imag/libimagstore/src/store.rs

2066 lines
68 KiB
Rust

use std::collections::HashMap;
use std::fs::{File, remove_file};
use std::ops::Drop;
use std::path::PathBuf;
use std::result::Result as RResult;
use std::sync::Arc;
use std::sync::RwLock;
use std::collections::BTreeMap;
use std::io::{Seek, SeekFrom};
use std::convert::From;
use std::convert::Into;
use std::sync::Mutex;
use std::ops::Deref;
use std::ops::DerefMut;
use std::fmt::Formatter;
use std::fmt::Debug;
use std::fmt::Error as FMTError;
use toml::{Table, Value};
use regex::Regex;
use glob::glob;
use walkdir::WalkDir;
use walkdir::Iter as WalkDirIter;
use error::{ParserErrorKind, ParserError};
use error::{StoreError as SE, StoreErrorKind as SEK};
use error::MapErrInto;
use storeid::{IntoStoreId, StoreId, StoreIdIterator};
use lazyfile::LazyFile;
use hook::aspect::Aspect;
use hook::error::HookErrorKind;
use hook::result::HookResult;
use hook::accessor::{ MutableHookDataAccessor,
StoreIdAccessor};
use hook::position::HookPosition;
use hook::Hook;
use libimagerror::into::IntoError;
use self::glob_store_iter::*;
/// The Result Type returned by any interaction with the store that could fail
pub type Result<T> = RResult<T, SE>;
#[derive(Debug, PartialEq)]
enum StoreEntryStatus {
Present,
Borrowed
}
/// A store entry, depending on the option type it is either borrowed currently
/// or not.
#[derive(Debug)]
struct StoreEntry {
id: StoreId,
file: LazyFile,
status: StoreEntryStatus,
}
pub enum StoreObject {
Id(StoreId),
Collection(PathBuf),
}
pub struct Walk {
dirwalker: WalkDirIter,
}
impl Walk {
fn new(mut store_path: PathBuf, mod_name: &str) -> Walk {
store_path.push(mod_name);
Walk {
dirwalker: WalkDir::new(store_path).into_iter(),
}
}
}
impl ::std::ops::Deref for Walk {
type Target = WalkDirIter;
fn deref(&self) -> &Self::Target {
&self.dirwalker
}
}
impl Iterator for Walk {
type Item = StoreObject;
fn next(&mut self) -> Option<Self::Item> {
while let Some(something) = self.dirwalker.next() {
match something {
Ok(next) => if next.file_type().is_dir() {
return Some(StoreObject::Collection(next.path().to_path_buf()))
} else if next.file_type().is_file() {
return Some(StoreObject::Id(next.path().to_path_buf().into()))
},
Err(e) => {
warn!("Error in Walker");
debug!("{:?}", e);
return None;
}
}
}
return None;
}
}
impl StoreEntry {
fn new(id: StoreId) -> StoreEntry {
StoreEntry {
id: id.clone(),
file: LazyFile::Absent(id.into()),
status: StoreEntryStatus::Present,
}
}
/// The entry is currently borrowed, meaning that some thread is currently
/// mutating it
fn is_borrowed(&self) -> bool {
self.status == StoreEntryStatus::Borrowed
}
fn get_entry(&mut self) -> Result<Entry> {
if !self.is_borrowed() {
let file = self.file.get_file_mut();
if let Err(err) = file {
if err.err_type() == SEK::FileNotFound {
Ok(Entry::new(self.id.clone()))
} else {
Err(err)
}
} else {
// TODO:
let mut file = file.unwrap();
let entry = Entry::from_file(self.id.clone(), &mut file);
file.seek(SeekFrom::Start(0)).ok();
entry
}
} else {
Err(SE::new(SEK::EntryAlreadyBorrowed, None))
}
}
fn write_entry(&mut self, entry: &Entry) -> Result<()> {
if self.is_borrowed() {
use std::io::Write;
let file = try!(self.file.create_file());
assert_eq!(self.id, entry.location);
try!(file.set_len(0).map_err_into(SEK::FileError));
file.write_all(entry.to_str().as_bytes()).map_err_into(SEK::FileError)
} else {
Ok(())
}
}
}
/// The Store itself, through this object one can interact with IMAG's entries
pub struct Store {
location: PathBuf,
/**
* Configuration object of the store
*/
configuration: Option<Value>,
/*
* Registered hooks
*/
store_unload_aspects : Arc<Mutex<Vec<Aspect>>>,
pre_create_aspects : Arc<Mutex<Vec<Aspect>>>,
post_create_aspects : Arc<Mutex<Vec<Aspect>>>,
pre_retrieve_aspects : Arc<Mutex<Vec<Aspect>>>,
post_retrieve_aspects : Arc<Mutex<Vec<Aspect>>>,
pre_update_aspects : Arc<Mutex<Vec<Aspect>>>,
post_update_aspects : Arc<Mutex<Vec<Aspect>>>,
pre_delete_aspects : Arc<Mutex<Vec<Aspect>>>,
post_delete_aspects : Arc<Mutex<Vec<Aspect>>>,
pre_move_aspects : Arc<Mutex<Vec<Aspect>>>,
post_move_aspects : Arc<Mutex<Vec<Aspect>>>,
/**
* Internal Path->File cache map
*
* Caches the files, so they remain flock()ed
*
* Could be optimized for a threadsafe HashMap
*/
entries: Arc<RwLock<HashMap<StoreId, StoreEntry>>>,
}
impl Store {
/// Create a new Store object
pub fn new(location: PathBuf, store_config: Option<Value>) -> Result<Store> {
use std::fs::create_dir_all;
use configuration::*;
debug!("Validating Store configuration");
if !config_is_valid(&store_config) {
return Err(SE::new(SEK::ConfigurationError, None));
}
debug!("Building new Store object");
if !location.exists() {
debug!("Creating store path");
let c = create_dir_all(location.clone());
if c.is_err() {
debug!("Failed");
return Err(SEK::StorePathCreate.into_error_with_cause(Box::new(c.unwrap_err())));
}
} else if location.is_file() {
debug!("Store path exists as file");
return Err(SEK::StorePathExists.into_error());
}
let store_unload_aspects = get_store_unload_aspect_names(&store_config)
.into_iter().map(|n| {
let cfg = AspectConfig::get_for(&store_config, n.clone());
Aspect::new(n, cfg)
}).collect();
let pre_create_aspects = get_pre_create_aspect_names(&store_config)
.into_iter().map(|n| {
let cfg = AspectConfig::get_for(&store_config, n.clone());
Aspect::new(n, cfg)
}).collect();
let post_create_aspects = get_post_create_aspect_names(&store_config)
.into_iter().map(|n| {
let cfg = AspectConfig::get_for(&store_config, n.clone());
Aspect::new(n, cfg)
}).collect();
let pre_retrieve_aspects = get_pre_retrieve_aspect_names(&store_config)
.into_iter().map(|n| {
let cfg = AspectConfig::get_for(&store_config, n.clone());
Aspect::new(n, cfg)
}).collect();
let post_retrieve_aspects = get_post_retrieve_aspect_names(&store_config)
.into_iter().map(|n| {
let cfg = AspectConfig::get_for(&store_config, n.clone());
Aspect::new(n, cfg)
}).collect();
let pre_update_aspects = get_pre_update_aspect_names(&store_config)
.into_iter().map(|n| {
let cfg = AspectConfig::get_for(&store_config, n.clone());
Aspect::new(n, cfg)
}).collect();
let post_update_aspects = get_post_update_aspect_names(&store_config)
.into_iter().map(|n| {
let cfg = AspectConfig::get_for(&store_config, n.clone());
Aspect::new(n, cfg)
}).collect();
let pre_delete_aspects = get_pre_delete_aspect_names(&store_config)
.into_iter().map(|n| {
let cfg = AspectConfig::get_for(&store_config, n.clone());
Aspect::new(n, cfg)
}).collect();
