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sortix--sortix/ext/fsmarshall.cpp
2015-08-27 22:12:11 +02:00

787 lines
22 KiB
C++

/*******************************************************************************
Copyright(C) Jonas 'Sortie' Termansen 2013, 2014, 2015.
This program 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.
This program 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
this program. If not, see <http://www.gnu.org/licenses/>.
fsmarshall.cpp
Sortix fsmarshall frontend.
*******************************************************************************/
#if defined(__sortix__)
#include <sys/socket.h>
#include <sys/stat.h>
#include <sys/types.h>
#include <errno.h>
#include <error.h>
#include <fcntl.h>
#include <ioleast.h>
#include <signal.h>
#include <stdint.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <time.h>
#include <timespec.h>
#include <unistd.h>
#include <sortix/dirent.h>
#include <fsmarshall.h>
#include "ext-constants.h"
#include "ext-structs.h"
#include "blockgroup.h"
#include "block.h"
#include "device.h"
#include "extfs.h"
#include "filesystem.h"
#include "fsmarshall.h"
#include "fuse.h"
#include "inode.h"
bool RespondData(int chl, const void* ptr, size_t count)
{
return writeall(chl, ptr, count) == count;
}
bool RespondHeader(int chl, size_t type, size_t size)
{
struct fsm_msg_header hdr;
hdr.msgtype = type;
hdr.msgsize = size;
return RespondData(chl, &hdr, sizeof(hdr));
}
bool RespondMessage(int chl, unsigned int type, const void* ptr, size_t count)
{
return RespondHeader(chl, type, count) &&
RespondData(chl, ptr, count);
}
bool RespondError(int chl, int errnum)
{
struct fsm_resp_error body;
body.errnum = errnum;
//fprintf(stderr, "extfs: sending error %i (%s)\n", errnum, strerror(errnum));
return RespondMessage(chl, FSM_RESP_ERROR, &body, sizeof(body));
}
bool RespondSuccess(int chl)
{
struct fsm_resp_success body;
return RespondMessage(chl, FSM_RESP_SUCCESS, &body, sizeof(body));
}
bool RespondStat(int chl, struct stat* st)
{
struct fsm_resp_stat body;
body.st = *st;
return RespondMessage(chl, FSM_RESP_STAT, &body, sizeof(body));
}
bool RespondStatVFS(int chl, struct statvfs* stvfs)
{
struct fsm_resp_statvfs body;
body.stvfs = *stvfs;
return RespondMessage(chl, FSM_RESP_STATVFS, &body, sizeof(body));
}
bool RespondSeek(int chl, off_t offset)
{
struct fsm_resp_lseek body;
body.offset = offset;
return RespondMessage(chl, FSM_RESP_LSEEK, &body, sizeof(body));
}
bool RespondRead(int chl, const uint8_t* buf, size_t count)
{
struct fsm_resp_read body;
body.count = count;
return RespondMessage(chl, FSM_RESP_READ, &body, sizeof(body)) &&
RespondData(chl, buf, count);
}
bool RespondReadlink(int chl, const uint8_t* buf, size_t count)
{
struct fsm_resp_readlink body;
body.targetlen = count;
return RespondMessage(chl, FSM_RESP_READLINK, &body, sizeof(body)) &&
RespondData(chl, buf, count);
}
bool RespondWrite(int chl, size_t count)
{
struct fsm_resp_write body;
body.count = count;
return RespondMessage(chl, FSM_RESP_WRITE, &body, sizeof(body));
}
bool RespondOpen(int chl, ino_t ino, mode_t type)
{
