/*!
* \brief Removes a thread from a thread queue
*/
void ThrRemoveQueue(thread_t *thr, thread_queue_t *queue)
{
thread_queuent_t *ent;
SpinAcquire(&sc_sem);
ent = ThrFindInQueue(queue, thr);
if (ent == NULL)
{
SpinRelease(&sc_sem);
return;
}
if (ent->prev)
ent->prev->next = ent->next;
if (ent->next)
ent->next->prev = ent->prev;
if (queue->first == ent)
queue->first = ent->next;
if (queue->last == ent)
queue->last = ent->prev;
SlabFree(&slab_thread_queuent, ent);
KeAtomicDec(&thr->queued);
TRACE2("ThrRemoveQueue: thread %u removed from queue %p\n",
thr->id, queue);
SpinRelease(&sc_sem);
}
bool PortPassthrough(fsd_t *fsd, file_t *file, uint32_t code, void *buf,
size_t length, fs_asyncio_t *io)
{
params_port_t *params;
port_t *server;
params = buf;
if (length < sizeof(params_port_t))
{
io->op.result = EBUFFER;
return false;
}
server = file->fsd_cookie;
if (!server->is_server)
{
io->op.result = EACCESS;
return false;
}
switch (code)
{
case PORT_LISTEN:
case PORT_CONNECT:
//wprintf(L"PortPassthrough(%p): PORT_LISTEN and PORT_CONNECT not implemented\n",
//server);
//FsNotifyCompletion(io, length, 0);
//break;
io->op.result = ENOTIMPL;
return false;
case PORT_ACCEPT:
SpinAcquire(&server->u.server.sem);
if (server->u.server.io_listen != NULL)
{
SpinRelease(&server->u.server.sem);
io->op.result = EACCESS;
return false;
}
//wprintf(L"PortPassthrough(%p): PORT_ACCEPT, waiter = %p\n",
//server,
//server->u.server.waiter_first);
server->u.server.io_listen = io;
server->u.server.pages_listen = MemCreatePageArray(buf, length);
SpinRelease(&server->u.server.sem);
io->op.result = io->original->result = SIOPENDING;
PortWakeBlockedAcceptors(server);
break;
default:
io->op.result = ENOTIMPL;
return false;
}
return true;
}
status_t PortCreateFile(fsd_t *fsd, vnode_id_t dir, const wchar_t *name,
void **cookie)
{
port_fsd_t *pfsd;
port_t *server;
pfsd = (port_fsd_t*) fsd;
assert(dir == VNODE_ROOT);
//wprintf(L"PortCreateFile(%s)\n", name);
server = malloc(sizeof(port_t));
if (server == NULL)
return errno;
memset(server, 0, sizeof(port_t));
server->is_server = true;
server->u.server.name = _wcsdup(name);
*cookie = server;
SpinAcquire(&pfsd->sem);
LIST_ADD(pfsd->server, server);
SpinRelease(&pfsd->sem);
return 0;
}
bool RtlIsr(device_t *device, uint8_t irq)
{
rtl8139_t *rtl;
uint16_t status;
rtl = device->cookie;
SpinAcquire(&rtl->sem);
out16(rtl->iobase + IntrMask, 0);
status = in16(rtl->iobase + IntrStatus);
out16(rtl->iobase + IntrStatus, status & ~(RxFIFOOver | RxOverflow | RxOK));
if (status & (RxOK | RxErr))
RtlHandleRx(rtl);
else if (status & TxOK)
RtlHandleTx(rtl);
else
wprintf(L"rtl8139: unknown interrupt: isr = %04x\n", status);
out16(rtl->iobase + IntrStatus, status & (RxFIFOOver | RxOverflow | RxOK));
out16(rtl->iobase + IntrMask, IntrDefault);
SpinRelease(&rtl->sem);
return true;
}
/*!
* \brief Places the specified thread onto the run queue for the
* appropriate priority
*/
static bool ThrRun(thread_t *thr)
{
assert(thr->priority < _countof(thr_priority));
ThrInsertQueue(thr, thr_priority + thr->priority, NULL);
SpinAcquire(&sc_sem);
thr_queue_ready |= 1 << thr->priority;
SpinRelease(&sc_sem);
return true;
}
/*!
* \brief Runs a queue of threads
*
* The threads on the queue are removed from the queue and added to their
* respective priority queues, to be scheduled next time the scheduler is
* called.
