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sortix--sortix/kernel/pipe.cpp
2017-05-15 22:11:24 +02:00

784 lines
20 KiB
C++

/*
* Copyright (c) 2011, 2012, 2013, 2014, 2015, 2017 Jonas 'Sortie' Termansen.
*
* Permission to use, copy, modify, and distribute this software for any
* purpose with or without fee is hereby granted, provided that the above
* copyright notice and this permission notice appear in all copies.
*
* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
* ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
* ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
* OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
*
* pipe.cpp
* A device with a writing end and a reading end.
*/
#include <assert.h>
#include <errno.h>
#include <limits.h>
#include <stdint.h>
#include <string.h>
#include <sortix/fcntl.h>
#ifndef IOV_MAX
#include <sortix/limits.h>
#endif
#include <sortix/poll.h>
#include <sortix/signal.h>
#include <sortix/stat.h>
#include <sortix/kernel/copy.h>
#include <sortix/kernel/descriptor.h>
#include <sortix/kernel/dtable.h>
#include <sortix/kernel/inode.h>
#include <sortix/kernel/interlock.h>
#include <sortix/kernel/ioctx.h>
#include <sortix/kernel/kernel.h>
#include <sortix/kernel/kthread.h>
#include <sortix/kernel/pipe.h>
#include <sortix/kernel/poll.h>
#include <sortix/kernel/process.h>
#include <sortix/kernel/refcount.h>
#include <sortix/kernel/scheduler.h>
#include <sortix/kernel/signal.h>
#include <sortix/kernel/syscall.h>
#include <sortix/kernel/thread.h>
#include <sortix/kernel/vnode.h>
namespace Sortix {
class PipeChannel
{
public:
PipeChannel(uint8_t* buffer, size_t buffersize);
~PipeChannel();
void CloseReading();
void CloseWriting();
bool GetSIGPIPEDelivery();
void SetSIGPIPEDelivery(bool deliver_sigpipe);
size_t ReadSize();
size_t WriteSize();
bool ReadResize(size_t new_size);
bool WriteResize(size_t new_size);
ssize_t readv(ioctx_t* ctx, const struct iovec* iov, int iovcnt);
ssize_t recv(ioctx_t* ctx, uint8_t* buf, size_t count, int flags);
ssize_t recvmsg(ioctx_t* ctx, struct msghdr* msg, int flags);
ssize_t recvmsg_internal(ioctx_t* ctx, struct msghdr* msg, int flags);
ssize_t send(ioctx_t* ctx, const uint8_t* buf, size_t count, int flags);
ssize_t sendmsg(ioctx_t* ctx, const struct msghdr* msg, int flags);
ssize_t sendmsg_internal(ioctx_t* ctx, const struct msghdr* msg, int flags);
ssize_t writev(ioctx_t* ctx, const struct iovec* iov, int iovcnt);
int read_poll(ioctx_t* ctx, PollNode* node);
int write_poll(ioctx_t* ctx, PollNode* node);
private:
short ReadPollEventStatus();
short WritePollEventStatus();
private:
PollChannel read_poll_channel;
PollChannel write_poll_channel;
kthread_mutex_t pipelock;
kthread_cond_t readcond;
kthread_cond_t writecond;
uint8_t* buffer;
uintptr_t sender_system_tid;
uintptr_t receiver_system_tid;
size_t bufferoffset;
size_t bufferused;
size_t buffersize;
size_t pretended_read_buffer_size;
size_t pledged_read;
size_t pledged_write;
unsigned long closers;
bool anyreading;
bool anywriting;
bool is_sigpipe_enabled;
};
PipeChannel::PipeChannel(uint8_t* buffer, size_t buffersize)
{
pipelock = KTHREAD_MUTEX_INITIALIZER;
readcond = KTHREAD_COND_INITIALIZER;
