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mentat/db/src/db.rs
Grisha Kruglov 31de5be64f Convert db/ to failure.
2018-06-20 14:42:34 -07:00

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// Copyright 2016 Mozilla
//
// Licensed under the Apache License, Version 2.0 (the "License"); you may not use
// this file except in compliance with the License. You may obtain a copy of the
// License at http://www.apache.org/licenses/LICENSE-2.0
// Unless required by applicable law or agreed to in writing, software distributed
// under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR
// CONDITIONS OF ANY KIND, either express or implied. See the License for the
// specific language governing permissions and limitations under the License.
#![allow(dead_code)]
use failure::ResultExt;
use std::borrow::Borrow;
use std::collections::HashMap;
use std::collections::hash_map::{
Entry,
};
use std::fmt::Display;
use std::iter::{once, repeat};
use std::ops::Range;
use std::path::Path;
use itertools;
use itertools::Itertools;
use rusqlite;
use rusqlite::TransactionBehavior;
use rusqlite::limits::Limit;
use rusqlite::types::{ToSql, ToSqlOutput};
use ::{repeat_values, to_namespaced_keyword};
use bootstrap;
use edn::{
DateTime,
Utc,
Uuid,
Value,
};
use entids;
use mentat_core::{
attribute,
Attribute,
AttributeBitFlags,
Entid,
FromMicros,
IdentMap,
Schema,
AttributeMap,
TypedValue,
ToMicros,
ValueType,
ValueRc,
};
use errors::{
DbError,
Result,
DbSqlErrorKind,
};
use metadata;
use schema::{
SchemaBuilding,
};
use types::{
AVMap,
AVPair,
DB,
Partition,
PartitionMap,
};
use tx::transact;
use watcher::{
NullWatcher,
};
// In PRAGMA foo='bar', `'bar'` must be a constant string (it cannot be a
// bound parameter), so we need to escape manually. According to
// https://www.sqlite.org/faq.html, the only character that must be escaped is
// the single quote, which is escaped by placing two single quotes in a row.
fn escape_string_for_pragma(s: &str) -> String {
s.replace("'", "''")
}
fn make_connection(uri: &Path, maybe_encryption_key: Option<&str>) -> rusqlite::Result<rusqlite::Connection> {
let conn = match uri.to_string_lossy().len() {
0 => rusqlite::Connection::open_in_memory()?,
_ => rusqlite::Connection::open(uri)?,
};
let page_size = 32768;
let initial_pragmas = if let Some(encryption_key) = maybe_encryption_key {
assert!(cfg!(feature = "sqlcipher"),
"This function shouldn't be called with a key unless we have sqlcipher support");
// Important: The `cipher_page_size` cannot be changed without breaking
// the ability to open databases that were written when using a
// different `cipher_page_size`. Additionally, it (AFAICT) must be a
// positive multiple of `page_size`. We use the same value for both here.
format!("
PRAGMA key='{}';
PRAGMA cipher_page_size={};
", escape_string_for_pragma(encryption_key), page_size)
} else {
String::new()
};
// See https://github.com/mozilla/mentat/issues/505 for details on temp_store
// pragma and how it might interact together with consumers such as Firefox.
// temp_store=2 is currently present to force SQLite to store temp files in memory.
// Some of the platforms we support do not have a tmp partition (e.g. Android)
// necessary to store temp files on disk. Ideally, consumers should be able to
// override this behaviour (see issue 505).
conn.execute_batch(&format!("
{}
PRAGMA journal_mode=wal;
PRAGMA wal_autocheckpoint=32;
PRAGMA journal_size_limit=3145728;
PRAGMA foreign_keys=ON;
PRAGMA temp_store=2;
", initial_pragmas))?;
Ok(conn)
}
pub fn new_connection<T>(uri: T) -> rusqlite::Result<rusqlite::Connection> where T: AsRef<Path> {
make_connection(uri.as_ref(), None)
}
#[cfg(feature = "sqlcipher")]
pub fn new_connection_with_key<P, S>(uri: P, encryption_key: S) -> rusqlite::Result<rusqlite::Connection>
where P: AsRef<Path>, S: AsRef<str> {
make_connection(uri.as_ref(), Some(encryption_key.as_ref()))
}
#[cfg(feature = "sqlcipher")]
pub fn change_encryption_key<S>(conn: &rusqlite::Connection, encryption_key: S) -> rusqlite::Result<()>
where S: AsRef<str> {
let escaped = escape_string_for_pragma(encryption_key.as_ref());
// `conn.execute` complains that this returns a result, and using a query
// for it requires more boilerplate.
conn.execute_batch(&format!("PRAGMA rekey = '{}';", escaped))
}
/// Version history:
///
/// 1: initial Rust Mentat schema.
pub const CURRENT_VERSION: i32 = 1;
/// MIN_SQLITE_VERSION should be changed when there's a new minimum version of sqlite required
/// for the project to work.
const MIN_SQLITE_VERSION: i32 = 3008000;
const TRUE: &'static bool = &true;
const FALSE: &'static bool = &false;
/// Turn an owned bool into a static reference to a bool.
///
/// `rusqlite` is designed around references to values; this lets us use computed bools easily.
#[inline(always)]
fn to_bool_ref(x: bool) -> &'static bool {
if x { TRUE } else { FALSE }
}
lazy_static! {
/// SQL statements to be executed, in order, to create the Mentat SQL schema (version 1).
#[cfg_attr(rustfmt, rustfmt_skip)]
static ref V1_STATEMENTS: Vec<&'static str> = { vec![
r#"CREATE TABLE datoms (e INTEGER NOT NULL, a SMALLINT NOT NULL, v BLOB NOT NULL, tx INTEGER NOT NULL,
value_type_tag SMALLINT NOT NULL,
index_avet TINYINT NOT NULL DEFAULT 0, index_vaet TINYINT NOT NULL DEFAULT 0,
index_fulltext TINYINT NOT NULL DEFAULT 0,
unique_value TINYINT NOT NULL DEFAULT 0)"#,
r#"CREATE UNIQUE INDEX idx_datoms_eavt ON datoms (e, a, value_type_tag, v)"#,
r#"CREATE UNIQUE INDEX idx_datoms_aevt ON datoms (a, e, value_type_tag, v)"#,
// Opt-in index: only if a has :db/index true.
r#"CREATE UNIQUE INDEX idx_datoms_avet ON datoms (a, value_type_tag, v, e) WHERE index_avet IS NOT 0"#,
// Opt-in index: only if a has :db/valueType :db.type/ref. No need for tag here since all
// indexed elements are refs.
r#"CREATE UNIQUE INDEX idx_datoms_vaet ON datoms (v, a, e) WHERE index_vaet IS NOT 0"#,
// Opt-in index: only if a has :db/fulltext true; thus, it has :db/valueType :db.type/string,
// which is not :db/valueType :db.type/ref. That is, index_vaet and index_fulltext are mutually
// exclusive.
r#"CREATE INDEX idx_datoms_fulltext ON datoms (value_type_tag, v, a, e) WHERE index_fulltext IS NOT 0"#,
// TODO: possibly remove this index. :db.unique/{value,identity} should be asserted by the
// transactor in all cases, but the index may speed up some of SQLite's query planning. For now,
// it serves to validate the transactor implementation. Note that tag is needed here to
// differentiate, e.g., keywords and strings.
r#"CREATE UNIQUE INDEX idx_datoms_unique_value ON datoms (a, value_type_tag, v) WHERE unique_value IS NOT 0"#,
r#"CREATE TABLE transactions (e INTEGER NOT NULL, a SMALLINT NOT NULL, v BLOB NOT NULL, tx INTEGER NOT NULL, added TINYINT NOT NULL DEFAULT 1, value_type_tag SMALLINT NOT NULL)"#,
r#"CREATE INDEX idx_transactions_tx ON transactions (tx, added)"#,
// Fulltext indexing.
// A fulltext indexed value v is an integer rowid referencing fulltext_values.
// Optional settings:
// tokenize="porter"#,
// prefix='2,3'
// By default we use Unicode-aware tokenizing (particularly for case folding), but preserve
// diacritics.
r#"CREATE VIRTUAL TABLE fulltext_values
USING FTS4 (text NOT NULL, searchid INT, tokenize=unicode61 "remove_diacritics=0")"#,
// This combination of view and triggers allows you to transparently
// update-or-insert into FTS. Just INSERT INTO fulltext_values_view (text, searchid).
r#"CREATE VIEW fulltext_values_view AS SELECT * FROM fulltext_values"#,
r#"CREATE TRIGGER replace_fulltext_searchid
INSTEAD OF INSERT ON fulltext_values_view
WHEN EXISTS (SELECT 1 FROM fulltext_values WHERE text = new.text)
BEGIN
UPDATE fulltext_values SET searchid = new.searchid WHERE text = new.text;
END"#,
r#"CREATE TRIGGER insert_fulltext_searchid
INSTEAD OF INSERT ON fulltext_values_view
WHEN NOT EXISTS (SELECT 1 FROM fulltext_values WHERE text = new.text)
BEGIN
INSERT INTO fulltext_values (text, searchid) VALUES (new.text, new.searchid);
END"#,
// A view transparently interpolating fulltext indexed values into the datom structure.
r#"CREATE VIEW fulltext_datoms AS
SELECT e, a, fulltext_values.text AS v, tx, value_type_tag, index_avet, index_vaet, index_fulltext, unique_value
FROM datoms, fulltext_values
WHERE datoms.index_fulltext IS NOT 0 AND datoms.v = fulltext_values.rowid"#,
// A view transparently interpolating all entities (fulltext and non-fulltext) into the datom structure.
r#"CREATE VIEW all_datoms AS
SELECT e, a, v, tx, value_type_tag, index_avet, index_vaet, index_fulltext, unique_value
FROM datoms
WHERE index_fulltext IS 0
UNION ALL
SELECT e, a, v, tx, value_type_tag, index_avet, index_vaet, index_fulltext, unique_value
FROM fulltext_datoms"#,
// Materialized views of the metadata.
r#"CREATE TABLE idents (e INTEGER NOT NULL, a SMALLINT NOT NULL, v BLOB NOT NULL, value_type_tag SMALLINT NOT NULL)"#,
r#"CREATE INDEX idx_idents_unique ON idents (e, a, v, value_type_tag)"#,
r#"CREATE TABLE schema (e INTEGER NOT NULL, a SMALLINT NOT NULL, v BLOB NOT NULL, value_type_tag SMALLINT NOT NULL)"#,
r#"CREATE INDEX idx_schema_unique ON schema (e, a, v, value_type_tag)"#,
// TODO: store entid instead of ident for partition name.
r#"CREATE TABLE parts (part TEXT NOT NULL PRIMARY KEY, start INTEGER NOT NULL, idx INTEGER NOT NULL)"#,
]
};
}
/// Set the SQLite user version.
///
/// Mentat manages its own SQL schema version using the user version. See the [SQLite
/// documentation](https://www.sqlite.org/pragma.html#pragma_user_version).
fn set_user_version(conn: &rusqlite::Connection, version: i32) -> Result<()> {
conn.execute(&format!("PRAGMA user_version = {}", version), &[])
.context(DbSqlErrorKind::CouldNotSetVersionPragma)?;
Ok(())
}
/// Get the SQLite user version.
///
/// Mentat manages its own SQL schema version using the user version. See the [SQLite
/// documentation](https://www.sqlite.org/pragma.html#pragma_user_version).
fn get_user_version(conn: &rusqlite::Connection) -> Result<i32> {
let v = conn.query_row("PRAGMA user_version", &[], |row| {
row.get(0)
}).context(DbSqlErrorKind::CouldNotGetVersionPragma)?;
Ok(v)
}
/// Do just enough work that either `create_current_version` or sync can populate the DB.
pub fn create_empty_current_version(conn: &mut rusqlite::Connection) -> Result<(rusqlite::Transaction, DB)> {
let tx = conn.transaction_with_behavior(TransactionBehavior::Exclusive)?;
for statement in (&V1_STATEMENTS).iter() {
tx.execute(statement, &[])?;
}
set_user_version(&tx, CURRENT_VERSION)?;
let bootstrap_schema = bootstrap::bootstrap_schema();
let bootstrap_partition_map = bootstrap::bootstrap_partition_map();
Ok((tx, DB::new(bootstrap_partition_map, bootstrap_schema)))
}
// TODO: rename "SQL" functions to align with "datoms" functions.
pub fn create_current_version(conn: &mut rusqlite::Connection) -> Result<DB> {
let (tx, mut db) = create_empty_current_version(conn)?;
// TODO: think more carefully about allocating new parts and bitmasking part ranges.
// TODO: install these using bootstrap assertions. It's tricky because the part ranges are implicit.
// TODO: one insert, chunk into 999/3 sections, for safety.
// This is necessary: `transact` will only UPDATE parts, not INSERT them if they're missing.
for (part, partition) in db.partition_map.iter() {
// TODO: Convert "keyword" part to SQL using Value conversion.
tx.execute("INSERT INTO parts VALUES (?, ?, ?)", &[part, &partition.start, &partition.index])?;
}
// TODO: return to transact_internal to self-manage the encompassing SQLite transaction.
let bootstrap_schema_for_mutation = Schema::default(); // The bootstrap transaction will populate this schema.
let (_report, next_partition_map, next_schema, _watcher) = transact(&tx, db.partition_map, &bootstrap_schema_for_mutation, &db.schema, NullWatcher(), bootstrap::bootstrap_entities())?;
// TODO: validate metadata mutations that aren't schema related, like additional partitions.
if let Some(next_schema) = next_schema {
if next_schema != db.schema {
bail!(DbError::NotYetImplemented(format!("Initial bootstrap transaction did not produce expected bootstrap schema")));
}
}
// TODO: use the drop semantics to do this automagically?
tx.commit()?;
db.partition_map = next_partition_map;
Ok(db)
}
pub fn ensure_current_version(conn: &mut rusqlite::Connection) -> Result<DB> {
if rusqlite::version_number() < MIN_SQLITE_VERSION {
panic!("Mentat requires at least sqlite {}", MIN_SQLITE_VERSION);
}
let user_version = get_user_version(&conn)?;
match user_version {
0 => create_current_version(conn),
CURRENT_VERSION => read_db(conn),
// TODO: support updating an existing store.
v => bail!(DbError::NotYetImplemented(format!("Opening databases with Mentat version: {}", v))),
}
}
pub trait TypedSQLValue {
fn from_sql_value_pair(value: rusqlite::types::Value, value_type_tag: i32) -> Result<TypedValue>;
fn to_sql_value_pair<'a>(&'a self) -> (ToSqlOutput<'a>, i32);
fn from_edn_value(value: &Value) -> Option<TypedValue>;
fn to_edn_value_pair(&self) -> (Value, ValueType);
}
impl TypedSQLValue for TypedValue {
/// Given a SQLite `value` and a `value_type_tag`, return the corresponding `TypedValue`.
fn from_sql_value_pair(value: rusqlite::types::Value, value_type_tag: i32) -> Result<TypedValue> {
match (value_type_tag, value) {
(0, rusqlite::types::Value::Integer(x)) => Ok(TypedValue::Ref(x)),
(1, rusqlite::types::Value::Integer(x)) => Ok(TypedValue::Boolean(0 != x)),
// Negative integers are simply times before 1970.
