src/kernel/dri/fs/ext2/ext2.c - bluejay - Git - code.swisschili.sh

 #include <alloc.h>
 #include <dri/ata_pio/ata_pio.h>
 #include <dri/fs/ext2/ext2.h>
 #include <dri/fs/ext2/ext2_vfs.h>
 #include <vfs.h>
 #include <io.h>
 #include <kint.h>
 #include <log.h>

 #define F(f,t) [EXT2_S_##f >> 12] = EXT2_FT_##t,
 const uchar ext2_s_to_ft[] =
 {
 	0,
 	F(IFSOCK, SOCK)
 	F(IFLINK, SYMLINK)
 	F(IFREG, REGULAR_FILE)
 	F(IFBLK, BLKDEV)
 	F(IFDIR, DIR)
 	F(IFCHR, CHRDEV)
 	F(IFIFO, FIFO)
 };
 #undef F

 void ext2_read_block(struct ext2_superblock *sb, void *buffer, uint block)
 {
 	uint block_size = ext2_block_size(sb) / 512;
 	uint block_start = block_size * block;

 	ata_pio_read_sectors(buffer, block_start, block_size);
 }

 void ext2_write_block(struct ext2_superblock *sb, void *buffer, uint block)
 {
 	uint block_size = ext2_block_size(sb) / 512;
 	uint block_start = block_size * block;

 	ata_pio_write_sectors(block_start, block_size, buffer);
 }

 struct ext2_superblock ext2_read_superblock()
 {
 	uchar buffer[512 * 2];
 	ata_pio_read_sectors(buffer, 2, 2);

 	struct ext2_superblock *sb = (void *)(buffer);
 	return *sb;
 }

 uint ext2_num_block_groups(struct ext2_superblock *sb)
 {
 	// This is a mildly janky way of rounding up
 	uint a = IDIV_CEIL(sb->total_blocks, sb->blocks_per_block_group);
 	uint b = IDIV_CEIL(sb->total_inodes, sb->inodes_per_block_group);

 	if (a == b)
 	{
 		return a;
 	}
 	else
 	{
 		kprintf(ERROR "EXT2 cannot find number of block groups, %d and %d "
 					  "should equal.\n",
 				a, b);
 		kpanic("Corrupted filesystem");
 	}
 }

 void ext2_write_bgd(struct ext2_superblock *sb, uint block_group,
 					struct ext2_block_group_descriptor *d)
 {
 	ext2_load_or_write_bgd(sb, block_group, d, true);
 }

 struct ext2_block_group_descriptor ext2_load_bgd(
 	struct ext2_superblock *sb, uint block_group)
 {
 	struct ext2_block_group_descriptor bgd;
 	ext2_load_or_write_bgd(sb, block_group, &bgd, false);

 	return bgd;
 }

 void ext2_load_or_write_bgd(struct ext2_superblock *sb,
 							uint block_group,
 							struct ext2_block_group_descriptor *d,
 							bool set)
 {
 	/**
 	 * The BGDT (not to be confused with the GDT) is located the block after the
 	 * superblock. On any block size EXCEPT 1024 (the minimum, remember that the
 	 * block size is specified by X where 1024 << X is the real size) this is
 	 * the second block (0-indexed, so 1). On 1024 this is the third block.
 	 */
 	uint bgdt_block = 1;
 	uint block_size = ext2_block_size(sb);

 	if (block_size == 1024)
 		bgdt_block = 2;

 	const uint bgd_size = sizeof(struct ext2_block_group_descriptor);

 	// Disk page that the BGD is on relative to the initial FILE SYSTEM block
 	uint hd_page = block_group / (512 / bgd_size);
 	// The offset from the beginning of that page the BGD is at
 	uint bgd_offset = block_group % (512 / bgd_size);

 	struct ext2_block_group_descriptor descriptors[512 / bgd_size];
 	kassert(sizeof(descriptors) == 512, "Wrong BGD size");

 	uint lba = (block_size / 512) * bgdt_block + hd_page;

 	ata_pio_read_sectors(descriptors, lba, 1);

 	if (set)
 	{
 		descriptors[bgd_offset] = *d;
 		ata_pio_write_sectors(lba, 1, (ushort *)descriptors);
 	}
 	else
 	{
 		*d = descriptors[bgd_offset];
 	}
 }

 static bool print_entry(uint inode, const char *name, uint l, void *sb)
 {
 	kprintf("%d\t %s\n", inode, name);

 	return true;

 	struct ext2_inode in;

 	if (ext2_find_inode(sb, inode, &in))
 	{
 		if ((in.mode & EXT2_F_TYPE) == EXT2_S_IFREG)
 		{
 			char buffer[65];
 			uint read = ext2_read_inode(sb, &in, buffer, 64);
 			buffer[read] = 0;

 			kprintf("contents: %d\n'%s'\n", read, buffer);
 		}
 	}

 	return true;
 }

 void ext2_mount(struct fs_node *where)
 {

 	struct ext2_superblock *sb = malloc(sizeof(struct ext2_superblock));
 	*sb = ext2_read_superblock();

 	struct fs_node *ext2_root = ext2_inode2vfs(sb, 2, "/", 1);
 	uint err;

 	if ((err = fs_mount(where, ext2_root)))
 	{
 		kprintf(WARN "Failed to mount EXT2: error %d\n", err);
 	}
 }

 bool ext2_valid_filesystem()
 {
 	struct ext2_superblock sb = ext2_read_superblock();

