toaruos/modules/ext2.c

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/**
* @file kernel/vfs/ext2.c
* @brief Implementation of the Ext2 filesystem.
*
* @copyright 2014-2021 K. Lange <klange@toaruos.org>
* This file is part of ToaruOS and is released under the terms
* of the NCSA / University of Illinois License - see LICENSE.md
*/
#include <errno.h>
#include <kernel/types.h>
#include <kernel/vfs.h>
#include <kernel/printf.h>
#include <kernel/time.h>
#include <kernel/string.h>
#include <kernel/spinlock.h>
#include <kernel/tokenize.h>
#include <kernel/module.h>
#include <sys/ioctl.h>
#define debug_print(lvl, str, ...) do { if (this->flags & EXT2_FLAG_LOUD) { printf("ext2: %s: " str "\n", #lvl __VA_OPT__(,) __VA_ARGS__); } } while (0)
#define EXT2_SUPER_MAGIC 0xEF53
#define EXT2_DIRECT_BLOCKS 12
/* Super block struct. */
struct ext2_superblock {
uint32_t inodes_count;
uint32_t blocks_count;
uint32_t r_blocks_count;
uint32_t free_blocks_count;
uint32_t free_inodes_count;
uint32_t first_data_block;
uint32_t log_block_size;
uint32_t log_frag_size;
uint32_t blocks_per_group;
uint32_t frags_per_group;
uint32_t inodes_per_group;
uint32_t mtime;
uint32_t wtime;
uint16_t mnt_count;
uint16_t max_mnt_count;
uint16_t magic;
uint16_t state;
uint16_t errors;
uint16_t minor_rev_level;
uint32_t lastcheck;
uint32_t checkinterval;
uint32_t creator_os;
uint32_t rev_level;
uint16_t def_resuid;
uint16_t def_resgid;
/* EXT2_DYNAMIC_REV */
uint32_t first_ino;
uint16_t inode_size;
uint16_t block_group_nr;
uint32_t feature_compat;
uint32_t feature_incompat;
uint32_t feature_ro_compat;
uint8_t uuid[16];
uint8_t volume_name[16];
uint8_t last_mounted[64];
uint32_t algo_bitmap;
/* Performance Hints */
uint8_t prealloc_blocks;
uint8_t prealloc_dir_blocks;
uint16_t _padding;
/* Journaling Support */
uint8_t journal_uuid[16];
uint32_t journal_inum;
uint32_t jounral_dev;
uint32_t last_orphan;
/* Directory Indexing Support */
uint32_t hash_seed[4];
uint8_t def_hash_version;
uint16_t _padding_a;
uint8_t _padding_b;
/* Other Options */
uint32_t default_mount_options;
uint32_t first_meta_bg;
uint8_t _unused[760];
} __attribute__ ((packed));
typedef struct ext2_superblock ext2_superblock_t;
/* Block group descriptor. */
struct ext2_bgdescriptor {
uint32_t block_bitmap;
uint32_t inode_bitmap; // block no. of inode bitmap
uint32_t inode_table;
uint16_t free_blocks_count;
uint16_t free_inodes_count;
uint16_t used_dirs_count;
uint16_t pad;
uint8_t reserved[12];
} __attribute__ ((packed));
typedef struct ext2_bgdescriptor ext2_bgdescriptor_t;
/* File Types */
#define EXT2_S_IFSOCK 0xC000
#define EXT2_S_IFLNK 0xA000
#define EXT2_S_IFREG 0x8000
#define EXT2_S_IFBLK 0x6000
#define EXT2_S_IFDIR 0x4000
#define EXT2_S_IFCHR 0x2000
#define EXT2_S_IFIFO 0x1000
/* setuid, etc. */
#define EXT2_S_ISUID 0x0800
#define EXT2_S_ISGID 0x0400
#define EXT2_S_ISVTX 0x0200
/* rights */
#define EXT2_S_IRUSR 0x0100
#define EXT2_S_IWUSR 0x0080
#define EXT2_S_IXUSR 0x0040
#define EXT2_S_IRGRP 0x0020
#define EXT2_S_IWGRP 0x0010
#define EXT2_S_IXGRP 0x0008
#define EXT2_S_IROTH 0x0004
#define EXT2_S_IWOTH 0x0002
#define EXT2_S_IXOTH 0x0001
/* This is not actually the inode table.
* It represents an inode in an inode table on disk. */
struct ext2_inodetable {
uint16_t mode;
uint16_t uid;
uint32_t size; // file length in byte.
uint32_t atime;
uint32_t ctime;
uint32_t mtime;
uint32_t dtime;
uint16_t gid;
uint16_t links_count;
uint32_t blocks;
uint32_t flags;
uint32_t osd1;
uint32_t block[15];
uint32_t generation;
uint32_t file_acl;
uint32_t dir_acl;
uint32_t faddr;
uint8_t osd2[12];
} __attribute__ ((packed));
typedef struct ext2_inodetable ext2_inodetable_t;
/* Represents directory entry on disk. */
struct ext2_dir {
uint32_t inode;
uint16_t rec_len;
uint8_t name_len;
uint8_t file_type;
char name[]; /* Actually a set of characters, at most 255 bytes */
} __attribute__ ((packed));
typedef struct ext2_dir ext2_dir_t;
#define EXT2_BGD_BLOCK 2
#define E_SUCCESS 0
#define E_BADBLOCK 1
#define E_NOSPACE 2
#define E_BADPARENT 3
#undef _symlink
#define _symlink(inode) ((char *)(inode)->block)
/*
* EXT2 filesystem object
*/
typedef struct {
ext2_superblock_t * superblock; /* Device superblock, contains important information */
ext2_bgdescriptor_t * block_groups; /* Block Group Descriptor / Block groups */
fs_node_t * root_node; /* Root FS node (attached to mountpoint) */
fs_node_t * block_device; /* Block device node XXX unused */
unsigned int block_size; /* Size of one block */
unsigned int pointers_per_block; /* Number of pointers that fit in a block */
unsigned int inodes_per_group; /* Number of inodes in a "group" */
unsigned int block_group_count; /* Number of blocks groups */
uint8_t bgd_block_span;
uint8_t bgd_offset;
unsigned int inode_size;
uint8_t * cache_data;
int flags;
} ext2_fs_t;
#define EXT2_FLAG_READWRITE 0x0002
#define EXT2_FLAG_LOUD 0x0004
/*
* These macros were used in the original toaru ext2 driver.
* They make referring to some of the core parts of the drive a bit easier.
