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base: rust:remove-byteorder
Branches Tags
rust:main rust:stuhood.upstream-erased-sort-computer rust:trinity.pointard/ff-query rust:bucket_id_agg rust:paradedb/fix-agg-validation rust:flatheadmill-geo rust:paradedb-paradedb/fix-overflow-issue rust:low_card_optimization rust:paul.masurel/clippy rust:fix_size_hint rust:qw-airmail-20250916 rust:unit-test-aggregation-sum-other rust:clippy-and-cleanups rust:trinity.pointard/opti-sstable-sorted-ords-to-term rust:release_0.24 rust:dependabot/cargo/rand-0.9.1 rust:dependabot/cargo/lru-0.14.0 rust:dependabot/cargo/fs4-0.13.1 rust:tagged-user-input-ast rust:1686a/parse-agg-res rust:dependabot/cargo/rand_distr-0.5.1 rust:issue/2411-adding-panic-handler-to-rayon-merge-thread-pool rust:dependabot/cargo/nom-8 rust:upgrade_deps rust:test_parser rust:dependabot/github_actions/codecov/codecov-action-5 rust:binggan-0.12.0 rust:agg_format rust:path_collector rust:test_order_bug rust:test_columnar_multi rust:columnar_optionalmask_in_multivalues rust:prefix-phrase-query-optim rust:tantivy-with-oneshot rust:update_example rust:store-reader-enumerate rust:document-deserialize-seed rust:check_doc_mem rust:experimental-do-not-merge rust:expdonotmerge rust:cherry-pick-vec-instead-of-btreemap rust:validate_length rust:raphael_bench_avx_filter rust:raphael_optim_memset2 rust:query-field-name-avoid-alloc rust:check_bug rust:missing_test rust:list_fields rust:block-cache-control rust:trinity--multilayer-sstable rust:tracing-tantivy2 rust:tracing-tantivy rust:index_writer_err rust:default_fast_field_tokenizer rust:fmassot/add-preserve-original-ascii-folding rust:numeric_with_str_col rust:straightforward-simplify rust:fmassot/fake-test-branch rust:fmassot/dynamic-tokenizer-poc-follow-up rust:fmassot/add-box-token-filter-and-refactor rust:dynamic-tokenizer-proof-of-concept rust:fmassot/add-box-tokenizer-and-token-filter rust:tokenizer-api-0.1.1 rust:addconversion rust:removed-extra-enum-alternative-for-datetime-precision rust:issue/1981-reproduce-bm25-bug rust:tokenizer_docs rust:merge-proptests rust:columnar-todo rust:quickwit-0.5 rust:remove-byteorder rust:remove_dyn rust:pr/alexcole/1855-inject-bm25-statistics rust:evance-expose-build-query-from-user-input-ast rust:missing-specialized-method-arcdyncolumn rust:fast-u64-range-query rust:0.19.2 rust:columnar-cli2 rust:trinity--pub-term-as-slice rust:typed-column3 rust:columnar-merge3 rust:columnar-merge-exploring-fn rust:use_columnar rust:typed-column2 rust:term_agg_bucket_limit rust:range rust:typed-column rust:columnar-main rust:forced-types rust:u128-columnar rust:use_stats rust:truncation_comment rust:0.19.1 rust:trinity/yoke-documents rust:column-handle rust:columnar-cli rust:columnar rust:revert-1711-sparse_dense_index rust:commit-changes rust:sparse_dense_index_headroom rust:optional_column rust:no-column-for-multivalued rust:fmassot--bench-hdfs-with-array rust:bugfix-position-broken rust:float rust:simplify rust:debug_time rust:sparse_codecs rust:fix_estimate rust:column-reader rust:column-reader-b rust:columnreader-simple rust:col-trait-refact rust:ip_fastfield rust:column-trait-2 rust:refact-dyn-column rust:column-trait rust:refact-codec-trait rust:pr/PSeitz/1485-1 rust:fastfieldcodec rust:termmap_per_field rust:fastfield-codecs-tests rust:rayon-indexing-writers rust:issue/1251 rust:index-bench rust:fix_open_bytes_index rust:warming rust:revert-1222-issue/1195 rust:add-random-bench-for-fast-field rust:wasm-friendly-exploratory rust:revert-1159-patch-1 rust:debug-position-panic-0.15.3 rust:fix-issue-1111 rust:remove_rand rust:unused-deps rust:hfb/phrase_match_slop rust:0.15.3 rust:expose-min-max-on-multi-fast-field-reader rust:revert-1094-expose-min-max-on-multi-fast-field-reader rust:hotfix-1088 rust:owned-bytes-instead-of-rawdoc rust:rihardsk-date-ranges rust:issue/997 rust:0.13.3 rust:fail-fast-store-checkpoint rust:debugging-store rust:issue/reproduce-897 rust:issue/969-reproduce rust:troublescooter-static rust:intermediate-mergeable-troublescooter rust:barrotsteindev-filter-collector-tpredicatevalue rust:issue/938b rust:issue/938 rust:barrotsteindev-filter-collector rust:issue/922 rust:issue/896 rust:quickfix-explain rust:slog rust:limit-random-seeks rust:0.13.1 rust:issue/866b rust:bugfix-unittest-macos rust:githubactions rust:fieldnorm_readers rust:blockwand rust:nodeffeatfails rust:removedaliveiterator rust:robyoung-introduce-offset-to-top-docs rust:specialization-of-foreach-for-union-scorer rust:elshize-bmw rust:cutt rust:nrt rust:storewriter-out rust:segment_writer_in_ram2 rust:polling rust:audunhalland-query-boost rust:poll-meta rust:segment_writer_in_ram rust:bundle rust:petr-tik-n662_footer_is_incompatible_impl rust:race-condition-in-tests rust:hotfix-0.10.3-issue681 rust:remove-tru rust:kkoziara-pre-tokenized-text rust:issue/681 rust:issue/680 rust:refactoring/field rust:updating/uuid rust:fix-bench rust:hotfix-656 rust:readd-macos-ci rust:incremental-search rust:crate-division rust:streamer-with-state rust:criterion rust:python-binding-changes rust:bump-version rust:gh-pages rust:issue/554 rust:perf/experimental-union-for_each rust:issue/526b rust:softcommits rust:0.9.1-hotfix rust:revert-521-fix-non-english-stemmers rust:issue/500-hotfix rust:hotfix/0.8.2 rust:issue/483 rust:bug/merge-deted rust:issue/407 rust:issue/457 rust:segment_fruits rust:doc rust:dds/lenient rust:issue/webasm rust:issue/396 rust:broken_collector_with_result rust:dss/automaton-weight-suggestion rust:wasm rust:common-crawl rust:tantivy-imhotep
rust:0.25.0 rust:0.22.1 rust:0.24.2 rust:0.24.1 rust:tantivy-query-grammar-v0.24.0 rust:tantivy-columnar-v0.5.0 rust:tantivy-bitpacker-v0.8.0 rust:ownedbytes-v0.9.0 rust:tantivy-stacker-v0.5.0 rust:tantivy-sstable-v0.5.0 rust:tantivy-common-v0.9.0 rust:tantivy-tokenizer-api-v0.5.0 rust:0.24 rust:qw-airmail-20250224-hotfix-merge-panic rust:qw-airmail-20250219-hotfix-merge-panic rust:qw-airmail-202406 rust:qw-airmail-20240611 rust:qw-airmail-20240606 rust:quickwit-rev rust:0.22.0 rust:tantivy-stacker-v0.3.0 rust:ownedbytes-v0.7.0 rust:tantivy-tokenizer-api-v0.3.0 rust:tantivy-columnar-v0.3.0 rust:tantivy-common-v0.7.0 rust:tantivy-query-grammar-v0.22.0 rust:tantivy-sstable-v0.3.0 rust:tantivy-bitpacker-v0.6.0 rust:0.21.1 rust:0.21 rust:0.20.2 rust:0.20.1 rust:0.20 rust:quickwit-0.5-rev rust:0.19.2 rust:0.19.1 rust:0.19 rust:0.18.1 rust:0.18 rust:0.17 rust:0.16.1 rust:0.15.3 rust:0.15.2 rust:0.15.1 rust:0.15 rust:0.14 rust:0.13.3 rust:0.13.2 rust:0.13.1 rust:0.13 rust:0.12 rust:0.11.3 rust:0.11.1 rust:0.11 rust:0.10.3 rust:0.1 rust:0.10.2 rust:0.10.1 rust:0.10.0 rust:0.9.1 rust:0.9 rust:0.8.2 rust:0.8.2b rust:0.8.1 rust:0.8.0 rust:0.7.2 rust:0.7.1 rust:0.7.0 rust:0.6.1 rust:0.6.0 rust:0.5.2 rust:0.5.1 rust:0.5.0 rust:0.4.3 rust:0.4.2 rust:0.4.0 rust:0.3.1 rust:0.3.0 rust:0.2.0
..
compare: rust:columnar-merge3
Branches Tags
rust:stuhood.upstream-erased-sort-computer rust:main rust:trinity.pointard/ff-query rust:bucket_id_agg rust:paradedb/fix-agg-validation rust:flatheadmill-geo rust:paradedb-paradedb/fix-overflow-issue rust:low_card_optimization rust:paul.masurel/clippy rust:fix_size_hint rust:qw-airmail-20250916 rust:unit-test-aggregation-sum-other rust:clippy-and-cleanups rust:trinity.pointard/opti-sstable-sorted-ords-to-term rust:release_0.24 rust:dependabot/cargo/rand-0.9.1 rust:dependabot/cargo/lru-0.14.0 rust:dependabot/cargo/fs4-0.13.1 rust:tagged-user-input-ast rust:1686a/parse-agg-res rust:dependabot/cargo/rand_distr-0.5.1 rust:issue/2411-adding-panic-handler-to-rayon-merge-thread-pool rust:dependabot/cargo/nom-8 rust:upgrade_deps rust:test_parser rust:dependabot/github_actions/codecov/codecov-action-5 rust:binggan-0.12.0 rust:agg_format rust:path_collector rust:test_order_bug rust:test_columnar_multi rust:columnar_optionalmask_in_multivalues rust:prefix-phrase-query-optim rust:tantivy-with-oneshot rust:update_example rust:store-reader-enumerate rust:document-deserialize-seed rust:check_doc_mem rust:experimental-do-not-merge rust:expdonotmerge rust:cherry-pick-vec-instead-of-btreemap rust:validate_length rust:raphael_bench_avx_filter rust:raphael_optim_memset2 rust:query-field-name-avoid-alloc rust:check_bug rust:missing_test rust:list_fields rust:block-cache-control rust:trinity--multilayer-sstable rust:tracing-tantivy2 rust:tracing-tantivy rust:index_writer_err rust:default_fast_field_tokenizer rust:fmassot/add-preserve-original-ascii-folding rust:numeric_with_str_col rust:straightforward-simplify rust:fmassot/fake-test-branch rust:fmassot/dynamic-tokenizer-poc-follow-up rust:fmassot/add-box-token-filter-and-refactor rust:dynamic-tokenizer-proof-of-concept rust:fmassot/add-box-tokenizer-and-token-filter rust:tokenizer-api-0.1.1 rust:addconversion rust:removed-extra-enum-alternative-for-datetime-precision rust:issue/1981-reproduce-bm25-bug rust:tokenizer_docs rust:merge-proptests rust:columnar-todo rust:quickwit-0.5 rust:remove-byteorder rust:remove_dyn rust:pr/alexcole/1855-inject-bm25-statistics rust:evance-expose-build-query-from-user-input-ast rust:missing-specialized-method-arcdyncolumn rust:fast-u64-range-query rust:0.19.2 rust:columnar-cli2 rust:trinity--pub-term-as-slice rust:typed-column3 rust:columnar-merge3 rust:columnar-merge-exploring-fn rust:use_columnar rust:typed-column2 rust:term_agg_bucket_limit rust:range rust:typed-column rust:columnar-main rust:forced-types rust:u128-columnar rust:use_stats rust:truncation_comment rust:0.19.1 rust:trinity/yoke-documents rust:column-handle rust:columnar-cli rust:columnar rust:revert-1711-sparse_dense_index rust:commit-changes rust:sparse_dense_index_headroom rust:optional_column rust:no-column-for-multivalued rust:fmassot--bench-hdfs-with-array rust:bugfix-position-broken rust:float rust:simplify rust:debug_time rust:sparse_codecs rust:fix_estimate rust:column-reader rust:column-reader-b rust:columnreader-simple rust:col-trait-refact rust:ip_fastfield rust:column-trait-2 rust:refact-dyn-column rust:column-trait rust:refact-codec-trait rust:pr/PSeitz/1485-1 rust:fastfieldcodec rust:termmap_per_field rust:fastfield-codecs-tests rust:rayon-indexing-writers rust:issue/1251 rust:index-bench rust:fix_open_bytes_index rust:warming rust:revert-1222-issue/1195 rust:add-random-bench-for-fast-field rust:wasm-friendly-exploratory rust:revert-1159-patch-1 rust:debug-position-panic-0.15.3 rust:fix-issue-1111 rust:remove_rand rust:unused-deps rust:hfb/phrase_match_slop rust:0.15.3 rust:expose-min-max-on-multi-fast-field-reader rust:revert-1094-expose-min-max-on-multi-fast-field-reader rust:hotfix-1088 rust:owned-bytes-instead-of-rawdoc rust:rihardsk-date-ranges rust:issue/997 rust:0.13.3 rust:fail-fast-store-checkpoint rust:debugging-store rust:issue/reproduce-897 rust:issue/969-reproduce rust:troublescooter-static rust:intermediate-mergeable-troublescooter rust:barrotsteindev-filter-collector-tpredicatevalue rust:issue/938b rust:issue/938 rust:barrotsteindev-filter-collector rust:issue/922 rust:issue/896 rust:quickfix-explain rust:slog rust:limit-random-seeks rust:0.13.1 rust:issue/866b rust:bugfix-unittest-macos rust:githubactions rust:fieldnorm_readers rust:blockwand rust:nodeffeatfails rust:removedaliveiterator rust:robyoung-introduce-offset-to-top-docs rust:specialization-of-foreach-for-union-scorer rust:elshize-bmw rust:cutt rust:nrt rust:storewriter-out rust:segment_writer_in_ram2 rust:polling rust:audunhalland-query-boost rust:poll-meta rust:segment_writer_in_ram rust:bundle rust:petr-tik-n662_footer_is_incompatible_impl rust:race-condition-in-tests rust:hotfix-0.10.3-issue681 rust:remove-tru rust:kkoziara-pre-tokenized-text rust:issue/681 rust:issue/680 rust:refactoring/field rust:updating/uuid rust:fix-bench rust:hotfix-656 rust:readd-macos-ci rust:incremental-search rust:crate-division rust:streamer-with-state rust:criterion rust:python-binding-changes rust:bump-version rust:gh-pages rust:issue/554 rust:perf/experimental-union-for_each rust:issue/526b rust:softcommits rust:0.9.1-hotfix rust:revert-521-fix-non-english-stemmers rust:issue/500-hotfix rust:hotfix/0.8.2 rust:issue/483 rust:bug/merge-deted rust:issue/407 rust:issue/457 rust:segment_fruits rust:doc rust:dds/lenient rust:issue/webasm rust:issue/396 rust:broken_collector_with_result rust:dss/automaton-weight-suggestion rust:wasm rust:common-crawl rust:tantivy-imhotep
rust:0.25.0 rust:0.22.1 rust:0.24.2 rust:0.24.1 rust:tantivy-query-grammar-v0.24.0 rust:tantivy-columnar-v0.5.0 rust:tantivy-bitpacker-v0.8.0 rust:ownedbytes-v0.9.0 rust:tantivy-stacker-v0.5.0 rust:tantivy-sstable-v0.5.0 rust:tantivy-common-v0.9.0 rust:tantivy-tokenizer-api-v0.5.0 rust:0.24 rust:qw-airmail-20250224-hotfix-merge-panic rust:qw-airmail-20250219-hotfix-merge-panic rust:qw-airmail-202406 rust:qw-airmail-20240611 rust:qw-airmail-20240606 rust:quickwit-rev rust:0.22.0 rust:tantivy-stacker-v0.3.0 rust:ownedbytes-v0.7.0 rust:tantivy-tokenizer-api-v0.3.0 rust:tantivy-columnar-v0.3.0 rust:tantivy-common-v0.7.0 rust:tantivy-query-grammar-v0.22.0 rust:tantivy-sstable-v0.3.0 rust:tantivy-bitpacker-v0.6.0 rust:0.21.1 rust:0.21 rust:0.20.2 rust:0.20.1 rust:0.20 rust:quickwit-0.5-rev rust:0.19.2 rust:0.19.1 rust:0.19 rust:0.18.1 rust:0.18 rust:0.17 rust:0.16.1 rust:0.15.3 rust:0.15.2 rust:0.15.1 rust:0.15 rust:0.14 rust:0.13.3 rust:0.13.2 rust:0.13.1 rust:0.13 rust:0.12 rust:0.11.3 rust:0.11.1 rust:0.11 rust:0.10.3 rust:0.1 rust:0.10.2 rust:0.10.1 rust:0.10.0 rust:0.9.1 rust:0.9 rust:0.8.2 rust:0.8.2b rust:0.8.1 rust:0.8.0 rust:0.7.2 rust:0.7.1 rust:0.7.0 rust:0.6.1 rust:0.6.0 rust:0.5.2 rust:0.5.1 rust:0.5.0 rust:0.4.3 rust:0.4.2 rust:0.4.0 rust:0.3.1 rust:0.3.0 rust:0.2.0