*
* \param queue Queue to run
*/
static void ThrRunQueue(thread_queue_t *queue)
{
thread_queuent_t *ent, *next;
thread_t *thr;
SpinAcquire(&sc_sem);
while (queue->first != NULL)
{
ent = queue->first;
next = ent->next;
thr = ent->thr;
TRACE1("ThrRunQueue: running thread %u\n", thr->id);
SpinRelease(&sc_sem);
ThrRemoveQueue(thr, queue);
ThrRun(thr);
SpinAcquire(&sc_sem);
}
ScNeedSchedule(true);
SpinRelease(&sc_sem);
}
void RtlInit(rtl8139_t *rtl)
{
unsigned i;
wprintf(L"rtl8139: resetting... ");
SpinAcquire(&rtl->sem);
/* Bring the chip out of low-power mode. */
out(rtl->iobase + Config1, 0x00);
if (RtlReadEeprom(rtl, 0) != 0xffff)
{
unsigned short *ap = (unsigned short*)rtl->station_address;
for (i = 0; i < 3; i++)
*ap++ = RtlReadEeprom(rtl, i + 7);
}
else
{
unsigned char *ap = (unsigned char*)rtl->station_address;
for (i = 0; i < 6; i++)
*ap++ = in(rtl->iobase + MAC0 + i);
}
rtl->speed10 = (in(rtl->iobase + MediaStatus) & MSRSpeed10) != 0;
rtl->fullduplex = (in16(rtl->iobase + MII_BMCR) & BMCRDuplex) != 0;
wprintf(L"rtl8139: %sMbps %s-duplex\n",
rtl->speed10 ? L"10" : L"100",
rtl->fullduplex ? L"full" : L"half");
rtl->rx_phys = MemAlloc();
rtl->tx_phys = MemAlloc();
rtl->rx_ring = sbrk_virtual(RX_BUF_LEN);
rtl->tx_ring = sbrk_virtual(TX_BUF_SIZE);
wprintf(L"rtl8139: rx_ring = %p, tx_ring = %p\n",
rtl->rx_ring, rtl->tx_ring);
MemMapRange(rtl->rx_ring,
rtl->rx_phys,
rtl->rx_ring + RX_BUF_LEN,
PRIV_RD | PRIV_PRES | PRIV_KERN);
MemMapRange(rtl->tx_ring,
rtl->tx_phys,
(uint8_t*) PAGE_ALIGN_UP((addr_t) rtl->tx_ring + TX_BUF_SIZE),
PRIV_WR | PRIV_PRES | PRIV_KERN);
RtlReset(rtl);
SpinRelease(&rtl->sem);
}
static void PortWakeBlockedAcceptors(port_t *server)
{
params_port_t *params;
fs_asyncio_t *io;
port_waiter_t *waiter;
assert(server->is_server);
SpinAcquire(&server->u.server.sem);
io = server->u.server.io_listen;
waiter = server->u.server.waiter_first;
//wprintf(L"PortWakeBlockedAcceptors(%p): io = %p, waiter = %p\n",
//server, io, waiter);
if (io != NULL && waiter != NULL)
{
file_t *file;
file_handle_t *fh;
params = MemMapPageArray(server->u.server.pages_listen);
file = FsCreateFileObject(&pipe_fsd, VNODE_NONE, waiter->end_server);
fh = FsCreateFileHandle(file, params->port_accept.flags);
params->port_accept.client = HndDuplicate(&fh->hdr, io->owner->process);
//wprintf(L"PortWakeBlockedAcceptors(%p): pipe = %p, handle = %u\n",
//server, waiter->end_server, params->port_accept.client);
MemUnmapPageArray(server->u.server.pages_listen);
LIST_REMOVE(server->u.server.waiter, waiter);
free(waiter);
MemDeletePageArray(server->u.server.pages_listen);
server->u.server.io_listen = NULL;
server->u.server.pages_listen = NULL;
SpinRelease(&server->u.server.sem);
FsNotifyCompletion(io, sizeof(params_port_t), 0);
}
else
SpinRelease(&server->u.server.sem);
}
status_t PortParseElement(fsd_t *fsd, const wchar_t *name,
wchar_t **new_path, vnode_t *node)
{
port_fsd_t *pfsd;
port_t *server;
pfsd = (port_fsd_t*) fsd;
assert(node->id == VNODE_ROOT);
SpinAcquire(&pfsd->sem);
for (server = pfsd->server_first; server != NULL; server = server->next)
{
assert(server->is_server);
if (_wcsicmp(server->u.server.name, name) == 0)
{
node->id = (vnode_id_t) server;