(4, rusqlite::types::Value::Integer(x)) => Ok(TypedValue::Instant(DateTime::<Utc>::from_micros(x))),
// SQLite distinguishes integral from decimal types, allowing long and double to
// share a tag.
(5, rusqlite::types::Value::Integer(x)) => Ok(TypedValue::Long(x)),
(5, rusqlite::types::Value::Real(x)) => Ok(TypedValue::Double(x.into())),
(10, rusqlite::types::Value::Text(x)) => Ok(x.into()),
(11, rusqlite::types::Value::Blob(x)) => {
let u = Uuid::from_bytes(x.as_slice());
if u.is_err() {
// Rather than exposing Uuid's ParseError…
bail!(DbError::BadSQLValuePair(rusqlite::types::Value::Blob(x),
value_type_tag));
}
Ok(TypedValue::Uuid(u.unwrap()))
},
(13, rusqlite::types::Value::Text(x)) => {
to_namespaced_keyword(&x).map(|k| k.into())
},
(_, value) => bail!(DbError::BadSQLValuePair(value, value_type_tag)),
}
}
/// Given an EDN `value`, return a corresponding Mentat `TypedValue`.
///
/// An EDN `Value` does not encode a unique Mentat `ValueType`, so the composition
/// `from_edn_value(first(to_edn_value_pair(...)))` loses information. Additionally, there are
/// EDN values which are not Mentat typed values.
///
/// This function is deterministic.
fn from_edn_value(value: &Value) -> Option<TypedValue> {
match value {
&Value::Boolean(x) => Some(TypedValue::Boolean(x)),
&Value::Instant(x) => Some(TypedValue::Instant(x)),
&Value::Integer(x) => Some(TypedValue::Long(x)),
&Value::Uuid(x) => Some(TypedValue::Uuid(x)),
&Value::Float(ref x) => Some(TypedValue::Double(x.clone())),
&Value::Text(ref x) => Some(x.clone().into()),
&Value::Keyword(ref x) => Some(x.clone().into()),
_ => None
}
}
/// Return the corresponding SQLite `value` and `value_type_tag` pair.
fn to_sql_value_pair<'a>(&'a self) -> (ToSqlOutput<'a>, i32) {
match self {
&TypedValue::Ref(x) => (rusqlite::types::Value::Integer(x).into(), 0),
&TypedValue::Boolean(x) => (rusqlite::types::Value::Integer(if x { 1 } else { 0 }).into(), 1),
&TypedValue::Instant(x) => (rusqlite::types::Value::Integer(x.to_micros()).into(), 4),
// SQLite distinguishes integral from decimal types, allowing long and double to share a tag.
&TypedValue::Long(x) => (rusqlite::types::Value::Integer(x).into(), 5),
&TypedValue::Double(x) => (rusqlite::types::Value::Real(x.into_inner()).into(), 5),
&TypedValue::String(ref x) => (rusqlite::types::ValueRef::Text(x.as_str()).into(), 10),
&TypedValue::Uuid(ref u) => (rusqlite::types::Value::Blob(u.as_bytes().to_vec()).into(), 11),
&TypedValue::Keyword(ref x) => (rusqlite::types::ValueRef::Text(&x.to_string()).into(), 13),
}
}
/// Return the corresponding EDN `value` and `value_type` pair.
fn to_edn_value_pair(&self) -> (Value, ValueType) {
match self {
&TypedValue::Ref(x) => (Value::Integer(x), ValueType::Ref),
&TypedValue::Boolean(x) => (Value::Boolean(x), ValueType::Boolean),
&TypedValue::Instant(x) => (Value::Instant(x), ValueType::Instant),
&TypedValue::Long(x) => (Value::Integer(x), ValueType::Long),
&TypedValue::Double(x) => (Value::Float(x), ValueType::Double),
&TypedValue::String(ref x) => (Value::Text(x.as_ref().clone()), ValueType::String),
&TypedValue::Uuid(ref u) => (Value::Uuid(u.clone()), ValueType::Uuid),
&TypedValue::Keyword(ref x) => (Value::Keyword(x.as_ref().clone()), ValueType::Keyword),
}
}
}
/// Read an arbitrary [e a v value_type_tag] materialized view from the given table in the SQL
/// store.
fn read_materialized_view(conn: &rusqlite::Connection, table: &str) -> Result<Vec<(Entid, Entid, TypedValue)>> {
let mut stmt: rusqlite::Statement = conn.prepare(format!("SELECT e, a, v, value_type_tag FROM {}", table).as_str())?;
let m: Result<Vec<(Entid, Entid, TypedValue)>> = stmt.query_and_then(&[], |row| {
let e: Entid = row.get_checked(0)?;
let a: Entid = row.get_checked(1)?;
let v: rusqlite::types::Value = row.get_checked(2)?;
let value_type_tag: i32 = row.get_checked(3)?;
let typed_value = TypedValue::from_sql_value_pair(v, value_type_tag)?;
Ok((e, a, typed_value))
})?.collect();
m
}
/// Read the partition map materialized view from the given SQL store.
fn read_partition_map(conn: &rusqlite::Connection) -> Result<PartitionMap> {
let mut stmt: rusqlite::Statement = conn.prepare("SELECT part, start, idx FROM parts")?;
let m = stmt.query_and_then(&[], |row| -> Result<(String, Partition)> {
Ok((row.get_checked(0)?, Partition::new(row.get_checked(1)?, row.get_checked(2)?)))
})?.collect();
m
}
/// Read the ident map materialized view from the given SQL store.
fn read_ident_map(conn: &rusqlite::Connection) -> Result<IdentMap> {
let v = read_materialized_view(conn, "idents")?;
v.into_iter().map(|(e, a, typed_value)| {
if a != entids::DB_IDENT {
bail!(DbError::NotYetImplemented(format!("bad idents materialized view: expected :db/ident but got {}", a)));
}
if let TypedValue::Keyword(keyword) = typed_value {
Ok((keyword.as_ref().clone(), e))
} else {
bail!(DbError::NotYetImplemented(format!("bad idents materialized view: expected [entid :db/ident keyword] but got [entid :db/ident {:?}]", typed_value)));
}
}).collect()
}
/// Read the schema materialized view from the given SQL store.
fn read_attribute_map(conn: &rusqlite::Connection) -> Result<AttributeMap> {
let entid_triples = read_materialized_view(conn, "schema")?;
let mut attribute_map = AttributeMap::default();
metadata::update_attribute_map_from_entid_triples(&mut attribute_map, entid_triples, ::std::iter::empty())?;
Ok(attribute_map)
}
/// Read the materialized views from the given SQL store and return a Mentat `DB` for querying and
/// applying transactions.
pub fn read_db(conn: &rusqlite::Connection) -> Result<DB> {
let partition_map = read_partition_map(conn)?;
let ident_map = read_ident_map(conn)?;
let attribute_map = read_attribute_map(conn)?;
let schema = Schema::from_ident_map_and_attribute_map(ident_map, attribute_map)?;
Ok(DB::new(partition_map, schema))
}
/// Internal representation of an [e a v added] datom, ready to be transacted against the store.
pub type ReducedEntity<'a> = (Entid, Entid, &'a Attribute, TypedValue, bool);
#[derive(Clone,Debug,Eq,Hash,Ord,PartialOrd,PartialEq)]
pub enum SearchType {
Exact,
Inexact,
}
/// `MentatStoring` will be the trait that encapsulates the storage layer. It is consumed by the
/// transaction processing layer.
///
/// Right now, the only implementation of `MentatStoring` is the SQLite-specific SQL schema. In the
/// future, we might consider other SQL engines (perhaps with different fulltext indexing), or
/// entirely different data stores, say ones shaped like key-value stores.
pub trait MentatStoring {
/// Given a slice of [a v] lookup-refs, look up the corresponding [e a v] triples.
///
/// It is assumed that the attribute `a` in each lookup-ref is `:db/unique`, so that at most one
/// matching [e a v] triple exists. (If this is not true, some matching entid `e` will be
/// chosen non-deterministically, if one exists.)
///
/// Returns a map &(a, v) -> e, to avoid cloning potentially large values. The keys of the map
/// are exactly those (a, v) pairs that have an assertion [e a v] in the store.
fn resolve_avs<'a>(&self, avs: &'a [&'a AVPair]) -> Result<AVMap<'a>>;
/// Begin (or prepare) the underlying storage layer for a new Mentat transaction.
///
/// Use this to create temporary tables, prepare indices, set pragmas, etc, before the initial
/// `insert_non_fts_searches` invocation.
fn begin_tx_application(&self) -> Result<()>;
// TODO: this is not a reasonable abstraction, but I don't want to really consider non-SQL storage just yet.
fn insert_non_fts_searches<'a>(&self, entities: &'a [ReducedEntity], search_type: SearchType) -> Result<()>;
fn insert_fts_searches<'a>(&self, entities: &'a [ReducedEntity], search_type: SearchType) -> Result<()>;
/// Finalize the underlying storage layer after a Mentat transaction.
///
/// Use this to finalize temporary tables, complete indices, revert pragmas, etc, after the
/// final `insert_non_fts_searches` invocation.
fn commit_transaction(&self, tx_id: Entid) -> Result<()>;
/// Extract metadata-related [e a typed_value added] datoms committed in the given transaction.
fn committed_metadata_assertions(&self, tx_id: Entid) -> Result<Vec<(Entid, Entid, TypedValue, bool)>>;
}
/// Take search rows and complete `temp.search_results`.
///
/// See https://github.com/mozilla/mentat/wiki/Transacting:-entity-to-SQL-translation.
fn search(conn: &rusqlite::Connection) -> Result<()> {
// First is fast, only one table walk: lookup by exact eav.
// Second is slower, but still only one table walk: lookup old value by ea.
let s = r#"
INSERT INTO temp.search_results
SELECT t.e0, t.a0, t.v0, t.value_type_tag0, t.added0, t.flags0, ':db.cardinality/many', d.rowid, d.v
FROM temp.exact_searches AS t
LEFT JOIN datoms AS d
ON t.e0 = d.e AND
t.a0 = d.a AND
t.value_type_tag0 = d.value_type_tag AND
t.v0 = d.v
UNION ALL
SELECT t.e0, t.a0, t.v0, t.value_type_tag0, t.added0, t.flags0, ':db.cardinality/one', d.rowid, d.v
FROM temp.inexact_searches AS t
LEFT JOIN datoms AS d
ON t.e0 = d.e AND
t.a0 = d.a"#;
let mut stmt = conn.prepare_cached(s)?;
stmt.execute(&[]).context(DbSqlErrorKind::CouldNotSearch)?;
Ok(())
}
/// Insert the new transaction into the `transactions` table.
///
/// This turns the contents of `search_results` into a new transaction.
///
/// See https://github.com/mozilla/mentat/wiki/Transacting:-entity-to-SQL-translation.
fn insert_transaction(conn: &rusqlite::Connection, tx: Entid) -> Result<()> {
// Mentat follows Datomic and treats its input as a set. That means it is okay to transact the
// same [e a v] twice in one transaction. However, we don't want to represent the transacted
// datom twice. Therefore, the transactor unifies repeated datoms, and in addition we add
// indices to the search inputs and search results to ensure that we don't see repeated datoms
// at this point.
let s = r#"
INSERT INTO transactions (e, a, v, tx, added, value_type_tag)
SELECT e0, a0, v0, ?, 1, value_type_tag0
FROM temp.search_results
WHERE added0 IS 1 AND ((rid IS NULL) OR ((rid IS NOT NULL) AND (v0 IS NOT v)))"#;
let mut stmt = conn.prepare_cached(s)?;
stmt.execute(&[&tx]).context(DbSqlErrorKind::TxInsertFailedToAddMissingDatoms)?;
let s = r#"
INSERT INTO transactions (e, a, v, tx, added, value_type_tag)
SELECT e0, a0, v, ?, 0, value_type_tag0
FROM temp.search_results
WHERE rid IS NOT NULL AND
((added0 IS 0) OR
(added0 IS 1 AND search_type IS ':db.cardinality/one' AND v0 IS NOT v))"#;
let mut stmt = conn.prepare_cached(s)?;
stmt.execute(&[&tx]).context(DbSqlErrorKind::TxInsertFailedToRetractDatoms)?;
Ok(())
}
/// Update the contents of the `datoms` materialized view with the new transaction.
///
/// This applies the contents of `search_results` to the `datoms` table (in place).
///
/// See https://github.com/mozilla/mentat/wiki/Transacting:-entity-to-SQL-translation.
fn update_datoms(conn: &rusqlite::Connection, tx: Entid) -> Result<()> {
// Delete datoms that were retracted, or those that were :db.cardinality/one and will be
// replaced.
let s = r#"
WITH ids AS (SELECT rid
FROM temp.search_results
WHERE rid IS NOT NULL AND
((added0 IS 0) OR
(added0 IS 1 AND search_type IS ':db.cardinality/one' AND v0 IS NOT v)))
DELETE FROM datoms WHERE rowid IN ids"#;
let mut stmt = conn.prepare_cached(s)?;
stmt.execute(&[]).context(DbSqlErrorKind::DatomsUpdateFailedToRetract)?;
// Insert datoms that were added and not already present. We also must expand our bitfield into
// flags. Since Mentat follows Datomic and treats its input as a set, it is okay to transact
// the same [e a v] twice in one transaction, but we don't want to represent the transacted
// datom twice in datoms. The transactor unifies repeated datoms, and in addition we add
// indices to the search inputs and search results to ensure that we don't see repeated datoms
// at this point.
let s = format!(r#"
INSERT INTO datoms (e, a, v, tx, value_type_tag, index_avet, index_vaet, index_fulltext, unique_value)
SELECT e0, a0, v0, ?, value_type_tag0,
flags0 & {} IS NOT 0,
flags0 & {} IS NOT 0,
flags0 & {} IS NOT 0,
flags0 & {} IS NOT 0
FROM temp.search_results
WHERE added0 IS 1 AND ((rid IS NULL) OR ((rid IS NOT NULL) AND (v0 IS NOT v)))"#,
AttributeBitFlags::IndexAVET as u8,
AttributeBitFlags::IndexVAET as u8,
AttributeBitFlags::IndexFulltext as u8,
AttributeBitFlags::UniqueValue as u8);
let mut stmt = conn.prepare_cached(&s)?;
stmt.execute(&[&tx]).context(DbSqlErrorKind::DatomsUpdateFailedToAdd)?;
Ok(())
}
impl MentatStoring for rusqlite::Connection {
fn resolve_avs<'a>(&self, avs: &'a [&'a AVPair]) -> Result<AVMap<'a>> {
// Start search_id's at some identifiable number.
let initial_search_id = 2000;
let bindings_per_statement = 4;
// We map [a v] -> numeric search_id -> e, and then we use the search_id lookups to finally
// produce the map [a v] -> e.