let post_delete_aspects = get_post_delete_aspect_names(&store_config)
.into_iter().map(|n| {
let cfg = AspectConfig::get_for(&store_config, n.clone());
Aspect::new(n, cfg)
}).collect();
let pre_move_aspects = get_pre_move_aspect_names(&store_config)
.into_iter().map(|n| {
let cfg = AspectConfig::get_for(&store_config, n.clone());
Aspect::new(n, cfg)
}).collect();
let post_move_aspects = get_post_move_aspect_names(&store_config)
.into_iter().map(|n| {
let cfg = AspectConfig::get_for(&store_config, n.clone());
Aspect::new(n, cfg)
}).collect();
let store = Store {
location: location.clone(),
configuration: store_config,
store_unload_aspects : Arc::new(Mutex::new(store_unload_aspects)),
pre_create_aspects : Arc::new(Mutex::new(pre_create_aspects)),
post_create_aspects : Arc::new(Mutex::new(post_create_aspects)),
pre_retrieve_aspects : Arc::new(Mutex::new(pre_retrieve_aspects)),
post_retrieve_aspects : Arc::new(Mutex::new(post_retrieve_aspects)),
pre_update_aspects : Arc::new(Mutex::new(pre_update_aspects)),
post_update_aspects : Arc::new(Mutex::new(post_update_aspects)),
pre_delete_aspects : Arc::new(Mutex::new(pre_delete_aspects)),
post_delete_aspects : Arc::new(Mutex::new(post_delete_aspects)),
pre_move_aspects : Arc::new(Mutex::new(pre_move_aspects)),
post_move_aspects : Arc::new(Mutex::new(post_move_aspects)),
entries: Arc::new(RwLock::new(HashMap::new())),
};
debug!("Store building succeeded");
Ok(store)
}
/// Get the store configuration
pub fn config(&self) -> Option<&Value> {
self.configuration.as_ref()
}
/// Creates the Entry at the given location (inside the entry)
pub fn create<'a, S: IntoStoreId>(&'a self, id: S) -> Result<FileLockEntry<'a>> {
let id = id.into_storeid().storified(self);
if let Err(e) = self.execute_hooks_for_id(self.pre_create_aspects.clone(), &id) {
return Err(e)
.map_err_into(SEK::PreHookExecuteError)
.map_err_into(SEK::CreateCallError)
}
let mut hsmap = match self.entries.write() {
Err(_) => return Err(SEK::LockPoisoned.into_error()).map_err_into(SEK::CreateCallError),
Ok(s) => s,
};
if hsmap.contains_key(&id) {
return Err(SEK::EntryAlreadyExists.into_error()).map_err_into(SEK::CreateCallError);
}
hsmap.insert(id.clone(), {
let mut se = StoreEntry::new(id.clone());
se.status = StoreEntryStatus::Borrowed;
se
});
let mut fle = FileLockEntry::new(self, Entry::new(id));
self.execute_hooks_for_mut_file(self.post_create_aspects.clone(), &mut fle)
.map_err_into(SEK::PostHookExecuteError)
.map(|_| fle)
.map_err_into(SEK::CreateCallError)
}
/// Borrow a given Entry. When the `FileLockEntry` is either `update`d or
/// dropped, the new Entry is written to disk
///
/// Implicitely creates a entry in the store if there is no entry with the id `id`. For a
/// non-implicitely-create look at `Store::get`.
pub fn retrieve<'a, S: IntoStoreId>(&'a self, id: S) -> Result<FileLockEntry<'a>> {
let id = id.into_storeid().storified(self);
if let Err(e) = self.execute_hooks_for_id(self.pre_retrieve_aspects.clone(), &id) {
return Err(e)
.map_err_into(SEK::PreHookExecuteError)
.map_err_into(SEK::RetrieveCallError)
}
self.entries
.write()
.map_err(|_| SE::new(SEK::LockPoisoned, None))
.and_then(|mut es| {
let mut se = es.entry(id.clone()).or_insert_with(|| StoreEntry::new(id.clone()));
let entry = se.get_entry();
se.status = StoreEntryStatus::Borrowed;
entry
})
.map(|e| FileLockEntry::new(self, e))
.and_then(|mut fle| {
self.execute_hooks_for_mut_file(self.post_retrieve_aspects.clone(), &mut fle)
.map_err_into(SEK::HookExecutionError)
.and(Ok(fle))
})
.map_err_into(SEK::RetrieveCallError)
}
/// Get an entry from the store if it exists.
///
/// This executes the {pre,post}_retrieve_aspects hooks.
pub fn get<'a, S: IntoStoreId + Clone>(&'a self, id: S) -> Result<Option<FileLockEntry<'a>>> {
if !id.clone().into_storeid().storified(self).exists() {
debug!("Does not exist: {:?}", id.clone().into_storeid());
return Ok(None);
}
self.retrieve(id).map(Some).map_err_into(SEK::GetCallError)
}
/// Same as `Store::get()` but also tries older versions of the entry, returning an iterator
/// over all versions of the entry.
pub fn get_all_versions<'a, S: IntoStoreId>(&'a self, id: S) -> Result<StoreIdIterator>
{
// get PathBuf component from storeid, but not version component
fn path_component<S: IntoStoreId>(id: S) -> Result<PathBuf> {
let p : PathBuf = id.into_storeid().into();
match p.to_str() {
Some(s) => {
let mut split = s.split("~");
let path_element = match split.next() {
Some(s) => s,
None => return Err(SE::new(SEK::StorePathError, None))
.map_err_into(SEK::GetAllVersionsCallError),
};
Ok(PathBuf::from(path_element))
},
None => Err(SE::new(SEK::StorePathError, None))
.map_err_into(SEK::GetAllVersionsCallError),
}
}
fn build_glob_pattern(mut pb: PathBuf) -> Option<String> {
pb.push("~*.*.*");
pb.to_str().map(String::from)
}
match path_component(id).map(build_glob_pattern) {
Err(e) => Err(SEK::StorePathError.into_error_with_cause(Box::new(e)))
.map_err_into(SEK::GetAllVersionsCallError),
Ok(None) => Err(SE::new(SEK::StorePathError, None))
.map_err_into(SEK::GetAllVersionsCallError),
Ok(Some(pattern)) => {
glob(&pattern[..])
.map(|paths| GlobStoreIdIterator::new(paths).into())
.map_err_into(SEK::GlobError)
.map_err_into(SEK::GetAllVersionsCallError)
}
}
}
/// Iterate over all StoreIds for one module name
pub fn retrieve_for_module(&self, mod_name: &str) -> Result<StoreIdIterator> {
let mut path = self.path().clone();
path.push(mod_name);
path.to_str()
.ok_or(SE::new(SEK::EncodingError, None))
.and_then(|path| {
let path = [ path, "/**/*" ].join("");
debug!("glob()ing with '{}'", path);
glob(&path[..]).map_err_into(SEK::GlobError)
})
.map(|paths| GlobStoreIdIterator::new(paths).into())
.map_err_into(SEK::GlobError)
.map_err_into(SEK::RetrieveForModuleCallError)
}
// Walk the store tree for the module
pub fn walk<'a>(&'a self, mod_name: &str) -> Walk {
Walk::new(self.path().clone(), mod_name)
}
/// Return the `FileLockEntry` and write to disk
pub fn update<'a>(&'a self, mut entry: FileLockEntry<'a>) -> Result<()> {
if let Err(e) = self.execute_hooks_for_mut_file(self.pre_update_aspects.clone(), &mut entry) {
return Err(e)
.map_err_into(SEK::PreHookExecuteError)
.map_err_into(SEK::UpdateCallError);
}
if let Err(e) = self._update(&entry) {
return Err(e).map_err_into(SEK::UpdateCallError);
}
self.execute_hooks_for_mut_file(self.post_update_aspects.clone(), &mut entry)
.map_err_into(SEK::PreHookExecuteError)
.map_err_into(SEK::UpdateCallError)
}
/// Internal method to write to the filesystem store.
