//! # Pool implementation providing pre-allocated sub-pools with fixed size memory blocks //! //! This is a simple memory pool implementation which pre-allocates all sub-pools using a given pool //! configuration. After the pre-allocation, no dynamic memory allocation will be performed //! during run-time. This makes the implementation suitable for real-time applications and //! embedded environments. The pool implementation will also track the size of the data stored //! inside it. //! //! Transactions with the [pool][LocalPool] are done using a special [address][StoreAddr] type. //! Adding any data to the pool will yield a store address. Modification and read operations are //! done using a reference to a store address. Deletion will consume the store address. //! //! # Example //! //! ``` //! use satrs_core::pool::{LocalPool, PoolCfg, PoolProvider}; //! //! // 4 buckets of 4 bytes, 2 of 8 bytes and 1 of 16 bytes //! let pool_cfg = PoolCfg::new(vec![(4, 4), (2, 8), (1, 16)]); //! let mut local_pool = LocalPool::new(pool_cfg); //! let mut addr; //! { //! // Add new data to the pool //! let mut example_data = [0; 4]; //! example_data[0] = 42; //! let res = local_pool.add(&example_data); //! assert!(res.is_ok()); //! addr = res.unwrap(); //! } //! //! { //! // Read the store data back //! let res = local_pool.read(&addr); //! assert!(res.is_ok()); //! let buf_read_back = res.unwrap(); //! assert_eq!(buf_read_back.len(), 4); //! assert_eq!(buf_read_back[0], 42); //! // Modify the stored data //! let res = local_pool.modify(&addr); //! assert!(res.is_ok()); //! let buf_read_back = res.unwrap(); //! buf_read_back[0] = 12; //! } //! //! { //! // Read the modified data back //! let res = local_pool.read(&addr); //! assert!(res.is_ok()); //! let buf_read_back = res.unwrap(); //! assert_eq!(buf_read_back.len(), 4); //! assert_eq!(buf_read_back[0], 12); //! } //! //! // Delete the stored data //! local_pool.delete(addr); //! //! // Get a free element in the pool with an appropriate size //! { //! let res = local_pool.free_element(12); //! assert!(res.is_ok()); //! let (tmp, mut_buf) = res.unwrap(); //! addr = tmp; //! mut_buf[0] = 7; //! } //! //! // Read back the data //! { //! // Read the store data back //! let res = local_pool.read(&addr); //! assert!(res.is_ok()); //! let buf_read_back = res.unwrap(); //! assert_eq!(buf_read_back.len(), 12); //! assert_eq!(buf_read_back[0], 7); //! } //! ``` use alloc::format; use alloc::string::String; use alloc::vec; use alloc::vec::Vec; use core::fmt::{Display, Formatter}; use delegate::delegate; #[cfg(feature = "serde")] use serde::{Deserialize, Serialize}; #[cfg(feature = "std")] use std::boxed::Box; #[cfg(feature = "std")] use std::error::Error; #[cfg(feature = "std")] use std::sync::{Arc, RwLock}; type NumBlocks = u16; #[cfg(feature = "std")] pub type ShareablePoolProvider = Box; #[cfg(feature = "std")] pub type SharedPool = Arc>; /// Configuration structure of the [local pool][LocalPool] /// /// # Parameters /// /// * `cfg`: Vector of tuples which represent a subpool. The first entry in the tuple specifies the /// number of memory blocks in the subpool, the second entry the size of the blocks #[derive(Clone)] pub struct PoolCfg { cfg: Vec<(NumBlocks, usize)>, } impl PoolCfg { pub fn new(cfg: Vec<(NumBlocks, usize)>) -> Self { PoolCfg { cfg } } pub fn sanitize(&mut