genode/repos/os/include/vfs/ram_file_system.h
Emery Hemingway 6cb0f3bb71 VFS ram: remove quota
Fixes #1780
2015-11-29 18:17:05 +01:00

725 lines
16 KiB
C++

/*
* \brief Embedded RAM VFS
* \author Emery Hemingway
* \date 2015-07-21
*/
/*
* Copyright (C) 2015 Genode Labs GmbH
*
* This file is part of the Genode OS framework, which is distributed
* under the terms of the GNU General Public License version 2.
*/
#ifndef _INCLUDE__VFS__RAM_FILE_SYSTEM_H_
#define _INCLUDE__VFS__RAM_FILE_SYSTEM_H_
#include <ram_fs/chunk.h>
#include <vfs/file_system.h>
#include <dataspace/client.h>
#include <util/avl_tree.h>
namespace Vfs_ram {
using namespace Genode;
using namespace Vfs;
class Node;
class File;
class Symlink;
class Directory;
enum { MAX_NAME_LEN = 128 };
/**
* Return base-name portion of null-terminated path string
*/
static inline char const *basename(char const *path)
{
char const *start = path;
for (; *path; ++path)
if (*path == '/')
start = path + 1;
return start;
}
}
namespace Vfs { class Ram_file_system; }
class Vfs_ram::Node : public Genode::Avl_node<Node>, public Genode::Lock
{
private:
char _name[MAX_NAME_LEN];
unsigned long const _inode;
/**
* Generate unique inode number
*
* XXX: these inodes could clash with other VFS plugins
*/
static unsigned long _unique_inode()
{
static unsigned long inode_count;
return ++inode_count;
}
public:
Node(char const *node_name)
: _inode(_unique_inode()) { name(node_name); }
virtual ~Node() { }
unsigned long inode() const { return _inode; }
char const *name() { return _name; }
void name(char const *name) { strncpy(_name, name, MAX_NAME_LEN); }
virtual Vfs::file_size length() = 0;
/************************
** Avl node interface **
************************/
bool higher(Node *c) { return (strcmp(c->_name, _name) > 0); }
/**
* Find index N by walking down the tree N times,
* not the most efficient way to do this.
*/
Node *index(file_offset &i)
{
if (i-- == 0)
return this;
Node *n;
n = child(LEFT);
if (n)
n = n->index(i);
if (n) return n;
n = child(RIGHT);
if (n)
n = n->index(i);
return n;
}
Node *sibling(const char *name)
{
if (strcmp(name, _name) == 0) return this;
Node *c =
Avl_node<Node>::child(strcmp(name, _name) > 0);
return c ? c->sibling(name) : 0;
}
struct Guard
{
Node *node;
Guard(Node *guard_node) : node(guard_node) { node->lock(); }
~Guard() { node->unlock(); }
};
};
class Vfs_ram::File : public Vfs_ram::Node
{
private:
typedef ::File_system::Chunk<4096> Chunk_level_3;
typedef ::File_system::Chunk_index<128, Chunk_level_3> Chunk_level_2;
typedef ::File_system::Chunk_index<64, Chunk_level_2> Chunk_level_1;
typedef ::File_system::Chunk_index<64, Chunk_level_1> Chunk_level_0;
Chunk_level_0 _chunk;
file_size _length = 0;
public:
File(char const *name, Allocator &alloc)
: Node(name), _chunk(alloc, 0) { }
size_t read(char *dst, size_t len, file_size seek_offset)
{
file_size const chunk_used_size = _chunk.used_size();
if (seek_offset >= _length)
return 0;
/*
* Constrain read transaction to available chunk data
*
* Note that 'chunk_used_size' may be lower than '_length'
* because 'Chunk' may have truncated tailing zeros.
*/
if (seek_offset + len >= _length)
len = _length - seek_offset;
file_size read_len = len;
if (seek_offset + read_len > chunk_used_size) {
if (chunk_used_size >= seek_offset)
read_len = chunk_used_size - seek_offset;
else
read_len = 0;
}
_chunk.read(dst, read_len, seek_offset);
/* add zero padding if needed */
if (read_len < len)
memset(dst + read_len, 0, len - read_len);
return len;
}
size_t write(char const *src, size_t len, file_size seek_offset)
{
if (seek_offset == (file_size)(~0))
seek_offset = _chunk.used_size();
if (seek_offset + len >= Chunk_level_0::SIZE)
len = Chunk_level_0::SIZE - (seek_offset + len);
_chunk.write(src, len, (size_t)seek_offset);
/*
* Keep track of file length. We cannot use 'chunk.used_size()'
* as file length because trailing zeros may by represented
* by zero chunks, which do not contribute to 'used_size()'.
