use anyhow::{anyhow, Result}; use byteorder::{LittleEndian, ReadBytesExt, WriteBytesExt}; use rand::prelude::*; use std::fs::OpenOptions; use std::io::{Cursor, Read, Seek, SeekFrom, Write}; use std::path::{Path}; use thinp::file_utils; use thinp::thin::xml::{self, Visit}; mod common; use common::test_dir::*; use common::thin_xml_generator::{ write_xml, EmptyPoolS, FragmentedS, SingleThinS, SnapS, XmlGen }; //------------------------------------ #[derive(Debug)] struct ThinBlock { thin_id: u32, thin_block: u64, data_block: u64, block_size: usize, } struct ThinReadRef { pub data: Vec, } struct ThinWriteRef<'a, W: Write + Seek> { file: &'a mut W, block_byte: u64, pub data: Vec, } impl ThinBlock { fn read_ref(&self, r: &mut R) -> Result { let mut rr = ThinReadRef { data: vec![0; self.block_size * 512], }; let byte = self.data_block * (self.block_size as u64) * 512; r.seek(SeekFrom::Start(byte))?; r.read_exact(&mut rr.data)?; Ok(rr) } fn zero_ref<'a, W: Write + Seek>(&self, w: &'a mut W) -> ThinWriteRef<'a, W> { ThinWriteRef { file: w, block_byte: self.data_block * (self.block_size as u64) * 512, data: vec![0; self.block_size * 512], } } //fn write_ref<'a, W>(&self, w: &'a mut W) -> Result> //where //W: Read + Write + Seek, //{ //let mut data = vec![0; self.block_size]; //w.seek(SeekFrom::Start(self.data_block * (self.block_size as u64)))?; //w.read_exact(&mut data[0..])?; // //let wr = ThinWriteRef { //file: w, //block_byte: self.data_block * (self.block_size as u64), //data: vec![0; self.block_size], //}; // //Ok(wr) //} } impl<'a, W: Write + Seek> Drop for ThinWriteRef<'a, W> { fn drop(&mut self) { // FIXME: We shouldn't panic in a drop function, so any IO // errors will have to make their way back to the user // another way (eg, via a flush() method). self.file.seek(SeekFrom::Start(self.block_byte)).unwrap(); self.file.write_all(&self.data).unwrap(); } } //------------------------------------ trait ThinVisitor { fn thin_block(&mut self, tb: &ThinBlock) -> Result<()>; } struct ThinXmlVisitor<'a, V: ThinVisitor> { inner: &'a mut V, block_size: Option, thin_id: Option, } impl<'a, V: ThinVisitor> xml::MetadataVisitor for ThinXmlVisitor<'a, V> { fn superblock_b(&mut self, sb: &xml::Superblock) -> Result { self.block_size = Some(sb.data_block_size); Ok(Visit::Continue) } fn superblock_e(&mut self) -> Result { Ok(Visit::Continue) } fn device_b(&mut self, d: &xml::Device) -> Result { self.thin_id = Some(d.dev_id); Ok(Visit::Continue) } fn device_e(&mut self) -> Result { Ok(Visit::Continue) } fn map(&mut self, m: &xml::Map) -> Result { for i in 0..m.len { let block = ThinBlock { thin_id: self.thin_id.unwrap(), thin_block: m.thin_begin + i, data_block: m.data_begin + i, block_size: self.block_size.unwrap() as usize, }; self.inner.thin_block(&block)?; } Ok(Visit::Continue) } fn eof(&mut self) -> Result { Ok(Visit::Stop) } } fn thin_visit(input: R, visitor: &mut M) -> Result<()> where R: Read, M: ThinVisitor, { let mut xml_visitor = ThinXmlVisitor { inner: visitor, block_size: None, thin_id: None, }; xml::read(input, &mut xml_visitor) } //------------------------------------ // To test thin_shrink we'd like to stamp a known pattern across the // provisioned areas of the thins in the pool, do the shrink, verify // the patterns. // A simple linear congruence generator used to create the data to // go into the thin blocks. struct Generator { x: u64, a: u64, c: u64, } impl Generator { fn new() -> Generator { Generator { x: 0, a: 6364136223846793005, c: 1442695040888963407, } } fn step(&mut self) { self.x = self.a.wrapping_mul(self.x).wrapping_add(self.c) } fn fill_buffer(&mut self, seed: u64, bytes: &mut [u8]) -> Result<()> { self.x = seed; assert!(bytes.len() % 8 == 0); let nr_words = bytes.len() / 8; let mut out = Cursor::new(bytes); for _ in 0..nr_words { out.write_u64::(self.x)?; self.step(); } Ok(()) } fn verify_buffer(&mut self, seed: u64, bytes: &[u8]) -> Result { self.x = seed; assert!(bytes.len() % 8 == 0); let nr_words = bytes.len() / 8; let mut input = Cursor::new(bytes); for _ in 0..nr_words { let w = input.read_u64::()?; if w != self.x { eprintln!