self) -> usize { self.cfg .retain(|&(bucket_num, size)| bucket_num > 0 && size < LocalPool::MAX_SIZE); self.cfg .sort_unstable_by(|(_, sz0), (_, sz1)| sz0.partial_cmp(sz1).unwrap()); self.cfg.len() } } type PoolSize = usize; /// Pool implementation providing sub-pools with fixed size memory blocks. More details in /// the [module documentation][super::pool] pub struct LocalPool { pool_cfg: PoolCfg, pool: Vec>, sizes_lists: Vec>, } /// Simple address type used for transactions with the local pool. #[derive(Debug, Copy, Clone, PartialEq, Eq)] #[cfg_attr(feature = "serde", derive(Serialize, Deserialize))] pub struct StoreAddr { pub(crate) pool_idx: u16, pub(crate) packet_idx: NumBlocks, } impl Display for StoreAddr { fn fmt(&self, f: &mut Formatter<'_>) -> core::fmt::Result { write!( f, "StoreAddr(pool index: {}, packet index: {})", self.pool_idx, self.packet_idx ) } } impl StoreAddr { pub const INVALID_ADDR: u32 = 0xFFFFFFFF; pub fn raw(&self) -> u32 { ((self.pool_idx as u32) << 16) | self.packet_idx as u32 } } #[derive(Debug, Clone, PartialEq, Eq)] #[cfg_attr(feature = "serde", derive(Serialize, Deserialize))] pub enum StoreIdError { InvalidSubpool(u16), InvalidPacketIdx(u16), } impl Display for StoreIdError { fn fmt(&self, f: &mut Formatter<'_>) -> core::fmt::Result { match self { StoreIdError::InvalidSubpool(pool) => { write!(f, "invalid subpool, index: {pool}") } StoreIdError::InvalidPacketIdx(packet_idx) => { write!(f, "invalid packet index: {packet_idx}") } } } } #[cfg(feature = "std")] impl Error for StoreIdError {} #[derive(Debug, Clone, PartialEq, Eq)] #[cfg_attr(feature = "serde", derive(Serialize, Deserialize))] pub enum StoreError { /// Requested data block is too large DataTooLarge(usize), /// The store is full. Contains the index of the full subpool StoreFull(u16), /// Store ID is invalid. This also includes partial errors where only the subpool is invalid InvalidStoreId(StoreIdError, Option), /// Valid subpool and packet index, but no data is stored at the given address DataDoesNotExist(StoreAddr), /// Internal or configuration errors InternalError(String), } impl Display for StoreError { fn fmt(&self, f: &mut Formatter<'_>) -> core::fmt::Result { match self { StoreError::DataTooLarge(size) => { write!(f, "data to store with size {size} is too large") } StoreError::StoreFull(u16) => { write!(f, "store is too full. index for full subpool: {u16}") } StoreError::InvalidStoreId(id_e, addr) => { write!(f, "invalid store ID: {id_e}, address: {addr:?}") } StoreError::DataDoesNotExist(addr) => { write!(f, "no data exists at address {addr:?}") } StoreError::InternalError(e) => { write!(f, "internal error: {e}") } } } } #[cfg(feature = "std")] impl Error for StoreError { fn source(&self) -> Option<&(dyn Error + 'static)> { if let StoreError::InvalidStoreId(e, _) = self { return Some(e); } None } } pub trait PoolProvider { /// Add new data to the pool. The provider should attempt to reserve a memory block with the /// appropriate size and then copy the given data to the block. Yields a [StoreAddr] which can /// be used to access the data stored in the pool fn add(&mut self, data: &[u8]) -> Result; /// The provider should attempt to reserve a free memory block with the appropriate size and /// then return a mutable reference to it. Yields a [StoreAddr] which can be used to access /// the data stored in the pool