kolibrios/programs/system/os/sync.inc

; High-level synchronization primitives.

; Mutex: stands for MUTual EXclusion.
; Allows to enforce that only one thread executes some code at a time.
; mutex_lock acquires the given mutex, mutex_unlock releases it;
; if thread 1 holds the mutex and thread 2 calls mutex_lock,
; thread 2 is blocked until thread 1 calls mutex_unlock.
; Several threads can wait for the same mutex; when the owner
; releases the mutex, one of waiting threads grabs the released mutex,
; but it is unspecified which one.

; If there is no contention, i.e. no one calls mutex_lock
; while somebody is holding the mutex, then
; mutex_lock and mutex_unlock use just a few instructions.
; This is the fast path.
; Otherwise, mutex_lock and mutex_unlock require a syscall
; to enter waiting state and wake someone up correspondingly.

; Implementation. We use one dword for status and
; kernel handle for underlying futex to be able to sleep/wake.
; Bit 31, the highest bit of status dword,
; is set if someone holds the mutex and clear otherwise.
; Bits 0-30 form the number of threads waiting in mutex_lock.
; All modifications of status dword should be atomic.

struct MUTEX
status  dd      ?
handle  dd      ?
ends

; Initialization. Set status dword to zero and
; open the underlying futex.
; in: ecx -> MUTEX
proc mutex_init
        mov     [ecx+MUTEX.status], 0
        push    ebx
        mov     eax, 77
        xor     ebx, ebx
        call    FS_SYSCALL_PTR
        pop     ebx
        mov     [ecx+MUTEX.handle], eax
        ret
endp

; Finalization. Close the underlying futex.
; in: ecx = MUTEX handle
proc mutex_destroy
        push    ebx
        mov     eax, 77
        mov     ebx, 1
        call    FS_SYSCALL_PTR
        pop     ebx
        ret
endp

; Acquire the mutex.
macro mutex_lock mutex
{
local .done
; Atomically set the locked status bit and get the previous value.
        lock bts [mutex+MUTEX.status], 31
; Fast path: the mutex was not locked. If so, we are done.
        jnc     .done
if ~(mutex eq ecx)
        mov     ecx, mutex
end if
        call    mutex_lock_slow_path
.done:
}

; Acquire the mutex, slow path.
; Someone holds the mutex... or has held it a moment ago.
; in: ecx -> MUTEX
proc mutex_lock_slow_path
; Atomically increment number of waiters.
        lock inc [ecx+MUTEX.status]
; When the mutex owner will release the mutex and wake us up,
; another thread can sneak in and grab the mutex before us.
; So, the following actions are potentially repeated in a loop.
.wait_loop:
        mov     edx, [ecx+MUTEX.status]
; The owner could have unlocked the mutex in parallel with us.
; If so, don't sleep: nobody would wake us up.
        test    edx, edx
        jns     .skip_wait
; Pass the fetched value to the kernel along with futex handle.
; If the owner unlocks the mutex while we are here,
; the kernel will detect mismatch and exit without sleeping.
; Otherwise, the owner will wake us up explicitly.
        push    ebx ecx esi
        mov     eax, 77
        mov     ebx, 2
        mov     ecx, [ecx+MUTEX.handle]
        xor     esi, esi
        call    FS_SYSCALL_PTR
        pop     esi ecx ebx
.skip_wait:
; We have woken up.
; Or we didn't even sleep because status dword has been changed beneath us.
; Anyway, something may have changed, re-evaluate the situation.
; Atomically set the locked status bit and get the previous value.
        lock bts [ecx+MUTEX.status], 31
; If the mutex was locked, someone has grabbed the mutex before us.
; Repeat the loop.
        jc      .wait_loop
; The mutex was unlocked and we have just managed to lock it.
; Our status has changed from a waiter to the owner.
; Decrease number of waiters and exit.
        lock dec [ecx+MUTEX.status]
        ret
endp

; Release the mutex.
macro mutex_unlock mutex
{
local .done
; Atomically clear the locked status bit and check whether someone is waiting.
        lock and [mutex+MUTEX.status], 0x7FFFFFFF
; Fast path: nobody is waiting.
        jz      .done
        mov     ecx, [mutex+MUTEX.handle]
        call    mutex_unlock_slow_path
.done:
}

; Release the mutex, slow path.
; Someone is sleeping in the kernel, or preparing for the sleep.
; Wake one of waiters.
; in: ecx = MUTEX handle
proc mutex_unlock_slow_path
        push    ebx
        mov     eax, 77
        mov     ebx, 3
        mov     edx, 1
        call    FS_SYSCALL_PTR
        pop     ebx
        ret
endp
import processing for the system library git-svn-id: svn://kolibrios.org@6767 a494cfbc-eb01-0410-851d-a64ba20cac60 2016-11-29 18:47:46 +01:00			`; High-level synchronization primitives.`