struct fsm_resp_open body;
body.ino = ino;
body.type = type;
return RespondMessage(chl, FSM_RESP_OPEN, &body, sizeof(body));
}
bool RespondMakeDir(int chl, ino_t ino)
{
struct fsm_resp_mkdir body;
body.ino = ino;
return RespondMessage(chl, FSM_RESP_MKDIR, &body, sizeof(body));
}
bool RespondReadDir(int chl, struct kernel_dirent* dirent)
{
struct fsm_resp_readdirents body;
body.ino = dirent->d_ino;
body.type = dirent->d_type;
body.namelen = dirent->d_namlen;
return RespondMessage(chl, FSM_RESP_READDIRENTS, &body, sizeof(body)) &&
RespondData(chl, dirent->d_name, dirent->d_namlen);
}
bool RespondTCGetBlob(int chl, const void* data, size_t data_size)
{
struct fsm_resp_tcgetblob body;
body.count = data_size;
return RespondMessage(chl, FSM_RESP_TCGETBLOB, &body, sizeof(body)) &&
RespondData(chl, data, data_size);
}
void HandleRefer(int chl, struct fsm_req_refer* msg, Filesystem* fs)
{
(void) chl;
if ( fs->num_inodes <= msg->ino )
return;
if ( Inode* inode = fs->GetInode((uint32_t) msg->ino) )
inode->RemoteRefer();
}
void HandleUnref(int chl, struct fsm_req_unref* msg, Filesystem* fs)
{
(void) chl;
if ( fs->num_inodes <= msg->ino )
return;
if ( Inode* inode = fs->GetInode((uint32_t) msg->ino) )
inode->RemoteUnref();
}
void HandleSync(int chl, struct fsm_req_sync* msg, Filesystem* fs)
{
if ( fs->num_inodes <= msg->ino ) { RespondError(chl, EBADF); return; }
Inode* inode = fs->GetInode((uint32_t) msg->ino);
if ( !inode ) { RespondError(chl, errno); return; }
inode->Sync();
inode->Unref();
RespondSuccess(chl);
}
void HandleStat(int chl, struct fsm_req_stat* msg, Filesystem* fs)
{
if ( fs->num_inodes <= msg->ino ) { RespondError(chl, EBADF); return; }
Inode* inode = fs->GetInode((uint32_t) msg->ino);
if ( !inode ) { RespondError(chl, errno); return; }
struct stat st;
StatInode(inode, &st);
inode->Unref();
RespondStat(chl, &st);
}
void HandleChangeMode(int chl, struct fsm_req_chmod* msg, Filesystem* fs)
{
if ( fs->num_inodes <= msg->ino ) { RespondError(chl, EBADF); return; }
Inode* inode = fs->GetInode((uint32_t) msg->ino);
if ( !inode ) { RespondError(chl, errno); return; }
uint32_t req_mode = ExtModeFromHostMode(msg->mode);
uint32_t old_mode = inode->Mode();
uint32_t new_mode = (old_mode & ~S_SETABLE) | (req_mode & S_SETABLE);
inode->SetMode(new_mode);
inode->Unref();
RespondSuccess(chl);
}
void HandleChangeOwner(int chl, struct fsm_req_chown* msg, Filesystem* fs)
{
if ( fs->num_inodes <= msg->ino ) { RespondError(chl, EBADF); return; }
Inode* inode = fs->GetInode((uint32_t) msg->ino);
if ( !inode ) { RespondError(chl, errno); return; }
inode->SetUserId((uint32_t) msg->uid);
inode->SetGroupId((uint32_t) msg->gid);
inode->Unref();
RespondSuccess(chl);
}
void HandleUTimens(int chl, struct fsm_req_utimens* msg, Filesystem* fs)
{
if ( fs->num_inodes <= msg->ino ) { RespondError(chl, EBADF); return; }
Inode* inode = fs->GetInode((uint32_t) msg->ino);
if ( !inode ) { RespondError(chl, errno); return; }
inode->BeginWrite();
inode->data->i_atime = msg->times[0].tv_sec;
inode->data->i_mtime = msg->times[1].tv_sec;
inode->FinishWrite();
inode->Unref();
RespondSuccess(chl);
}
