use anyhow::{anyhow, Context, Result}; use ipfs_sqlite_block_store::BlockStore; use libipld::cbor::DagCborCodec; use libipld::multihash::Code; use libipld::prelude::Codec; use libipld::store::DefaultParams; use libipld::Block; use libipld::{Cid, DagCbor}; use log::{debug, error, info}; use std::collections::BTreeMap; use std::path::PathBuf; #[derive(Debug, DagCbor, PartialEq, Eq)] pub struct CommitNode { pub root: Cid, pub sig: Box<[u8]>, } #[derive(Debug, DagCbor, PartialEq, Eq)] pub struct RootNode { pub auth_token: Option, pub prev: Option, // TODO: not 'metadata'? pub meta: Cid, pub data: Cid, } #[derive(Debug, DagCbor, PartialEq, Eq)] pub struct MetadataNode { pub datastore: String, // "mst" pub did: String, pub version: u8, // 1 } #[derive(Debug, DagCbor, PartialEq, Eq)] struct MstEntry { k: String, p: u32, v: Cid, t: Option, } #[derive(Debug, DagCbor, PartialEq)] struct MstNode { l: Option, e: Vec, } struct WipEntry { height: u8, key: String, val: Cid, right: Option>, } struct WipNode { height: u8, left: Option>, entries: Vec, } fn get_mst_node(db: &mut BlockStore, cid: &Cid) -> Result { let block = &db .get_block(cid)? .ok_or(anyhow!("reading MST node from blockstore"))?; //println!("{:?}", block); let mst_node: MstNode = DagCborCodec .decode(block) .context("parsing MST DAG-CBOR IPLD node from blockstore")?; Ok(mst_node) } pub fn print_mst_keys(db: &mut BlockStore, cid: &Cid) -> Result<()> { let node = get_mst_node(db, cid)?; if let Some(ref left) = node.l { print_mst_keys(db, left)?; } let mut key: String = "".to_string(); for entry in node.e.iter() { key = format!("{}{}", &key[0..entry.p as usize], entry.k); println!("\t{}\t-> {}", key, entry.v); if let Some(ref right) = entry.t { print_mst_keys(db, right)?; } } Ok(()) } pub fn dump_mst_keys(db_path: &PathBuf) -> Result<()> { let mut db: BlockStore = BlockStore::open(db_path, Default::default())?; let all_aliases: Vec<(Vec, Cid)> = db.aliases()?; if all_aliases.is_empty() { error!("expected at least one alias in block store"); std::process::exit(-1); } // print all the aliases for (alias, commit_cid) in all_aliases.iter() { let did = String::from_utf8_lossy(alias); println!("{} -> {}", did, commit_cid); } let (did, commit_cid) = all_aliases[0].clone(); let did = String::from_utf8_lossy(&did); info!("starting from {} [{}]", commit_cid, did); // NOTE: the faster way to develop would have been to decode to libipld::ipld::Ipld first? meh debug!( "raw commit: {:?}", &db.get_block(&commit_cid)? .ok_or(anyhow!("expected commit block in store"))? ); let commit: CommitNode = DagCborCodec.decode( &db.get_block(&commit_cid)? .ok_or(anyhow!("expected commit block in store"))?, )?; debug!("Commit: {:?}", commit); let root: RootNode = DagCborCodec.decode( &db.get_block(&commit.root)? .ok_or(anyhow!("expected root block in store"))?, )?; debug!("Root: {:?}", root); let metadata: MetadataNode = DagCborCodec.decode( &db.get_block(&root.meta)? .ok_or(anyhow!("expected metadata block in store"))?, )?; debug!("Metadata: {:?}", metadata); let mst_node: MstNode = DagCborCodec.decode( &db.get_block(&root.data)? .ok_or(anyhow!("expected block in store"))?, )?; debug!("MST root node: {:?}", mst_node); debug!("============"); println!("{}", did); print_mst_keys(&mut db, &root.data)?; Ok(()) } pub fn collect_mst_keys( db: &mut BlockStore, cid: &Cid, map: &mut BTreeMap, ) -> Result<()> { let node = get_mst_node(db, cid)?; if let Some(ref left) = node.l { collect_mst_keys(db, left, map)?; } let mut key: String = "".to_string(); for entry in node.e.iter() { key = format!("{}{}", &key[0..entry.p as usize], entry.k); map.insert(key.clone(), entry.v); if let Some(ref right) = entry.t { collect_mst_keys(db, right, map)?; } } Ok(()) } fn leading_zeros(key: &str) -> u8 { let digest = sha256::digest(key); let digest = digest.as_bytes(); for (i, c) in digest.iter().enumerate() { if *c != b'0' { return i as u8; } } digest.len() as u8 } // # python code to generate test cases // import hashlib // seed = b"asdf" // while True: // out = hashlib.sha256(seed).hexdigest() // if out.startswith("00"): // print(f"{seed} -> {out}") // seed = b"app.bsky.feed.post/" + out.encode('utf8')[:12] #[test] fn test_leading_zeros() { assert_eq!(leading_zeros(""), 0); assert_eq!(leading_zeros("asdf"), 0); assert_eq!(leading_zeros("2653ae71"), 0); assert_eq!(leading_zeros("88bfafc7"), 1); assert_eq!(leading_zeros("2a92d355"), 2); assert_eq!(leading_zeros("884976f5"), 3); assert_eq!(leading_zeros("app.bsky.feed.post/454397e440ec"), 2); assert_eq!