module sync import time import rand import sync.stdatomic const aops_used = stdatomic.used const ( // how often to try to get data without blocking before to wait for semaphore spinloops = 750 spinloops_sem = 4000 ) enum BufferElemStat { unused = 0 writing written reading } struct Subscription { mut: sem &Semaphore prev &&Subscription nxt &Subscription } enum Direction { pop push } struct Channel { ringbuf &byte // queue for buffered channels statusbuf &byte // flags to synchronize write/read in ringbuf objsize u32 mut: // atomic writesem Semaphore // to wake thread that wanted to write, but buffer was full readsem Semaphore // to wake thread that wanted to read, but buffer was empty writesem_im Semaphore readsem_im Semaphore write_adr C.atomic_uintptr_t // if != NULL the next obj can be written here without wait read_adr C.atomic_uintptr_t // if != NULL an obj can be read from here without wait adr_read C.atomic_uintptr_t // used to identify origin of writesem adr_written C.atomic_uintptr_t // used to identify origin of readsem write_free u32 // for queue state read_avail u32 buf_elem_write_idx u32 buf_elem_read_idx u32 // for select write_subscriber &Subscription read_subscriber &Subscription write_sub_mtx u16 read_sub_mtx u16 closed u16 pub: cap u32 // queue length in #objects } pub fn new_channel(n u32) &Channel { st := sizeof(T) if isreftype(T) { return new_channel_st(n, st) } else { return new_channel_st_noscan(n, st) } } fn new_channel_st(n u32, st u32) &Channel { wsem := if n > 0 { n } else { 1 } rsem := if n > 0 { u32(0) } else { 1 } rbuf := if n > 0 { unsafe { malloc(int(n * st)) } } else { &byte(0) } sbuf := if n > 0 { vcalloc_noscan(int(n * 2)) } else { &byte(0) } mut ch := Channel{ objsize: st cap: n write_free: n read_avail: 0 ringbuf: rbuf statusbuf: sbuf write_subscriber: 0 read_subscriber: 0 } ch.writesem.init(wsem) ch.readsem.init(rsem) ch.writesem_im.init(0) ch.readsem_im.init(0) return &ch } fn new_channel_st_noscan(n u32, st u32) &Channel { $if gcboehm_opt ? { wsem := if n > 0 { n } else { 1 } rsem := if n > 0 { u32(0) } else { 1 } rbuf := if n > 0 { unsafe { malloc_noscan(int(n * st)) } } else { &byte(0) } sbuf := if n > 0 { vcalloc_noscan(int(n * 2)) } else { &byte(0) } mut ch := Channel{ objsize: st cap: n write_free: n read_avail: 0 ringbuf: rbuf statusbuf: sbuf write_subscriber: 0 read_subscriber: 0 } ch.writesem.init(wsem) ch.readsem.init(rsem) ch.writesem_im.init(0) ch.readsem_im.init(0) return &ch } $else { return new_channel_st(n, st) } } pub fn (ch &Channel) auto_str(typename string) string { return 'chan $typename{cap: $ch.cap, closed: $ch.closed}' } pub fn (mut ch Channel) close() { open_val := u16(0) if !C.atomic_compare_exchange_strong_u16(&ch.closed, &open_val, 1) { return } mut nulladr := voidptr(0) for !C.atomic_compare_exchange_weak_ptr(unsafe { &voidptr(&ch.adr_written) }, &nulladr, voidptr(-1)) { nulladr = voidptr(0) } ch.readsem_im.post() ch.readsem.post() mut null16 := u16(0) for !C.atomic_compare_exchange_weak_u16(&ch.read_sub_mtx, &null16, u16(1)) { null16 = u16(0) } if ch.read_subscriber != voidptr(0) { ch.read_subscriber.sem.post() } C.atomic_store_u16(&ch.read_sub_mtx, u16(0)) null16 = u16(0) for !C.atomic_compare_exchange_weak_u16(&ch.write_sub_mtx, &null16, u16(1)) { null16 = u16(0) } if ch.write_subscriber != voidptr(0) { ch.write_subscriber.sem.post() } C.atomic_store_u16(&ch.write_sub_mtx, u16(0)) ch.writesem.post() if ch.cap == 0 { C.atomic_store_ptr(unsafe { &voidptr(&ch.read_adr) }, voidptr(0)) } ch.writesem_im.post() } [inline] pub fn (mut ch Channel) len() int { return int(C.atomic_load_u32(&ch.read_avail)) } [inline] pub fn (mut ch Channel) closed() bool { return C.atomic_load_u16(&ch.closed) != 0 } [inline] pub fn (mut ch Channel) push(src voidptr) { if ch.try_push_priv(src, false) == .closed { panic('push on closed channel') } } [inline] pub fn (mut