/*******************************************************************************
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 .
inode.cpp
Filesystem inode.
*******************************************************************************/
#define __STDC_CONSTANT_MACROS
#define __STDC_LIMIT_MACROS
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include "ext-constants.h"
#include "ext-structs.h"
#include "block.h"
#include "blockgroup.h"
#include "device.h"
#include "filesystem.h"
#include "inode.h"
#include "util.h"
#ifndef S_SETABLE
#define S_SETABLE 02777
#endif
Inode::Inode(Filesystem* filesystem, uint32_t inode_id)
{
this->prev_inode = NULL;
this->next_inode = NULL;
this->prev_hashed = NULL;
this->next_hashed = NULL;
this->prev_dirty = NULL;
this->next_dirty = NULL;
this->data_block = NULL;
this->data = NULL;
this->filesystem = filesystem;
this->reference_count = 1;
this->remote_reference_count = 1;
this->inode_id = inode_id;
this->dirty = false;
}
Inode::~Inode()
{
Sync();
if ( data_block )
data_block->Unref();
Unlink();
}
uint32_t Inode::Mode()
{
// TODO: Use i_mode_high.
return data->i_mode;
}
void Inode::SetMode(uint32_t mode)
{
// TODO: Use i_mode_high.
data->i_mode = (uint16_t) mode;
Dirty();
}
uint32_t Inode::UserId()
{
// TODO: Use i_uid_high.
return data->i_uid;
}
void Inode::SetUserId(uint32_t user)
{
// TODO: Use i_uid_high.
data->i_uid = (uint16_t) user;
Dirty();
}
uint32_t Inode::GroupId()
{
// TODO: Use i_gid_high.
return data->i_gid;
}
void Inode::SetGroupId(uint32_t group)
{
// TODO: Use i_gid_high.
data->i_gid = (uint16_t) group;
Dirty();
}
uint64_t Inode::Size()
{
bool largefile = filesystem->sb->s_feature_ro_compat &
EXT2_FEATURE_RO_COMPAT_LARGE_FILE;
if ( !EXT2_S_ISREG(data->i_mode) || !largefile )
return data->i_size;
uint64_t lower = data->i_size;
uint64_t upper = data->i_dir_acl;
uint64_t size = lower | (upper << 32ULL);
return size;
}
void Inode::SetSize(uint64_t new_size)
{
bool largefile = filesystem->sb->s_feature_ro_compat &
EXT2_FEATURE_RO_COMPAT_LARGE_FILE;
uint32_t lower = new_size & 0xFFFFFFFF;
uint32_t upper = new_size >> 32;
// TODO: Enforce filesize limit with no largefile support or non-files.
data->i_size = lower;
// TODO: Figure out these i_blocks semantics and how stuff is reserved.
const uint64_t ENTRIES = filesystem->block_size / sizeof(uint32_t);
uint64_t block_direct = sizeof(data->i_block) / sizeof(uint32_t) - 3;
uint64_t block_singly = ENTRIES;
uint64_t block_doubly = block_singly * block_singly;
uint64_t max_direct = block_direct;
uint64_t max_singly = max_direct + block_singly;
uint64_t max_doubly = max_singly + block_doubly;
uint64_t logical_blocks = divup(new_size, (uint64_t) filesystem->block_size);
uint64_t actual_blocks = logical_blocks;
if ( max_direct <= logical_blocks )
actual_blocks += divup(logical_blocks - max_direct, ENTRIES);
if ( max_singly <= logical_blocks )
actual_blocks += divup(logical_blocks - max_singly, ENTRIES * ENTRIES);
if ( max_doubly <= logical_blocks )
actual_blocks += divup(logical_blocks - max_doubly, ENTRIES * ENTRIES * ENTRIES);
data->i_blocks = (actual_blocks * filesystem->block_size) / 512;
if ( EXT2_S_ISREG(data->i_mode) && largefile )
data->i_dir_acl = upper;
Dirty();
Modified();
}
void Inode::Linked()
{
data->i_links_count++;
Dirty();
}
void Inode::Unlinked()
{
data->i_links_count--;
Dirty();
}
Block* Inode::GetBlockFromTable(Block* table, uint32_t index)
{
if ( uint32_t block_id = ((uint32_t*) table->block_data)[index] )