fn free_element(&mut self, len: usize) -> Result<(StoreAddr, &mut [u8]), StoreError>; /// Modify data added previously using a given [StoreAddr] by yielding a mutable reference /// to it fn modify(&mut self, addr: &StoreAddr) -> Result<&mut [u8], StoreError>; /// This function behaves like [Self::modify], but consumes the provided address and returns a /// RAII conformant guard object. /// /// Unless the guard [PoolRwGuard::release] method is called, the data for the /// given address will be deleted automatically when the guard is dropped. /// This can prevent memory leaks. Users can read (and modify) the data and release the guard /// if the data in the store is valid for further processing. If the data is faulty, no /// manual deletion is necessary when returning from a processing function prematurely. fn modify_with_guard(&mut self, addr: StoreAddr) -> PoolRwGuard; /// Read data by yielding a read-only reference given a [StoreAddr] fn read(&self, addr: &StoreAddr) -> Result<&[u8], StoreError>; /// This function behaves like [Self::read], but consumes the provided address and returns a /// RAII conformant guard object. /// /// Unless the guard [PoolRwGuard::release] method is called, the data for the /// given address will be deleted automatically when the guard is dropped. /// This can prevent memory leaks. Users can read the data and release the guard /// if the data in the store is valid for further processing. If the data is faulty, no /// manual deletion is necessary when returning from a processing function prematurely. fn read_with_guard(&mut self, addr: StoreAddr) -> PoolGuard; /// Delete data inside the pool given a [StoreAddr] fn delete(&mut self, addr: StoreAddr) -> Result<(), StoreError>; fn has_element_at(&self, addr: &StoreAddr) -> Result; /// Retrieve the length of the data at the given store address. fn len_of_data(&self, addr: &StoreAddr) -> Result { if !self.has_element_at(addr)? { return Err(StoreError::DataDoesNotExist(*addr)); } Ok(self.read(addr)?.len()) } } impl LocalPool { const STORE_FREE: PoolSize = PoolSize::MAX; const MAX_SIZE: PoolSize = Self::STORE_FREE - 1; /// Create a new local pool from the [given configuration][PoolCfg]. This function will sanitize /// the given configuration as well. pub fn new(mut cfg: PoolCfg) -> LocalPool { let subpools_num = cfg.sanitize(); let mut local_pool = LocalPool { pool_cfg: cfg, pool: Vec::with_capacity(subpools_num), sizes_lists: Vec::with_capacity(subpools_num), }; for &(num_elems, elem_size) in local_pool.pool_cfg.cfg.iter() { let next_pool_len = elem_size * num_elems as usize; local_pool.pool.push(vec![0; next_pool_len]); let next_sizes_list_len = num_elems as usize; local_pool .sizes_lists .push(vec![Self::STORE_FREE; next_sizes_list_len]); } local_pool } fn addr_check(&self, addr: &StoreAddr) -> Result { self.validate_addr(addr)?; let pool_idx = addr.pool_idx as usize; let size_list = self.sizes_lists.get(pool_idx).unwrap(); let curr_size = size_list[addr.packet_idx as usize]; if curr_size == Self::STORE_FREE { return Err(StoreError::DataDoesNotExist(*addr)); } Ok(curr_size) } fn validate_addr(&self, addr: &StoreAddr) -> Result<(), StoreError> { let pool_idx = addr.pool_idx as usize; if pool_idx >= self.pool_cfg.cfg.len() { return Err(StoreError::InvalidStoreId( StoreIdError::InvalidSubpool(addr.pool_idx), Some(*addr), )); } if