10 Commits
remove-byt ... columnar-m

Author SHA1 Message Date
Paul Masurel
e9af721e60 Fixing compile 2023-02-05 18:05:29 +01:00
Paul Masurel
88ed3d8b48 Switching back to iterable. 2023-02-02 14:02:10 +01:00
Paul Masurel
aa8408a979 Updated TODO 2023-02-02 08:30:14 +01:00
Paul Masurel
4319d8c1bd Reenabling bench 2023-02-02 13:09:19 +09:00
Paul Masurel
33d18d0424 Plugged fastfield merge 
Fixing unit tests.
Fixing gcd
stats isolation
 2023-02-02 12:07:56 +09:00
Pascal Seitz
3de018c49f add merge for bytes/str column 2023-02-01 12:13:25 +08:00
Paul Masurel
96485f21d6 Added merge code for trivial mapping u64 & u128 
Added rank
 2023-01-30 10:05:40 +09:00
Pascal Seitz
1330e6f10d prepare for merge 2023-01-25 11:32:08 +09:00
Paul Masurel
5086914304 Integration of columnar 2023-01-24 18:18:05 +09:00
Paul Masurel
d7a8053cc2 Introduced a select cursor. 2023-01-20 23:27:39 +09:00
185 changed files with 7998 additions and 11533 deletions
Expand all files Collapse all files

6
.github/workflows/coverage.yml vendored
View File

@@ -2,9 +2,9 @@ name: Coverage
on:
push:
branches: [main]
branches: [ main ]
pull_request:
branches: [main]
branches: [ main ]
jobs:
coverage:
@@ -16,7 +16,7 @@ jobs:
- uses: Swatinem/rust-cache@v2
- uses: taiki-e/install-action@cargo-llvm-cov
- name: Generate code coverage
run: cargo +nightly llvm-cov --all-features --workspace --doctests --lcov --output-path lcov.info
run: cargo +nightly llvm-cov --all-features --workspace --lcov --output-path lcov.info
- name: Upload coverage to Codecov
uses: codecov/codecov-action@v3
continue-on-error: true

14
Cargo.toml
View File

@@ -16,13 +16,14 @@ rust-version = "1.62"
[dependencies]
oneshot = "0.1.5"
base64 = "0.21.0"
byteorder = "1.4.3"
crc32fast = "1.3.2"
once_cell = "1.10.0"
regex = { version = "1.5.5", default-features = false, features = ["std", "unicode"] }
aho-corasick = "0.7"
tantivy-fst = "0.4.0"
memmap2 = { version = "0.5.3", optional = true }
lz4_flex = { version = "0.10", default-features = false, features = ["checked-decode"], optional = true }
lz4_flex = { version = "0.9.2", default-features = false, features = ["checked-decode"], optional = true }
brotli = { version = "3.3.4", optional = true }
zstd = { version = "0.12", optional = true, default-features = false }
snap = { version = "1.0.5", optional = true }
@@ -43,7 +44,7 @@ rustc-hash = "1.1.0"
thiserror = "1.0.30"
htmlescape = "0.3.1"
fail = "0.5.0"
murmurhash32 = "0.3.0"
murmurhash32 = "0.2.0"
time = { version = "0.3.10", features = ["serde-well-known"] }
smallvec = "1.8.0"
rayon = "1.5.2"
@@ -54,12 +55,12 @@ measure_time = "0.8.2"
async-trait = "0.1.53"
arc-swap = "1.5.0"
columnar = { version="0.1", path="./columnar", package ="tantivy-columnar" }
sstable = { version="0.1", path="./sstable", package ="tantivy-sstable", optional = true }
stacker = { version="0.1", path="./stacker", package ="tantivy-stacker" }
query-grammar = { version= "0.19.0", path="./query-grammar", package = "tantivy-query-grammar" }
tantivy-bitpacker = { version= "0.3", path="./bitpacker" }
common = { version= "0.5", path = "./common/", package = "tantivy-common" }
tantivy-query-grammar = { version= "0.19.0", path="./query-grammar" }
tantivy-bitpacker = { version= "0.3", path="./bitpacker" }
columnar = { version= "0.1", path="./columnar", package="tantivy-columnar" }
common = { version= "0.5", path = "./common/", package = "tantivy-common" }
tokenizer-api = { version="0.1", path="./tokenizer-api", package="tantivy-tokenizer-api" }
[target.'cfg(windows)'.dependencies]
@@ -76,7 +77,6 @@ test-log = "0.2.10"
env_logger = "0.10.0"
pprof = { version = "0.11.0", features = ["flamegraph", "criterion"] }
futures = "0.3.21"
paste = "1.0.11"
[dev-dependencies.fail]
version = "0.5.0"

23
ci/before_deploy.ps1 Normal file
View File

@@ -0,0 +1,23 @@
# This script takes care of packaging the build artifacts that will go in the
# release zipfile
$SRC_DIR = $PWD.Path
$STAGE = [System.Guid]::NewGuid().ToString()
Set-Location $ENV:Temp
New-Item -Type Directory -Name $STAGE
Set-Location $STAGE
$ZIP = "$SRC_DIR\$($Env:CRATE_NAME)-$($Env:APPVEYOR_REPO_TAG_NAME)-$($Env:TARGET).zip"
# TODO Update this to package the right artifacts
Copy-Item "$SRC_DIR\target\$($Env:TARGET)\release\hello.exe" '.\'
7z a "$ZIP" *
Push-AppveyorArtifact "$ZIP"
Remove-Item *.* -Force
Set-Location ..
Remove-Item $STAGE
Set-Location $SRC_DIR

33
ci/before_deploy.sh Normal file
View File

@@ -0,0 +1,33 @@
# This script takes care of building your crate and packaging it for release
set -ex
main() {
local src=$(pwd) \
stage=
case $TRAVIS_OS_NAME in
linux)
stage=$(mktemp -d)
;;
osx)
stage=$(mktemp -d -t tmp)
;;
esac
test -f Cargo.lock || cargo generate-lockfile
# TODO Update this to build the artifacts that matter to you
cross rustc --bin hello --target $TARGET --release -- -C lto
# TODO Update this to package the right artifacts
cp target/$TARGET/release/hello $stage/
cd $stage
tar czf $src/$CRATE_NAME-$TRAVIS_TAG-$TARGET.tar.gz *
cd $src
rm -rf $stage
}
main

47
ci/install.sh Normal file
View File

@@ -0,0 +1,47 @@
set -ex
main() {
local target=
if [ $TRAVIS_OS_NAME = linux ]; then
target=x86_64-unknown-linux-musl
sort=sort
else
target=x86_64-apple-darwin
sort=gsort # for `sort --sort-version`, from brew's coreutils.
fi
# Builds for iOS are done on OSX, but require the specific target to be
# installed.
case $TARGET in
aarch64-apple-ios)
rustup target install aarch64-apple-ios
;;
armv7-apple-ios)
rustup target install armv7-apple-ios
;;
armv7s-apple-ios)
rustup target install armv7s-apple-ios
;;
i386-apple-ios)
rustup target install i386-apple-ios
;;
x86_64-apple-ios)
rustup target install x86_64-apple-ios
;;
esac
# This fetches latest stable release
local tag=$(git ls-remote --tags --refs --exit-code https://github.com/japaric/cross \
| cut -d/ -f3 \
| grep -E '^v[0.1.0-9.]+$' \
| $sort --version-sort \
| tail -n1)
curl -LSfs https://japaric.github.io/trust/install.sh | \
sh -s -- \
--force \
--git japaric/cross \
--tag $tag \
--target $target
}
main

30
ci/script.sh Normal file
View File

@@ -0,0 +1,30 @@
#!/usr/bin/env bash
# This script takes care of testing your crate
set -ex
main() {
if [ ! -z $CODECOV ]; then
echo "Codecov"
cargo build --verbose && cargo coverage --verbose --all && bash <(curl -s https://codecov.io/bash) -s target/kcov
else
echo "Build"
cross build --target $TARGET
if [ ! -z $DISABLE_TESTS ]; then
return
fi
echo "Test"
cross test --target $TARGET --no-default-features --features mmap
cross test --target $TARGET --no-default-features --features mmap query-grammar
fi
for example in $(ls examples/*.rs)
do
cargo run --example $(basename $example .rs)
done
}
# we don't run the "test phase" when doing deploys
if [ -z $TRAVIS_TAG ]; then
main
fi

22
columnar/Cargo.toml
View File

@@ -5,24 +5,24 @@ edition = "2021"
license = "MIT"
[dependencies]
itertools = "0.10.5"
log = "0.4.17"
fnv = "1.0.7"
fastdivide = "0.4.0"
rand = { version = "0.8.5", optional = true }
measure_time = { version = "0.8.2", optional = true }
prettytable-rs = { version = "0.10.0", optional = true }
stacker = { path = "../stacker", package="tantivy-stacker"}
serde_json = "1"
thiserror = "1"
fnv = "1"
sstable = { path = "../sstable", package = "tantivy-sstable" }
common = { path = "../common", package = "tantivy-common" }
itertools = "0.10"
log = "0.4"
tantivy-bitpacker = { version= "0.3", path = "../bitpacker/" }
serde = "1.0.152"
prettytable-rs = {version="0.10.0", optional= true}
rand = {version="0.8.3", optional= true}
fastdivide = "0.4"
measure_time = { version="0.8.2", optional=true}
[dev-dependencies]
proptest = "1"
more-asserts = "0.3.1"
rand = "0.8.5"
more-asserts = "0.3.0"
rand = "0.8.3"
[features]
unstable = []

6
columnar/Makefile Normal file
View File

@@ -0,0 +1,6 @@
test:
echo "Run test only... No examples."
cargo test --tests --lib
fmt:
cargo +nightly fmt --all