return filesystem->device->GetBlock(block_id);
uint32_t group_id = (inode_id - 1) / filesystem->sb->s_inodes_per_group;
assert(group_id < filesystem->num_groups);
BlockGroup* block_group = filesystem->GetBlockGroup(group_id);
uint32_t block_id = filesystem->AllocateBlock(block_group);
block_group->Unref();
if ( block_id )
{
Block* block = filesystem->device->GetBlockZeroed(block_id);
((uint32_t*) table->block_data)[index] = block_id;
table->Dirty();
return block;
}
return NULL;
}
Block* Inode::GetBlock(uint64_t offset)
{
const uint64_t ENTRIES = filesystem->block_size / sizeof(uint32_t);
uint64_t block_direct = sizeof(data->i_block) / sizeof(uint32_t) - 3;
uint64_t block_singly = ENTRIES;
uint64_t block_doubly = block_singly * block_singly;
uint64_t block_triply = block_doubly * block_singly;
uint64_t max_direct = block_direct;
uint64_t max_singly = max_direct + block_singly;
uint64_t max_doubly = max_singly + block_doubly;
uint64_t max_triply = max_doubly + block_triply;
uint32_t index;
Block* table = data_block; table->Refer();
Block* block;
uint32_t inode_offset = (uintptr_t) data - (uintptr_t) data_block->block_data;
uint32_t table_offset = offsetof(struct ext_inode, i_block);
uint32_t inode_block_table_offset = (inode_offset + table_offset) / sizeof(uint32_t);
// TODO: It would seem that somebody needs a lesson in induction. :-)
if ( offset < max_direct )
{
offset -= 0;
offset += inode_block_table_offset * 1;
read_direct:
index = offset;
offset %= 1;
block = GetBlockFromTable(table, index);
table->Unref();
if ( !block )
return NULL;
return block;
}
else if ( offset < max_singly )
{
offset -= max_direct;
offset += (inode_block_table_offset + 12) * ENTRIES;
read_singly:
index = offset / ENTRIES;
offset = offset % ENTRIES;
block = GetBlockFromTable(table, index);
table->Unref();
if ( !block )
return NULL;
table = block;
goto read_direct;
}
else if ( offset < max_doubly )
{
offset -= max_singly;
offset += (inode_block_table_offset + 13) * ENTRIES * ENTRIES;
read_doubly:
index = offset / (ENTRIES * ENTRIES);
offset = offset % (ENTRIES * ENTRIES);
block = GetBlockFromTable(table, index);
table->Unref();
if ( !block )
return NULL;
table = block;
goto read_singly;
}
else if ( offset < max_triply )
{
offset -= max_doubly;
offset += (inode_block_table_offset + 14) * ENTRIES * ENTRIES * ENTRIES;
/*read_triply:*/
index = offset / (ENTRIES * ENTRIES * ENTRIES);
offset = offset % (ENTRIES * ENTRIES * ENTRIES);
block = GetBlockFromTable(table, index);
table->Unref();
if ( !block )
return NULL;
table = block;
goto read_doubly;
}
return NULL;
}
bool Inode::FreeIndirect(uint64_t from, uint64_t offset, uint32_t block_id,
int indirection, uint64_t entry_span)
{
const uint64_t ENTRIES = filesystem->block_size / sizeof(uint32_t);
Block* block = filesystem->device->GetBlock(block_id);
uint32_t* table = (uint32_t*) block->block_data;
bool any_children = false;
for ( uint64_t i = 0; i < ENTRIES; i++ )
{
if ( !table[i] )
continue;
uint64_t entry_offset = offset + entry_span * i;
if ( entry_offset < from ||
(indirection &&
FreeIndirect(from, entry_offset, table[i], indirection-1,
entry_span / ENTRIES)) )
{
any_children = true;
continue;
}
filesystem->FreeBlock(table[i]);
table[i] = 0;
block->Dirty();
}
return any_children;
}
void Inode::Truncate(uint64_t new_size)
{
if ( 0 < Size() && Size() <= 60 && !data->i_blocks )
{
fprintf(stderr, "extfs: Truncating optimized symlinks is not implemented!\n");
return;
}
// TODO: Enforce a filesize limit!
