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sortix--sortix/sortix/fs/user.cpp

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/*******************************************************************************
Copyright(C) Jonas 'Sortie' Termansen 2012, 2013.
This file is part of Sortix.
Sortix is free software: you can redistribute it and/or modify it under the
terms of the GNU General Public License as published by the Free Software
Foundation, either version 3 of the License, or (at your option) any later
version.
Sortix is distributed in the hope that it will be useful, but WITHOUT ANY
WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
FOR A PARTICULAR PURPOSE. See the GNU General Public License for more
details.
You should have received a copy of the GNU General Public License along with
Sortix. If not, see <http://www.gnu.org/licenses/>.
fs/user.cpp
User-space filesystem.
*******************************************************************************/
#include <sys/types.h>
#include <assert.h>
#include <ctype.h>
#include <errno.h>
#include <stddef.h>
#include <stdint.h>
#include <stdlib.h>
#include <string.h>
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#include <timespec.h>
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#include <sortix/dirent.h>
#include <sortix/fcntl.h>
#include <sortix/stat.h>
#include <sortix/termios.h>
#include <sortix/timespec.h>
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#include <fsmarshall-msg.h>
#include <sortix/kernel/platform.h>
#include <sortix/kernel/kthread.h>
#include <sortix/kernel/refcount.h>
#include <sortix/kernel/inode.h>
#include <sortix/kernel/ioctx.h>
#include <sortix/kernel/descriptor.h>
#include <sortix/kernel/vnode.h>
#include <sortix/kernel/mtable.h>
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#include <sortix/kernel/syscall.h>
#include <sortix/kernel/process.h>
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namespace Sortix {
namespace UserFS {
class ChannelDirection;
class Channel;
class ChannelNode;
class Server;
class ServerNode;
class Unode;
class ChannelDirection
{
public:
ChannelDirection();
~ChannelDirection();
size_t Send(ioctx_t* ctx, const void* ptr, size_t least, size_t max);
size_t Recv(ioctx_t* ctx, void* ptr, size_t least, size_t max);
void SendClose();
void RecvClose();
private:
static const size_t BUFFER_SIZE = 8192;
uint8_t buffer[BUFFER_SIZE];
size_t buffer_used;
size_t buffer_offset;
kthread_mutex_t transfer_lock;
kthread_cond_t not_empty;
kthread_cond_t not_full;
bool still_reading;
bool still_writing;
};
class Channel
{
public:
Channel();
~Channel();
public:
bool KernelSend(ioctx_t* ctx, const void* ptr, size_t count)
{
return KernelSend(ctx, ptr, count, count) == count;
}
size_t KernelSend(ioctx_t* ctx, const void* ptr, size_t least, size_t max);
bool KernelRecv(ioctx_t* ctx, void* ptr, size_t count)
{
return KernelRecv(ctx, ptr, count, count) == count;
}
size_t KernelRecv(ioctx_t* ctx, void* ptr, size_t least, size_t max);
void KernelClose();
public:
bool UserSend(ioctx_t* ctx, const void* ptr, size_t count)
{
return UserSend(ctx, ptr, count, count) == count;
}
size_t UserSend(ioctx_t* ctx, const void* ptr, size_t least, size_t max);
bool UserRecv(ioctx_t* ctx, void* ptr, size_t count)
{
return UserRecv(ctx, ptr, count, count) == count;
}
size_t UserRecv(ioctx_t* ctx, void* ptr, size_t least, size_t max);
void UserClose();
private:
kthread_mutex_t kernel_lock;
kthread_mutex_t user_lock;
kthread_mutex_t destruction_lock;
ChannelDirection from_kernel;
ChannelDirection from_user;
bool kernel_closed;
bool user_closed;
};
class ChannelNode : public AbstractInode
{
public:
ChannelNode();
ChannelNode(Channel* channel);
~ChannelNode();
void Construct(Channel* channel);
virtual ssize_t read(ioctx_t* ctx, uint8_t* buf, size_t count);
virtual ssize_t write(ioctx_t* ctx, const uint8_t* buf, size_t count);
private:
Channel* channel;
};
class Server : public Refcountable
{
public:
Server();
virtual ~Server();
Channel* Connect();
Channel* Listen();
Ref<Inode> BootstrapNode(ino_t ino, mode_t type);
Ref<Inode> OpenNode(ino_t ino, mode_t type);
private:
kthread_mutex_t connect_lock;
kthread_cond_t connecting_cond;
kthread_cond_t connectable_cond;
Channel* connecting;
};
class ServerNode : public AbstractInode
{
public:
ServerNode(Ref<Server> server);
virtual ~ServerNode();
virtual Ref<Inode> open(ioctx_t* ctx, const char* filename, int flags,
mode_t mode);
private:
Ref<Server> server;
};
class Unode : public Inode
{
public:
Unode(Ref<Server> server, ino_t ino, mode_t type);
virtual ~Unode();
virtual void linked();
virtual void unlinked();
virtual int sync(ioctx_t* ctx);
virtual int stat(ioctx_t* ctx, struct stat* st);
virtual int chmod(ioctx_t* ctx, mode_t mode);
virtual int chown(ioctx_t* ctx, uid_t owner, gid_t group);
virtual int truncate(ioctx_t* ctx, off_t length);
virtual off_t lseek(ioctx_t* ctx, off_t offset, int whence);
virtual ssize_t read(ioctx_t* ctx, uint8_t* buf, size_t count);
virtual ssize_t pread(ioctx_t* ctx, uint8_t* buf, size_t count,
off_t off);
virtual ssize_t write(ioctx_t* ctx, const uint8_t* buf, size_t count);