 	kprintf(DEBUG "superblock signature is %d (0x%x)\n", sb.signature,
 			sb.signature);

 	return sb.signature == EXT2_SIGNATURE;
 }

 void ext2_write_superblock(struct ext2_superblock *sb)
 {
 	ushort *wp = (ushort *)sb;

 	ata_pio_write_sectors(2, 2, wp);
 }

 void ext2_corrupt_superblock_for_fun()
 {
 	struct ext2_superblock sb = ext2_read_superblock();
 	sb.signature = 0xDEAD;
 	ext2_write_superblock(&sb);
 }

 bool ext2_get_or_set_inode(struct ext2_superblock *sb, uint number,
 						   struct ext2_inode *inode, bool set)
 {
 	if (number == 0)
 		return false;

 	uint block_group = (number - 1) / sb->inodes_per_block_group;
 	uint local_index = (number - 1) % sb->inodes_per_block_group;

 	// Load this from the block group descriptor table
 	struct ext2_block_group_descriptor descriptor =
 		ext2_load_bgd(sb, block_group);

 	// We need to figure out what FS block the inode is on, we know how many
 	// inodes there are total in this BGD and the number per page, so this is
 	// simple.

 	const uint block_size = ext2_block_size(sb);

 	const uint inodes_per_block =
 		block_size / sizeof(struct ext2_inode);

 	uint inode_block = local_index / inodes_per_block;
 	uint inode_index = local_index % inodes_per_block;

 	struct ext2_inode inodes[block_size / sizeof(struct ext2_inode)];

 	const uint fs_block = descriptor.inode_table_start_block +
 		inode_block;

 	ext2_read_block(sb, inodes, fs_block);

 	if (set)
 	{
 		inodes[inode_index] = *inode;

 		ext2_write_block(sb, inodes, fs_block);
 	}
 	else
 	{
 		*inode = inodes[inode_index];
 	}

 	return true;
 }

 bool ext2_find_inode(struct ext2_superblock *sb, uint number,
 					 struct ext2_inode *inode)
 {
 	return ext2_get_or_set_inode(sb, number, inode, false);
 }

 bool ext2_set_inode(struct ext2_superblock *sb, uint number,
 					struct ext2_inode *inode)
 {
 	return ext2_get_or_set_inode(sb, number, inode, true);
 }

 bool ext2_dir_ls(struct ext2_superblock *sb, struct ext2_inode *dir,
 				 bool (*cb)(uint inode, const char *name, uint name_len,
 							void *data),
 				 void *data)
 {
 	if ((dir->mode & 0xf000) != EXT2_S_IFDIR)
 		return false;

 	for (uint i = 0; i < dir->num_blocks; i++)
 	{
 		uchar buffer[ext2_block_size(sb)];
 		ext2_read_inode_block(sb, dir, buffer, i);

 		struct ext2_dirent *ent = (void *)buffer;

 		// While there are files in this block
 		while ((uint)ent < (uint)(buffer + ext2_block_size(sb)))
 		{
 			if (ent->inode == 0)
 				return true;

 			if (cb)
 			{
 				char name[256];
 				uint name_len = MIN(ent->name_len, 255);

 				memcpy(name, ent->name, name_len);
 				name[name_len] = '\0';

 				if (!cb(ent->inode, name, name_len, data))
 					return true;
 			}

 			ent = (void *)(((uint)(void *)ent) + ent->rec_len);
 		}
 		// We ran out of files in this block, continue to the next one. This
 		// works because files cannot span blocks
 	}

 	return true;
 }

 static void ext2_show_dirent(struct ext2_dirent *ent)
 {
 	char name[ent->name_len + 1];
 	memcpy(name, ent->name, ent->name_len);
 	name[ent->name_len] = '\0';

 	kprintf(DEBUG "<ent ft=%p, i=%d, s=%s, l=%d>\n", ent->file_type, ent->inode,
 			ent->name, ent->rec_len);
 }

 bool ext2_hard_link(struct ext2_superblock *sb, struct ext2_inode *dir,
                     char *name, uint name_len, uint inode)
 {
 	struct ext2_inode in;

 	if (!ext2_dir_contains(sb, dir, name, name_len) &&
 		ext2_find_inode(sb, inode, &in))
 	{
 		if ((dir->mode & 0xf000) != EXT2_S_IFDIR)
 		{
 			return false;
 		}

 		// Increment the reference count to this inode
 		in.links_count++;
 		ext2_set_inode(sb, inode, &in);

 		// Insert it into the directory
 		uchar type = EXT2_S_TO_FT(in.mode);
 		ext2_insert_into_dir(sb, dir, name, name_len, inode, type);

 		return true;
 	}
 	else
 	{
 		return false;
 	}
 }

 void ext2_insert_into_dir(struct ext2_superblock *sb, struct ext2_inode *dir,
 						  char *name, uint name_len, uint inode, uchar type)
 {
 	name_len = MIN(name_len, 255);
 	const uint min_size = PAD(name_len + sizeof(struct ext2_dirent));
 	const uint block_size = ext2_block_size(sb);

 	if ((dir->mode & 0xf000) != EXT2_S_IFDIR)
 		return;

 	uchar buffer[block_size];
 	uint i; // block #

 	for (i = 0; i < dir->num_blocks; i++)
 	{
 		ext2_read_inode_block(sb, dir, buffer, i);

 		struct ext2_dirent *ent = (void *)buffer;