addr.packet_idx >= self.pool_cfg.cfg[addr.pool_idx as usize].0 { return Err(StoreError::InvalidStoreId( StoreIdError::InvalidPacketIdx(addr.packet_idx), Some(*addr), )); } Ok(()) } fn reserve(&mut self, data_len: usize) -> Result { let subpool_idx = self.find_subpool(data_len, 0)?; let (slot, size_slot_ref) = self.find_empty(subpool_idx)?; *size_slot_ref = data_len; Ok(StoreAddr { pool_idx: subpool_idx, packet_idx: slot, }) } fn find_subpool(&self, req_size: usize, start_at_subpool: u16) -> Result { for (i, &(_, elem_size)) in self.pool_cfg.cfg.iter().enumerate() { if i < start_at_subpool as usize { continue; } if elem_size >= req_size { return Ok(i as u16); } } Err(StoreError::DataTooLarge(req_size)) } fn write(&mut self, addr: &StoreAddr, data: &[u8]) -> Result<(), StoreError> { let packet_pos = self.raw_pos(addr).ok_or_else(|| { StoreError::InternalError(format!( "write: Error in raw_pos func with address {addr:?}" )) })?; let subpool = self.pool.get_mut(addr.pool_idx as usize).ok_or_else(|| { StoreError::InternalError(format!( "write: Error retrieving pool slice with address {addr:?}" )) })?; let pool_slice = &mut subpool[packet_pos..packet_pos + data.len()]; pool_slice.copy_from_slice(data); Ok(()) } fn find_empty(&mut self, subpool: u16) -> Result<(u16, &mut usize), StoreError> { if let Some(size_list) = self.sizes_lists.get_mut(subpool as usize) { for (i, elem_size) in size_list.iter_mut().enumerate() { if *elem_size == Self::STORE_FREE { return Ok((i as u16, elem_size)); } } } else { return Err(StoreError::InvalidStoreId( StoreIdError::InvalidSubpool(subpool), None, )); } Err(StoreError::StoreFull(subpool)) } fn raw_pos(&self, addr: &StoreAddr) -> Option { let (_, size) = self.pool_cfg.cfg.get(addr.pool_idx as usize)?; Some(addr.packet_idx as usize * size) } } impl PoolProvider for LocalPool { fn add(&mut self, data: &[u8]) -> Result { let data_len = data.len(); if data_len > Self::MAX_SIZE { return Err(StoreError::DataTooLarge(data_len)); } let addr = self.reserve(data_len)?; self.write(&addr, data)?; Ok(addr) } fn free_element(&mut self, len: usize) -> Result<(StoreAddr, &mut [u8]), StoreError> { if len > Self::MAX_SIZE { return Err(StoreError::DataTooLarge(len)); } let addr = self.reserve(len)?; let raw_pos = self.raw_pos(&addr).unwrap(); let block = &mut self.pool.get_mut(addr.pool_idx as usize).unwrap()[raw_pos..raw_pos + len]; Ok((addr, block)) } fn modify(&mut self, addr: &StoreAddr) -> Result<&mut [u8], StoreError> { let curr_size = self.addr_check(addr)?; let raw_pos = self.raw_pos(addr).unwrap(); let block = &mut self.pool.get_mut(addr.pool_idx as usize).unwrap()[raw_pos..raw_pos + curr_size]; Ok(block) } fn modify_with_guard(&mut self, addr: StoreAddr) -> PoolRwGuard { PoolRwGuard::new(self, addr) } fn read(&self, addr: &StoreAddr) -> Result<&[u8], StoreError> { let curr_size = self.addr_check(addr)?; let raw_pos = self.raw_pos(addr).unwrap(); let block = &self.pool.get(addr.pool_idx as usize).unwrap()[raw_pos..raw_pos + curr_size]; Ok(block) } fn read_with_guard(&mut self, addr: StoreAddr) -> PoolGuard { PoolGuard::new(self, addr) } fn delete(&mut self, addr: StoreAddr) -> Result<(), StoreError> { self.addr_check(&addr)?; let block_size = self.pool_cfg.cfg.get(addr.pool_idx as usize).unwrap().1; let raw_pos = self.raw_pos(&addr).unwrap(); let block = &mut self.pool.get_mut(addr.pool_idx as