void HandleTruncate(int chl, struct fsm_req_truncate* msg, Filesystem* fs)
{
if( msg->size < 0 ) { RespondError(chl, EINVAL); return; }
if ( fs->num_inodes <= msg->ino ) { RespondError(chl, EBADF); return; }
Inode* inode = fs->GetInode((uint32_t) msg->ino);
if ( !inode ) { RespondError(chl, errno); return; }
inode->Truncate((uint64_t) msg->size);
inode->Unref();
RespondSuccess(chl);
}
void HandleSeek(int chl, struct fsm_req_lseek* msg, Filesystem* fs)
{
if ( fs->num_inodes <= msg->ino ) { RespondError(chl, EBADF); return; }
Inode* inode = fs->GetInode((uint32_t) msg->ino);
if ( !inode ) { RespondError(chl, errno); return; }
if ( msg->whence == SEEK_SET )
RespondSeek(chl, msg->offset);
else if ( msg->whence == SEEK_END )
{
off_t inode_size = inode->Size();
if ( (msg->offset < 0 && inode_size + msg->offset < 0) ||
(0 <= msg->offset && OFF_MAX - inode_size < msg->offset) )
RespondError(chl, EOVERFLOW);
else
RespondSeek(chl, msg->offset + inode_size);
}
else
RespondError(chl, EINVAL);
inode->Unref();
}
void HandleReadAt(int chl, struct fsm_req_pread* msg, Filesystem* fs)
{
if ( fs->num_inodes <= msg->ino ) { RespondError(chl, EBADF); return; }
Inode* inode = fs->GetInode((uint32_t) msg->ino);
if ( !inode ) { RespondError(chl, errno); return; }
uint8_t* buf = (uint8_t*) malloc(msg->count);
if ( !buf ) { inode->Unref(); RespondError(chl, errno); return; }
ssize_t amount = inode->ReadAt(buf, msg->count, msg->offset);
RespondRead(chl, buf, amount);
inode->Unref();
free(buf);
}
void HandleWriteAt(int chl, struct fsm_req_pwrite* msg, Filesystem* fs)
{
if ( fs->num_inodes <= msg->ino ) { RespondError(chl, EBADF); return; }
Inode* inode = fs->GetInode((uint32_t) msg->ino);
if ( !inode ) { RespondError(chl, errno); return; }
const uint8_t* buf = (const uint8_t*) &msg[1];
ssize_t amount = inode->WriteAt(buf, msg->count, msg->offset);
RespondWrite(chl, amount);
inode->Unref();
}
void HandleOpen(int chl, struct fsm_req_open* msg, Filesystem* fs)
{
if ( fs->num_inodes <= msg->dirino ) { RespondError(chl, EBADF); return; }
Inode* inode = fs->GetInode((uint32_t) msg->dirino);
if ( !inode ) { RespondError(chl, errno); return; }
char* pathraw = (char*) &(msg[1]);
char* path = (char*) malloc(msg->namelen+1);
if ( !path )
{
RespondError(chl, errno);
inode->Unref();
return;
}
memcpy(path, pathraw, msg->namelen);
path[msg->namelen] = '\0';
Inode* result = inode->Open(path, msg->flags, ExtModeFromHostMode(msg->mode));
free(path);
inode->Unref();
if ( !result ) { RespondError(chl, errno); return; }
RespondOpen(chl, result->inode_id, result->Mode() & S_IFMT);
result->Unref();
}
void HandleMakeDir(int chl, struct fsm_req_mkdir* msg, Filesystem* fs)
{
if ( fs->num_inodes <= msg->dirino ) { RespondError(chl, EBADF); return; }
Inode* inode = fs->GetInode((uint32_t) msg->dirino);
if ( !inode ) { RespondError(chl, errno); return; }
char* pathraw = (char*) &(msg[1]);
char* path = (char*) malloc(msg->namelen+1);
if ( !path )
{
RespondError(chl, errno);
inode->Unref();
return;
}
memcpy(path, pathraw, msg->namelen);
path[msg->namelen] = '\0';
Inode* result = inode->CreateDirectory(path, ExtModeFromHostMode(msg->mode));