writecond = KTHREAD_COND_INITIALIZER;
this->buffer = buffer;
this->buffersize = buffersize;
bufferoffset = bufferused = 0;
anyreading = anywriting = true;
is_sigpipe_enabled = true;
sender_system_tid = 0;
receiver_system_tid = 0;
pledged_read = 0;
pledged_write = 0;
closers = 0;
}
PipeChannel::~PipeChannel()
{
delete[] buffer;
}
void PipeChannel::CloseReading()
{
kthread_mutex_lock(&pipelock);
anyreading = false;
kthread_cond_broadcast(&writecond);
read_poll_channel.Signal(ReadPollEventStatus());
write_poll_channel.Signal(WritePollEventStatus());
kthread_mutex_unlock(&pipelock);
unsigned long count = InterlockedIncrement(&closers).n;
if ( count == 2 )
delete this;
}
void PipeChannel::CloseWriting()
{
kthread_mutex_lock(&pipelock);
anywriting = false;
kthread_cond_broadcast(&readcond);
read_poll_channel.Signal(ReadPollEventStatus());
write_poll_channel.Signal(WritePollEventStatus());
kthread_mutex_unlock(&pipelock);
unsigned long count = InterlockedIncrement(&closers).n;
if ( count == 2 )
delete this;
}
ssize_t PipeChannel::recv(ioctx_t* ctx, uint8_t* buf, size_t count,
int flags)
{
struct iovec iov;
memset(&iov, 0, sizeof(iov));
iov.iov_base = (void*) buf;
iov.iov_len = count;
struct msghdr msg;
memset(&msg, 0, sizeof(msg));
msg.msg_iov = &iov;
msg.msg_iovlen = 1;
return recvmsg_internal(ctx, &msg, flags);
}
ssize_t PipeChannel::readv(ioctx_t* ctx, const struct iovec* iov, int iovcnt)
{
struct msghdr msg;
memset(&msg, 0, sizeof(msg));
msg.msg_iov = (struct iovec*) iov;
msg.msg_iovlen = iovcnt;
return recvmsg_internal(ctx, &msg, 0);
}
ssize_t PipeChannel::recvmsg(ioctx_t* ctx, struct msghdr* msg_ptr, int flags)
{
struct msghdr msg;
if ( !ctx->copy_from_src(&msg, msg_ptr, sizeof(msg)) )
return -1;
if ( msg.msg_iovlen < 0 || IOV_MAX < msg.msg_iovlen )
return errno = EINVAL, -1;
size_t iov_size = msg.msg_iovlen * sizeof(struct iovec);
struct iovec* iov = new struct iovec[msg.msg_iovlen];
if ( !iov )
return -1;
if ( !ctx->copy_from_src(iov, msg.msg_iov, iov_size) )
return delete[] iov, -1;
msg.msg_iov = iov;
size_t result = recvmsg_internal(ctx, &msg, flags);
delete[] iov;
if ( !ctx->copy_to_dest(msg_ptr, &msg, sizeof(msg)) )
return -1;
return result;
}
ssize_t PipeChannel::recvmsg_internal(ioctx_t* ctx, struct msghdr* msg,
int flags)
{
if ( flags & ~(MSG_PEEK | MSG_WAITALL) )
return errno = EINVAL, -1;
Thread* this_thread = CurrentThread();
this_thread->yield_to_tid = sender_system_tid;
ScopedLockSignal lock(&pipelock);
if ( !lock.IsAcquired() )
return errno = EINTR, -1;
ssize_t so_far = 0;
size_t peeked = 0;
int iov_i = 0;
size_t iov_offset = 0;
while ( iov_i < msg->msg_iovlen && so_far < SSIZE_MAX )
{
size_t maxcount = SSIZE_MAX - so_far;
struct iovec* iov = &msg->msg_iov[iov_i];
uint8_t* buf = (uint8_t*) iov->iov_base + iov_offset;
size_t count = iov->iov_len - iov_offset;
if ( maxcount < count )
count = maxcount;
if ( count == 0 )
{
iov_i++;
iov_offset = 0;
continue;
}
receiver_system_tid = this_thread->system_tid;
while ( anywriting && bufferused <= peeked )
{
if ( (flags & MSG_PEEK) && so_far )
return so_far;
this_thread->yield_to_tid = sender_system_tid;
if ( pledged_read )
{
pledged_write++;
kthread_mutex_unlock(&pipelock);
kthread_yield();