virtual ssize_t pwrite(ioctx_t* ctx, const uint8_t* buf, size_t count,
off_t off);
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virtual int utimens(ioctx_t* ctx, const struct timespec* atime,
const struct timespec* ctime,
const struct timespec* mtime);
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virtual int isatty(ioctx_t* ctx);
virtual ssize_t readdirents(ioctx_t* ctx, struct kernel_dirent* dirent,
size_t size, off_t start, size_t maxcount);
virtual Ref<Inode> open(ioctx_t* ctx, const char* filename, int flags,
mode_t mode);
virtual int mkdir(ioctx_t* ctx, const char* filename, mode_t mode);
virtual int link(ioctx_t* ctx, const char* filename, Ref<Inode> node);
virtual int link_raw(ioctx_t* ctx, const char* filename, Ref<Inode> node);
virtual int unlink(ioctx_t* ctx, const char* filename);
virtual int unlink_raw(ioctx_t* ctx, const char* filename);
virtual int rmdir(ioctx_t* ctx, const char* filename);
virtual int rmdir_me(ioctx_t* ctx);
virtual int symlink(ioctx_t* ctx, const char* oldname,
const char* filename);
virtual ssize_t readlink(ioctx_t* ctx, char* buf, size_t bufsiz);
virtual int tcgetwinsize(ioctx_t* ctx, struct winsize* ws);
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virtual int tcsetpgrp(ioctx_t* ctx, pid_t pgid);
virtual pid_t tcgetpgrp(ioctx_t* ctx);
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virtual int settermmode(ioctx_t* ctx, unsigned mode);
virtual int gettermmode(ioctx_t* ctx, unsigned* mode);
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virtual int poll(ioctx_t* ctx, PollNode* node);
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virtual int rename_here(ioctx_t* ctx, Ref<Inode> from, const char* oldname,
const char* newname);
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virtual Ref<Inode> accept(ioctx_t* ctx, uint8_t* addr, size_t* addrlen,
int flags);
virtual int bind(ioctx_t* ctx, const uint8_t* addr, size_t addrlen);
virtual int connect(ioctx_t* ctx, const uint8_t* addr, size_t addrlen);
virtual int listen(ioctx_t* ctx, int backlog);
virtual ssize_t recv(ioctx_t* ctx, uint8_t* buf, size_t count, int flags);
virtual ssize_t send(ioctx_t* ctx, const uint8_t* buf, size_t count,
int flags);
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private:
bool SendMessage(Channel* channel, size_t type, void* ptr, size_t size,
size_t extra = 0);
bool RecvMessage(Channel* channel, size_t type, void* ptr, size_t size);
void RecvError(Channel* channel);
bool RecvBoolean(Channel* channel);
void UnexpectedResponse(Channel* channel, struct fsm_msg_header* hdr);
private:
ioctx_t kctx;
Ref<Server> server;
};
//
// Implementation of Channel Directory.
//
ChannelDirection::ChannelDirection()
{
buffer_used = 0;
buffer_offset = 0;
transfer_lock = KTHREAD_MUTEX_INITIALIZER;
not_empty = KTHREAD_COND_INITIALIZER;
not_full = KTHREAD_COND_INITIALIZER;
still_reading = true;
still_writing = true;
}
ChannelDirection::~ChannelDirection()
{
}
size_t ChannelDirection::Send(ioctx_t* ctx, const void* ptr, size_t least, size_t max)
{
const uint8_t* src = (const uint8_t*) ptr;
size_t sofar = 0;
ScopedLock inner_lock(&transfer_lock);
while ( true )
{
while ( true )
{
if ( !still_reading )
return errno = EPIPE, sofar;
if ( buffer_used < BUFFER_SIZE )
break;
if ( least <= sofar )
return sofar;
if ( !kthread_cond_wait_signal(&not_full, &transfer_lock) )
return errno = EINTR, sofar;
}
size_t use_offset = (buffer_offset + buffer_used) % BUFFER_SIZE;
size_t count = max - sofar;
size_t available_to_end = BUFFER_SIZE - use_offset;
size_t available = BUFFER_SIZE - buffer_used;
if ( available_to_end < available )
available = available_to_end;
if ( available < count )
count = available;
if ( !ctx->copy_to_dest(buffer + use_offset, src + sofar, count) )
return sofar;
if ( !buffer_used )
kthread_cond_signal(&not_empty);
buffer_used += count;
sofar += count;
if ( sofar == max )
return sofar;
}
}
size_t ChannelDirection::Recv(ioctx_t* ctx, void* ptr, size_t least, size_t max)
{
uint8_t* dst = (uint8_t*) ptr;
size_t sofar = 0;
ScopedLock inner_lock(&transfer_lock);
while ( true )
{
while ( true )
{
if ( buffer_used )
break;
if ( least <= sofar )
return sofar;
if ( !still_writing )
return errno = EPIPE, sofar;
if ( !kthread_cond_wait_signal(&not_empty, &transfer_lock) )
return errno = EINTR, sofar;
}
size_t use_offset = buffer_offset;
size_t count = max - sofar;
size_t available_to_end = BUFFER_SIZE - use_offset;
size_t available = buffer_used;
if ( available_to_end < available )
available = available_to_end;
if ( available < count )
count = available;
if ( !ctx->copy_from_src(dst + sofar, buffer + use_offset, count) )
return sofar;
if ( buffer_used == BUFFER_SIZE )
kthread_cond_signal(&not_full);
buffer_offset = (buffer_offset + count) % BUFFER_SIZE;
buffer_used -= count;
sofar += count;
if ( sofar == max )
return sofar;
}
}
void ChannelDirection::SendClose()
{
ScopedLock lock(&transfer_lock);
still_writing = false;
kthread_cond_signal(&not_empty);
}
void ChannelDirection::RecvClose()
{
ScopedLock lock(&transfer_lock);
still_writing = false;
kthread_cond_signal(&not_full);
}
//
// Implementation of Channel.