usize).unwrap()[raw_pos..raw_pos + block_size]; let size_list = self.sizes_lists.get_mut(addr.pool_idx as usize).unwrap(); size_list[addr.packet_idx as usize] = Self::STORE_FREE; block.fill(0); Ok(()) } fn has_element_at(&self, addr: &StoreAddr) -> Result { self.validate_addr(addr)?; let pool_idx = addr.pool_idx as usize; let size_list = self.sizes_lists.get(pool_idx).unwrap(); let curr_size = size_list[addr.packet_idx as usize]; if curr_size == Self::STORE_FREE { return Ok(false); } Ok(true) } } pub struct PoolGuard<'a> { pool: &'a mut LocalPool, pub addr: StoreAddr, no_deletion: bool, deletion_failed_error: Option, } /// This helper object impl<'a> PoolGuard<'a> { pub fn new(pool: &'a mut LocalPool, addr: StoreAddr) -> Self { Self { pool, addr, no_deletion: false, deletion_failed_error: None, } } pub fn read(&self) -> Result<&[u8], StoreError> { self.pool.read(&self.addr) } /// Releasing the pool guard will disable the automatic deletion of the data when the guard /// is dropped. pub fn release(&mut self) { self.no_deletion = true; } } impl Drop for PoolGuard<'_> { fn drop(&mut self) { if !self.no_deletion { if let Err(e) = self.pool.delete(self.addr) { self.deletion_failed_error = Some(e); } } } } pub struct PoolRwGuard<'a> { guard: PoolGuard<'a>, } impl<'a> PoolRwGuard<'a> { pub fn new(pool: &'a mut LocalPool, addr: StoreAddr) -> Self { Self { guard: PoolGuard::new(pool, addr), } } pub fn modify(&mut self) -> Result<&mut [u8], StoreError> { self.guard.pool.modify(&self.guard.addr) } delegate!( to self.guard { pub fn read(&self) -> Result<&[u8], StoreError>; /// Releasing the pool guard will disable the automatic deletion of the data when the guard /// is dropped. pub fn release(&mut self); } ); } #[cfg(test)] mod tests { use crate::pool::{ LocalPool, PoolCfg, PoolGuard, PoolProvider, PoolRwGuard, StoreAddr, StoreError, StoreIdError, }; use std::vec; fn basic_small_pool() -> LocalPool { // 4 buckets of 4 bytes, 2 of 8 bytes and 1 of 16 bytes let pool_cfg = PoolCfg::new(vec![(4, 4), (2, 8), (1, 16)]); LocalPool::new(pool_cfg) } #[test] fn test_cfg() { // Values where number of buckets is 0 or size is too large should be removed let mut pool_cfg = PoolCfg::new(vec![(0, 0), (1, 0), (2, LocalPool::MAX_SIZE)]); pool_cfg.sanitize(); assert_eq!(pool_cfg.cfg, vec![(1, 0)]); // Entries should be ordered according to bucket size pool_cfg = PoolCfg::new(vec![(16, 6), (32, 3), (8, 12)]); pool_cfg.sanitize(); assert_eq!(pool_cfg.cfg, vec![(32, 3), (16, 6), (8, 12)]); // Unstable sort is used, so order of entries with same block length should not matter pool_cfg = PoolCfg::new(vec![(12, 12), (14, 16), (10, 12)]); pool_cfg.sanitize(); assert!( pool_cfg.cfg == vec![(12, 12), (10, 12), (14, 16)] || pool_cfg.cfg == vec![(10, 12), (12, 12), (14, 16)] ); } #[test] fn test_add_and_read() { let mut local_pool = basic_small_pool(); let mut test_buf: [u8; 16] = [0; 16]; for (i, val) in test_buf.iter_mut().enumerate() { *val = i as u8; } let addr = local_pool.add(&test_buf).expect("Adding data failed"); // Read back data and verify correctness let res = local_pool.read(&addr); assert!(res.is_ok()); let buf_read_back = res.unwrap(); assert_eq!(buf_read_back.len(), 16); for (i, &val) in buf_read_back.iter().enumerate() { assert_eq!