///
/// # Assumptions
/// This method assumes that entry is dropped _right after_ the call, hence
/// it is not public.
fn _update<'a>(&'a self, entry: &FileLockEntry<'a>) -> Result<()> {
let mut hsmap = match self.entries.write() {
Err(_) => return Err(SE::new(SEK::LockPoisoned, None)),
Ok(e) => e,
};
let mut se = try!(hsmap.get_mut(&entry.location).ok_or(SE::new(SEK::IdNotFound, None)));
assert!(se.is_borrowed(), "Tried to update a non borrowed entry.");
debug!("Verifying Entry");
try!(entry.entry.verify());
debug!("Writing Entry");
try!(se.write_entry(&entry.entry));
se.status = StoreEntryStatus::Present;
Ok(())
}
/// Retrieve a copy of a given entry, this cannot be used to mutate
/// the one on disk
pub fn retrieve_copy<S: IntoStoreId>(&self, id: S) -> Result<Entry> {
let id = id.into_storeid().storified(self);
let entries = match self.entries.write() {
Err(_) => {
return Err(SE::new(SEK::LockPoisoned, None))
.map_err_into(SEK::RetrieveCopyCallError);
},
Ok(e) => e,
};
// if the entry is currently modified by the user, we cannot drop it
if entries.get(&id).map(|e| e.is_borrowed()).unwrap_or(false) {
return Err(SE::new(SEK::IdLocked, None)).map_err_into(SEK::RetrieveCopyCallError);
}
StoreEntry::new(id).get_entry()
}
/// Delete an entry
pub fn delete<S: IntoStoreId>(&self, id: S) -> Result<()> {
let id = id.into_storeid().storified(self);
if let Err(e) = self.execute_hooks_for_id(self.pre_delete_aspects.clone(), &id) {
return Err(e)
.map_err_into(SEK::PreHookExecuteError)
.map_err_into(SEK::DeleteCallError)
}
let mut entries = match self.entries.write() {
Err(_) => return Err(SE::new(SEK::LockPoisoned, None))
.map_err_into(SEK::DeleteCallError),
Ok(e) => e,
};
// if the entry is currently modified by the user, we cannot drop it
if entries.get(&id).map(|e| e.is_borrowed()).unwrap_or(false) {
return Err(SE::new(SEK::IdLocked, None))
.map_err_into(SEK::DeleteCallError);
}
// remove the entry first, then the file
entries.remove(&id);
if let Err(e) = remove_file(&id) {
return Err(SEK::FileError.into_error_with_cause(Box::new(e)))
.map_err_into(SEK::DeleteCallError);
}
self.execute_hooks_for_id(self.post_delete_aspects.clone(), &id)
.map_err_into(SEK::PreHookExecuteError)
.map_err_into(SEK::DeleteCallError)
}
/// Save a copy of the Entry in another place
/// Executes the post_move_aspects for the new id
pub fn save_to(&self, entry: &FileLockEntry, new_id: StoreId) -> Result<()> {
self.save_to_other_location(entry, new_id, false)
}
/// Save an Entry in another place
/// Removes the original entry
/// Executes the post_move_aspects for the new id
pub fn save_as(&self, entry: FileLockEntry, new_id: StoreId) -> Result<()> {
self.save_to_other_location(&entry, new_id, true)
}
fn save_to_other_location(&self, entry: &FileLockEntry, new_id: StoreId, remove_old: bool)
-> Result<()>
{
use std::fs::copy;
use std::fs::remove_file;
let new_id = new_id.storified(self);
let hsmap = self.entries.write();
if hsmap.is_err() {
return Err(SE::new(SEK::LockPoisoned, None)).map_err_into(SEK::MoveCallError)
}
if hsmap.unwrap().contains_key(&new_id) {
return Err(SE::new(SEK::EntryAlreadyExists, None)).map_err_into(SEK::MoveCallError)
}
let old_id = entry.get_location().clone();
copy(old_id.clone(), new_id.clone())
.and_then(|_| {
if remove_old {
remove_file(old_id)
} else {
Ok(())
}
})
.map_err_into(SEK::FileError)
.and_then(|_| self.execute_hooks_for_id(self.post_move_aspects.clone(), &new_id)
.map_err_into(SEK::PostHookExecuteError))
.map_err_into(SEK::MoveCallError)
}
/// Move an entry without loading
pub fn move_by_id(&self, old_id: StoreId, new_id: StoreId) -> Result<()> {
use std::fs::rename;
let new_id = new_id.storified(self);
let old_id = old_id.storified(self);
if let Err(e) = self.execute_hooks_for_id(self.pre_move_aspects.clone(), &old_id) {
return Err(e)
.map_err_into(SEK::PreHookExecuteError)
.map_err_into(SEK::MoveByIdCallError)
}
let hsmap = self.entries.write();
if hsmap.is_err() {
return Err(SE::new(SEK::LockPoisoned, None))
}
if hsmap.unwrap().contains_key(&old_id) {
return Err(SE::new(SEK::EntryAlreadyBorrowed, None));
} else {
match rename(old_id, new_id.clone()) {
Err(e) => return Err(SEK::EntryRenameError.into_error_with_cause(Box::new(e))),
_ => {
debug!("Rename worked");
},
}
}
self.execute_hooks_for_id(self.pre_move_aspects.clone(), &new_id)
.map_err_into(SEK::PostHookExecuteError)
.map_err_into(SEK::MoveByIdCallError)
}
/// Gets the path where this store is on the disk
pub fn path(&self) -> &PathBuf {
&self.location
}
pub fn register_hook(&mut self,
position: HookPosition,
aspect_name: &str,
mut h: Box<Hook>)
-> Result<()>
{
debug!("Registering hook: {:?}", h);
debug!(" in position: {:?}", position);
debug!(" with aspect: {:?}", aspect_name);
let guard = match position {
HookPosition::StoreUnload => self.store_unload_aspects.clone(),
HookPosition::PreCreate => self.pre_create_aspects.clone(),
HookPosition::PostCreate => self.post_create_aspects.clone(),
HookPosition::PreRetrieve => self.pre_retrieve_aspects.clone(),
HookPosition::PostRetrieve => self.post_retrieve_aspects.clone(),
HookPosition::PreUpdate => self.pre_update_aspects.clone(),
HookPosition::PostUpdate => self.post_update_aspects.clone(),
HookPosition::PreDelete => self.pre_delete_aspects.clone(),
HookPosition::PostDelete => self.post_delete_aspects.clone(),
};
let mut guard = match guard.deref().lock().map_err(|_| SE::new(SEK::LockError, None)) {
Err(e) => return Err(SEK::HookRegisterError.into_error_with_cause(Box::new(e))),
Ok(g) => g,
};
for mut aspect in guard.deref_mut() {
if aspect.name().clone() == aspect_name.clone() {
self.get_config_for_hook(h.name()).map(|config| h.set_config(config));
aspect.register_hook(h);
return Ok(());
}
}
let annfe = SEK::AspectNameNotFoundError.into_error();
Err(SEK::HookRegisterError.into_error_with_cause(Box::new(annfe)))
}
fn get_config_for_hook(&self, name: &str) -> Option<&Value> {
match self.configuration {
Some(Value::Table(ref tabl)) => {
tabl.get("hooks")
.map(|hook_section| {
match *hook_section {
Value::Table(ref tabl) => tabl.get(name),
_ => None
}
})
.unwrap_or(None)
},
_ => None,
}
}
fn execute_hooks_for_id(&self,
aspects: Arc<Mutex<Vec<Aspect>>>,
id: &StoreId)
-> HookResult<()>
{
match aspects.lock() {
Err(_) => return Err(HookErrorKind::HookExecutionError.into()),
Ok(g) => g
}.iter().fold(Ok(()), |acc, aspect| {
debug!("[Aspect][exec]: {:?}", aspect);
acc.and_then(|_| (aspect as &StoreIdAccessor).access(id))
}).map_err(Box::new).map_err(|e| HookErrorKind::HookExecutionError.into_error_with_cause(e))
}
fn execute_hooks_for_mut_file(&self,
aspects: Arc<Mutex<Vec<Aspect>>>,
fle: &mut FileLockEntry)
-> HookResult<()>
{
match aspects.lock() {
Err(_) => return Err(HookErrorKind::HookExecutionError.into()),
Ok(g) => g
}.iter().fold(Ok(()), |acc, aspect| {
debug!("[Aspect][exec]: {:?}", aspect);
acc.and_then(|_| aspect.access_mut(fle))
}).map_err(Box::new).map_err(|e| HookErrorKind::HookExecutionError.into_error_with_cause(e))
}
}
impl Debug for Store {
fn fmt(&self, fmt: &mut Formatter) -> RResult<(), FMTError> {
try!(write!(fmt, " --- Store ---\n"));
try!(write!(fmt, "\n"));
try!(write!(fmt, " - location : {:?}\n", self.location));
try!(write!(fmt, " - configuration : {:?}\n", self.configuration));
try!(write!(fmt, " - pre_create_aspects : {:?}\n", self.pre_create_aspects ));
try!(write!(fmt, " - post_create_aspects : {:?}\n", self.post_create_aspects ));