SpinRelease(&pfsd->sem);
return 0;
}
}
SpinRelease(&pfsd->sem);
return ENOTFOUND;
}
status_t PortLookupFile(fsd_t *fsd, vnode_id_t node, uint32_t open_flags,
void **cookie)
{
port_fsd_t *pfsd;
port_t *server, *client;
port_waiter_t *waiter;
pipe_t *ends[2];
pfsd = (port_fsd_t*) fsd;
if (node == VNODE_ROOT)
return EACCESS;
server = (port_t*) node;
assert(server->is_server);
client = malloc(sizeof(port_t));
if (client == NULL)
goto error0;
waiter = malloc(sizeof(port_waiter_t));
if (waiter == NULL)
goto error1;
if (!FsCreatePipeInternal(ends))
goto error2;
memset(client, 0, sizeof(*client));
memset(waiter, 0, sizeof(*waiter));
client->is_server = false;
waiter->end_client = client->u.client = ends[0];
waiter->end_server = ends[1];
SpinAcquire(&server->u.server.sem);
LIST_ADD(server->u.server.waiter, waiter);
SpinRelease(&server->u.server.sem);
*cookie = client;
PortWakeBlockedAcceptors(server);
return 0;
error2:
free(waiter);
error1:
free(client);
error0:
return errno;
}
void
ProcReleaseSpins(PROC *proc)
{
int i;
if (!proc)
proc = MyProc;
if (!proc)
return;
for (i=0; i < (int)MAX_SPINS; i++)
{
if (proc->sLocks[i])
{
Assert(proc->sLocks[i] == 1);
SpinRelease(i);
}
}
}
void PortFreeCookie(fsd_t *fsd, void *cookie)
{
port_fsd_t *pfsd;
port_t *server;
pfsd = (port_fsd_t*) fsd;
server = cookie;
if (server->is_server)
{
SpinAcquire(&pfsd->sem);
LIST_REMOVE(pfsd->server, server);
SpinRelease(&pfsd->sem);
free(server->u.server.name);
}
else
PipeFreeCookie(fsd, server->u.client);
free(server);
}
/*!
* \brief Inserts a thread into a thread queue
*/
static void ThrInsertQueue(thread_t *thr, thread_queue_t *queue, thread_queuent_t *before)
{
thread_queuent_t *ent;
SpinAcquire(&sc_sem);
ent = SlabAlloc(&slab_thread_queuent);
assert(ent != NULL);
ent->thr = thr;
if (before == NULL)
{
if (queue->last != NULL)
queue->last->next = ent;
ent->prev = queue->last;
ent->next = NULL;
queue->last = ent;
if (queue->first == NULL)
queue->first = ent;
}
else
{
ent->next = before;
ent->prev = before->prev;
if (before->prev != NULL)
before->prev->next = ent;
before->prev = ent;
if (queue->first == before)
queue->first = ent;
}
KeAtomicInc(&thr->queued);
TRACE2("ThrInsertQueue: thread %u added to queue %p\n",
thr->id, queue);
SpinRelease(&sc_sem);
}
/*
* ProcRemove -
* used by the postmaster to clean up the global tables. This also frees
* up the semaphore used for the lmgr of the process. (We have to do
* this is the postmaster instead of doing a IpcSemaphoreKill on exiting
* the process because the semaphore set is shared among backends and
* we don't want to remove other's semaphores on exit.)
*/
bool
ProcRemove(int pid)
{
SHMEM_OFFSET location;
PROC *proc;
location = INVALID_OFFSET;
location = ShmemPIDDestroy(pid);
if (location == INVALID_OFFSET)
return(FALSE);
proc = (PROC *) MAKE_PTR(location);
SpinAcquire(ProcStructLock);
ProcFreeSem(proc->sem.semKey, proc->sem.semNum);
proc->links.next = ProcGlobal->freeProcs;
ProcGlobal->freeProcs = MAKE_OFFSET(proc);
SpinRelease(ProcStructLock);
return(TRUE);
}
/* ------------------------
* InitProc -- create a per-process data structure for this process
* used by the lock manager on semaphore queues.