15
columnar/benches/bench_u128.rs
View File

@@ -28,7 +28,12 @@ fn get_u128_column_random() -> Arc<dyn ColumnValues<u128>> {
fn get_u128_column_from_data(data: &[u128]) -> Arc<dyn ColumnValues<u128>> {
let mut out = vec![];
tantivy_columnar::column_values::serialize_column_values_u128(&data, &mut out).unwrap();
tantivy_columnar::column_values::serialize_column_values_u128(
&(|| data.iter().copied()),
data.len() as u32,
&mut out,
)
.unwrap();
let out = OwnedBytes::new(out);
tantivy_columnar::column_values::open_u128_mapped::<u128>(out).unwrap()
}
@@ -36,7 +41,7 @@ fn get_u128_column_from_data(data: &[u128]) -> Arc<dyn ColumnValues<u128>> {
const FIFTY_PERCENT_RANGE: RangeInclusive<u64> = 1..=50;
const SINGLE_ITEM: u64 = 90;
const SINGLE_ITEM_RANGE: RangeInclusive<u64> = 90..=90;
const ONE_PERCENT_ITEM_RANGE: RangeInclusive<u64> = 49..=49;
fn get_data_50percent_item() -> Vec<u128> {
let mut rng = StdRng::from_seed([1u8; 32]);
@@ -58,7 +63,7 @@ fn bench_intfastfield_getrange_u128_50percent_hit(b: &mut Bencher) {
b.iter(|| {
let mut positions = Vec::new();
column.get_row_ids_for_value_range(
column.get_docids_for_value_range(
*FIFTY_PERCENT_RANGE.start() as u128..=*FIFTY_PERCENT_RANGE.end() as u128,
0..data.len() as u32,
&mut positions,
@@ -74,7 +79,7 @@ fn bench_intfastfield_getrange_u128_single_hit(b: &mut Bencher) {
b.iter(|| {
let mut positions = Vec::new();
column.get_row_ids_for_value_range(
column.get_docids_for_value_range(
*SINGLE_ITEM_RANGE.start() as u128..=*SINGLE_ITEM_RANGE.end() as u128,
0..data.len() as u32,
&mut positions,
@@ -90,7 +95,7 @@ fn bench_intfastfield_getrange_u128_hit_all(b: &mut Bencher) {
b.iter(|| {
let mut positions = Vec::new();
column.get_row_ids_for_value_range(0..=u128::MAX, 0..data.len() as u32, &mut positions);
column.get_docids_for_value_range(0..=u128::MAX, 0..data.len() as u32, &mut positions);
positions
});
}

14
columnar/benches/bench_u64.rs
View File

@@ -5,7 +5,9 @@ use std::ops::RangeInclusive;
use std::sync::Arc;
use rand::prelude::*;
use tantivy_columnar::column_values::{serialize_and_load_u64_based_column_values, CodecType};
use tantivy_columnar::column_values::{
serialize_and_load_u64_based_column_values, CodecType, ALL_U64_CODEC_TYPES,
};
use tantivy_columnar::*;
use test::Bencher;
@@ -89,7 +91,7 @@ fn bench_intfastfield_getrange_u64_50percent_hit(b: &mut Bencher) {
let column: Arc<dyn ColumnValues<u64>> = serialize_and_load(&data, CodecType::Bitpacked);
b.iter(|| {
let mut positions = Vec::new();
column.get_row_ids_for_value_range(
column.get_docids_for_value_range(
FIFTY_PERCENT_RANGE,
0..data.len() as u32,
&mut positions,
@@ -106,7 +108,7 @@ fn bench_intfastfield_getrange_u64_1percent_hit(b: &mut Bencher) {
b.iter(|| {
let mut positions = Vec::new();
column.get_row_ids_for_value_range(
column.get_docids_for_value_range(
ONE_PERCENT_ITEM_RANGE,
0..data.len() as u32,
&mut positions,
@@ -123,7 +125,7 @@ fn bench_intfastfield_getrange_u64_single_hit(b: &mut Bencher) {
b.iter(|| {
let mut positions = Vec::new();
column.get_row_ids_for_value_range(SINGLE_ITEM_RANGE, 0..data.len() as u32, &mut positions);
column.get_docids_for_value_range(SINGLE_ITEM_RANGE, 0..data.len() as u32, &mut positions);
positions
});
}
@@ -136,7 +138,7 @@ fn bench_intfastfield_getrange_u64_hit_all(b: &mut Bencher) {
b.iter(|| {
let mut positions = Vec::new();
column.get_row_ids_for_value_range(0..=u64::MAX, 0..data.len() as u32, &mut positions);
column.get_docids_for_value_range(0..=u64::MAX, 0..data.len() as u32, &mut positions);
positions
});
}
@@ -178,7 +180,7 @@ fn bench_intfastfield_scan_all_fflookup(b: &mut Bencher) {
b.iter(|| {
let mut a = 0u64;
for i in 0u32..n as u32 {
a += column_ref.get_val(i);
a += column.get_val(i);
}
a
});

17
columnar/columnar-cli/Cargo.toml
View File

@@ -1,17 +0,0 @@
[package]
name = "tantivy-columnar-cli"
version = "0.1.0"
edition = "2021"
license = "MIT"
[dependencies]
columnar = {path="../", package="tantivy-columnar"}
serde_json = "1"
serde_json_borrow = {git="https://github.com/PSeitz/serde_json_borrow/"}
serde = "1"
[workspace]
members = []
[profile.release]
debug = true

134
columnar/columnar-cli/src/main.rs
View File

@@ -1,134 +0,0 @@
use columnar::ColumnarWriter;
use columnar::NumericalValue;
use serde_json_borrow;
use std::fs::File;
use std::io;
use std::io::BufRead;
use std::io::BufReader;
use std::time::Instant;
#[derive(Default)]
struct JsonStack {
path: String,
stack: Vec<usize>,
}
impl JsonStack {
fn push(&mut self, seg: &str) {
let len = self.path.len();
self.stack.push(len);
self.path.push('.');
self.path.push_str(seg);
}
fn pop(&mut self) {
if let Some(len) = self.stack.pop() {
self.path.truncate(len);
}
}
fn path(&self) -> &str {
&self.path[1..]
}
}
fn append_json_to_columnar(
doc: u32,
json_value: &serde_json_borrow::Value,
columnar: &mut ColumnarWriter,
stack: &mut JsonStack,
) -> usize {
let mut count = 0;
match json_value {
serde_json_borrow::Value::Null => {}
serde_json_borrow::Value::Bool(val) => {
columnar.record_numerical(
doc,
stack.path(),
NumericalValue::from(if *val { 1u64 } else { 0u64 }),
);
count += 1;
}
serde_json_borrow::Value::Number(num) => {
let numerical_value: NumericalValue = if let Some(num_i64) = num.as_i64() {
num_i64.into()
} else if let Some(num_u64) = num.as_u64() {
num_u64.into()
} else if let Some(num_f64) = num.as_f64() {
num_f64.into()
} else {
panic!();
};
count += 1;
columnar.record_numerical(
doc,
stack.path(),
numerical_value,
);
}
serde_json_borrow::Value::Str(msg) => {
columnar.record_str(
doc,
stack.path(),
msg,
);
count += 1;
},
serde_json_borrow::Value::Array(vals) => {
for val in vals {
count += append_json_to_columnar(doc, val, columnar, stack);
}
},
serde_json_borrow::Value::Object(json_map) => {
for (child_key, child_val) in json_map {
stack.push(child_key);
count += append_json_to_columnar(doc, child_val, columnar, stack);
stack.pop();
}
},
}
count
}
fn main() -> io::Result<()> {
let file = File::open("gh_small.json")?;
let mut reader = BufReader::new(file);
let mut line = String::with_capacity(100);
let mut columnar = columnar::ColumnarWriter::default();
let mut doc = 0;
let start = Instant::now();
let mut stack = JsonStack::default();
let mut total_count = 0;
let start_build = Instant::now();
loop {
line.clear();
let len = reader.read_line(&mut line)?;
if len == 0 {
break;
}
let Ok(json_value) = serde_json::from_str::<serde_json_borrow::Value>(&line) else { continue; };
total_count += append_json_to_columnar(doc, &json_value, &mut columnar, &mut stack);
doc += 1;
}
println!("Build in {:?}", start_build.elapsed());
println!("value count {total_count}");
let mut buffer = Vec::new();
let start_serialize = Instant::now();
columnar.serialize(doc, None, &mut buffer)?;
println!("Serialized in {:?}", start_serialize.elapsed());
println!("num docs: {doc}, {:?}", start.elapsed());
println!("buffer len {} MB", buffer.len() / 1_000_000);
let columnar = columnar::ColumnarReader::open(buffer)?;
for (column_name, dynamic_column) in columnar.list_columns()? {
let num_bytes = dynamic_column.num_bytes();
let typ = dynamic_column.column_type();
if num_bytes > 1_000_000 {
println!("{column_name} {typ:?} {} KB", num_bytes / 1_000);
}
}
println!("{} columns", columnar.num_columns());
Ok(())
}

14
columnar/src/TODO.md
View File

@@ -1,16 +1,14 @@
# zero to one
* merges with non trivial mapping (deletes / sort)
* emission of the sort mapping.
+ muttivaued range queries restrat frm the beginning all of the time.
* revisit line codec
* add columns from schema on merge
* removal of all rows of a column in the schema due to deletes
* Plugging JSON
* replug examples
* move datetime to quickwit common
* switch to nanos
* reintroduce the gcd map.
replug examples
# Perf and Size
* remove alloc in `ord_to_term`
+ multivaued range queries restrat frm the beginning all of the time.
* re-add ZSTD compression for dictionaries
no systematic monotonic mapping
consider removing multilinear

14
columnar/src/column/dictionary_encoded.rs
View File

@@ -32,11 +32,11 @@ impl BytesColumn {
/// Returns the number of rows in the column.
pub fn num_rows(&self) -> RowId {
self.term_ord_column.num_docs()
self.term_ord_column.num_rows()
}
pub fn term_ords(&self, row_id: RowId) -> impl Iterator<Item = u64> + '_ {
self.term_ord_column.values_for_doc(row_id)
self.term_ord_column.values(row_id)
}
/// Returns the column of ordinals
@@ -56,6 +56,12 @@ impl BytesColumn {
#[derive(Clone)]
pub struct StrColumn(BytesColumn);
impl From<BytesColumn> for StrColumn {
fn from(bytes_col: BytesColumn) -> Self {
StrColumn(bytes_col)
}
}
impl From<StrColumn> for BytesColumn {
fn from(str_column: StrColumn) -> BytesColumn {
str_column.0
@@ -63,10 +69,6 @@ impl From<StrColumn> for BytesColumn {
}
impl StrColumn {
pub(crate) fn wrap(bytes_column: BytesColumn) -> StrColumn {
StrColumn(bytes_column)
}
pub fn dictionary(&self) -> &Dictionary<VoidSSTable> {
self.0.dictionary.as_ref()
}

54
columnar/src/column/mod.rs
View File

@@ -3,14 +3,14 @@ mod serialize;
use std::fmt::Debug;
use std::io::Write;
use std::ops::{Deref, Range, RangeInclusive};
use std::ops::Deref;
use std::sync::Arc;
use common::BinarySerializable;
pub use dictionary_encoded::{BytesColumn, StrColumn};
pub use serialize::{
open_column_bytes, open_column_str, open_column_u128, open_column_u64,
serialize_column_mappable_to_u128, serialize_column_mappable_to_u64,
open_column_bytes, open_column_u128, open_column_u64, serialize_column_mappable_to_u128,
serialize_column_mappable_to_u64,
};
use crate::column_index::ColumnIndex;
@@ -38,20 +38,17 @@ impl<T: MonotonicallyMappableToU64> Column<T> {
}
impl<T: PartialOrd + Copy + Debug + Send + Sync + 'static> Column<T> {
#[inline]
pub fn get_cardinality(&self) -> Cardinality {
self.idx.get_cardinality()
}
pub fn num_docs(&self) -> RowId {
pub fn num_rows(&self) -> RowId {
match &self.idx {
ColumnIndex::Empty { num_docs } => *num_docs,
ColumnIndex::Full => self.values.num_vals(),
ColumnIndex::Optional(optional_index) => optional_index.num_docs(),
ColumnIndex::Full => self.values.num_vals() as u32,
ColumnIndex::Optional(optional_index) => optional_index.num_rows(),
ColumnIndex::Multivalued(col_index) => {
// The multivalued index contains all value start row_id,
// and one extra value at the end with the overall number of rows.
col_index.num_docs()
col_index.num_rows()
}
}
}
@@ -65,42 +62,14 @@ impl<T: PartialOrd + Copy + Debug + Send + Sync + 'static> Column<T> {
}
pub fn first(&self, row_id: RowId) -> Option<T> {
self.values_for_doc(row_id).next()
self.values(row_id).next()
}
pub fn values_for_doc(&self, row_id: RowId) -> impl Iterator<Item = T> + '_ {
pub fn values(&self, row_id: RowId) -> impl Iterator<Item = T> + '_ {
self.value_row_ids(row_id)
.map(|value_row_id: RowId| self.values.get_val(value_row_id))
}
/// Get the docids of values which are in the provided value range.
#[inline]
pub fn get_docids_for_value_range(
&self,
value_range: RangeInclusive<T>,
selected_docid_range: Range<u32>,
doc_ids: &mut Vec<u32>,
) {
// convert passed docid range to row id range
let rowid_range = self.idx.docid_range_to_rowids(selected_docid_range.clone());
// Load rows
self.values
.get_row_ids_for_value_range(value_range, rowid_range, doc_ids);
// Convert rows to docids
self.idx
.select_batch_in_place(selected_docid_range.start, doc_ids);
}
/// Fils the output vector with the (possibly multiple values that are associated_with
/// `row_id`.
///
/// This method clears the `output` vector.
pub fn fill_vals(&self, row_id: RowId, output: &mut Vec<T>) {
output.clear();
output.extend(self.values_for_doc(row_id));
}
pub fn first_or_default_col(self, default_value: T) -> Arc<dyn ColumnValues<T>> {
Arc::new(FirstValueWithDefault {
column: self,
@@ -152,10 +121,9 @@ impl<T: PartialOrd + Debug + Send + Sync + Copy + 'static> ColumnValues<T>
fn num_vals(&self) -> u32 {
match &self.column.idx {
ColumnIndex::Empty { .. } => 0u32,
ColumnIndex::Full => self.column.values.num_vals(),
ColumnIndex::Optional(optional_idx) => optional_idx.num_docs(),
ColumnIndex::Multivalued(multivalue_idx) => multivalue_idx.num_docs(),
ColumnIndex::Optional(optional_idx) => optional_idx.num_rows(),
ColumnIndex::Multivalued(_) => todo!(),
}
}
}