try!(write!(fmt, " - pre_retrieve_aspects : {:?}\n", self.pre_retrieve_aspects ));
try!(write!(fmt, " - post_retrieve_aspects : {:?}\n", self.post_retrieve_aspects ));
try!(write!(fmt, " - pre_update_aspects : {:?}\n", self.pre_update_aspects ));
try!(write!(fmt, " - post_update_aspects : {:?}\n", self.post_update_aspects ));
try!(write!(fmt, " - pre_delete_aspects : {:?}\n", self.pre_delete_aspects ));
try!(write!(fmt, " - post_delete_aspects : {:?}\n", self.post_delete_aspects ));
try!(write!(fmt, "\n"));
try!(write!(fmt, "Entries:\n"));
try!(write!(fmt, "{:?}", self.entries));
try!(write!(fmt, "\n"));
Ok(())
}
}
impl Drop for Store {
/**
* Unlock all files on drop
*
* TODO: Unlock them
*/
fn drop(&mut self) {
let store_id = StoreId::from(self.location.clone());
if let Err(e) = self.execute_hooks_for_id(self.store_unload_aspects.clone(), &store_id) {
debug!("Store-load hooks execution failed. Cannot create store object.");
warn!("Store Unload Hook error: {:?}", e);
}
debug!("Dropping store");
}
}
/// A struct that allows you to borrow an Entry
#[derive(Debug)]
pub struct FileLockEntry<'a> {
store: &'a Store,
entry: Entry,
}
impl<'a> FileLockEntry<'a, > {
fn new(store: &'a Store, entry: Entry) -> FileLockEntry<'a> {
FileLockEntry {
store: store,
entry: entry,
}
}
}
impl<'a> Deref for FileLockEntry<'a> {
type Target = Entry;
fn deref(&self) -> &Self::Target {
&self.entry
}
}
impl<'a> DerefMut for FileLockEntry<'a> {
fn deref_mut(&mut self) -> &mut Self::Target {
&mut self.entry
}
}
impl<'a> Drop for FileLockEntry<'a> {
/// This will silently ignore errors, use `Store::update` if you want to catch the errors
fn drop(&mut self) {
let _ = self.store._update(self);
}
}
/// `EntryContent` type
pub type EntryContent = String;
/// `EntryHeader`
///
/// This is basically a wrapper around `toml::Table` which provides convenience to the user of the
/// library.
#[derive(Debug, Clone)]
pub struct EntryHeader {
header: Value,
}
pub type EntryResult<V> = RResult<V, ParserError>;
#[derive(Debug, Clone, PartialEq, Eq)]
enum Token {
Key(String),
Index(usize),
}
/**
* Wrapper type around file header (TOML) object
*/
impl EntryHeader {
pub fn new() -> EntryHeader {
EntryHeader {
header: build_default_header()
}
}
pub fn header(&self) -> &Value {
&self.header
}
fn from_table(t: Table) -> EntryHeader {
EntryHeader {
header: Value::Table(t)
}
}
pub fn parse(s: &str) -> EntryResult<EntryHeader> {
use toml::Parser;
let mut parser = Parser::new(s);
parser.parse()
.ok_or(ParserErrorKind::TOMLParserErrors.into())
.and_then(verify_header_consistency)
.map(EntryHeader::from_table)
}
pub fn verify(&self) -> Result<()> {
match self.header {
Value::Table(ref t) => verify_header(&t),
_ => Err(SE::new(SEK::HeaderTypeFailure, None)),
}
}
/**
* Insert a header field by a string-spec
*
* ```ignore
* insert("something.in.a.field", Boolean(true));
* ```
*
* If an array field was accessed which is _out of bounds_ of the array available, the element
* is appended to the array.
*
* Inserts a Boolean in the section "something" -> "in" -> "a" -> "field"
* A JSON equivalent would be
*
* {
* something: {
* in: {
* a: {
* field: true
* }
* }
* }
* }
*
* Returns true if header field was set, false if there is already a value
*/
pub fn insert(&mut self, spec: &str, v: Value) -> Result<bool> {
self.insert_with_sep(spec, '.', v)
}
pub fn insert_with_sep(&mut self, spec: &str, sep: char, v: Value) -> Result<bool> {
let tokens = match EntryHeader::tokenize(spec, sep) {
Err(e) => return Err(e),
Ok(t) => t
};
let destination = match tokens.iter().last() {
None => return Err(SE::new(SEK::HeaderPathSyntaxError, None)),
Some(d) => d,
};
let path_to_dest = tokens[..(tokens.len() - 1)].into(); // N - 1 tokens
// walk N-1 tokens
let value = match EntryHeader::walk_header(&mut self.header, path_to_dest) {
Err(e) => return Err(e),
Ok(v) => v
};
// There is already an value at this place
if EntryHeader::extract(value, destination).is_ok() {
return Ok(false);
}
match *destination {
Token::Key(ref s) => { // if the destination shall be an map key
match *value {
/*
* Put it in there if we have a map
*/
Value::Table(ref mut t) => {
t.insert(s.clone(), v);
}
/*
* Fail if there is no map here
*/
_ => return Err(SE::new(SEK::HeaderPathTypeFailure, None)),
}
},
Token::Index(i) => { // if the destination shall be an array
match *value {
/*
* Put it in there if we have an array
*/
Value::Array(ref mut a) => {
a.push(v); // push to the end of the array
// if the index is inside the array, we swap-remove the element at this
// index
if a.len() < i {
a.swap_remove(i);
}
},
/*
* Fail if there is no array here
*/
_ => return Err(SE::new(SEK::HeaderPathTypeFailure, None)),
}
},
}
Ok(true)
}
/**
* Set a header field by a string-spec
*
* ```ignore
* set("something.in.a.field", Boolean(true));
* ```
*
* Sets a Boolean in the section "something" -> "in" -> "a" -> "field"
* A JSON equivalent would be
*
* {
* something: {
* in: {
* a: {
* field: true
* }
* }
* }
* }
*
* If there is already a value at this place, this value will be overridden and the old value
* will be returned
*/
pub fn set(&mut self, spec: &str, v: Value) -> Result<Option<Value>> {
self.set_with_sep(spec, '.', v)
}
pub fn set_with_sep(&mut self, spec: &str, sep: char, v: Value) -> Result<Option<Value>> {
let tokens = match EntryHeader::tokenize(spec, sep) {
Err(e) => return Err(e),
Ok(t) => t,
};
debug!("tokens = {:?}", tokens);
let destination = match tokens.iter().last() {
None => return Err(SE::new(SEK::HeaderPathSyntaxError, None)),
Some(d) => d
};
debug!("destination = {:?}", destination);
let path_to_dest = tokens[..(tokens.len() - 1)].into(); // N - 1 tokens
// walk N-1 tokens
let value = match EntryHeader::walk_header(&mut self.header, path_to_dest) {
Err(e) => return Err(e),
Ok(v) => v
};
debug!("walked value = {:?}", value);
match *destination {
Token::Key(ref s) => { // if the destination shall be an map key->value
match *value {
/*
* Put it in there if we have a map
*/
Value::Table(ref mut t) => {
debug!("Matched Key->Table");
return Ok(t.insert(s.clone(), v));
}
/*
* Fail if there is no map here
*/
_ => {
debug!("Matched Key->NON-Table");
return Err(SE::new(SEK::HeaderPathTypeFailure, None));
}
}
},
Token::Index(i) => { // if the destination shall be an array
match *value {
/*
* Put it in there if we have an array
*/
Value::Array(ref mut a) => {
debug!("Matched Index->Array");
a.push(v); // push to the end of the array
// if the index is inside the array, we swap-remove the element at this
// index
if a.len() > i {
debug!("Swap-Removing in Array {:?}[{:?}] <- {:?}", a, i, a[a.len()-1]);
return Ok(Some(a.swap_remove(i)));
}
debug!("Appended");
return Ok(None);
},
/*
* Fail if there is no array here
*/
_ => {
debug!("Matched Index->NON-Array");
return Err(SE::new(SEK::HeaderPathTypeFailure, None));
},
}
},
}
Ok(None)
}
/**
* Read a header field by a string-spec
*
* ```ignore
* let value = read("something.in.a.field");
* ```
*
* Reads a Value in the section "something" -> "in" -> "a" -> "field"
* A JSON equivalent would be
*
* {
* something: {
* in: {
* a: {
* field: true
* }
* }
* }
* }
*
* If there is no a value at this place, None will be returned. This also holds true for Arrays
* which are accessed at an index which is not yet there, even if the accessed index is much
* larger than the array length.