("{} != {}", w, self.x); return Ok(false); } self.step(); } Ok(true) } } //------------------------------------ struct Stamper<'a, W: Write + Seek> { data_file: &'a mut W, seed: u64, } impl<'a, W: Write + Seek> Stamper<'a, W> { fn new(w: &'a mut W, seed: u64) -> Stamper<'a, W> { Stamper { data_file: w, seed } } } impl<'a, W: Write + Seek> ThinVisitor for Stamper<'a, W> { fn thin_block(&mut self, b: &ThinBlock) -> Result<()> { let mut wr = b.zero_ref(self.data_file); let mut gen = Generator::new(); gen.fill_buffer(self.seed ^ (b.thin_id as u64) ^ b.thin_block, &mut wr.data)?; Ok(()) } } //------------------------------------ struct Verifier<'a, R: Read + Seek> { data_file: &'a mut R, seed: u64, } impl<'a, R: Read + Seek> Verifier<'a, R> { fn new(r: &'a mut R, seed: u64) -> Verifier<'a, R> { Verifier { data_file: r, seed } } } impl<'a, R: Read + Seek> ThinVisitor for Verifier<'a, R> { fn thin_block(&mut self, b: &ThinBlock) -> Result<()> { let rr = b.read_ref(self.data_file)?; let mut gen = Generator::new(); if !gen.verify_buffer(self.seed ^ (b.thin_id as u64) ^ b.thin_block, &rr.data)? { return Err(anyhow!("data verify failed for {:?}", b)); } Ok(()) } } //------------------------------------ fn create_data_file(data_path: &Path, xml_path: &Path) -> Result<()> { let input = OpenOptions::new().read(true).write(false).open(xml_path)?; let sb = xml::read_superblock(input)?; let nr_blocks = sb.nr_data_blocks as u64; let block_size = sb.data_block_size as u64 * 512; let _file = file_utils::create_sized_file(data_path, nr_blocks * block_size)?; Ok(()) } fn stamp(xml_path: &Path, data_path: &Path, seed: u64) -> Result<()> { let mut data = OpenOptions::new() .read(false) .write(true) .open(&data_path)?; let xml = OpenOptions::new().read(true).write(false).open(&xml_path)?; let mut stamper = Stamper::new(&mut data, seed); thin_visit(xml, &mut stamper) } fn verify(xml_path: &Path, data_path: &Path, seed: u64) -> Result<()> { let mut data = OpenOptions::new() .read(true) .write(false) .open(&data_path)?; let xml = OpenOptions::new().read(true).write(false).open(&xml_path)?; let mut verifier = Verifier::new(&mut data, seed); thin_visit(xml, &mut verifier) } trait Scenario { fn get_new_nr_blocks(&self) -> u64; } fn test_shrink(scenario: &mut S) -> Result<()> where S: Scenario + XmlGen, { let mut td = TestDir::new()?; let xml_before = td.mk_path("before.xml"); let xml_after = td.mk_path("after.xml"); let data_path = td.mk_path("metadata.bin"); write_xml(&xml_before, scenario)?; create_data_file(&data_path, &xml_before)?; let mut rng = rand::thread_rng(); let seed = rng.gen::(); stamp(&xml_before, &data_path, seed)?; verify(&xml_before, &data_path, seed)?; let new_nr_blocks = scenario.get_new_nr_blocks(); thinp::shrink::toplevel::shrink(&xml_before, &xml_after, &data_path, new_nr_blocks, true)?; verify(&xml_after, &data_path, seed)?; Ok(()) } //------------------------------------ impl Scenario for EmptyPoolS { fn get_new_nr_blocks(&self) -> u64 { 512 } } #[test] fn shrink_empty_pool() -> Result<()> { let mut s = EmptyPoolS {}; test_shrink(&mut s) } //------------------------------------ impl Scenario for SingleThinS { fn get_new_nr_blocks(&self) -> u64 { self.new_nr_data_blocks } } #[test] fn shrink_single_no_move_1() -> Result<()> { let mut s = SingleThinS::new(0, 1024, 2048, 1280); test_shrink(&mut s) } #[test] fn shrink_single_no_move_2() -> Result<()> { let mut s = SingleThinS::new(100, 1024, 2048, 1280); test_shrink(&mut s) } #[test] fn shrink_single_no_move_3() -> Result<()> { let mut s = SingleThinS::new(1024, 1024, 2048, 2048); test_shrink(&mut s) } #[test] fn shrink_single_partial_move() -> Result<()> { let mut s = SingleThinS::new(1024, 1024, 2048, 1280); test_shrink(&mut s) } #[test] fn shrink_single_total_move() -> Result<()> { let mut s = SingleThinS::new(2048, 1024, 1024 + 2048, 1280); test_shrink(&mut s) } #[test] fn shrink_insufficient_space() -> Result<()> { let mut s = SingleThinS::new(0, 2048, 3000, 1280); match test_shrink(&mut s) { Ok(_) => Err(anyhow!("Shrink unexpectedly succeeded")), Err(_) => Ok(()), } } //------------------------------------ impl Scenario for FragmentedS { fn get_new_nr_blocks(&self) -> u64 { self.new_nr_data_blocks } } #[test] fn shrink_fragmented_thin_1() -> Result<()> { let mut s = FragmentedS::new(1, 2048); test_shrink(&mut s) } #[test] fn shrink_fragmented_thin_2() -> Result<()> { let mut s = FragmentedS::new(2, 2048); test_shrink(&mut s) } #[test] fn shrink_fragmented_thin_8() -> Result<()> { let mut s = FragmentedS::new(2, 2048); test_shrink(&mut s) } #[test] fn shrink_fragmented_thin_64() -> Result<()> { let mut s = FragmentedS::new(2, 2048); test_shrink(&mut s) } //------------------------------------ impl Scenario for SnapS { fn get_new_nr_blocks(&self) -> u64 { self.new_nr_data_blocks } } #[test] fn shrink_identical_snap() -> Result<()> { let mut s = SnapS::new(1024, 1, 0); test_shrink(&mut s) } //------------------------------------