//
Channel::Channel()
{
kernel_lock = KTHREAD_MUTEX_INITIALIZER;
user_lock = KTHREAD_MUTEX_INITIALIZER;
destruction_lock = KTHREAD_MUTEX_INITIALIZER;
user_closed = false;
kernel_closed = false;
}
Channel::~Channel()
{
}
size_t Channel::KernelSend(ioctx_t* ctx, const void* ptr, size_t least,
size_t max)
{
ScopedLockSignal outer_lock(&kernel_lock);
if ( !outer_lock.IsAcquired() )
return errno = EINTR, 0;
size_t ret = from_kernel.Send(ctx, ptr, least, max);
return ret;
}
size_t Channel::KernelRecv(ioctx_t* ctx, void* ptr, size_t least, size_t max)
{
ScopedLockSignal outer_lock(&kernel_lock);
if ( !outer_lock.IsAcquired() )
return errno = EINTR, 0;
return from_user.Recv(ctx, ptr, least, max);
}
void Channel::KernelClose()
{
// No lock needed, this thread is the last to use this object as kernel.
from_kernel.SendClose();
from_user.RecvClose();
kthread_mutex_lock(&destruction_lock);
kernel_closed = true;
bool delete_this = user_closed;
kthread_mutex_unlock(&destruction_lock);
if ( delete_this )
delete this;
}
size_t Channel::UserSend(ioctx_t* ctx, const void* ptr, size_t least,
size_t max)
{
ScopedLockSignal outer_lock(&user_lock);
if ( !outer_lock.IsAcquired() )
return errno = EINTR, 0;
return from_user.Send(ctx, ptr, least, max);
}
size_t Channel::UserRecv(ioctx_t* ctx, void* ptr, size_t least, size_t max)
{
ScopedLockSignal outer_lock(&user_lock);
if ( !outer_lock.IsAcquired() )
return errno = EINTR, 0;
return from_kernel.Recv(ctx, ptr, least, max);
}
void Channel::UserClose()
{
// No lock needed, this thread is the last to use this object as user.
from_kernel.RecvClose();
from_user.SendClose();
kthread_mutex_lock(&destruction_lock);
user_closed = true;
bool delete_this = kernel_closed;
kthread_mutex_unlock(&destruction_lock);
if ( delete_this )
delete this;
}
//
// Implementation of ChannelNode.
//
ChannelNode::ChannelNode()
{
channel = NULL;
}
ChannelNode::ChannelNode(Channel* channel)
{
Construct(channel);
}
ChannelNode::~ChannelNode()
{
if ( channel )
channel->UserClose();
}
void ChannelNode::Construct(Channel* channel)
{
inode_type = INODE_TYPE_STREAM;
this->channel = channel;
this->type = S_IFCHR;
this->dev = (dev_t) this;
this->ino = 0;
// TODO: Set uid, gid, mode.
}
ssize_t ChannelNode::read(ioctx_t* ctx, uint8_t* buf, size_t count)
{
return channel->UserRecv(ctx, buf, /*1*/ count, count);
}
ssize_t ChannelNode::write(ioctx_t* ctx, const uint8_t* buf, size_t count)
{
return channel->UserSend(ctx, buf, /*1*/ count, count);
}
//
// Implementation of Server.
//
Server::Server()
{
connect_lock = KTHREAD_MUTEX_INITIALIZER;
connecting_cond = KTHREAD_COND_INITIALIZER;
connectable_cond = KTHREAD_COND_INITIALIZER;
connecting = NULL;
}
Server::~Server()
{
}
Channel* Server::Connect()
{
Channel* channel = new Channel();
if ( !channel )
return NULL;
ScopedLock lock(&connect_lock);
while ( connecting )
if ( !kthread_cond_wait_signal(&connectable_cond, &connect_lock) )
{
delete channel;
return errno = EINTR, (Channel*) NULL;
}
connecting = channel;
kthread_cond_signal(&connecting_cond);
return channel;
}
Channel* Server::Listen()
{
ScopedLock lock(&connect_lock);
while ( !connecting )
if ( !kthread_cond_wait_signal(&connecting_cond, &connect_lock) )
return errno = EINTR, (Channel*) NULL;
Channel* result = connecting;
connecting = NULL;
kthread_cond_signal(&connectable_cond);
return result;
}
Ref<Inode> Server::BootstrapNode(ino_t ino, mode_t type)
{
return Ref<Inode>(new Unode(Ref<Server>(this), ino, type));
}
Ref<Inode> Server::OpenNode(ino_t ino, mode_t type)
{
return BootstrapNode(ino, type);
}
//
// Implementation of ServerNode.
//
ServerNode::ServerNode(Ref<Server> server)
{
inode_type = INODE_TYPE_UNKNOWN;
this->server = server;
this->type = S_IFDIR;
this->dev = (dev_t) this;
this->ino = 0;
// TODO: Set uid, gid, mode.
