#[macro_use] pub mod documents; mod asc_desc; mod criterion; mod error; mod external_documents_ids; pub mod facet; mod fields_ids_map; pub mod heed_codec; pub mod index; pub mod proximity; mod search; pub mod update; use std::collections::{BTreeMap, HashMap}; use std::convert::{TryFrom, TryInto}; use std::hash::BuildHasherDefault; pub use filter_parser::{Condition, FilterCondition}; use fxhash::{FxHasher32, FxHasher64}; pub use grenad::CompressionType; use serde_json::{Map, Value}; pub use {heed, meilisearch_tokenizer as tokenizer}; 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; pub use self::heed_codec::{ BEU32StrCodec, BoRoaringBitmapCodec, BoRoaringBitmapLenCodec, CboRoaringBitmapCodec, CboRoaringBitmapLenCodec, FieldIdWordCountCodec, ObkvCodec, RoaringBitmapCodec, RoaringBitmapLenCodec, StrBEU32Codec, StrStrU8Codec, }; pub use self::index::Index; pub use self::search::{FacetDistribution, Filter, MatchingWords, Search, SearchResult}; pub type Result = std::result::Result; pub type FastMap4 = HashMap>; pub type FastMap8 = HashMap>; pub type SmallString32 = smallstr::SmallString<[u8; 32]>; pub type SmallVec16 = smallvec::SmallVec<[T; 16]>; pub type SmallVec32 = smallvec::SmallVec<[T; 32]>; pub type SmallVec8 = smallvec::SmallVec<[T; 8]>; pub type BEU32 = heed::zerocopy::U32; pub type BEU64 = heed::zerocopy::U64; pub type Attribute = u32; pub type DocumentId = u32; pub type FieldId = u16; pub type Position = u32; pub type RelativePosition = u16; pub type FieldDistribution = BTreeMap; /// 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])>; 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) } /// Transform a raw obkv store into a JSON Object. pub fn obkv_to_json( displayed_fields: &[FieldId], fields_ids_map: &FieldsIdsMap, obkv: obkv::KvReaderU16, ) -> Result> { 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() } /// Transform a JSON value into a string that can be indexed. pub fn json_to_string(value: &Value) -> Option { 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 } 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 } } } 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(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(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 { let a = geoutils::Location::new(a[0], a[1]); let b = geoutils::Location::new(b[0], b[1]); a.haversine_distance_to(&b).meters() } /// 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] } #[cfg(test)] mod tests { use serde_json::json; 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)); } }