//
// TODO: `collect` into a HashSet so that any (a, v) is resolved at most once.
let max_vars = self.limit(Limit::SQLITE_LIMIT_VARIABLE_NUMBER) as usize;
let chunks: itertools::IntoChunks<_> = avs.into_iter().enumerate().chunks(max_vars / 4);
// We'd like to `flat_map` here, but it's not obvious how to `flat_map` across `Result`.
// Alternatively, this is a `fold`, and it might be wise to express it as such.
let results: Result<Vec<Vec<_>>> = chunks.into_iter().map(|chunk| -> Result<Vec<_>> {
let mut count = 0;
// We must keep these computed values somewhere to reference them later, so we can't
// combine this `map` and the subsequent `flat_map`.
let block: Vec<(i64, i64, ToSqlOutput<'a>, i32)> = chunk.map(|(index, &&(a, ref v))| {
count += 1;
let search_id: i64 = initial_search_id + index as i64;
let (value, value_type_tag) = v.to_sql_value_pair();
(search_id, a, value, value_type_tag)
}).collect();
// `params` reference computed values in `block`.
let params: Vec<&ToSql> = block.iter().flat_map(|&(ref searchid, ref a, ref value, ref value_type_tag)| {
// Avoid inner heap allocation.
once(searchid as &ToSql)
.chain(once(a as &ToSql)
.chain(once(value as &ToSql)
.chain(once(value_type_tag as &ToSql))))
}).collect();
// TODO: cache these statements for selected values of `count`.
// TODO: query against `datoms` and UNION ALL with `fulltext_datoms` rather than
// querying against `all_datoms`. We know all the attributes, and in the common case,
// where most unique attributes will not be fulltext-indexed, we'll be querying just
// `datoms`, which will be much faster.ˇ
assert!(bindings_per_statement * count < max_vars, "Too many values: {} * {} >= {}", bindings_per_statement, count, max_vars);
let values: String = repeat_values(bindings_per_statement, count);
let s: String = format!("WITH t(search_id, a, v, value_type_tag) AS (VALUES {}) SELECT t.search_id, d.e \
FROM t, all_datoms AS d \
WHERE d.index_avet IS NOT 0 AND d.a = t.a AND d.value_type_tag = t.value_type_tag AND d.v = t.v",
values);
let mut stmt: rusqlite::Statement = self.prepare(s.as_str())?;
let m: Result<Vec<(i64, Entid)>> = stmt.query_and_then(&params, |row| -> Result<(i64, Entid)> {
Ok((row.get_checked(0)?, row.get_checked(1)?))
})?.collect();
m
}).collect::<Result<Vec<Vec<(i64, Entid)>>>>();
// Flatten.
let results: Vec<(i64, Entid)> = results?.as_slice().concat();
// Create map [a v] -> e.
let m: HashMap<&'a AVPair, Entid> = results.into_iter().map(|(search_id, entid)| {
let index: usize = (search_id - initial_search_id) as usize;
(avs[index], entid)
}).collect();
Ok(m)
}
/// Create empty temporary tables for search parameters and search results.
fn begin_tx_application(&self) -> Result<()> {
// We can't do this in one shot, since we can't prepare a batch statement.
let statements = [
r#"DROP TABLE IF EXISTS temp.exact_searches"#,
// Note that `flags0` is a bitfield of several flags compressed via
// `AttributeBitFlags.flags()` in the temporary search tables, later
// expanded in the `datoms` insertion.
r#"CREATE TABLE temp.exact_searches (
e0 INTEGER NOT NULL,
a0 SMALLINT NOT NULL,
v0 BLOB NOT NULL,
value_type_tag0 SMALLINT NOT NULL,
added0 TINYINT NOT NULL,
flags0 TINYINT NOT NULL)"#,
// There's no real need to split exact and inexact searches, so long as we keep things
// in the correct place and performant. Splitting has the advantage of being explicit
// and slightly easier to read, so we'll do that to start.
r#"DROP TABLE IF EXISTS temp.inexact_searches"#,
r#"CREATE TABLE temp.inexact_searches (
e0 INTEGER NOT NULL,
a0 SMALLINT NOT NULL,
v0 BLOB NOT NULL,
value_type_tag0 SMALLINT NOT NULL,
added0 TINYINT NOT NULL,
flags0 TINYINT NOT NULL)"#,
// It is fine to transact the same [e a v] twice in one transaction, but the transaction
// processor should unify such repeated datoms. This index will cause insertion to fail
// if the transaction processor incorrectly tries to assert the same (cardinality one)
// datom twice. (Sadly, the failure is opaque.)
r#"CREATE UNIQUE INDEX IF NOT EXISTS temp.inexact_searches_unique ON inexact_searches (e0, a0) WHERE added0 = 1"#,
r#"DROP TABLE IF EXISTS temp.search_results"#,
// TODO: don't encode search_type as a STRING. This is explicit and much easier to read
// than another flag, so we'll do it to start, and optimize later.
r#"CREATE TABLE temp.search_results (
e0 INTEGER NOT NULL,
a0 SMALLINT NOT NULL,
v0 BLOB NOT NULL,
value_type_tag0 SMALLINT NOT NULL,
added0 TINYINT NOT NULL,
flags0 TINYINT NOT NULL,
search_type STRING NOT NULL,
rid INTEGER,
v BLOB)"#,
// It is fine to transact the same [e a v] twice in one transaction, but the transaction
// processor should identify those datoms. This index will cause insertion to fail if
// the internals of the database searching code incorrectly find the same datom twice.
// (Sadly, the failure is opaque.)
//
// N.b.: temp goes on index name, not table name. See http://stackoverflow.com/a/22308016.
r#"CREATE UNIQUE INDEX IF NOT EXISTS temp.search_results_unique ON search_results (e0, a0, v0, value_type_tag0)"#,
];
for statement in &statements {
let mut stmt = self.prepare_cached(statement)?;
stmt.execute(&[]).context(DbSqlErrorKind::FailedToCreateTempTables)?;
}
Ok(())
}
/// Insert search rows into temporary search tables.
///
/// Eventually, the details of this approach will be captured in
/// https://github.com/mozilla/mentat/wiki/Transacting:-entity-to-SQL-translation.
fn insert_non_fts_searches<'a>(&self, entities: &'a [ReducedEntity<'a>], search_type: SearchType) -> Result<()> {
let bindings_per_statement = 6;
let max_vars = self.limit(Limit::SQLITE_LIMIT_VARIABLE_NUMBER) as usize;
let chunks: itertools::IntoChunks<_> = entities.into_iter().chunks(max_vars / bindings_per_statement);
// We'd like to flat_map here, but it's not obvious how to flat_map across Result.
let results: Result<Vec<()>> = chunks.into_iter().map(|chunk| -> Result<()> {
let mut count = 0;
// We must keep these computed values somewhere to reference them later, so we can't
// combine this map and the subsequent flat_map.
// (e0, a0, v0, value_type_tag0, added0, flags0)
let block: Result<Vec<(i64 /* e */,
i64 /* a */,
ToSqlOutput<'a> /* value */,
i32 /* value_type_tag */,
bool, /* added0 */
u8 /* flags0 */)>> = chunk.map(|&(e, a, ref attribute, ref typed_value, added)| {
count += 1;
// Now we can represent the typed value as an SQL value.
let (value, value_type_tag): (ToSqlOutput, i32) = typed_value.to_sql_value_pair();
Ok((e, a, value, value_type_tag, added, attribute.flags()))
}).collect();
let block = block?;
// `params` reference computed values in `block`.
let params: Vec<&ToSql> = block.iter().flat_map(|&(ref e, ref a, ref value, ref value_type_tag, added, ref flags)| {
// Avoid inner heap allocation.
// TODO: extract some finite length iterator to make this less indented!
once(e as &ToSql)
.chain(once(a as &ToSql)
.chain(once(value as &ToSql)
.chain(once(value_type_tag as &ToSql)
.chain(once(to_bool_ref(added) as &ToSql)
.chain(once(flags as &ToSql))))))
}).collect();
// TODO: cache this for selected values of count.
assert!(bindings_per_statement * count < max_vars, "Too many values: {} * {} >= {}", bindings_per_statement, count, max_vars);
let values: String = repeat_values(bindings_per_statement, count);
let s: String = if search_type == SearchType::Exact {
format!("INSERT INTO temp.exact_searches (e0, a0, v0, value_type_tag0, added0, flags0) VALUES {}", values)
} else {
// This will err for duplicates within the tx.
format!("INSERT INTO temp.inexact_searches (e0, a0, v0, value_type_tag0, added0, flags0) VALUES {}", values)
};
// TODO: consider ensuring we inserted the expected number of rows.
let mut stmt = self.prepare_cached(s.as_str())?;
stmt.execute(&params)
.context(DbSqlErrorKind::NonFtsInsertionIntoTempSearchTableFailed)
.map_err(|e| e.into())
.map(|_c| ())
}).collect::<Result<Vec<()>>>();
results.map(|_| ())
}
/// Insert search rows into temporary search tables.
///
/// Eventually, the details of this approach will be captured in
/// https://github.com/mozilla/mentat/wiki/Transacting:-entity-to-SQL-translation.
fn insert_fts_searches<'a>(&self, entities: &'a [ReducedEntity<'a>], search_type: SearchType) -> Result<()> {
let max_vars = self.limit(Limit::SQLITE_LIMIT_VARIABLE_NUMBER) as usize;
let bindings_per_statement = 6;
let mut outer_searchid = 2000;
let chunks: itertools::IntoChunks<_> = entities.into_iter().chunks(max_vars / bindings_per_statement);
// From string to (searchid, value_type_tag).
let mut seen: HashMap<ValueRc<String>, (i64, i32)> = HashMap::with_capacity(entities.len());
// We'd like to flat_map here, but it's not obvious how to flat_map across Result.
let results: Result<Vec<()>> = chunks.into_iter().map(|chunk| -> Result<()> {
let mut datom_count = 0;
let mut string_count = 0;
// We must keep these computed values somewhere to reference them later, so we can't
// combine this map and the subsequent flat_map.
// (e0, a0, v0, value_type_tag0, added0, flags0)
let block: Result<Vec<(i64 /* e */,
i64 /* a */,
Option<ToSqlOutput<'a>> /* value */,
i32 /* value_type_tag */,
bool /* added0 */,
u8 /* flags0 */,
i64 /* searchid */)>> = chunk.map(|&(e, a, ref attribute, ref typed_value, added)| {
match typed_value {
&TypedValue::String(ref rc) => {
datom_count += 1;
let entry = seen.entry(rc.clone());
match entry {
Entry::Occupied(entry) => {
let &(searchid, value_type_tag) = entry.get();
Ok((e, a, None, value_type_tag, added, attribute.flags(), searchid))
},
Entry::Vacant(entry) => {
outer_searchid += 1;
string_count += 1;
// Now we can represent the typed value as an SQL value.
let (value, value_type_tag): (ToSqlOutput, i32) = typed_value.to_sql_value_pair();
entry.insert((outer_searchid, value_type_tag));
Ok((e, a, Some(value), value_type_tag, added, attribute.flags(), outer_searchid))
}
}
},
_ => {
bail!(DbError::WrongTypeValueForFtsAssertion);
},
}
}).collect();
let block = block?;
// First, insert all fulltext string values.
// `fts_params` reference computed values in `block`.
let fts_params: Vec<&ToSql> =
block.iter()
.filter(|&&(ref _e, ref _a, ref value, ref _value_type_tag, _added, ref _flags, ref _searchid)| {
value.is_some()
})
.flat_map(|&(ref _e, ref _a, ref value, ref _value_type_tag, _added, ref _flags, ref searchid)| {
// Avoid inner heap allocation.
once(value as &ToSql)
.chain(once(searchid as &ToSql))
}).collect();
// TODO: make this maximally efficient. It's not terribly inefficient right now.
let fts_values: String = repeat_values(2, string_count);
let fts_s: String = format!("INSERT INTO fulltext_values_view (text, searchid) VALUES {}", fts_values);
// TODO: consider ensuring we inserted the expected number of rows.
let mut stmt = self.prepare_cached(fts_s.as_str())?;
stmt.execute(&fts_params).context(DbSqlErrorKind::FtsInsertionFailed)?;
// Second, insert searches.
// `params` reference computed values in `block`.
let params: Vec<&ToSql> = block.iter().flat_map(|&(ref e, ref a, ref _value, ref value_type_tag, added, ref flags, ref searchid)| {
// Avoid inner heap allocation.
// TODO: extract some finite length iterator to make this less indented!
once(e as &ToSql)
.chain(once(a as &ToSql)
.chain(once(searchid as &ToSql)
.chain(once(value_type_tag as &ToSql)
.chain(once(to_bool_ref(added) as &ToSql)
.chain(once(flags as &ToSql))))))
}).collect();
// TODO: cache this for selected values of count.
assert!(bindings_per_statement * datom_count < max_vars, "Too many values: {} * {} >= {}", bindings_per_statement, datom_count, max_vars);
let inner = "(?, ?, (SELECT rowid FROM fulltext_values WHERE searchid = ?), ?, ?, ?)".to_string();
// Like "(?, ?, (SELECT rowid FROM fulltext_values WHERE searchid = ?), ?, ?, ?), (?, ?, (SELECT rowid FROM fulltext_values WHERE searchid = ?), ?, ?, ?)".
let fts_values: String = repeat(inner).take(datom_count).join(", ");
let s: String = if search_type == SearchType::Exact {
format!("INSERT INTO temp.exact_searches (e0, a0, v0, value_type_tag0, added0, flags0) VALUES {}", fts_values)
} else {
format!("INSERT INTO temp.inexact_searches (e0, a0, v0, value_type_tag0, added0, flags0) VALUES {}", fts_values)
};
// TODO: consider ensuring we inserted the expected number of rows.
let mut stmt = self.prepare_cached(s.as_str())?;
stmt.execute(&params).context(DbSqlErrorKind::FtsInsertionIntoTempSearchTableFailed)
.map_err(|e| e.into())
.map(|_c| ())
}).collect::<Result<Vec<()>>>();
// Finally, clean up temporary searchids.
let mut stmt = self.prepare_cached("UPDATE fulltext_values SET searchid = NULL WHERE searchid IS NOT NULL")?;
stmt.execute(&[]).context(DbSqlErrorKind::FtsFailedToDropSearchIds)?;
results.map(|_| ())
}
fn commit_transaction(&self, tx_id: Entid) -> Result<()> {
search(&self)?;
insert_transaction(&self, tx_id)?;
update_datoms(&self, tx_id)?;
Ok(())
}
fn committed_metadata_assertions(&self, tx_id: Entid) -> Result<Vec<(Entid, Entid, TypedValue, bool)>> {
// TODO: use concat! to avoid creating String instances.
let mut stmt = self.prepare_cached(format!("SELECT e, a, v, value_type_tag, added FROM transactions WHERE tx = ? AND a IN {} ORDER BY e, a, v, value_type_tag, added", entids::METADATA_SQL_LIST.as_str()).as_str())?;
let params = [&tx_id as &ToSql];
let m: Result<Vec<_>> = stmt.query_and_then(&params[..], |row| -> Result<(Entid, Entid, TypedValue, bool)> {
Ok((row.get_checked(0)?,
row.get_checked(1)?,
TypedValue::from_sql_value_pair(row.get_checked(2)?, row.get_checked(3)?)?,
row.get_checked(4)?))