uint64_t old_size = Size();
SetSize(new_size);
if ( old_size <= new_size )
return;
uint64_t old_num_blocks = divup(old_size, (uint64_t) filesystem->block_size);
uint64_t new_num_blocks = divup(new_size, (uint64_t) filesystem->block_size);
// Zero out the rest of the last partial block, if any.
uint32_t partial = new_size % filesystem->block_size;
if ( partial )
{
Block* partial_block = GetBlock(new_num_blocks-1);
uint8_t* data = partial_block->block_data;
memset(data + partial, 0, filesystem->block_size - partial);
partial_block->Dirty();
}
const uint64_t ENTRIES = filesystem->block_size / sizeof(uint32_t);
uint64_t block_direct = sizeof(data->i_block) / sizeof(uint32_t) - 3;
uint64_t block_singly = ENTRIES;
uint64_t block_doubly = block_singly * block_singly;
uint64_t block_triply = block_doubly * block_singly;
uint64_t max_direct = block_direct;
uint64_t max_singly = max_direct + block_singly;
uint64_t max_doubly = max_singly + block_doubly;
uint64_t max_triply = max_doubly + block_triply;
for ( uint64_t i = new_num_blocks; i < old_num_blocks && i < 12; i++ )
{
filesystem->FreeBlock(data->i_block[i]);
data->i_block[i] = 0;
}
if ( data->i_block[12] && !FreeIndirect(new_num_blocks, max_direct, data->i_block[12], 0, 1) )
{
filesystem->FreeBlock(data->i_block[12]);
data->i_block[12] = 0;
}
if ( data->i_block[13] && !FreeIndirect(new_num_blocks, max_singly, data->i_block[13], 1, ENTRIES) )
{
filesystem->FreeBlock(data->i_block[13]);
data->i_block[13] = 0;
}
if ( data->i_block[14] && !FreeIndirect(new_num_blocks, max_doubly, data->i_block[14], 2, ENTRIES * ENTRIES) )
{
filesystem->FreeBlock(data->i_block[14]);
data->i_block[14] = 0;
}
(void) max_triply;
Dirty();
}
Inode* Inode::Open(const char* elem, int flags, mode_t mode)
{
if ( !EXT2_S_ISDIR(Mode()) )
return errno = ENOTDIR, (Inode*) NULL;
size_t elem_length = strlen(elem);
uint64_t filesize = Size();
uint64_t offset = 0;
Block* block = NULL;
uint64_t block_id = 0;
while ( offset < filesize )
{
uint64_t entry_block_id = offset / filesystem->block_size;
uint64_t entry_block_offset = offset % filesystem->block_size;
if ( block && block_id != entry_block_id )
block->Unref(),
block = NULL;
if ( !block && !(block = GetBlock(block_id = entry_block_id)) )
return NULL;
const uint8_t* block_data = block->block_data + entry_block_offset;
const struct ext_dirent* entry = (const struct ext_dirent*) block_data;
if ( entry->name_len == elem_length &&
memcmp(elem, entry->name, elem_length) == 0 &&
entry->inode )
{
uint8_t file_type = entry->file_type;
uint32_t inode_id = entry->inode;
assert(inode_id);
block->Unref();
if ( (flags & O_CREAT) && (flags & O_EXCL) )
return errno = EEXIST, (Inode*) NULL;
if ( (flags & O_DIRECTORY) &&
file_type != EXT2_FT_UNKNOWN &&
file_type != EXT2_FT_DIR &&
file_type != EXT2_FT_SYMLINK )
return errno = ENOTDIR, (Inode*) NULL;
Inode* inode = filesystem->GetInode(inode_id);
if ( flags & O_DIRECTORY &&
!EXT2_S_ISDIR(inode->Mode()) &&
!EXT2_S_ISLNK(inode->Mode()) )
{
inode->Unref();
return errno = ENOTDIR, (Inode*) NULL;
}
if ( S_ISREG(inode->Mode()) && flags & O_TRUNC )
inode->Truncate(0);
return inode;
}
offset += entry->reclen;
}
if ( block )
block->Unref();
if ( flags & O_CREAT )
{
// TODO: Preferred block group!