 		// While there are files in this block
 		while ((uint)ent < (uint)(buffer + block_size))
 		{
 			// kprintf(" %d@%db,%d-%d", ent->inode, i, (uint)ent - (uint)buffer,
 			// 		ent->rec_len);
 			if (ent->inode == 0)
 			{
 				// This is the last item, just insert it at the end
 				// TODO: check this actually fits!
 				// TODO: if we are in a new block, actually create it!

 				ent->rec_len = min_size;
 				ent->name_len = name_len;
 				memcpy(ent->name, name, name_len);
 				ent->inode = inode;
 				ent->file_type = type;

 				kprintf(DEBUG
 						"Inserted into dir (appending) at block=%d, b=%p \n",
 						i, (uint)ent - (uint)buffer);

 				goto finish;
 			}

 			uint this_min_size =
 				PAD(ent->name_len + sizeof(struct ext2_dirent));
 			uint available_size = ent->rec_len - this_min_size;

 			// kprintf(",%d=%d/%d", ent->name_len, this_min_size,
 			// available_size);

 			if (available_size >= min_size)
 			{
 				// We can fit this in here
 				struct ext2_dirent *inserting =
 					(void *)(((uint)(void *)ent) + this_min_size);

 				ent->rec_len = this_min_size;

 				inserting->rec_len = available_size;
 				inserting->name_len = name_len;
 				inserting->inode = inode;
 				inserting->file_type = type;
 				memcpy(inserting->name, name, name_len);

 				kprintf(DEBUG
 						"Inserted into dir (splicing) at block=%d, b=%p \n",
 						i, (uint)inserting - (uint)buffer);

 				// Done!
 				goto finish;
 			}

 			ent = (void *)(((uint)(void *)ent) + ent->rec_len);
 		}
 		// We ran out of files in this block, continue to the next one. This
 		// works because files cannot span blocks
 	}

 	kprintf("\n");

 	kprintf(WARN "Failed to insert!\n");

 finish:
 	kprintf("\n");
 	ext2_write_inode_block(sb, dir, buffer, i);
 	kprintf(DEBUG "[insert] writing inode block %d\n", i);
 }

 ssize_t ext2_read_inode(struct ext2_superblock *sb, struct ext2_inode *inode,
 						void *buffer, ssize_t size)
 {
 	const uint block_size = ext2_block_size(sb);
 	char transfer[block_size];

 	uint fsize = MIN(inode->size, (uint)size);
 	uint i;

 	// Transfer full blocks straight to the output buffer
 	for (i = 0; i < fsize / block_size; i++)
 	{
 		ext2_read_inode_block(sb, inode, buffer + i * block_size, i);
 	}

 	// If we have part of a block left over read it here first, then transfer
 	// what we need
 	if (i * block_size < fsize)
 	{
 		uint remainder = fsize % block_size;

 		ext2_read_inode_block(sb, inode, transfer, i);
 		memcpy(buffer + i * block_size, transfer, remainder);
 	}

 	return fsize;
 }

 static uint ext2_compute_absolute_block(struct ext2_superblock *sb,
 										struct ext2_inode *inode, uint block)
 {
 	if (block >= 12)
 	{
 		kprintf(ERROR
 				"Sorry, EXT2 can only access the first 12 (direct) blocks "
 				"of an inode for now. Indirect look-up will be added later\n");
 		kpanic("Invalid inode block");
 	}

 	return block;
 }

 bool ext2_read_inode_block(struct ext2_superblock *sb, struct ext2_inode *inode,
 						   void *buffer, uint block)
 {
 	block = ext2_compute_absolute_block(sb, inode, block);
 	uint block_address = inode->blocks[block];

 	ext2_read_block(sb, buffer, block_address);

 	return true;
 }

 bool ext2_write_inode_block(struct ext2_superblock *sb, struct ext2_inode *dir,
 							void *buffer, uint block)
 {
 	block = ext2_compute_absolute_block(sb, dir, block);
 	uint block_address = dir->blocks[block];

 	kprintf(DEBUG "Writing size=%d, inode block %p, b=%d\n",
 			ext2_block_size(sb), block_address * ext2_block_size(sb), block);

 	ext2_write_block(sb, buffer, block_address);

 	return true;
 }

 static uint ext2_bitmap_block(struct ext2_superblock *sb,
 							  uint *bitmap_block, uint *index)
 {
 	const uint block_size = ext2_block_size(sb);

 	while (*index > block_size)
 	{
 		*index -= block_size;
 		*bitmap_block += 1;
 	}

 	return block_size;
 }

 bool ext2_check_in_bitmap(struct ext2_superblock *sb, uint bitmap_block,
 						  uint index)
 {
 	const uint block_size = ext2_bitmap_block(sb, &bitmap_block, &index);

 	uint byte = index / 8;
 	uint bit = index % 8;

 	uchar buffer[block_size];

 	ext2_read_block(sb, buffer, bitmap_block);

 	return !!(buffer[byte] & (1 << bit));
 }

 void ext2_set_in_bitmap(struct ext2_superblock *sb, uint bitmap_block,
 						uint index, bool value)
 {
 	const uint block_size = ext2_bitmap_block(sb, &bitmap_block, &index);

 	uint byte = index / 8;
 	uint bit = index % 8;

 	uchar buffer[block_size];

 	ext2_read_block(sb, buffer, bitmap_block);

 	uchar target_bit = 1 << bit;
 	buffer[byte] =
 		value ? (buffer[byte] | target_bit) : (buffer[byte] | ~target_bit);

 	ext2_write_block(sb, buffer, bitmap_block);
 }

 uint ext2_first_zero_bit(struct ext2_superblock *sb, uint bitmap_block,
 						 uint num_blocks, uint start_at)
 {
 	uint block_size = ext2_block_size(sb);

 	for (uint block = bitmap_block; block < bitmap_block + num_blocks; block++)
 	{
 		// dword-array for performance
 		uint buffer[block_size / 4];

 		ext2_read_block(sb, buffer, block);