29
columnar/src/column/serialize.rs
View File

@@ -1,3 +1,4 @@
use std::fmt::Debug;
use std::io;
use std::io::Write;
use std::sync::Arc;
@@ -7,25 +8,24 @@ use sstable::Dictionary;
use crate::column::{BytesColumn, Column};
use crate::column_index::{serialize_column_index, SerializableColumnIndex};
use crate::column_values::{
load_u64_based_column_values, serialize_column_values_u128, serialize_u64_based_column_values,
CodecType, MonotonicallyMappableToU128, MonotonicallyMappableToU64,
};
use crate::column_values::serialize::serialize_column_values_u128;
use crate::column_values::u64_based::{serialize_u64_based_column_values, CodecType};
use crate::column_values::{MonotonicallyMappableToU128, MonotonicallyMappableToU64};
use crate::iterable::Iterable;
use crate::StrColumn;
pub fn serialize_column_mappable_to_u128<T: MonotonicallyMappableToU128>(
column_index: SerializableColumnIndex<'_>,
iterable: &dyn Iterable<T>,
num_vals: u32,
output: &mut impl Write,
) -> io::Result<()> {
let column_index_num_bytes = serialize_column_index(column_index, output)?;
serialize_column_values_u128(iterable, output)?;
serialize_column_values_u128(iterable, num_vals, output)?;
output.write_all(&column_index_num_bytes.to_le_bytes())?;
Ok(())
}
pub fn serialize_column_mappable_to_u64<T: MonotonicallyMappableToU64>(
pub fn serialize_column_mappable_to_u64<T: MonotonicallyMappableToU64 + Debug>(
column_index: SerializableColumnIndex<'_>,
column_values: &impl Iterable<T>,
output: &mut impl Write,
@@ -50,7 +50,8 @@ pub fn open_column_u64<T: MonotonicallyMappableToU64>(bytes: OwnedBytes) -> io::
);
let (column_index_data, column_values_data) = body.split(column_index_num_bytes as usize);
let column_index = crate::column_index::open_column_index(column_index_data)?;
let column_values = load_u64_based_column_values(column_values_data)?;
let column_values =
crate::column_values::u64_based::load_u64_based_column_values(column_values_data)?;
Ok(Column {
idx: column_index,
values: column_values,
@@ -76,19 +77,15 @@ pub fn open_column_u128<T: MonotonicallyMappableToU128>(
})
}
pub fn open_column_bytes(data: OwnedBytes) -> io::Result<BytesColumn> {
pub fn open_column_bytes<T: From<BytesColumn>>(data: OwnedBytes) -> io::Result<T> {
let (body, dictionary_len_bytes) = data.rsplit(4);
let dictionary_len = u32::from_le_bytes(dictionary_len_bytes.as_slice().try_into().unwrap());
let (dictionary_bytes, column_bytes) = body.split(dictionary_len as usize);
let dictionary = Arc::new(Dictionary::from_bytes(dictionary_bytes)?);
let term_ord_column = crate::column::open_column_u64::<u64>(column_bytes)?;
Ok(BytesColumn {
let bytes_column = BytesColumn {
dictionary,
term_ord_column,
})
}
pub fn open_column_str(data: OwnedBytes) -> io::Result<StrColumn> {
let bytes_column = open_column_bytes(data)?;
Ok(StrColumn::wrap(bytes_column))
};
Ok(bytes_column.into())
}

45
columnar/src/column_index/merge/stacked.rs → columnar/src/column_index/merge.rs
View File

@@ -1,19 +1,29 @@
use std::iter;
use crate::column_index::{SerializableColumnIndex, Set};
use crate::column_index::{
multivalued_index, serialize_column_index, SerializableColumnIndex, Set,
};
use crate::iterable::Iterable;
use crate::{Cardinality, ColumnIndex, RowId, StackMergeOrder};
use crate::{Cardinality, ColumnIndex, MergeRowOrder, RowId, StackMergeOrder};
/// Simple case:
/// The new mapping just consists in stacking the different column indexes.
///
/// There are no sort nor deletes involved.
pub fn merge_column_index_stacked<'a>(
fn detect_cardinality(columns: &[Option<ColumnIndex>]) -> Cardinality {
columns
.iter()
.flatten()
.map(ColumnIndex::get_cardinality)
.max()
.unwrap_or(Cardinality::Full)
}
pub fn stack_column_index<'a>(
columns: &'a [Option<ColumnIndex>],
cardinality_after_merge: Cardinality,
stack_merge_order: &'a StackMergeOrder,
merge_row_order: &'a MergeRowOrder,
) -> SerializableColumnIndex<'a> {
match cardinality_after_merge {
let MergeRowOrder::Stack(stack_merge_order) = merge_row_order else {
panic!("only supporting stacking at the moment.");
};
let cardinality = detect_cardinality(columns);
match cardinality {
Cardinality::Full => SerializableColumnIndex::Full,
Cardinality::Optional => SerializableColumnIndex::Optional {
non_null_row_ids: Box::new(StackedOptionalIndex {
@@ -50,12 +60,12 @@ impl<'a> Iterable<RowId> for StackedOptionalIndex<'a> {
Some(ColumnIndex::Optional(optional_index)) => Box::new(
optional_index
.iter_rows()
.map(move |row_id: RowId| columnar_row_range.start + row_id),
.map(move |row_id: RowId| row_id + columnar_row_range.start),
),
Some(ColumnIndex::Multivalued(_)) => {
panic!("No multivalued index is allowed when stacking column index");
}
None | Some(ColumnIndex::Empty { .. }) => Box::new(std::iter::empty()),
None => Box::new(std::iter::empty()),
};
rows_it
}),
@@ -74,9 +84,7 @@ fn convert_column_opt_to_multivalued_index<'a>(
num_rows: RowId,
) -> Box<dyn Iterator<Item = RowId> + 'a> {
match column_index_opt {
None | Some(ColumnIndex::Empty { .. }) => {
Box::new(iter::repeat(0u32).take(num_rows as usize + 1))
}
None => Box::new(iter::repeat(0u32).take(num_rows as usize + 1)),
Some(ColumnIndex::Full) => Box::new(0..num_rows + 1),
Some(ColumnIndex::Optional(optional_index)) => {
Box::new(
@@ -133,6 +141,13 @@ fn stack_multivalued_indexes<'a>(
}))
}
fn stack_multivalued_index<'a>(
columns: &'a [Option<ColumnIndex>],
stack_merge_order: &StackMergeOrder,
) -> Box<dyn Iterable<RowId> + 'a> {
todo!()
}
#[cfg(test)]
mod tests {
use crate::RowId;

136
columnar/src/column_index/merge/mod.rs
View File

@@ -1,136 +0,0 @@
mod shuffled;
mod stacked;
use shuffled::merge_column_index_shuffled;
use stacked::merge_column_index_stacked;
use crate::column_index::SerializableColumnIndex;
use crate::{Cardinality, ColumnIndex, MergeRowOrder};
// For simplification, we never have cardinality go down due to deletes.
fn detect_cardinality(columns: &[Option<ColumnIndex>]) -> Cardinality {
columns
.iter()
.flatten()
.map(ColumnIndex::get_cardinality)
.max()
.unwrap_or(Cardinality::Full)
}
pub fn merge_column_index<'a>(
columns: &'a [Option<ColumnIndex>],
merge_row_order: &'a MergeRowOrder,
) -> SerializableColumnIndex<'a> {
// For simplification, we do not try to detect whether the cardinality could be
// downgraded thanks to deletes.
let cardinality_after_merge = detect_cardinality(columns);
match merge_row_order {
MergeRowOrder::Stack(stack_merge_order) => {
merge_column_index_stacked(columns, cardinality_after_merge, stack_merge_order)
}
MergeRowOrder::Shuffled(complex_merge_order) => {
merge_column_index_shuffled(columns, cardinality_after_merge, complex_merge_order)
}
}
}
// TODO actually, the shuffled code path is a bit too general.
// In practise, we do not really shuffle everything.
// The merge order restricted to a specific column keeps the original row order.
//
// This may offer some optimization that we have not explored yet.
#[cfg(test)]
mod tests {
use crate::column_index::merge::detect_cardinality;
use crate::column_index::multivalued_index::MultiValueIndex;
use crate::column_index::{merge_column_index, OptionalIndex, SerializableColumnIndex};
use crate::{Cardinality, ColumnIndex, MergeRowOrder, RowAddr, RowId, ShuffleMergeOrder};
#[test]
fn test_detect_cardinality() {
assert_eq!(detect_cardinality(&[]), Cardinality::Full);
let optional_index: ColumnIndex = OptionalIndex::for_test(1, &[]).into();
let multivalued_index: ColumnIndex = MultiValueIndex::for_test(&[0, 1]).into();
assert_eq!(
detect_cardinality(&[Some(optional_index.clone()), None]),
Cardinality::Optional
);
assert_eq!(
detect_cardinality(&[Some(optional_index.clone()), Some(ColumnIndex::Full)]),
Cardinality::Optional
);
assert_eq!(
detect_cardinality(&[Some(multivalued_index.clone()), None]),
Cardinality::Multivalued
);
assert_eq!(
detect_cardinality(&[
Some(multivalued_index.clone()),
Some(optional_index.clone())
]),
Cardinality::Multivalued
);
assert_eq!(
detect_cardinality(&[Some(optional_index), Some(multivalued_index)]),
Cardinality::Multivalued
);
}
#[test]
fn test_merge_index_multivalued_sorted() {
let column_indexes: Vec<Option<ColumnIndex>> =
vec![Some(MultiValueIndex::for_test(&[0, 2, 5]).into())];
let merge_row_order: MergeRowOrder = ShuffleMergeOrder::for_test(
&[2],
vec![
RowAddr {
segment_ord: 0u32,
row_id: 1u32,
},
RowAddr {
segment_ord: 0u32,
row_id: 0u32,
},
],
)
.into();
let merged_column_index = merge_column_index(&column_indexes[..], &merge_row_order);
let SerializableColumnIndex::Multivalued(start_index_iterable) = merged_column_index
else { panic!("Excpected a multivalued index") };
let start_indexes: Vec<RowId> = start_index_iterable.boxed_iter().collect();
assert_eq!(&start_indexes, &[0, 3, 5]);
}
#[test]
fn test_merge_index_multivalued_sorted_several_segment() {
let column_indexes: Vec<Option<ColumnIndex>> = vec![
Some(MultiValueIndex::for_test(&[0, 2, 5]).into()),
None,
Some(MultiValueIndex::for_test(&[0, 1, 4]).into()),
];
let merge_row_order: MergeRowOrder = ShuffleMergeOrder::for_test(
&[2, 0, 2],
vec![
RowAddr {
segment_ord: 2u32,
row_id: 1u32,
},
RowAddr {
segment_ord: 0u32,
row_id: 0u32,
},
RowAddr {
segment_ord: 2u32,
row_id: 0u32,
},
],
)
.into();
let merged_column_index = merge_column_index(&column_indexes[..], &merge_row_order);
let SerializableColumnIndex::Multivalued(start_index_iterable) = merged_column_index
else { panic!("Excpected a multivalued index") };
let start_indexes: Vec<RowId> = start_index_iterable.boxed_iter().collect();
assert_eq!(&start_indexes, &[0, 3, 5, 6]);
}
}