kthread_mutex_lock(&pipelock);
pledged_write--;
continue;
}
if ( !(flags & MSG_WAITALL) && so_far )
return so_far;
if ( ctx->dflags & O_NONBLOCK )
return errno = EWOULDBLOCK, -1;
pledged_write++;
bool interrupted = !kthread_cond_wait_signal(&readcond, &pipelock);
pledged_write--;
if ( interrupted )
return so_far ? so_far : (errno = EINTR, -1);
}
size_t used = bufferused - peeked;
if ( !used && !anywriting )
return so_far;
size_t amount = count;
if ( used < amount )
amount = used;
size_t offset = bufferoffset;
if ( peeked )
offset = (bufferoffset + peeked) % buffersize;
size_t linear = buffersize - offset;
if ( linear < amount )
amount = linear;
assert(amount);
if ( !ctx->copy_to_dest(buf, buffer + offset, amount) )
return so_far ? so_far : -1;
so_far += amount;
if ( flags & MSG_PEEK )
peeked += amount;
else
{
bufferoffset = (bufferoffset + amount) % buffersize;
bufferused -= amount;
kthread_cond_broadcast(&writecond);
read_poll_channel.Signal(ReadPollEventStatus());
write_poll_channel.Signal(WritePollEventStatus());
}
iov_offset += amount;
if ( iov_offset == iov->iov_len )
{
iov_i++;
iov_offset = 0;
}
}
return so_far;
}
ssize_t PipeChannel::send(ioctx_t* ctx, const uint8_t* buf, size_t count,
int flags)
{
struct iovec iov;
memset(&iov, 0, sizeof(iov));
iov.iov_base = (void*) buf;
iov.iov_len = count;
struct msghdr msg;
memset(&msg, 0, sizeof(msg));
msg.msg_iov = &iov;
msg.msg_iovlen = 1;
return sendmsg_internal(ctx, &msg, flags);
}
ssize_t PipeChannel::writev(ioctx_t* ctx, const struct iovec* iov, int iovcnt)
{
struct msghdr msg;
memset(&msg, 0, sizeof(msg));
msg.msg_iov = (struct iovec*) iov;
msg.msg_iovlen = iovcnt;
return sendmsg_internal(ctx, &msg, 0);
}
ssize_t PipeChannel::sendmsg(ioctx_t* ctx, const struct msghdr* msg_ptr,
int flags)
{
struct msghdr msg;
if ( !ctx->copy_from_src(&msg, msg_ptr, sizeof(msg)) )
return -1;
if ( msg.msg_iovlen < 0 || IOV_MAX < msg.msg_iovlen )
return errno = EINVAL, -1;
size_t iov_size = msg.msg_iovlen * sizeof(struct iovec);
struct iovec* iov = new struct iovec[msg.msg_iovlen];
if ( !iov )
return -1;
if ( !ctx->copy_from_src(iov, msg.msg_iov, iov_size) )
return delete[] iov, -1;
msg.msg_iov = iov;
size_t result = sendmsg_internal(ctx, &msg, flags);
delete[] iov;
return result;
}
ssize_t PipeChannel::sendmsg_internal(ioctx_t* ctx, const struct msghdr* msg,
int flags)
{
if ( flags & ~(MSG_WAITALL | MSG_NOSIGNAL) )
return errno = EINVAL, -1;
Thread* this_thread = CurrentThread();
this_thread->yield_to_tid = receiver_system_tid;
ScopedLockSignal lock(&pipelock);
if ( !lock.IsAcquired() )
return errno = EINTR, -1;
sender_system_tid = this_thread->system_tid;
ssize_t so_far = 0;
int iov_i = 0;
size_t iov_offset = 0;
while ( iov_i < msg->msg_iovlen && so_far < SSIZE_MAX )
{
size_t maxcount = SSIZE_MAX - so_far;
struct iovec* iov = &msg->msg_iov[iov_i];
const uint8_t* buf = (const uint8_t*) iov->iov_base + iov_offset;
size_t count = iov->iov_len - iov_offset;
if ( maxcount < count )
count = maxcount;
if ( count == 0 )
{
iov_i++;
iov_offset = 0;
continue;
}
sender_system_tid = this_thread->system_tid;
while ( anyreading && bufferused == buffersize )
{
this_thread->yield_to_tid = receiver_system_tid;
if ( pledged_write )