(val, i as u8); } } #[test] fn test_add_smaller_than_full_slot() { let mut local_pool = basic_small_pool(); let test_buf: [u8; 12] = [0; 12]; let addr = local_pool.add(&test_buf).expect("Adding data failed"); let res = local_pool.read(&addr).expect("Read back failed"); assert_eq!(res.len(), 12); } #[test] fn test_delete() { let mut local_pool = basic_small_pool(); let test_buf: [u8; 16] = [0; 16]; let addr = local_pool.add(&test_buf).expect("Adding data failed"); // Delete the data let res = local_pool.delete(addr); assert!(res.is_ok()); // Verify that the slot is free by trying to get a reference to it let res = local_pool.free_element(12); assert!(res.is_ok()); let (addr, buf_ref) = res.unwrap(); assert_eq!( addr, StoreAddr { pool_idx: 2, packet_idx: 0 } ); assert_eq!(buf_ref.len(), 12); } #[test] fn test_modify() { let mut local_pool = basic_small_pool(); let mut test_buf: [u8; 16] = [0; 16]; for (i, val) in test_buf.iter_mut().enumerate() { *val = i as u8; } let addr = local_pool.add(&test_buf).expect("Adding data failed"); { // Verify that the slot is free by trying to get a reference to it let res = local_pool.modify(&addr).expect("Modifying data failed"); res[0] = 0; res[1] = 0x42; } let res = local_pool.read(&addr).expect("Reading back data failed"); assert_eq!(res[0], 0); assert_eq!(res[1], 0x42); assert_eq!(res[2], 2); assert_eq!(res[3], 3); } #[test] fn test_consecutive_reservation() { let mut local_pool = basic_small_pool(); // Reserve two smaller blocks consecutively and verify that the third reservation fails let res = local_pool.free_element(8); assert!(res.is_ok()); let (addr0, _) = res.unwrap(); let res = local_pool.free_element(8); assert!(res.is_ok()); let (addr1, _) = res.unwrap(); let res = local_pool.free_element(8); assert!(res.is_err()); let err = res.unwrap_err(); assert_eq!(err, StoreError::StoreFull(1)); // Verify that the two deletions are successful assert!(local_pool.delete(addr0).is_ok()); assert!(local_pool.delete(addr1).is_ok()); } #[test] fn test_read_does_not_exist() { let local_pool = basic_small_pool(); // Try to access data which does not exist let res = local_pool.read(&StoreAddr { packet_idx: 0, pool_idx: 0, }); assert!(res.is_err()); assert!(matches!( res.unwrap_err(), StoreError::DataDoesNotExist { .. } )); } #[test] fn test_store_full() { let mut local_pool = basic_small_pool(); let test_buf: [u8; 16] = [0; 16]; assert!(local_pool.add(&test_buf).is_ok()); // The subpool is now full and the call should fail accordingly let res = local_pool.add(&test_buf); assert!(res.is_err()); let err = res.unwrap_err(); assert!(matches!(err, StoreError::StoreFull { .. })); if let StoreError::StoreFull(subpool) = err { assert_eq!(subpool, 2); } } #[test] fn test_invalid_pool_idx() { let local_pool = basic_small_pool(); let addr = StoreAddr { pool_idx: 3, packet_idx: 0, }; let res = local_pool.read(&addr); assert!(res.is_err()); let err = res.unwrap_err(); assert!(matches!( err, StoreError::InvalidStoreId(StoreIdError::InvalidSubpool(3), Some(_)) )); } #[test] fn test_invalid_packet_idx() { let local_pool = basic_small_pool(); let addr = StoreAddr { pool_idx: 2, packet_idx: 1, }; assert_eq!(addr.raw(), 0x00020001); let res = local_pool.read(&addr); assert!(res.is_err()); let err = res.unwrap_err(); assert!(matches!( err, StoreError::InvalidStoreId(StoreIdError::InvalidPacketIdx(1), Some(_)) )); } #[test] fn test_add_too_large() { let mut local_pool = basic_small_pool(); let data_too_large = [0; 20]; let res = local_pool.add(&data_too_large); assert!