uint32_t result_inode_id = filesystem->AllocateInode();
if ( !result_inode_id )
return NULL;
Inode* result = filesystem->GetInode(result_inode_id);
memset(result->data, 0, sizeof(*result->data));
result->SetMode((mode & S_SETABLE) | S_IFREG);
struct timespec now;
clock_gettime(CLOCK_REALTIME, &now);
result->data->i_atime = now.tv_sec;
result->data->i_ctime = now.tv_sec;
result->data->i_mtime = now.tv_sec;
// TODO: Set all the other inode properties!
if ( !Link(elem, result, false) )
{
memset(result->data, 0, sizeof(*result->data));
// TODO: dtime
result->Unref();
filesystem->FreeInode(result_inode_id);
return NULL;
}
return result;
}
return errno = ENOENT, (Inode*) NULL;
}
bool Inode::Link(const char* elem, Inode* dest, bool directories)
{
// TODO: Check if dest has checked the link limit!
if ( !EXT2_S_ISDIR(Mode()) )
return errno = ENOTDIR, false;
if ( directories && !EXT2_S_ISDIR(dest->Mode()) )
return errno = ENOTDIR, false;
if ( !directories && EXT2_S_ISDIR(dest->Mode()) )
return errno = EISDIR, false;
Modified();
// Search for a hole in which we can store the new directory entry and stop
// if we meet an existing link with the requested name.
size_t elem_length = strlen(elem);
size_t new_entry_size = roundup(sizeof(struct ext_dirent) + elem_length, (size_t) 4);
uint64_t filesize = Size();
uint64_t offset = 0;
Block* block = NULL;
uint64_t block_id = 0;
bool found_hole = false;
bool splitting = false;
uint64_t hole_block_id = 0;
uint64_t hole_block_offset = 0;
while ( offset < filesize )
{
uint64_t entry_block_id = offset / filesystem->block_size;
uint64_t entry_block_offset = offset % filesystem->block_size;
if ( block && block_id != entry_block_id )
block->Unref(),
block = NULL;
if ( !block && !(block = GetBlock(block_id = entry_block_id)) )
return NULL;
const uint8_t* block_data = block->block_data + entry_block_offset;
const struct ext_dirent* entry = (const struct ext_dirent*) block_data;
if ( entry->name_len == elem_length &&
memcmp(elem, entry->name, elem_length) == 0 &&
entry->inode )
{
block->Unref();
return errno = EEXIST, false;
}
if ( !found_hole )
{
size_t entry_size = roundup(sizeof(struct ext_dirent) + entry->name_len, (size_t) 4);
if ( (!entry->name[0] || !entry->inode) && new_entry_size <= entry->reclen )
{
hole_block_id = entry_block_id;
hole_block_offset = entry_block_offset;
new_entry_size = entry->reclen;
found_hole = true;
}
else if ( new_entry_size <= entry->reclen - entry_size )
{
hole_block_id = entry_block_id;
hole_block_offset = entry_block_offset;
new_entry_size = entry->reclen - entry_size;
splitting = true;
found_hole = true;
}
}
offset += entry->reclen;
}
// We'll append another block if we failed to find a suitable hole.
