking.
//
// Arguments:
//
// CriticalSection (a0) - Supplies a pointer to a critical section.
//
// Return Value:
//
// If the critical section was successfully entered, then a value of TRUE
// is returned as the function value. Otherwise, a value of FALSE is returned.
//
//--
.struct 0
EcRa: .space 8 // saved return address
EcA0: .space 8 // saved critical section address
EcA1: .space 8 // saved unique thread id
.space 1 * 8 // required for 16-byte stack alignment
EcFrameLength: // length of stack frame
LEAF_ENTRY(RtlTryEnterCriticalSection)
GET_THREAD_ENVIRONMENT_BLOCK // (PALcode) get TEB address in v0
LDP a1, TeClientId + CidUniqueThread(v0) // get current thread unique id
//
// Attempt to enter the critical section.
//
10: ldl_l t0, CsLockCount(a0) // get addend value - locked
addl t0, 1, t1 // increment addend value
bne t1, 20f // critical section owned
stl_c t1, CsLockCount(a0) // store conditionally
beq t1, 40f // if eq, conditional store failed
mb // synchronize memory access
//
// The critical section is now owned by this thread. Initialize the owner
// thread id and return a successful status.
//
STP a1, CsOwningThread(a0) // set critical section owner
ldil v0, TRUE // set success status
ret zero, (ra)
//
// The critical section is already owned. If it is owned by another thread,
// return FALSE immediately. If it is owned by this thread, we must increment
// the lock count here.
//
20: LDP t2, CsOwningThread(a0) // get current owner
cmpeq t2, a1, t3 // check if current thread owner
bne t3, 30f // if ne, current thread owner
bis zero,zero,v0 // set failure status
ret zero, (ra) // return
//
// This thread is already the owner of the critical section. Perform an atomic
// increment of the LockCount and a normal increment of the RecursionCount and
// return success.
//
30: ldl_l t0, CsLockCount(a0) // get addend value - locked
addl t0, 1, t1 // increment addend value
stl_c t1, CsLockCount(a0) // store conditionally
beq t1, 50f // if eq, conditional store failed
ldl t0, CsRecursionCount(a0) // increment recursion count
addl t0, 1, t1 //
stl t1, CsRecursionCount(a0) //
ldil v0, TRUE // set success status
ret zero, (ra) // return
//
// We expect the store conditional will usually succeed the first time so it
// is faster to branch forward (predicted not taken) to here and then branch
// backward (predicted taken) to where we wanted to go.
//
40: br zero, 10b // go try lock again
50: br zero, 30b // retry lock
.end RtlTryEnterCriticalSection