Commit Graph

2303 Commits

Author SHA1 Message Date
unvalley
811f156031 Execute cargo clippy --fix 2022-10-27 01:00:00 +09:00
unvalley
d8fed1f7a9 Add clippy job
Add Run Clippy to bors.toml
2022-10-27 01:00:00 +09:00
bors[bot]
2e539249cb
Merge #619
619: Refactor the Facets databases to enable incremental indexing r=curquiza a=loiclec

# Pull Request

## What does this PR do?
Party fixes https://github.com/meilisearch/milli/issues/605 by making the indexing of the facet databases (i.e. `facet_id_f64_docids` and `facet_id_string_docids`) incremental. It also closes #327 and https://github.com/meilisearch/meilisearch/issues/2820 . Two more untracked bugs were also fixed:
1. The facet distribution algorithm did not respect the `maxFacetValues` parameter when there were only a few candidate document ids.
2. The structure of the levels > 0 of the facet databases were not updated following the deletion of documents

## How to review this PR

First, read this comment to get an overview of the changes.

Then, based on this comment, raise any concerns you might have about:
1. the new structure of the databases
2. the algorithms for sort, facet distribution, and range search
3. the new/removed heed codecs

Then, weigh in on the following concerns:
1. adding `fuzzcheck` as a fuzz-only dependency may add too much complexity for the benefits it provides
2. the `ByteSliceRef` and `StrRefCodec` are misnamed or should not exist
3. the new behaviour of facet distributions can be considered incorrect
4. incremental deletion is useless given that documents are always deleted in bulk

## What's left for me to do

1. Re-read everything once to make sure I haven't forgotten anything
2. Wait for the results of the benchmarks and see if (1) they provide enough information (2) there was any change in performance, especially for search queries. Then, maybe, spend some time optimising the code.
3. Test whether the `info`/`http-ui` crates survived the refactor

## Old structure of the `facet_id_f64_docids` and `facet_id_string_docids` databases

Previously, these two databases had different but conceptually similar structures. For each field id, the facet number database had the following format:
```
            ┌───────────────────────────────┬───────────────────────────────┬───────────────┐
┌───────┐   │            1.2 – 2            │           3.4 – 100           │   102 – 104   │
│Level 2│   │                               │                               │               │
└───────┘   │         a, b, d, f, z         │         c, d, e, f, g         │     u, y      │
            ├───────────────┬───────────────┼───────────────┬───────────────┼───────────────┤
┌───────┐   │   1.2 – 1.3   │    1.6 – 2    │   3.4 – 12    │  12.3 – 100   │   102 – 104   │
│Level 1│   │               │               │               │               │               │
└───────┘   │  a, b, d, z   │    a, b, f    │    c, d, g    │     e, f      │     u, y      │
            ├───────┬───────┼───────┬───────┼───────┬───────┼───────┬───────┼───────┬───────┤
┌───────┐   │  1.2  │  1.3  │  1.6  │   2   │  3.4  │   12  │  12.3 │  100  │  102  │  104  │
│Level 0│   │       │       │       │       │       │       │       │       │       │       │
└───────┘   │  a, b │  d, z │  b, f │  a, f │  c, d │   g   │   e   │  e, f │   y   │   u   │
            └───────┴───────┴───────┴───────┴───────┴───────┴───────┴───────┴───────┴───────┘
```
where the first line is the key of the database, consisting of :
- the field id
- the level height
- the left and right bound of the group 

and the second line is the value of the database, consisting of:
- a bitmap of all the docids that have a facet value within the bounds