(res.is_err()); let err = res.unwrap_err(); assert_eq!(err, StoreError::DataTooLarge(20)); } #[test] fn test_data_too_large_1() { let mut local_pool = basic_small_pool(); let res = local_pool.free_element(LocalPool::MAX_SIZE + 1); assert!(res.is_err()); assert_eq!( res.unwrap_err(), StoreError::DataTooLarge(LocalPool::MAX_SIZE + 1) ); } #[test] fn test_free_element_too_large() { let mut local_pool = basic_small_pool(); // Try to request a slot which is too large let res = local_pool.free_element(20); assert!(res.is_err()); assert_eq!(res.unwrap_err(), StoreError::DataTooLarge(20)); } #[test] fn test_pool_guard_deletion_man_creation() { let mut local_pool = basic_small_pool(); let test_buf: [u8; 16] = [0; 16]; let addr = local_pool.add(&test_buf).expect("Adding data failed"); let read_guard = PoolGuard::new(&mut local_pool, addr); drop(read_guard); assert!(!local_pool.has_element_at(&addr).expect("Invalid address")); } #[test] fn test_pool_guard_deletion() { let mut local_pool = basic_small_pool(); let test_buf: [u8; 16] = [0; 16]; let addr = local_pool.add(&test_buf).expect("Adding data failed"); let read_guard = local_pool.read_with_guard(addr); drop(read_guard); assert!(!local_pool.has_element_at(&addr).expect("Invalid address")); } #[test] fn test_pool_guard_with_release() { let mut local_pool = basic_small_pool(); let test_buf: [u8; 16] = [0; 16]; let addr = local_pool.add(&test_buf).expect("Adding data failed"); let mut read_guard = PoolGuard::new(&mut local_pool, addr); read_guard.release(); drop(read_guard); assert!(local_pool.has_element_at(&addr).expect("Invalid address")); } #[test] fn test_pool_modify_guard_man_creation() { let mut local_pool = basic_small_pool(); let test_buf: [u8; 16] = [0; 16]; let addr = local_pool.add(&test_buf).expect("Adding data failed"); let mut rw_guard = PoolRwGuard::new(&mut local_pool, addr); let _ = rw_guard.modify().expect("modify failed"); drop(rw_guard); assert!(!local_pool.has_element_at(&addr).expect("Invalid address")); } #[test] fn test_pool_modify_guard() { let mut local_pool = basic_small_pool(); let test_buf: [u8; 16] = [0; 16]; let addr = local_pool.add(&test_buf).expect("Adding data failed"); let mut rw_guard = local_pool.modify_with_guard(addr); let _ = rw_guard.modify().expect("modify failed"); drop(rw_guard); assert!(!local_pool.has_element_at(&addr).expect("Invalid address")); } #[test] fn modify_pool_index_above_0() { let mut local_pool = basic_small_pool(); let test_buf_0: [u8; 4] = [1; 4]; let test_buf_1: [u8; 4] = [2; 4]; let test_buf_2: [u8; 4] = [3; 4]; let test_buf_3: [u8; 4] = [4; 4]; let addr0 = local_pool.add(&test_buf_0).expect("Adding data failed"); let addr1 = local_pool.add(&test_buf_1).expect("Adding data failed"); let addr2 = local_pool.add(&test_buf_2).expect("Adding data failed"); let addr3 = local_pool.add(&test_buf_3).expect("Adding data failed"); let tm0_raw = local_pool.modify(&addr0).expect("Modifying data failed"); assert_eq!(tm0_raw, test_buf_0); let tm1_raw = local_pool.modify(&addr1).expect("Modifying data failed"); assert_eq!(tm1_raw, test_buf_1); let tm2_raw = local_pool.modify(&addr2).expect("Modifying data failed"); assert_eq!(tm2_raw, test_buf_2); let tm3_raw = local_pool.modify(&addr3).expect("Modifying data failed"); assert_eq!(tm3_raw, test_buf_3); } }