*/
#define BGDS (this->block_group_count)
#define SB (this->superblock)
#define BGD (this->block_groups)
#define RN (this->root_node)
/*
* These macros deal with the block group descriptor bitmap
*/
#define BLOCKBIT(n) (bg_buffer[((n) >> 3)] & (1 << (((n) % 8))))
#define BLOCKBYTE(n) (bg_buffer[((n) >> 3)])
#define SETBIT(n) (1 << (((n) % 8)))
static int node_from_file(ext2_fs_t * this, ext2_inodetable_t *inode, ext2_dir_t *direntry, fs_node_t *fnode);
static int ext2_root(ext2_fs_t * this, ext2_inodetable_t *inode, fs_node_t *fnode);
static ext2_inodetable_t * read_inode(ext2_fs_t * this, size_t inode);
static void refresh_inode(ext2_fs_t * this, ext2_inodetable_t * inodet, size_t inode);
static int write_inode(ext2_fs_t * this, ext2_inodetable_t *inode, size_t index);
static fs_node_t * finddir_ext2(fs_node_t *node, char *name);
static size_t allocate_block(ext2_fs_t * this);
/**
* ext2->rewrite_superblock Rewrite the superblock.
*
* Superblocks are a bit different from other blocks, as they are always in the same place,
* regardless of what the filesystem block size is. This doesn't work well with our setup,
* so we need to special-case it.
*/
static int rewrite_superblock(ext2_fs_t * this) {
write_fs(this->block_device, 1024, sizeof(ext2_superblock_t), (uint8_t *)SB);
return E_SUCCESS;
}
/**
* ext2->read_block Read a block from the block device associated with this filesystem.
*
* The read block will be copied into the buffer pointed to by `buf`.
*
* @param block_no Number of block to read.
* @param buf Where to put the data read.
* @returns Error code or E_SUCCESS
*/
static int read_block(ext2_fs_t * this, unsigned int block_no, uint8_t * buf) {
/* 0 is an invalid block number. So is anything beyond the total block count, but we can't check that. */
if (!block_no) {
return E_BADBLOCK;
}
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/* In such cases, we read directly from the block device */
read_fs(this->block_device, block_no * this->block_size, this->block_size, (uint8_t *)buf);
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/* And return SUCCESS */
return E_SUCCESS;
}
/**
* ext2->write_block Write a block to the block device.
*
* @param block_no Block to write
* @param buf Data in the block
* @returns Error code or E_SUCCESSS
*/
static int write_block(ext2_fs_t * this, unsigned int block_no, uint8_t *buf) {
if (!block_no) {
debug_print(ERROR, "Attempted to write to block #0. Enable tracing and retry this operation.");
debug_print(ERROR, "Your file system is most likely corrupted now.");
return E_BADBLOCK;
}
/* This operation requires the filesystem lock */
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write_fs(this->block_device, block_no * this->block_size, this->block_size, buf);
/* We're done. */
return E_SUCCESS;
}
/**
* ext2->set_block_number Set the "real" block number for a given "inode" block number.
*
* @param inode Inode to operate on
* @param iblock Block offset within the inode
* @param rblock Real block number
* @returns Error code or E_SUCCESS
*/
static unsigned int set_block_number(ext2_fs_t * this, ext2_inodetable_t * inode, unsigned int inode_no, unsigned int iblock, unsigned int rblock) {
unsigned int p = this->pointers_per_block;
/* We're going to do some crazy math in a bit... */
unsigned int a, b, c, d, e, f, g;
uint8_t * tmp;
if (iblock < EXT2_DIRECT_BLOCKS) {
inode->block[iblock] = rblock;
return E_SUCCESS;
} else if (iblock < EXT2_DIRECT_BLOCKS + p) {
/* XXX what if inode->block[EXT2_DIRECT_BLOCKS] isn't set? */
if (!inode->block[EXT2_DIRECT_BLOCKS]) {
unsigned int block_no = allocate_block(this);
if (!block_no) return E_NOSPACE;
inode->block[EXT2_DIRECT_BLOCKS] = block_no;
write_inode(this, inode, inode_no);
}
tmp = malloc(this->block_size);
read_block(this, inode->block[EXT2_DIRECT_BLOCKS], (uint8_t *)tmp);
((uint32_t *)tmp)[iblock - EXT2_DIRECT_BLOCKS] = rblock;
write_block(this, inode->block[EXT2_DIRECT_BLOCKS], (uint8_t *)tmp);
free(tmp);
return E_SUCCESS;
} else if (iblock < EXT2_DIRECT_BLOCKS + p + p * p) {
a = iblock - EXT2_DIRECT_BLOCKS;
b = a - p;
c = b / p;
d = b - c * p;
if (!inode->block[EXT2_DIRECT_BLOCKS+1]) {
unsigned int block_no = allocate_block(this);
if (!block_no) return E_NOSPACE;
inode->block[EXT2_DIRECT_BLOCKS+1] = block_no;
write_inode(this, inode, inode_no);
}
tmp = malloc(this->block_size);
read_block(this, inode->block[EXT2_DIRECT_BLOCKS + 1], (uint8_t *)tmp);
if (!((uint32_t *)tmp)[c]) {
unsigned int block_no = allocate_block(this);
if (!block_no) goto no_space_free;
((uint32_t *)tmp)[c] = block_no;
write_block(this, inode->block[EXT2_DIRECT_BLOCKS + 1], (uint8_t *)tmp);
}
uint32_t nblock = ((uint32_t *)tmp)[c];
read_block(this, nblock, (uint8_t *)tmp);
((uint32_t *)tmp)[d] = rblock;
write_block(this, nblock, (uint8_t *)tmp);
free(tmp);
return E_SUCCESS;
} else if (iblock < EXT2_DIRECT_BLOCKS + p + p * p + p) {
a = iblock - EXT2_DIRECT_BLOCKS;
b = a - p;
c = b - p * p;
d = c / (p * p);
e = c - d * p * p;
f = e / p;
g = e - f * p;
if (!inode->block[EXT2_DIRECT_BLOCKS+2]) {
unsigned int block_no = allocate_block(this);
if (!block_no) return E_NOSPACE;
inode->block[EXT2_DIRECT_BLOCKS+2] = block_no;
write_inode(this, inode, inode_no);
}
tmp = malloc(this->block_size);
read_block(this, inode->block[EXT2_DIRECT_BLOCKS + 2], (uint8_t *)tmp);
if (!((uint32_t *)tmp)[d]) {
unsigned int block_no = allocate_block(this);
if (!block_no) goto no_space_free;
((uint32_t *)tmp)[d] = block_no;
write_block(this, inode->block[EXT2_DIRECT_BLOCKS + 2], (uint8_t *)tmp);
}
uint32_t nblock = ((uint32_t *)tmp)[d];
read_block(this, nblock, (uint8_t *)tmp);
if (!((uint32_t *)tmp)[f]) {
unsigned int block_no = allocate_block(this);
if (!block_no) goto no_space_free;
((uint32_t *)tmp)[f] = block_no;
write_block(this, nblock, (uint8_t *)tmp);
}
nblock = ((uint32_t *)tmp)[f];
read_block(this, nblock, (uint8_t *)tmp);
((uint32_t *)tmp)[g] = nblock;
write_block(this, nblock, (uint8_t *)tmp);
free(tmp);
return E_SUCCESS;
}
debug_print(CRITICAL, "EXT2 driver tried to write to a block number that was too high (%d)", rblock);
return E_BADBLOCK;
no_space_free:
free(tmp);
return E_NOSPACE;
}
/**
* ext2->get_block_number Given an inode block number, get the real block number.