if ( !found_hole )
{
hole_block_id = filesize / filesystem->block_size;
hole_block_offset = filesize % filesystem->block_size;
new_entry_size = filesystem->block_size;
}
if ( block && block_id != hole_block_id )
block->Unref(),
block = NULL;
if ( !block && !(block = GetBlock(block_id = hole_block_id)) )
return NULL;
uint8_t* block_data = block->block_data + hole_block_offset;
struct ext_dirent* entry = (struct ext_dirent*) block_data;
// If we found a directory entry with room at the end, split it!
if ( splitting )
{
entry->reclen = roundup(sizeof(struct ext_dirent) + entry->name_len, (size_t) 4);
assert(entry->reclen);
// Block marked dirty below.
block_data += entry->reclen;
entry = (struct ext_dirent*) block_data;
}
// Write the new directory entry.
entry->inode = dest->inode_id;
entry->reclen = new_entry_size;
entry->name_len = elem_length;
// TODO: Only do this if the filetype feature is on!
entry->file_type = EXT2_FT_OF_MODE(dest->Mode());
strncpy(entry->name, elem, new_entry_size - sizeof(struct ext_dirent));
assert(entry->reclen);
block->Dirty();
dest->Linked();
if ( !found_hole )
SetSize(Size() + filesystem->block_size);
block->Unref();
return true;
}
Inode* Inode::Unlink(const char* elem, bool directories, bool force)
{
if ( !EXT2_S_ISDIR(Mode()) )
return errno = ENOTDIR, (Inode*) NULL;
Modified();
size_t elem_length = strlen(elem);
uint32_t block_size = filesystem->block_size;
uint64_t filesize = Size();
uint64_t num_blocks = divup(filesize, (uint64_t) block_size);
uint64_t offset = 0;
Block* block = NULL;
uint64_t block_id = 0;
struct ext_dirent* last_entry = NULL;
while ( offset < filesize )
{
uint64_t entry_block_id = offset / block_size;
uint64_t entry_block_offset = offset % block_size;
if ( block && block_id != entry_block_id )
last_entry = NULL,
block->Unref(),
block = NULL;
if ( !block && !(block = GetBlock(block_id = entry_block_id)) )
return NULL;
uint8_t* block_data = block->block_data + entry_block_offset;
struct ext_dirent* entry = (struct ext_dirent*) block_data;
assert(entry->reclen);
if ( entry->name_len == elem_length &&
memcmp(elem, entry->name, elem_length) == 0 &&
entry->inode )
{
Inode* inode = filesystem->GetInode(entry->inode);
if ( !force && directories && !EXT2_S_ISDIR(inode->Mode()) )
{
inode->Unref();
block->Unref();
return errno = ENOTDIR, (Inode*) NULL;
}
if ( !force && directories && !inode->IsEmptyDirectory() )
{
inode->Unref();
block->Unref();
return errno = ENOTEMPTY, (Inode*) NULL;
}
if ( !force && !directories && EXT2_S_ISDIR(inode->Mode()) )
{
inode->Unref();
block->Unref();
return errno = EISDIR, (Inode*) NULL;
}
inode->Unlinked();
entry->inode = 0;
entry->name_len = 0;
entry->file_type = 0;
// Merge the current entry with the previous if any.
if ( last_entry )
{
assert(entry->reclen);
last_entry->reclen += entry->reclen;
memset(entry, 0, entry->reclen);
entry = last_entry;
assert(last_entry->reclen);
}
assert(entry->reclen);
strncpy(entry->name + entry->name_len, "",
entry->reclen - sizeof(struct ext_dirent) - entry->name_len);
assert(entry->reclen);
block->Dirty();
// If the entire block is empty, we'll need to remove it.
if ( !entry->name[0] && entry->reclen == block_size )
{
// If this is not the last block, we'll make it. This is faster
// than shifting the entire directory a single block. We don't
// actually copy this block to the end, since we'll truncate it
// regardless.