free(path);
inode->Unref();
if ( !result ) { RespondError(chl, errno); return; }
RespondMakeDir(chl, result->inode_id);
result->Unref();
}
void HandleReadDir(int chl, struct fsm_req_readdirents* msg, Filesystem* fs)
{
if ( fs->num_inodes <= msg->ino ) { RespondError(chl, EBADF); return; }
Inode* inode = fs->GetInode((uint32_t) msg->ino);
if ( !inode ) { RespondError(chl, errno); return; }
if ( !S_ISDIR(inode->Mode()) )
{
inode->Unref();
RespondError(chl, ENOTDIR);
return;
}
union
{
struct kernel_dirent kernel_entry;
uint8_t padding[sizeof(struct kernel_dirent) + 256];
};
memset(&kernel_entry, 0, sizeof(kernel_entry));
uint64_t file_size = inode->Size();
uint64_t offset = 0;
Block* block = NULL;
uint64_t block_id = 0;
while ( offset < file_size )
{
uint64_t entry_block_id = offset / fs->block_size;
uint64_t entry_block_offset = offset % fs->block_size;
if ( block && block_id != entry_block_id )
block->Unref(),
block = NULL;
if ( !block && !(block = inode->GetBlock(block_id = entry_block_id)) )
{
inode->Unref();
RespondError(chl, errno);
return;
}
const uint8_t* block_data = block->block_data + entry_block_offset;
const struct ext_dirent* entry = (const struct ext_dirent*) block_data;
if ( entry->inode && entry->name_len && !(msg->rec_num--) )
{
kernel_entry.d_reclen = sizeof(kernel_entry) + entry->name_len;
kernel_entry.d_nextoff = 0;
kernel_entry.d_ino = entry->inode;
kernel_entry.d_dev = 0;
kernel_entry.d_type = 0; // TODO: Support this!
kernel_entry.d_namlen = entry->name_len;
memcpy(kernel_entry.d_name, entry->name, entry->name_len);
size_t dname_offset = offsetof(struct kernel_dirent, d_name);
padding[dname_offset + kernel_entry.d_namlen] = '\0';
block->Unref();
inode->Unref();
RespondReadDir(chl, &kernel_entry);
return;
}
offset += entry->reclen;
}
if ( block )
block->Unref();
kernel_entry.d_reclen = sizeof(kernel_entry);
RespondReadDir(chl, &kernel_entry);
}
void HandleIsATTY(int chl, struct fsm_req_isatty* msg, Filesystem* fs)
{
if ( fs->num_inodes <= msg->ino ) { RespondError(chl, EBADF); return; }
Inode* inode = fs->GetInode((uint32_t) msg->ino);
if ( !inode ) { RespondError(chl, errno); return; }
RespondError(chl, ENOTTY);
inode->Unref();
}
void HandleUnlink(int chl, struct fsm_req_unlink* msg, Filesystem* fs)
{
if ( fs->num_inodes <= msg->dirino ) { RespondError(chl, EBADF); return; }
Inode* inode = fs->GetInode((uint32_t) msg->dirino);
if ( !inode ) { RespondError(chl, errno); return; }
char* pathraw = (char*) &(msg[1]);
char* path = (char*) malloc(msg->namelen+1);
if ( !path )
{
RespondError(chl, errno);
inode->Unref();
return;
}
memcpy(path, pathraw, msg->namelen);
path[msg->namelen] = '\0';
Inode* result = inode->Unlink(path, false);
free(path);
inode->Unref();
if ( !result ) { RespondError(chl, errno); return; }
result->Unref();
RespondSuccess(chl);
}
void HandleRemoveDir(int chl, struct fsm_req_unlink* msg, Filesystem* fs)
{
if ( fs->num_inodes <= msg->dirino ) { RespondError(chl, EBADF); return; }
Inode* inode = fs->GetInode((uint32_t) msg->dirino);
if ( !inode ) { RespondError(chl, errno); return; }