* ------------------------
*/
void
InitProcess(IPCKey key)
{
bool found = false;
int pid;
int semstat;
unsigned long location, myOffset;
/* ------------------
* Routine called if deadlock timer goes off. See ProcSleep()
* ------------------
*/
#ifndef WIN32
signal(SIGALRM, HandleDeadLock);
#endif /* WIN32 we'll have to figure out how to handle this later */
SpinAcquire(ProcStructLock);
/* attach to the free list */
ProcGlobal = (PROC_HDR *)
ShmemInitStruct("Proc Header",(unsigned)sizeof(PROC_HDR),&found);
if (!found) {
/* this should not happen. InitProcGlobal() is called before this. */
elog(WARN, "InitProcess: Proc Header uninitialized");
}
if (MyProc != NULL)
{
SpinRelease(ProcStructLock);
elog(WARN,"ProcInit: you already exist");
return;
}
/* try to get a proc from the free list first */
myOffset = ProcGlobal->freeProcs;
if (myOffset != INVALID_OFFSET)
{
MyProc = (PROC *) MAKE_PTR(myOffset);
ProcGlobal->freeProcs = MyProc->links.next;
}
else
{
/* have to allocate one. We can't use the normal binding
* table mechanism because the proc structure is stored
* by PID instead of by a global name (need to look it
* up by PID when we cleanup dead processes).
*/
MyProc = (PROC *) ShmemAlloc((unsigned)sizeof(PROC));
if (! MyProc)
{
SpinRelease(ProcStructLock);
elog (FATAL,"cannot create new proc: out of memory");
}
/* this cannot be initialized until after the buffer pool */
SHMQueueInit(&(MyProc->lockQueue));
MyProc->procId = ProcGlobal->numProcs;
ProcGlobal->numProcs++;
}
/*
* zero out the spin lock counts and set the sLocks field for
* ProcStructLock to 1 as we have acquired this spinlock above but
* didn't record it since we didn't have MyProc until now.
*/
memset(MyProc->sLocks, 0, sizeof(MyProc->sLocks));
MyProc->sLocks[ProcStructLock] = 1;
if (IsUnderPostmaster) {
IPCKey semKey;
int semNum;
int semId;
union semun semun;
ProcGetNewSemKeyAndNum(&semKey, &semNum);
semId = IpcSemaphoreCreate(semKey,
PROC_NSEMS_PER_SET,
IPCProtection,
IpcSemaphoreDefaultStartValue,
0,
&semstat);
/*
* we might be reusing a semaphore that belongs to a dead
* backend. So be careful and reinitialize its value here.
*/
semun.val = IpcSemaphoreDefaultStartValue;
semctl(semId, semNum, SETVAL, semun);
IpcSemaphoreLock(semId, semNum, IpcExclusiveLock);
MyProc->sem.semId = semId;
MyProc->sem.semNum = semNum;
MyProc->sem.semKey = semKey;
} else {
MyProc->sem.semId = -1;
}
/* ----------------------
* Release the lock.
* ----------------------
*/
SpinRelease(ProcStructLock);
MyProc->pid = 0;
#if 0
MyProc->pid = MyPid;
#endif
/* ----------------
* Start keeping spin lock stats from here on. Any botch before
* this initialization is forever botched
* ----------------
*/
memset(MyProc->sLocks, 0, MAX_SPINS*sizeof(*MyProc->sLocks));
/* -------------------------
* Install ourselves in the binding table. The name to
* use is determined by the OS-assigned process id. That
* allows the cleanup process to find us after any untimely
* exit.
* -------------------------
*/
pid = getpid();
location = MAKE_OFFSET(MyProc);
if ((! ShmemPIDLookup(pid,&location)) || (location != MAKE_OFFSET(MyProc)))
{
elog(FATAL,"InitProc: ShmemPID table broken");
}
MyProc->errType = NO_ERROR;
SHMQueueElemInit(&(MyProc->links));
on_exitpg(ProcKill, (caddr_t)pid);
ProcInitialized = TRUE;
}
/*
* ProcSleep -- put a process to sleep
*
* P() on the semaphore should put us to sleep. The process
* semaphore is cleared by default, so the first time we try
* to acquire it, we sleep.
*
* ASSUME: that no one will fiddle with the queue until after
* we release the spin lock.