if ( entry_block_id + 1 != num_blocks )
{
Block* last_block = GetBlock(num_blocks-1);
memcpy(block->block_data, last_block->block_data, block_size);
block->Dirty();
last_block->Unref();
}
Truncate(filesize - block_size);
}
block->Unref();
return inode;
}
offset += entry->reclen;
last_entry = entry;
}
if ( block )
block->Unref();
return errno = ENOENT, (Inode*) NULL;
}
ssize_t Inode::ReadAt(uint8_t* buf, size_t s_count, off_t o_offset)
{
if ( !EXT2_S_ISREG(Mode()) && !EXT2_S_ISLNK(Mode()) )
return errno = EISDIR, -1;
if ( o_offset < 0 )
return errno = EINVAL, -1;
if ( SSIZE_MAX < s_count )
s_count = SSIZE_MAX;
uint64_t sofar = 0;
uint64_t count = (uint64_t) s_count;
uint64_t offset = (uint64_t) o_offset;
uint64_t file_size = Size();
if ( file_size <= offset )
return 0;
if ( file_size - offset < count )
count = file_size - offset;
// TODO: This case also needs to be handled in SetSize, Truncate, WriteAt,
// and so on.
if ( 0 < file_size && file_size <= 60 && !data->i_blocks )
{
assert(count <= 60);
unsigned char* block_data = (unsigned char*) &(data->i_block[0]);
memcpy(buf, block_data + offset, count);
return (ssize_t) count;
}
while ( sofar < count )
{
uint64_t block_id = offset / filesystem->block_size;
uint32_t block_offset = offset % filesystem->block_size;
uint32_t block_left = filesystem->block_size - block_offset;
Block* block = GetBlock(block_id);
if ( !block )
return sofar ? sofar : -1;
size_t amount = count - sofar < block_left ? count - sofar : block_left;
memcpy(buf + sofar, block->block_data + block_offset, amount);
sofar += amount;
offset += amount;
block->Unref();
}
return (ssize_t) sofar;
}
ssize_t Inode::WriteAt(const uint8_t* buf, size_t s_count, off_t o_offset)
{
if ( !EXT2_S_ISREG(Mode()) && !EXT2_S_ISLNK(Mode()) )
return errno = EISDIR, -1;
if ( o_offset < 0 )
return errno = EINVAL, -1;
if ( SSIZE_MAX < s_count )
s_count = SSIZE_MAX;
Modified();
uint64_t sofar = 0;
uint64_t count = (uint64_t) s_count;
uint64_t offset = (uint64_t) o_offset;
uint64_t file_size = Size();
uint64_t end_at = offset + count;
if ( offset < end_at )
/* TODO: Overflow! off_t overflow? */{};
if ( 0 < file_size && file_size <= 60 && !data->i_blocks )
{
fprintf(stderr, "extfs: Writing to optimized symlinks is not implemented!\n");
return errno = EROFS, -1;
}
if ( file_size < end_at )
Truncate(end_at);
while ( sofar < count )
{
uint64_t block_id = offset / filesystem->block_size;
uint32_t block_offset = offset % filesystem->block_size;
uint32_t block_left = filesystem->block_size - block_offset;
Block* block = GetBlock(block_id);
if ( !block )
return sofar ? sofar : -1;
size_t amount = count - sofar < block_left ? count - sofar : block_left;
memcpy(block->block_data + block_offset, buf + sofar, amount);
block->Dirty();
sofar += amount;
offset += amount;
block->Unref();
}
return (ssize_t) sofar;
}
bool Inode::Rename(Inode* olddir, const char* oldname, const char* newname)
{
if ( !strcmp(oldname, ".") || !strcmp(oldname, "..") ||
!strcmp(newname, ".") || !strcmp(newname, "..") )
return errno = EPERM, false;
Inode* src_inode = olddir->Open(oldname, O_RDONLY, 0);
if ( !src_inode )
return false;
if ( Inode* dst_inode = Open(newname, O_RDONLY, 0) )
{
bool same_inode = src_inode->inode_id == dst_inode->inode_id;
dst_inode->Unref();
if ( same_inode )
return src_inode->Unref(), true;
}
// TODO: Prove that this cannot fail and handle such a situation.