char* pathraw = (char*) &(msg[1]);
char* path = (char*) malloc(msg->namelen+1);
if ( !path )
{
RespondError(chl, errno);
inode->Unref();
return;
}
memcpy(path, pathraw, msg->namelen);
path[msg->namelen] = '\0';
if ( inode->RemoveDirectory(path) )
RespondSuccess(chl);
else
RespondError(chl, errno);
free(path);
inode->Unref();
}
void HandleLink(int chl, struct fsm_req_link* msg, Filesystem* fs)
{
if ( fs->num_inodes <= msg->dirino ) { RespondError(chl, EBADF); return; }
if ( fs->num_inodes <= msg->linkino ) { RespondError(chl, EBADF); return; }
Inode* inode = fs->GetInode((uint32_t) msg->dirino);
if ( !inode ) { RespondError(chl, errno); return; }
Inode* dest = fs->GetInode((uint32_t) msg->linkino);
if ( !dest ) { inode->Unref(); RespondError(chl, errno); return; }
char* pathraw = (char*) &(msg[1]);
char* path = (char*) malloc(msg->namelen+1);
if ( !path )
{
RespondError(chl, errno);
inode->Unref();
return;
}
memcpy(path, pathraw, msg->namelen);
path[msg->namelen] = '\0';
if ( inode->Link(path, dest, false) )
RespondSuccess(chl);
else
RespondError(chl, errno);
free(path);
dest->Unref();
inode->Unref();
}
void HandleSymlink(int chl, struct fsm_req_symlink* msg, Filesystem* fs)
{
if ( fs->num_inodes <= msg->dirino ) { RespondError(chl, EBADF); return; }
Inode* inode = fs->GetInode((uint32_t) msg->dirino);
if ( !inode ) { RespondError(chl, errno); return; }
char* dest_raw = (char*) &(msg[1]);
char* dest = (char*) malloc(msg->targetlen + 1);
if ( !dest )
{
RespondError(chl, errno);
inode->Unref();
return;
}
memcpy(dest, dest_raw, msg->targetlen);
dest[msg->targetlen] = '\0';
char* path_raw = (char*) dest_raw + msg->targetlen;
char* path = (char*) malloc(msg->namelen + 1);
if ( !path )
{
RespondError(chl, errno);
inode->Unref();
return;
}
memcpy(path, path_raw, msg->namelen);
path[msg->namelen] = '\0';
if ( inode->Symlink(path, dest) )
RespondSuccess(chl);
else
RespondError(chl, errno);
free(path);
free(dest);
inode->Unref();
}
void HandleReadlink(int chl, struct fsm_req_readlink* msg, Filesystem* fs)
{
if ( fs->num_inodes <= msg->ino ) { RespondError(chl, EBADF); return; }
Inode* inode = fs->GetInode((uint32_t) msg->ino);
if ( !inode ) { RespondError(chl, errno); return; }
if ( !EXT2_S_ISLNK(inode->Mode()) ) { inode->Unref(); RespondError(chl, EINVAL); return; }
size_t count = inode->Size();
uint8_t* buf = (uint8_t*) malloc(count);
if ( !buf ) { inode->Unref(); RespondError(chl, errno); return; }
ssize_t amount = inode->ReadAt(buf, count, 0);
RespondReadlink(chl, buf, amount);
inode->Unref();
free(buf);
}
void HandleRename(int chl, struct fsm_req_rename* msg, Filesystem* fs)
{
if ( fs->num_inodes <= msg->olddirino ) { RespondError(chl, EBADF); return; }
if ( fs->num_inodes <= msg->newdirino ) { RespondError(chl, EBADF); return; }
char* pathraw = (char*) &(msg[1]);
char* path = (char*) malloc(msg->oldnamelen+1 + msg->newnamelen+1);
if ( !path ) { RespondError(chl, errno); return; }
memcpy(path, pathraw, msg->oldnamelen);
path[msg->oldnamelen] = '\0';
memcpy(path + msg->oldnamelen + 1, pathraw + msg->oldnamelen, msg->newnamelen);
path[msg->oldnamelen + 1 + msg->newnamelen] = '\0';