*
* @param inode Inode to operate on
* @param iblock Block offset within the inode
* @returns Real block number
*/
static unsigned int get_block_number(ext2_fs_t * this, ext2_inodetable_t * inode, unsigned int iblock) {
unsigned int p = this->pointers_per_block;
/* We're going to do some crazy math in a bit... */
unsigned int a, b, c, d, e, f, g;
uint8_t * tmp;
if (iblock < EXT2_DIRECT_BLOCKS) {
return inode->block[iblock];
} else if (iblock < EXT2_DIRECT_BLOCKS + p) {
/* XXX what if inode->block[EXT2_DIRECT_BLOCKS] isn't set? */
tmp = malloc(this->block_size);
read_block(this, inode->block[EXT2_DIRECT_BLOCKS], (uint8_t *)tmp);
unsigned int out = ((uint32_t *)tmp)[iblock - EXT2_DIRECT_BLOCKS];
free(tmp);
return out;
} else if (iblock < EXT2_DIRECT_BLOCKS + p + p * p) {
a = iblock - EXT2_DIRECT_BLOCKS;
b = a - p;
c = b / p;
d = b - c * p;
tmp = malloc(this->block_size);
read_block(this, inode->block[EXT2_DIRECT_BLOCKS + 1], (uint8_t *)tmp);
uint32_t nblock = ((uint32_t *)tmp)[c];
read_block(this, nblock, (uint8_t *)tmp);
unsigned int out = ((uint32_t *)tmp)[d];
free(tmp);
return out;
} else if (iblock < EXT2_DIRECT_BLOCKS + p + p * p + p) {
a = iblock - EXT2_DIRECT_BLOCKS;
b = a - p;
c = b - p * p;
d = c / (p * p);
e = c - d * p * p;
f = e / p;
g = e - f * p;
tmp = malloc(this->block_size);
read_block(this, inode->block[EXT2_DIRECT_BLOCKS + 2], (uint8_t *)tmp);
uint32_t nblock = ((uint32_t *)tmp)[d];
read_block(this, nblock, (uint8_t *)tmp);
nblock = ((uint32_t *)tmp)[f];
read_block(this, nblock, (uint8_t *)tmp);
unsigned int out = ((uint32_t *)tmp)[g];
free(tmp);
return out;
}
debug_print(CRITICAL, "EXT2 driver tried to read to a block number that was too high (%d)", iblock);
return 0;
}
static int write_inode(ext2_fs_t * this, ext2_inodetable_t *inode, size_t index) {
size_t group = index / this->inodes_per_group;
if (group > BGDS) {
return E_BADBLOCK;
}
size_t inode_table_block = BGD[group].inode_table;
index -= group * this->inodes_per_group;
size_t block_offset = ((index - 1) * this->inode_size) / this->block_size;
size_t offset_in_block = (index - 1) - block_offset * (this->block_size / this->inode_size);
ext2_inodetable_t *inodet = malloc(this->block_size);
/* Read the current table block */
read_block(this, inode_table_block + block_offset, (uint8_t *)inodet);
memcpy((uint8_t *)((uintptr_t)inodet + offset_in_block * this->inode_size), inode, this->inode_size);
write_block(this, inode_table_block + block_offset, (uint8_t *)inodet);
free(inodet);
return E_SUCCESS;
}
static size_t allocate_block(ext2_fs_t * this) {
size_t block_no = 0;
size_t block_offset = 0;
size_t group = 0;
uint8_t * bg_buffer = malloc(this->block_size);
for (unsigned int i = 0; i < BGDS; ++i) {
if (BGD[i].free_blocks_count > 0) {
read_block(this, BGD[i].block_bitmap, (uint8_t *)bg_buffer);
while (BLOCKBIT(block_offset)) {
++block_offset;
}
block_no = block_offset + SB->blocks_per_group * i;
group = i;
break;
}
}
if (!block_no) {
debug_print(CRITICAL, "No available blocks, disk is out of space!");
free(bg_buffer);
return 0;
}
debug_print(WARNING, "allocating block #%zu (group %zu)", block_no, group);
BLOCKBYTE(block_offset) |= SETBIT(block_offset);
write_block(this, BGD[group].block_bitmap, (uint8_t *)bg_buffer);
BGD[group].free_blocks_count--;
for (int i = 0; i < this->bgd_block_span; ++i) {
write_block(this, this->bgd_offset + i, (uint8_t *)((uintptr_t)BGD + this->block_size * i));
}
SB->free_blocks_count--;
rewrite_superblock(this);
memset(bg_buffer, 0x00, this->block_size);
write_block(this, block_no, bg_buffer);
free(bg_buffer);
return block_no;
}
/**
* ext2->allocate_inode_block Allocate a block in an inode.
*
* @param inode Inode to operate on
* @param inode_no Number of the inode (this is not part of the struct)
* @param block Block within inode to allocate
* @returns Error code or E_SUCCESS
*/
static int allocate_inode_block(ext2_fs_t * this, ext2_inodetable_t * inode, unsigned int inode_no, unsigned int block) {
debug_print(NOTICE, "Allocating block #%d for inode #%d", block, inode_no);
unsigned int block_no = allocate_block(this);
if (!block_no) return E_NOSPACE;
set_block_number(this, inode, inode_no, block, block_no);
unsigned int t = (block + 1) * (this->block_size / 512);
if (inode->blocks < t) {
debug_print(NOTICE, "Setting inode->blocks to %d = (%d fs blocks)", t, t / (this->block_size / 512));
inode->blocks = t;
}
write_inode(this, inode, inode_no);
return E_SUCCESS;
}
/**
* ext2->inode_read_block
*
* @param inode
* @param no
* @param block
* @parma buf
* @returns Real block number for reference.