The `facet_id_string_docids` had a similar structure:
```
            ┌───────────────────────────────┬───────────────────────────────┬───────────────┐
┌───────┐   │             0 – 3             │             4 – 7             │     8 – 9     │
│Level 2│   │                               │                               │               │
└───────┘   │         a, b, d, f, z         │         c, d, e, f, g         │     u, y      │
            ├───────────────┬───────────────┼───────────────┬───────────────┼───────────────┤
┌───────┐   │     0 – 1     │     2 – 3     │     4 – 5     │     6 – 7     │     8 – 9     │
│Level 1│   │  "ab" – "ac"  │ "ba" – "bac"  │ "gaf" – "gal" │"form" – "wow" │ "woz" – "zz"  │
└───────┘   │  a, b, d, z   │    a, b, f    │    c, d, g    │     e, f      │     u, y      │
            ├───────┬───────┼───────┬───────┼───────┬───────┼───────┬───────┼───────┬───────┤
┌───────┐   │  "ab" │  "ac" │  "ba" │ "bac" │ "gaf" │ "gal" │ "form"│ "wow" │ "woz" │  "zz" │
│Level 0│   │  "AB" │ " Ac" │ "ba " │ "Bac" │ " GAF"│ "gal" │ "Form"│ " wow"│ "woz" │  "ZZ" │
└───────┘   │  a, b │  d, z │  b, f │  a, f │  c, d │   g   │   e   │  e, f │   y   │   u   │
            └───────┴───────┴───────┴───────┴───────┴───────┴───────┴───────┴───────┴───────┘
```
where, **at level 0**, the key is:
* the normalised facet value (string)

and the value is:
* the original facet value (string)
* a bitmap of all the docids that have this normalised string facet value

**At level 1**, the key is:
* the left bound of the range as an index in level 0
* the right bound of the range as an index in level 0

and the value is:
* the left bound of the range as a normalised string
* the right bound of the range as a normalised string
* a bitmap of all the docids that have a string facet value within the bounds

**At level > 1**, the key is:
* the left bound of the range as an index in level 0
* the right bound of the range as an index in level 0

and the value is:
* a bitmap of all the docids that have a string facet value within the bounds

## New structure of the `facet_id_f64_docids` and `facet_id_string_docids` databases

Now both the `facet_id_f64_docids` and `facet_id_string_docids` databases have the exact same structure:
```                                                                                             
            ┌───────────────────────────────┬───────────────────────────────┬───────────────┐
┌───────┐   │           "ab" (2)            │           "gaf" (2)           │   "woz" (1)   │
│Level 2│   │                               │                               │               │
└───────┘   │        [a, b, d, f, z]        │        [c, d, e, f, g]        │    [u, y]     │
            ├───────────────┬───────────────┼───────────────┬───────────────┼───────────────┤
┌───────┐   │   "ab" (2)    │   "ba" (2)    │   "gaf" (2)   │  "form" (2)   │   "woz" (2)   │
│Level 1│   │               │               │               │               │               │
└───────┘   │ [a, b, d, z]  │   [a, b, f]   │   [c, d, g]   │    [e, f]     │    [u, y]     │
            ├───────┬───────┼───────┬───────┼───────┬───────┼───────┬───────┼───────┬───────┤
┌───────┐   │  "ab" │  "ac" │  "ba" │ "bac" │ "gaf" │ "gal" │ "form"│ "wow" │ "woz" │  "zz" │
│Level 0│   │       │       │       │       │       │       │       │       │       │       │
└───────┘   │ [a, b]│ [d, z]│ [b, f]│ [a, f]│ [c, d]│  [g]  │  [e]  │ [e, f]│  [y]  │  [u]  │
            └───────┴───────┴───────┴───────┴───────┴───────┴───────┴───────┴───────┴───────┘
```
where for all levels, the key is a `FacetGroupKey<T>` containing:
* the field id (`u16`)
* the level height (`u8`)
* the left bound of the range (`T`)

and the value is a `FacetGroupValue` containing:
* the number of elements from the level below that are part of the range (`u8`, =0 for level 0)
* a bitmap of all the docids that have a facet value within the bounds (`RoaringBitmap`)

The right bound of the range is now implicit, it is equal to `Excluded(next_left_bound)`.

In the code, the key is always encoded using `FacetGroupKeyCodec<C>` where `C` is the codec used to encode the facet value (either `OrderedF64Codec` or `StrRefCodec`) and the value is encoded with `FacetGroupValueCodec`.

Since both databases share the same structure, we can implement almost all operations only once by treating the facet value as a byte slice (i.e. `FacetGroupKey<&[u8]>` encoded as `FacetGroupKeyCodec<ByteSliceRef>`). This is, in my opinion, a big simplification.

The reason for changing the structure of the databases is to make it possible to incrementally add a facet value to an existing database. Since the `facet_id_string_docids` used to store indices to `level 0` in all levels > 0, adding an element to level 0 would potentially invalidate all the indices.