*/
_length = max(_length, seek_offset + len);
return len;
}
file_size length() { return _length; }
void truncate(file_size size)
{
if (size < _chunk.used_size())
_chunk.truncate(size);
_length = size;
}
};
class Vfs_ram::Symlink : public Vfs_ram::Node
{
private:
char _target[MAX_PATH_LEN];
size_t _len = 0;
public:
Symlink(char const *name) : Node(name) { }
file_size length() { return _len; }
void set(char const *target, size_t len)
{
_len = min(len, MAX_PATH_LEN);
memcpy(_target, target, _len);
}
size_t get(char *buf, size_t len)
{
size_t out = min(len, _len);
memcpy(buf, _target, out);
return out;
}
};
class Vfs_ram::Directory : public Vfs_ram::Node
{
private:
Avl_tree<Node> _entries;
file_size _count = 0;
public:
Directory(char const *name) : Node(name) { }
~Directory()
{
while (Node *node = _entries.first()) {
_entries.remove(node);
destroy(env()->heap(), node);
}
}
void adopt(Node *node)
{
_entries.insert(node);
++_count;
}
Node *child(char const *name)
{
Node *node = _entries.first();
return node ? node->sibling(name) : 0;
}
void release(Node *node)
{
_entries.remove(node);
--_count;
}
file_size length() override { return _count; }
void dirent(file_offset index, Directory_service::Dirent &dirent)
{
dirent.fileno = index+1;
dirent.type = Directory_service::DIRENT_TYPE_END;
dirent.name[0] = '\0';
Node *node = _entries.first();
if (node) {
node = node->index(index);
if (!node) return;
strncpy(dirent.name, node->name(), sizeof(dirent.name));
File *file = dynamic_cast<File *>(node);
if (file) {
dirent.type = Directory_service::DIRENT_TYPE_FILE;
return;
}
Directory *dir = dynamic_cast<Directory *>(node);
if (dir) {
dirent.type = Directory_service::DIRENT_TYPE_DIRECTORY;
return;
}
Symlink *symlink = dynamic_cast<Symlink *>(node);
if (symlink) {
dirent.type = Directory_service::DIRENT_TYPE_SYMLINK;
}
}
}
};
class Vfs::Ram_file_system : public Vfs::File_system
{
private:
class Ram_vfs_handle : public Vfs_handle
{
private:
Vfs_ram::File *_file;
public:
Ram_vfs_handle(File_system &fs, int status_flags, Vfs_ram::File *file)
: Vfs_handle(fs, fs, status_flags), _file(file)
{ }
Vfs_ram::File *file() const { return _file; }
};
Genode::Allocator &_alloc;
Vfs_ram::Directory _root;
Vfs_ram::Node *lookup(char const *path, bool return_parent = false)
{
using namespace Vfs_ram;
if (*path == '/') ++path;
if (*path == '\0') return &_root;
char buf[Vfs::MAX_PATH_LEN];
strncpy(buf, path, Vfs::MAX_PATH_LEN);
Directory *dir = &_root;
char *name = &buf[0];
for (size_t i = 0; i < MAX_NAME_LEN; ++i) {
if (buf[i] == '/') {
buf[i] = '\0';
Node *node = dir->child(name);
if (!node) return 0;
dir = dynamic_cast<Directory *>(node);
if (!dir) return 0;
/* set the current name aside */
name = &buf[i+1];
} else if (buf[i] == '\0') {
if (return_parent)
return dir;
else
return dir->child(name);
}
}
return 0;
}
Vfs_ram::Directory *lookup_parent(char const *path)
{
using namespace Vfs_ram;
Node *node = lookup(path, true);
if (node)
return dynamic_cast<Directory *>(node);
return 0;
}
public:
Ram_file_system(Xml_node config)
: _alloc(*env()->heap()), _root("") { }
/*********************************
** Directory service interface **
*********************************/
file_size num_dirent(char const *path) override
{
using namespace Vfs_ram;
if (Node *node = lookup(path)) {
Node::Guard guard(node);
if (Directory *dir = dynamic_cast<Directory *>(node))
return dir->length();
}
return 0;
}
bool is_directory(char const *path)