*/
static unsigned int inode_read_block(ext2_fs_t * this, ext2_inodetable_t * inode, unsigned int block, uint8_t * buf) {
if (block >= inode->blocks / (this->block_size / 512)) {
memset(buf, 0x00, this->block_size);
debug_print(WARNING, "Tried to read an invalid block. Asked for %d (0-indexed), but inode only has %d!", block, inode->blocks / (this->block_size / 512));
return 0;
}
unsigned int real_block = get_block_number(this, inode, block);
read_block(this, real_block, buf);
return real_block;
}
/**
* ext2->inode_write_block
*/
static unsigned int inode_write_block(ext2_fs_t * this, ext2_inodetable_t * inode, unsigned int inode_no, unsigned int block, uint8_t * buf) {
if (block >= inode->blocks / (this->block_size / 512)) {
debug_print(WARNING, "Attempting to write beyond the existing allocated blocks for this inode.");
debug_print(WARNING, "Inode %d, Block %d", inode_no, block);
}
debug_print(WARNING, "clearing and allocating up to required blocks (block=%d, %d)", block, inode->blocks);
char * empty = NULL;
while (block >= inode->blocks / (this->block_size / 512)) {
allocate_inode_block(this, inode, inode_no, inode->blocks / (this->block_size / 512));
refresh_inode(this, inode, inode_no);
}
if (empty) free(empty);
debug_print(WARNING, "... done");
unsigned int real_block = get_block_number(this, inode, block);
debug_print(WARNING, "Writing virtual block %d for inode %d maps to real block %d", block, inode_no, real_block);
write_block(this, real_block, buf);
return real_block;
}
/**
* ext2->create_entry
*
* @returns Error code or E_SUCCESS
*/
static int create_entry(fs_node_t * parent, char * name, uint32_t inode) {
ext2_fs_t * this = (ext2_fs_t *)parent->device;
ext2_inodetable_t * pinode = read_inode(this,parent->inode);
if (((pinode->mode & EXT2_S_IFDIR) == 0) || (name == NULL)) {
debug_print(WARNING, "Attempted to allocate an inode in a parent that was not a directory.");
return E_BADPARENT;
}
debug_print(WARNING, "Creating a directory entry for %s pointing to inode %d.", name, inode);
/* okay, how big is it... */
debug_print(WARNING, "We need to append %zd bytes to the direcotry.", sizeof(ext2_dir_t) + strlen(name));
unsigned int rec_len = sizeof(ext2_dir_t) + strlen(name);
rec_len += (rec_len % 4) ? (4 - (rec_len % 4)) : 0;
debug_print(WARNING, "Our directory entry looks like this:");
debug_print(WARNING, " inode = %d", inode);
debug_print(WARNING, " rec_len = %d", rec_len);
debug_print(WARNING, " name_len = %zd", strlen(name));
debug_print(WARNING, " file_type = %d", 0);
debug_print(WARNING, " name = %s", name);
debug_print(WARNING, "The inode size is marked as: %d", pinode->size);
debug_print(WARNING, "Block size is %d", this->block_size);
uint8_t * block = malloc(this->block_size);
uint8_t block_nr = 0;
uint32_t dir_offset = 0;
uint32_t total_offset = 0;
int modify_or_replace = 0;
ext2_dir_t *previous;
inode_read_block(this, pinode, block_nr, block);
while (total_offset < pinode->size) {
if (dir_offset >= this->block_size) {
block_nr++;
dir_offset -= this->block_size;
inode_read_block(this, pinode, block_nr, block);
}
ext2_dir_t *d_ent = (ext2_dir_t *)((uintptr_t)block + dir_offset);
unsigned int sreclen = d_ent->name_len + sizeof(ext2_dir_t);
sreclen += (sreclen % 4) ? (4 - (sreclen % 4)) : 0;
{
char f[d_ent->name_len+1];
memcpy(f, d_ent->name, d_ent->name_len);
f[d_ent->name_len] = 0;
debug_print(WARNING, " * file: %s", f);
}
debug_print(WARNING, " rec_len: %d", d_ent->rec_len);
debug_print(WARNING, " type: %d", d_ent->file_type);
debug_print(WARNING, " namel: %d", d_ent->name_len);
debug_print(WARNING, " inode: %d", d_ent->inode);
if (d_ent->rec_len != sreclen && total_offset + d_ent->rec_len == pinode->size) {
debug_print(WARNING, " - should be %d, but instead points to end of block", sreclen);
debug_print(WARNING, " - we've hit the end, should change this pointer");
dir_offset += sreclen;
total_offset += sreclen;
modify_or_replace = 1; /* Modify */
previous = d_ent;
break;
}
if (d_ent->inode == 0) {
modify_or_replace = 2; /* Replace */
}
dir_offset += d_ent->rec_len;
total_offset += d_ent->rec_len;
}
if (!modify_or_replace) {
debug_print(WARNING, "That's odd, this shouldn't have happened, we made it all the way here without hitting our two end conditions?");
}
if (modify_or_replace == 1) {
debug_print(WARNING, "The last node in the list is a real node, we need to modify it.");
if (dir_offset + rec_len >= this->block_size) {
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block_nr++;
allocate_inode_block(this, pinode, parent->inode, block_nr);
memset(block, 0, this->block_size);
dir_offset = 0;
pinode->size += this->block_size;
write_inode(this, pinode, parent->inode);
} else {
unsigned int sreclen = previous->name_len + sizeof(ext2_dir_t);
sreclen += (sreclen % 4) ? (4 - (sreclen % 4)) : 0;
previous->rec_len = sreclen;
debug_print(WARNING, "Set previous node rec_len to %d", sreclen);
}
} else if (modify_or_replace == 2) {
debug_print(WARNING, "The last node in the list is a fake node, we'll replace it.");
}
debug_print(WARNING, " total_offset = 0x%x", total_offset);
debug_print(WARNING, " dir_offset = 0x%x", dir_offset);
ext2_dir_t *d_ent = (ext2_dir_t *)((uintptr_t)block + dir_offset);
d_ent->inode = inode;
d_ent->rec_len = this->block_size - dir_offset;
d_ent->name_len = strlen(name);
d_ent->file_type = 0; /* This is unused */
memcpy(d_ent->name, name, strlen(name));
inode_write_block(this, pinode, parent->inode, block_nr, block);
free(block);
free(pinode);
return E_NOSPACE;
}
static unsigned int allocate_inode(ext2_fs_t * this) {
uint32_t node_no = 0;
uint32_t node_offset = 0;
uint32_t group = 0;
uint8_t * bg_buffer = malloc(this->block_size);
for (unsigned int i = 0; i < BGDS; ++i) {
if (BGD[i].free_inodes_count > 0) {
debug_print(NOTICE, "Group %d has %d free inodes.", i, BGD[i].free_inodes_count);
read_block(this, BGD[i].inode_bitmap, (uint8_t *)bg_buffer);
while (BLOCKBIT(node_offset)) {
node_offset++;
}
node_no = node_offset + i * this->inodes_per_group + 1;
group = i;
break;
}
}
if (!node_no) {
debug_print(ERROR, "Ran out of inodes!");
return 0;
}
