meilisearch/milli/src/lib.rs

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#![cfg_attr(all(test, fuzzing), feature(no_coverage))]
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#![allow(clippy::type_complexity)]
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#[cfg(test)]
#[global_allocator]
pub static ALLOC: mimalloc::MiMalloc = mimalloc::MiMalloc;
#[macro_use]
pub mod documents;
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mod asc_desc;
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mod criterion;
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mod distance;
mod error;
mod external_documents_ids;
pub mod facet;
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mod fields_ids_map;
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pub mod heed_codec;
pub mod index;
pub mod proximity;
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pub mod score_details;
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mod search;
pub mod update;
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#[cfg(test)]
#[macro_use]
pub mod snapshot_tests;
use std::collections::{BTreeMap, HashMap};
use std::convert::{TryFrom, TryInto};
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use std::hash::BuildHasherDefault;
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use charabia::normalizer::{CharNormalizer, CompatibilityDecompositionNormalizer};
pub use filter_parser::{Condition, FilterCondition, Span, Token};
use fxhash::{FxHasher32, FxHasher64};
pub use grenad::CompressionType;
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pub use search::new::{
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execute_search, DefaultSearchLogger, GeoSortStrategy, SearchContext, SearchLogger,
VisualSearchLogger,
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};
use serde_json::Value;
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pub use {charabia as tokenizer, heed};
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pub use self::asc_desc::{AscDesc, AscDescError, Member, SortError};
pub use self::criterion::{default_criteria, Criterion, CriterionError};
pub use self::error::{
Error, FieldIdMapMissingEntry, InternalError, SerializationError, UserError,
};
pub use self::external_documents_ids::ExternalDocumentsIds;
pub use self::fields_ids_map::FieldsIdsMap;
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pub use self::heed_codec::{
BEU32StrCodec, BoRoaringBitmapCodec, BoRoaringBitmapLenCodec, CboRoaringBitmapCodec,
CboRoaringBitmapLenCodec, FieldIdWordCountCodec, ObkvCodec, RoaringBitmapCodec,
RoaringBitmapLenCodec, StrBEU32Codec, U8StrStrCodec, UncheckedU8StrStrCodec,
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};
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pub use self::index::Index;
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pub use self::search::{
FacetDistribution, Filter, FormatOptions, MatchBounds, MatcherBuilder, MatchingWords, Search,
SearchResult, TermsMatchingStrategy, DEFAULT_VALUES_PER_FACET,
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};
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pub type Result<T> = std::result::Result<T, error::Error>;
pub type Attribute = u32;
pub type BEU16 = heed::zerocopy::U16<heed::byteorder::BE>;
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pub type BEU32 = heed::zerocopy::U32<heed::byteorder::BE>;
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pub type BEU64 = heed::zerocopy::U64<heed::byteorder::BE>;
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pub type DocumentId = u32;
pub type FastMap4<K, V> = HashMap<K, V, BuildHasherDefault<FxHasher32>>;
pub type FastMap8<K, V> = HashMap<K, V, BuildHasherDefault<FxHasher64>>;
pub type FieldDistribution = BTreeMap<String, u64>;
pub type FieldId = u16;
pub type Object = serde_json::Map<String, serde_json::Value>;
pub type Position = u32;
pub type RelativePosition = u16;
pub type SmallString32 = smallstr::SmallString<[u8; 32]>;
pub type SmallVec16<T> = smallvec::SmallVec<[T; 16]>;
pub type SmallVec32<T> = smallvec::SmallVec<[T; 32]>;
pub type SmallVec8<T> = smallvec::SmallVec<[T; 8]>;
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/// A GeoPoint is a point in cartesian plan, called xyz_point in the code. Its metadata
/// is a tuple composed of 1. the DocumentId of the associated document and 2. the original point
/// expressed in term of latitude and longitude.
pub type GeoPoint = rstar::primitives::GeomWithData<[f64; 3], (DocumentId, [f64; 2])>;
/// The maximum length a LMDB key can be.
///
/// Note that the actual allowed length is a little bit higher, but
/// we keep a margin of safety.
const MAX_LMDB_KEY_LENGTH: usize = 500;
/// The maximum length a field value can be when inserted in an LMDB key.
///
/// This number is determined by the keys of the different facet databases
/// and adding a margin of safety.
pub const MAX_FACET_VALUE_LENGTH: usize = MAX_LMDB_KEY_LENGTH - 20;
/// The maximum length a word can be
pub const MAX_WORD_LENGTH: usize = MAX_LMDB_KEY_LENGTH / 2;
pub const MAX_POSITION_PER_ATTRIBUTE: u32 = u16::MAX as u32 + 1;
// Convert an absolute word position into a relative position.
// Return the field id of the attribute related to the absolute position
// and the relative position in the attribute.
pub fn relative_from_absolute_position(absolute: Position) -> (FieldId, RelativePosition) {
((absolute >> 16) as u16, (absolute & 0xFFFF) as u16)
}
// Compute the absolute word position with the field id of the attribute and relative position in the attribute.
pub fn absolute_from_relative_position(field_id: FieldId, relative: RelativePosition) -> Position {
(field_id as u32) << 16 | (relative as u32)
}
// TODO: this is wrong, but will do for now
/// Compute the "bucketed" absolute position from the field id and relative position in the field.