{
using namespace Vfs_ram;
Node *node = lookup(path);
return node ? dynamic_cast<Directory *>(node) : 0;
}
char const *leaf_path(char const *path) {
return lookup(path) ? path : 0; }
Mkdir_result mkdir(char const *path, unsigned mode) override
{
using namespace Vfs_ram;
Directory *parent = lookup_parent(path);
if (!parent) return MKDIR_ERR_NO_ENTRY;
Node::Guard guard(parent);
char const *name = basename(path);
if (strlen(name) >= MAX_NAME_LEN)
return MKDIR_ERR_NAME_TOO_LONG;
if (parent->child(name)) return MKDIR_ERR_EXISTS;
parent->adopt(new (_alloc) Directory(name));
return MKDIR_OK;
}
Open_result open(char const *path, unsigned mode, Vfs_handle **handle) override
{
using namespace Vfs_ram;
File *file;
char const *name = basename(path);
if (mode & OPEN_MODE_CREATE) {
Directory *parent = lookup_parent(path);
Node::Guard guard(parent);
if (!parent) return OPEN_ERR_UNACCESSIBLE;
if (parent->child(name)) return OPEN_ERR_EXISTS;
if (strlen(name) >= MAX_NAME_LEN)
return OPEN_ERR_NAME_TOO_LONG;
file = new (_alloc) File(name, _alloc);
parent->adopt(file);
} else {
Node *node = lookup(path);
if (!node) return OPEN_ERR_UNACCESSIBLE;
file = dynamic_cast<File *>(node);
if (!file) return OPEN_ERR_UNACCESSIBLE;
}
/* allocate handle on the heap */
*handle = new (env()->heap()) Ram_vfs_handle(*this, mode, file);
return OPEN_OK;
}
Stat_result stat(char const *path, Stat &stat) override
{
using namespace Vfs_ram;
Node *node = lookup(path);
if (!node) return STAT_ERR_NO_ENTRY;
Node::Guard guard(node);
stat.inode = node->inode();
stat.size = node->length();
File *file = dynamic_cast<File *>(node);
if (file) {
stat.mode = STAT_MODE_FILE | 0777;
return STAT_OK;
}
Directory *dir = dynamic_cast<Directory *>(node);
if (dir) {
stat.mode = STAT_MODE_DIRECTORY | 0777;
return STAT_OK;
}
Symlink *symlink = dynamic_cast<Symlink *>(node);
if (symlink) {
stat.mode = STAT_MODE_SYMLINK | 0777;
return STAT_OK;
}
return STAT_ERR_NO_ENTRY;
}
Dirent_result dirent(char const *path, file_offset index, Dirent &dirent) override
{
using namespace Vfs_ram;
Node *node = lookup(path);
if (!node) return DIRENT_ERR_INVALID_PATH;
Node::Guard guard(node);
Directory *dir = dynamic_cast<Directory *>(node);
if (!dir) return DIRENT_ERR_INVALID_PATH;
dir->dirent(index, dirent);
return DIRENT_OK;
}
Symlink_result symlink(char const *target, char const *path) override
{
using namespace Vfs_ram;
Symlink *link;
Directory *parent = lookup_parent(path);
if (!parent) return SYMLINK_ERR_NO_ENTRY;
Node::Guard guard(parent);
char const *name = basename(path);
Node *node = parent->child(name);
if (node) {
node->lock();
link = dynamic_cast<Symlink *>(node);
if (!link) {
node->unlock();
return SYMLINK_ERR_EXISTS;
}
} else {
if (strlen(name) >= MAX_NAME_LEN)
return SYMLINK_ERR_NAME_TOO_LONG;
link = new (_alloc) Symlink(name);
link->lock();
parent->adopt(link);
}
if (*target)
link->set(target, strlen(target));
link->unlock();
return SYMLINK_OK;
}
Readlink_result readlink(char const *path, char *buf,
file_size buf_size, file_size &out_len) override
{
using namespace Vfs_ram;
Directory *parent = lookup_parent(path);
if (!parent)
return READLINK_ERR_NO_ENTRY;
Node::Guard parent_guard(parent);
Node *node = parent->child(basename(path));
if (!node) return READLINK_ERR_NO_ENTRY;
Node::Guard guard(node);
Symlink *link = dynamic_cast<Symlink *>(node);
if (!link) return READLINK_ERR_NO_ENTRY;
out_len = link->get(buf, buf_size);