}
ServerNode::~ServerNode()
{
}
Ref<Inode> ServerNode::open(ioctx_t* /*ctx*/, const char* filename, int flags,
mode_t mode)
{
unsigned long long ull_ino;
char* end;
int saved_errno = errno; errno = 0;
if ( !isspace(*filename) &&
0 < (ull_ino = strtoull(filename, &end, 10)) &&
*end == '\0' &&
errno != ERANGE )
{
errno = saved_errno;
if ( !(flags & O_CREAT) )
return errno = ENOENT, Ref<Inode>(NULL);
ino_t ino = (ino_t) ull_ino;
return server->BootstrapNode(ino, mode & S_IFMT);
}
errno = saved_errno;
if ( !strcmp(filename, "listen") )
{
Ref<ChannelNode> node(new ChannelNode);
if ( !node )
return Ref<Inode>(NULL);
Channel* channel = server->Listen();
if ( !channel )
return Ref<Inode>(NULL);
node->Construct(channel);
return node;
}
return errno = ENOENT, Ref<Inode>(NULL);
}
//
// Implementation of Unode.
//
Unode::Unode(Ref<Server> server, ino_t ino, mode_t type)
{
SetupKernelIOCtx(&kctx);
this->server = server;
this->ino = ino;
this->dev = (dev_t) server;
this->type = type;
// Let the remote know that the kernel is using this inode.
if ( Channel* channel = server->Connect() )
{
struct fsm_req_refer msg;
msg.ino = ino;
SendMessage(channel, FSM_REQ_REFER, &msg, sizeof(msg));
channel->KernelClose();
}
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}
Unode::~Unode()
{
// Let the remote know that the kernel is no longer using this inode.
if ( Channel* channel = server->Connect() )
{
struct fsm_req_unref msg;
msg.ino = ino;
SendMessage(channel, FSM_REQ_UNREF, &msg, sizeof(msg));
channel->KernelClose();
}
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}
bool Unode::SendMessage(Channel* channel, size_t type, void* ptr, size_t size,
size_t extra)
{
struct fsm_msg_header hdr;
hdr.msgtype = type;
hdr.msgsize = size + extra;
if ( !channel->KernelSend(&kctx, &hdr, sizeof(hdr)) )
return false;
if ( !channel->KernelSend(&kctx, ptr, size) )
return false;
return true;
}
bool Unode::RecvMessage(Channel* channel, size_t type, void* ptr, size_t size)
{
struct fsm_msg_header resp_hdr;
if ( !channel->KernelRecv(&kctx, &resp_hdr, sizeof(resp_hdr)) )
return false;
if ( resp_hdr.msgtype != type )
{
UnexpectedResponse(channel, &resp_hdr);
return false;
}
return !ptr || !size || channel->KernelRecv(&kctx, ptr, size);
}
void Unode::RecvError(Channel* channel)
{
SetupKernelIOCtx(&kctx);
struct fsm_resp_error resp;
if ( channel->KernelRecv(&kctx, &resp, sizeof(resp)) )
errno = resp.errnum;
// In case of error, errno is set to that error.
}
bool Unode::RecvBoolean(Channel* channel)
{
struct fsm_msg_header resp_hdr;
if ( !channel->KernelRecv(&kctx, &resp_hdr, sizeof(resp_hdr)) )
return false;
if ( resp_hdr.msgtype == FSM_RESP_SUCCESS )
return true;
UnexpectedResponse(channel, &resp_hdr);
return false;
}
void Unode::UnexpectedResponse(Channel* channel, struct fsm_msg_header* hdr)
{
if ( hdr->msgtype == FSM_RESP_ERROR )
RecvError(channel);
else
errno = EIO;
}
void Unode::linked()
{
}
void Unode::unlinked()
{
}
int Unode::sync(ioctx_t* /*ctx*/)
{
Channel* channel = server->Connect();
if ( !channel )
return -1;
int ret = -1;
struct fsm_req_sync msg;
msg.ino = ino;
if ( SendMessage(channel, FSM_REQ_SYNC, &msg, sizeof(msg)) &&
RecvMessage(channel, FSM_RESP_SUCCESS, NULL, 0) )
ret = 0;
channel->KernelClose();
return ret;
}
int Unode::stat(ioctx_t* ctx, struct stat* st)
{
Channel* channel = server->Connect();
if ( !channel )
return -1;
int ret = -1;
struct fsm_req_stat msg;
struct fsm_resp_stat resp;
msg.ino = ino;
if ( SendMessage(channel, FSM_REQ_STAT, &msg, sizeof(msg)) &&
RecvMessage(channel, FSM_RESP_STAT, &resp, sizeof(resp)) &&
(resp.st.st_dev = (dev_t) server, true) &&
ctx->copy_to_dest(st, &resp.st, sizeof(*st)) )
ret = 0;
channel->KernelClose();
return ret;
}
int Unode::chmod(ioctx_t* /*ctx*/, mode_t mode)
{
Channel* channel = server->Connect();
if ( !channel )
return -1;
int ret = -1;
struct fsm_req_chmod msg;
msg.ino = ino;
msg.mode = mode;
if ( SendMessage(channel, FSM_REQ_CHMOD, &msg, sizeof(msg)) &&
RecvMessage(channel, FSM_RESP_SUCCESS, NULL, 0) )
ret = 0;
channel->KernelClose();
return ret;
}
int Unode::chown(ioctx_t* /*ctx*/, uid_t owner, gid_t group)