{
pledged_read++;
kthread_mutex_unlock(&pipelock);
kthread_yield();
kthread_mutex_lock(&pipelock);
pledged_read--;
continue;
}
if ( so_far && !(flags & MSG_WAITALL) )
return so_far;
if ( ctx->dflags & O_NONBLOCK )
return errno = EWOULDBLOCK, -1;
pledged_read++;
bool interrupted = !kthread_cond_wait_signal(&writecond, &pipelock);
pledged_read--;
if ( interrupted )
return errno = EINTR, -1;
}
if ( !anyreading )
{
if ( so_far )
return so_far;
if ( is_sigpipe_enabled && !(flags & MSG_NOSIGNAL) )
CurrentThread()->DeliverSignal(SIGPIPE);
return errno = EPIPE, -1;
}
size_t amount = count;
if ( buffersize - bufferused < amount )
amount = buffersize - bufferused;
size_t writeoffset = (bufferoffset + bufferused) % buffersize;
size_t linear = buffersize - writeoffset;
if ( linear < amount )
amount = linear;
assert(amount);
if ( !ctx->copy_from_src(buffer + writeoffset, buf, amount) )
return so_far ? so_far : -1;
bufferused += amount;
so_far += amount;
kthread_cond_broadcast(&readcond);
read_poll_channel.Signal(ReadPollEventStatus());
write_poll_channel.Signal(WritePollEventStatus());
iov_offset += amount;
if ( iov_offset == iov->iov_len )
{
iov_i++;
iov_offset = 0;
}
}
return so_far;
}
short PipeChannel::ReadPollEventStatus()
{
short status = 0;
if ( !anywriting && !bufferused )
status |= POLLHUP;
if ( bufferused )
status |= POLLIN | POLLRDNORM;
return status;
}
short PipeChannel::WritePollEventStatus()
{
short status = 0;
if ( !anyreading )
status |= POLLERR;
if ( anyreading && bufferused != buffersize )
status |= POLLOUT | POLLWRNORM;
return status;
}
int PipeChannel::read_poll(ioctx_t* /*ctx*/, PollNode* node)
{
ScopedLockSignal lock(&pipelock);
short ret_status = ReadPollEventStatus() & node->events;
if ( ret_status )
return node->master->revents |= ret_status, 0;
read_poll_channel.Register(node);
return errno = EAGAIN, -1;
}
int PipeChannel::write_poll(ioctx_t* /*ctx*/, PollNode* node)
{
ScopedLockSignal lock(&pipelock);
short ret_status = WritePollEventStatus() & node->events;
if ( ret_status )
return node->master->revents |= ret_status, 0;
write_poll_channel.Register(node);
return errno = EAGAIN, -1;
}
bool PipeChannel::GetSIGPIPEDelivery()
{
ScopedLockSignal lock(&pipelock);
return is_sigpipe_enabled;
}
void PipeChannel::SetSIGPIPEDelivery(bool deliver_sigpipe)
{
ScopedLockSignal lock(&pipelock);
is_sigpipe_enabled = deliver_sigpipe;
}
size_t PipeChannel::ReadSize()
{
ScopedLockSignal lock(&pipelock);
return pretended_read_buffer_size;
}
size_t PipeChannel::WriteSize()
{
ScopedLockSignal lock(&pipelock);
return buffersize;
}
bool PipeChannel::ReadResize(size_t new_size)
{
ScopedLockSignal lock(&pipelock);
if ( !new_size )
return errno = EINVAL, false;
// The read and write end share the same buffer, so let the write end decide
// how big a buffer it wants and pretend the read end can decide too.
pretended_read_buffer_size = new_size;
return true;
}
bool PipeChannel::WriteResize(size_t new_size)
{
ScopedLockSignal lock(&pipelock);
if ( !new_size )
return errno = EINVAL, false;
size_t MAX_PIPE_SIZE = 2 * 1024 * 1024;
if ( MAX_PIPE_SIZE < new_size )
new_size = MAX_PIPE_SIZE;
// Refuse to lose data if the the new size would cause truncation.