 		// If this is the first block start at start_at, otherwise 0
 		for (uint i = 0; i < block_size / 4; i++)
 		{
 			// The bitwise negative will be non-zero if there are zero bits in
 			// the original.
 			if (~buffer[i])
 			{
 				// 4 bytes * 8 bits * i dwords
 				uint index =
 					(4 * 8 * i) + (block - bitmap_block) * 8 * block_size;

 				// __builtin_ffs gives us 1+the index of the least-significant 1
 				// bit. Since we take the bitwise inverse this is actuall the
 				// least significant 0 bit. This is a GCC intrinsic. This works
 				// particularly well on little-endian systems where the least
 				// significant bit happens to also correspond to the first bit
 				// in the dword bitset.
 				//
 				// ________ ________ ________ ________
 				//        ^ this is the LSB   ^
 				//                            | this is the MSB
 				//
 				// This means that the LSB is also the first bit in the bitset.
 				uint trailing = __builtin_ffs(~buffer[i]) - 1;

 				return trailing + index;
 			}
 		}
 	}

 	return -1;
 }

 uint ext2_first_free_inode(struct ext2_superblock *sb)
 {
 	uint num_block_groups = ext2_num_block_groups(sb);

 	kprintf(INFO "%d block groups\n", num_block_groups);

 	for (uint bg_num = 0; bg_num < num_block_groups; bg_num++)
 	{
 		struct ext2_block_group_descriptor bgd =
 			ext2_load_bgd(sb, 0);

 		const uint block_size = ext2_block_size(sb);
 		// + 1 because we need to round up (ie 1025 for 1024 size blocks will
 		// yield 1, should 2)
 		uint bitset_blocks = (sb->inodes_per_block_group / 8) / block_size + 1;

 		// inodes start at 1
 		uint inode =
 			ext2_first_zero_bit(sb, bgd.inode_bitmap, bitset_blocks, 12) + 1;
 		// This will overflow back to zero if no inode was found

 		if (inode)
 			return inode;
 	}

 	return 0;
 }

 // ^
 // | this and | this are awfully similar, should refactor
 //            v

 uint ext2_first_free_block(struct ext2_superblock *sb)
 {
 	uint num_block_groups = ext2_num_block_groups(sb);

 	for (uint bg_num = 0; bg_num < num_block_groups; bg_num++)
 	{
 		struct ext2_block_group_descriptor bgd =
 			ext2_load_bgd(sb, 0);

 		const uint block_size = ext2_block_size(sb);
 		// + 1 because we need to round up (ie 1025 for 1024 size blocks will
 		// yield 1, should 2)
 		uint bitset_blocks = (sb->blocks_per_block_group / 8) / block_size + 1;

 		// inodes start at 1
 		uint block_no =
 			ext2_first_zero_bit(sb, bgd.block_bitmap, bitset_blocks, 0);
 		// This will overflow back to zero if no inode was found

 		if (block_no != 0xffffffff)
 			return block_no;
 	}

 	return 0;
 }

 struct ext2_dir_contains_data
 {
 	char *name;
 	uint len;
 	bool found;
 };

 static bool ext2_dir_contains_cb(uint inode, const char *name,
 								uint name_len,
 								struct ext2_dir_contains_data *d)
 {
 	if (strncmp((char *)name, d->name, MIN(name_len, d->len)) == 0)
 	{
 		d->found = true;
 		return false;
 	}

 	return true;
 }

 bool ext2_dir_contains(struct ext2_superblock *sb, struct ext2_inode *dir,
 					   char *name, uint len)
 {
 	if ((dir->mode & EXT2_F_TYPE) != EXT2_S_IFDIR)
 	{
 		return false;
 	}

 	struct ext2_dir_contains_data d =
 		{
 			.name = name,
 			.len = len,
 			.found = false,
 		};

 	ext2_dir_ls(sb, dir, ext2_dir_contains_cb, &d);

 	return d.found;
 }

 struct ext2_dir_find_data
 {
 	char *name;
 	uint len;
 	uint inode;
 };

 bool ext2_dir_find_cb(uint inode, const char *name, uint len,
 					  struct ext2_dir_find_data *d)
 {
 	if (strncmp((char *)name, d->name, MIN(len, d->len)) == 0)
 	{
 		d->inode = inode;
 		return false;
 	}

 	return true;
 }

 uint ext2_dir_find(struct ext2_superblock *sb, struct ext2_inode *dir,
 				   char *name, uint name_len)
 {
 	if ((dir->mode & EXT2_F_TYPE) != EXT2_S_IFDIR)
 	{
 		return false;
 	}

 	struct ext2_dir_find_data d =
 		{
 			.name = name,
 			.len = name_len,
 			.inode = 0,
 		};

 	ext2_dir_ls(sb, dir, ext2_dir_find_cb, &d);

 	return d.inode;
 }

 uint ext2_alloc_new_block(struct ext2_superblock *sb,
 						  uint block_group)
 {
 	struct ext2_block_group_descriptor bgd =
 		ext2_load_bgd(sb, block_group);

 	if (bgd.unallocated_blocks == 0)
 		// TODO: handle out of blocks
 		return ext2_alloc_new_block(sb, block_group + 1);