{
Channel* channel = server->Connect();
if ( !channel )
return -1;
int ret = -1;
struct fsm_req_chown msg;
msg.ino = ino;
msg.uid = owner;
msg.gid = group;
if ( SendMessage(channel, FSM_REQ_CHOWN, &msg, sizeof(msg)) &&
RecvMessage(channel, FSM_RESP_SUCCESS, NULL, 0) )
ret = 0;
channel->KernelClose();
return ret;
}
int Unode::truncate(ioctx_t* /*ctx*/, off_t length)
{
Channel* channel = server->Connect();
if ( !channel )
return -1;
int ret = -1;
struct fsm_req_truncate msg;
msg.ino = ino;
msg.size = length;
if ( SendMessage(channel, FSM_REQ_TRUNCATE, &msg, sizeof(msg)) &&
RecvMessage(channel, FSM_RESP_SUCCESS, NULL, 0) )
ret = 0;
channel->KernelClose();
return ret;
}
off_t Unode::lseek(ioctx_t* /*ctx*/, off_t offset, int whence)
{
Channel* channel = server->Connect();
if ( !channel )
return -1;
off_t ret = -1;
struct fsm_req_lseek msg;
struct fsm_resp_lseek resp;
msg.ino = ino;
msg.offset = offset;
msg.whence = whence;
if ( SendMessage(channel, FSM_REQ_LSEEK, &msg, sizeof(msg)) &&
RecvMessage(channel, FSM_RESP_LSEEK, &resp, sizeof(resp)) )
ret = resp.offset;
channel->KernelClose();
return ret;
}
ssize_t Unode::read(ioctx_t* ctx, uint8_t* buf, size_t count)
{
Channel* channel = server->Connect();
if ( !channel )
return -1;
ssize_t ret = -1;
struct fsm_req_read msg;
struct fsm_resp_read resp;
msg.ino = ino;
msg.count = count;
if ( SendMessage(channel, FSM_REQ_READ, &msg, sizeof(msg)) &&
RecvMessage(channel, FSM_RESP_READ, &resp, sizeof(resp)) )
{
if ( resp.count < count )
count = resp.count;
if ( channel->KernelRecv(ctx, buf, count) )
ret = (ssize_t) count;
}
channel->KernelClose();
return ret;
}
ssize_t Unode::pread(ioctx_t* ctx, uint8_t* buf, size_t count, off_t off)
{
Channel* channel = server->Connect();
if ( !channel )
return -1;
ssize_t ret = -1;
struct fsm_req_pread msg;
struct fsm_resp_read resp;
msg.ino = ino;
msg.count = count;
msg.offset = off;
if ( SendMessage(channel, FSM_REQ_PREAD, &msg, sizeof(msg)) &&
RecvMessage(channel, FSM_RESP_READ, &resp, sizeof(resp)) )
{
if ( resp.count < count )
count = resp.count;
if ( channel->KernelRecv(ctx, buf, count) )
ret = (ssize_t) count;
}
channel->KernelClose();
return ret;
}
ssize_t Unode::write(ioctx_t* ctx, const uint8_t* buf, size_t count)
{
Channel* channel = server->Connect();
if ( !channel )
return -1;
int ret = -1;
struct fsm_req_write msg;
msg.ino = ino;
msg.count = count;
struct fsm_msg_header hdr;
hdr.msgtype = FSM_REQ_WRITE;
hdr.msgsize = sizeof(msg) + count;
struct fsm_resp_write resp;
if ( channel->KernelSend(&kctx, &hdr, sizeof(hdr)) &&
channel->KernelSend(&kctx, &msg, sizeof(msg)) &&
channel->KernelSend(ctx, buf, count) &&
RecvMessage(channel, FSM_RESP_WRITE, &resp, sizeof(resp)) )
ret = (ssize_t) resp.count;
channel->KernelClose();
return ret;
}
ssize_t Unode::pwrite(ioctx_t* ctx, const uint8_t* buf, size_t count, off_t off)
{
Channel* channel = server->Connect();
if ( !channel )
return -1;
ssize_t ret = -1;
struct fsm_req_pwrite msg;
msg.ino = ino;
msg.count = count;
msg.offset = off;
struct fsm_msg_header hdr;
hdr.msgtype = FSM_REQ_PWRITE;
hdr.msgsize = sizeof(msg) + count;
struct fsm_resp_write resp;
if ( channel->KernelSend(&kctx, &hdr, sizeof(hdr)) &&
channel->KernelSend(&kctx, &msg, sizeof(msg)) &&
channel->KernelSend(ctx, buf, count) &&
RecvMessage(channel, FSM_RESP_WRITE, &resp, sizeof(resp)) )
ret = (ssize_t) resp.count;
channel->KernelClose();
return ret;
}
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int Unode::utimens(ioctx_t* /*ctx*/,
const struct timespec* atime,
const struct timespec* /*ctime*/,
const struct timespec* mtime)
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{
Channel* channel = server->Connect();
if ( !channel )
return -1;
int ret = -1;
struct fsm_req_utimens msg;
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msg.ino = ino;
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msg.times[0] = atime ? *atime : timespec_nul();
msg.times[1] = mtime ? *mtime : timespec_nul();
if ( SendMessage(channel, FSM_REQ_UTIMENS, &msg, sizeof(msg)) &&