})?.collect();
m
}
}
/// Update the current partition map materialized view.
// TODO: only update changed partitions.
pub fn update_partition_map(conn: &rusqlite::Connection, partition_map: &PartitionMap) -> Result<()> {
let values_per_statement = 2;
let max_vars = conn.limit(Limit::SQLITE_LIMIT_VARIABLE_NUMBER) as usize;
let max_partitions = max_vars / values_per_statement;
if partition_map.len() > max_partitions {
bail!(DbError::NotYetImplemented(format!("No more than {} partitions are supported", max_partitions)));
}
// Like "UPDATE parts SET idx = CASE WHEN part = ? THEN ? WHEN part = ? THEN ? ELSE idx END".
let s = format!("UPDATE parts SET idx = CASE {} ELSE idx END",
repeat("WHEN part = ? THEN ?").take(partition_map.len()).join(" "));
let params: Vec<&ToSql> = partition_map.iter().flat_map(|(name, partition)| {
once(name as &ToSql)
.chain(once(&partition.index as &ToSql))
}).collect();
// TODO: only cache the latest of these statements. Changing the set of partitions isn't
// supported in the Clojure implementation at all, and might not be supported in Mentat soon,
// so this is very low priority.
let mut stmt = conn.prepare_cached(s.as_str())?;
stmt.execute(&params[..]).context(DbSqlErrorKind::FailedToUpdatePartitionMap)?;
Ok(())
}
/// Update the metadata materialized views based on the given metadata report.
///
/// This updates the "entids", "idents", and "schema" materialized views, copying directly from the
/// "datoms" and "transactions" table as appropriate.
pub fn update_metadata(conn: &rusqlite::Connection, _old_schema: &Schema, new_schema: &Schema, metadata_report: &metadata::MetadataReport) -> Result<()>
{
use metadata::AttributeAlteration::*;
// Populate the materialized view directly from datoms (and, potentially in the future,
// transactions). This might generalize nicely as we expand the set of materialized views.
// TODO: consider doing this in fewer SQLite execute() invocations.
// TODO: use concat! to avoid creating String instances.
if !metadata_report.idents_altered.is_empty() {
// Idents is the materialized view of the [entid :db/ident ident] slice of datoms.
conn.execute(format!("DELETE FROM idents").as_str(),
&[])?;
conn.execute(format!("INSERT INTO idents SELECT e, a, v, value_type_tag FROM datoms WHERE a IN {}", entids::IDENTS_SQL_LIST.as_str()).as_str(),
&[])?;
}
let mut stmt = conn.prepare(format!("INSERT INTO schema SELECT e, a, v, value_type_tag FROM datoms WHERE e = ? AND a IN {}", entids::SCHEMA_SQL_LIST.as_str()).as_str())?;
for &entid in &metadata_report.attributes_installed {
stmt.execute(&[&entid as &ToSql])?;
}
let mut delete_stmt = conn.prepare(format!("DELETE FROM schema WHERE e = ? AND a IN {}", entids::SCHEMA_SQL_LIST.as_str()).as_str())?;
let mut insert_stmt = conn.prepare(format!("INSERT INTO schema SELECT e, a, v, value_type_tag FROM datoms WHERE e = ? AND a IN {}", entids::SCHEMA_SQL_LIST.as_str()).as_str())?;
let mut index_stmt = conn.prepare("UPDATE datoms SET index_avet = ? WHERE a = ?")?;
let mut unique_value_stmt = conn.prepare("UPDATE datoms SET unique_value = ? WHERE a = ?")?;
let mut cardinality_stmt = conn.prepare(r#"
SELECT EXISTS
(SELECT 1
FROM datoms AS left, datoms AS right
WHERE left.a = ? AND
left.a = right.a AND
left.e = right.e AND
left.v <> right.v)"#)?;
for (&entid, alterations) in &metadata_report.attributes_altered {
delete_stmt.execute(&[&entid as &ToSql])?;
insert_stmt.execute(&[&entid as &ToSql])?;
let attribute = new_schema.require_attribute_for_entid(entid)?;
for alteration in alterations {
match alteration {
&Index => {
// This should always succeed.
index_stmt.execute(&[&attribute.index, &entid as &ToSql])?;
},
&Unique => {
// TODO: This can fail if there are conflicting values; give a more helpful
// error message in this case.
if unique_value_stmt.execute(&[to_bool_ref(attribute.unique.is_some()), &entid as &ToSql]).is_err() {
match attribute.unique {
Some(attribute::Unique::Value) => bail!(DbError::SchemaAlterationFailed(format!("Cannot alter schema attribute {} to be :db.unique/value", entid))),
Some(attribute::Unique::Identity) => bail!(DbError::SchemaAlterationFailed(format!("Cannot alter schema attribute {} to be :db.unique/identity", entid))),
None => unreachable!(), // This shouldn't happen, even after we support removing :db/unique.
}
}
},
&Cardinality => {
// We can always go from :db.cardinality/one to :db.cardinality many. It's
// :db.cardinality/many to :db.cardinality/one that can fail.
//
// TODO: improve the failure message. Perhaps try to mimic what Datomic says in
// this case?
if !attribute.multival {
let mut rows = cardinality_stmt.query(&[&entid as &ToSql])?;
if rows.next().is_some() {
bail!(DbError::SchemaAlterationFailed(format!("Cannot alter schema attribute {} to be :db.cardinality/one", entid)));
}
}
},
&NoHistory | &IsComponent => {
// There's no on disk change required for either of these.
},
}
}
}
Ok(())
}
pub trait PartitionMapping {
fn allocate_entid<S: ?Sized + Ord + Display>(&mut self, partition: &S) -> i64 where String: Borrow<S>;
fn allocate_entids<S: ?Sized + Ord + Display>(&mut self, partition: &S, n: usize) -> Range<i64> where String: Borrow<S>;
fn contains_entid(&self, entid: Entid) -> bool;
}
impl PartitionMapping for PartitionMap {
/// Allocate a single fresh entid in the given `partition`.
fn allocate_entid<S: ?Sized + Ord + Display>(&mut self, partition: &S) -> i64 where String: Borrow<S> {
self.allocate_entids(partition, 1).start
}
/// Allocate `n` fresh entids in the given `partition`.
fn allocate_entids<S: ?Sized + Ord + Display>(&mut self, partition: &S, n: usize) -> Range<i64> where String: Borrow<S> {
match self.get_mut(partition) {
Some(partition) => {
let idx = partition.index;
partition.index += n as i64;
idx..partition.index
},
// This is a programming error.
None => panic!("Cannot allocate entid from unknown partition: {}", partition),
}
}
fn contains_entid(&self, entid: Entid) -> bool {
self.values().any(|partition| partition.contains_entid(entid))
}
}
#[cfg(test)]
mod tests {
extern crate env_logger;
use super::*;
use bootstrap;
use debug;
use errors;
use edn;
use mentat_core::{
HasSchema,
Keyword,
KnownEntid,
attribute,
};
use mentat_core::intern_set::{
InternSet,
};
use mentat_core::util::Either::*;
use edn::entities::{
OpType,
TempId,
};
use rusqlite;
use std::collections::{
BTreeMap,
};
use internal_types::{
Term,
TermWithTempIds,
};
use types::TxReport;
use tx::{
transact_terms,
};
// Macro to parse a `Borrow<str>` to an `edn::Value` and assert the given `edn::Value` `matches`
// against it.
//
// This is a macro only to give nice line numbers when tests fail.
macro_rules! assert_matches {
( $input: expr, $expected: expr ) => {{
// Failure to parse the expected pattern is a coding error, so we unwrap.
let pattern_value = edn::parse::value($expected.borrow())
.expect(format!("to be able to parse expected {}", $expected).as_str())
.without_spans();
assert!($input.matches(&pattern_value),
"Expected value:\n{}\nto match pattern:\n{}\n",
$input.to_pretty(120).unwrap(),
pattern_value.to_pretty(120).unwrap());
}}
}
// Transact $input against the given $conn, expecting success or a `Result<TxReport, String>`.
//
// This unwraps safely and makes asserting errors pleasant.
macro_rules! assert_transact {
( $conn: expr, $input: expr, $expected: expr ) => {{
trace!("assert_transact: {}", $input);
let result = $conn.transact($input).map_err(|e| e.to_string());
assert_eq!(result, $expected.map_err(|e| e.to_string()));
}};
( $conn: expr, $input: expr ) => {{
trace!("assert_transact: {}", $input);
let result = $conn.transact($input);
assert!(result.is_ok(), "Expected Ok(_), got `{}`", result.unwrap_err());
result.unwrap()
}};
}
// A connection that doesn't try to be clever about possibly sharing its `Schema`. Compare to
// `mentat::Conn`.
struct TestConn {
sqlite: rusqlite::Connection,
partition_map: PartitionMap,
schema: Schema,
}
impl TestConn {
fn assert_materialized_views(&self) {
let materialized_ident_map = read_ident_map(&self.sqlite).expect("ident map");
let materialized_attribute_map = read_attribute_map(&self.sqlite).expect("schema map");
let materialized_schema = Schema::from_ident_map_and_attribute_map(materialized_ident_map, materialized_attribute_map).expect("schema");
assert_eq!(materialized_schema, self.schema);
}
fn transact<I>(&mut self, transaction: I) -> Result<TxReport> where I: Borrow<str> {
// Failure to parse the transaction is a coding error, so we unwrap.
let entities = edn::parse::entities(transaction.borrow()).expect(format!("to be able to parse {} into entities", transaction.borrow()).as_str());
let details = {
// The block scopes the borrow of self.sqlite.
// We're about to write, so go straight ahead and get an IMMEDIATE transaction.
let tx = self.sqlite.transaction_with_behavior(TransactionBehavior::Immediate)?;
// Applying the transaction can fail, so we don't unwrap.
let details = transact(&tx, self.partition_map.clone(), &self.schema, &self.schema, NullWatcher(), entities)?;
tx.commit()?;
details
};
let (report, next_partition_map, next_schema, _watcher) = details;
self.partition_map = next_partition_map;
if let Some(next_schema) = next_schema {
self.schema = next_schema;
}
// Verify that we've updated the materialized views during transacting.
self.assert_materialized_views();
Ok(report)
}
fn transact_simple_terms<I>(&mut self, terms: I, tempid_set: InternSet<TempId>) -> Result<TxReport> where I: IntoIterator<Item=TermWithTempIds> {
let details = {
// The block scopes the borrow of self.sqlite.
// We're about to write, so go straight ahead and get an IMMEDIATE transaction.
let tx = self.sqlite.transaction_with_behavior(TransactionBehavior::Immediate)?;
// Applying the transaction can fail, so we don't unwrap.
let details = transact_terms(&tx, self.partition_map.clone(), &self.schema, &self.schema, NullWatcher(), terms, tempid_set)?;
tx.commit()?;
details
};
let (report, next_partition_map, next_schema, _watcher) = details;
self.partition_map = next_partition_map;
if let Some(next_schema) = next_schema {
self.schema = next_schema;
}
// Verify that we've updated the materialized views during transacting.
self.assert_materialized_views();
Ok(report)
}
fn last_tx_id(&self) -> Entid {
self.partition_map.get(&":db.part/tx".to_string()).unwrap().index - 1
}
fn last_transaction(&self) -> edn::Value {
debug::transactions_after(&self.sqlite, &self.schema, self.last_tx_id() - 1).expect("last_transaction").0[0].into_edn()
}
fn datoms(&self) -> edn::Value {
debug::datoms_after(&self.sqlite, &self.schema, bootstrap::TX0).expect("datoms").into_edn()
}
fn fulltext_values(&self) -> edn::Value {
debug::fulltext_values(&self.sqlite).expect("fulltext_values").into_edn()
}
fn with_sqlite(mut conn: rusqlite::Connection) -> TestConn {
let db = ensure_current_version(&mut conn).unwrap();
// Does not include :db/txInstant.
let datoms = debug::datoms_after(&conn, &db.schema, 0).unwrap();
assert_eq!(datoms.0.len(), 94);
// Includes :db/txInstant.
let transactions = debug::transactions_after(&conn, &db.schema, 0).unwrap();
assert_eq!(transactions.0.len(), 1);
assert_eq!(transactions.0[0].0.len(), 95);
let mut parts = db.partition_map;
// Add a fake partition to allow tests to do things like
// [:db/add 111 :foo/bar 222]
{
let fake_partition = Partition { start: 100, index: 1000 };
parts.insert(":db.part/fake".into(), fake_partition);
}
let test_conn = TestConn {
sqlite: conn,
partition_map: parts,
schema: db.schema,
};
// Verify that we've created the materialized views during bootstrapping.
test_conn.assert_materialized_views();
test_conn
}
}
impl Default for TestConn {
fn default() -> TestConn {
TestConn::with_sqlite(new_connection("").expect("Couldn't open in-memory db"))
}
}
fn tempids(report: &TxReport) -> edn::Value {
let mut map: BTreeMap<edn::Value, edn::Value> = BTreeMap::default();
for (tempid, &entid) in report.tempids.iter() {
map.insert(edn::Value::Text(tempid.clone()), edn::Value::Integer(entid));
}
edn::Value::Map(map)
}
fn run_test_add(mut conn: TestConn) {
// Test inserting :db.cardinality/one elements.
assert_transact!(conn, "[[:db/add 100 :db.schema/version 1]
[:db/add 101 :db.schema/version 2]]");
assert_matches!(conn.last_transaction(),
"[[100 :db.schema/version 1 ?tx true]
[101 :db.schema/version 2 ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(conn.datoms(),
"[[100 :db.schema/version 1]
[101 :db.schema/version 2]]");
// Test inserting :db.cardinality/many elements.
assert_transact!(conn, "[[:db/add 200 :db.schema/attribute 100]
[:db/add 200 :db.schema/attribute 101]]");
assert_matches!(conn.last_transaction(),
"[[200 :db.schema/attribute 100 ?tx true]
[200 :db.schema/attribute 101 ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(conn.datoms(),
"[[100 :db.schema/version 1]
[101 :db.schema/version 2]
[200 :db.schema/attribute 100]
[200 :db.schema/attribute 101]]");
// Test replacing existing :db.cardinality/one elements.
assert_transact!(conn, "[[:db/add 100 :db.schema/version 11]
[:db/add 101 :db.schema/version 22]]");
assert_matches!(conn.last_transaction(),
"[[100 :db.schema/version 1 ?tx false]
[100 :db.schema/version 11 ?tx true]
[101 :db.schema/version 2 ?tx false]
[101 :db.schema/version 22 ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(conn.datoms(),
"[[100 :db.schema/version 11]
[101 :db.schema/version 22]
[200 :db.schema/attribute 100]
[200 :db.schema/attribute 101]]");
// Test that asserting existing :db.cardinality/one elements doesn't change the store.