 	// We can safely pass ~0 here as long as the FS is well formed
 	// because we know there is at least 1 free block
 	uint block = ext2_first_zero_bit(sb, bgd.block_bitmap, ~0, 0);

 	ext2_set_in_bitmap(sb, bgd.block_bitmap, block, true);
 	bgd.unallocated_blocks--;

 	ext2_write_bgd(sb, block_group, &bgd);

 	return block;
 }
	#include <alloc.h>
	#include <dri/ata_pio/ata_pio.h>
	#include <dri/fs/ext2/ext2.h>
	#include <dri/fs/ext2/ext2_vfs.h>
	#include <vfs.h>
	#include <io.h>
	#include <kint.h>
	#include <log.h>

	#define F(f,t) [EXT2_S_##f >> 12] = EXT2_FT_##t,
	const uchar ext2_s_to_ft[] =
	{
	0,
	F(IFSOCK, SOCK)
	F(IFLINK, SYMLINK)
	F(IFREG, REGULAR_FILE)
	F(IFBLK, BLKDEV)
	F(IFDIR, DIR)
	F(IFCHR, CHRDEV)
	F(IFIFO, FIFO)
	};
	#undef F

	void ext2_read_block(struct ext2_superblock sb, void buffer, uint block)
	{
	uint block_size = ext2_block_size(sb) / 512;
	uint block_start = block_size * block;

	ata_pio_read_sectors(buffer, block_start, block_size);
	}

	void ext2_write_block(struct ext2_superblock sb, void buffer, uint block)
	{
	uint block_size = ext2_block_size(sb) / 512;
	uint block_start = block_size * block;

	ata_pio_write_sectors(block_start, block_size, buffer);
	}

	struct ext2_superblock ext2_read_superblock()
	{
	uchar buffer[512 * 2];
	ata_pio_read_sectors(buffer, 2, 2);

	struct ext2_superblock sb = (void )(buffer);
	return *sb;
	}

	uint ext2_num_block_groups(struct ext2_superblock *sb)
	{
	// This is a mildly janky way of rounding up
	uint a = IDIV_CEIL(sb->total_blocks, sb->blocks_per_block_group);
	uint b = IDIV_CEIL(sb->total_inodes, sb->inodes_per_block_group);

	if (a == b)
	{
	return a;
	}
	else
	{
	kprintf(ERROR "EXT2 cannot find number of block groups, %d and %d "
	"should equal.\n",
	a, b);
	kpanic("Corrupted filesystem");
	}
	}

	void ext2_write_bgd(struct ext2_superblock *sb, uint block_group,
	struct ext2_block_group_descriptor *d)
	{
	ext2_load_or_write_bgd(sb, block_group, d, true);
	}

	struct ext2_block_group_descriptor ext2_load_bgd(
	struct ext2_superblock *sb, uint block_group)
	{
	struct ext2_block_group_descriptor bgd;
	ext2_load_or_write_bgd(sb, block_group, &bgd, false);

	return bgd;
	}

	void ext2_load_or_write_bgd(struct ext2_superblock *sb,
	uint block_group,
	struct ext2_block_group_descriptor *d,
	bool set)
	{
	/**
	* The BGDT (not to be confused with the GDT) is located the block after the
	* superblock. On any block size EXCEPT 1024 (the minimum, remember that the
	* block size is specified by X where 1024 << X is the real size) this is
	* the second block (0-indexed, so 1). On 1024 this is the third block.
	*/
	uint bgdt_block = 1;
	uint block_size = ext2_block_size(sb);

	if (block_size == 1024)
	bgdt_block = 2;

	const uint bgd_size = sizeof(struct ext2_block_group_descriptor);

	// Disk page that the BGD is on relative to the initial FILE SYSTEM block
	uint hd_page = block_group / (512 / bgd_size);
	// The offset from the beginning of that page the BGD is at
	uint bgd_offset = block_group % (512 / bgd_size);

	struct ext2_block_group_descriptor descriptors[512 / bgd_size];
	kassert(sizeof(descriptors) == 512, "Wrong BGD size");

	uint lba = (block_size / 512) * bgdt_block + hd_page;

	ata_pio_read_sectors(descriptors, lba, 1);

	if (set)
	{
	descriptors[bgd_offset] = *d;
	ata_pio_write_sectors(lba, 1, (ushort *)descriptors);
	}
	else
	{
	*d = descriptors[bgd_offset];
	}
	}

	static bool print_entry(uint inode, const char name, uint l, void sb)
	{
	kprintf("%d\t %s\n", inode, name);

	return true;

	struct ext2_inode in;

	if (ext2_find_inode(sb, inode, &in))
	{
	if ((in.mode & EXT2_F_TYPE) == EXT2_S_IFREG)
	{
	char buffer[65];
	uint read = ext2_read_inode(sb, &in, buffer, 64);
	buffer[read] = 0;

	kprintf("contents: %d\n'%s'\n", read, buffer);
	}
	}

	return true;
	}

	void ext2_mount(struct fs_node *where)
	{

	struct ext2_superblock *sb = malloc(sizeof(struct ext2_superblock));
	*sb = ext2_read_superblock();