168
columnar/src/column_index/merge/shuffled.rs
View File

@@ -1,168 +0,0 @@
use std::iter;
use crate::column_index::{SerializableColumnIndex, Set};
use crate::iterable::Iterable;
use crate::{Cardinality, ColumnIndex, RowId, ShuffleMergeOrder};
pub fn merge_column_index_shuffled<'a>(
column_indexes: &'a [Option<ColumnIndex>],
cardinality_after_merge: Cardinality,
shuffle_merge_order: &'a ShuffleMergeOrder,
) -> SerializableColumnIndex<'a> {
match cardinality_after_merge {
Cardinality::Full => SerializableColumnIndex::Full,
Cardinality::Optional => {
let non_null_row_ids =
merge_column_index_shuffled_optional(column_indexes, shuffle_merge_order);
SerializableColumnIndex::Optional {
non_null_row_ids,
num_rows: shuffle_merge_order.num_rows(),
}
}
Cardinality::Multivalued => {
let multivalue_start_index =
merge_column_index_shuffled_multivalued(column_indexes, shuffle_merge_order);
SerializableColumnIndex::Multivalued(multivalue_start_index)
}
}
}
/// Merge several column indexes into one, ordering rows according to the merge_order passed as
/// argument. While it is true that the `merge_order` may imply deletes and hence could in theory a
/// multivalued index into an optional one, this is not supported today for simplification.
///
/// In other words the column_indexes passed as argument may NOT be multivalued.
fn merge_column_index_shuffled_optional<'a>(
column_indexes: &'a [Option<ColumnIndex>],
merge_order: &'a ShuffleMergeOrder,
) -> Box<dyn Iterable<RowId> + 'a> {
Box::new(ShuffledOptionalIndex {
column_indexes,
merge_order,
})
}
struct ShuffledOptionalIndex<'a> {
column_indexes: &'a [Option<ColumnIndex>],
merge_order: &'a ShuffleMergeOrder,
}
impl<'a> Iterable<u32> for ShuffledOptionalIndex<'a> {
fn boxed_iter(&self) -> Box<dyn Iterator<Item = u32> + '_> {
Box::new(self.merge_order
.iter_new_to_old_row_addrs()
.enumerate()
.filter_map(|(new_row_id, old_row_addr)| {
let Some(column_index) = &self.column_indexes[old_row_addr.segment_ord as usize] else {
return None;
};
let row_id = new_row_id as u32;
if column_index.has_value(old_row_addr.row_id) {
Some(row_id)
} else {
None
}
}))
}
}
fn merge_column_index_shuffled_multivalued<'a>(
column_indexes: &'a [Option<ColumnIndex>],
merge_order: &'a ShuffleMergeOrder,
) -> Box<dyn Iterable<RowId> + 'a> {
Box::new(ShuffledMultivaluedIndex {
column_indexes,
merge_order,
})
}
struct ShuffledMultivaluedIndex<'a> {
column_indexes: &'a [Option<ColumnIndex>],
merge_order: &'a ShuffleMergeOrder,
}
fn iter_num_values<'a>(
column_indexes: &'a [Option<ColumnIndex>],
merge_order: &'a ShuffleMergeOrder,
) -> impl Iterator<Item = u32> + 'a {
merge_order.iter_new_to_old_row_addrs().map(|row_addr| {
let Some(column_index) = &column_indexes[row_addr.segment_ord as usize] else {
// No values in the entire column. It surely means there are 0 values associated to this row.
return 0u32;
};
match column_index {
ColumnIndex::Empty { .. } => 0u32,
ColumnIndex::Full => 1,
ColumnIndex::Optional(optional_index) => {
u32::from(optional_index.contains(row_addr.row_id))
}
ColumnIndex::Multivalued(multivalued_index) => {
multivalued_index.range(row_addr.row_id).len() as u32
}
}
})
}
/// Transforms an iterator containing the number of vals per row (with `num_rows` elements)
/// into a `start_offset` iterator starting at 0 and (with `num_rows + 1` element)
fn integrate_num_vals(num_vals: impl Iterator<Item = u32>) -> impl Iterator<Item = RowId> {
iter::once(0u32).chain(num_vals.scan(0, |state, num_vals| {
*state += num_vals;
Some(*state)
}))
}
impl<'a> Iterable<u32> for ShuffledMultivaluedIndex<'a> {
fn boxed_iter(&self) -> Box<dyn Iterator<Item = u32> + '_> {
let num_vals_per_row = iter_num_values(self.column_indexes, self.merge_order);
Box::new(integrate_num_vals(num_vals_per_row))
}
}
#[cfg(test)]
mod tests {
use super::*;
use crate::column_index::OptionalIndex;
use crate::RowAddr;
#[test]
fn test_integrate_num_vals_empty() {
assert!(integrate_num_vals(iter::empty()).eq(iter::once(0)));
}
#[test]
fn test_integrate_num_vals_one_el() {
assert!(integrate_num_vals(iter::once(10)).eq([0, 10].into_iter()));
}
#[test]
fn test_integrate_num_vals_several() {
assert!(integrate_num_vals([3, 0, 10, 20].into_iter()).eq([0, 3, 3, 13, 33].into_iter()));
}
#[test]
fn test_merge_column_index_optional_shuffle() {
let optional_index: ColumnIndex = OptionalIndex::for_test(2, &[0]).into();
let column_indexes = vec![Some(optional_index), Some(ColumnIndex::Full)];
let row_addrs = vec![
RowAddr {
segment_ord: 0u32,
row_id: 1u32,
},
RowAddr {
segment_ord: 1u32,
row_id: 0u32,
},
];
let shuffle_merge_order = ShuffleMergeOrder::for_test(&[2, 1], row_addrs);
let serializable_index = merge_column_index_shuffled(
&column_indexes[..],
Cardinality::Optional,
&shuffle_merge_order,
);
let SerializableColumnIndex::Optional { non_null_row_ids, num_rows } = serializable_index else { panic!() };
assert_eq!(num_rows, 2);
let non_null_rows: Vec<RowId> = non_null_row_ids.boxed_iter().collect();
assert_eq!(&non_null_rows, &[1]);
}
}

71
columnar/src/column_index/mod.rs
View File

@@ -5,18 +5,15 @@ mod serialize;
use std::ops::Range;
pub use merge::merge_column_index;
pub use merge::stack_column_index;
pub use optional_index::{OptionalIndex, Set};
pub use serialize::{open_column_index, serialize_column_index, SerializableColumnIndex};
use crate::column_index::multivalued_index::MultiValueIndex;
use crate::{Cardinality, DocId, RowId};
use crate::{Cardinality, RowId};
#[derive(Clone)]
pub enum ColumnIndex {
Empty {
num_docs: u32,
},
Full,
Optional(OptionalIndex),
/// In addition, at index num_rows, an extra value is added
@@ -24,82 +21,31 @@ pub enum ColumnIndex {
Multivalued(MultiValueIndex),
}
impl From<OptionalIndex> for ColumnIndex {
fn from(optional_index: OptionalIndex) -> ColumnIndex {
ColumnIndex::Optional(optional_index)
}
}
impl From<MultiValueIndex> for ColumnIndex {
fn from(multi_value_index: MultiValueIndex) -> ColumnIndex {
ColumnIndex::Multivalued(multi_value_index)
}
}
impl ColumnIndex {
#[inline]
pub fn get_cardinality(&self) -> Cardinality {
match self {
ColumnIndex::Empty { .. } => Cardinality::Optional,
ColumnIndex::Full => Cardinality::Full,
ColumnIndex::Optional(_) => Cardinality::Optional,
ColumnIndex::Multivalued(_) => Cardinality::Multivalued,
}
}
/// Returns true if and only if there are at least one value associated to the row.
pub fn has_value(&self, doc_id: DocId) -> bool {
pub fn value_row_ids(&self, row_id: RowId) -> Range<RowId> {
match self {
ColumnIndex::Empty { .. } => false,
ColumnIndex::Full => true,
ColumnIndex::Optional(optional_index) => optional_index.contains(doc_id),
ColumnIndex::Multivalued(multivalued_index) => {
!multivalued_index.range(doc_id).is_empty()
}
}
}
pub fn value_row_ids(&self, doc_id: DocId) -> Range<RowId> {
match self {
ColumnIndex::Empty { .. } => 0..0,
ColumnIndex::Full => doc_id..doc_id + 1,
ColumnIndex::Full => row_id..row_id + 1,
ColumnIndex::Optional(optional_index) => {
if let Some(val) = optional_index.rank_if_exists(doc_id) {
if let Some(val) = optional_index.rank_if_exists(row_id) {
val..val + 1
} else {
0..0
}
}
ColumnIndex::Multivalued(multivalued_index) => multivalued_index.range(doc_id),
ColumnIndex::Multivalued(multivalued_index) => multivalued_index.range(row_id),
}
}
pub fn docid_range_to_rowids(&self, doc_id: Range<DocId>) -> Range<RowId> {
pub fn select_batch_in_place(&self, rank_ids: &mut Vec<RowId>) {
match self {
ColumnIndex::Empty { .. } => 0..0,
ColumnIndex::Full => doc_id,
ColumnIndex::Optional(optional_index) => {
let row_start = optional_index.rank(doc_id.start);
let row_end = optional_index.rank(doc_id.end);
row_start..row_end
}
ColumnIndex::Multivalued(multivalued_index) => {
let end_docid = doc_id.end.min(multivalued_index.num_docs() - 1) + 1;
let start_docid = doc_id.start.min(end_docid);
let row_start = multivalued_index.start_index_column.get_val(start_docid);
let row_end = multivalued_index.start_index_column.get_val(end_docid);
row_start..row_end
}
}
}
pub fn select_batch_in_place(&self, doc_id_start: DocId, rank_ids: &mut Vec<RowId>) {
match self {
ColumnIndex::Empty { .. } => {
rank_ids.clear();
}
ColumnIndex::Full => {
// No need to do anything:
// value_idx and row_idx are the same.
@@ -108,7 +54,8 @@ impl ColumnIndex {
optional_index.select_batch(&mut rank_ids[..]);
}
ColumnIndex::Multivalued(multivalued_index) => {
multivalued_index.select_batch_in_place(doc_id_start, rank_ids)
// TODO important: avoid using 0u32, and restart from the beginning all of the time.
multivalued_index.select_batch_in_place(0u32, rank_ids)
}
}
}

39
columnar/src/column_index/multivalued_index.rs
View File

@@ -5,17 +5,16 @@ use std::sync::Arc;
use common::OwnedBytes;
use crate::column_values::{
load_u64_based_column_values, serialize_u64_based_column_values, CodecType, ColumnValues,
};
use crate::column_values::u64_based::CodecType;
use crate::column_values::ColumnValues;
use crate::iterable::Iterable;
use crate::{DocId, RowId};
use crate::RowId;
pub fn serialize_multivalued_index(
multivalued_index: &dyn Iterable<RowId>,
output: &mut impl Write,
) -> io::Result<()> {
serialize_u64_based_column_values(
crate::column_values::u64_based::serialize_u64_based_column_values(
multivalued_index,
&[CodecType::Bitpacked, CodecType::Linear],
output,
@@ -24,7 +23,8 @@ pub fn serialize_multivalued_index(
}
pub fn open_multivalued_index(bytes: OwnedBytes) -> io::Result<MultiValueIndex> {
let start_index_column: Arc<dyn ColumnValues<RowId>> = load_u64_based_column_values(bytes)?;
let start_index_column: Arc<dyn ColumnValues<RowId>> =
crate::column_values::u64_based::load_u64_based_column_values(bytes)?;
Ok(MultiValueIndex { start_index_column })
}
@@ -42,30 +42,23 @@ impl From<Arc<dyn ColumnValues<RowId>>> for MultiValueIndex {
}
impl MultiValueIndex {
pub fn for_test(start_offsets: &[RowId]) -> MultiValueIndex {
let mut buffer = Vec::new();
serialize_multivalued_index(&start_offsets, &mut buffer).unwrap();
let bytes = OwnedBytes::new(buffer);
open_multivalued_index(bytes).unwrap()
}
/// Returns `[start, end)`, such that the values associated with
/// the given document are `start..end`.
#[inline]
pub(crate) fn range(&self, doc_id: DocId) -> Range<RowId> {
let start = self.start_index_column.get_val(doc_id);
let end = self.start_index_column.get_val(doc_id + 1);
pub(crate) fn range(&self, row_id: RowId) -> Range<RowId> {
let start = self.start_index_column.get_val(row_id);
let end = self.start_index_column.get_val(row_id + 1);
start..end
}
/// Returns the number of documents in the index.
#[inline]
pub fn num_docs(&self) -> u32 {
pub fn num_rows(&self) -> u32 {
self.start_index_column.num_vals() - 1
}
/// Converts a list of ranks (row ids of values) in a 1:n index to the corresponding list of
/// docids. Positions are converted inplace to docids.
/// row_ids. Positions are converted inplace to docids.
///
/// Since there is no index for value pos -> docid, but docid -> value pos range, we scan the
/// index.
@@ -76,20 +69,20 @@ impl MultiValueIndex {
/// TODO: Instead of a linear scan we can employ a exponential search into binary search to
/// match a docid to its value position.
#[allow(clippy::bool_to_int_with_if)]
pub(crate) fn select_batch_in_place(&self, docid_start: DocId, ranks: &mut Vec<u32>) {
pub(crate) fn select_batch_in_place(&self, row_start: RowId, ranks: &mut Vec<u32>) {
if ranks.is_empty() {
return;
}
let mut cur_doc = docid_start;
let mut cur_doc = row_start;
let mut last_doc = None;
assert!(self.start_index_column.get_val(docid_start) <= ranks[0]);
assert!(self.start_index_column.get_val(row_start) as u32 <= ranks[0]);
let mut write_doc_pos = 0;
for i in 0..ranks.len() {
let pos = ranks[i];
loop {
let end = self.start_index_column.get_val(cur_doc + 1);
let end = self.start_index_column.get_val(cur_doc + 1) as u32;
if end > pos {
ranks[write_doc_pos] = cur_doc;
write_doc_pos += if last_doc == Some(cur_doc) { 0 } else { 1 };
@@ -127,7 +120,7 @@ mod tests {
let offsets: Vec<RowId> = vec![0, 10, 12, 15, 22, 23]; // docid values are [0..10, 10..12, 12..15, etc.]
let column: Arc<dyn ColumnValues<RowId>> = Arc::new(IterColumn::from(offsets.into_iter()));
let index = MultiValueIndex::from(column);
assert_eq!(index.num_docs(), 5);
assert_eq!(index.num_rows(), 5);
let positions = &[10u32, 11, 15, 20, 21, 22];
assert_eq!(index_to_pos_helper(&index, 0..5, positions), vec![1, 3, 4]);
assert_eq!(index_to_pos_helper(&index, 1..5, positions), vec![1, 3, 4]);

