use std::cmp::min;
use syscall::error::{Result, Error, EEXIST, EISDIR, ENOENT, ENOSPC, ENOTDIR, ENOTEMPTY};
use super::{Disk, ExNode, Extent, Header, Node};
/// A file system
pub struct FileSystem {
pub disk: Box<Disk>,
pub block: u64,
pub header: (u64, Header)
}
impl FileSystem {
/// Open a file system on a disk
pub fn open(mut disk: Box<Disk>) -> Result<Self> {
for block in 0..65536 {
let mut header = (0, Header::default());
try!(disk.read_at(block + header.0, &mut header.1));
if header.1.valid() {
let mut root = (header.1.root, Node::default());
try!(disk.read_at(block + root.0, &mut root.1));
let mut free = (header.1.free, Node::default());
try!(disk.read_at(block + free.0, &mut free.1));
return Ok(FileSystem {
disk: disk,
block: block,
header: header
});
}
}
Err(Error::new(ENOENT))
}
/// Create a file system on a disk
pub fn create(mut disk: Box<Disk>) -> Result<Self> {
let size = try!(disk.size());
if size >= 4 * 512 {
let mut free = (2, Node::new(Node::MODE_FILE, "free", 0));
free.1.extents[0] = Extent::new(4, size - 4 * 512);
try!(disk.write_at(free.0, &free.1));
let root = (1, Node::new(Node::MODE_DIR | 0o755, "root", 0));
try!(disk.write_at(root.0, &root.1));
let header = (0, Header::new(size, root.0, free.0));
try!(disk.write_at(header.0, &header.1));
Ok(FileSystem {
disk: disk,
block: 0,
header: header
})
} else {
Err(Error::new(ENOSPC))
}
}
pub fn read_at(&mut self, block: u64, buffer: &mut [u8]) -> Result<usize> {
self.disk.read_at(self.block + block, buffer)
}
pub fn write_at(&mut self, block: u64, buffer: &[u8]) -> Result<usize> {
self.disk.write_at(self.block + block, buffer)
}
pub fn allocate(&mut self, length: u64) -> Result<u64> {
//TODO: traverse next pointer
let free_block = self.header.1.free;
let mut free = try!(self.node(free_block));
let mut block_option = None;
for mut extent in free.1.extents.iter_mut() {
if extent.length/512 >= length {
block_option = Some(extent.block);
extent.length -= length * 512;
extent.block += length;
break;
}
}
if let Some(block) = block_option {
try!(self.write_at(free.0, &free.1));
Ok(block)
} else {
Err(Error::new(ENOSPC))
}
}
pub fn deallocate(&mut self, block: u64, length: u64) -> Result<()> {
let free_block = self.header.1.free;
self.insert_blocks(block, length, free_block)
}
pub fn node(&mut self, block: u64) -> Result<(u64, Node)> {
let mut node = Node::default();
try!(self.read_at(block, &mut node));
Ok((block, node))
}
pub fn ex_node(&mut self, block: u64) -> Result<(u64, ExNode)> {
let mut node = ExNode::default();
try!(self.read_at(block, &mut node));
Ok((block, node))
}
pub fn child_nodes(&mut self, children: &mut Vec<(u64, Node)>, parent_block: u64) -> Result<()> {
if parent_block == 0 {
return Ok(());
}
let parent = try!(self.node(parent_block));
for extent in parent.1.extents.iter() {
for (block, size) in extent.blocks() {
if size >= 512 {
children.push(try!(self.node(block)));
}
}
}
self.child_nodes(children, parent.1.next)
}
pub fn find_node(&mut self, name: &str, parent_block: u64) -> Result<(u64, Node)> {
if parent_block == 0 {
return Err(Error::new(ENOENT));
}
let parent = try!(self.node(parent_block));
for extent in parent.1.extents.iter() {
for (block, size) in extent.blocks() {
if size >= 512 {
let child = try!(self.node(block));
let mut matches = false;
if let Ok(child_name) = child.1.name() {
if child_name == name {
matches = true;
}
}
if matches {
return Ok(child);
}
}
}
}
self.find_node(name, parent.1.next)
}
pub fn path_nodes(&mut self, path: &str, nodes: &mut Vec<(u64, Node)>) -> Result<(u64, Node)> {
let mut block = self.header.1.root;
nodes.push(try!(self.node(block)));
for part in path.split('/') {
if ! part.is_empty() {
let node = try!(self.find_node(part, block));
block = node.0;
nodes.push(node);
}
}
Ok(nodes.pop().unwrap())
}
fn insert_blocks(&mut self, block: u64, length: u64, parent_block: u64) -> Result<()> {
if parent_block == 0 {
return Err(Error::new(ENOSPC));
}
let mut inserted = false;
let mut parent = try!(self.node(parent_block));