*/
pub fn read(&self, spec: &str) -> Result<Option<Value>> {
self.read_with_sep(spec, '.')
}
pub fn read_with_sep(&self, spec: &str, splitchr: char) -> Result<Option<Value>> {
let tokens = match EntryHeader::tokenize(spec, splitchr) {
Err(e) => return Err(e),
Ok(t) => t,
};
let mut header_clone = self.header.clone(); // we clone as READing is simpler this way
// walk N-1 tokens
match EntryHeader::walk_header(&mut header_clone, tokens) {
Err(e) => match e.err_type() {
// We cannot find the header key, as there is no path to it
SEK::HeaderKeyNotFound => Ok(None),
_ => Err(e),
},
Ok(v) => Ok(Some(v.clone())),
}
}
pub fn delete(&mut self, spec: &str) -> Result<Option<Value>> {
let tokens = match EntryHeader::tokenize(spec, '.') {
Err(e) => return Err(e),
Ok(t) => t
};
let destination = match tokens.iter().last() {
None => return Err(SE::new(SEK::HeaderPathSyntaxError, None)),
Some(d) => d
};
debug!("destination = {:?}", destination);
let path_to_dest = tokens[..(tokens.len() - 1)].into(); // N - 1 tokens
// walk N-1 tokens
let mut value = match EntryHeader::walk_header(&mut self.header, path_to_dest) {
Err(e) => return Err(e),
Ok(v) => v
};
debug!("walked value = {:?}", value);
match *destination {
Token::Key(ref s) => { // if the destination shall be an map key->value
match *value {
Value::Table(ref mut t) => {
debug!("Matched Key->Table, removing {:?}", s);
return Ok(t.remove(s));
},
_ => {
debug!("Matched Key->NON-Table");
return Err(SE::new(SEK::HeaderPathTypeFailure, None));
}
}
},
Token::Index(i) => { // if the destination shall be an array
match *value {
Value::Array(ref mut a) => {
// if the index is inside the array, we swap-remove the element at this
// index
if a.len() > i {
debug!("Removing in Array {:?}[{:?}]", a, i);
return Ok(Some(a.remove(i)));
} else {
return Ok(None);
}
},
_ => {
debug!("Matched Index->NON-Array");
return Err(SE::new(SEK::HeaderPathTypeFailure, None));
},
}
},
}
Ok(None)
}
fn tokenize(spec: &str, splitchr: char) -> Result<Vec<Token>> {
use std::str::FromStr;
spec.split(splitchr)
.map(|s| {
usize::from_str(s)
.map(Token::Index)
.or_else(|_| Ok(Token::Key(String::from(s))))
})
.collect()
}
fn walk_header(v: &mut Value, tokens: Vec<Token>) -> Result<&mut Value> {
use std::vec::IntoIter;
fn walk_iter<'a>(v: Result<&'a mut Value>, i: &mut IntoIter<Token>) -> Result<&'a mut Value> {
let next = i.next();
v.and_then(move |value| {
if let Some(token) = next {
walk_iter(EntryHeader::extract(value, &token), i)
} else {
Ok(value)
}
})
}
walk_iter(Ok(v), &mut tokens.into_iter())
}
fn extract_from_table<'a>(v: &'a mut Value, s: &str) -> Result<&'a mut Value> {
match *v {
Value::Table(ref mut t) => {
t.get_mut(&s[..])
.ok_or(SE::new(SEK::HeaderKeyNotFound, None))
},
_ => Err(SE::new(SEK::HeaderPathTypeFailure, None)),
}
}
fn extract_from_array(v: &mut Value, i: usize) -> Result<&mut Value> {
match *v {
Value::Array(ref mut a) => {
if a.len() < i {
Err(SE::new(SEK::HeaderKeyNotFound, None))
} else {
Ok(&mut a[i])
}
},
_ => Err(SE::new(SEK::HeaderPathTypeFailure, None)),
}
}
fn extract<'a>(v: &'a mut Value, token: &Token) -> Result<&'a mut Value> {
match *token {
Token::Key(ref s) => EntryHeader::extract_from_table(v, s),
Token::Index(i) => EntryHeader::extract_from_array(v, i),
}
}
}
impl Into<Table> for EntryHeader {
fn into(self) -> Table {
match self.header {
Value::Table(t) => t,
_ => panic!("EntryHeader is not a table!"),
}
}
}
impl From<Table> for EntryHeader {
fn from(t: Table) -> EntryHeader {
EntryHeader { header: Value::Table(t) }
}
}
fn build_default_header() -> Value { // BTreeMap<String, Value>
let mut m = BTreeMap::new();
m.insert(String::from("imag"), {
let mut imag_map = BTreeMap::<String, Value>::new();
imag_map.insert(String::from("version"), Value::String(String::from(version!())));
imag_map.insert(String::from("links"), Value::Array(vec![]));
Value::Table(imag_map)
});
Value::Table(m)
}
fn verify_header(t: &Table) -> Result<()> {
if !has_main_section(t) {
Err(SE::from(ParserErrorKind::MissingMainSection.into_error()))
} else if !has_imag_version_in_main_section(t) {
Err(SE::from(ParserErrorKind::MissingVersionInfo.into_error()))
} else if !has_only_tables(t) {
debug!("Could not verify that it only has tables in its base table");
Err(SE::from(ParserErrorKind::NonTableInBaseTable.into_error()))
} else {
Ok(())
}
}
fn verify_header_consistency(t: Table) -> EntryResult<Table> {
verify_header(&t)
.map_err(Box::new)
.map_err(|e| ParserErrorKind::HeaderInconsistency.into_error_with_cause(e))
.map(|_| t)
}
fn has_only_tables(t: &Table) -> bool {
debug!("Verifying that table has only tables");
t.iter().all(|(_, x)| if let Value::Table(_) = *x { true } else { false })
}
fn has_main_section(t: &Table) -> bool {
t.contains_key("imag") &&
match t.get("imag") {
Some(&Value::Table(_)) => true,
Some(_) => false,
None => false,
}
}
fn has_imag_version_in_main_section(t: &Table) -> bool {
use semver::Version;
match *t.get("imag").unwrap() {
Value::Table(ref sec) => {
sec.get("version")
.and_then(|v| {
match *v {
Value::String(ref s) => Some(Version::parse(&s[..]).is_ok()),
_ => Some(false),
}
})
.unwrap_or(false)
}
_ => false,
}
}
/**
* An Entry of the store
*
* Contains location, header and content part.