Note that the original string value of a facet is no longer stored in this database.

## Incrementally adding a facet value

Here I describe how we can add a facet value to the new database incrementally. If we want to add the document with id `z` and facet value `gap`., then we want to add/modify the elements highlighted below in pink:
<img width="946" alt="Screenshot 2022-09-12 at 10 14 54" src="https://user-images.githubusercontent.com/6040237/189605532-fe4b0f52-e13d-4b3c-92d9-10c705953e3d.png">

which results in:
<img width="662" alt="Screenshot 2022-09-12 at 10 23 29" src="https://user-images.githubusercontent.com/6040237/189607015-c3a37588-b825-43c2-878a-f8f85c000b94.png">

* one element was added in level 0
* one key/value was modified in level 1
* one value was modified in level 2

Adding this element was easy since we could simply add it to level 0 and then increase the `group_size` part of the value for the level above. However, in order to keep the structure balanced, we can't always do this. If the group size reaches a threshold (`max_group_size`), then we split the node into two. For example, let's imagine that `max_group_size` is `4` and we add the docid `y` with facet value `gas`. First, we add it in level 0:
<img width="904" alt="Screenshot 2022-09-12 at 10 30 40" src="https://user-images.githubusercontent.com/6040237/189608391-531f9df1-3424-4f1f-8344-73eb194570e5.png">
Then, we realise that the group size of its parent is going to reach the maximum group size (=4) and thus we split the parent into two nodes:
<img width="919" alt="Screenshot 2022-09-12 at 10 33 16" src="https://user-images.githubusercontent.com/6040237/189608884-66f87635-1fc6-41d2-a459-87c995491ac4.png">
and since we inserted an element in level 1, we also update level 2 accordingly, by increasing the group size of the parent:
<img width="915" alt="Screenshot 2022-09-12 at 10 34 42" src="https://user-images.githubusercontent.com/6040237/189609233-d4a893ff-254a-48a7-a5ad-c0dc337f23ca.png">

We also have two other parameters:
* `group_size` is the default group size when building the database from scratch
* `min_level_size` is the minimum number of elements that a level should contain

When the highest level size is greater than `group_size * min_level_size`, then we create an additional level above it.

There is one more edge case for the insertion algorithm. While we normally don't modify the existing left bounds of a key, we have to do it if the facet value being inserted is smaller than the first left bound. For example, inserting `"aa"` with the docid `w` would change the database to:
<img width="756" alt="Screenshot 2022-09-12 at 10 41 56" src="https://user-images.githubusercontent.com/6040237/189610637-a043ef71-7159-4bf1-b4fd-9903134fc095.png">

The root of the code for incremental indexing is the `FacetUpdateIncremental` builder.

## Incrementally removing a facet value
TODO: the algorithm was implemented and works, but its current API is: `fn delete(self, facet_value, single_docid)`. It removes the given document id from all keys containing the given facet value. I don't think it is the right way to implement it anymore. Perhaps a bitmap of docids should be given instead. This is fairly easy to do. But since we batch document deletions together (because of soft deletion), it's not clear to me anymore that incremental deletion should be implemented at all.  

## Bulk insertion
While it's faster to incrementally add a single facet value to the database, it is sometimes **slower** to repeatedly add facet values one-by-one instead of doing it in bulk. For example, during initial indexing, we'd like to build the database from a list of facet values and associated document ids in one go. The `FacetUpdateBulk` builder provides a way to do so. It works by:
1. clearing all levels > 0 from the DB
2. adding all new elements in level 0
3. rebuilding the higher levels from scratch 

The algorithm for bulk insertion is the same as the previous one.

## Choosing between incremental and bulk insertion
On my computer, I measured that is about 50x slower to add N facet values incrementally than it is to re-build a database with N facet values in level 0. Therefore, we dynamically choose to use either incremental insertion or bulk insertion based on (1) the number of existing elements in level 0 of the database and (2) the number of facet values from the new documents.

This is imprecise but is mainly aimed at avoiding the worst-case scenario where the incremental insertion method is used repeatedly millions of times.