	struct fs_node *ext2_root = ext2_inode2vfs(sb, 2, "/", 1);
	uint err;

	if ((err = fs_mount(where, ext2_root)))
	{
	kprintf(WARN "Failed to mount EXT2: error %d\n", err);
	}
	}

	bool ext2_valid_filesystem()
	{
	struct ext2_superblock sb = ext2_read_superblock();

	kprintf(DEBUG "superblock signature is %d (0x%x)\n", sb.signature,
	sb.signature);

	return sb.signature == EXT2_SIGNATURE;
	}

	void ext2_write_superblock(struct ext2_superblock *sb)
	{
	ushort wp = (ushort )sb;

	ata_pio_write_sectors(2, 2, wp);
	}

	void ext2_corrupt_superblock_for_fun()
	{
	struct ext2_superblock sb = ext2_read_superblock();
	sb.signature = 0xDEAD;
	ext2_write_superblock(&sb);
	}

	bool ext2_get_or_set_inode(struct ext2_superblock *sb, uint number,
	struct ext2_inode *inode, bool set)
	{
	if (number == 0)
	return false;

	uint block_group = (number - 1) / sb->inodes_per_block_group;
	uint local_index = (number - 1) % sb->inodes_per_block_group;

	// Load this from the block group descriptor table
	struct ext2_block_group_descriptor descriptor =
	ext2_load_bgd(sb, block_group);

	// We need to figure out what FS block the inode is on, we know how many
	// inodes there are total in this BGD and the number per page, so this is
	// simple.

	const uint block_size = ext2_block_size(sb);

	const uint inodes_per_block =
	block_size / sizeof(struct ext2_inode);

	uint inode_block = local_index / inodes_per_block;
	uint inode_index = local_index % inodes_per_block;

	struct ext2_inode inodes[block_size / sizeof(struct ext2_inode)];

	const uint fs_block = descriptor.inode_table_start_block +
	inode_block;

	ext2_read_block(sb, inodes, fs_block);

	if (set)
	{
	inodes[inode_index] = *inode;

	ext2_write_block(sb, inodes, fs_block);
	}
	else
	{
	*inode = inodes[inode_index];
	}

	return true;
	}

	bool ext2_find_inode(struct ext2_superblock *sb, uint number,
	struct ext2_inode *inode)
	{
	return ext2_get_or_set_inode(sb, number, inode, false);
	}

	bool ext2_set_inode(struct ext2_superblock *sb, uint number,
	struct ext2_inode *inode)
	{
	return ext2_get_or_set_inode(sb, number, inode, true);
	}

	bool ext2_dir_ls(struct ext2_superblock sb, struct ext2_inode dir,
	bool (cb)(uint inode, const char name, uint name_len,
	void *data),
	void *data)
	{
	if ((dir->mode & 0xf000) != EXT2_S_IFDIR)
	return false;

	for (uint i = 0; i < dir->num_blocks; i++)
	{
	uchar buffer[ext2_block_size(sb)];
	ext2_read_inode_block(sb, dir, buffer, i);

	struct ext2_dirent ent = (void )buffer;

	// While there are files in this block
	while ((uint)ent < (uint)(buffer + ext2_block_size(sb)))
	{
	if (ent->inode == 0)
	return true;

	if (cb)
	{
	char name[256];
	uint name_len = MIN(ent->name_len, 255);

	memcpy(name, ent->name, name_len);
	name[name_len] = '\0';

	if (!cb(ent->inode, name, name_len, data))
	return true;
	}

	ent = (void )(((uint)(void )ent) + ent->rec_len);
	}
	// We ran out of files in this block, continue to the next one. This
	// works because files cannot span blocks
	}

	return true;
	}

	static void ext2_show_dirent(struct ext2_dirent *ent)
	{
	char name[ent->name_len + 1];
	memcpy(name, ent->name, ent->name_len);
	name[ent->name_len] = '\0';

	kprintf(DEBUG "<ent ft=%p, i=%d, s=%s, l=%d>\n", ent->file_type, ent->inode,
	ent->name, ent->rec_len);
	}

	bool ext2_hard_link(struct ext2_superblock sb, struct ext2_inode dir,
	char *name, uint name_len, uint inode)
	{
	struct ext2_inode in;

	if (!ext2_dir_contains(sb, dir, name, name_len) &&
	ext2_find_inode(sb, inode, &in))
	{
	if ((dir->mode & 0xf000) != EXT2_S_IFDIR)
	{
	return false;
	}

	// Increment the reference count to this inode
	in.links_count++;
	ext2_set_inode(sb, inode, &in);

	// Insert it into the directory
	uchar type = EXT2_S_TO_FT(in.mode);
	ext2_insert_into_dir(sb, dir, name, name_len, inode, type);

	return true;
	}
	else
	{
	return false;
	}
	}

	void ext2_insert_into_dir(struct ext2_superblock sb, struct ext2_inode dir,
	char *name, uint name_len, uint inode, uchar type)
	{
	name_len = MIN(name_len, 255);
	const uint min_size = PAD(name_len + sizeof(struct ext2_dirent));
	const uint block_size = ext2_block_size(sb);

	if ((dir->mode & 0xf000) != EXT2_S_IFDIR)
	return;

	uchar buffer[block_size];
	uint i; // block #

	for (i = 0; i < dir->num_blocks; i++)
	{
	ext2_read_inode_block(sb, dir, buffer, i);

	struct ext2_dirent ent = (void )buffer;