assert_transact!(conn, "[[:db/add 100 :db.schema/version 11]
[:db/add 101 :db.schema/version 22]]");
assert_matches!(conn.last_transaction(),
"[[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(conn.datoms(),
"[[100 :db.schema/version 11]
[101 :db.schema/version 22]
[200 :db.schema/attribute 100]
[200 :db.schema/attribute 101]]");
// Test that asserting existing :db.cardinality/many elements doesn't change the store.
assert_transact!(conn, "[[:db/add 200 :db.schema/attribute 100]
[:db/add 200 :db.schema/attribute 101]]");
assert_matches!(conn.last_transaction(),
"[[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(conn.datoms(),
"[[100 :db.schema/version 11]
[101 :db.schema/version 22]
[200 :db.schema/attribute 100]
[200 :db.schema/attribute 101]]");
}
#[test]
fn test_add() {
run_test_add(TestConn::default());
}
#[test]
fn test_tx_assertions() {
let mut conn = TestConn::default();
// Test that txInstant can be asserted.
assert_transact!(conn, "[[:db/add (transaction-tx) :db/txInstant #inst \"2017-06-16T00:56:41.257Z\"]
[:db/add 100 :db/ident :name/Ivan]
[:db/add 101 :db/ident :name/Petr]]");
assert_matches!(conn.last_transaction(),
"[[100 :db/ident :name/Ivan ?tx true]
[101 :db/ident :name/Petr ?tx true]
[?tx :db/txInstant #inst \"2017-06-16T00:56:41.257Z\" ?tx true]]");
// Test multiple txInstant with different values should fail.
assert_transact!(conn, "[[:db/add (transaction-tx) :db/txInstant #inst \"2017-06-16T00:59:11.257Z\"]
[:db/add (transaction-tx) :db/txInstant #inst \"2017-06-16T00:59:11.752Z\"]
[:db/add 102 :db/ident :name/Vlad]]",
Err("schema constraint violation: cardinality conflicts:\n CardinalityOneAddConflict { e: 268435458, a: 3, vs: {Instant(2017-06-16T00:59:11.257Z), Instant(2017-06-16T00:59:11.752Z)} }\n"));
// Test multiple txInstants with the same value.
assert_transact!(conn, "[[:db/add (transaction-tx) :db/txInstant #inst \"2017-06-16T00:59:11.257Z\"]
[:db/add (transaction-tx) :db/txInstant #inst \"2017-06-16T00:59:11.257Z\"]
[:db/add 103 :db/ident :name/Dimitri]
[:db/add 104 :db/ident :name/Anton]]");
assert_matches!(conn.last_transaction(),
"[[103 :db/ident :name/Dimitri ?tx true]
[104 :db/ident :name/Anton ?tx true]
[?tx :db/txInstant #inst \"2017-06-16T00:59:11.257Z\" ?tx true]]");
// We need a few attributes to work with.
assert_transact!(conn, "[[:db/add 111 :db/ident :test/str]
[:db/add 111 :db/valueType :db.type/string]
[:db/add 222 :db/ident :test/ref]
[:db/add 222 :db/valueType :db.type/ref]]");
// Test that we can assert metadata about the current transaction.
assert_transact!(conn, "[[:db/add (transaction-tx) :test/str \"We want metadata!\"]]");
assert_matches!(conn.last_transaction(),
"[[?tx :db/txInstant ?ms ?tx true]
[?tx :test/str \"We want metadata!\" ?tx true]]");
// Test that we can use (transaction-tx) as a value.
assert_transact!(conn, "[[:db/add 333 :test/ref (transaction-tx)]]");
assert_matches!(conn.last_transaction(),
"[[333 :test/ref ?tx ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
// Test that we type-check properly. In the value position, (transaction-tx) yields a ref;
// :db/ident expects a keyword.
assert_transact!(conn, "[[:db/add 444 :db/ident (transaction-tx)]]",
Err("not yet implemented: Transaction function transaction-tx produced value of type :db.type/ref but expected type :db.type/keyword"));
// Test that we can assert metadata about the current transaction.
assert_transact!(conn, "[[:db/add (transaction-tx) :test/ref (transaction-tx)]]");
assert_matches!(conn.last_transaction(),
"[[?tx :db/txInstant ?ms ?tx true]
[?tx :test/ref ?tx ?tx true]]");
}
#[test]
fn test_retract() {
let mut conn = TestConn::default();
// Insert a few :db.cardinality/one elements.
assert_transact!(conn, "[[:db/add 100 :db.schema/version 1]
[:db/add 101 :db.schema/version 2]]");
assert_matches!(conn.last_transaction(),
"[[100 :db.schema/version 1 ?tx true]
[101 :db.schema/version 2 ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(conn.datoms(),
"[[100 :db.schema/version 1]
[101 :db.schema/version 2]]");
// And a few :db.cardinality/many elements.
assert_transact!(conn, "[[:db/add 200 :db.schema/attribute 100]
[:db/add 200 :db.schema/attribute 101]]");
assert_matches!(conn.last_transaction(),
"[[200 :db.schema/attribute 100 ?tx true]
[200 :db.schema/attribute 101 ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(conn.datoms(),
"[[100 :db.schema/version 1]
[101 :db.schema/version 2]
[200 :db.schema/attribute 100]
[200 :db.schema/attribute 101]]");
// Test that we can retract :db.cardinality/one elements.
assert_transact!(conn, "[[:db/retract 100 :db.schema/version 1]]");
assert_matches!(conn.last_transaction(),
"[[100 :db.schema/version 1 ?tx false]
[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(conn.datoms(),
"[[101 :db.schema/version 2]
[200 :db.schema/attribute 100]
[200 :db.schema/attribute 101]]");
// Test that we can retract :db.cardinality/many elements.
assert_transact!(conn, "[[:db/retract 200 :db.schema/attribute 100]]");
assert_matches!(conn.last_transaction(),
"[[200 :db.schema/attribute 100 ?tx false]
[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(conn.datoms(),
"[[101 :db.schema/version 2]
[200 :db.schema/attribute 101]]");
// Verify that retracting :db.cardinality/{one,many} elements that are not present doesn't
// change the store.
assert_transact!(conn, "[[:db/retract 100 :db.schema/version 1]
[:db/retract 200 :db.schema/attribute 100]]");
assert_matches!(conn.last_transaction(),
"[[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(conn.datoms(),
"[[101 :db.schema/version 2]
[200 :db.schema/attribute 101]]");
}
// Unique is required!
#[test]
fn test_upsert_issue_538() {
let mut conn = TestConn::default();
assert_transact!(conn, "
[{:db/ident :person/name
:db/valueType :db.type/string
:db/cardinality :db.cardinality/many}
{:db/ident :person/age
:db/valueType :db.type/long
:db/cardinality :db.cardinality/one}
{:db/ident :person/email
:db/valueType :db.type/string
:db/unique :db.unique/identity
:db/cardinality :db.cardinality/many}]",
Err("bad schema assertion: :db/unique :db/unique_identity without :db/index true for entid: 65538"));
}
// TODO: don't use :db/ident to test upserts!
#[test]
fn test_upsert_vector() {
let mut conn = TestConn::default();
// Insert some :db.unique/identity elements.
assert_transact!(conn, "[[:db/add 100 :db/ident :name/Ivan]
[:db/add 101 :db/ident :name/Petr]]");
assert_matches!(conn.last_transaction(),
"[[100 :db/ident :name/Ivan ?tx true]
[101 :db/ident :name/Petr ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(conn.datoms(),
"[[100 :db/ident :name/Ivan]
[101 :db/ident :name/Petr]]");
// Upserting two tempids to the same entid works.
let report = assert_transact!(conn, "[[:db/add \"t1\" :db/ident :name/Ivan]
[:db/add \"t1\" :db.schema/attribute 100]
[:db/add \"t2\" :db/ident :name/Petr]
[:db/add \"t2\" :db.schema/attribute 101]]");
assert_matches!(conn.last_transaction(),
"[[100 :db.schema/attribute :name/Ivan ?tx true]
[101 :db.schema/attribute :name/Petr ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(conn.datoms(),
"[[100 :db/ident :name/Ivan]
[100 :db.schema/attribute :name/Ivan]
[101 :db/ident :name/Petr]
[101 :db.schema/attribute :name/Petr]]");
assert_matches!(tempids(&report),
"{\"t1\" 100
\"t2\" 101}");
// Upserting a tempid works. The ref doesn't have to exist (at this time), but we can't
// reuse an existing ref due to :db/unique :db.unique/value.
let report = assert_transact!(conn, "[[:db/add \"t1\" :db/ident :name/Ivan]
[:db/add \"t1\" :db.schema/attribute 102]]");
assert_matches!(conn.last_transaction(),
"[[100 :db.schema/attribute 102 ?tx true]
[?true :db/txInstant ?ms ?tx true]]");
assert_matches!(conn.datoms(),
"[[100 :db/ident :name/Ivan]
[100 :db.schema/attribute :name/Ivan]
[100 :db.schema/attribute 102]
[101 :db/ident :name/Petr]
[101 :db.schema/attribute :name/Petr]]");
assert_matches!(tempids(&report),
"{\"t1\" 100}");
// A single complex upsert allocates a new entid.
let report = assert_transact!(conn, "[[:db/add \"t1\" :db.schema/attribute \"t2\"]]");
assert_matches!(conn.last_transaction(),
"[[65536 :db.schema/attribute 65537 ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(tempids(&report),
"{\"t1\" 65536
\"t2\" 65537}");
// Conflicting upserts fail.
assert_transact!(conn, "[[:db/add \"t1\" :db/ident :name/Ivan]
[:db/add \"t1\" :db/ident :name/Petr]]",
Err("schema constraint violation: conflicting upserts:\n tempid External(\"t1\") upserts to {KnownEntid(100), KnownEntid(101)}\n"));
// The error messages of conflicting upserts gives information about all failing upserts (in a particular generation).
assert_transact!(conn, "[[:db/add \"t2\" :db/ident :name/Grigory]
[:db/add \"t2\" :db/ident :name/Petr]
[:db/add \"t2\" :db/ident :name/Ivan]
[:db/add \"t1\" :db/ident :name/Ivan]
[:db/add \"t1\" :db/ident :name/Petr]]",
Err("schema constraint violation: conflicting upserts:\n tempid External(\"t1\") upserts to {KnownEntid(100), KnownEntid(101)}\n tempid External(\"t2\") upserts to {KnownEntid(100), KnownEntid(101)}\n"));
// tempids in :db/retract that don't upsert fail.
assert_transact!(conn, "[[:db/retract \"t1\" :db/ident :name/Anonymous]]",
Err("not yet implemented: [:db/retract ...] entity referenced tempid that did not upsert: t1"));
// tempids in :db/retract that do upsert are retracted. The ref given doesn't exist, so the
// assertion will be ignored.
let report = assert_transact!(conn, "[[:db/add \"t1\" :db/ident :name/Ivan]
[:db/retract \"t1\" :db.schema/attribute 103]]");
assert_matches!(conn.last_transaction(),
"[[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(tempids(&report),
"{\"t1\" 100}");
// A multistep upsert. The upsert algorithm will first try to resolve "t1", fail, and then
// allocate both "t1" and "t2".
let report = assert_transact!(conn, "[[:db/add \"t1\" :db/ident :name/Josef]
[:db/add \"t2\" :db.schema/attribute \"t1\"]]");
assert_matches!(conn.last_transaction(),
"[[65538 :db/ident :name/Josef ?tx true]
[65539 :db.schema/attribute :name/Josef ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(tempids(&report),
"{\"t1\" 65538
\"t2\" 65539}");
// A multistep insert. This time, we can resolve both, but we have to try "t1", succeed,
// and then resolve "t2".
// TODO: We can't quite test this without more schema elements.
// conn.transact("[[:db/add \"t1\" :db/ident :name/Josef]
// [:db/add \"t2\" :db/ident \"t1\"]]");
// assert_matches!(conn.last_transaction(),
// "[[65538 :db/ident :name/Josef]
// [65538 :db/ident :name/Karl]
// [?tx :db/txInstant ?ms ?tx true]]");
}
#[test]
fn test_resolved_upserts() {
let mut conn = TestConn::default();
assert_transact!(conn, "[
{:db/ident :test/id
:db/valueType :db.type/string
:db/unique :db.unique/identity
:db/index true
:db/cardinality :db.cardinality/one}
{:db/ident :test/ref
:db/valueType :db.type/ref
:db/unique :db.unique/identity
:db/index true
:db/cardinality :db.cardinality/one}
]");
// Partial data for :test/id, links via :test/ref.
assert_transact!(conn, r#"[
[:db/add 100 :test/id "0"]
[:db/add 101 :test/ref 100]
[:db/add 102 :test/ref 101]
[:db/add 103 :test/ref 102]
]"#);
// Fill in the rest of the data for :test/id, using the links of :test/ref.
let report = assert_transact!(conn, r#"[
{:db/id "a" :test/id "0"}
{:db/id "b" :test/id "1" :test/ref "a"}
{:db/id "c" :test/id "2" :test/ref "b"}
{:db/id "d" :test/id "3" :test/ref "c"}
]"#);
assert_matches!(tempids(&report), r#"{
"a" 100
"b" 101
"c" 102
"d" 103
}"#);
assert_matches!(conn.last_transaction(), r#"[
[101 :test/id "1" ?tx true]
[102 :test/id "2" ?tx true]
[103 :test/id "3" ?tx true]
[?tx :db/txInstant ?ms ?tx true]
]"#);
}
#[test]
fn test_sqlite_limit() {
let conn = new_connection("").expect("Couldn't open in-memory db");
let initial = conn.limit(Limit::SQLITE_LIMIT_VARIABLE_NUMBER);
// Sanity check.
assert!(initial > 500);
// Make sure setting works.
conn.set_limit(Limit::SQLITE_LIMIT_VARIABLE_NUMBER, 222);
assert_eq!(222, conn.limit(Limit::SQLITE_LIMIT_VARIABLE_NUMBER));
}
#[test]
fn test_db_install() {
let mut conn = TestConn::default();
// We can assert a new attribute.
assert_transact!(conn, "[[:db/add 100 :db/ident :test/ident]
[:db/add 100 :db/valueType :db.type/long]
[:db/add 100 :db/cardinality :db.cardinality/many]]");
assert_eq!(conn.schema.entid_map.get(&100).cloned().unwrap(), to_namespaced_keyword(":test/ident").unwrap());
assert_eq!(conn.schema.ident_map.get(&to_namespaced_keyword(":test/ident").unwrap()).cloned().unwrap(), 100);
let attribute = conn.schema.attribute_for_entid(100).unwrap().clone();
assert_eq!(attribute.value_type, ValueType::Long);
assert_eq!(attribute.multival, true);
assert_eq!(attribute.fulltext, false);
assert_matches!(conn.last_transaction(),
"[[100 :db/ident :test/ident ?tx true]
[100 :db/valueType :db.type/long ?tx true]
[100 :db/cardinality :db.cardinality/many ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(conn.datoms(),
"[[100 :db/ident :test/ident]
[100 :db/valueType :db.type/long]
[100 :db/cardinality :db.cardinality/many]]");
// Let's check we actually have the schema characteristics we expect.