///
/// In a bucketed position, the accuracy of the relative position is reduced exponentially as it gets larger.
pub fn bucketed_position(relative: u16) -> u16 {
// The first few relative positions are kept intact.
if relative < 16 {
relative
} else if relative < 24 {
// Relative positions between 16 and 24 all become equal to 24
24
} else {
// Then, groups of positions that have the same base-2 logarithm are reduced to
// the same relative position: the smallest power of 2 that is greater than them
(relative as f64).log2().ceil().exp2() as u16
}
}
/// Transform a raw obkv store into a JSON Object.
pub fn obkv_to_json(
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displayed_fields: &[FieldId],
fields_ids_map: &FieldsIdsMap,
obkv: obkv::KvReaderU16,
) -> Result<Object> {
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displayed_fields
.iter()
.copied()
.flat_map(|id| obkv.get(id).map(|value| (id, value)))
.map(|(id, value)| {
let name = fields_ids_map.name(id).ok_or(error::FieldIdMapMissingEntry::FieldId {
field_id: id,
process: "obkv_to_json",
})?;
let value = serde_json::from_slice(value).map_err(error::InternalError::SerdeJson)?;
Ok((name.to_owned(), value))
})
.collect()
}
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/// Transform every field of a raw obkv store into a JSON Object.
pub fn all_obkv_to_json(obkv: obkv::KvReaderU16, fields_ids_map: &FieldsIdsMap) -> Result<Object> {
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let all_keys = obkv.iter().map(|(k, _v)| k).collect::<Vec<_>>();
obkv_to_json(all_keys.as_slice(), fields_ids_map, obkv)
}
/// Transform a JSON value into a string that can be indexed.
pub fn json_to_string(value: &Value) -> Option<String> {
fn inner(value: &Value, output: &mut String) -> bool {
use std::fmt::Write;
match value {
Value::Null => false,
Value::Bool(boolean) => write!(output, "{}", boolean).is_ok(),
Value::Number(number) => write!(output, "{}", number).is_ok(),
Value::String(string) => write!(output, "{}", string).is_ok(),
Value::Array(array) => {
let mut count = 0;
for value in array {
if inner(value, output) {
output.push_str(". ");
count += 1;
}
}
// check that at least one value was written
count != 0
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}
Value::Object(object) => {
let mut buffer = String::new();
let mut count = 0;
for (key, value) in object {
buffer.clear();
let _ = write!(&mut buffer, "{}: ", key);
if inner(value, &mut buffer) {
buffer.push_str(". ");
// We write the "key: value. " pair only when
// we are sure that the value can be written.
output.push_str(&buffer);
count += 1;
}
}
// check that at least one value was written
count != 0
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}
}
}
let mut string = String::new();
if inner(value, &mut string) {
Some(string)
} else {
None
}
}
/// Divides one slice into two at an index, returns `None` if mid is out of bounds.
fn try_split_at<T>(slice: &[T], mid: usize) -> Option<(&[T], &[T])> {
if mid <= slice.len() {
Some(slice.split_at(mid))
} else {
None
}
}
/// Divides one slice into an array and the tail at an index,
/// returns `None` if `N` is out of bounds.
fn try_split_array_at<T, const N: usize>(slice: &[T]) -> Option<([T; N], &[T])>
where
[T; N]: for<'a> TryFrom<&'a [T]>,
{
let (head, tail) = try_split_at(slice, N)?;
let head = head.try_into().ok()?;
Some((head, tail))
}
/// Return the distance between two points in meters. Each points are composed of two f64,
/// one latitude and one longitude.
pub fn distance_between_two_points(a: &[f64; 2], b: &[f64; 2]) -> f64 {
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let a = geoutils::Location::new(a[0], a[1]);
let b = geoutils::Location::new(b[0], b[1]);
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a.haversine_distance_to(&b).meters()
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}
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/// Convert a point expressed in terms of latitude and longitude to a point in the
/// cartesian coordinate expressed in terms of x, y and z.
pub fn lat_lng_to_xyz(coord: &[f64; 2]) -> [f64; 3] {
let [lat, lng] = coord.map(|f| f.to_radians());
let x = lat.cos() * lng.cos();
let y = lat.cos() * lng.sin();
let z = lat.sin();
[x, y, z]
}
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/// Returns `true` if the field match one of the faceted fields.
/// See the function [`is_faceted_by`] below to see what “matching” means.
pub fn is_faceted(field: &str, faceted_fields: impl IntoIterator<Item = impl AsRef<str>>) -> bool {
faceted_fields.into_iter().any(|facet| is_faceted_by(field, facet.as_ref()))
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}
/// Returns `true` if the field match the facet.