return READLINK_OK;
}
Rename_result rename(char const *from, char const *to) override
{
using namespace Vfs_ram;
char const *new_name = basename(to);
if (strlen(new_name) >= MAX_NAME_LEN)
return RENAME_ERR_NO_PERM;
Directory *from_dir = lookup_parent(from);
if (!from_dir) return RENAME_ERR_NO_ENTRY;
Node::Guard from_guard(from_dir);
Directory *to_dir = lookup_parent(to);
if (!to_dir) return RENAME_ERR_NO_ENTRY;
if (from_dir == to_dir) {
Node *node = from_dir->child(basename(from));
if (!node) return RENAME_ERR_NO_ENTRY;
Node::Guard guard(node);
if (from_dir->child(new_name)) return RENAME_ERR_NO_PERM;
node->name(new_name);
} else {
Node::Guard toguard(to_dir);
if (to_dir->child(new_name)) return RENAME_ERR_NO_PERM;
Node *node = from_dir->child(basename(from));
if (!node) return RENAME_ERR_NO_ENTRY;
node->name(new_name);
to_dir->adopt(node);
from_dir->release(node);
}
return RENAME_OK;
}
Unlink_result unlink(char const *path) override
{
using namespace Vfs_ram;
Directory *parent = lookup_parent(path);
if (!parent) return UNLINK_ERR_NO_ENTRY;
Node::Guard guard(parent);
Node *node = parent->child(basename(path));
if (!node) return UNLINK_ERR_NO_ENTRY;
node->lock();
parent->release(node);
destroy(_alloc, node);
return UNLINK_OK;
}
Dataspace_capability dataspace(char const *path) override
{
using namespace Vfs_ram;
Ram_dataspace_capability ds_cap;
Node *node = lookup(path);
if (!node) return ds_cap;
Node::Guard guard(node);
File *file = dynamic_cast<File *>(node);
if (!file) return ds_cap;
size_t len = file->length();
char *local_addr = nullptr;
try {
ds_cap = env()->ram_session()->alloc(len);
local_addr = env()->rm_session()->attach(ds_cap);
file->read(local_addr, file->length(), 0);
env()->rm_session()->detach(local_addr);
} catch(...) {
env()->rm_session()->detach(local_addr);
env()->ram_session()->free(ds_cap);
return Dataspace_capability();
}
return ds_cap;
}
void release(char const *path, Dataspace_capability ds_cap) override {
env()->ram_session()->free(
static_cap_cast<Genode::Ram_dataspace>(ds_cap)); }
/************************
** File I/O interface **
************************/
Write_result write(Vfs_handle *vfs_handle,
char const *buf, file_size len,
Vfs::file_size &out) override
{
if (!(vfs_handle->status_flags() & (OPEN_MODE_WRONLY|OPEN_MODE_RDWR)))
return WRITE_ERR_INVALID;
Ram_vfs_handle const *handle =
static_cast<Ram_vfs_handle *>(vfs_handle);
Vfs_ram::Node::Guard guard(handle->file());
out = handle->file()->write(buf, len, handle->seek());
return WRITE_OK;
}
Read_result read(Vfs_handle *vfs_handle,
char *buf, file_size len,
file_size &out) override
{
if ((vfs_handle->status_flags() & OPEN_MODE_ACCMODE) == OPEN_MODE_WRONLY)
return READ_ERR_INVALID;
Ram_vfs_handle const *handle =
static_cast<Ram_vfs_handle *>(vfs_handle);
Vfs_ram::Node::Guard guard(handle->file());
out = handle->file()->read(buf, len, handle->seek());
return READ_OK;
}
Ftruncate_result ftruncate(Vfs_handle *vfs_handle, file_size len) override
{
if (!(vfs_handle->status_flags() & (OPEN_MODE_WRONLY|OPEN_MODE_RDWR)))
return FTRUNCATE_ERR_NO_PERM;
Ram_vfs_handle const *handle =
static_cast<Ram_vfs_handle *>(vfs_handle);
Vfs_ram::Node::Guard guard(handle->file());
handle->file()->truncate(len);
return FTRUNCATE_OK;
}
/***************************
** File_system interface **
***************************/
static char const *name() { return "ram"; }
};
#endif /* _INCLUDE__VFS__RAM_FILE_SYSTEM_H_ */