*/
#[derive(Debug, Clone)]
pub struct Entry {
location: StoreId,
header: EntryHeader,
content: EntryContent,
}
impl Entry {
pub fn new(loc: StoreId) -> Entry {
Entry {
location: loc,
header: EntryHeader::new(),
content: EntryContent::new()
}
}
pub fn from_file<S: IntoStoreId>(loc: S, file: &mut File) -> Result<Entry> {
let text = {
use std::io::Read;
let mut s = String::new();
try!(file.read_to_string(&mut s));
s
};
Self::from_str(loc, &text[..])
}
pub fn from_str<S: IntoStoreId>(loc: S, s: &str) -> Result<Entry> {
debug!("Building entry from string");
lazy_static! {
static ref RE: Regex = Regex::new(r"(?smx)
^---$
(?P<header>.*) # Header
^---$\n
(?P<content>.*) # Content
").unwrap();
}
let matches = match RE.captures(s) {
None => return Err(SE::new(SEK::MalformedEntry, None)),
Some(s) => s,
};
let header = match matches.name("header") {
None => return Err(SE::new(SEK::MalformedEntry, None)),
Some(s) => s
};
let content = matches.name("content").unwrap_or("");
debug!("Header and content found. Yay! Building Entry object now");
Ok(Entry {
location: loc.into_storeid(),
header: try!(EntryHeader::parse(header)),
content: content.into(),
})
}
pub fn to_str(&self) -> String {
format!("---{header}---\n{content}",
header = ::toml::encode_str(&self.header.header),
content = self.content)
}
pub fn get_location(&self) -> &StoreId {
&self.location
}
pub fn get_header(&self) -> &EntryHeader {
&self.header
}
pub fn get_header_mut(&mut self) -> &mut EntryHeader {
&mut self.header
}
pub fn get_content(&self) -> &EntryContent {
&self.content
}
pub fn get_content_mut(&mut self) -> &mut EntryContent {
&mut self.content
}
pub fn verify(&self) -> Result<()> {
self.header.verify()
}
}
mod glob_store_iter {
use std::fmt::{Debug, Formatter};
use std::fmt::Error as FmtError;
use glob::Paths;
use storeid::StoreId;
use storeid::StoreIdIterator;
pub struct GlobStoreIdIterator {
paths: Paths,
}
impl Debug for GlobStoreIdIterator {
fn fmt(&self, fmt: &mut Formatter) -> Result<(), FmtError> {
write!(fmt, "GlobStoreIdIterator")
}
}
impl Into<StoreIdIterator> for GlobStoreIdIterator {
fn into(self) -> StoreIdIterator {
StoreIdIterator::new(Box::new(self))
}
}
impl GlobStoreIdIterator {
pub fn new(paths: Paths) -> GlobStoreIdIterator {
GlobStoreIdIterator {
paths: paths,
}
}
}
impl Iterator for GlobStoreIdIterator {
type Item = StoreId;
fn next(&mut self) -> Option<StoreId> {
self.paths.next().and_then(|o| {
match o {
Ok(o) => Some(o),
Err(e) => {
debug!("GlobStoreIdIterator error: {:?}", e);
None
},
}
}).map(|p| StoreId::from(p))
}
}
}
#[cfg(test)]
mod test {
extern crate env_logger;
use std::collections::BTreeMap;
use super::EntryHeader;
use super::Token;
use toml::Value;
#[test]
fn test_imag_section() {
use super::has_main_section;
let mut map = BTreeMap::new();
map.insert("imag".into(), Value::Table(BTreeMap::new()));
assert!(has_main_section(&map));
}
#[test]
fn test_imag_invalid_section_type() {
use super::has_main_section;
let mut map = BTreeMap::new();
map.insert("imag".into(), Value::Boolean(false));
assert!(!has_main_section(&map));
}
#[test]
fn test_imag_abscent_main_section() {
use super::has_main_section;
let mut map = BTreeMap::new();
map.insert("not_imag".into(), Value::Boolean(false));
assert!(!has_main_section(&map));
}
#[test]
fn test_main_section_without_version() {
use super::has_imag_version_in_main_section;
let mut map = BTreeMap::new();
map.insert("imag".into(), Value::Table(BTreeMap::new()));
assert!(!has_imag_version_in_main_section(&map));
}
#[test]
fn test_main_section_with_version() {
use super::has_imag_version_in_main_section;
let mut map = BTreeMap::new();
let mut sub = BTreeMap::new();
sub.insert("version".into(), Value::String("0.0.0".into()));
map.insert("imag".into(), Value::Table(sub));
assert!(has_imag_version_in_main_section(&map));
}
#[test]
fn test_main_section_with_version_in_wrong_type() {
use super::has_imag_version_in_main_section;
let mut map = BTreeMap::new();
let mut sub = BTreeMap::new();
sub.insert("version".into(), Value::Boolean(false));
map.insert("imag".into(), Value::Table(sub));
assert!(!has_imag_version_in_main_section(&map));
}
#[test]
fn test_verification_good() {
use super::verify_header_consistency;
let mut header = BTreeMap::new();
let sub = {
let mut sub = BTreeMap::new();
sub.insert("version".into(), Value::String(String::from("0.0.0")));
Value::Table(sub)
};
header.insert("imag".into(), sub);
assert!(verify_header_consistency(header).is_ok());
}
#[test]
fn test_verification_invalid_versionstring() {
use super::verify_header_consistency;
let mut header = BTreeMap::new();
let sub = {
let mut sub = BTreeMap::new();
sub.insert("version".into(), Value::String(String::from("000")));
Value::Table(sub)
};
header.insert("imag".into(), sub);
assert!(!verify_header_consistency(header).is_ok());
}
#[test]
fn test_verification_current_version() {
use super::verify_header_consistency;
let mut header = BTreeMap::new();
let sub = {
let mut sub = BTreeMap::new();
sub.insert("version".into(), Value::String(String::from(version!())));
Value::Table(sub)
};
header.insert("imag".into(), sub);
assert!(verify_header_consistency(header).is_ok());
}
static TEST_ENTRY : &'static str = "---
[imag]
version = \"0.0.3\"
---
Hai";
#[test]
fn test_entry_from_str() {
use super::Entry;
use std::path::PathBuf;
println!("{}", TEST_ENTRY);
let entry = Entry::from_str(PathBuf::from("/test/foo~1.3"),
TEST_ENTRY).unwrap();
assert_eq!(entry.content, "Hai");
}
#[test]
fn test_entry_to_str() {
use super::Entry;
use std::path::PathBuf;
println!("{}", TEST_ENTRY);
let entry = Entry::from_str(PathBuf::from("/test/foo~1.3"),
TEST_ENTRY).unwrap();
let string = entry.to_str();
assert_eq!(TEST_ENTRY, string);
}
#[test]
fn test_walk_header_simple() {
let tokens = EntryHeader::tokenize("a", '.').unwrap();
assert!(tokens.len() == 1, "1 token was expected, {} were parsed", tokens.len());
assert!(tokens.iter().next().unwrap() == &Token::Key(String::from("a")),
"'a' token was expected, {:?} was parsed", tokens.iter().next());
let mut header = BTreeMap::new();
header.insert(String::from("a"), Value::Integer(1));
let mut v_header = Value::Table(header);
let res = EntryHeader::walk_header(&mut v_header, tokens);
assert_eq!(&mut Value::Integer(1), res.unwrap());
}
#[test]
fn test_walk_header_with_array() {
let tokens = EntryHeader::tokenize("a.0", '.').unwrap();
assert!(tokens.len() == 2, "2 token was expected, {} were parsed", tokens.len());
assert!(tokens.iter().next().unwrap() == &Token::Key(String::from("a")),
"'a' token was expected, {:?} was parsed", tokens.iter().next());
let mut header = BTreeMap::new();
let ary = Value::Array(vec![Value::Integer(1)]);
header.insert(String::from("a"), ary);
let mut v_header = Value::Table(header);
let res = EntryHeader::walk_header(&mut v_header, tokens);
assert_eq!(&mut Value::Integer(1), res.unwrap());
}
#[test]
fn test_walk_header_extract_array() {
let tokens = EntryHeader::tokenize("a", '.').unwrap();
assert!(tokens.len() == 1, "1 token was expected, {} were parsed", tokens.len());
assert!(tokens.iter().next().unwrap() == &Token::Key(String::from("a")),
"'a' token was expected, {:?} was parsed", tokens.iter().next());
let mut header = BTreeMap::new();
let ary = Value::Array(vec![Value::Integer(1)]);
header.insert(String::from("a"), ary);
let mut v_header = Value::Table(header);
let res = EntryHeader::walk_header(&mut v_header, tokens);
assert_eq!(&mut Value::Array(vec![Value::Integer(1)]), res.unwrap());
}
/**
* Creates a big testing header.
