//! This module prepares the database layout.
//!
//! The XML import may be in an arbitrary order, so importing data is
//! a multi-step process where we first set up schemas matching the
//! data layout, import the data, and then modify the schema to
//! introduce things like foreign key constraints between tables that
//! represent relations.
use super::Ensure;
use crate::oc_parser::*;
use crate::or_parser;
use log::{debug, info};
use rusqlite::Connection;
/// Sets up an initial schema which matches the OpenCorpora data.
pub fn initial_oc_schema(conn: &Connection) {
conn.execute_batch(
r#"
-- table for plain import of grammemes from XML
CREATE TABLE oc_grammemes (
name TEXT PRIMARY KEY,
parent TEXT,
alias TEXT,
description TEXT
) STRICT;
-- table for plain import of lemmas (*not* their variations!)
CREATE TABLE oc_lemmas (
id INTEGER PRIMARY KEY,
lemma TEXT NOT NULL
) STRICT;
-- table for relationship between grammemes and lemmas
CREATE TABLE oc_lemma_grammemes (
lemma INTEGER,
grammeme TEXT NOT NULL,
FOREIGN KEY(lemma) REFERENCES oc_lemmas(id)
) STRICT;
-- table for all words, i.e. including variations of lemmata
CREATE TABLE oc_words (
lemma INTEGER NOT NULL,
word TEXT NOT NULL,
FOREIGN KEY(lemma) REFERENCES oc_lemmas(id)
) STRICT;
-- table for relationship between words and grammemes
CREATE TABLE oc_word_grammemes (
word INTEGER NOT NULL,
grammeme TEXT NOT NULL,
FOREIGN KEY(word) REFERENCES oc_words(ROWID)
) STRICT;
-- table for link types
CREATE TABLE oc_link_types (
id INTEGER PRIMARY KEY,
name TEXT
) STRICT;
-- table for links between lemmata
CREATE TABLE oc_links (
id INTEGER PRIMARY KEY,
link_type INTEGER NOT NULL,
from_lemma INTEGER NOT NULL,
to_lemma INTEGER NOT NULL,
FOREIGN KEY(link_type) REFERENCES oc_link_types(id),
FOREIGN KEY(from_lemma) REFERENCES oc_lemmas(id),
FOREIGN KEY(to_lemma) REFERENCES oc_lemmas(id)
) STRICT;
"#,
)
.ensure("setting up OpenCorpora table schema failed");
info!("set up initial table schema for OpenCorpora import");
}
/// Inserts a single OpenCorpora element into the initial table structure.
pub fn insert_oc_element(conn: &Connection, elem: OcElement) {
match elem {
OcElement::Grammeme(grammeme) => {
conn.execute(
"INSERT INTO oc_grammemes (name, parent, alias, description) VALUES (?1, ?2, ?3, ?4)",
(
&grammeme.name,
&grammeme.parent,
&grammeme.alias,
&grammeme.description,
),
)
.ensure("failed to insert grammeme");
debug!("inserted grammeme {}", grammeme.name);
}
OcElement::Lemma(lemma) => insert_lemma(conn, lemma),
OcElement::LinkType(lt) => {
conn.execute(
"INSERT INTO oc_link_types (id, name) VALUES (?1, ?2)",
(<.id, <.name),
)
.ensure("failed to insert link type");
info!("inserted link type {}", lt.name);
}
OcElement::Link(link) => {
let mut stmt = conn
.prepare_cached(
"INSERT INTO oc_links (id, link_type, from_lemma, to_lemma) VALUES (?1, ?2, ?3, ?4)",
)
.ensure("failed to prepare link statement");
stmt.execute((&link.id, &link.link_type, &link.from, &link.to))
.ensure("failed to insert link");
debug!("inserted link {}", link.id);
}
}
}
/// Insert a single lemma into the initial structure. This is somewhat
/// involved because it also establishes a bunch of relations.
fn insert_lemma(conn: &Connection, lemma: Lemma) {
// insert the lemma itself
let mut stmt = conn
.prepare_cached("INSERT INTO oc_lemmas (id, lemma) VALUES (?1, ?2)")
.ensure("failed to prepare statement");
stmt.execute((&lemma.id, &lemma.lemma.word))
.ensure("failed to insert grammeme");
// followed by its relations to the grammemes set
let mut stmt = conn
.prepare_cached("INSERT INTO oc_lemma_grammemes (lemma, grammeme) VALUES (?1, ?2)")
.ensure("failed to prepare statement");
for grammeme in lemma.grammemes {
stmt.execute((&lemma.id, grammeme))
.ensure("failed to insert grammeme<>lemma relationship");
}
// followed by all of its variations ...