67
columnar/src/column_index/optional_index/mod.rs
View File

@@ -11,7 +11,7 @@ use set_block::{
};
use crate::iterable::Iterable;
use crate::{DocId, InvalidData, RowId};
use crate::{InvalidData, RowId};
/// The threshold for for number of elements after which we switch to dense block encoding.
///
@@ -88,6 +88,22 @@ pub struct OptionalIndex {
block_metas: Arc<[BlockMeta]>,
}
impl OptionalIndex {
pub fn num_rows(&self) -> RowId {
self.num_rows
}
pub fn num_non_nulls(&self) -> RowId {
self.num_non_null_rows
}
pub fn iter_rows<'a>(&'a self) -> impl Iterator<Item = RowId> + 'a {
// TODO optimize
let mut select_batch = self.select_cursor();
(0..self.num_non_null_rows).map(move |rank| select_batch.select(rank))
}
}
/// Splits a value address into lower and upper 16bits.
/// The lower 16 bits are the value in the block
/// The upper 16 bits are the block index
@@ -177,11 +193,11 @@ impl Set<RowId> for OptionalIndex {
}
#[inline]
fn rank(&self, doc_id: DocId) -> RowId {
fn rank(&self, row_id: RowId) -> RowId {
let RowAddr {
block_id,
in_block_row_id,
} = row_addr_from_row_id(doc_id);
} = row_addr_from_row_id(row_id);
let block_meta = self.block_metas[block_id as usize];
let block = self.block(block_meta);
let block_offset_row_id = match block {
@@ -192,11 +208,11 @@ impl Set<RowId> for OptionalIndex {
}
#[inline]
fn rank_if_exists(&self, doc_id: DocId) -> Option<RowId> {
fn rank_if_exists(&self, row_id: RowId) -> Option<RowId> {
let RowAddr {
block_id,
in_block_row_id,
} = row_addr_from_row_id(doc_id);
} = row_addr_from_row_id(row_id);
let block_meta = self.block_metas[block_id as usize];
let block = self.block(block_meta);
let block_offset_row_id = match block {
@@ -220,7 +236,7 @@ impl Set<RowId> for OptionalIndex {
block_doc_idx_start + in_block_rank as u32
}
fn select_cursor(&self) -> OptionalIndexSelectCursor<'_> {
fn select_cursor<'b>(&'b self) -> OptionalIndexSelectCursor<'b> {
OptionalIndexSelectCursor {
current_block_cursor: BlockSelectCursor::Sparse(
SparseBlockCodec::open(b"").select_cursor(),
@@ -235,31 +251,6 @@ impl Set<RowId> for OptionalIndex {
}
impl OptionalIndex {
pub fn for_test(num_rows: RowId, row_ids: &[RowId]) -> OptionalIndex {
assert!(row_ids
.last()
.copied()
.map(|last_row_id| last_row_id < num_rows)
.unwrap_or(true));
let mut buffer = Vec::new();
serialize_optional_index(&row_ids, num_rows, &mut buffer).unwrap();
let bytes = OwnedBytes::new(buffer);
open_optional_index(bytes).unwrap()
}
pub fn num_docs(&self) -> RowId {
self.num_rows
}
pub fn num_non_nulls(&self) -> RowId {
self.num_non_null_rows
}
pub fn iter_rows(&self) -> impl Iterator<Item = RowId> + '_ {
// TODO optimize
let mut select_batch = self.select_cursor();
(0..self.num_non_null_rows).map(move |rank| select_batch.select(rank))
}
pub fn select_batch(&self, ranks: &mut [RowId]) {
let mut select_cursor = self.select_cursor();
for rank in ranks.iter_mut() {
@@ -268,7 +259,7 @@ impl OptionalIndex {
}
#[inline]
fn block(&self, block_meta: BlockMeta) -> Block<'_> {
fn block<'a>(&'a self, block_meta: BlockMeta) -> Block<'a> {
let BlockMeta {
start_byte_offset,
block_variant,
@@ -351,7 +342,7 @@ fn serialize_optional_index_block(block_els: &[u16], out: &mut impl io::Write) -
Ok(())
}
pub fn serialize_optional_index<W: io::Write>(
pub fn serialize_optional_index<'a, W: io::Write>(
non_null_rows: &dyn Iterable<RowId>,
num_rows: RowId,
output: &mut W,
@@ -427,7 +418,7 @@ impl SerializedBlockMeta {
}
#[inline]
fn to_bytes(self) -> [u8; SERIALIZED_BLOCK_META_NUM_BYTES] {
fn to_bytes(&self) -> [u8; SERIALIZED_BLOCK_META_NUM_BYTES] {
assert!(self.num_non_null_rows > 0);
let mut bytes = [0u8; SERIALIZED_BLOCK_META_NUM_BYTES];
bytes[0..2].copy_from_slice(&self.block_id.to_le_bytes());
@@ -440,7 +431,7 @@ impl SerializedBlockMeta {
#[inline]
fn is_sparse(num_rows_in_block: u32) -> bool {
num_rows_in_block < DENSE_BLOCK_THRESHOLD
num_rows_in_block < DENSE_BLOCK_THRESHOLD as u32
}
fn deserialize_optional_index_block_metadatas(
@@ -448,7 +439,7 @@ fn deserialize_optional_index_block_metadatas(
num_rows: u32,
) -> (Box<[BlockMeta]>, u32) {
let num_blocks = data.len() / SERIALIZED_BLOCK_META_NUM_BYTES;
let mut block_metas = Vec::with_capacity(num_blocks + 1);
let mut block_metas = Vec::with_capacity(num_blocks as usize + 1);
let mut start_byte_offset = 0;
let mut non_null_rows_before_block = 0;
for block_meta_bytes in data.chunks_exact(SERIALIZED_BLOCK_META_NUM_BYTES) {
@@ -479,7 +470,7 @@ fn deserialize_optional_index_block_metadatas(
block_variant,
});
start_byte_offset += block_variant.num_bytes_in_block();
non_null_rows_before_block += num_non_null_rows;
non_null_rows_before_block += num_non_null_rows as u32;
}
block_metas.resize(
((num_rows + BLOCK_SIZE - 1) / BLOCK_SIZE) as usize,
@@ -501,7 +492,7 @@ pub fn open_optional_index(bytes: OwnedBytes) -> io::Result<OptionalIndex> {
num_non_empty_block_bytes as usize * SERIALIZED_BLOCK_META_NUM_BYTES;
let (block_data, block_metas) = bytes.rsplit(block_metas_num_bytes);
let (block_metas, num_non_null_rows) =
deserialize_optional_index_block_metadatas(block_metas.as_slice(), num_rows);
deserialize_optional_index_block_metadatas(block_metas.as_slice(), num_rows).into();
let optional_index = OptionalIndex {
num_rows,
num_non_null_rows,

4
columnar/src/column_index/optional_index/set.rs
View File

@@ -10,7 +10,7 @@ pub trait SetCodec {
///
/// May panic if the elements are not sorted.
fn serialize(els: impl Iterator<Item = Self::Item>, wrt: impl io::Write) -> io::Result<()>;
fn open(data: &[u8]) -> Self::Reader<'_>;
fn open<'a>(data: &'a [u8]) -> Self::Reader<'a>;
}
/// Stateful object that makes it possible to compute several select in a row,
@@ -43,5 +43,5 @@ pub trait Set<T> {
fn select(&self, rank: T) -> T;
/// Creates a brand new select cursor.
fn select_cursor(&self) -> Self::SelectCursor<'_>;
fn select_cursor<'b>(&'b self) -> Self::SelectCursor<'b>;
}

10
columnar/src/column_index/optional_index/set_block/dense.rs
View File

@@ -32,7 +32,7 @@ pub const MINI_BLOCK_NUM_BYTES: usize = MINI_BLOCK_BITVEC_NUM_BYTES + MINI_BLOCK
/// Number of bytes in a dense block.
pub const DENSE_BLOCK_NUM_BYTES: u32 =
(ELEMENTS_PER_BLOCK / ELEMENTS_PER_MINI_BLOCK as u32) * MINI_BLOCK_NUM_BYTES as u32;
(ELEMENTS_PER_BLOCK as u32 / ELEMENTS_PER_MINI_BLOCK as u32) * MINI_BLOCK_NUM_BYTES as u32;
pub struct DenseBlockCodec;
@@ -45,7 +45,7 @@ impl SetCodec for DenseBlockCodec {
}
#[inline]
fn open(data: &[u8]) -> Self::Reader<'_> {
fn open<'a>(data: &'a [u8]) -> Self::Reader<'a> {
assert_eq!(data.len(), DENSE_BLOCK_NUM_BYTES as usize);
DenseBlock(data)
}
@@ -94,7 +94,7 @@ impl DenseMiniBlock {
Self { bitvec, rank }
}
fn to_bytes(self) -> [u8; MINI_BLOCK_NUM_BYTES] {
fn to_bytes(&self) -> [u8; MINI_BLOCK_NUM_BYTES] {
let mut bytes = [0u8; MINI_BLOCK_NUM_BYTES];
bytes[..MINI_BLOCK_BITVEC_NUM_BYTES].copy_from_slice(&self.bitvec.to_le_bytes());
bytes[MINI_BLOCK_BITVEC_NUM_BYTES..].copy_from_slice(&self.rank.to_le_bytes());
@@ -166,7 +166,7 @@ impl<'a> Set<u16> for DenseBlock<'a> {
}
#[inline(always)]
fn select_cursor(&self) -> Self::SelectCursor<'_> {
fn select_cursor<'b>(&'b self) -> Self::SelectCursor<'b> {
DenseBlockSelectCursor {
block_id: 0,
dense_block: *self,
@@ -229,7 +229,7 @@ pub fn serialize_dense_codec(
while block_id > current_block_id {
let dense_mini_block = DenseMiniBlock {
bitvec: block,
rank: non_null_rows_before,
rank: non_null_rows_before as u16,
};
output.write_all(&dense_mini_block.to_bytes())?;
non_null_rows_before += block.count_ones() as u16;

4
columnar/src/column_index/optional_index/set_block/sparse.rs
View File

@@ -16,7 +16,7 @@ impl SetCodec for SparseBlockCodec {
Ok(())
}
fn open(data: &[u8]) -> Self::Reader<'_> {
fn open<'a>(data: &'a [u8]) -> Self::Reader<'a> {
SparseBlock(data)
}
}
@@ -56,7 +56,7 @@ impl<'a> Set<u16> for SparseBlock<'a> {
}
#[inline(always)]
fn select_cursor(&self) -> Self::SelectCursor<'_> {
fn select_cursor<'b>(&'b self) -> Self::SelectCursor<'b> {
*self
}
}

81
columnar/src/column_index/optional_index/tests.rs
View File

@@ -37,7 +37,7 @@ proptest! {
fn test_with_random_sets_simple() {
let vals = 10..BLOCK_SIZE * 2;
let mut out: Vec<u8> = Vec::new();
serialize_optional_index(&vals, 100, &mut out).unwrap();
serialize_optional_index(&vals.clone(), 100, &mut out).unwrap();
let null_index = open_optional_index(OwnedBytes::new(out)).unwrap();
let ranks: Vec<u32> = (65_472u32..65_473u32).collect();
let els: Vec<u32> = ranks.iter().copied().map(|rank| rank + 10).collect();
@@ -107,43 +107,59 @@ fn test_null_index(data: &[bool]) {
#[test]
fn test_optional_index_test_translation() {
let optional_index = OptionalIndex::for_test(4, &[0, 2]);
let mut select_cursor = optional_index.select_cursor();
let mut out = vec![];
let iter = &[true, false, true, false];
serialize_optional_index(&&iter[..], iter.len() as u32, &mut out).unwrap();
let null_index = open_optional_index(OwnedBytes::new(out)).unwrap();
let mut select_cursor = null_index.select_cursor();
assert_eq!(select_cursor.select(0), 0);
assert_eq!(select_cursor.select(1), 2);
}
#[test]
fn test_optional_index_translate() {
let optional_index = OptionalIndex::for_test(4, &[0, 2]);
assert_eq!(optional_index.rank_if_exists(0), Some(0));
assert_eq!(optional_index.rank_if_exists(2), Some(1));
let mut out = vec![];
let iter = &[true, false, true, false];
serialize_optional_index(&&iter[..], iter.len() as RowId, &mut out).unwrap();
let null_index = open_optional_index(OwnedBytes::new(out)).unwrap();
assert_eq!(null_index.rank_if_exists(0), Some(0));
assert_eq!(null_index.rank_if_exists(2), Some(1));
}
#[test]
fn test_optional_index_small() {
let optional_index = OptionalIndex::for_test(4, &[0, 2]);
assert!(optional_index.contains(0));
assert!(!optional_index.contains(1));
assert!(optional_index.contains(2));
assert!(!optional_index.contains(3));
let mut out = vec![];
let iter = &[true, false, true, false];
serialize_optional_index(&&iter[..], iter.len() as RowId, &mut out).unwrap();
let null_index = open_optional_index(OwnedBytes::new(out)).unwrap();
assert!(null_index.contains(0));
assert!(!null_index.contains(1));
assert!(null_index.contains(2));
assert!(!null_index.contains(3));
}
#[test]
fn test_optional_index_large() {
let row_ids = &[ELEMENTS_PER_BLOCK, ELEMENTS_PER_BLOCK + 1];
let optional_index = OptionalIndex::for_test(ELEMENTS_PER_BLOCK + 2, row_ids);
assert!(!optional_index.contains(0));
assert!(!optional_index.contains(100));
assert!(!optional_index.contains(ELEMENTS_PER_BLOCK - 1));
assert!(optional_index.contains(ELEMENTS_PER_BLOCK));
assert!(optional_index.contains(ELEMENTS_PER_BLOCK + 1));
let mut docs = vec![];
docs.extend((0..ELEMENTS_PER_BLOCK).map(|_idx| false));
docs.extend((0..=1).map(|_idx| true));
let mut out = vec![];
serialize_optional_index(&&docs[..], docs.len() as RowId, &mut out).unwrap();
let null_index = open_optional_index(OwnedBytes::new(out)).unwrap();
assert!(!null_index.contains(0));
assert!(!null_index.contains(100));
assert!(!null_index.contains(ELEMENTS_PER_BLOCK - 1));
assert!(null_index.contains(ELEMENTS_PER_BLOCK));
assert!(null_index.contains(ELEMENTS_PER_BLOCK + 1));
}
fn test_optional_index_iter_aux(row_ids: &[RowId], num_rows: RowId) {
let optional_index = OptionalIndex::for_test(num_rows, row_ids);
assert_eq!(optional_index.num_docs(), num_rows);
assert!(optional_index.iter_rows().eq(row_ids.iter().copied()));
let mut buffer: Vec<u8> = Vec::new();
serialize_optional_index(&row_ids, num_rows, &mut buffer).unwrap();
let null_index = open_optional_index(OwnedBytes::new(buffer)).unwrap();
assert_eq!(null_index.num_rows(), num_rows);
assert!(null_index.iter_rows().eq(row_ids.iter().copied()));
}
#[test]
@@ -152,9 +168,11 @@ fn test_optional_index_iter_empty() {
}
fn test_optional_index_rank_aux(row_ids: &[RowId]) {
let mut buffer: Vec<u8> = Vec::new();
let num_rows = row_ids.last().copied().unwrap_or(0u32) + 1;
let null_index = OptionalIndex::for_test(num_rows, row_ids);
assert_eq!(null_index.num_docs(), num_rows);
serialize_optional_index(&row_ids, num_rows, &mut buffer).unwrap();
let null_index = open_optional_index(OwnedBytes::new(buffer)).unwrap();
assert_eq!(null_index.num_rows(), num_rows);
for (row_id, row_val) in row_ids.iter().copied().enumerate() {
assert_eq!(null_index.rank(row_val), row_id as u32);
assert_eq!(null_index.rank_if_exists(row_val), Some(row_id as u32));
@@ -189,16 +207,6 @@ fn test_optional_index_iter_dense_block() {
test_optional_index_iter_aux(&block, 3 * BLOCK_SIZE);
}
#[test]
fn test_optional_index_for_tests() {
let optional_index = OptionalIndex::for_test(4, &[1, 2]);
assert!(!optional_index.contains(0));
assert!(optional_index.contains(1));
assert!(optional_index.contains(2));
assert!(!optional_index.contains(3));
assert_eq!(optional_index.num_docs(), 4);
}
#[cfg(all(test, feature = "unstable"))]
mod bench {
@@ -212,13 +220,10 @@ mod bench {
fn gen_bools(fill_ratio: f64) -> OptionalIndex {
let mut out = Vec::new();
let mut rng: StdRng = StdRng::from_seed([1u8; 32]);
let vals: Vec<RowId> = (0..TOTAL_NUM_VALUES)
let vals: Vec<bool> = (0..TOTAL_NUM_VALUES)
.map(|_| rng.gen_bool(fill_ratio))
.enumerate()
.filter(|(pos, val)| *val)
.map(|(pos, _)| pos as RowId)
.collect();
serialize_optional_index(&&vals[..], TOTAL_NUM_VALUES, &mut out).unwrap();
serialize_optional_index(&&vals[..], &mut out).unwrap();
let codec = open_optional_index(OwnedBytes::new(out)).unwrap();
codec
}