for mut extent in parent.1.extents.iter_mut() {
if extent.length == 0 {
//New extent
inserted = true;
extent.block = block;
extent.length = length;
break;
} else if length % 512 == 0 && extent.block == block + length/512 {
//At beginning
inserted = true;
extent.block = block;
extent.length += length;
break;
} else if extent.length % 512 == 0 && extent.block + extent.length/512 == block {
//At end
inserted = true;
extent.length += length;
break;
}
}
if inserted {
try!(self.write_at(parent.0, &parent.1));
Ok(())
} else {
if parent.1.next == 0 {
parent.1.next = try!(self.allocate(1));
try!(self.write_at(parent.0, &parent.1));
try!(self.write_at(parent.1.next, &Node::default()));
}
self.insert_blocks(block, length, parent.1.next)
}
}
pub fn create_node(&mut self, mode: u16, name: &str, parent_block: u64) -> Result<(u64, Node)> {
if self.find_node(name, parent_block).is_ok() {
Err(Error::new(EEXIST))
} else {
let node = (try!(self.allocate(1)), Node::new(mode, name, parent_block));
try!(self.write_at(node.0, &node.1));
try!(self.insert_blocks(node.0, 512, parent_block));
Ok(node)
}
}
fn remove_blocks(&mut self, block: u64, length: u64, parent_block: u64) -> Result<()> {
if parent_block == 0 {
return Err(Error::new(ENOENT));
}
let mut removed = false;
let mut replace_option = None;
let mut parent = try!(self.node(parent_block));
for mut extent in parent.1.extents.iter_mut() {
if block >= extent.block && block + length <= extent.block + extent.length/512 {
//Inside
removed = true;
let left = Extent::new(extent.block, (block - extent.block) * 512);
let right = Extent::new(block + length, ((extent.block + extent.length/512) - (block + length)) * 512);
if left.length > 0 {
*extent = left;
if right.length > 0 {
replace_option = Some(right);
}
} else if right.length > 0 {
*extent = right;
} else {
*extent = Extent::default();
}
break;
}
}
if removed {
try!(self.write_at(parent.0, &parent.1));
if let Some(replace) = replace_option {
try!(self.insert_blocks(replace.block, replace.length, parent_block));
}
try!(self.deallocate(block, 512));
Ok(())
} else {
self.remove_blocks(block, length, parent.1.next)
}
}
pub fn remove_node(&mut self, mode: u16, name: &str, parent_block: u64) -> Result<()> {
let node = try!(self.find_node(name, parent_block));
if node.1.mode & Node::MODE_TYPE == mode {
if node.1.is_dir() {
let mut children = Vec::new();
try!(self.child_nodes(&mut children, node.0));
if ! children.is_empty() {
return Err(Error::new(ENOTEMPTY));
}
}
try!(self.remove_blocks(node.0, 1, parent_block));
try!(self.write_at(node.0, &Node::default()));
Ok(())
} else if node.1.is_dir() {
Err(Error::new(EISDIR))
} else {
Err(Error::new(ENOTDIR))
}
}
fn node_ensure_len(&mut self, block: u64, mut length: u64) -> Result<()> {
if block == 0 {
return Err(Error::new(ENOENT));
}
let mut changed = false;
let mut node = try!(self.node(block));
for mut extent in node.1.extents.iter_mut() {
if extent.length >= length {
length = 0;
break;
} else {
changed = true;
let allocated = ((extent.length + 511)/512) * 512;
if allocated >= length {
extent.length = length;
length = 0;
break;
} else {
extent.length = allocated;
length -= allocated;
}
}
}
if changed {
try!(self.write_at(node.0, &node.1));
}
if length > 0 {
if node.1.next > 0 {
self.node_ensure_len(node.1.next, length)
} else {
let new_block = try!(self.allocate((length + 511)/512));
try!(self.insert_blocks(new_block, length, block));
Ok(())
}
} else {
Ok(())
}
}
pub fn node_set_len(&mut self, block: u64, mut length: u64) -> Result<()> {
if block == 0 {
return Err(Error::new(ENOENT));
}
let mut changed = false;
let mut node = try!(self.node(block));
for mut extent in node.1.extents.iter_mut() {
if extent.length > length {
//TODO: try!(self.deallocate(block, 512));
extent.length = length;
changed = true;
length = 0;
} else {
length -= extent.length;
}
}
if changed {
try!(self.write_at(node.0, &node.1));
}
if node.1.next > 0 {
self.node_set_len(node.1.next, length)
} else {