let mut word_insert = conn
.prepare_cached("INSERT INTO oc_words (lemma, word) VALUES (?1, ?2)")
.unwrap();
let mut word_grammeme = conn
.prepare_cached("INSERT INTO oc_word_grammemes (word, grammeme) VALUES (?1, ?2)")
.unwrap();
for variation in lemma.variations {
// insert the word itself and get its rowid
word_insert
.execute((&lemma.id, &variation.word))
.ensure("failed to insert word");
let row_id = conn.last_insert_rowid();
// then insert its grammeme links
for grammeme in variation.grammemes {
word_grammeme
.execute((row_id, grammeme))
.ensure("failed to insert word<>grammeme link");
}
}
debug!("inserted lemma {}", lemma.id);
}
/// Sets up an initial schema for the OpenRussian data.
pub fn initial_or_schema(conn: &Connection) {
conn.execute_batch(
r#"
CREATE TABLE or_words (
id INTEGER PRIMARY KEY,
bare TEXT NOT NULL,
accented TEXT,
derived_from_word_id INTEGER,
rank INTEGER,
word_type TEXT,
level TEXT
) STRICT;
CREATE TABLE or_words_forms (
id INTEGER PRIMARY KEY,
word_id INTEGER NOT NULL,
form_type TEXT,
position TEXT,
form TEXT,
form_bare TEXT,
FOREIGN KEY(word_id) REFERENCES words(id)
) STRICT;
CREATE TABLE or_translations (
id INTEGER PRIMARY KEY,
word_id INTEGER NOT NULL,
translation TEXT,
example_ru TEXT,
example_tl TEXT,
info TEXT,
FOREIGN KEY(word_id) REFERENCES words(id)
) STRICT;
"#,
)
.ensure("setting up OpenRussian table schema failed");
info!("set up initial table schema for OpenRussian import");
}
pub fn insert_or_words<I: Iterator<Item = or_parser::Word>>(conn: &Connection, words: I) {
let mut stmt = conn
.prepare_cached(
"
INSERT INTO or_words (id, bare, accented, derived_from_word_id, rank, word_type, level)
VALUES (?1, ?2, ?3, ?4, ?5, ?6, ?7)
",
)
.ensure("failed to prepare OR words statement");
let mut count = 0;
for word in words {
stmt.execute((
word.id,
word.bare,
word.accented,
word.derived_from_word_id,
word.rank,
word.word_type,
word.level,
))
.ensure("failed to insert OR word");
count += 1;
}
info!("inserted {} OpenRussian words", count);
}
pub fn insert_or_word_forms<I: Iterator<Item = or_parser::WordForm>>(conn: &Connection, forms: I) {
let mut stmt = conn
.prepare_cached(
"
INSERT INTO or_words_forms (id, word_id, form_type, position, form, form_bare)
VALUES (?1, ?2, ?3, ?4, ?5, ?6)
",
)
.ensure("failed to prepare OR word forms statement");
let mut count = 0;
for form in forms {
stmt.execute((
form.id,
form.word_id,
form.form_type,
form.position,
form.form,
form.form_bare,
))
.ensure("failed to insert OR word form");
count += 1;
}
info!("inserted {} OpenRussian word forms", count);
}
pub fn insert_or_translations<I: Iterator<Item = or_parser::Translation>>(
conn: &Connection,
translations: I,
) {
let mut stmt = conn
.prepare_cached(
"INSERT INTO or_translations (id, word_id, translation, example_ru, example_tl, info)
VALUES (?1, ?2, ?3, ?4, ?5, ?6)",
)
.ensure("failed to prepare OR translation statement");
let mut count = 0;
for tl in translations {
if tl.lang != "en" {
continue;
}
stmt.execute((
tl.id,
tl.word_id,
tl.tl,
tl.example_ru,
tl.example_tl,
tl.info,
))
.ensure("failed to insert OR translation");
count += 1;
}
info!("inserted {} OpenRussian translations", count);
}