const char* oldname = path;
const char* newname = path + msg->oldnamelen + 1;
Inode* olddir = fs->GetInode((uint32_t) msg->olddirino);
if ( !olddir ) { free(path); RespondError(chl, errno); return; }
Inode* newdir = fs->GetInode((uint32_t) msg->newdirino);
if ( !newdir ) { olddir->Unref(); free(path); RespondError(chl, errno); return; }
if ( newdir->Rename(olddir, oldname, newname) )
RespondSuccess(chl);
else
RespondError(chl, errno);
newdir->Unref();
olddir->Unref();
free(path);
}
void HandleStatVFS(int chl, struct fsm_req_statvfs* msg, Filesystem* fs)
{
(void) msg;
struct statvfs stvfs;
stvfs.f_bsize = fs->block_size;
stvfs.f_frsize = fs->block_size;
stvfs.f_blocks = fs->num_blocks;
stvfs.f_bfree = fs->sb->s_free_blocks_count;
stvfs.f_bavail = fs->sb->s_free_blocks_count;
stvfs.f_files = fs->num_inodes;
stvfs.f_ffree = fs->sb->s_free_inodes_count;
stvfs.f_favail = fs->sb->s_free_inodes_count;
stvfs.f_ffree = fs->sb->s_free_inodes_count;
stvfs.f_fsid = 0;
stvfs.f_flag = 0;
if ( !fs->device->write )
stvfs.f_flag |= ST_RDONLY;
stvfs.f_namemax = 255;
RespondStatVFS(chl, &stvfs);
}
void HandleTCGetBlob(int chl, struct fsm_req_tcgetblob* msg, Filesystem* fs)
{
if ( fs->num_inodes <= msg->ino )
return (void) RespondError(chl, EBADF);
char* nameraw = (char*) &(msg[1]);
char* name = (char*) malloc(msg->namelen + 1);
if ( !name )
return (void) RespondError(chl, errno);
memcpy(name, nameraw, msg->namelen);
name[msg->namelen] = '\0';
static const char index[] = "device-path\0filesystem-type\0filesystem-uuid\0mount-path\0";
if ( !strcmp(name, "") )
RespondTCGetBlob(chl, index, sizeof(index) - 1);
else if ( !strcmp(name, "device-path") )
RespondTCGetBlob(chl, fs->device->path, strlen(fs->device->path));
else if ( !strcmp(name, "filesystem-type") )
RespondTCGetBlob(chl, "ext2", strlen("ext2"));
else if ( !strcmp(name, "filesystem-uuid") )
RespondTCGetBlob(chl, fs->sb->s_uuid, sizeof(fs->sb->s_uuid));
else if ( !strcmp(name, "mount-path") )
RespondTCGetBlob(chl, fs->mount_path, strlen(fs->mount_path));
else
RespondError(chl, ENOENT);
free(name);
}
void HandleIncomingMessage(int chl, struct fsm_msg_header* hdr, Filesystem* fs)
{
typedef void (*handler_t)(int, void*, Filesystem*);
handler_t handlers[FSM_MSG_NUM] = { NULL };
handlers[FSM_REQ_SYNC] = (handler_t) HandleSync;
handlers[FSM_REQ_STAT] = (handler_t) HandleStat;
handlers[FSM_REQ_CHMOD] = (handler_t) HandleChangeMode;
handlers[FSM_REQ_CHOWN] = (handler_t) HandleChangeOwner;
handlers[FSM_REQ_TRUNCATE] = (handler_t) HandleTruncate;
handlers[FSM_REQ_LSEEK] = (handler_t) HandleSeek;
handlers[FSM_REQ_PREAD] = (handler_t) HandleReadAt;
handlers[FSM_REQ_OPEN] = (handler_t) HandleOpen;
handlers[FSM_REQ_READDIRENTS] = (handler_t) HandleReadDir;
handlers[FSM_REQ_PWRITE] = (handler_t) HandleWriteAt;
handlers[FSM_REQ_ISATTY] = (handler_t) HandleIsATTY;
handlers[FSM_REQ_UTIMENS] = (handler_t) HandleUTimens;
handlers[FSM_REQ_MKDIR] = (handler_t) HandleMakeDir;
handlers[FSM_REQ_RMDIR] = (handler_t) HandleRemoveDir;
handlers[FSM_REQ_UNLINK] = (handler_t) HandleUnlink;
handlers[FSM_REQ_LINK] = (handler_t) HandleLink;