if ( new_size < bufferused )
new_size = bufferused;
uint8_t* new_buffer = new uint8_t[new_size];
if ( !new_buffer )
return false;
for ( size_t i = 0; i < bufferused; i++ )
new_buffer[i] = buffer[(bufferoffset + i) % buffersize];
delete[] buffer;
buffer = new_buffer;
buffersize = new_size;
return true;
}
PipeEndpoint::PipeEndpoint()
{
channel = NULL;
reading = false;
}
PipeEndpoint::~PipeEndpoint()
{
if ( channel )
Disconnect();
}
bool PipeEndpoint::Connect(PipeEndpoint* destination)
{
assert(!channel);
assert(!destination->channel);
const size_t BUFFER_SIZE = 64 * 1024;
size_t size = BUFFER_SIZE;
uint8_t* buffer = new uint8_t[size];
if ( !buffer )
return false;
destination->reading = !(reading = false);
if ( !(destination->channel = channel = new PipeChannel(buffer, size)) )
{
delete[] buffer;
return false;
}
return true;
}
void PipeEndpoint::Disconnect()
{
if ( !channel )
return;
if ( reading )
channel->CloseReading();
else
channel->CloseWriting();
channel = NULL;
}
ssize_t PipeEndpoint::recv(ioctx_t* ctx, uint8_t* buf, size_t count, int flags)
{
if ( !reading )
return errno = EBADF, -1;
if ( !channel )
return 0;
ssize_t result = channel->recv(ctx, buf, count, flags);
CurrentThread()->yield_to_tid = 0;
Scheduler::ScheduleTrueThread();
return result;
}
ssize_t PipeEndpoint::recvmsg(ioctx_t* ctx, struct msghdr* msg, int flags)
{
if ( !reading )
return errno = EBADF, -1;
if ( !channel )
return 0;
ssize_t result = channel->recvmsg(ctx, msg, flags);
CurrentThread()->yield_to_tid = 0;
Scheduler::ScheduleTrueThread();
return result;
}
ssize_t PipeEndpoint::send(ioctx_t* ctx, const uint8_t* buf, size_t count,
int flags)
{
if ( reading )
return errno = EBADF, -1;
if ( !channel )
{
if ( !(flags & MSG_NOSIGNAL) )
CurrentThread()->DeliverSignal(SIGPIPE);
return errno = EPIPE, -1;
}
ssize_t result = channel->send(ctx, buf, count, flags);
CurrentThread()->yield_to_tid = 0;
Scheduler::ScheduleTrueThread();
return result;
}
ssize_t PipeEndpoint::sendmsg(ioctx_t* ctx, const struct msghdr* msg, int flags)
{
if ( reading )
return errno = EBADF, -1;
if ( !channel )
{
if ( !(flags & MSG_NOSIGNAL) )
CurrentThread()->DeliverSignal(SIGPIPE);
return errno = EPIPE, -1;
}
ssize_t result = channel->sendmsg(ctx, msg, flags);
CurrentThread()->yield_to_tid = 0;
Scheduler::ScheduleTrueThread();
return result;
}
ssize_t PipeEndpoint::readv(ioctx_t* ctx, const struct iovec* iov, int iovcnt)
{
if ( !reading )
return errno = EBADF, -1;
ssize_t result = channel->readv(ctx, iov, iovcnt);
if ( !channel )
return 0;
CurrentThread()->yield_to_tid = 0;
Scheduler::ScheduleTrueThread();
return result;
}
ssize_t PipeEndpoint::writev(ioctx_t* ctx, const struct iovec* iov, int iovcnt)
{
if ( reading )
return errno = EBADF, -1;
if ( !channel )
{
CurrentThread()->DeliverSignal(SIGPIPE);
return errno = EPIPE, -1;
}
ssize_t result = channel->writev(ctx, iov, iovcnt);
CurrentThread()->yield_to_tid = 0;
Scheduler::ScheduleTrueThread();
return result;
}
int PipeEndpoint::poll(ioctx_t* ctx, PollNode* node)
{
if ( !channel )
return 0;
return reading ? channel->read_poll(ctx, node)
: channel->write_poll(ctx, node);
}
bool PipeEndpoint::GetSIGPIPEDelivery()
{
if ( !channel )