let attribute = conn.schema.attribute_for_entid(100).unwrap().clone();
assert_eq!(attribute.value_type, ValueType::Long);
assert_eq!(attribute.multival, true);
assert_eq!(attribute.fulltext, false);
// Let's check that we can use the freshly installed attribute.
assert_transact!(conn, "[[:db/add 101 100 -10]
[:db/add 101 :test/ident -9]]");
assert_matches!(conn.last_transaction(),
"[[101 :test/ident -10 ?tx true]
[101 :test/ident -9 ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
// Cannot retract a characteristic of an installed attribute.
assert_transact!(conn,
"[[:db/retract 100 :db/cardinality :db.cardinality/many]]",
Err("bad schema assertion: Retracting attribute 8 for entity 100 not permitted."));
// Trying to install an attribute without a :db/ident is allowed.
assert_transact!(conn, "[[:db/add 101 :db/valueType :db.type/long]
[:db/add 101 :db/cardinality :db.cardinality/many]]");
}
#[test]
fn test_db_alter() {
let mut conn = TestConn::default();
// Start by installing a :db.cardinality/one attribute.
assert_transact!(conn, "[[:db/add 100 :db/ident :test/ident]
[:db/add 100 :db/valueType :db.type/keyword]
[:db/add 100 :db/cardinality :db.cardinality/one]]");
// Trying to alter the :db/valueType will fail.
assert_transact!(conn, "[[:db/add 100 :db/valueType :db.type/long]]",
Err("bad schema assertion: Schema alteration for existing attribute with entid 100 is not valid"));
// But we can alter the cardinality.
assert_transact!(conn, "[[:db/add 100 :db/cardinality :db.cardinality/many]]");
assert_matches!(conn.last_transaction(),
"[[100 :db/cardinality :db.cardinality/one ?tx false]
[100 :db/cardinality :db.cardinality/many ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(conn.datoms(),
"[[100 :db/ident :test/ident]
[100 :db/valueType :db.type/keyword]
[100 :db/cardinality :db.cardinality/many]]");
// Let's check we actually have the schema characteristics we expect.
let attribute = conn.schema.attribute_for_entid(100).unwrap().clone();
assert_eq!(attribute.value_type, ValueType::Keyword);
assert_eq!(attribute.multival, true);
assert_eq!(attribute.fulltext, false);
// Let's check that we can use the freshly altered attribute's new characteristic.
assert_transact!(conn, "[[:db/add 101 100 :test/value1]
[:db/add 101 :test/ident :test/value2]]");
assert_matches!(conn.last_transaction(),
"[[101 :test/ident :test/value1 ?tx true]
[101 :test/ident :test/value2 ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
}
#[test]
fn test_db_ident() {
let mut conn = TestConn::default();
// We can assert a new :db/ident.
assert_transact!(conn, "[[:db/add 100 :db/ident :name/Ivan]]");
assert_matches!(conn.last_transaction(),
"[[100 :db/ident :name/Ivan ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(conn.datoms(),
"[[100 :db/ident :name/Ivan]]");
assert_eq!(conn.schema.entid_map.get(&100).cloned().unwrap(), to_namespaced_keyword(":name/Ivan").unwrap());
assert_eq!(conn.schema.ident_map.get(&to_namespaced_keyword(":name/Ivan").unwrap()).cloned().unwrap(), 100);
// We can re-assert an existing :db/ident.
assert_transact!(conn, "[[:db/add 100 :db/ident :name/Ivan]]");
assert_matches!(conn.last_transaction(),
"[[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(conn.datoms(),
"[[100 :db/ident :name/Ivan]]");
assert_eq!(conn.schema.entid_map.get(&100).cloned().unwrap(), to_namespaced_keyword(":name/Ivan").unwrap());
assert_eq!(conn.schema.ident_map.get(&to_namespaced_keyword(":name/Ivan").unwrap()).cloned().unwrap(), 100);
// We can alter an existing :db/ident to have a new keyword.
assert_transact!(conn, "[[:db/add :name/Ivan :db/ident :name/Petr]]");
assert_matches!(conn.last_transaction(),
"[[100 :db/ident :name/Ivan ?tx false]
[100 :db/ident :name/Petr ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(conn.datoms(),
"[[100 :db/ident :name/Petr]]");
// Entid map is updated.
assert_eq!(conn.schema.entid_map.get(&100).cloned().unwrap(), to_namespaced_keyword(":name/Petr").unwrap());
// Ident map contains the new ident.
assert_eq!(conn.schema.ident_map.get(&to_namespaced_keyword(":name/Petr").unwrap()).cloned().unwrap(), 100);
// Ident map no longer contains the old ident.
assert!(conn.schema.ident_map.get(&to_namespaced_keyword(":name/Ivan").unwrap()).is_none());
// We can re-purpose an old ident.
assert_transact!(conn, "[[:db/add 101 :db/ident :name/Ivan]]");
assert_matches!(conn.last_transaction(),
"[[101 :db/ident :name/Ivan ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(conn.datoms(),
"[[100 :db/ident :name/Petr]
[101 :db/ident :name/Ivan]]");
// Entid map contains both entids.
assert_eq!(conn.schema.entid_map.get(&100).cloned().unwrap(), to_namespaced_keyword(":name/Petr").unwrap());
assert_eq!(conn.schema.entid_map.get(&101).cloned().unwrap(), to_namespaced_keyword(":name/Ivan").unwrap());
// Ident map contains the new ident.
assert_eq!(conn.schema.ident_map.get(&to_namespaced_keyword(":name/Petr").unwrap()).cloned().unwrap(), 100);
// Ident map contains the old ident, but re-purposed to the new entid.
assert_eq!(conn.schema.ident_map.get(&to_namespaced_keyword(":name/Ivan").unwrap()).cloned().unwrap(), 101);
// We can retract an existing :db/ident.
assert_transact!(conn, "[[:db/retract :name/Petr :db/ident :name/Petr]]");
// It's really gone.
assert!(conn.schema.entid_map.get(&100).is_none());
assert!(conn.schema.ident_map.get(&to_namespaced_keyword(":name/Petr").unwrap()).is_none());
}
#[test]
fn test_db_alter_cardinality() {
let mut conn = TestConn::default();
// Start by installing a :db.cardinality/one attribute.
assert_transact!(conn, "[[:db/add 100 :db/ident :test/ident]
[:db/add 100 :db/valueType :db.type/long]
[:db/add 100 :db/cardinality :db.cardinality/one]]");
assert_transact!(conn, "[[:db/add 200 :test/ident 1]]");
// We can always go from :db.cardinality/one to :db.cardinality/many.
assert_transact!(conn, "[[:db/add 100 :db/cardinality :db.cardinality/many]]");
assert_transact!(conn, "[[:db/add 200 :test/ident 2]]");
assert_matches!(conn.datoms(),
"[[100 :db/ident :test/ident]
[100 :db/valueType :db.type/long]
[100 :db/cardinality :db.cardinality/many]
[200 :test/ident 1]
[200 :test/ident 2]]");
// We can't always go from :db.cardinality/many to :db.cardinality/one.
assert_transact!(conn, "[[:db/add 100 :db/cardinality :db.cardinality/one]]",
// TODO: give more helpful error details.
Err("schema alteration failed: Cannot alter schema attribute 100 to be :db.cardinality/one"));
}
#[test]
fn test_db_alter_unique_value() {
let mut conn = TestConn::default();
// Start by installing a :db.cardinality/one attribute.
assert_transact!(conn, "[[:db/add 100 :db/ident :test/ident]
[:db/add 100 :db/valueType :db.type/long]
[:db/add 100 :db/cardinality :db.cardinality/one]]");
assert_transact!(conn, "[[:db/add 200 :test/ident 1]
[:db/add 201 :test/ident 1]]");
// We can't always migrate to be :db.unique/value.
assert_transact!(conn, "[[:db/add :test/ident :db/unique :db.unique/value]]",
// TODO: give more helpful error details.
Err("schema alteration failed: Cannot alter schema attribute 100 to be :db.unique/value"));
// Not even indirectly!
assert_transact!(conn, "[[:db/add :test/ident :db/unique :db.unique/identity]]",
// TODO: give more helpful error details.
Err("schema alteration failed: Cannot alter schema attribute 100 to be :db.unique/identity"));
// But we can if we make sure there's no repeated [a v] pair.
assert_transact!(conn, "[[:db/add 201 :test/ident 2]]");
assert_transact!(conn, "[[:db/add :test/ident :db/index true]
[:db/add :test/ident :db/unique :db.unique/value]
[:db/add :db.part/db :db.alter/attribute 100]]");
// We can also retract the uniqueness constraint altogether.
assert_transact!(conn, "[[:db/retract :test/ident :db/unique :db.unique/value]]");
// Once we've done so, the schema shows it's not unique…
{
let attr = conn.schema.attribute_for_ident(&Keyword::namespaced("test", "ident")).unwrap().0;
assert_eq!(None, attr.unique);
}
// … and we can add more assertions with duplicate values.
assert_transact!(conn, "[[:db/add 121 :test/ident 1]
[:db/add 221 :test/ident 2]]");
}
/// Verify that we can't alter :db/fulltext schema characteristics at all.
#[test]
fn test_db_alter_fulltext() {
let mut conn = TestConn::default();
// Start by installing a :db/fulltext true and a :db/fulltext unset attribute.
assert_transact!(conn, "[[:db/add 111 :db/ident :test/fulltext]
[:db/add 111 :db/valueType :db.type/string]
[:db/add 111 :db/unique :db.unique/identity]
[:db/add 111 :db/index true]
[:db/add 111 :db/fulltext true]
[:db/add 222 :db/ident :test/string]
[:db/add 222 :db/cardinality :db.cardinality/one]
[:db/add 222 :db/valueType :db.type/string]
[:db/add 222 :db/index true]]");
assert_transact!(conn,
"[[:db/retract 111 :db/fulltext true]]",
Err("bad schema assertion: Retracting attribute 12 for entity 111 not permitted."));
assert_transact!(conn,
"[[:db/add 222 :db/fulltext true]]",
Err("bad schema assertion: Schema alteration for existing attribute with entid 222 is not valid"));
}
#[test]
fn test_db_fulltext() {
let mut conn = TestConn::default();
// Start by installing a few :db/fulltext true attributes.
assert_transact!(conn, "[[:db/add 111 :db/ident :test/fulltext]
[:db/add 111 :db/valueType :db.type/string]
[:db/add 111 :db/unique :db.unique/identity]
[:db/add 111 :db/index true]
[:db/add 111 :db/fulltext true]
[:db/add 222 :db/ident :test/other]
[:db/add 222 :db/cardinality :db.cardinality/one]
[:db/add 222 :db/valueType :db.type/string]
[:db/add 222 :db/index true]
[:db/add 222 :db/fulltext true]]");
// Let's check we actually have the schema characteristics we expect.
let fulltext = conn.schema.attribute_for_entid(111).cloned().expect(":test/fulltext");
assert_eq!(fulltext.value_type, ValueType::String);
assert_eq!(fulltext.fulltext, true);
assert_eq!(fulltext.multival, false);
assert_eq!(fulltext.unique, Some(attribute::Unique::Identity));
let other = conn.schema.attribute_for_entid(222).cloned().expect(":test/other");
assert_eq!(other.value_type, ValueType::String);
assert_eq!(other.fulltext, true);
assert_eq!(other.multival, false);
assert_eq!(other.unique, None);
// We can add fulltext indexed datoms.
assert_transact!(conn, "[[:db/add 301 :test/fulltext \"test this\"]]");
// value column is rowid into fulltext table.
assert_matches!(conn.fulltext_values(),
"[[1 \"test this\"]]");
assert_matches!(conn.last_transaction(),
"[[301 :test/fulltext 1 ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(conn.datoms(),
"[[111 :db/ident :test/fulltext]
[111 :db/valueType :db.type/string]
[111 :db/unique :db.unique/identity]
[111 :db/index true]
[111 :db/fulltext true]
[222 :db/ident :test/other]
[222 :db/valueType :db.type/string]
[222 :db/cardinality :db.cardinality/one]
[222 :db/index true]
[222 :db/fulltext true]
[301 :test/fulltext 1]]");
// We can replace existing fulltext indexed datoms.
assert_transact!(conn, "[[:db/add 301 :test/fulltext \"alternate thing\"]]");
// value column is rowid into fulltext table.
assert_matches!(conn.fulltext_values(),
"[[1 \"test this\"]
[2 \"alternate thing\"]]");
assert_matches!(conn.last_transaction(),
"[[301 :test/fulltext 1 ?tx false]
[301 :test/fulltext 2 ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(conn.datoms(),
"[[111 :db/ident :test/fulltext]
[111 :db/valueType :db.type/string]
[111 :db/unique :db.unique/identity]
[111 :db/index true]
[111 :db/fulltext true]
[222 :db/ident :test/other]
[222 :db/valueType :db.type/string]
[222 :db/cardinality :db.cardinality/one]
[222 :db/index true]
[222 :db/fulltext true]
[301 :test/fulltext 2]]");
// We can upsert keyed by fulltext indexed datoms.
assert_transact!(conn, "[[:db/add \"t\" :test/fulltext \"alternate thing\"]
[:db/add \"t\" :test/other \"other\"]]");
// value column is rowid into fulltext table.
assert_matches!(conn.fulltext_values(),
"[[1 \"test this\"]
[2 \"alternate thing\"]
[3 \"other\"]]");
assert_matches!(conn.last_transaction(),
"[[301 :test/other 3 ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(conn.datoms(),
"[[111 :db/ident :test/fulltext]
[111 :db/valueType :db.type/string]
[111 :db/unique :db.unique/identity]
[111 :db/index true]
[111 :db/fulltext true]
[222 :db/ident :test/other]
[222 :db/valueType :db.type/string]
[222 :db/cardinality :db.cardinality/one]
[222 :db/index true]
[222 :db/fulltext true]
[301 :test/fulltext 2]
[301 :test/other 3]]");
// We can re-use fulltext values; they won't be added to the fulltext values table twice.
assert_transact!(conn, "[[:db/add 302 :test/other \"alternate thing\"]]");
// value column is rowid into fulltext table.
assert_matches!(conn.fulltext_values(),
"[[1 \"test this\"]
[2 \"alternate thing\"]
[3 \"other\"]]");
assert_matches!(conn.last_transaction(),
"[[302 :test/other 2 ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(conn.datoms(),
"[[111 :db/ident :test/fulltext]
[111 :db/valueType :db.type/string]
[111 :db/unique :db.unique/identity]
[111 :db/index true]
[111 :db/fulltext true]
[222 :db/ident :test/other]
[222 :db/valueType :db.type/string]
[222 :db/cardinality :db.cardinality/one]
[222 :db/index true]
[222 :db/fulltext true]
[301 :test/fulltext 2]
[301 :test/other 3]
[302 :test/other 2]]");
// We can retract fulltext indexed datoms. The underlying fulltext value remains -- indeed,
// it might still be in use.