BLOCKBYTE(node_offset) |= SETBIT(node_offset);
write_block(this, BGD[group].inode_bitmap, (uint8_t *)bg_buffer);
free(bg_buffer);
BGD[group].free_inodes_count--;
for (int i = 0; i < this->bgd_block_span; ++i) {
write_block(this, this->bgd_offset + i, (uint8_t *)((uintptr_t)BGD + this->block_size * i));
}
SB->free_inodes_count--;
rewrite_superblock(this);
return node_no;
}
static int mkdir_ext2(fs_node_t * parent, char * name, mode_t permission) {
if (!name) return -EINVAL;
ext2_fs_t * this = parent->device;
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if (!(this->flags & EXT2_FLAG_READWRITE)) return -EROFS;
/* first off, check if it exists */
fs_node_t * check = finddir_ext2(parent, name);
if (check) {
debug_print(WARNING, "A file by this name already exists: %s", name);
free(check);
return -EEXIST;
}
/* Allocate an inode for it */
unsigned int inode_no = allocate_inode(this);
ext2_inodetable_t * inode = read_inode(this,inode_no);
/* Set the access and creation times to now */
inode->atime = now();
inode->ctime = inode->atime;
inode->mtime = inode->atime;
inode->dtime = 0; /* This inode was never deleted */
/* Empty the file */
memset(inode->block, 0x00, sizeof(inode->block));
inode->blocks = 0;
inode->size = 0; /* empty */
/* Assign it to root */
inode->uid = this_core->current_process->user;
inode->gid = this_core->current_process->user_group;
/* misc */
inode->faddr = 0;
inode->links_count = 2; /* There's the parent's pointer to us, and our pointer to us. */
inode->flags = 0;
inode->osd1 = 0;
inode->generation = 0;
inode->file_acl = 0;
inode->dir_acl = 0;
/* File mode */
inode->mode = EXT2_S_IFDIR;
inode->mode |= 0xFFF & permission;
/* Write the osd blocks to 0 */
memset(inode->osd2, 0x00, sizeof(inode->osd2));
/* Write out inode changes */
write_inode(this, inode, inode_no);
/* Now append the entry to the parent */
create_entry(parent, name, inode_no);
inode->size = this->block_size;
write_inode(this, inode, inode_no);
uint8_t * tmp = malloc(this->block_size);
ext2_dir_t * t = malloc(12);
memset(t, 0, 12);
t->inode = inode_no;
t->rec_len = 12;
t->name_len = 1;
t->name[0] = '.';
memcpy(&tmp[0], t, 12);
t->inode = parent->inode;
t->name_len = 2;
t->name[1] = '.';
t->rec_len = this->block_size - 12;
memcpy(&tmp[12], t, 12);
free(t);
inode_write_block(this, inode, inode_no, 0, tmp);
free(inode);
free(tmp);
/* Update parent link count */
ext2_inodetable_t * pinode = read_inode(this, parent->inode);
pinode->links_count++;
write_inode(this, pinode, parent->inode);
free(pinode);
/* Update directory count in block group descriptor */
uint32_t group = inode_no / this->inodes_per_group;
BGD[group].used_dirs_count++;
for (int i = 0; i < this->bgd_block_span; ++i) {
write_block(this, this->bgd_offset + i, (uint8_t *)((uintptr_t)BGD + this->block_size * i));
}
return 0;
}
static int create_ext2(fs_node_t * parent, char * name, mode_t permission) {
if (!name) return -EINVAL;
ext2_fs_t * this = parent->device;
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if (!(this->flags & EXT2_FLAG_READWRITE)) return -EROFS;
/* first off, check if it exists */
fs_node_t * check = finddir_ext2(parent, name);
if (check) {
debug_print(WARNING, "A file by this name already exists: %s", name);
free(check);
return -EEXIST;
}
/* Allocate an inode for it */
unsigned int inode_no = allocate_inode(this);
ext2_inodetable_t * inode = read_inode(this,inode_no);
/* Set the access and creation times to now */
inode->atime = now();
inode->ctime = inode->atime;
inode->mtime = inode->atime;
inode->dtime = 0; /* This inode was never deleted */
/* Empty the file */
memset(inode->block, 0x00, sizeof(inode->block));
inode->blocks = 0;
inode->size = 0; /* empty */
inode->uid = this_core->current_process->user;
inode->gid = this_core->current_process->user_group;
/* misc */
inode->faddr = 0;
inode->links_count = 1; /* The one we're about to create. */
inode->flags = 0;
inode->osd1 = 0;
inode->generation = 0;
inode->file_acl = 0;
inode->dir_acl = 0;
/* File mode */
/* TODO: Use the mask from `permission` */
inode->mode = EXT2_S_IFREG;
inode->mode |= 0xFFF & permission;
/* Write the osd blocks to 0 */
memset(inode->osd2, 0x00, sizeof(inode->osd2));
/* Write out inode changes */
write_inode(this, inode, inode_no);
/* Now append the entry to the parent */
create_entry(parent, name, inode_no);
free(inode);
return 0;
}
static int chmod_ext2(fs_node_t * node, mode_t mode) {
ext2_fs_t * this = node->device;
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if (!(this->flags & EXT2_FLAG_READWRITE)) return -EROFS;
ext2_inodetable_t * inode = read_inode(this,node->inode);
inode->mode = (inode->mode & 0xFFFFF000) | mode;
write_inode(this, inode, node->inode);
return 0;
}
/**
* direntry_ext2
*/
static ext2_dir_t * direntry_ext2(ext2_fs_t * this, ext2_inodetable_t * inode, uint32_t no, uint32_t index) {
uint8_t *block = malloc(this->block_size);
uint8_t block_nr = 0;
inode_read_block(this, inode, block_nr, block);
uint32_t dir_offset = 0;
uint32_t total_offset = 0;
uint32_t dir_index = 0;
while (total_offset < inode->size && dir_index <= index) {
ext2_dir_t *d_ent = (ext2_dir_t *)((uintptr_t)block + dir_offset);
if (d_ent->inode != 0 && dir_index == index) {
ext2_dir_t *out = malloc(d_ent->rec_len);
memcpy(out, d_ent, d_ent->rec_len);
free(block);
return out;
}
dir_offset += d_ent->rec_len;
total_offset += d_ent->rec_len;
if (d_ent->inode) {
dir_index++;
}
if (dir_offset >= this->block_size) {
block_nr++;
dir_offset -= this->block_size;
inode_read_block(this, inode, block_nr, block);
}
}
free(block);
return NULL;
}
/**
* finddir_ext2
*/
static fs_node_t * finddir_ext2(fs_node_t *node, char *name) {
ext2_fs_t * this = (ext2_fs_t *)node->device;
ext2_inodetable_t *inode = read_inode(this,node->inode);
//assert(inode->mode & EXT2_S_IFDIR);
uint8_t * block = malloc(this->block_size);
ext2_dir_t *direntry = NULL;
uint8_t block_nr = 0;
inode_read_block(this, inode, block_nr, block);
uint32_t dir_offset = 0;
uint32_t total_offset = 0;
while (total_offset < inode->size) {
if (dir_offset >= this->block_size) {
block_nr++;