## Fuzz-testing

**Potentially controversial:**
I fuzz-tested incremental addition and deletion using fuzzcheck, which found many bugs. The fuzz-test consists of inserting/deleting facet values and docids in succession, each operation is processed with different parameters for `group_size`, `max_group_size`, and `min_level_size`. After all the operations are processed, the content of level 0 is compared to the content of an equivalent structure with a simple and easily-checked implementation. Furthermore, we check that the database has a correct structure (all groups from levels > 0 correctly combine the content of their children). I also visualised the code coverage found by the fuzz-test. It covered 100% of the relevant code except for `unreachable/panic` statements and errors returned by `heed`.

The fuzz-test and the fuzzcheck dependency are only compiled when `cargo fuzzcheck` is used. For now, the dependency is from a local path on my computer, but it can be changed to a crate version if we decide to keep it. 

## Algorithms operating on the facet databases

There are four important algorithms making use of the facet databases:
1. Sort, ascending
2. Sort, descending
3. Facet distribution
4. Range search

Previously, the implementation of all four algorithms was based on a number of iterators specific to each database kind (number or string): `FacetNumberRange`, `FacetNumberRevRange`, `FacetNumberIter` (with a reversed and reducing/non-reducing option), `FacetStringGroupRange`, `FacetStringGroupRevRange`, `FacetStringLevel0Range`, `FacetStringLevel0RevRange`, and `FacetStringIter` (reversed + reducing/non-reducing). 

Now, all four algorithms have a unique implementation shared by both the string and number databases. There are four functions:
1. `ascending_facet_sort` in `search/facet/facet_sort_ascending.rs`
2. `descending_facet_sort` in `search/facet/facet_sort_descending.rs`
3. `iterate_over_facet_distribution` in `search/facet/facet_distribution_iter.rs`
4. `find_docids_of_facet_within_bounds` in `search/facet/facet_range_search.rs`

I have tried to test them with some snapshot tests but more testing could still be done. I don't *think* that the performance of these algorithms regressed, but that will need to be confirmed by benchmarks.

## Change of behaviour for facet distributions

Previously, the original string value of a facet was stored in the level 0 of `facet_id_string_docids `. This is no longer the case. The original string value was used in the implementation of the facet distribution algorithm. Now, to recover it, we pick a random document id which contains the normalised string value and look up the original one in `field_id_docid_facet_strings`. As a consequence, it may be that the string value returned in the field distribution does not appear in any of the candidates. For example,
```json
{ "id": 0, "colour": "RED" }
{ "id": 1, "colour": "red" }
```
Facet distribution for the `colour` field among the candidates `[1]`:
```
{ "RED": 1 }
```
Here, "RED" was given as the original facet value even though it does not appear in the document id `1`.

## Heed codecs

A number of heed codecs related to the facet databases were removed:
* `FacetLevelValueF64Codec`
* `FacetLevelValueU32Codec`
* `FacetStringLevelZeroCodec`
* `StringValueCodec`
* `FacetStringZeroBoundsValueCodec`
* `FacetValueStringCodec`
* `FieldDocIdFacetStringCodec`
* `FieldDocIdFacetF64Codec`

They were replaced by:
* `FacetGroupKeyCodec<C>` (replaces all key codecs for the facet databases)
* `FacetGroupValueCodec` (replaces all value codecs for the facet databases)
* `FieldDocIdFacetCodec<C>` (replaces `FieldDocIdFacetStringCodec` and `FieldDocIdFacetF64Codec`)

Since the associated encoded item of `FacetGroupKeyCodec<C>` is `FacetKey<T>` and we often work with `FacetKey<&[u8]>` and `FacetKey<&str>`, then we need to have codecs that encode values of type `&str` and `&[u8]`. The existing `ByteSlice` and `Str` codecs do not work for that purpose (their `EItem` are `[u8]` and `str`), I have also created two new codecs:
* `ByteSliceRef` is a codec with a `EItem = DItem = &[u8]`
* `StrRefCodec` is a codec with a `EItem = DItem = &str`

I have also factored out the code used to encode an ordered f64 into its own `OrderedF64Codec`.