return errno = EINVAL, true;
return !reading ? channel->GetSIGPIPEDelivery() : false;
}
bool PipeEndpoint::SetSIGPIPEDelivery(bool deliver_sigpipe)
{
if ( !channel )
return errno = EINVAL, false;
if ( !reading )
channel->SetSIGPIPEDelivery(deliver_sigpipe);
else if ( reading && deliver_sigpipe != false )
return errno = EINVAL, false;
return true;
}
size_t PipeEndpoint::Size()
{
if ( !channel )
return errno = EINVAL, 0;
return reading ? channel->ReadSize()
: channel->WriteSize();
}
bool PipeEndpoint::Resize(size_t new_size)
{
if ( !channel )
return errno = EINVAL, false;
return reading ? channel->ReadResize(new_size)
: channel->WriteResize(new_size);
}
class PipeNode : public AbstractInode
{
public:
PipeNode(dev_t dev, uid_t owner, gid_t group, mode_t mode);
virtual ~PipeNode();
virtual ssize_t readv(ioctx_t* ctx, const struct iovec* iov, int iovcnt);
virtual ssize_t writev(ioctx_t* ctx, const struct iovec* iov, int iovcnt);
virtual int poll(ioctx_t* ctx, PollNode* node);
public:
bool Connect(PipeNode* destination);
private:
PipeEndpoint endpoint;
};
bool PipeNode::Connect(PipeNode* destination)
{
return endpoint.Connect(&destination->endpoint);
}
PipeNode::PipeNode(dev_t dev, uid_t owner, gid_t group, mode_t mode)
{
inode_type = INODE_TYPE_STREAM;
this->dev = dev;
this->ino = (ino_t) this;
this->stat_uid = owner;
this->stat_gid = group;
this->type = S_IFCHR;
this->stat_mode = (mode & S_SETABLE) | this->type;
supports_iovec = true;
}
PipeNode::~PipeNode()
{
}
ssize_t PipeNode::readv(ioctx_t* ctx, const struct iovec* iov, int iovcnt)
{
return endpoint.readv(ctx, iov, iovcnt);
}
ssize_t PipeNode::writev(ioctx_t* ctx, const struct iovec* iov, int iovcnt)
{
return endpoint.writev(ctx, iov, iovcnt);
}
int PipeNode::poll(ioctx_t* ctx, PollNode* node)
{
return endpoint.poll(ctx, node);
}
int sys_pipe2(int* pipefd, int flags)
{
int fdflags = 0;
if ( flags & O_CLOEXEC ) fdflags |= FD_CLOEXEC;
if ( flags & O_CLOFORK ) fdflags |= FD_CLOFORK;
flags &= ~(O_CLOEXEC | O_CLOFORK);
if ( flags & ~(O_NONBLOCK) )
return errno = EINVAL, -1;
Process* process = CurrentProcess();
uid_t uid = process->uid;
uid_t gid = process->gid;
mode_t mode = 0600;
Ref<PipeNode> recv_inode(new PipeNode(0, uid, gid, mode));
if ( !recv_inode ) return -1;
Ref<PipeNode> send_inode(new PipeNode(0, uid, gid, mode));
if ( !send_inode ) return -1;
if ( !send_inode->Connect(recv_inode.Get()) )
return -1;
Ref<Vnode> recv_vnode(new Vnode(recv_inode, Ref<Vnode>(NULL), 0, 0));
Ref<Vnode> send_vnode(new Vnode(send_inode, Ref<Vnode>(NULL), 0, 0));
if ( !recv_vnode || !send_vnode ) return -1;
Ref<Descriptor> recv_desc(new Descriptor(recv_vnode, O_READ | flags));
Ref<Descriptor> send_desc(new Descriptor(send_vnode, O_WRITE | flags));
if ( !recv_desc || !send_desc ) return -1;
Ref<DescriptorTable> dtable = process->GetDTable();
int recv_index, send_index;
if ( 0 <= (recv_index = dtable->Allocate(recv_desc, fdflags)) )
{
if ( 0 <= (send_index = dtable->Allocate(send_desc, fdflags)) )
{
int ret[2] = { recv_index, send_index };
if ( CopyToUser(pipefd, ret, sizeof(ret)) )
return 0;
dtable->Free(send_index);
}
dtable->Free(recv_index);
}
return -1;
}
} // namespace Sortix