135
columnar/src/column_values/bench.rs
View File

@@ -1,135 +0,0 @@
use std::sync::Arc;
use common::OwnedBytes;
use rand::rngs::StdRng;
use rand::{Rng, SeedableRng};
use test::{self, Bencher};
use super::*;
use crate::column_values::u64_based::*;
fn get_data() -> Vec<u64> {
let mut rng = StdRng::seed_from_u64(2u64);
let mut data: Vec<_> = (100..55000_u64)
.map(|num| num + rng.gen::<u8>() as u64)
.collect();
data.push(99_000);
data.insert(1000, 2000);
data.insert(2000, 100);
data.insert(3000, 4100);
data.insert(4000, 100);
data.insert(5000, 800);
data
}
fn compute_stats(vals: impl Iterator<Item = u64>) -> ColumnStats {
let mut stats_collector = StatsCollector::default();
for val in vals {
stats_collector.collect(val);
}
stats_collector.stats()
}
#[inline(never)]
fn value_iter() -> impl Iterator<Item = u64> {
0..20_000
}
fn get_reader_for_bench<Codec: ColumnCodec>(data: &[u64]) -> Codec::ColumnValues {
let mut bytes = Vec::new();
let stats = compute_stats(data.iter().cloned());
let mut codec_serializer = Codec::estimator();
for val in data {
codec_serializer.collect(*val);
}
codec_serializer.serialize(&stats, Box::new(data.iter().copied()).as_mut(), &mut bytes);
Codec::load(OwnedBytes::new(bytes)).unwrap()
}
fn bench_get<Codec: ColumnCodec>(b: &mut Bencher, data: &[u64]) {
let col = get_reader_for_bench::<Codec>(data);
b.iter(|| {
let mut sum = 0u64;
for pos in value_iter() {
let val = col.get_val(pos as u32);
sum = sum.wrapping_add(val);
}
sum
});
}
#[inline(never)]
fn bench_get_dynamic_helper(b: &mut Bencher, col: Arc<dyn ColumnValues>) {
b.iter(|| {
let mut sum = 0u64;
for pos in value_iter() {
let val = col.get_val(pos as u32);
sum = sum.wrapping_add(val);
}
sum
});
}
fn bench_get_dynamic<Codec: ColumnCodec>(b: &mut Bencher, data: &[u64]) {
let col = Arc::new(get_reader_for_bench::<Codec>(data));
bench_get_dynamic_helper(b, col);
}
fn bench_create<Codec: ColumnCodec>(b: &mut Bencher, data: &[u64]) {
let stats = compute_stats(data.iter().cloned());
let mut bytes = Vec::new();
b.iter(|| {
bytes.clear();
let mut codec_serializer = Codec::estimator();
for val in data.iter().take(1024) {
codec_serializer.collect(*val);
}
codec_serializer.serialize(&stats, Box::new(data.iter().copied()).as_mut(), &mut bytes)
});
}
#[bench]
fn bench_fastfield_bitpack_create(b: &mut Bencher) {
let data: Vec<_> = get_data();
bench_create::<BitpackedCodec>(b, &data);
}
#[bench]
fn bench_fastfield_linearinterpol_create(b: &mut Bencher) {
let data: Vec<_> = get_data();
bench_create::<LinearCodec>(b, &data);
}
#[bench]
fn bench_fastfield_multilinearinterpol_create(b: &mut Bencher) {
let data: Vec<_> = get_data();
bench_create::<BlockwiseLinearCodec>(b, &data);
}
#[bench]
fn bench_fastfield_bitpack_get(b: &mut Bencher) {
let data: Vec<_> = get_data();
bench_get::<BitpackedCodec>(b, &data);
}
#[bench]
fn bench_fastfield_bitpack_get_dynamic(b: &mut Bencher) {
let data: Vec<_> = get_data();
bench_get_dynamic::<BitpackedCodec>(b, &data);
}
#[bench]
fn bench_fastfield_linearinterpol_get(b: &mut Bencher) {
let data: Vec<_> = get_data();
bench_get::<LinearCodec>(b, &data);
}
#[bench]
fn bench_fastfield_linearinterpol_get_dynamic(b: &mut Bencher) {
let data: Vec<_> = get_data();
bench_get_dynamic::<LinearCodec>(b, &data);
}
#[bench]
fn bench_fastfield_multilinearinterpol_get(b: &mut Bencher) {
let data: Vec<_> = get_data();
bench_get::<BlockwiseLinearCodec>(b, &data);
}
#[bench]
fn bench_fastfield_multilinearinterpol_get_dynamic(b: &mut Bencher) {
let data: Vec<_> = get_data();
bench_get_dynamic::<BlockwiseLinearCodec>(b, &data);
}

390
columnar/src/column_values/column.rs Normal file
View File

@@ -0,0 +1,390 @@
use std::fmt::Debug;
use std::marker::PhantomData;
use std::ops::{Range, RangeInclusive};
use std::sync::Arc;
use tantivy_bitpacker::minmax;
use crate::column_values::monotonic_mapping::StrictlyMonotonicFn;
use crate::iterable::Iterable;
/// `ColumnValues` provides access to a dense field column.
///
/// `Column` are just a wrapper over `ColumnValues` and a `ColumnIndex`.
pub trait ColumnValues<T: PartialOrd = u64>: Send + Sync {
/// Return the value associated with the given idx.
///
/// This accessor should return as fast as possible.
///
/// # Panics
///
/// May panic if `idx` is greater than the column length.
fn get_val(&self, idx: u32) -> T;
/// Fills an output buffer with the fast field values
/// associated with the `DocId` going from
/// `start` to `start + output.len()`.
///
/// # Panics
///
/// Must panic if `start + output.len()` is greater than
/// the segment's `maxdoc`.
#[inline(always)]
fn get_range(&self, start: u64, output: &mut [T]) {
for (out, idx) in output.iter_mut().zip(start..) {
*out = self.get_val(idx as u32);
}
}
/// Get the positions of values which are in the provided value range.
///
/// Note that position == docid for single value fast fields
#[inline(always)]
fn get_docids_for_value_range(
&self,
value_range: RangeInclusive<T>,
doc_id_range: Range<u32>,
positions: &mut Vec<u32>,
) {
let doc_id_range = doc_id_range.start..doc_id_range.end.min(self.num_vals());
for idx in doc_id_range.start..doc_id_range.end {
let val = self.get_val(idx);
if value_range.contains(&val) {
positions.push(idx);
}
}
}
/// Returns the minimum value for this fast field.
///
/// This min_value may not be exact.
/// For instance, the min value does not take in account of possible
/// deleted document. All values are however guaranteed to be higher than
/// `.min_value()`.
fn min_value(&self) -> T;
/// Returns the maximum value for this fast field.
///
/// This max_value may not be exact.
/// For instance, the max value does not take in account of possible
/// deleted document. All values are however guaranteed to be higher than
/// `.max_value()`.
fn max_value(&self) -> T;
/// The number of values in the column.
fn num_vals(&self) -> u32;
/// Returns a iterator over the data
fn iter<'a>(&'a self) -> Box<dyn Iterator<Item = T> + 'a> {
Box::new((0..self.num_vals()).map(|idx| self.get_val(idx)))
}
}
impl<'a, T: PartialOrd> Iterable<T> for &'a [Arc<dyn ColumnValues<T>>] {
fn boxed_iter(&self) -> Box<dyn Iterator<Item = T> + '_> {
Box::new(self.iter().flat_map(|column_value| column_value.iter()))
}
}
impl<T: Copy + PartialOrd + Debug> ColumnValues<T> for Arc<dyn ColumnValues<T>> {
#[inline(always)]
fn get_val(&self, idx: u32) -> T {
self.as_ref().get_val(idx)
}
#[inline(always)]
fn min_value(&self) -> T {
self.as_ref().min_value()
}
#[inline(always)]
fn max_value(&self) -> T {
self.as_ref().max_value()
}
#[inline(always)]
fn num_vals(&self) -> u32 {
self.as_ref().num_vals()
}
#[inline(always)]
fn iter<'b>(&'b self) -> Box<dyn Iterator<Item = T> + 'b> {
self.as_ref().iter()
}
#[inline(always)]
fn get_range(&self, start: u64, output: &mut [T]) {
self.as_ref().get_range(start, output)
}
}
impl<'a, C: ColumnValues<T> + ?Sized, T: Copy + PartialOrd + Debug> ColumnValues<T> for &'a C {
fn get_val(&self, idx: u32) -> T {
(*self).get_val(idx)
}
fn min_value(&self) -> T {
(*self).min_value()
}
fn max_value(&self) -> T {
(*self).max_value()
}
fn num_vals(&self) -> u32 {
(*self).num_vals()
}
fn iter<'b>(&'b self) -> Box<dyn Iterator<Item = T> + 'b> {
(*self).iter()
}
fn get_range(&self, start: u64, output: &mut [T]) {
(*self).get_range(start, output)
}
}
/// VecColumn provides `Column` over a slice.
pub struct VecColumn<'a, T = u64> {
pub(crate) values: &'a [T],
pub(crate) min_value: T,
pub(crate) max_value: T,
}
impl<'a, T: Copy + PartialOrd + Send + Sync + Debug> ColumnValues<T> for VecColumn<'a, T> {
fn get_val(&self, position: u32) -> T {
self.values[position as usize]
}
fn iter(&self) -> Box<dyn Iterator<Item = T> + '_> {
Box::new(self.values.iter().copied())
}
fn min_value(&self) -> T {
self.min_value
}
fn max_value(&self) -> T {
self.max_value
}
fn num_vals(&self) -> u32 {
self.values.len() as u32
}
fn get_range(&self, start: u64, output: &mut [T]) {
output.copy_from_slice(&self.values[start as usize..][..output.len()])
}
}
impl<'a, T: Copy + PartialOrd + Default, V> From<&'a V> for VecColumn<'a, T>
where V: AsRef<[T]> + ?Sized
{
fn from(values: &'a V) -> Self {
let values = values.as_ref();
let (min_value, max_value) = minmax(values.iter().copied()).unwrap_or_default();
Self {
values,
min_value,
max_value,
}
}
}
struct MonotonicMappingColumn<C, T, Input> {
from_column: C,
monotonic_mapping: T,
_phantom: PhantomData<Input>,
}
/// Creates a view of a column transformed by a strictly monotonic mapping. See
/// [`StrictlyMonotonicFn`].
///
/// E.g. apply a gcd monotonic_mapping([100, 200, 300]) == [1, 2, 3]
/// monotonic_mapping.mapping() is expected to be injective, and we should always have
/// monotonic_mapping.inverse(monotonic_mapping.mapping(el)) == el
///
/// The inverse of the mapping is required for:
/// `fn get_positions_for_value_range(&self, range: RangeInclusive<T>) -> Vec<u64> `
/// The user provides the original value range and we need to monotonic map them in the same way the
/// serialization does before calling the underlying column.
///
/// Note that when opening a codec, the monotonic_mapping should be the inverse of the mapping
/// during serialization. And therefore the monotonic_mapping_inv when opening is the same as
/// monotonic_mapping during serialization.
pub fn monotonic_map_column<C, T, Input, Output>(
from_column: C,
monotonic_mapping: T,
) -> impl ColumnValues<Output>
where
C: ColumnValues<Input>,
T: StrictlyMonotonicFn<Input, Output> + Send + Sync,
Input: PartialOrd + Debug + Send + Sync + Clone,
Output: PartialOrd + Debug + Send + Sync + Clone,
{
MonotonicMappingColumn {
from_column,
monotonic_mapping,
_phantom: PhantomData,
}
}
impl<C, T, Input, Output> ColumnValues<Output> for MonotonicMappingColumn<C, T, Input>
where
C: ColumnValues<Input>,
T: StrictlyMonotonicFn<Input, Output> + Send + Sync,
Input: PartialOrd + Send + Debug + Sync + Clone,
Output: PartialOrd + Send + Debug + Sync + Clone,
{
#[inline]
fn get_val(&self, idx: u32) -> Output {
let from_val = self.from_column.get_val(idx);
self.monotonic_mapping.mapping(from_val)
}
fn min_value(&self) -> Output {
let from_min_value = self.from_column.min_value();
self.monotonic_mapping.mapping(from_min_value)
}
fn max_value(&self) -> Output {
let from_max_value = self.from_column.max_value();
self.monotonic_mapping.mapping(from_max_value)
}
fn num_vals(&self) -> u32 {
self.from_column.num_vals()
}
fn iter(&self) -> Box<dyn Iterator<Item = Output> + '_> {
Box::new(
self.from_column
.iter()
.map(|el| self.monotonic_mapping.mapping(el)),
)
}
fn get_docids_for_value_range(
&self,
range: RangeInclusive<Output>,
doc_id_range: Range<u32>,
positions: &mut Vec<u32>,
) {
self.from_column.get_docids_for_value_range(
self.monotonic_mapping.inverse(range.start().clone())
..=self.monotonic_mapping.inverse(range.end().clone()),
doc_id_range,
positions,
)
}
// We voluntarily do not implement get_range as it yields a regression,
// and we do not have any specialized implementation anyway.
}
/// Wraps an iterator into a `Column`.
pub struct IterColumn<T>(T);
impl<T> From<T> for IterColumn<T>
where T: Iterator + Clone + ExactSizeIterator
{
fn from(iter: T) -> Self {
IterColumn(iter)
}
}
impl<T> ColumnValues<T::Item> for IterColumn<T>
where
T: Iterator + Clone + ExactSizeIterator + Send + Sync,
T::Item: PartialOrd + Debug,
{
fn get_val(&self, idx: u32) -> T::Item {
self.0.clone().nth(idx as usize).unwrap()
}
fn min_value(&self) -> T::Item {
self.0.clone().next().unwrap()
}
fn max_value(&self) -> T::Item {
self.0.clone().last().unwrap()
}
fn num_vals(&self) -> u32 {
self.0.len() as u32
}
fn iter(&self) -> Box<dyn Iterator<Item = T::Item> + '_> {
Box::new(self.0.clone())
}
}
#[cfg(test)]
mod tests {
use super::*;
use crate::column_values::monotonic_mapping::{
StrictlyMonotonicMappingInverter, StrictlyMonotonicMappingToInternalBaseval,
StrictlyMonotonicMappingToInternalGCDBaseval,
};
#[test]
fn test_monotonic_mapping() {
let vals = &[3u64, 5u64][..];
let col = VecColumn::from(vals);
let mapped = monotonic_map_column(col, StrictlyMonotonicMappingToInternalBaseval::new(2));
assert_eq!(mapped.min_value(), 1u64);
assert_eq!(mapped.max_value(), 3u64);
assert_eq!(mapped.num_vals(), 2);
assert_eq!(mapped.num_vals(), 2);
assert_eq!(mapped.get_val(0), 1);
assert_eq!(mapped.get_val(1), 3);
}
#[test]
fn test_range_as_col() {
let col = IterColumn::from(10..100);
assert_eq!(col.num_vals(), 90);
assert_eq!(col.max_value(), 99);
}
#[test]
fn test_monotonic_mapping_iter() {
let vals: Vec<u64> = (10..110u64).map(|el| el * 10).collect();
let col = VecColumn::from(&vals);
let mapped = monotonic_map_column(
col,
StrictlyMonotonicMappingInverter::from(
StrictlyMonotonicMappingToInternalGCDBaseval::new(10, 100),
),
);
let val_i64s: Vec<u64> = mapped.iter().collect();
for i in 0..100 {
assert_eq!(val_i64s[i as usize], mapped.get_val(i));
}
}
#[test]
fn test_monotonic_mapping_get_range() {
let vals: Vec<u64> = (0..100u64).map(|el| el * 10).collect();
let col = VecColumn::from(&vals);
let mapped = monotonic_map_column(
col,
StrictlyMonotonicMappingInverter::from(
StrictlyMonotonicMappingToInternalGCDBaseval::new(10, 0),
),
);
assert_eq!(mapped.min_value(), 0u64);
assert_eq!(mapped.max_value(), 9900u64);
assert_eq!(mapped.num_vals(), 100);
let val_u64s: Vec<u64> = mapped.iter().collect();
assert_eq!(val_u64s.len(), 100);
for i in 0..100 {
assert_eq!(val_u64s[i as usize], mapped.get_val(i));
assert_eq!(val_u64s[i as usize], vals[i as usize] * 10);
}
let mut buf = [0u64; 20];
mapped.get_range(7, &mut buf[..]);
assert_eq!(&val_u64s[7..][..20], &buf);
}
}