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RecvMessage(channel, FSM_RESP_SUCCESS, NULL, 0) )
ret = 0;
channel->KernelClose();
return ret;
}
int Unode::isatty(ioctx_t* /*ctx*/)
{
Channel* channel = server->Connect();
if ( !channel )
return 0;
int ret = 0;
struct fsm_req_isatty msg;
msg.ino = ino;
if ( SendMessage(channel, FSM_REQ_ISATTY, &msg, sizeof(msg)) &&
RecvMessage(channel, FSM_RESP_SUCCESS, NULL, 0) )
ret = 1;
channel->KernelClose();
return ret;
}
ssize_t Unode::readdirents(ioctx_t* ctx, struct kernel_dirent* dirent,
size_t size, off_t start, size_t /*maxcount*/)
{
Channel* channel = server->Connect();
if ( !channel )
return -1;
ssize_t ret = -1;
struct fsm_req_readdirents msg;
struct fsm_resp_readdirents resp;
msg.ino = ino;
msg.rec_num = start;
errno = 0;
if ( SendMessage(channel, FSM_REQ_READDIRENTS, &msg, sizeof(msg)) &&
RecvMessage(channel, FSM_RESP_READDIRENTS, &resp, sizeof(resp)) )
{
if ( !resp.namelen )
{
ret = 0;
goto break_if;
}
struct kernel_dirent entry;
entry.d_reclen = sizeof(entry) + resp.namelen + 1;
entry.d_off = 0;
entry.d_namelen = resp.namelen;
entry.d_dev = (dev_t) server;
entry.d_ino = resp.ino;
if ( !ctx->copy_from_src(dirent, &entry, sizeof(entry)) )
goto break_if;
size_t needed = sizeof(*dirent) + resp.namelen + 1;
if ( size < needed && (errno = ERANGE) )
goto break_if;
uint8_t nul = 0;
if ( channel->KernelRecv(ctx, dirent->d_name, resp.namelen) &&
ctx->copy_from_src(&dirent->d_name[resp.namelen], &nul, 1) )
ret = (ssize_t) needed;
} break_if:
channel->KernelClose();
return ret;
}
Ref<Inode> Unode::open(ioctx_t* /*ctx*/, const char* filename, int flags,
mode_t mode)
{
Channel* channel = server->Connect();
if ( !channel )
return Ref<Inode>(NULL);
size_t filenamelen = strlen(filename);
Ref<Inode> ret;
struct fsm_req_open msg;
msg.dirino = ino;
msg.flags = flags;
msg.mode = mode;
msg.namelen = filenamelen;
struct fsm_resp_open resp;
if ( SendMessage(channel, FSM_REQ_OPEN, &msg, sizeof(msg), filenamelen) &&
channel->KernelSend(&kctx, filename, filenamelen) &&
RecvMessage(channel, FSM_RESP_OPEN, &resp, sizeof(resp)) )
ret = server->OpenNode(resp.ino, resp.type);
channel->KernelClose();
return ret;
}
int Unode::mkdir(ioctx_t* /*ctx*/, const char* filename, mode_t mode)
{
Channel* channel = server->Connect();
if ( !channel )
return 0;
size_t filenamelen = strlen(filename);
int ret = -1;
struct fsm_req_mkdir msg;
msg.dirino = ino;
msg.mode = mode;
msg.namelen = filenamelen;
struct fsm_resp_mkdir resp;
if ( SendMessage(channel, FSM_REQ_MKDIR, &msg, sizeof(msg), filenamelen) &&
channel->KernelSend(&kctx, filename, filenamelen) &&
RecvMessage(channel, FSM_RESP_MKDIR, &resp, sizeof(resp)) )
ret = 0;
channel->KernelClose();
return ret;
}
int Unode::link(ioctx_t* /*ctx*/, const char* filename, Ref<Inode> node)
{
if ( node->dev != this->dev )
return errno = EXDEV, -1;
Channel* channel = server->Connect();
if ( !channel )
return 0;
size_t filenamelen = strlen(filename);
int ret = -1;
struct fsm_req_link msg;
msg.dirino = ino;
msg.linkino = node->ino;
msg.namelen = filenamelen;
if ( SendMessage(channel, FSM_REQ_LINK, &msg, sizeof(msg), filenamelen) &&
channel->KernelSend(&kctx, filename, filenamelen) &&
RecvMessage(channel, FSM_RESP_SUCCESS, NULL, 0) )
ret = 0;
channel->KernelClose();
return ret;
}
int Unode::link_raw(ioctx_t* /*ctx*/, const char* /*filename*/, Ref<Inode> /*node*/)
{
return errno = EPERM, -1;
}
int Unode::unlink(ioctx_t* /*ctx*/, const char* filename)
{
// TODO: Make sure the target is no longer used!
Channel* channel = server->Connect();
if ( !channel )
return 0;
size_t filenamelen = strlen(filename);
int ret = -1;
struct fsm_req_unlink msg;
msg.dirino = ino;
msg.namelen = filenamelen;
if ( SendMessage(channel, FSM_REQ_UNLINK, &msg, sizeof(msg), filenamelen) &&
channel->KernelSend(&kctx, filename, filenamelen) &&
RecvMessage(channel, FSM_RESP_SUCCESS, NULL, 0) )
ret = 0;
channel->KernelClose();
return ret;
}
int Unode::unlink_raw(ioctx_t* /*ctx*/, const char* /*filename*/)
{
return errno = EPERM, -1;
}
int Unode::rmdir(ioctx_t* /*ctx*/, const char* filename)
{
// TODO: Make sure the target is no longer used!