(leading_zeros("app.bsky.feed.post/9adeb165882c"), 4); } pub fn generate_mst( db: &mut BlockStore, map: &BTreeMap, ) -> Result { // construct a "WIP" tree let mut root: Option = None; for (key, val) in map { let height = leading_zeros(key); let entry = WipEntry { height, key: key.clone(), val: *val, right: None, }; if let Some(node) = root { root = Some(insert_entry(node, entry)); } else { root = Some(WipNode { height: entry.height, left: None, entries: vec![entry], }); } } let empty_node = WipNode { height: 0, left: None, entries: vec![], }; serialize_wip_tree(db, root.unwrap_or(empty_node)) } // this routine assumes that entries are added in sorted key order. AKA, the `entry` being added is // "further right" in the tree than any existing entries fn insert_entry(mut node: WipNode, entry: WipEntry) -> WipNode { // if we are higher on tree than existing node, replace it (recursively) with new layers first while entry.height > node.height { node = WipNode { height: node.height + 1, left: Some(Box::new(node)), entries: vec![], } } // if we are lower on tree, then need to descend first if entry.height < node.height { // if no entries at this node, then we should insert down "left" (which is just "down", not // "before" any entries) if node.entries.is_empty() { if let Some(left) = node.left { node.left = Some(Box::new(insert_entry(*left, entry))); return node; } else { panic!("hit existing totally empty MST node"); } } let mut last = node.entries.pop().expect("hit empty existing entry list"); assert!(entry.key > last.key); if last.right.is_some() { last.right = Some(Box::new(insert_entry(*last.right.unwrap(), entry))); } else { let mut new_node = WipNode { height: entry.height, left: None, entries: vec![entry], }; // may need to (recursively) insert multiple filler layers while new_node.height + 1 < node.height { new_node = WipNode { height: new_node.height + 1, left: Some(Box::new(new_node)), entries: vec![], } } last.right = Some(Box::new(new_node)); } node.entries.push(last); return node; } // same height, simply append to end (but verify first) assert!(node.height == entry.height); if !node.entries.is_empty() { let last = &node.entries.last().unwrap(); assert!(entry.key > last.key); } node.entries.push(entry); node } /// returns the length of common characters between the two strings. Strings must be simple ASCII, /// which should hold for current ATP MST keys (collection plus TID) fn common_prefix_len(a: &str, b: &str) -> usize { let a = a.as_bytes(); let b = b.as_bytes(); for i in 0..std::cmp::min(a.len(), b.len()) { if a[i] != b[i] { return i; } } // strings are the same, up to common length std::cmp::min(a.len(), b.len()) } #[test] fn test_common_prefix_len() { assert_eq!(common_prefix_len("abc", "abc"), 3); assert_eq!(common_prefix_len("", "abc"), 0); assert_eq!(common_prefix_len("abc", ""), 0); assert_eq!(common_prefix_len("ab", "abc"), 2); assert_eq!(common_prefix_len("abc", "ab"), 2); assert_eq!(common_prefix_len("abcde", "abc"), 3); assert_eq!(common_prefix_len("abc", "abcde"), 3); assert_eq!(common_prefix_len("abcde", "abc1"), 3); assert_eq!(common_prefix_len("abcde", "abb"), 2); assert_eq!(common_prefix_len("abcde", "qbb"), 0); assert_eq!(common_prefix_len("abc", "abc\x00"), 3); assert_eq!(common_prefix_len("abc\x00", "abc"), 3); } #[test] fn test_common_prefix_len_wide() { // TODO: these are not cross-language consistent! assert_eq!("jalapeño".len(), 9); // 8 in javascript assert_eq!("💩".len(), 4); // 2 in javascript assert_eq!("👩‍👧‍👧".len(), 18); // 8 in javascript // many of the below are different in JS; in Rust we *must* cast down to bytes to count assert_eq!(common_prefix_len("jalapeño", "jalapeno"), 6); assert_eq!(common_prefix_len("jalapeñoA", "jalapeñoB"), 9); assert_eq!(common_prefix_len("coöperative", "coüperative"), 3); assert_eq!(common_prefix_len("abc💩abc", "abcabc"), 3); assert_eq!(common_prefix_len("💩abc", "💩ab"), 6); assert_eq!(common_prefix_len("abc👩‍👦‍👦de", "abc👩‍👧‍👧de"), 13); } fn serialize_wip_tree( db: &mut BlockStore, wip_node: WipNode, ) -> Result { let left: Option = if let Some(left) = wip_node.left { Some(serialize_wip_tree(db, *left)?) } else { None }; let mut entries: Vec = vec![]; let mut last_key = "".to_string(); for wip_entry in wip_node.entries { let right: Option = if let Some(right) = wip_entry.right { Some(serialize_wip_tree(db, *right)?) } else { None }; let prefix_len = common_prefix_len(&last_key, &wip_entry.key); entries.push(MstEntry { k: wip_entry.key[prefix_len..].to_string(), p: prefix_len as u32, v: wip_entry.val, t: right, }); last_key = wip_entry.key; } let mst_node = MstNode { l: left, e: entries, }; let block = Block::::encode(DagCborCodec, Code::Sha2_256, &mst_node)?; let cid = *block.cid(); db.put_block(block, None)?; Ok(cid) }