assert_transact!(conn, "[[:db/retract 302 :test/other \"alternate thing\"]]");
// value column is rowid into fulltext table.
assert_matches!(conn.fulltext_values(),
"[[1 \"test this\"]
[2 \"alternate thing\"]
[3 \"other\"]]");
assert_matches!(conn.last_transaction(),
"[[302 :test/other 2 ?tx false]
[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(conn.datoms(),
"[[111 :db/ident :test/fulltext]
[111 :db/valueType :db.type/string]
[111 :db/unique :db.unique/identity]
[111 :db/index true]
[111 :db/fulltext true]
[222 :db/ident :test/other]
[222 :db/valueType :db.type/string]
[222 :db/cardinality :db.cardinality/one]
[222 :db/index true]
[222 :db/fulltext true]
[301 :test/fulltext 2]
[301 :test/other 3]]");
}
#[test]
fn test_lookup_refs_entity_column() {
let mut conn = TestConn::default();
// Start by installing a few attributes.
assert_transact!(conn, "[[:db/add 111 :db/ident :test/unique_value]
[:db/add 111 :db/valueType :db.type/string]
[:db/add 111 :db/unique :db.unique/value]
[:db/add 111 :db/index true]
[:db/add 222 :db/ident :test/unique_identity]
[:db/add 222 :db/valueType :db.type/long]
[:db/add 222 :db/unique :db.unique/identity]
[:db/add 222 :db/index true]
[:db/add 333 :db/ident :test/not_unique]
[:db/add 333 :db/cardinality :db.cardinality/one]
[:db/add 333 :db/valueType :db.type/keyword]
[:db/add 333 :db/index true]]");
// And a few datoms to match against.
assert_transact!(conn, "[[:db/add 501 :test/unique_value \"test this\"]
[:db/add 502 :test/unique_value \"other\"]
[:db/add 503 :test/unique_identity -10]
[:db/add 504 :test/unique_identity -20]
[:db/add 505 :test/not_unique :test/keyword]
[:db/add 506 :test/not_unique :test/keyword]]");
// We can resolve lookup refs in the entity column, referring to the attribute as an entid or an ident.
assert_transact!(conn, "[[:db/add (lookup-ref :test/unique_value \"test this\") :test/not_unique :test/keyword]
[:db/add (lookup-ref 111 \"other\") :test/not_unique :test/keyword]
[:db/add (lookup-ref :test/unique_identity -10) :test/not_unique :test/keyword]
[:db/add (lookup-ref 222 -20) :test/not_unique :test/keyword]]");
assert_matches!(conn.last_transaction(),
"[[501 :test/not_unique :test/keyword ?tx true]
[502 :test/not_unique :test/keyword ?tx true]
[503 :test/not_unique :test/keyword ?tx true]
[504 :test/not_unique :test/keyword ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
// We cannot resolve lookup refs that aren't :db/unique.
assert_transact!(conn,
"[[:db/add (lookup-ref :test/not_unique :test/keyword) :test/not_unique :test/keyword]]",
Err("not yet implemented: Cannot resolve (lookup-ref 333 Keyword(Keyword(NamespaceableName { namespace: Some(\"test\"), name: \"keyword\" }))) with attribute that is not :db/unique"));
// We type check the lookup ref's value against the lookup ref's attribute.
assert_transact!(conn,
"[[:db/add (lookup-ref :test/unique_value :test/not_a_string) :test/not_unique :test/keyword]]",
Err("value \':test/not_a_string\' is not the expected Mentat value type String"));
// Each lookup ref in the entity column must resolve
assert_transact!(conn,
"[[:db/add (lookup-ref :test/unique_value \"unmatched string value\") :test/not_unique :test/keyword]]",
Err("no entid found for ident: couldn\'t lookup [a v]: (111, String(\"unmatched string value\"))"));
}
#[test]
fn test_lookup_refs_value_column() {
let mut conn = TestConn::default();
// Start by installing a few attributes.
assert_transact!(conn, "[[:db/add 111 :db/ident :test/unique_value]
[:db/add 111 :db/valueType :db.type/string]
[:db/add 111 :db/unique :db.unique/value]
[:db/add 111 :db/index true]
[:db/add 222 :db/ident :test/unique_identity]
[:db/add 222 :db/valueType :db.type/long]
[:db/add 222 :db/unique :db.unique/identity]
[:db/add 222 :db/index true]
[:db/add 333 :db/ident :test/not_unique]
[:db/add 333 :db/cardinality :db.cardinality/one]
[:db/add 333 :db/valueType :db.type/keyword]
[:db/add 333 :db/index true]
[:db/add 444 :db/ident :test/ref]
[:db/add 444 :db/valueType :db.type/ref]
[:db/add 444 :db/unique :db.unique/identity]
[:db/add 444 :db/index true]]");
// And a few datoms to match against.
assert_transact!(conn, "[[:db/add 501 :test/unique_value \"test this\"]
[:db/add 502 :test/unique_value \"other\"]
[:db/add 503 :test/unique_identity -10]
[:db/add 504 :test/unique_identity -20]
[:db/add 505 :test/not_unique :test/keyword]
[:db/add 506 :test/not_unique :test/keyword]]");
// We can resolve lookup refs in the entity column, referring to the attribute as an entid or an ident.
assert_transact!(conn, "[[:db/add 601 :test/ref (lookup-ref :test/unique_value \"test this\")]
[:db/add 602 :test/ref (lookup-ref 111 \"other\")]
[:db/add 603 :test/ref (lookup-ref :test/unique_identity -10)]
[:db/add 604 :test/ref (lookup-ref 222 -20)]]");
assert_matches!(conn.last_transaction(),
"[[601 :test/ref 501 ?tx true]
[602 :test/ref 502 ?tx true]
[603 :test/ref 503 ?tx true]
[604 :test/ref 504 ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
// We cannot resolve lookup refs for attributes that aren't :db/ref.
assert_transact!(conn,
"[[:db/add \"t\" :test/not_unique (lookup-ref :test/unique_value \"test this\")]]",
Err("not yet implemented: Cannot resolve value lookup ref for attribute 333 that is not :db/valueType :db.type/ref"));
// If a value column lookup ref resolves, we can upsert against it. Here, the lookup ref
// resolves to 501, which upserts "t" to 601.
assert_transact!(conn, "[[:db/add \"t\" :test/ref (lookup-ref :test/unique_value \"test this\")]
[:db/add \"t\" :test/not_unique :test/keyword]]");
assert_matches!(conn.last_transaction(),
"[[601 :test/not_unique :test/keyword ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
// Each lookup ref in the value column must resolve
assert_transact!(conn,
"[[:db/add \"t\" :test/ref (lookup-ref :test/unique_value \"unmatched string value\")]]",
Err("no entid found for ident: couldn\'t lookup [a v]: (111, String(\"unmatched string value\"))"));
}
#[test]
fn test_explode_value_lists() {
let mut conn = TestConn::default();
// Start by installing a few attributes.
assert_transact!(conn, "[[:db/add 111 :db/ident :test/many]
[:db/add 111 :db/valueType :db.type/long]
[:db/add 111 :db/cardinality :db.cardinality/many]
[:db/add 222 :db/ident :test/one]
[:db/add 222 :db/valueType :db.type/long]
[:db/add 222 :db/cardinality :db.cardinality/one]]");
// Check that we can explode vectors for :db.cardinality/many attributes.
assert_transact!(conn, "[[:db/add 501 :test/many [1]]
[:db/add 502 :test/many [2 3]]
[:db/add 503 :test/many [4 5 6]]]");
assert_matches!(conn.last_transaction(),
"[[501 :test/many 1 ?tx true]
[502 :test/many 2 ?tx true]
[502 :test/many 3 ?tx true]
[503 :test/many 4 ?tx true]
[503 :test/many 5 ?tx true]
[503 :test/many 6 ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
// Check that we can explode nested vectors for :db.cardinality/many attributes.
assert_transact!(conn, "[[:db/add 600 :test/many [1 [2] [[3] [4]] []]]]");
assert_matches!(conn.last_transaction(),
"[[600 :test/many 1 ?tx true]
[600 :test/many 2 ?tx true]
[600 :test/many 3 ?tx true]
[600 :test/many 4 ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
// Check that we cannot explode vectors for :db.cardinality/one attributes.
assert_transact!(conn,
"[[:db/add 501 :test/one [1]]]",
Err("not yet implemented: Cannot explode vector value for attribute 222 that is not :db.cardinality :db.cardinality/many"));
assert_transact!(conn,
"[[:db/add 501 :test/one [2 3]]]",
Err("not yet implemented: Cannot explode vector value for attribute 222 that is not :db.cardinality :db.cardinality/many"));
}
#[test]
fn test_explode_map_notation() {
let mut conn = TestConn::default();
// Start by installing a few attributes.
assert_transact!(conn, "[[:db/add 111 :db/ident :test/many]
[:db/add 111 :db/valueType :db.type/long]
[:db/add 111 :db/cardinality :db.cardinality/many]
[:db/add 222 :db/ident :test/component]
[:db/add 222 :db/isComponent true]
[:db/add 222 :db/valueType :db.type/ref]
[:db/add 333 :db/ident :test/unique]
[:db/add 333 :db/unique :db.unique/identity]
[:db/add 333 :db/index true]
[:db/add 333 :db/valueType :db.type/long]
[:db/add 444 :db/ident :test/dangling]
[:db/add 444 :db/valueType :db.type/ref]]");
// Check that we can explode map notation without :db/id.
let report = assert_transact!(conn, "[{:test/many 1}]");
assert_matches!(conn.last_transaction(),
"[[?e :test/many 1 ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(tempids(&report),
"{}");
// Check that we can explode map notation with :db/id, as an entid, ident, and tempid.
let report = assert_transact!(conn, "[{:db/id :db/ident :test/many 1}
{:db/id 500 :test/many 2}
{:db/id \"t\" :test/many 3}]");
assert_matches!(conn.last_transaction(),
"[[1 :test/many 1 ?tx true]
[500 :test/many 2 ?tx true]
[?e :test/many 3 ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(tempids(&report),
"{\"t\" 65537}");
// Check that we can explode map notation with :db/id as a lookup-ref or tx-function.
let report = assert_transact!(conn, "[{:db/id (lookup-ref :db/ident :db/ident) :test/many 4}
{:db/id (transaction-tx) :test/many 5}]");
assert_matches!(conn.last_transaction(),
"[[1 :test/many 4 ?tx true]
[?tx :db/txInstant ?ms ?tx true]
[?tx :test/many 5 ?tx true]]");
assert_matches!(tempids(&report),
"{}");
// Check that we can explode map notation with nested vector values.
let report = assert_transact!(conn, "[{:test/many [1 2]}]");
assert_matches!(conn.last_transaction(),
"[[?e :test/many 1 ?tx true]
[?e :test/many 2 ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(tempids(&report),
"{}");
// Check that we can explode map notation with nested maps if the attribute is
// :db/isComponent true.
let report = assert_transact!(conn, "[{:test/component {:test/many 1}}]");
assert_matches!(conn.last_transaction(),
"[[?e :test/component ?f ?tx true]
[?f :test/many 1 ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(tempids(&report),
"{}");
// Check that we can explode map notation with nested maps if the inner map contains a
// :db/unique :db.unique/identity attribute.
let report = assert_transact!(conn, "[{:test/dangling {:test/unique 10}}]");
assert_matches!(conn.last_transaction(),
"[[?e :test/dangling ?f ?tx true]
[?f :test/unique 10 ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(tempids(&report),
"{}");
// Verify that we can't explode map notation with nested maps if the inner map would be
// dangling.
assert_transact!(conn,
"[{:test/dangling {:test/many 11}}]",
Err("not yet implemented: Cannot explode nested map value that would lead to dangling entity for attribute 444"));
// Verify that we can explode map notation with nested maps, even if the inner map would be
// dangling, if we give a :db/id explicitly.
assert_transact!(conn, "[{:test/dangling {:db/id \"t\" :test/many 12}}]");
}
#[test]
fn test_explode_reversed_notation() {
let mut conn = TestConn::default();
// Start by installing a few attributes.
assert_transact!(conn, "[[:db/add 111 :db/ident :test/many]
[:db/add 111 :db/valueType :db.type/long]
[:db/add 111 :db/cardinality :db.cardinality/many]
[:db/add 222 :db/ident :test/component]
[:db/add 222 :db/isComponent true]
[:db/add 222 :db/valueType :db.type/ref]
[:db/add 333 :db/ident :test/unique]
[:db/add 333 :db/unique :db.unique/identity]
[:db/add 333 :db/index true]
[:db/add 333 :db/valueType :db.type/long]
[:db/add 444 :db/ident :test/dangling]
[:db/add 444 :db/valueType :db.type/ref]]");
// Check that we can explode direct reversed notation, entids.
let report = assert_transact!(conn, "[[:db/add 100 :test/_dangling 200]]");
assert_matches!(conn.last_transaction(),
"[[200 :test/dangling 100 ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(tempids(&report),
"{}");
// Check that we can explode direct reversed notation, idents.
let report = assert_transact!(conn, "[[:db/add :test/many :test/_dangling :test/unique]]");
assert_matches!(conn.last_transaction(),
"[[333 :test/dangling :test/many ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(tempids(&report),
"{}");
// Check that we can explode direct reversed notation, tempids.
let report = assert_transact!(conn, "[[:db/add \"s\" :test/_dangling \"t\"]]");
assert_matches!(conn.last_transaction(),
"[[65537 :test/dangling 65536 ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
// This is implementation specific, but it should be deterministic.
assert_matches!(tempids(&report),
"{\"s\" 65536
\"t\" 65537}");
// Check that we can explode reversed notation in map notation without :db/id.
let report = assert_transact!(conn, "[{:test/_dangling 501}
{:test/_dangling :test/many}
{:test/_dangling \"t\"}]");
assert_matches!(conn.last_transaction(),
"[[111 :test/dangling ?e1 ?tx true]
[501 :test/dangling ?e2 ?tx true]
[65538 :test/dangling ?e3 ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(tempids(&report),
"{\"t\" 65538}");
// Check that we can explode reversed notation in map notation with :db/id, entid.
let report = assert_transact!(conn, "[{:db/id 600 :test/_dangling 601}]");
assert_matches!(conn.last_transaction(),
"[[601 :test/dangling 600 ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(tempids(&report),
"{}");
// Check that we can explode reversed notation in map notation with :db/id, ident.
let report = assert_transact!(conn, "[{:db/id :test/component :test/_dangling :test/component}]");
assert_matches!(conn.last_transaction(),
"[[222 :test/dangling :test/component ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(tempids(&report),
"{}");
// Check that we can explode reversed notation in map notation with :db/id, tempid.
let report = assert_transact!(conn, "[{:db/id \"s\" :test/_dangling \"t\"}]");
assert_matches!(conn.last_transaction(),
"[[65543 :test/dangling 65542 ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
// This is implementation specific, but it should be deterministic.
assert_matches!(tempids(&report),
"{\"s\" 65542
\"t\" 65543}");
// Check that we can use the same attribute in both forward and backward form in the same
// transaction.
let report = assert_transact!(conn, "[[:db/add 888 :test/dangling 889]
[:db/add 888 :test/_dangling 889]]");
assert_matches!(conn.last_transaction(),
"[[888 :test/dangling 889 ?tx true]
[889 :test/dangling 888 ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(tempids(&report),
"{}");
// Check that we can use the same attribute in both forward and backward form in the same
// transaction in map notation.
let report = assert_transact!(conn, "[{:db/id 998 :test/dangling 999 :test/_dangling 999}]");
assert_matches!(conn.last_transaction(),
"[[998 :test/dangling 999 ?tx true]
[999 :test/dangling 998 ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
assert_matches!(tempids(&report),
"{}");
}
#[test]
fn test_explode_reversed_notation_errors() {
let mut conn = TestConn::default();
// Start by installing a few attributes.
assert_transact!(conn, "[[:db/add 111 :db/ident :test/many]
[:db/add 111 :db/valueType :db.type/long]
[:db/add 111 :db/cardinality :db.cardinality/many]
[:db/add 222 :db/ident :test/component]
[:db/add 222 :db/isComponent true]
[:db/add 222 :db/valueType :db.type/ref]
[:db/add 333 :db/ident :test/unique]
[:db/add 333 :db/unique :db.unique/identity]
[:db/add 333 :db/index true]
[:db/add 333 :db/valueType :db.type/long]
[:db/add 444 :db/ident :test/dangling]
[:db/add 444 :db/valueType :db.type/ref]]");
// `tx-parser` should fail to parse direct reverse notation with nested value maps and
// nested value vectors, so we only test things that "get through" to the map notation
// dynamic processor here.