if ( EXT2_S_ISDIR(src_inode->Mode()) )
{
if ( !Unlink(newname, true) && errno != ENOENT )
return src_inode->Unref(), false;
Link(newname, src_inode, true);
olddir->Unlink(oldname, true, true);
if ( olddir != this )
{
src_inode->Unlink("..", true, true);
src_inode->Link("..", this, true);
}
}
else
{
if ( !Unlink(newname, false) && errno != ENOENT )
return src_inode->Unref(), false;
Link(newname, src_inode, false);
olddir->Unlink(oldname, false);
}
src_inode->Unref();
return true;
}
bool Inode::Symlink(const char* elem, const char* dest)
{
// TODO: Preferred block group!
uint32_t result_inode_id = filesystem->AllocateInode();
if ( !result_inode_id )
return NULL;
Inode* result = filesystem->GetInode(result_inode_id);
memset(result->data, 0, sizeof(*result->data));
result->SetMode((0777 & S_SETABLE) | EXT2_S_IFLNK);
struct timespec now;
clock_gettime(CLOCK_REALTIME, &now);
result->data->i_atime = now.tv_sec;
result->data->i_ctime = now.tv_sec;
result->data->i_mtime = now.tv_sec;
// TODO: Set all the other inode properties!
if ( result->WriteAt((const uint8_t*) dest, strlen(dest), 0) < 0 )
{
error:
memset(result->data, 0, sizeof(*result->data));
// TODO: dtime
result->Unref();
filesystem->FreeInode(result_inode_id);
return false;
}
if ( !Link(elem, result, false) )
{
result->Truncate(0);
goto error;
}
result->Unref();
return true;
}
Inode* Inode::CreateDirectory(const char* path, mode_t mode)
{
// TODO: Preferred block group!
uint32_t result_inode_id = filesystem->AllocateInode();
if ( !result_inode_id )
return NULL;
Inode* result = filesystem->GetInode(result_inode_id);
memset(result->data, 0, sizeof(*result->data));
result->SetMode((mode & S_SETABLE) | EXT2_S_IFDIR);
// Increase the directory count statistics.
uint32_t group_id = (result->inode_id - 1) / filesystem->sb->s_inodes_per_group;
assert(group_id < filesystem->num_groups);
BlockGroup* block_group = filesystem->GetBlockGroup(group_id);
block_group->data->bg_used_dirs_count++;
block_group->Dirty();
block_group->Unref();
struct timespec now;
clock_gettime(CLOCK_REALTIME, &now);
result->data->i_atime = now.tv_sec;
result->data->i_ctime = now.tv_sec;
result->data->i_mtime = now.tv_sec;
// TODO: Set all the other inode properties!
if ( !Link(path, result, true) )
{
error:
result->Truncate(0);
memset(result->data, 0, sizeof(*result->data));
// TODO: dtime
result->Unref();
filesystem->FreeInode(result_inode_id);
return NULL;
}
if ( !result->Link(".", result, true) )
{
Unlink(path, true);
goto error;
}
if ( !result->Link("..", this, true) )
{
result->Unlink(".", true);
Unlink(path, true);
goto error;
}
return result;
}
bool Inode::RemoveDirectory(const char* path)
{
Inode* result = Unlink(path, true);
if ( !result )
return false;
result->Unlink("..", true);
result->Unlink(".", true);
result->Truncate(0);
// Decrease the directory count statistics.