handlers[FSM_REQ_SYMLINK] = (handler_t) HandleSymlink;
handlers[FSM_REQ_READLINK] = (handler_t) HandleReadlink;
handlers[FSM_REQ_RENAME] = (handler_t) HandleRename;
handlers[FSM_REQ_REFER] = (handler_t) HandleRefer;
handlers[FSM_REQ_UNREF] = (handler_t) HandleUnref;
handlers[FSM_REQ_STATVFS] = (handler_t) HandleStatVFS;
handlers[FSM_REQ_TCGETBLOB] = (handler_t) HandleTCGetBlob;
if ( FSM_MSG_NUM <= hdr->msgtype || !handlers[hdr->msgtype] )
{
fprintf(stderr, "extfs: message type %zu not supported!\n", hdr->msgtype);
RespondError(chl, ENOTSUP);
return;
}
uint8_t* body = (uint8_t*) malloc(hdr->msgsize);
if ( !body )
{
fprintf(stderr, "extfs: message of type %zu too large: %zu bytes\n", hdr->msgtype, hdr->msgsize);
RespondError(chl, errno);
return;
}
size_t amount = readall(chl, body, hdr->msgsize);
if ( amount < hdr->msgsize )
{
fprintf(stderr, "extfs: incomplete message of type %zu: got %zi of %zu bytes\n", hdr->msgtype, amount, hdr->msgsize);
RespondError(chl, errno);
free(body);
return;
}
handlers[hdr->msgtype](chl, body, fs);
free(body);
}
static volatile bool should_terminate = false;
void TerminationHandler(int)
{
should_terminate = true;
}
int fsmarshall_main(const char* argv0,
const char* mount_path,
bool foreground,
Filesystem* fs,
Device* dev)
{
// Stat the root inode.
struct stat root_inode_st;
Inode* root_inode = fs->GetInode((uint32_t) EXT2_ROOT_INO);
if ( !root_inode )
error(1, errno, "GetInode(%u)", EXT2_ROOT_INO);
StatInode(root_inode, &root_inode_st);
root_inode->Unref();
// Create a filesystem server connected to the kernel that we'll listen on.
int serverfd = fsm_mountat(AT_FDCWD, mount_path, &root_inode_st, 0);
if ( serverfd < 0 )
error(1, errno, "%s", mount_path);
// Make sure the server isn't unexpectedly killed and data is lost.
signal(SIGINT, TerminationHandler);
signal(SIGTERM, TerminationHandler);
signal(SIGQUIT, TerminationHandler);
// Become a background process in its own process group by default.
if ( !foreground )
{
pid_t child_pid = fork();
if ( child_pid < 0 )
error(1, errno, "fork");
if ( child_pid )
exit(0);
setpgid(0, 0);
}
dev->SpawnSyncThread();
// Listen for filesystem messages and sync the filesystem every few seconds.
struct timespec last_sync_at;
clock_gettime(CLOCK_MONOTONIC, &last_sync_at);
int channel;
while ( 0 <= (channel = accept(serverfd, NULL, NULL)) )
{
if ( should_terminate )
break;
struct fsm_msg_header hdr;
size_t amount;
if ( (amount = readall(channel, &hdr, sizeof(hdr))) != sizeof(hdr) )
{
//error(0, errno, "incomplete header: got %zi of %zu bytes", amount, sizeof(hdr));
errno = 0;
continue;
}
HandleIncomingMessage(channel, &hdr, fs);
close(channel);
struct timespec now;
clock_gettime(CLOCK_MONOTONIC, &now);
if ( dev->write && !dev->has_sync_thread &&
5 <= timespec_sub(now, last_sync_at).tv_sec )
{
fs->Sync();
last_sync_at = now;
}
}
// Sync the filesystem before shutting down.
if ( dev->write )
{
fprintf(stderr, "%s: filesystem server shutting down, syncing...", argv0);
fflush(stderr);
fs->Sync();
fprintf(stderr, " done.\n");
}
close(serverfd);
delete fs;
delete dev;
return 0;
}
#endif