dir_offset -= this->block_size;
inode_read_block(this, inode, block_nr, block);
}
ext2_dir_t *d_ent = (ext2_dir_t *)((uintptr_t)block + dir_offset);
if (d_ent->inode == 0 || strlen(name) != d_ent->name_len) {
dir_offset += d_ent->rec_len;
total_offset += d_ent->rec_len;
continue;
}
char *dname = malloc(sizeof(char) * (d_ent->name_len + 1));
memcpy(dname, &(d_ent->name), d_ent->name_len);
dname[d_ent->name_len] = '\0';
if (!strcmp(dname, name)) {
free(dname);
direntry = malloc(d_ent->rec_len);
memcpy(direntry, d_ent, d_ent->rec_len);
break;
}
free(dname);
dir_offset += d_ent->rec_len;
total_offset += d_ent->rec_len;
}
free(inode);
if (!direntry) {
free(block);
return NULL;
}
fs_node_t *outnode = malloc(sizeof(fs_node_t));
memset(outnode, 0, sizeof(fs_node_t));
inode = read_inode(this, direntry->inode);
if (!node_from_file(this, inode, direntry, outnode)) {
debug_print(CRITICAL, "Oh dear. Couldn't allocate the outnode?");
}
free(direntry);
free(inode);
free(block);
return outnode;
}
static int unlink_ext2(fs_node_t * node, char * name) {
/* XXX this is a very bad implementation */
ext2_fs_t * this = (ext2_fs_t *)node->device;
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if (!(this->flags & EXT2_FLAG_READWRITE)) return -EROFS;
ext2_inodetable_t *inode = read_inode(this,node->inode);
//assert(inode->mode & EXT2_S_IFDIR);
uint8_t * block = malloc(this->block_size);
ext2_dir_t *direntry = NULL;
uint8_t block_nr = 0;
inode_read_block(this, inode, block_nr, block);
uint32_t dir_offset = 0;
uint32_t total_offset = 0;
while (total_offset < inode->size) {
if (dir_offset >= this->block_size) {
block_nr++;
dir_offset -= this->block_size;
inode_read_block(this, inode, block_nr, block);
}
ext2_dir_t *d_ent = (ext2_dir_t *)((uintptr_t)block + dir_offset);
if (d_ent->inode == 0 || strlen(name) != d_ent->name_len) {
dir_offset += d_ent->rec_len;
total_offset += d_ent->rec_len;
continue;
}
char *dname = malloc(sizeof(char) * (d_ent->name_len + 1));
memcpy(dname, &(d_ent->name), d_ent->name_len);
dname[d_ent->name_len] = '\0';
if (!strcmp(dname, name)) {
free(dname);
direntry = d_ent;
break;
}
free(dname);
dir_offset += d_ent->rec_len;
total_offset += d_ent->rec_len;
}
free(inode);
if (!direntry) {
free(block);
return -ENOENT;
}
direntry->inode = 0;
inode_write_block(this, inode, node->inode, block_nr, block);
free(block);
return 0;
}
static void refresh_inode(ext2_fs_t * this, ext2_inodetable_t * inodet, size_t inode) {
uint32_t group = inode / this->inodes_per_group;
if (group > BGDS) {
return;
}
uint32_t inode_table_block = BGD[group].inode_table;
inode -= group * this->inodes_per_group; // adjust index within group
uint32_t block_offset = ((inode - 1) * this->inode_size) / this->block_size;
uint32_t offset_in_block = (inode - 1) - block_offset * (this->block_size / this->inode_size);
uint8_t * buf = malloc(this->block_size);
read_block(this, inode_table_block + block_offset, buf);
ext2_inodetable_t *inodes = (ext2_inodetable_t *)buf;
memcpy(inodet, (uint8_t *)((uintptr_t)inodes + offset_in_block * this->inode_size), this->inode_size);
free(buf);
}
/**
* read_inode
*/
static ext2_inodetable_t * read_inode(ext2_fs_t * this, size_t inode) {
ext2_inodetable_t *inodet = malloc(this->inode_size);
refresh_inode(this, inodet, inode);
return inodet;
}
static ssize_t read_ext2(fs_node_t *node, off_t offset, size_t size, uint8_t *buffer) {
ext2_fs_t * this = (ext2_fs_t *)node->device;
ext2_inodetable_t * inode = read_inode(this, node->inode);
uint32_t end;
if (inode->size == 0) return 0;
if (offset + size > inode->size) {
end = inode->size;
} else {
end = offset + size;
}
uint32_t start_block = offset / this->block_size;
uint32_t end_block = end / this->block_size;
uint32_t end_size = end - end_block * this->block_size;
uint32_t size_to_read = end - offset;
uint8_t * buf = malloc(this->block_size);
if (start_block == end_block) {
inode_read_block(this, inode, start_block, buf);
memcpy(buffer, (uint8_t *)(((uintptr_t)buf) + ((uintptr_t)offset % this->block_size)), size_to_read);
} else {
uint32_t block_offset;
uint32_t blocks_read = 0;
for (block_offset = start_block; block_offset < end_block; block_offset++, blocks_read++) {
if (block_offset == start_block) {
inode_read_block(this, inode, block_offset, buf);
memcpy(buffer, (uint8_t *)(((uintptr_t)buf) + ((uintptr_t)offset % this->block_size)), this->block_size - (offset % this->block_size));
} else {
inode_read_block(this, inode, block_offset, buf);
memcpy(buffer + this->block_size * blocks_read - (offset % this->block_size), buf, this->block_size);
}
}
if (end_size) {
inode_read_block(this, inode, end_block, buf);
memcpy(buffer + this->block_size * blocks_read - (offset % this->block_size), buf, end_size);
}
}
free(inode);
free(buf);
return size_to_read;
}
static ssize_t write_inode_buffer(ext2_fs_t * this, ext2_inodetable_t * inode, uint32_t inode_number, off_t offset, size_t size, uint8_t *buffer) {
uint32_t end = offset + size;
if (end > inode->size) {
inode->size = end;
write_inode(this, inode, inode_number);
}
uint32_t start_block = offset / this->block_size;
uint32_t end_block = end / this->block_size;
uint32_t end_size = end - end_block * this->block_size;
uint32_t size_to_read = end - offset;
uint8_t * buf = malloc(this->block_size);
if (start_block == end_block) {
inode_read_block(this, inode, start_block, buf);
memcpy((uint8_t *)(((uintptr_t)buf) + ((uintptr_t)offset % this->block_size)), buffer, size_to_read);
inode_write_block(this, inode, inode_number, start_block, buf);
} else {
uint32_t block_offset;
uint32_t blocks_read = 0;
for (block_offset = start_block; block_offset < end_block; block_offset++, blocks_read++) {
if (block_offset == start_block) {
int b = inode_read_block(this, inode, block_offset, buf);
memcpy((uint8_t *)(((uintptr_t)buf) + ((uintptr_t)offset % this->block_size)), buffer, this->block_size - (offset % this->block_size));
inode_write_block(this, inode, inode_number, block_offset, buf);
if (!b) {
refresh_inode(this, inode, inode_number);
}
} else {
int b = inode_read_block(this, inode, block_offset, buf);