ch Channel) try_push(src voidptr) ChanState { return ch.try_push_priv(src, true) } fn (mut ch Channel) try_push_priv(src voidptr, no_block bool) ChanState { if C.atomic_load_u16(&ch.closed) != 0 { return .closed } spinloops_sem_, spinloops_ := if no_block { 1, 1 } else { sync.spinloops, sync.spinloops_sem } mut have_swapped := false for { mut got_sem := false mut wradr := C.atomic_load_ptr(unsafe { &voidptr(&ch.write_adr) }) for wradr != C.NULL { if C.atomic_compare_exchange_strong_ptr(unsafe { &voidptr(&ch.write_adr) }, &wradr, voidptr(0)) { // there is a reader waiting for us unsafe { C.memcpy(wradr, src, ch.objsize) } mut nulladr := voidptr(0) for !C.atomic_compare_exchange_weak_ptr(unsafe { &voidptr(&ch.adr_written) }, &nulladr, wradr) { nulladr = voidptr(0) } ch.readsem_im.post() return .success } } if no_block && ch.cap == 0 { return .not_ready } // get token to read for _ in 0 .. spinloops_sem_ { if got_sem { break } got_sem = ch.writesem.try_wait() } if !got_sem { if no_block { return .not_ready } ch.writesem.wait() } if C.atomic_load_u16(&ch.closed) != 0 { ch.writesem.post() return .closed } if ch.cap == 0 { // try to advertise current object as readable mut read_in_progress := false C.atomic_store_ptr(unsafe { &voidptr(&ch.read_adr) }, src) wradr = C.atomic_load_ptr(unsafe { &voidptr(&ch.write_adr) }) if wradr != C.NULL { mut src2 := src if C.atomic_compare_exchange_strong_ptr(unsafe { &voidptr(&ch.read_adr) }, &src2, voidptr(0)) { ch.writesem.post() continue } else { read_in_progress = true } } if !read_in_progress { mut null16 := u16(0) for !C.atomic_compare_exchange_weak_u16(voidptr(&ch.read_sub_mtx), &null16, u16(1)) { null16 = u16(0) } if ch.read_subscriber != voidptr(0) { ch.read_subscriber.sem.post() } C.atomic_store_u16(&ch.read_sub_mtx, u16(0)) } mut src2 := src for sp := u32(0); sp < spinloops_ || read_in_progress; sp++ { if C.atomic_compare_exchange_strong_ptr(unsafe { &voidptr(&ch.adr_read) }, &src2, voidptr(0)) { have_swapped = true read_in_progress = true break } src2 = src } mut got_im_sem := false for sp := u32(0); sp < spinloops_sem_ || read_in_progress; sp++ { got_im_sem = ch.writesem_im.try_wait() if got_im_sem { break } } for { if got_im_sem { got_im_sem = false } else { ch.writesem_im.wait() } if C.atomic_load_u16(&ch.closed) != 0 { if have_swapped || C.atomic_compare_exchange_strong_ptr(unsafe { &voidptr(&ch.adr_read) }, &src2, voidptr(0)) { ch.writesem.post() return .success } else { return .closed } } if have_swapped || C.atomic_compare_exchange_strong_ptr(unsafe { &voidptr(&ch.adr_read) }, &src2, voidptr(0)) { ch.writesem.post() break } else { // this semaphore was not for us - repost in ch.writesem_im.post() if src2 == voidptr(-1) { ch.readsem.post() return .closed } src2 = src } } return .success } else { // buffered channel mut space_in_queue := false mut wr_free := C.atomic_load_u32(&ch.write_free) for wr_free > 0 { space_in_queue = C.atomic_compare_exchange_weak_u32(&ch.write_free, &wr_free, wr_free - 1) if space_in_queue { break } } if space_in_queue { mut wr_idx := C.atomic_load_u32(&ch.buf_elem_write_idx) for { mut new_wr_idx := wr_idx + 1 for new_wr_idx >= ch.cap { new_wr_idx -= ch.cap } if C.atomic_compare_exchange_strong_u32(&ch.buf_elem_write_idx, &wr_idx, new_wr_idx) { break } } mut wr_ptr := ch.ringbuf mut status_adr := ch.statusbuf unsafe { wr_ptr += wr_idx * ch.objsize status_adr += wr_idx * sizeof(u16) } mut expected_status := u16(BufferElemStat.unused) for !C.atomic_compare_exchange_weak_u16(status_adr, &expected_status, u16(BufferElemStat.writing)) { expected_status = u16(BufferElemStat.unused) } unsafe { C.memcpy(wr_ptr, src, ch.objsize) } C.atomic_store_u16(unsafe { &u16(status_adr) }, u16(BufferElemStat.written)) C.atomic_fetch_add_u32(&ch.read_avail, 1) ch.readsem.post() mut null16 := u16(0) for !C.atomic_compare_exchange_weak_u16(&ch.read_sub_mtx, &null16, u16(1)) { null16 = u16(0) } if ch.read_subscriber != voidptr(0) { ch.read_subscriber.sem.post() } C.atomic_store_u16(&ch.read_sub_mtx, u16(0)) return .success } else { if no_block { return .not_ready } ch.writesem.post() } } } // we should not get here but the V compiler want's to see a return statement panic('unknown `try_push_priv` state') } [inline] pub fn (mut ch Channel) pop(dest voidptr) bool { return ch.try_pop_priv(dest, false) == .success } [inline] pub fn (mut ch Channel) try_pop(dest voidptr) ChanState { return ch.try_pop_priv(dest, true) } fn (mut ch Channel) try_pop_priv(dest voidptr, no_block bool) ChanState { spinloops_sem_, spinloops_ := if no_block { 1, 1 } else { sync.spinloops, sync.spinloops_sem } mut have_swapped := false mut write_in_progress := false for { mut got_sem := false if ch.cap == 0 { // unbuffered channel - first see if a `push()` has adversized mut rdadr := C.atomic_load_ptr(unsafe { &voidptr(&ch.read_adr) }) for rdadr != C.NULL { if C.atomic_compare_exchange_strong_ptr(unsafe { &voidptr(&ch.read_adr) }, &rdadr, voidptr(0)) { // there is a writer waiting for us unsafe { C.memcpy(dest, rdadr, ch.objsize) } mut nulladr := voidptr(0) for !C.atomic_compare_exchange_weak_ptr(unsafe { &voidptr(&ch.adr_read) }, &nulladr, rdadr) { nulladr = voidptr(0) } ch.writesem_im.post() return .success } } if no_block { if C.atomic_load_u16(&ch.closed) == 0 { return .not_ready } else { return .closed } } } // get token to read for _ in 0 .. spinloops_sem_ { if got_sem { break } got_sem = ch.readsem.try_wait() } if !got_sem { if no_block { if C.atomic_load_u16(&ch.closed) == 0 { return .not_ready } else { return .closed } } ch.readsem.wait() } if ch.cap > 0 { // try to get buffer token mut obj_in_queue := false mut rd_avail := C.atomic_load_u32(&ch.read_avail) for rd_avail > 0 { obj_in_queue = C.atomic_compare_exchange_weak_u32(&ch.read_avail, &rd_avail, rd_avail - 1) if obj_in_queue { break } } if obj_in_queue { mut rd_idx := C.atomic_load_u32(&ch.buf_elem_read_idx) for { mut new_rd_idx := rd_idx + 1 for new_rd_idx >= ch.cap { new_rd_idx -= ch.cap } if C.atomic_compare_exchange_weak_u32(&ch.buf_elem_read_idx, &rd_idx, new_rd_idx) { break } } mut rd_ptr := ch.ringbuf mut status_adr := ch.statusbuf unsafe { rd_ptr += rd_idx * ch.objsize status_adr += rd_idx * sizeof(u16) } mut expected_status := u16(BufferElemStat.written) for !C.atomic_compare_exchange_weak_u16(status_adr, &expected_status, u16(BufferElemStat.reading)) { expected_status = u16(BufferElemStat.written) } unsafe { C.memcpy(dest, rd_ptr, ch.objsize) } C.atomic_store_u16(unsafe { &u16(status_adr) }, u16(BufferElemStat.unused)) C.atomic_fetch_add_u32(&ch.write_free, 1) ch.writesem.post() mut null16 := u16(0) for !C.atomic_compare_exchange_weak_u16(&ch.write_sub_mtx, &null16, u16(1)) { null16 = u16(0) } if ch.write_subscriber != voidptr(0) { ch.write_subscriber.sem.post() } C.atomic_store_u16(&ch.write_sub_mtx, u16(0)) return .success } } // try to advertise `dest` as writable C.atomic_store_ptr(unsafe { &voidptr(&ch.write_adr) }, dest) if ch.cap == 0 { mut rdadr := C.atomic_load_ptr(unsafe { &voidptr(&ch.read_adr) }) if rdadr != C.NULL { mut dest2 := dest if C.atomic_compare_exchange_strong_ptr(unsafe { &voidptr(&ch.write_adr) }, &dest2, voidptr(0)) { ch.readsem.post() continue } else { write_in_progress = true } } } if ch.cap == 0 && !write_in_progress { mut null16 := u16(0) for !C.atomic_compare_exchange_weak_u16(&ch.write_sub_mtx, &null16, u16(1)) { null16 = u16(0) } if ch.write_subscriber != voidptr(0) { ch.write_subscriber.sem.post() } C.atomic_store_u16(&ch.write_sub_mtx, u16(0)) } mut dest2 := dest for sp := u32(0); sp < spinloops_ || write_in_progress; sp++ { if C.atomic_compare_exchange_strong_ptr(unsafe { &voidptr(&ch.adr_written) }, &dest2, voidptr(0)) { have_swapped = true break } else if dest2 == voidptr(-1) { ch.readsem.post() return .closed } dest2 = dest } mut got_im_sem := false for sp := u32(0); sp < spinloops_sem_ || write_in_progress; sp++ { got_im_sem = ch.readsem_im.try_wait() if got_im_sem { break } } for { if got_im_sem { got_im_sem = false } else { ch.readsem_im.wait() } if have_swapped || C.atomic_compare_exchange_strong_ptr(unsafe { &voidptr(&ch.adr_written) }, &dest2, voidptr(0)) { ch.readsem.post() break } else { // this semaphore was not for us - repost in ch.readsem_im.post() if dest2 == voidptr(-1) { ch.readsem.post() return .closed } dest2 = dest } } break } return .success } // Wait `timeout` on any of `channels[i]` until one of them can push (`is_push[i] = true`) or pop (`is_push[i] = false`) // object referenced by `objrefs[i]`. `timeout = time.infinite` means wait unlimited time. `timeout <= 0` means return // immediately if no transaction can be performed without waiting. // return value: the index of the channel on which a transaction has taken place // -1 if waiting for a transaction has exceeded timeout // -2 if all channels are closed pub fn channel_select(mut channels []&Channel, dir []Direction, mut objrefs []voidptr, timeout time.Duration) int { $if debug { assert channels.len == dir.len assert dir.len == objrefs.len } mut subscr := []Subscription{len: channels.len} mut sem := unsafe { Semaphore{} } sem.init(0) for i, ch in channels { subscr[i].sem = unsafe { &sem } if dir[i] == .push { mut null16 := u16(0) for !C.atomic_compare_exchange_weak_u16(&ch.write_sub_mtx, &null16, u16(1)) { null16 = u16(0) } subscr[i].prev = unsafe { &ch.write_subscriber } unsafe { subscr[i].nxt = &Subscription(C.atomic_exchange_ptr(&voidptr(&ch.write_subscriber), &subscr[i])) } if voidptr(subscr[i].nxt) != voidptr(0) { subscr[i].nxt.prev = unsafe { &subscr[i].nxt } } C.atomic_store_u16(&ch.write_sub_mtx, u16(0)) } else { mut null16 := u16(0) for !C.atomic_compare_exchange_weak_u16(&ch.read_sub_mtx, &null16, u16(1)) { null16 = u16(0) } subscr[i].prev = unsafe { &ch.read_subscriber } unsafe { subscr[i].nxt = &Subscription(C.atomic_exchange_ptr(&voidptr(&ch.read_subscriber), &subscr[i])) } if voidptr(subscr[i].nxt) != voidptr(0) { subscr[i].nxt.prev = unsafe { &subscr[i].nxt } } C.atomic_store_u16(&ch.read_sub_mtx, u16(0)) } } stopwatch := if timeout == time.infinite || timeout <= 0 { time.StopWatch{} } else { time.new_stopwatch() } mut event_idx := -1 // negative index means `timed out` outer: for { rnd := rand.intn(channels.len) or { 0 } mut num_closed := 0 for j, _ in channels { mut i := j + rnd if i >= channels.len { i -= channels.len } if dir[i] == .push { stat := channels[i].try_push_priv(objrefs[i], true) if stat == .success { event_idx = i break outer } else if stat == .closed { num_closed++ } } else { stat := channels[i].try_pop_priv(objrefs[i], true) if stat == .success { event_idx = i break outer } else if stat == .closed { num_closed++ } } } if num_closed == channels.len { event_idx = -2 break outer } if timeout <= 0 { break outer } if timeout != time.infinite { remaining := timeout - stopwatch.elapsed() if !sem.timed_wait(remaining) { break outer } } else { sem.wait() } } // reset subscribers for i, ch in channels { if dir[i] == .push { mut null16 := u16(0) for !C.atomic_compare_exchange_weak_u16(&ch.write_sub_mtx, &null16, u16(1)) { null16 = u16(0) } unsafe { *subscr[i].prev = subscr[i].nxt } if subscr[i].nxt != 0 { subscr[i].nxt.prev = subscr[i].prev // just in case we have missed a semaphore during restore subscr[i].nxt.sem.post() } C.atomic_store_u16(&ch.write_sub_mtx, u16(0)) } else { mut null16 := u16(0) for !C.atomic_compare_exchange_weak_u16(&ch.read_sub_mtx, &null16, u16(1)) { null16 = u16(0) } unsafe { *subscr[i].prev = subscr[i].nxt } if subscr[i].nxt != 0 { subscr[i].nxt.prev = subscr[i].prev subscr[i].nxt.sem.post() } C.atomic_store_u16(&ch.read_sub_mtx, u16(0)) } } sem.destroy() return event_idx }