*
* JSON equivalent:
*
* ```json
* {
* "a": {
* "array": [ 0, 1, 2, 3, 4, 5, 6, 7, 8, 9 ]
* },
* "b": {
* "array": [ "string1", "string2", "string3", "string4" ]
* },
* "c": {
* "array": [ 1, "string2", 3, "string4" ]
* },
* "d": {
* "array": [
* {
* "d1": 1
* },
* {
* "d2": 2
* },
* {
* "d3": 3
* },
* ],
*
* "something": "else",
*
* "and": {
* "something": {
* "totally": "different"
* }
* }
* }
* }
* ```
*
* The sections "a", "b", "c", "d" are created in the respective helper functions
* create_header_section_a, create_header_section_b, create_header_section_c and
* create_header_section_d.
*
* These functions can also be used for testing.
*
*/
fn create_header() -> Value {
let a = create_header_section_a();
let b = create_header_section_b();
let c = create_header_section_c();
let d = create_header_section_d();
let mut header = BTreeMap::new();
header.insert(String::from("a"), a);
header.insert(String::from("b"), b);
header.insert(String::from("c"), c);
header.insert(String::from("d"), d);
Value::Table(header)
}
fn create_header_section_a() -> Value {
// 0..10 is exclusive 10
let a_ary = Value::Array((0..10).map(|x| Value::Integer(x)).collect());
let mut a_obj = BTreeMap::new();
a_obj.insert(String::from("array"), a_ary);
Value::Table(a_obj)
}
fn create_header_section_b() -> Value {
let b_ary = Value::Array((0..9)
.map(|x| Value::String(format!("string{}", x)))
.collect());
let mut b_obj = BTreeMap::new();
b_obj.insert(String::from("array"), b_ary);
Value::Table(b_obj)
}
fn create_header_section_c() -> Value {
let c_ary = Value::Array(
vec![
Value::Integer(1),
Value::String(String::from("string2")),
Value::Integer(3),
Value::String(String::from("string4"))
]);
let mut c_obj = BTreeMap::new();
c_obj.insert(String::from("array"), c_ary);
Value::Table(c_obj)
}
fn create_header_section_d() -> Value {
let d_ary = Value::Array(
vec![
{
let mut tab = BTreeMap::new();
tab.insert(String::from("d1"), Value::Integer(1));
tab
},
{
let mut tab = BTreeMap::new();
tab.insert(String::from("d2"), Value::Integer(2));
tab
},
{
let mut tab = BTreeMap::new();
tab.insert(String::from("d3"), Value::Integer(3));
tab
},
].into_iter().map(Value::Table).collect());
let and_obj = Value::Table({
let mut tab = BTreeMap::new();
let something_tab = Value::Table({
let mut tab = BTreeMap::new();
tab.insert(String::from("totally"), Value::String(String::from("different")));
tab
});
tab.insert(String::from("something"), something_tab);
tab
});
let mut d_obj = BTreeMap::new();
d_obj.insert(String::from("array"), d_ary);
d_obj.insert(String::from("something"), Value::String(String::from("else")));
d_obj.insert(String::from("and"), and_obj);
Value::Table(d_obj)
}
#[test]
fn test_walk_header_big_a() {
test_walk_header_extract_section("a", &create_header_section_a());
}
#[test]
fn test_walk_header_big_b() {
test_walk_header_extract_section("b", &create_header_section_b());
}
#[test]
fn test_walk_header_big_c() {
test_walk_header_extract_section("c", &create_header_section_c());
}
#[test]
fn test_walk_header_big_d() {
test_walk_header_extract_section("d", &create_header_section_d());
}
fn test_walk_header_extract_section(secname: &str, expected: &Value) {
let tokens = EntryHeader::tokenize(secname, '.').unwrap();
assert!(tokens.len() == 1, "1 token was expected, {} were parsed", tokens.len());
assert!(tokens.iter().next().unwrap() == &Token::Key(String::from(secname)),
"'{}' token was expected, {:?} was parsed", secname, tokens.iter().next());
let mut header = create_header();
let res = EntryHeader::walk_header(&mut header, tokens);
assert_eq!(expected, res.unwrap());
}
#[test]
fn test_walk_header_extract_numbers() {
test_extract_number("a", 0, 0);
test_extract_number("a", 1, 1);
test_extract_number("a", 2, 2);
test_extract_number("a", 3, 3);
test_extract_number("a", 4, 4);
test_extract_number("a", 5, 5);
test_extract_number("a", 6, 6);
test_extract_number("a", 7, 7);
test_extract_number("a", 8, 8);
test_extract_number("a", 9, 9);
test_extract_number("c", 0, 1);
test_extract_number("c", 2, 3);
}
fn test_extract_number(sec: &str, idx: usize, exp: i64) {
let tokens = EntryHeader::tokenize(&format!("{}.array.{}", sec, idx)[..], '.').unwrap();
assert!(tokens.len() == 3, "3 token was expected, {} were parsed", tokens.len());
{
let mut iter = tokens.iter();
let tok = iter.next().unwrap();
let exp = Token::Key(String::from(sec));
assert!(tok == &exp, "'{}' token was expected, {:?} was parsed", sec, tok);
let tok = iter.next().unwrap();
let exp = Token::Key(String::from("array"));
assert!(tok == &exp, "'array' token was expected, {:?} was parsed", tok);
let tok = iter.next().unwrap();
let exp = Token::Index(idx);
assert!(tok == &exp, "'{}' token was expected, {:?} was parsed", idx, tok);
}
let mut header = create_header();
let res = EntryHeader::walk_header(&mut header, tokens);
assert_eq!(&mut Value::Integer(exp), res.unwrap());
}
#[test]
fn test_header_read() {
let v = create_header();
let h = match v {
Value::Table(t) => EntryHeader::from_table(t),
_ => panic!("create_header() doesn't return a table!"),
};
assert!(if let Ok(Some(Value::Table(_))) = h.read("a") { true } else { false });
assert!(if let Ok(Some(Value::Array(_))) = h.read("a.array") { true } else { false });
assert!(if let Ok(Some(Value::Integer(_))) = h.read("a.array.1") { true } else { false });
assert!(if let Ok(Some(Value::Integer(_))) = h.read("a.array.9") { true } else { false });
assert!(if let Ok(Some(Value::Table(_))) = h.read("c") { true } else { false });
assert!(if let Ok(Some(Value::Array(_))) = h.read("c.array") { true } else { false });
assert!(if let Ok(Some(Value::String(_))) = h.read("c.array.1") { true } else { false });
assert!(if let Ok(None) = h.read("c.array.9") { true } else { false });
assert!(if let Ok(Some(Value::Integer(_))) = h.read("d.array.0.d1") { true } else { false });
assert!(if let Ok(None) = h.read("d.array.0.d2") { true } else { false });
assert!(if let Ok(None) = h.read("d.array.0.d3") { true } else { false });
assert!(if let Ok(None) = h.read("d.array.1.d1") { true } else { false });
assert!(if let Ok(Some(Value::Integer(_))) = h.read("d.array.1.d2") { true } else { false });
assert!(if let Ok(None) = h.read("d.array.1.d3") { true } else { false });