*
* NOTES: The process queue is now a priority queue for locking.
*/
int
ProcSleep(PROC_QUEUE *queue,
SPINLOCK spinlock,
int token,
int prio,
LOCK *lock)
{
int i;
PROC *proc;
#ifndef WIN32 /* figure this out later */
struct itimerval timeval, dummy;
#endif /* WIN32 */
proc = (PROC *) MAKE_PTR(queue->links.prev);
for (i=0;i<queue->size;i++)
{
if (proc->prio < prio)
proc = (PROC *) MAKE_PTR(proc->links.prev);
else
break;
}
MyProc->token = token;
MyProc->waitLock = lock;
/* -------------------
* currently, we only need this for the ProcWakeup routines
* -------------------
*/
TransactionIdStore((TransactionId) GetCurrentTransactionId(), &MyProc->xid);
/* -------------------
* assume that these two operations are atomic (because
* of the spinlock).
* -------------------
*/
SHMQueueInsertTL(&(proc->links),&(MyProc->links));
queue->size++;
SpinRelease(spinlock);
/* --------------
* Postgres does not have any deadlock detection code and for this
* reason we must set a timer to wake up the process in the event of
* a deadlock. For now the timer is set for 1 minute and we assume that
* any process which sleeps for this amount of time is deadlocked and will
* receive a SIGALRM signal. The handler should release the processes
* semaphore and abort the current transaction.
*
* Need to zero out struct to set the interval and the micro seconds fields
* to 0.
* --------------
*/
#ifndef WIN32
memset(&timeval, 0, sizeof(struct itimerval));
timeval.it_value.tv_sec = DEADLOCK_TIMEOUT;
if (setitimer(ITIMER_REAL, &timeval, &dummy))
elog(FATAL, "ProcSleep: Unable to set timer for process wakeup");
#endif /* WIN32 */
/* --------------
* if someone wakes us between SpinRelease and IpcSemaphoreLock,
* IpcSemaphoreLock will not block. The wakeup is "saved" by
* the semaphore implementation.
* --------------
*/
IpcSemaphoreLock(MyProc->sem.semId, MyProc->sem.semNum, IpcExclusiveLock);
/* ---------------
* We were awoken before a timeout - now disable the timer
* ---------------
*/
#ifndef WIN32
timeval.it_value.tv_sec = 0;
if (setitimer(ITIMER_REAL, &timeval, &dummy))
elog(FATAL, "ProcSleep: Unable to diable timer for process wakeup");
#endif /* WIN32 */
/* ----------------
* We were assumed to be in a critical section when we went
* to sleep.
* ----------------
*/
SpinAcquire(spinlock);
return(MyProc->errType);
}
static status_t RtlRequest(device_t *device, request_t* req)
{
rtl8139_t *rtl;
request_eth_t *req_eth;
request_net_t *req_net;
asyncio_t *io;
bool was_empty;
net_hwaddr_t *addr;
rtl = device->cookie;
req_eth = (request_eth_t*) req;
req_net = (request_net_t*) req;
switch (req->code)
{
case ETH_SEND:
case ETH_RECEIVE:
if (req->code == ETH_SEND)
{
was_empty = true;
for (io = device->io_first; io != NULL; io = io->next)
if (io->req->code == ETH_SEND)
was_empty = false;
}
else
was_empty = true;
io = DevQueueRequest(device,
&req_eth->header,
sizeof(*req_eth),
req_eth->params.buffered.pages,
req_eth->params.buffered.length);
if (io == NULL)
{
req->result = errno;
return false;
}
io->extra = NULL;
if (was_empty)
{
SpinAcquire(&rtl->sem);
RtlStartIo(rtl);
SpinRelease(&rtl->sem);
}
return true;
case NET_GET_HW_INFO:
addr = req_net->params.net_hw_info.addr;
if (addr != NULL)
{
if (req_net->params.net_hw_info.addr_data_size < 6)
{
req->result = EBUFFER;
req_net->params.net_hw_info.addr_data_size = 6;
return false;
}
memcpy(addr->u.ethernet, rtl->station_address, 6);
addr->type = NET_HW_ETHERNET;
addr->data_size = 6;
}
req_net->params.net_hw_info.addr_data_size = 6;
req_net->params.net_hw_info.mtu = ETH_MAX_MTU;
return true;
}
req->result = ENOTIMPL;
return false;
}