memcpy(buf, buffer + this->block_size * blocks_read - (offset % this->block_size), this->block_size);
inode_write_block(this, inode, inode_number, block_offset, buf);
if (!b) {
refresh_inode(this, inode, inode_number);
}
}
}
if (end_size) {
inode_read_block(this, inode, end_block, buf);
memcpy(buf, buffer + this->block_size * blocks_read - (offset % this->block_size), end_size);
inode_write_block(this, inode, inode_number, end_block, buf);
}
}
free(buf);
return size_to_read;
}
static ssize_t write_ext2(fs_node_t *node, off_t offset, size_t size, uint8_t *buffer) {
ext2_fs_t * this = (ext2_fs_t *)node->device;
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if (!(this->flags & EXT2_FLAG_READWRITE)) return -EROFS;
ext2_inodetable_t * inode = read_inode(this, node->inode);
ssize_t rv = write_inode_buffer(this, inode, node->inode, offset, size, buffer);
free(inode);
return rv;
}
static int truncate_ext2(fs_node_t * node) {
ext2_fs_t * this = node->device;
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if (!(this->flags & EXT2_FLAG_READWRITE)) return -EROFS;
ext2_inodetable_t * inode = read_inode(this,node->inode);
inode->size = 0;
write_inode(this, inode, node->inode);
return 0;
}
static void open_ext2(fs_node_t *node, unsigned int flags) {
/* Nothing to do here */
}
static void close_ext2(fs_node_t *node) {
/* Nothing to do here */
}
/**
* readdir_ext2
*/
static struct dirent * readdir_ext2(fs_node_t *node, unsigned long index) {
ext2_fs_t * this = (ext2_fs_t *)node->device;
ext2_inodetable_t *inode = read_inode(this, node->inode);
//assert(inode->mode & EXT2_S_IFDIR);
ext2_dir_t *direntry = direntry_ext2(this, inode, node->inode, index);
if (!direntry) {
free(inode);
return NULL;
}
struct dirent *dirent = malloc(sizeof(struct dirent));
memcpy(&dirent->d_name, &direntry->name, direntry->name_len);
dirent->d_name[direntry->name_len] = '\0';
dirent->d_ino = direntry->inode;
free(direntry);
free(inode);
return dirent;
}
static int symlink_ext2(fs_node_t * parent, char * target, char * name) {
if (!name) return -EINVAL;
ext2_fs_t * this = parent->device;
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if (!(this->flags & EXT2_FLAG_READWRITE)) return -EROFS;
/* first off, check if it exists */
fs_node_t * check = finddir_ext2(parent, name);
if (check) {
debug_print(WARNING, "A file by this name already exists: %s", name);
free(check);
return -EEXIST; /* this should probably have a return value... */
}
/* Allocate an inode for it */
unsigned int inode_no = allocate_inode(this);
ext2_inodetable_t * inode = read_inode(this,inode_no);
/* Set the access and creation times to now */
inode->atime = now();
inode->ctime = inode->atime;
inode->mtime = inode->atime;
inode->dtime = 0; /* This inode was never deleted */
/* Empty the file */
memset(inode->block, 0x00, sizeof(inode->block));
inode->blocks = 0;
inode->size = 0; /* empty */
/* Assign it to current user */
inode->uid = this_core->current_process->user;
inode->gid = this_core->current_process->user_group;
/* misc */
inode->faddr = 0;
inode->links_count = 1; /* The one we're about to create. */
inode->flags = 0;
inode->osd1 = 0;
inode->generation = 0;
inode->file_acl = 0;
inode->dir_acl = 0;
inode->mode = EXT2_S_IFLNK;
/* I *think* this is what you're supposed to do with symlinks */
inode->mode |= 0777;
/* Write the osd blocks to 0 */
memset(inode->osd2, 0x00, sizeof(inode->osd2));
size_t target_len = strlen(target);
int embedded = target_len <= 60; // sizeof(_symlink(inode));
if (embedded) {
memcpy(_symlink(inode), target, target_len);
inode->size = target_len;
}
/* Write out inode changes */
write_inode(this, inode, inode_no);
/* Now append the entry to the parent */
create_entry(parent, name, inode_no);
/* If we didn't embed it in the inode just use write_inode_buffer to finish the job */
if (!embedded) {
write_inode_buffer(parent->device, inode, inode_no, 0, target_len, (uint8_t *)target);
}
free(inode);
return 0;
}
static ssize_t readlink_ext2(fs_node_t * node, char * buf, size_t size) {
ext2_fs_t * this = (ext2_fs_t *)node->device;
ext2_inodetable_t * inode = read_inode(this, node->inode);
size_t read_size = inode->size < size ? inode->size : size;
if (inode->size > 60) { //sizeof(_symlink(inode))) {
read_ext2(node, 0, read_size, (uint8_t *)buf);
} else {
memcpy(buf, _symlink(inode), read_size);
}
/* Believe it or not, we actually aren't supposed to include the nul in the length. */
if (read_size < size) {
buf[read_size] = '\0';
}
free(inode);
return read_size;
}
static int ioctl_ext2(fs_node_t * node, unsigned long request, void * argp) {
ext2_fs_t * this = (ext2_fs_t *)node->device;
switch (request) {
case IOCTLSYNC:
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return ioctl_fs(this->block_device, IOCTLSYNC, NULL);
default:
return -EINVAL;
}
}
static int node_from_file(ext2_fs_t * this, ext2_inodetable_t *inode, ext2_dir_t *direntry, fs_node_t *fnode) {
if (!fnode) {
/* You didn't give me a node to write into, go **** yourself */
return 0;
}
/* Information from the direntry */
fnode->device = (void *)this;
fnode->inode = direntry->inode;
memcpy(&fnode->name, &direntry->name, direntry->name_len);
fnode->name[direntry->name_len] = '\0';
/* Information from the inode */
fnode->uid = inode->uid;
fnode->gid = inode->gid;
fnode->length = inode->size;
fnode->mask = inode->mode & 0xFFF;
fnode->nlink = inode->links_count;
/* File Flags */
fnode->flags = 0;
if ((inode->mode & EXT2_S_IFREG) == EXT2_S_IFREG) {
fnode->flags |= FS_FILE;
fnode->read = read_ext2;
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fnode->write = write_ext2;
fnode->truncate = truncate_ext2;
fnode->create = NULL;
fnode->mkdir = NULL;
fnode->readdir = NULL;
fnode->finddir = NULL;
fnode->symlink = NULL;
fnode->readlink = NULL;
}
if ((inode->mode & EXT2_S_IFDIR) == EXT2_S_IFDIR) {
fnode->flags |= FS_DIRECTORY;
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fnode->create = create_ext2;
fnode->mkdir = mkdir_ext2;
fnode->unlink = unlink_ext2;
fnode->symlink = symlink_ext2;
fnode->readdir = readdir_ext2;
fnode->finddir = finddir_ext2;
fnode->write = NULL;