Channel* channel = server->Connect();
if ( !channel )
return 0;
size_t filenamelen = strlen(filename);
int ret = -1;
struct fsm_req_rmdir msg;
msg.dirino = ino;
msg.namelen = filenamelen;
if ( SendMessage(channel, FSM_REQ_RMDIR, &msg, sizeof(msg), filenamelen) &&
channel->KernelSend(&kctx, filename, filenamelen) &&
RecvMessage(channel, FSM_RESP_SUCCESS, NULL, 0) )
ret = 0;
channel->KernelClose();
return ret;
}
int Unode::rmdir_me(ioctx_t* /*ctx*/)
{
return errno = EPERM, -1;
}
int Unode::symlink(ioctx_t* /*ctx*/, const char* oldname, const char* filename)
{
Channel* channel = server->Connect();
if ( !channel )
return 0;
size_t oldnamelen = strlen(oldname);
size_t filenamelen = strlen(filename);
int ret = -1;
struct fsm_req_symlink msg;
msg.dirino = ino;
msg.targetlen = oldnamelen;
msg.namelen = filenamelen;
size_t extra = msg.targetlen + msg.namelen;
if ( SendMessage(channel, FSM_REQ_SYMLINK, &msg, sizeof(msg), extra) &&
channel->KernelSend(&kctx, oldname, oldnamelen) &&
channel->KernelSend(&kctx, filename, filenamelen) &&
RecvMessage(channel, FSM_RESP_SUCCESS, NULL, 0) )
ret = 0;
channel->KernelClose();
return ret;
}
ssize_t Unode::readlink(ioctx_t* ctx, char* buf, size_t bufsiz)
{
Channel* channel = server->Connect();
if ( !channel )
return -1;
ssize_t ret = -1;
struct fsm_req_readlink msg;
struct fsm_resp_readlink resp;
msg.ino = ino;
if ( SendMessage(channel, FSM_REQ_READLINK, &msg, sizeof(msg)) &&
RecvMessage(channel, FSM_RESP_READLINK, &resp, sizeof(resp)) )
{
if ( resp.targetlen < bufsiz )
bufsiz = resp.targetlen;
if ( channel->KernelRecv(ctx, buf, bufsiz) )
ret = (ssize_t) bufsiz;
}
channel->KernelClose();
return ret;
}
int Unode::tcgetwinsize(ioctx_t* ctx, struct winsize* ws)
{
Channel* channel = server->Connect();
if ( !channel )
return -1;
int ret = -1;
struct fsm_req_tcgetwinsize msg;
struct fsm_resp_tcgetwinsize resp;
msg.ino = ino;
if ( SendMessage(channel, FSM_REQ_TCGETWINSIZE, &msg, sizeof(msg)) &&
RecvMessage(channel, FSM_RESP_TCGETWINSIZE, &resp, sizeof(resp)) &&
ctx->copy_to_dest(ws, &resp.size, sizeof(*ws)) )
ret = 0;
channel->KernelClose();
return ret;
}
2013-06-11 20:18:07 -04:00
int Unode::tcsetpgrp(ioctx_t* /*ctx*/, pid_t pgid)
{
Channel* channel = server->Connect();
if ( !channel )
return -1;
int ret = -1;
struct fsm_req_tcsetpgrp msg;
msg.ino = ino;
msg.pgid = pgid;
if ( SendMessage(channel, FSM_REQ_TCSETPGRP, &msg, sizeof(msg)) &&
RecvMessage(channel, FSM_RESP_SUCCESS, NULL, 0) )
ret = 0;
channel->KernelClose();
return ret;
}
pid_t Unode::tcgetpgrp(ioctx_t* /*ctx*/)
{
Channel* channel = server->Connect();
if ( !channel )
return -1;
pid_t ret = -1;
struct fsm_req_tcgetpgrp msg;
struct fsm_resp_tcgetpgrp resp;
msg.ino = ino;
if ( SendMessage(channel, FSM_REQ_TCGETPGRP, &msg, sizeof(msg)) &&
RecvMessage(channel, FSM_RESP_TCGETPGRP, &resp, sizeof(resp)) )
ret = resp.pgid;
channel->KernelClose();
return ret;
}
2013-01-30 14:33:13 -05:00
int Unode::settermmode(ioctx_t* /*ctx*/, unsigned mode)
{
Channel* channel = server->Connect();
if ( !channel )
return -1;
int ret = -1;
struct fsm_req_settermmode msg;
msg.ino = ino;
msg.termmode = mode;
if ( SendMessage(channel, FSM_REQ_SETTERMMODE, &msg, sizeof(msg)) &&
RecvMessage(channel, FSM_RESP_SUCCESS, NULL, 0) )
ret = 0;
channel->KernelClose();
return ret;
}
int Unode::gettermmode(ioctx_t* ctx, unsigned* mode)
{
Channel* channel = server->Connect();
if ( !channel )
return -1;
int ret = -1;
struct fsm_req_gettermmode msg;
struct fsm_resp_gettermmode resp;
msg.ino = ino;
if ( SendMessage(channel, FSM_REQ_GETTERMMODE, &msg, sizeof(msg)) &&
RecvMessage(channel, FSM_RESP_GETTERMMODE, &resp, sizeof(resp)) &&
ctx->copy_to_dest(mode, &resp.termmode, sizeof(*mode)) )
ret = 0;
channel->KernelClose();
return ret;
}
2012-12-29 17:09:09 -05:00