/// ```
/// use milli::is_faceted_by;
/// // -- the valid basics
/// assert!(is_faceted_by("animaux", "animaux"));
/// assert!(is_faceted_by("animaux.chien", "animaux"));
/// assert!(is_faceted_by("animaux.chien.race.bouvier bernois.fourrure.couleur", "animaux"));
/// assert!(is_faceted_by("animaux.chien.race.bouvier bernois.fourrure.couleur", "animaux.chien"));
/// assert!(is_faceted_by("animaux.chien.race.bouvier bernois.fourrure.couleur", "animaux.chien.race.bouvier bernois"));
/// assert!(is_faceted_by("animaux.chien.race.bouvier bernois.fourrure.couleur", "animaux.chien.race.bouvier bernois.fourrure"));
/// assert!(is_faceted_by("animaux.chien.race.bouvier bernois.fourrure.couleur", "animaux.chien.race.bouvier bernois.fourrure.couleur"));
///
/// // -- the wrongs
/// assert!(!is_faceted_by("chien", "chat"));
/// assert!(!is_faceted_by("animaux", "animaux.chien"));
/// assert!(!is_faceted_by("animaux.chien", "animaux.chat"));
///
/// // -- the strange edge cases
/// assert!(!is_faceted_by("animaux.chien", "anima"));
/// assert!(!is_faceted_by("animaux.chien", "animau"));
/// assert!(!is_faceted_by("animaux.chien", "animaux."));
/// assert!(!is_faceted_by("animaux.chien", "animaux.c"));
/// assert!(!is_faceted_by("animaux.chien", "animaux.ch"));
/// assert!(!is_faceted_by("animaux.chien", "animaux.chi"));
/// assert!(!is_faceted_by("animaux.chien", "animaux.chie"));
/// ```
pub fn is_faceted_by(field: &str, facet: &str) -> bool {
field.starts_with(facet)
&& field[facet.len()..].chars().next().map(|c| c == '.').unwrap_or(true)
}
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pub fn normalize_facet(original: &str) -> String {
CompatibilityDecompositionNormalizer.normalize_str(original.trim()).to_lowercase()
}
#[cfg(test)]
mod tests {
use serde_json::json;
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use super::*;
#[test]
fn json_to_string_object() {
let value = json!({
"name": "John Doe",
"age": 43,
"not_there": null,
});
let string = json_to_string(&value).unwrap();
assert_eq!(string, "name: John Doe. age: 43. ");
}
#[test]
fn json_to_string_array() {
let value = json!([
{ "name": "John Doe" },
43,
"hello",
[ "I", "am", "fine" ],
null,
]);
let string = json_to_string(&value).unwrap();
// We don't care about having two point (.) after the other as
// the distance of hard separators is clamped to 8 anyway.
assert_eq!(string, "name: John Doe. . 43. hello. I. am. fine. . ");
}
#[test]
fn test_relative_position_conversion() {
assert_eq!((0x0000, 0x0000), relative_from_absolute_position(0x00000000));
assert_eq!((0x0000, 0xFFFF), relative_from_absolute_position(0x0000FFFF));
assert_eq!((0xFFFF, 0x0000), relative_from_absolute_position(0xFFFF0000));
assert_eq!((0xFF00, 0xFF00), relative_from_absolute_position(0xFF00FF00));
assert_eq!((0xFF00, 0x00FF), relative_from_absolute_position(0xFF0000FF));
assert_eq!((0x1234, 0x5678), relative_from_absolute_position(0x12345678));
assert_eq!((0xFFFF, 0xFFFF), relative_from_absolute_position(0xFFFFFFFF));
}
#[test]
fn test_absolute_position_conversion() {
assert_eq!(0x00000000, absolute_from_relative_position(0x0000, 0x0000));
assert_eq!(0x0000FFFF, absolute_from_relative_position(0x0000, 0xFFFF));
assert_eq!(0xFFFF0000, absolute_from_relative_position(0xFFFF, 0x0000));
assert_eq!(0xFF00FF00, absolute_from_relative_position(0xFF00, 0xFF00));
assert_eq!(0xFF0000FF, absolute_from_relative_position(0xFF00, 0x00FF));
assert_eq!(0x12345678, absolute_from_relative_position(0x1234, 0x5678));
assert_eq!(0xFFFFFFFF, absolute_from_relative_position(0xFFFF, 0xFFFF));
}
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#[test]
fn test_all_obkv_to_json() {
let mut fields_ids_map = FieldsIdsMap::new();
let id1 = fields_ids_map.insert("field1").unwrap();
let id2 = fields_ids_map.insert("field2").unwrap();
let mut writer = obkv::KvWriterU16::memory();
writer.insert(id1, b"1234").unwrap();
writer.insert(id2, b"4321").unwrap();
let contents = writer.into_inner().unwrap();
let obkv = obkv::KvReaderU16::new(&contents);
let expected = json!({
"field1": 1234,
"field2": 4321,
});
let expected = expected.as_object().unwrap();
let actual = all_obkv_to_json(obkv, &fields_ids_map).unwrap();
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assert_eq!(&actual, expected);
}
}