assert!(if let Ok(None) = h.read("d.array.2.d1") { true } else { false });
assert!(if let Ok(None) = h.read("d.array.2.d2") { true } else { false });
assert!(if let Ok(Some(Value::Integer(_))) = h.read("d.array.2.d3") { true } else { false });
assert!(if let Ok(Some(Value::String(_))) = h.read("d.something") { true } else { false });
assert!(if let Ok(Some(Value::Table(_))) = h.read("d.and") { true } else { false });
assert!(if let Ok(Some(Value::Table(_))) = h.read("d.and.something") { true } else { false });
assert!(if let Ok(Some(Value::String(_))) = h.read("d.and.something.totally") { true } else { false });
}
#[test]
fn test_header_set_override() {
let _ = env_logger::init();
let v = create_header();
let mut h = match v {
Value::Table(t) => EntryHeader::from_table(t),
_ => panic!("create_header() doesn't return a table!"),
};
println!("Testing index 0");
assert_eq!(h.read("a.array.0").unwrap().unwrap(), Value::Integer(0));
println!("Altering index 0");
assert_eq!(h.set("a.array.0", Value::Integer(42)).unwrap().unwrap(), Value::Integer(0));
println!("Values now: {:?}", h);
println!("Testing all indexes");
assert_eq!(h.read("a.array.0").unwrap().unwrap(), Value::Integer(42));
assert_eq!(h.read("a.array.1").unwrap().unwrap(), Value::Integer(1));
assert_eq!(h.read("a.array.2").unwrap().unwrap(), Value::Integer(2));
assert_eq!(h.read("a.array.3").unwrap().unwrap(), Value::Integer(3));
assert_eq!(h.read("a.array.4").unwrap().unwrap(), Value::Integer(4));
assert_eq!(h.read("a.array.5").unwrap().unwrap(), Value::Integer(5));
assert_eq!(h.read("a.array.6").unwrap().unwrap(), Value::Integer(6));
assert_eq!(h.read("a.array.7").unwrap().unwrap(), Value::Integer(7));
assert_eq!(h.read("a.array.8").unwrap().unwrap(), Value::Integer(8));
assert_eq!(h.read("a.array.9").unwrap().unwrap(), Value::Integer(9));
}
#[test]
fn test_header_set_new() {
let _ = env_logger::init();
let v = create_header();
let mut h = match v {
Value::Table(t) => EntryHeader::from_table(t),
_ => panic!("create_header() doesn't return a table!"),
};
assert!(h.read("a.foo").is_ok());
assert!(h.read("a.foo").unwrap().is_none());
{
let v = h.set("a.foo", Value::Integer(42));
assert!(v.is_ok());
assert!(v.unwrap().is_none());
assert!(if let Ok(Some(Value::Table(_))) = h.read("a") { true } else { false });
assert!(if let Ok(Some(Value::Integer(_))) = h.read("a.foo") { true } else { false });
}
{
let v = h.set("new", Value::Table(BTreeMap::new()));
assert!(v.is_ok());
assert!(v.unwrap().is_none());
let v = h.set("new.subset", Value::Table(BTreeMap::new()));
assert!(v.is_ok());
assert!(v.unwrap().is_none());
let v = h.set("new.subset.dest", Value::Integer(1337));
assert!(v.is_ok());
assert!(v.unwrap().is_none());
assert!(if let Ok(Some(Value::Table(_))) = h.read("new") { true } else { false });
assert!(if let Ok(Some(Value::Table(_))) = h.read("new.subset") { true } else { false });
assert!(if let Ok(Some(Value::Integer(_))) = h.read("new.subset.dest") { true } else { false });
}
}
#[test]
fn test_header_insert_override() {
let _ = env_logger::init();
let v = create_header();
let mut h = match v {
Value::Table(t) => EntryHeader::from_table(t),
_ => panic!("create_header() doesn't return a table!"),
};
println!("Testing index 0");
assert_eq!(h.read("a.array.0").unwrap().unwrap(), Value::Integer(0));
println!("Altering index 0");
assert_eq!(h.insert("a.array.0", Value::Integer(42)).unwrap(), false);
println!("...should have failed");
println!("Testing all indexes");
assert_eq!(h.read("a.array.0").unwrap().unwrap(), Value::Integer(0));
assert_eq!(h.read("a.array.1").unwrap().unwrap(), Value::Integer(1));
assert_eq!(h.read("a.array.2").unwrap().unwrap(), Value::Integer(2));
assert_eq!(h.read("a.array.3").unwrap().unwrap(), Value::Integer(3));
assert_eq!(h.read("a.array.4").unwrap().unwrap(), Value::Integer(4));
assert_eq!(h.read("a.array.5").unwrap().unwrap(), Value::Integer(5));
assert_eq!(h.read("a.array.6").unwrap().unwrap(), Value::Integer(6));
assert_eq!(h.read("a.array.7").unwrap().unwrap(), Value::Integer(7));
assert_eq!(h.read("a.array.8").unwrap().unwrap(), Value::Integer(8));
assert_eq!(h.read("a.array.9").unwrap().unwrap(), Value::Integer(9));
}
#[test]
fn test_header_insert_new() {
let _ = env_logger::init();
let v = create_header();
let mut h = match v {
Value::Table(t) => EntryHeader::from_table(t),
_ => panic!("create_header() doesn't return a table!"),
};
assert!(h.read("a.foo").is_ok());
assert!(h.read("a.foo").unwrap().is_none());
{
let v = h.insert("a.foo", Value::Integer(42));
assert!(v.is_ok());
assert_eq!(v.unwrap(), true);
assert!(if let Ok(Some(Value::Table(_))) = h.read("a") { true } else { false });
assert!(if let Ok(Some(Value::Integer(_))) = h.read("a.foo") { true } else { false });
}
{
let v = h.insert("new", Value::Table(BTreeMap::new()));
assert!(v.is_ok());
assert_eq!(v.unwrap(), true);
let v = h.insert("new.subset", Value::Table(BTreeMap::new()));
assert!(v.is_ok());
assert_eq!(v.unwrap(), true);
let v = h.insert("new.subset.dest", Value::Integer(1337));
assert!(v.is_ok());
assert_eq!(v.unwrap(), true);
assert!(if let Ok(Some(Value::Table(_))) = h.read("new") { true } else { false });
assert!(if let Ok(Some(Value::Table(_))) = h.read("new.subset") { true } else { false });
assert!(if let Ok(Some(Value::Integer(_))) = h.read("new.subset.dest") { true } else { false });
}
}
#[test]
fn test_header_delete() {
let _ = env_logger::init();
let v = create_header();
let mut h = match v {
Value::Table(t) => EntryHeader::from_table(t),
_ => panic!("create_header() doesn't return a table!"),
};
assert!(if let Ok(Some(Value::Table(_))) = h.read("a") { true } else { false });
assert!(if let Ok(Some(Value::Array(_))) = h.read("a.array") { true } else { false });
assert!(if let Ok(Some(Value::Integer(_))) = h.read("a.array.1") { true } else { false });
assert!(if let Ok(Some(Value::Integer(_))) = h.read("a.array.9") { true } else { false });
assert!(if let Ok(Some(Value::Integer(1))) = h.delete("a.array.1") { true } else { false });
assert!(if let Ok(Some(Value::Integer(9))) = h.delete("a.array.8") { true } else { false });
assert!(if let Ok(Some(Value::Array(_))) = h.delete("a.array") { true } else { false });
assert!(if let Ok(Some(Value::Table(_))) = h.delete("a") { true } else { false });
}
}