Ok(())
}
}
fn node_extents(&mut self, block: u64, mut offset: u64, mut len: usize, extents: &mut Vec<Extent>) -> Result<()> {
if block == 0 {
return Ok(());
}
let node = try!(self.node(block));
for extent in node.1.extents.iter() {
let mut push_extent = Extent::default();
for (block, size) in extent.blocks() {
if offset == 0 {
if push_extent.block == 0 {
push_extent.block = block;
}
if len >= size {
push_extent.length += size as u64;
len -= size;
} else if len > 0 {
push_extent.length += len as u64;
len = 0;
break;
} else {
break;
}
} else {
offset -= 1;
}
}
if push_extent.length > 0 {
extents.push(push_extent);
}
if len == 0 {
break;
}
}
if len > 0 {
self.node_extents(node.1.next, offset, len, extents)
} else {
Ok(())
}
}
pub fn read_node(&mut self, block: u64, offset: u64, buf: &mut [u8]) -> Result<usize> {
let block_offset = offset / 512;
let mut byte_offset = (offset % 512) as usize;
let mut extents = Vec::new();
try!(self.node_extents(block, block_offset, byte_offset + buf.len(), &mut extents));
let mut i = 0;
for extent in extents.iter() {
let mut block = extent.block;
let mut length = extent.length;
if byte_offset > 0 && length > 0 {
let mut sector = [0; 512];
try!(self.read_at(block, &mut sector));
let sector_size = min(sector.len() as u64, length) as usize;
for (s_b, mut b) in sector[byte_offset..sector_size].iter().zip(buf[i..].iter_mut()) {
*b = *s_b;
i += 1;
}
block += 1;
length -= sector_size as u64;
byte_offset = 0;
}
let length_aligned = ((min(length, (buf.len() - i) as u64)/512) * 512) as usize;
if length_aligned > 0 {
let extent_buf = &mut buf[i..i + length_aligned];
try!(self.read_at(block, extent_buf));
i += length_aligned;
block += (length_aligned as u64)/512;
length -= length_aligned as u64;
}
if length > 0 {
let mut sector = [0; 512];
try!(self.read_at(block, &mut sector));
let sector_size = min(sector.len() as u64, length) as usize;
for (s_b, mut b) in sector[..sector_size].iter().zip(buf[i..].iter_mut()) {
*b = *s_b;
i += 1;
}
block += 1;
length -= sector_size as u64;
}
assert_eq!(length, 0);
assert_eq!(block, extent.block + (extent.length + 511)/512);
}
Ok(i)
}
pub fn write_node(&mut self, block: u64, offset: u64, buf: &[u8]) -> Result<usize> {
let block_offset = offset / 512;
let mut byte_offset = (offset % 512) as usize;
try!(self.node_ensure_len(block, block_offset as u64 * 512 + (byte_offset + buf.len()) as u64));
let mut extents = Vec::new();
try!(self.node_extents(block, block_offset, byte_offset + buf.len(), &mut extents));
let mut i = 0;
for extent in extents.iter() {
let mut block = extent.block;
let mut length = extent.length;
if byte_offset > 0 && length > 0 {
let mut sector = [0; 512];
try!(self.read_at(block, &mut sector));
let sector_size = min(sector.len() as u64, length) as usize;
for (mut s_b, b) in sector[byte_offset..sector_size].iter_mut().zip(buf[i..].iter()) {
*s_b = *b;
i += 1;
}
try!(self.write_at(block, §or));
block += 1;
length -= sector_size as u64;
byte_offset = 0;
}
let length_aligned = ((min(length, (buf.len() - i) as u64)/512) * 512) as usize;
if length_aligned > 0 {
let extent_buf = &buf[i..i + length_aligned];
try!(self.write_at(block, extent_buf));
i += length_aligned;
block += (length_aligned as u64)/512;
length -= length_aligned as u64;
}
if length > 0 {
let mut sector = [0; 512];
try!(self.read_at(block, &mut sector));
let sector_size = min(sector.len() as u64, length) as usize;
for (mut s_b, b) in sector[..sector_size].iter_mut().zip(buf[i..].iter()) {
*s_b = *b;
i += 1;
}
try!(self.write_at(block, §or));
block += 1;
length -= sector_size as u64;
}
assert_eq!(length, 0);
assert_eq!(block, extent.block + (extent.length + 511)/512);
}
Ok(i)
}
pub fn node_len(&mut self, block: u64) -> Result<u64> {
if block == 0 {
return Err(Error::new(ENOENT));
}
let mut size = 0;
let node = try!(self.node(block));
for extent in node.1.extents.iter() {
size += extent.length;
}
if node.1.next > 0 {
size += try!(self.node_len(node.1.next));
Ok(size)
} else {
Ok(size)
}
}
}