// Verify that we can't explode reverse notation in map notation with nested value maps.
assert_transact!(conn,
"[{:test/_dangling {:test/many 14}}]",
Err("not yet implemented: Cannot explode map notation value in :attr/_reversed notation for attribute 444"));
// Verify that we can't explode reverse notation in map notation with nested value vectors.
assert_transact!(conn,
"[{:test/_dangling [:test/many]}]",
Err("not yet implemented: Cannot explode vector value in :attr/_reversed notation for attribute 444"));
// Verify that we can't use reverse notation with non-:db.type/ref attributes.
assert_transact!(conn,
"[{:test/_unique 500}]",
Err("not yet implemented: Cannot use :attr/_reversed notation for attribute 333 that is not :db/valueType :db.type/ref"));
// Verify that we can't use reverse notation with unrecognized attributes.
assert_transact!(conn,
"[{:test/_unknown 500}]",
Err("no entid found for ident: :test/unknown")); // TODO: make this error reference the original :test/_unknown.
// Verify that we can't use reverse notation with bad value types: here, an unknown keyword
// that can't be coerced to a ref.
assert_transact!(conn,
"[{:test/_dangling :test/unknown}]",
Err("no entid found for ident: :test/unknown"));
// And here, a float.
assert_transact!(conn,
"[{:test/_dangling 1.23}]",
Err("value \'1.23\' is not the expected Mentat value type Ref"));
}
#[test]
fn test_cardinality_one_violation_existing_entity() {
let mut conn = TestConn::default();
// Start by installing a few attributes.
assert_transact!(conn, r#"[
[:db/add 111 :db/ident :test/one]
[:db/add 111 :db/valueType :db.type/long]
[:db/add 111 :db/cardinality :db.cardinality/one]
[:db/add 112 :db/ident :test/unique]
[:db/add 112 :db/index true]
[:db/add 112 :db/valueType :db.type/string]
[:db/add 112 :db/cardinality :db.cardinality/one]
[:db/add 112 :db/unique :db.unique/identity]
]"#);
assert_transact!(conn, r#"[
[:db/add "foo" :test/unique "x"]
]"#);
// You can try to assert two values for the same entity and attribute,
// but you'll get an error.
assert_transact!(conn, r#"[
[:db/add "foo" :test/unique "x"]
[:db/add "foo" :test/one 123]
[:db/add "bar" :test/unique "x"]
[:db/add "bar" :test/one 124]
]"#,
// This is implementation specific (due to the allocated entid), but it should be deterministic.
Err("schema constraint violation: cardinality conflicts:\n CardinalityOneAddConflict { e: 65536, a: 111, vs: {Long(123), Long(124)} }\n"));
// It also fails for map notation.
assert_transact!(conn, r#"[
{:test/unique "x", :test/one 123}
{:test/unique "x", :test/one 124}
]"#,
// This is implementation specific (due to the allocated entid), but it should be deterministic.
Err("schema constraint violation: cardinality conflicts:\n CardinalityOneAddConflict { e: 65536, a: 111, vs: {Long(123), Long(124)} }\n"));
}
#[test]
fn test_conflicting_upserts() {
let mut conn = TestConn::default();
assert_transact!(conn, r#"[
{:db/ident :page/id :db/valueType :db.type/string :db/index true :db/unique :db.unique/identity}
{:db/ident :page/ref :db/valueType :db.type/ref :db/index true :db/unique :db.unique/identity}
{:db/ident :page/title :db/valueType :db.type/string :db/cardinality :db.cardinality/many}
]"#);
// Let's test some conflicting upserts. First, valid data to work with -- note self references.
assert_transact!(conn, r#"[
[:db/add 111 :page/id "1"]
[:db/add 111 :page/ref 111]
[:db/add 222 :page/id "2"]
[:db/add 222 :page/ref 222]
]"#);
// Now valid upserts. Note the references are valid.
let report = assert_transact!(conn, r#"[
[:db/add "a" :page/id "1"]
[:db/add "a" :page/ref "a"]
[:db/add "b" :page/id "2"]
[:db/add "b" :page/ref "b"]
]"#);
assert_matches!(tempids(&report),
"{\"a\" 111
\"b\" 222}");
// Now conflicting upserts. Note the references are reversed. This example is interesting
// because the first round `UpsertE` instances upsert, and this resolves all of the tempids
// in the `UpsertEV` instances. However, those `UpsertEV` instances lead to conflicting
// upserts! This tests that we don't resolve too far, giving a chance for those upserts to
// fail. This error message is crossing generations, although it's not reflected in the
// error data structure.
assert_transact!(conn, r#"[
[:db/add "a" :page/id "1"]
[:db/add "a" :page/ref "b"]
[:db/add "b" :page/id "2"]
[:db/add "b" :page/ref "a"]
]"#,
Err("schema constraint violation: conflicting upserts:\n tempid External(\"a\") upserts to {KnownEntid(111), KnownEntid(222)}\n tempid External(\"b\") upserts to {KnownEntid(111), KnownEntid(222)}\n"));
// Here's a case where the upsert is not resolved, just allocated, but leads to conflicting
// cardinality one datoms.
assert_transact!(conn, r#"[
[:db/add "x" :page/ref 333]
[:db/add "x" :page/ref 444]
]"#,
Err("schema constraint violation: cardinality conflicts:\n CardinalityOneAddConflict { e: 65539, a: 65537, vs: {Ref(333), Ref(444)} }\n"));
}
#[test]
fn test_upsert_issue_532() {
let mut conn = TestConn::default();
assert_transact!(conn, r#"[
{:db/ident :page/id :db/valueType :db.type/string :db/index true :db/unique :db.unique/identity}
{:db/ident :page/ref :db/valueType :db.type/ref :db/index true :db/unique :db.unique/identity}
{:db/ident :page/title :db/valueType :db.type/string :db/cardinality :db.cardinality/many}
]"#);
// Observe that "foo" and "zot" upsert to the same entid, and that doesn't cause a
// cardinality conflict, because we treat the input with set semantics and accept
// duplicate datoms.
let report = assert_transact!(conn, r#"[
[:db/add "bar" :page/id "z"]
[:db/add "foo" :page/ref "bar"]
[:db/add "foo" :page/title "x"]
[:db/add "zot" :page/ref "bar"]
[:db/add "zot" :db/ident :other/ident]
]"#);
assert_matches!(tempids(&report),
"{\"bar\" ?b
\"foo\" ?f
\"zot\" ?f}");
assert_matches!(conn.last_transaction(),
"[[?b :page/id \"z\" ?tx true]
[?f :db/ident :other/ident ?tx true]
[?f :page/ref ?b ?tx true]
[?f :page/title \"x\" ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
let report = assert_transact!(conn, r#"[
[:db/add "foo" :page/id "x"]
[:db/add "foo" :page/title "x"]
[:db/add "bar" :page/id "x"]
[:db/add "bar" :page/title "y"]
]"#);
assert_matches!(tempids(&report),
"{\"foo\" ?e
\"bar\" ?e}");
// One entity, two page titles.
assert_matches!(conn.last_transaction(),
"[[?e :page/id \"x\" ?tx true]
[?e :page/title \"x\" ?tx true]
[?e :page/title \"y\" ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
// Here, "foo", "bar", and "baz", all refer to the same reference, but none of them actually
// upsert to existing entities.
let report = assert_transact!(conn, r#"[
[:db/add "foo" :page/id "id"]
[:db/add "bar" :db/ident :bar/bar]
{:db/id "baz" :page/id "id" :db/ident :bar/bar}
]"#);
assert_matches!(tempids(&report),
"{\"foo\" ?e
\"bar\" ?e
\"baz\" ?e}");
assert_matches!(conn.last_transaction(),
"[[?e :db/ident :bar/bar ?tx true]
[?e :page/id \"id\" ?tx true]
[?tx :db/txInstant ?ms ?tx true]]");
// If we do it again, everything resolves to the same IDs.
let report = assert_transact!(conn, r#"[
[:db/add "foo" :page/id "id"]
[:db/add "bar" :db/ident :bar/bar]
{:db/id "baz" :page/id "id" :db/ident :bar/bar}
]"#);
assert_matches!(tempids(&report),
"{\"foo\" ?e
\"bar\" ?e
\"baz\" ?e}");
assert_matches!(conn.last_transaction(),
"[[?tx :db/txInstant ?ms ?tx true]]");
}
#[test]
fn test_term_typechecking_issue_663() {
// The builder interfaces provide untrusted `Term` instances to the transactor, bypassing
// the typechecking layers invoked in the schema-aware coercion from `edn::Value` into
// `TypedValue`. Typechecking now happens lower in the stack (as well as higher in the
// stack) so we shouldn't be able to insert bad data into the store.
let mut conn = TestConn::default();
let mut terms = vec![];
terms.push(Term::AddOrRetract(OpType::Add, Left(KnownEntid(200)), entids::DB_IDENT, Left(TypedValue::typed_string("test"))));
terms.push(Term::AddOrRetract(OpType::Retract, Left(KnownEntid(100)), entids::DB_TX_INSTANT, Left(TypedValue::Long(-1))));
let report = conn.transact_simple_terms(terms, InternSet::new());
match report.unwrap_err().downcast() {
Ok(DbError::SchemaConstraintViolation(errors::SchemaConstraintViolation::TypeDisagreements { conflicting_datoms })) => {
let mut map = BTreeMap::default();
map.insert((100, entids::DB_TX_INSTANT, TypedValue::Long(-1)), ValueType::Instant);
map.insert((200, entids::DB_IDENT, TypedValue::typed_string("test")), ValueType::Keyword);
assert_eq!(conflicting_datoms, map);
},
x => panic!("expected schema constraint violation, got {:?}", x),
}
}
#[test]
fn test_cardinality_constraints() {
let mut conn = TestConn::default();
assert_transact!(conn, r#"[
{:db/id 200 :db/ident :test/one :db/valueType :db.type/long :db/cardinality :db.cardinality/one}
{:db/id 201 :db/ident :test/many :db/valueType :db.type/long :db/cardinality :db.cardinality/many}
]"#);
// Can add the same datom multiple times for an attribute, regardless of cardinality.
assert_transact!(conn, r#"[
[:db/add 100 :test/one 1]
[:db/add 100 :test/one 1]
[:db/add 100 :test/many 2]
[:db/add 100 :test/many 2]
]"#);
// Can retract the same datom multiple times for an attribute, regardless of cardinality.
assert_transact!(conn, r#"[
[:db/retract 100 :test/one 1]
[:db/retract 100 :test/one 1]
[:db/retract 100 :test/many 2]
[:db/retract 100 :test/many 2]
]"#);
// Can't transact multiple datoms for a cardinality one attribute.
assert_transact!(conn, r#"[
[:db/add 100 :test/one 3]
[:db/add 100 :test/one 4]
]"#,
Err("schema constraint violation: cardinality conflicts:\n CardinalityOneAddConflict { e: 100, a: 200, vs: {Long(3), Long(4)} }\n"));
// Can transact multiple datoms for a cardinality many attribute.
assert_transact!(conn, r#"[
[:db/add 100 :test/many 5]
[:db/add 100 :test/many 6]
]"#);
// Can't add and retract the same datom for an attribute, regardless of cardinality.
assert_transact!(conn, r#"[
[:db/add 100 :test/one 7]
[:db/retract 100 :test/one 7]
[:db/add 100 :test/many 8]
[:db/retract 100 :test/many 8]
]"#,
Err("schema constraint violation: cardinality conflicts:\n AddRetractConflict { e: 100, a: 200, vs: {Long(7)} }\n AddRetractConflict { e: 100, a: 201, vs: {Long(8)} }\n"));
}
#[test]
#[cfg(feature = "sqlcipher")]
fn test_sqlcipher_openable() {
let secret_key = "key";
let sqlite = new_connection_with_key("../fixtures/v1encrypted.db", secret_key).expect("Failed to find test DB");
sqlite.query_row("SELECT COUNT(*) FROM sqlite_master", &[], |row| row.get::<_, i64>(0))
.expect("Failed to execute sql query on encrypted DB");
}
#[cfg(feature = "sqlcipher")]
fn test_open_fail<F>(opener: F) where F: FnOnce() -> rusqlite::Result<rusqlite::Connection> {
let err = opener().expect_err("Should fail to open encrypted DB");
match err {
rusqlite::Error::SqliteFailure(err, ..) => {
assert_eq!(err.extended_code, 26, "Should get error code 26 (not a database).");
},
err => {
panic!("Wrong error type! {}", err);
}
}
}
#[test]
#[cfg(feature = "sqlcipher")]
fn test_sqlcipher_requires_key() {
// Don't use a key.
test_open_fail(|| new_connection("../fixtures/v1encrypted.db"));
}
#[test]
#[cfg(feature = "sqlcipher")]
fn test_sqlcipher_requires_correct_key() {
// Use a key, but the wrong one.
test_open_fail(|| new_connection_with_key("../fixtures/v1encrypted.db", "wrong key"));
}
#[test]
#[cfg(feature = "sqlcipher")]
fn test_sqlcipher_some_transactions() {
let sqlite = new_connection_with_key("", "hunter2").expect("Failed to create encrypted connection");
// Run a basic test as a sanity check.
run_test_add(TestConn::with_sqlite(sqlite));
}
}
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