int Unode::poll(ioctx_t* /*ctx*/, PollNode* /*node*/)
{
return errno = ENOTSUP, -1;
}
2012-12-20 10:19:07 -05:00
int Unode::rename_here(ioctx_t* /*ctx*/, Ref<Inode> from, const char* oldname,
const char* newname)
{
Channel* channel = server->Connect();
if ( !channel )
return -1;
int ret = -1;
struct fsm_req_rename msg;
msg.olddirino = this->ino;
msg.newdirino = from->ino;
msg.oldnamelen = strlen(oldname);
msg.newnamelen = strlen(newname);
size_t extra = msg.oldnamelen + msg.newnamelen;
if ( SendMessage(channel, FSM_REQ_RENAME, &msg, sizeof(msg), extra) &&
channel->KernelSend(&kctx, oldname, msg.oldnamelen) &&
channel->KernelSend(&kctx, newname, msg.newnamelen) &&
RecvMessage(channel, FSM_RESP_SUCCESS, NULL, 0) )
ret = 0;
channel->KernelClose();
return ret;
}
2013-03-19 17:40:37 -04:00
Ref<Inode> Unode::accept(ioctx_t* /*ctx*/, uint8_t* /*addr*/,
size_t* /*addrlen*/, int /*flags*/)
{
return errno = ENOTSOCK, Ref<Inode>();
}
int Unode::bind(ioctx_t* /*ctx*/, const uint8_t* /*addr*/, size_t /*addrlen*/)
{
return errno = ENOTSOCK, -1;
}
int Unode::connect(ioctx_t* /*ctx*/, const uint8_t* /*addr*/, size_t /*addrlen*/)
{
return errno = ENOTSOCK, -1;
}
int Unode::listen(ioctx_t* /*ctx*/, int /*backlog*/)
{
return errno = ENOTSOCK, -1;
}
ssize_t Unode::recv(ioctx_t* /*ctx*/, uint8_t* /*buf*/, size_t /*count*/,
int /*flags*/)
{
return errno = ENOTSOCK, -1;
}
ssize_t Unode::send(ioctx_t* /*ctx*/, const uint8_t* /*buf*/, size_t /*count*/,
int /*flags*/)
{
return errno = ENOTSOCK, -1;
}
2013-01-30 14:33:13 -05:00
//
// Initialization.
//
class FactoryNode : public AbstractInode
{
public:
FactoryNode(uid_t owner, gid_t group, mode_t mode);
virtual ~FactoryNode() { }
virtual Ref<Inode> open(ioctx_t* ctx, const char* filename, int flags,
mode_t mode);
};
FactoryNode::FactoryNode(uid_t owner, gid_t group, mode_t mode)
{
inode_type = INODE_TYPE_UNKNOWN;
dev = (dev_t) this;
ino = 0;
this->type = S_IFDIR;
this->stat_uid = owner;
this->stat_gid = group;
this->stat_mode = (mode & S_SETABLE) | this->type;
}
Ref<Inode> FactoryNode::open(ioctx_t* /*ctx*/, const char* filename,
int /*flags*/, mode_t /*mode*/)
{
if ( !strcmp(filename, "new") )
{
Ref<Server> server(new Server());
if ( !server )
return Ref<Inode>(NULL);
Ref<ServerNode> node(new ServerNode(server));
if ( !node )
return Ref<Inode>(NULL);
return node;
}
return errno = ENOENT, Ref<Inode>(NULL);
}
static int sys_fsm_fsbind(int rootfd, int mpointfd, int /*flags*/)
{
Ref<Descriptor> desc = CurrentProcess()->GetDescriptor(rootfd);
if ( !desc ) { return -1; }
Ref<Descriptor> mpoint = CurrentProcess()->GetDescriptor(mpointfd);
if ( !mpoint ) { return -1; }
Ref<MountTable> mtable = CurrentProcess()->GetMTable();
Ref<Inode> node = desc->vnode->inode;
return mtable->AddMount(mpoint->ino, mpoint->dev, node) ? 0 : -1;
}
void Init(const char* devpath, Ref<Descriptor> slashdev)
{
ioctx_t ctx; SetupKernelIOCtx(&ctx);
Ref<Inode> node(new FactoryNode(0, 0, 0666));
if ( !node )
PanicF("Unable to allocate %s/fs inode.", devpath);
// TODO: Race condition! Create a mkdir function that returns what it
// created, possibly with a O_MKDIR flag to open.
if ( slashdev->mkdir(&ctx, "fs", 0755) < 0 && errno != EEXIST )
PanicF("Could not create a %s/fs directory", devpath);
Ref<Descriptor> mpoint = slashdev->open(&ctx, "fs", O_READ | O_WRITE, 0);
2013-01-30 14:33:13 -05:00
if ( !mpoint )
PanicF("Could not open the %s/fs directory", devpath);
Ref<MountTable> mtable = CurrentProcess()->GetMTable();
// TODO: Make sure that the mount point is *empty*! Add a proper function
// for this on the file descriptor class!
if ( !mtable->AddMount(mpoint->ino, mpoint->dev, node) )
PanicF("Unable to mount filesystem on %s/fs", devpath);
Syscall::Register(SYSCALL_FSM_FSBIND, (void*) sys_fsm_fsbind);
}
} // namespace UserFS
} // namespace Sortix