			`; Mutex: stands for MUTual EXclusion.`
			`; Allows to enforce that only one thread executes some code at a time.`
			`; mutex_lock acquires the given mutex, mutex_unlock releases it;`
			`; if thread 1 holds the mutex and thread 2 calls mutex_lock,`
			`; thread 2 is blocked until thread 1 calls mutex_unlock.`
			`; Several threads can wait for the same mutex; when the owner`
			`; releases the mutex, one of waiting threads grabs the released mutex,`
			`; but it is unspecified which one.`

			`; If there is no contention, i.e. no one calls mutex_lock`
			`; while somebody is holding the mutex, then`
			`; mutex_lock and mutex_unlock use just a few instructions.`
			`; This is the fast path.`
			`; Otherwise, mutex_lock and mutex_unlock require a syscall`
			`; to enter waiting state and wake someone up correspondingly.`

			`; Implementation. We use one dword for status and`
			`; kernel handle for underlying futex to be able to sleep/wake.`
			`; Bit 31, the highest bit of status dword,`
			`; is set if someone holds the mutex and clear otherwise.`
			`; Bits 0-30 form the number of threads waiting in mutex_lock.`
			`; All modifications of status dword should be atomic.`

			`struct MUTEX`
			`status dd ?`
			`handle dd ?`
			`ends`

			`; Initialization. Set status dword to zero and`
			`; open the underlying futex.`
			`; in: ecx -> MUTEX`
			`proc mutex_init`
			`mov [ecx+MUTEX.status], 0`
			`push ebx`
			`mov eax, 77`
			`xor ebx, ebx`
			`call FS_SYSCALL_PTR`
			`pop ebx`
			`mov [ecx+MUTEX.handle], eax`
			`ret`
			`endp`

			`; Finalization. Close the underlying futex.`
			`; in: ecx = MUTEX handle`
			`proc mutex_destroy`
			`push ebx`
			`mov eax, 77`
			`mov ebx, 1`
			`call FS_SYSCALL_PTR`
			`pop ebx`
			`ret`
			`endp`

			`; Acquire the mutex.`
			`macro mutex_lock mutex`
			`{`
			`local .done`
			`; Atomically set the locked status bit and get the previous value.`
			`lock bts [mutex+MUTEX.status], 31`
			`; Fast path: the mutex was not locked. If so, we are done.`
			`jnc .done`
			`if ~(mutex eq ecx)`
			`mov ecx, mutex`
			`end if`
			`call mutex_lock_slow_path`
			`.done:`
			`}`

			`; Acquire the mutex, slow path.`
			`; Someone holds the mutex... or has held it a moment ago.`
			`; in: ecx -> MUTEX`
			`proc mutex_lock_slow_path`
			`; Atomically increment number of waiters.`
			`lock inc [ecx+MUTEX.status]`
			`; When the mutex owner will release the mutex and wake us up,`
			`; another thread can sneak in and grab the mutex before us.`
			`; So, the following actions are potentially repeated in a loop.`
			`.wait_loop:`
			`mov edx, [ecx+MUTEX.status]`
			`; The owner could have unlocked the mutex in parallel with us.`
			`; If so, don't sleep: nobody would wake us up.`
			`test edx, edx`
			`jns .skip_wait`
			`; Pass the fetched value to the kernel along with futex handle.`
			`; If the owner unlocks the mutex while we are here,`
			`; the kernel will detect mismatch and exit without sleeping.`
			`; Otherwise, the owner will wake us up explicitly.`
			`push ebx ecx esi`
			`mov eax, 77`
			`mov ebx, 2`
			`mov ecx, [ecx+MUTEX.handle]`
			`xor esi, esi`
			`call FS_SYSCALL_PTR`
			`pop esi ecx ebx`
			`.skip_wait:`
			`; We have woken up.`
			`; Or we didn't even sleep because status dword has been changed beneath us.`
			`; Anyway, something may have changed, re-evaluate the situation.`
			`; Atomically set the locked status bit and get the previous value.`
			`lock bts [ecx+MUTEX.status], 31`
			`; If the mutex was locked, someone has grabbed the mutex before us.`
			`; Repeat the loop.`
			`jc .wait_loop`
			`; The mutex was unlocked and we have just managed to lock it.`
			`; Our status has changed from a waiter to the owner.`
			`; Decrease number of waiters and exit.`
			`lock dec [ecx+MUTEX.status]`
			`ret`
			`endp`

			`; Release the mutex.`
			`macro mutex_unlock mutex`
			`{`
			`local .done`
			`; Atomically clear the locked status bit and check whether someone is waiting.`
			`lock and [mutex+MUTEX.status], 0x7FFFFFFF`
			`; Fast path: nobody is waiting.`
			`jz .done`
			`mov ecx, [mutex+MUTEX.handle]`
			`call mutex_unlock_slow_path`
			`.done:`
			`}`

			`; Release the mutex, slow path.`
			`; Someone is sleeping in the kernel, or preparing for the sleep.`
			`; Wake one of waiters.`
			`; in: ecx = MUTEX handle`
			`proc mutex_unlock_slow_path`
			`push ebx`
			`mov eax, 77`
			`mov ebx, 3`
			`mov edx, 1`
			`call FS_SYSCALL_PTR`
			`pop ebx`
			`ret`
			`endp`