uint32_t group_id = (result->inode_id - 1) / filesystem->sb->s_inodes_per_group;
assert(group_id < filesystem->num_groups);
BlockGroup* block_group = filesystem->GetBlockGroup(group_id);
block_group->data->bg_used_dirs_count--;
block_group->Dirty();
block_group->Unref();
result->Unref();
return true;
}
bool Inode::IsEmptyDirectory()
{
if ( !EXT2_S_ISDIR(Mode()) )
return errno = ENOTDIR, false;
uint32_t block_size = filesystem->block_size;
uint64_t filesize = Size();
uint64_t offset = 0;
Block* block = NULL;
uint64_t block_id = 0;
while ( offset < filesize )
{
uint64_t entry_block_id = offset / block_size;
uint64_t entry_block_offset = offset % block_size;
if ( block && block_id != entry_block_id )
block->Unref(),
block = NULL;
if ( !block && !(block = GetBlock(block_id = entry_block_id)) )
return false;
uint8_t* block_data = block->block_data + entry_block_offset;
struct ext_dirent* entry = (struct ext_dirent*) block_data;
if ( entry->inode &&
!((entry->name_len == 1 && entry->name[0] == '.') ||
(entry->name_len == 2 && entry->name[0] == '.' &&
entry->name[1] == '.' )) )
{
block->Unref();
return false;
}
offset += entry->reclen;
}
if ( block )
block->Unref();
return true;
}
void Inode::Delete()
{
assert(!data->i_links_count);
assert(!reference_count);
assert(!remote_reference_count);
Truncate(0);
uint32_t deleted_inode_id = inode_id;
memset(data, 0, sizeof(*data));
struct timespec now;
clock_gettime(CLOCK_REALTIME, &now);
data->i_dtime = now.tv_sec;
Dirty();
delete this;
filesystem->FreeInode(deleted_inode_id);
}
void Inode::Refer()
{
reference_count++;
}
void Inode::Unref()
{
reference_count--;
if ( !reference_count && !remote_reference_count )
{
if ( !data->i_links_count )
Delete();
else
delete this;
}
}
void Inode::RemoteRefer()
{
remote_reference_count++;
}
void Inode::RemoteUnref()
{
remote_reference_count--;
if ( !reference_count && !remote_reference_count )
{
if ( !data->i_links_count )
Delete();
else
delete this;
}
}
void Inode::Modified()
{
struct timespec now;
clock_gettime(CLOCK_REALTIME, &now);
data->i_mtime = now.tv_sec;
Dirty();
}
void Inode::Dirty()
{
struct timespec now;
clock_gettime(CLOCK_REALTIME, &now);
data->i_ctime = now.tv_sec;
if ( !dirty )
{
dirty = true;
prev_dirty = NULL;
next_dirty = filesystem->dirty_inode;
if ( next_dirty )
next_dirty->prev_dirty = this;
filesystem->dirty_inode = this;
}
data_block->Dirty();
Use();
}
void Inode::Sync()
{
if ( !dirty )
return;
data_block->Sync();
(prev_dirty ? prev_dirty->next_dirty : filesystem->dirty_inode) = next_dirty;
if ( next_dirty )
next_dirty->prev_dirty = prev_dirty;
prev_dirty = NULL;
next_dirty = NULL;
dirty = false;
}
void Inode::Use()
{
data_block->Use();
Unlink();
Prelink();
}
void Inode::Unlink()
{
(prev_inode ? prev_inode->next_inode : filesystem->mru_inode) = next_inode;
(next_inode ? next_inode->prev_inode : filesystem->lru_inode) = prev_inode;
size_t bin = inode_id % INODE_HASH_LENGTH;
(prev_hashed ? prev_hashed->next_hashed : filesystem->hash_inodes[bin]) = next_hashed;
if ( next_hashed ) next_hashed->prev_hashed = prev_hashed;
}
void Inode::Prelink()
{
prev_inode = NULL;
next_inode = filesystem->mru_inode;
if ( filesystem->mru_inode )
filesystem->mru_inode->prev_inode = this;
filesystem->mru_inode = this;
if ( !filesystem->lru_inode )
filesystem->lru_inode = this;
size_t bin = inode_id % INODE_HASH_LENGTH;
prev_hashed = NULL;
next_hashed = filesystem->hash_inodes[bin];
filesystem->hash_inodes[bin] = this;
if ( next_hashed )
next_hashed->prev_hashed = this;
}