fnode->readlink = NULL;
}
if ((inode->mode & EXT2_S_IFBLK) == EXT2_S_IFBLK) {
fnode->flags |= FS_BLOCKDEVICE;
}
if ((inode->mode & EXT2_S_IFCHR) == EXT2_S_IFCHR) {
fnode->flags |= FS_CHARDEVICE;
}
if ((inode->mode & EXT2_S_IFIFO) == EXT2_S_IFIFO) {
fnode->flags |= FS_PIPE;
}
if ((inode->mode & EXT2_S_IFLNK) == EXT2_S_IFLNK) {
fnode->flags |= FS_SYMLINK;
fnode->read = NULL;
fnode->write = NULL;
fnode->create = NULL;
fnode->mkdir = NULL;
fnode->readdir = NULL;
fnode->finddir = NULL;
fnode->readlink = readlink_ext2;
}
fnode->atime = inode->atime;
fnode->mtime = inode->mtime;
fnode->ctime = inode->ctime;
2021-09-07 13:00:16 +03:00
fnode->chmod = chmod_ext2;
fnode->open = open_ext2;
fnode->close = close_ext2;
fnode->ioctl = ioctl_ext2;
return 1;
}
static int ext2_root(ext2_fs_t * this, ext2_inodetable_t *inode, fs_node_t *fnode) {
if (!fnode) {
return 0;
}
/* Information for root dir */
fnode->device = (void *)this;
fnode->inode = 2;
fnode->name[0] = '/';
fnode->name[1] = '\0';
/* Information from the inode */
fnode->uid = inode->uid;
fnode->gid = inode->gid;
fnode->length = inode->size;
fnode->mask = inode->mode & 0xFFF;
fnode->nlink = inode->links_count;
/* File Flags */
fnode->flags = 0;
if ((inode->mode & EXT2_S_IFREG) == EXT2_S_IFREG) {
debug_print(CRITICAL, "Root appears to be a regular file.");
debug_print(CRITICAL, "This is probably very, very wrong.");
return 0;
}
if ((inode->mode & EXT2_S_IFDIR) == EXT2_S_IFDIR) {
} else {
debug_print(CRITICAL, "Root doesn't appear to be a directory.");
debug_print(CRITICAL, "This is probably very, very wrong.");
debug_print(ERROR, "Other useful information:");
debug_print(ERROR, "%d", inode->uid);
debug_print(ERROR, "%d", inode->gid);
debug_print(ERROR, "%d", inode->size);
debug_print(ERROR, "%d", inode->mode);
debug_print(ERROR, "%d", inode->links_count);
return 0;
}
if ((inode->mode & EXT2_S_IFBLK) == EXT2_S_IFBLK) {
fnode->flags |= FS_BLOCKDEVICE;
}
if ((inode->mode & EXT2_S_IFCHR) == EXT2_S_IFCHR) {
fnode->flags |= FS_CHARDEVICE;
}
if ((inode->mode & EXT2_S_IFIFO) == EXT2_S_IFIFO) {
fnode->flags |= FS_PIPE;
}
if ((inode->mode & EXT2_S_IFLNK) == EXT2_S_IFLNK) {
fnode->flags |= FS_SYMLINK;
}
fnode->atime = inode->atime;
fnode->mtime = inode->mtime;
fnode->ctime = inode->ctime;
fnode->flags |= FS_DIRECTORY;
fnode->read = NULL;
fnode->write = NULL;
fnode->chmod = chmod_ext2;
fnode->open = open_ext2;
fnode->close = close_ext2;
fnode->readdir = readdir_ext2;
fnode->finddir = finddir_ext2;
fnode->ioctl = NULL;
fnode->create = create_ext2;
fnode->mkdir = mkdir_ext2;
fnode->unlink = unlink_ext2;
return 1;
}
static fs_node_t * mount_ext2(fs_node_t * block_device, int flags) {
ext2_fs_t * this = malloc(sizeof(ext2_fs_t));
memset(this, 0x00, sizeof(ext2_fs_t));
this->flags = flags;
this->block_device = block_device;
this->block_size = 1024;
/* We need to keep an owned refcount to this device if it was something we opened... */
//vfs_lock(this->block_device);
SB = malloc(this->block_size);
debug_print(INFO, "Reading superblock...");
read_block(this, 1, (uint8_t *)SB);
if (SB->magic != EXT2_SUPER_MAGIC) {
debug_print(ERROR, "... not an EXT2 filesystem? (magic didn't match, got 0x%x)", SB->magic);
return NULL;
}
this->inode_size = SB->inode_size;
if (SB->inode_size == 0) {
this->inode_size = 128;
}
this->block_size = 1024 << SB->log_block_size;
this->pointers_per_block = this->block_size / 4;
debug_print(INFO, "Log block size = %d -> %d", SB->log_block_size, this->block_size);
BGDS = SB->blocks_count / SB->blocks_per_group;
if (SB->blocks_per_group * BGDS < SB->blocks_count) {
BGDS += 1;
}
this->inodes_per_group = SB->inodes_count / BGDS;
// load the block group descriptors
this->bgd_block_span = sizeof(ext2_bgdescriptor_t) * BGDS / this->block_size + 1;
BGD = malloc(this->block_size * this->bgd_block_span);
debug_print(INFO, "bgd_block_span = %d", this->bgd_block_span);
this->bgd_offset = 2;
if (this->block_size > 1024) {
this->bgd_offset = 1;
}
for (int i = 0; i < this->bgd_block_span; ++i) {
read_block(this, this->bgd_offset + i, (uint8_t *)((uintptr_t)BGD + this->block_size * i));
}
#if 1 // DEBUG_BLOCK_DESCRIPTORS
char * bg_buffer = malloc(this->block_size * sizeof(char));
for (uint32_t i = 0; i < BGDS; ++i) {
debug_print(INFO, "Block Group Descriptor #%d @ %d", i, this->bgd_offset + i * SB->blocks_per_group);
debug_print(INFO, "\tBlock Bitmap @ %d", BGD[i].block_bitmap); {
debug_print(INFO, "\t\tExamining block bitmap at %d", BGD[i].block_bitmap);
read_block(this, BGD[i].block_bitmap, (uint8_t *)bg_buffer);
uint32_t j = 0;
while (BLOCKBIT(j)) {
++j;
}
debug_print(INFO, "\t\tFirst free block in group is %d", j + BGD[i].block_bitmap - 2);
}
debug_print(INFO, "\tInode Bitmap @ %d", BGD[i].inode_bitmap); {
debug_print(INFO, "\t\tExamining inode bitmap at %d", BGD[i].inode_bitmap);
read_block(this, BGD[i].inode_bitmap, (uint8_t *)bg_buffer);
uint32_t j = 0;
while (BLOCKBIT(j)) {
++j;
}
debug_print(INFO, "\t\tFirst free inode in group is %d", j + this->inodes_per_group * i + 1);
}
debug_print(INFO, "\tInode Table @ %d", BGD[i].inode_table);
debug_print(INFO, "\tFree Blocks = %d", BGD[i].free_blocks_count);
debug_print(INFO, "\tFree Inodes = %d", BGD[i].free_inodes_count);
}
free(bg_buffer);
#endif
ext2_inodetable_t *root_inode = read_inode(this, 2);
RN = (fs_node_t *)malloc(sizeof(fs_node_t));
if (!ext2_root(this, root_inode, RN)) {
return NULL;
}
debug_print(NOTICE, "Mounted EXT2 disk, root VFS node is at %#zx", (uintptr_t)RN);
return RN;
}
fs_node_t * ext2_fs_mount(const char * device, const char * mount_path) {
char * arg = strdup(device);
char * argv[10];
int argc = tokenize(arg, ",", argv);
fs_node_t * dev = kopen(argv[0], 0);
if (!dev) {
return NULL;
}
int flags = 0;
for (int i = 1; i < argc; ++i) {
if (!strcmp(argv[i],"rw")) {
flags |= EXT2_FLAG_READWRITE;
}
if (!strcmp(argv[i],"verbose")) {
flags |= EXT2_FLAG_LOUD;
}
}
return mount_ext2(dev, flags);
}
static int init(int argc, char * argv[]) {
vfs_register("ext2", ext2_fs_mount);
return 0;
}
static int fini(void) {
return 0;
}
struct Module metadata = {
.name = "ext2",
.init = init,
.fini = fini,
};