Co-authored-by: Loïc Lecrenier <loic@meilisearch.com>
2022-10-26 15:04:53 +00:00
Samyak S Sarnayak
488d31ecdf
Run cargo fmt 2022-10-26 19:09:45 +05:30
Samyak S Sarnayak
af33d22f25
Consecutive is false when at least 1 stop word is surrounded by words 2022-10-26 19:09:45 +05:30
Samyak S Sarnayak
f1da623af3
Add test for phrase search with stop words and all criteria at once
Moved the actual test into a separate function used by both the existing
test and the new test.
2022-10-26 19:09:44 +05:30
Samyak S Sarnayak
77f1ff019b
Simplify stop word checking in create_primitive_query 2022-10-26 19:09:44 +05:30
Samyak S Sarnayak
2aa11afb87
Fix panic when phrase contains only one stop word and nothing else 2022-10-26 19:09:42 +05:30
Samyak S Sarnayak
bb9ce3c5c5
Run cargo fmt 2022-10-26 19:09:03 +05:30
Samyak S Sarnayak
d187b32a28
Fix snapshots to use new phrase type 2022-10-26 19:09:03 +05:30
Samyak S Sarnayak
c8c666c6a6
Use resolve_phrase in exactness and typo criteria 2022-10-26 19:09:01 +05:30
Samyak S Sarnayak
3e190503e6
Search for closest non-stop words in proximity criteria 2022-10-26 19:08:34 +05:30
Samyak S Sarnayak
709ab3c14c
Increment position even when it's a stop word in exactness criteria 2022-10-26 19:08:33 +05:30
Samyak S Sarnayak
ef13c6a5b6
Perform filter after enumerate to keep origin indices 2022-10-26 19:08:33 +05:30
Samyak S Sarnayak
6a10b679ca
Add test for phrase search with stop words
Originally written by ManyTheFish here:
https://gist.github.com/ManyTheFish/f840e37cb2d2e029ce05396b4d540762

Co-authored-by: ManyTheFish <many@meilisearch.com>
2022-10-26 19:08:32 +05:30
Samyak S Sarnayak
62816dddde
[WIP] Fix phrase search containing stop words
Fixes #661 and meilisearch/meilisearch#2905
2022-10-26 19:08:06 +05:30
Loïc Lecrenier
54c0cf93fe Merge remote-tracking branch 'origin/main' into facet-levels-refactor 2022-10-26 15:13:34 +02:00
bors[bot]
365f44c39b
Merge #668
668: Fix many Clippy errors part 2 r=ManyTheFish a=ehiggs

This brings us a step closer to enforcing clippy on each build.

# Pull Request

## Related issue
This does not fix any issue outright, but it is a second round of fixes for clippy after https://github.com/meilisearch/milli/pull/665. This should contribute to fixing https://github.com/meilisearch/milli/pull/659.

## What does this PR do?

Satisfies many issues for clippy. The complaints are mostly:

* Passing reference where a variable is already a reference.
* Using clone where a struct already implements `Copy`
* Using `ok_or_else` when it is a closure that returns a value instead of using the closure to call function (hence we use `ok_or`)
* Unambiguous lifetimes don't need names, so we can just use `'_`
* Using `return` when it is not needed as we are on the last expression of a function.

## PR checklist
Please check if your PR fulfills the following requirements:
- [x] Does this PR fix an existing issue, or have you listed the changes applied in the PR description (and why they are needed)?
- [x] Have you read the contributing guidelines?
- [x] Have you made sure that the title is accurate and descriptive of the changes?

Thank you so much for contributing to Meilisearch!


Co-authored-by: Ewan Higgs <ewan.higgs@gmail.com>
2022-10-26 12:16:24 +00:00
Loïc Lecrenier
2fa85a24ec Remove outdated files from http-ui/ and infos/
... that were reintroduced after a rebase
2022-10-26 14:09:35 +02:00
Loïc Lecrenier
631e9910da Depend on released version of fuzzcheck from crates.io 2022-10-26 14:06:59 +02:00
Loïc Lecrenier
2741756248 Merge remote-tracking branch 'origin/main' into facet-levels-refactor 2022-10-26 14:03:23 +02:00
bors[bot]
d3f95e6c69
Merge #671
671: Update version for the next release (v0.35.0) in Cargo.toml files r=Kerollmops a=meili-bot

⚠️ This PR is automatically generated. Check the new version is the expected one before merging.