	// While there are files in this block
	while ((uint)ent < (uint)(buffer + block_size))
	{
	// kprintf(" %d@%db,%d-%d", ent->inode, i, (uint)ent - (uint)buffer,
	// ent->rec_len);
	if (ent->inode == 0)
	{
	// This is the last item, just insert it at the end
	// TODO: check this actually fits!
	// TODO: if we are in a new block, actually create it!

	ent->rec_len = min_size;
	ent->name_len = name_len;
	memcpy(ent->name, name, name_len);
	ent->inode = inode;
	ent->file_type = type;

	kprintf(DEBUG
	"Inserted into dir (appending) at block=%d, b=%p \n",
	i, (uint)ent - (uint)buffer);

	goto finish;
	}

	uint this_min_size =
	PAD(ent->name_len + sizeof(struct ext2_dirent));
	uint available_size = ent->rec_len - this_min_size;

	// kprintf(",%d=%d/%d", ent->name_len, this_min_size,
	// available_size);

	if (available_size >= min_size)
	{
	// We can fit this in here
	struct ext2_dirent *inserting =
	(void )(((uint)(void )ent) + this_min_size);

	ent->rec_len = this_min_size;

	inserting->rec_len = available_size;
	inserting->name_len = name_len;
	inserting->inode = inode;
	inserting->file_type = type;
	memcpy(inserting->name, name, name_len);

	kprintf(DEBUG
	"Inserted into dir (splicing) at block=%d, b=%p \n",
	i, (uint)inserting - (uint)buffer);

	// Done!
	goto finish;
	}

	ent = (void )(((uint)(void )ent) + ent->rec_len);
	}
	// We ran out of files in this block, continue to the next one. This
	// works because files cannot span blocks
	}

	kprintf("\n");

	kprintf(WARN "Failed to insert!\n");

	finish:
	kprintf("\n");
	ext2_write_inode_block(sb, dir, buffer, i);
	kprintf(DEBUG "[insert] writing inode block %d\n", i);
	}

	ssize_t ext2_read_inode(struct ext2_superblock sb, struct ext2_inode inode,
	void *buffer, ssize_t size)
	{
	const uint block_size = ext2_block_size(sb);
	char transfer[block_size];

	uint fsize = MIN(inode->size, (uint)size);
	uint i;

	// Transfer full blocks straight to the output buffer
	for (i = 0; i < fsize / block_size; i++)
	{
	ext2_read_inode_block(sb, inode, buffer + i * block_size, i);
	}

	// If we have part of a block left over read it here first, then transfer
	// what we need
	if (i * block_size < fsize)
	{
	uint remainder = fsize % block_size;

	ext2_read_inode_block(sb, inode, transfer, i);
	memcpy(buffer + i * block_size, transfer, remainder);
	}

	return fsize;
	}

	static uint ext2_compute_absolute_block(struct ext2_superblock *sb,
	struct ext2_inode *inode, uint block)
	{
	if (block >= 12)
	{
	kprintf(ERROR
	"Sorry, EXT2 can only access the first 12 (direct) blocks "
	"of an inode for now. Indirect look-up will be added later\n");
	kpanic("Invalid inode block");
	}

	return block;
	}

	bool ext2_read_inode_block(struct ext2_superblock sb, struct ext2_inode inode,
	void *buffer, uint block)
	{
	block = ext2_compute_absolute_block(sb, inode, block);
	uint block_address = inode->blocks[block];

	ext2_read_block(sb, buffer, block_address);

	return true;
	}

	bool ext2_write_inode_block(struct ext2_superblock sb, struct ext2_inode dir,
	void *buffer, uint block)
	{
	block = ext2_compute_absolute_block(sb, dir, block);
	uint block_address = dir->blocks[block];

	kprintf(DEBUG "Writing size=%d, inode block %p, b=%d\n",
	ext2_block_size(sb), block_address * ext2_block_size(sb), block);

	ext2_write_block(sb, buffer, block_address);

	return true;
	}

	static uint ext2_bitmap_block(struct ext2_superblock *sb,
	uint bitmap_block, uint index)
	{
	const uint block_size = ext2_block_size(sb);

	while (*index > block_size)
	{
	*index -= block_size;
	*bitmap_block += 1;
	}

	return block_size;
	}

	bool ext2_check_in_bitmap(struct ext2_superblock *sb, uint bitmap_block,
	uint index)
	{
	const uint block_size = ext2_bitmap_block(sb, &bitmap_block, &index);

	uint byte = index / 8;
	uint bit = index % 8;

	uchar buffer[block_size];

	ext2_read_block(sb, buffer, bitmap_block);

	return !!(buffer[byte] & (1 << bit));
	}

	void ext2_set_in_bitmap(struct ext2_superblock *sb, uint bitmap_block,
	uint index, bool value)
	{
	const uint block_size = ext2_bitmap_block(sb, &bitmap_block, &index);

	uint byte = index / 8;
	uint bit = index % 8;

	uchar buffer[block_size];

	ext2_read_block(sb, buffer, bitmap_block);

	uchar target_bit = 1 << bit;
	buffer[byte] =
	value ? (buffer[byte] \| target_bit) : (buffer[byte] \| ~target_bit);

	ext2_write_block(sb, buffer, bitmap_block);
	}

	uint ext2_first_zero_bit(struct ext2_superblock *sb, uint bitmap_block,
	uint num_blocks, uint start_at)
	{
	uint block_size = ext2_block_size(sb);

	for (uint block = bitmap_block; block < bitmap_block + num_blocks; block++)
	{
	// dword-array for performance
	uint buffer[block_size / 4];

	ext2_read_block(sb, buffer, block);