Co-authored-by: curquiza <curquiza@users.noreply.github.com>
2022-10-26 11:58:05 +00:00
Loïc Lecrenier
b7f2428961 Fix formatting and warning after rebasing from main 2022-10-26 13:49:33 +02:00
Loïc Lecrenier
3b1f908e5e Revert behaviour of facet distribution to what it was before
Where the docid that is used to get the original facet string value
definitely belongs to the candidates
2022-10-26 13:48:01 +02:00
Loïc Lecrenier
14ca8048a8 Add some documentation on how to run the facet db fuzzer 2022-10-26 13:48:01 +02:00
Loïc Lecrenier
206a3e00e5 cargo fmt 2022-10-26 13:48:01 +02:00
Loïc Lecrenier
f198b20c42 Add facet deletion tests that use both the incremental and bulk methods
+ update deletion snapshots to the new database format
2022-10-26 13:47:46 +02:00
Loïc Lecrenier
e3ba1fc883 Make deletion tests for both soft-deletion and hard-deletion 2022-10-26 13:47:46 +02:00
Loïc Lecrenier
ab5e56fd16 Add document deletion snapshot tests and tests for hard-deletion 2022-10-26 13:47:46 +02:00
Loïc Lecrenier
d885de1600 Add option to avoid soft deletion of documents 2022-10-26 13:47:46 +02:00
Loïc Lecrenier
ee1abfd1c1 Ignore files generated by fuzzcheck 2022-10-26 13:47:46 +02:00
Loïc Lecrenier
2295e0e3ce Use real delete function in facet indexing fuzz tests
By deleting multiple docids at once instead of one-by-one
2022-10-26 13:47:46 +02:00
Loïc Lecrenier
acc8caebe6 Add link to GitHub PR to document of update/facet module 2022-10-26 13:47:46 +02:00
Loïc Lecrenier
a034a1e628 Move StrRefCodec and ByteSliceRefCodec to their own files 2022-10-26 13:47:46 +02:00
Loïc Lecrenier
1165ba2171 Make facet deletion incremental 2022-10-26 13:47:04 +02:00
Loïc Lecrenier
0ade699873 Don't crash when failing to decode using StrRef codec 2022-10-26 13:47:04 +02:00
Loïc Lecrenier
d0109627b9 Fix a bug in facet_range_search and add documentation 2022-10-26 13:47:04 +02:00
Loïc Lecrenier
a2270b7432 Change fuzzcheck dependency to point to git repository 2022-10-26 13:47:04 +02:00
Loïc Lecrenier
1ecd3bb822 Fix bug in FieldDocIdFacetCodec 2022-10-26 13:47:04 +02:00
Loïc Lecrenier
51961e1064 Polish some details 2022-10-26 13:47:04 +02:00
Loïc Lecrenier
cb8442a119 Further unify facet databases of f64s and strings 2022-10-26 13:47:04 +02:00
Loïc Lecrenier
3baa34d842 Fix compiler errors/warnings 2022-10-26 13:47:04 +02:00
Loïc Lecrenier
86d9f50b9c Fix bugs in incremental facet indexing with variable parameters
e.g. add one facet value incrementally with a group_size = X and then
add another one with group_size = Y

It is not actually possible to do so with the public API of milli,
but I wanted to make sure the algorithm worked well in those cases
anyway.

The bugs were found by fuzzing the code with fuzzcheck, which I've added
to milli as a conditional dev-dependency. But it can be removed later.
2022-10-26 13:47:04 +02:00
Loïc Lecrenier
de52a9bf75 Improve documentation of some facet-related algorithms 2022-10-26 13:47:04 +02:00
Loïc Lecrenier
985a94adfc cargo fmt 2022-10-26 13:47:04 +02:00
Loïc Lecrenier
b1ab09196c Remove outdated TODOs 2022-10-26 13:47:04 +02:00
Loïc Lecrenier
3d7ed3263f Fix bug in string facet distribution with few candidates 2022-10-26 13:47:04 +02:00
Loïc Lecrenier
fca4577e23 Return original string in facet distributions, work on facet tests 2022-10-26 13:47:04 +02:00
Loïc Lecrenier
27454e9828 Document and refine facet indexing algorithms 2022-10-26 13:47:04 +02:00
Loïc Lecrenier
bee3c23b45 Add comparison benchmark between bulk and incremental facet indexing 2022-10-26 13:47:04 +02:00