	// If this is the first block start at start_at, otherwise 0
	for (uint i = 0; i < block_size / 4; i++)
	{
	// The bitwise negative will be non-zero if there are zero bits in
	// the original.
	if (~buffer[i])
	{
	// 4 bytes * 8 bits * i dwords
	uint index =
	(4 * 8 * i) + (block - bitmap_block) * 8 * block_size;

	// __builtin_ffs gives us 1+the index of the least-significant 1
	// bit. Since we take the bitwise inverse this is actuall the
	// least significant 0 bit. This is a GCC intrinsic. This works
	// particularly well on little-endian systems where the least
	// significant bit happens to also correspond to the first bit
	// in the dword bitset.
	//
	// ________ ________ ________ ________
	// ^ this is the LSB ^
	// \| this is the MSB
	//
	// This means that the LSB is also the first bit in the bitset.
	uint trailing = __builtin_ffs(~buffer[i]) - 1;

	return trailing + index;
	}
	}
	}

	return -1;
	}

	uint ext2_first_free_inode(struct ext2_superblock *sb)
	{
	uint num_block_groups = ext2_num_block_groups(sb);

	kprintf(INFO "%d block groups\n", num_block_groups);

	for (uint bg_num = 0; bg_num < num_block_groups; bg_num++)
	{
	struct ext2_block_group_descriptor bgd =
	ext2_load_bgd(sb, 0);

	const uint block_size = ext2_block_size(sb);
	// + 1 because we need to round up (ie 1025 for 1024 size blocks will
	// yield 1, should 2)
	uint bitset_blocks = (sb->inodes_per_block_group / 8) / block_size + 1;

	// inodes start at 1
	uint inode =
	ext2_first_zero_bit(sb, bgd.inode_bitmap, bitset_blocks, 12) + 1;
	// This will overflow back to zero if no inode was found

	if (inode)
	return inode;
	}

	return 0;
	}

	// ^
	// \| this and \| this are awfully similar, should refactor
	// v

	uint ext2_first_free_block(struct ext2_superblock *sb)
	{
	uint num_block_groups = ext2_num_block_groups(sb);

	for (uint bg_num = 0; bg_num < num_block_groups; bg_num++)
	{
	struct ext2_block_group_descriptor bgd =
	ext2_load_bgd(sb, 0);

	const uint block_size = ext2_block_size(sb);
	// + 1 because we need to round up (ie 1025 for 1024 size blocks will
	// yield 1, should 2)
	uint bitset_blocks = (sb->blocks_per_block_group / 8) / block_size + 1;

	// inodes start at 1
	uint block_no =
	ext2_first_zero_bit(sb, bgd.block_bitmap, bitset_blocks, 0);
	// This will overflow back to zero if no inode was found

	if (block_no != 0xffffffff)
	return block_no;
	}

	return 0;
	}

	struct ext2_dir_contains_data
	{
	char *name;
	uint len;
	bool found;
	};

	static bool ext2_dir_contains_cb(uint inode, const char *name,
	uint name_len,
	struct ext2_dir_contains_data *d)
	{
	if (strncmp((char *)name, d->name, MIN(name_len, d->len)) == 0)
	{
	d->found = true;
	return false;
	}

	return true;
	}

	bool ext2_dir_contains(struct ext2_superblock sb, struct ext2_inode dir,
	char *name, uint len)
	{
	if ((dir->mode & EXT2_F_TYPE) != EXT2_S_IFDIR)
	{
	return false;
	}

	struct ext2_dir_contains_data d =
	{
	.name = name,
	.len = len,
	.found = false,
	};

	ext2_dir_ls(sb, dir, ext2_dir_contains_cb, &d);

	return d.found;
	}

	struct ext2_dir_find_data
	{
	char *name;
	uint len;
	uint inode;
	};

	bool ext2_dir_find_cb(uint inode, const char *name, uint len,
	struct ext2_dir_find_data *d)
	{
	if (strncmp((char *)name, d->name, MIN(len, d->len)) == 0)
	{
	d->inode = inode;
	return false;
	}

	return true;
	}

	uint ext2_dir_find(struct ext2_superblock sb, struct ext2_inode dir,
	char *name, uint name_len)
	{
	if ((dir->mode & EXT2_F_TYPE) != EXT2_S_IFDIR)
	{
	return false;
	}

	struct ext2_dir_find_data d =
	{
	.name = name,
	.len = name_len,
	.inode = 0,
	};

	ext2_dir_ls(sb, dir, ext2_dir_find_cb, &d);

	return d.inode;
	}

	uint ext2_alloc_new_block(struct ext2_superblock *sb,
	uint block_group)
	{
	struct ext2_block_group_descriptor bgd =
	ext2_load_bgd(sb, block_group);

	if (bgd.unallocated_blocks == 0)
	// TODO: handle out of blocks
	return ext2_alloc_new_block(sb, block_group + 1);

	// We can safely pass ~0 here as long as the FS is well formed
	// because we know there is at least 1 free block
	uint block = ext2_first_zero_bit(sb, bgd.block_bitmap, ~0, 0);

	ext2_set_in_bitmap(sb, bgd.block_bitmap, block, true);
	bgd.unallocated_blocks--;

	ext2_write_bgd(sb, block_group, &bgd);

	return block;
	}