0
columnar/src/column_values/u128_based/compact_space/blank_range.rs → columnar/src/column_values/compact_space/blank_range.rs
View File

0
columnar/src/column_values/u128_based/compact_space/build_compact_space.rs → columnar/src/column_values/compact_space/build_compact_space.rs
View File

738
columnar/src/column_values/u128_based/compact_space/mod.rs → columnar/src/column_values/compact_space/mod.rs
View File

@@ -17,15 +17,14 @@ use std::{
ops::{Range, RangeInclusive},
};
mod blank_range;
mod build_compact_space;
use build_compact_space::get_compact_space;
use common::{BinarySerializable, CountingWriter, OwnedBytes, VInt, VIntU128};
use tantivy_bitpacker::{self, BitPacker, BitUnpacker};
use crate::column_values::compact_space::build_compact_space::get_compact_space;
use crate::column_values::ColumnValues;
use crate::RowId;
mod blank_range;
mod build_compact_space;
/// The cost per blank is quite hard actually, since blanks are delta encoded, the actual cost of
/// blanks depends on the number of blanks.
@@ -159,30 +158,23 @@ impl CompactSpace {
pub struct CompactSpaceCompressor {
params: IPCodecParams,
}
#[derive(Debug, Clone)]
pub struct IPCodecParams {
compact_space: CompactSpace,
bit_unpacker: BitUnpacker,
min_value: u128,
max_value: u128,
num_vals: RowId,
num_vals: u32,
num_bits: u8,
}
impl CompactSpaceCompressor {
pub fn num_vals(&self) -> RowId {
self.params.num_vals
}
/// Taking the vals as Vec may cost a lot of memory. It is used to sort the vals.
pub fn train_from(iter: impl Iterator<Item = u128>) -> Self {
pub fn train_from(iter: impl Iterator<Item = u128>, num_vals: u32) -> Self {
let mut values_sorted = BTreeSet::new();
let mut total_num_values = 0u32;
for val in iter {
total_num_values += 1u32;
values_sorted.insert(val);
}
values_sorted.extend(iter);
let total_num_values = num_vals;
let compact_space =
get_compact_space(&values_sorted, total_num_values, COST_PER_BLANK_IN_BITS);
let amplitude_compact_space = compact_space.amplitude_compact_space();
@@ -313,7 +305,7 @@ impl ColumnValues<u128> for CompactSpaceDecompressor {
}
#[inline]
fn get_row_ids_for_value_range(
fn get_docids_for_value_range(
&self,
value_range: RangeInclusive<u128>,
positions_range: Range<u32>,
@@ -458,352 +450,364 @@ impl CompactSpaceDecompressor {
}
}
#[cfg(test)]
mod tests {
use itertools::Itertools;
use super::*;
use crate::column_values::u128_based::U128Header;
use crate::column_values::{open_u128_mapped, serialize_column_values_u128};
#[test]
fn compact_space_test() {
let ips = &[
2u128, 4u128, 1000, 1001, 1002, 1003, 1004, 1005, 1008, 1010, 1012, 1260,
]
.into_iter()
.collect();
let compact_space = get_compact_space(ips, ips.len() as u32, 11);
let amplitude = compact_space.amplitude_compact_space();
assert_eq!(amplitude, 17);
assert_eq!(1, compact_space.u128_to_compact(2).unwrap());
assert_eq!(2, compact_space.u128_to_compact(3).unwrap());
assert_eq!(compact_space.u128_to_compact(100).unwrap_err(), 1);
for (num1, num2) in (0..3).tuple_windows() {
assert_eq!(
compact_space.get_range_mapping(num1).compact_end() + 1,
compact_space.get_range_mapping(num2).compact_start
);
}
let mut output: Vec<u8> = Vec::new();
compact_space.serialize(&mut output).unwrap();
assert_eq!(
compact_space,
CompactSpace::deserialize(&mut &output[..]).unwrap()
);
for ip in ips {
let compact = compact_space.u128_to_compact(*ip).unwrap();
assert_eq!(compact_space.compact_to_u128(compact), *ip);
}
}
#[test]
fn compact_space_amplitude_test() {
let ips = &[100000u128, 1000000].into_iter().collect();
let compact_space = get_compact_space(ips, ips.len() as u32, 1);
let amplitude = compact_space.amplitude_compact_space();
assert_eq!(amplitude, 2);
}
fn test_all(mut data: OwnedBytes, expected: &[u128]) {
let _header = U128Header::deserialize(&mut data);
let decompressor = CompactSpaceDecompressor::open(data).unwrap();
for (idx, expected_val) in expected.iter().cloned().enumerate() {
let val = decompressor.get(idx as u32);
assert_eq!(val, expected_val);
let test_range = |range: RangeInclusive<u128>| {
let expected_positions = expected
.iter()
.positions(|val| range.contains(val))
.map(|pos| pos as u32)
.collect::<Vec<_>>();
let mut positions = Vec::new();
decompressor.get_positions_for_value_range(
range,
0..decompressor.num_vals(),
&mut positions,
);
assert_eq!(positions, expected_positions);
};
test_range(expected_val.saturating_sub(1)..=expected_val);
test_range(expected_val..=expected_val);
test_range(expected_val..=expected_val.saturating_add(1));
test_range(expected_val.saturating_sub(1)..=expected_val.saturating_add(1));
}
}
fn test_aux_vals(u128_vals: &[u128]) -> OwnedBytes {
let mut out = Vec::new();
serialize_column_values_u128(&u128_vals, &mut out).unwrap();
let data = OwnedBytes::new(out);
test_all(data.clone(), u128_vals);
data
}
#[test]
fn test_range_1() {
let vals = &[
1u128,
100u128,
3u128,
99999u128,
100000u128,
100001u128,
4_000_211_221u128,
4_000_211_222u128,
333u128,
];
let mut data = test_aux_vals(vals);
let _header = U128Header::deserialize(&mut data);
let decomp = CompactSpaceDecompressor::open(data).unwrap();
let complete_range = 0..vals.len() as u32;
for (pos, val) in vals.iter().enumerate() {
let val = *val;
let pos = pos as u32;
let mut positions = Vec::new();
decomp.get_positions_for_value_range(val..=val, pos..pos + 1, &mut positions);
assert_eq!(positions, vec![pos]);
}
// handle docid range out of bounds
let positions: Vec<u32> = get_positions_for_value_range_helper(&decomp, 0..=1, 1..u32::MAX);
assert!(positions.is_empty());
let positions =
get_positions_for_value_range_helper(&decomp, 0..=1, complete_range.clone());
assert_eq!(positions, vec![0]);
let positions =
get_positions_for_value_range_helper(&decomp, 0..=2, complete_range.clone());
assert_eq!(positions, vec![0]);
let positions =
get_positions_for_value_range_helper(&decomp, 0..=3, complete_range.clone());
assert_eq!(positions, vec![0, 2]);
assert_eq!(
get_positions_for_value_range_helper(
&decomp,
99999u128..=99999u128,
complete_range.clone()
),
vec![3]
);
assert_eq!(
get_positions_for_value_range_helper(
&decomp,
99999u128..=100000u128,
complete_range.clone()
),
vec![3, 4]
);
assert_eq!(
get_positions_for_value_range_helper(
&decomp,
99998u128..=100000u128,
complete_range.clone()
),
vec![3, 4]
);
assert_eq!(
&get_positions_for_value_range_helper(
&decomp,
99998u128..=99999u128,
complete_range.clone()
),
&[3]
);
assert!(get_positions_for_value_range_helper(
&decomp,
99998u128..=99998u128,
complete_range.clone()
)
.is_empty());
assert_eq!(
&get_positions_for_value_range_helper(
&decomp,
333u128..=333u128,
complete_range.clone()
),
&[8]
);
assert_eq!(
&get_positions_for_value_range_helper(
&decomp,
332u128..=333u128,
complete_range.clone()
),
&[8]
);
assert_eq!(
&get_positions_for_value_range_helper(
&decomp,
332u128..=334u128,
complete_range.clone()
),
&[8]
);
assert_eq!(
&get_positions_for_value_range_helper(
&decomp,
333u128..=334u128,
complete_range.clone()
),
&[8]
);
assert_eq!(
&get_positions_for_value_range_helper(
&decomp,
4_000_211_221u128..=5_000_000_000u128,
complete_range
),
&[6, 7]
);
}
#[test]
fn test_empty() {
let vals = &[];
let data = test_aux_vals(vals);
let _decomp = CompactSpaceDecompressor::open(data).unwrap();
}
#[test]
fn test_range_2() {
let vals = &[
100u128,
99999u128,
100000u128,
100001u128,
4_000_211_221u128,
4_000_211_222u128,
333u128,
];
let mut data = test_aux_vals(vals);
let _header = U128Header::deserialize(&mut data);
let decomp = CompactSpaceDecompressor::open(data).unwrap();
let complete_range = 0..vals.len() as u32;
assert!(
&get_positions_for_value_range_helper(&decomp, 0..=5, complete_range.clone())
.is_empty(),
);
assert_eq!(
&get_positions_for_value_range_helper(&decomp, 0..=100, complete_range.clone()),
&[0]
);
assert_eq!(
&get_positions_for_value_range_helper(&decomp, 0..=105, complete_range),
&[0]
);
}
fn get_positions_for_value_range_helper<C: ColumnValues<T> + ?Sized, T: PartialOrd>(
column: &C,
value_range: RangeInclusive<T>,
doc_id_range: Range<u32>,
) -> Vec<u32> {
let mut positions = Vec::new();
column.get_row_ids_for_value_range(value_range, doc_id_range, &mut positions);
positions
}
#[test]
fn test_range_3() {
let vals = &[
200u128,
201,
202,
203,
204,
204,
206,
207,
208,
209,
210,
1_000_000,
5_000_000_000,
];
let mut out = Vec::new();
serialize_column_values_u128(&&vals[..], &mut out).unwrap();
let decomp = open_u128_mapped(OwnedBytes::new(out)).unwrap();
let complete_range = 0..vals.len() as u32;
assert_eq!(
get_positions_for_value_range_helper(&*decomp, 199..=200, complete_range.clone()),
vec![0]
);
assert_eq!(
get_positions_for_value_range_helper(&*decomp, 199..=201, complete_range.clone()),
vec![0, 1]
);
assert_eq!(
get_positions_for_value_range_helper(&*decomp, 200..=200, complete_range.clone()),
vec![0]
);
assert_eq!(
get_positions_for_value_range_helper(&*decomp, 1_000_000..=1_000_000, complete_range),
vec![11]
);
}
#[test]
fn test_bug1() {
let vals = &[9223372036854775806];
let _data = test_aux_vals(vals);
}
#[test]
fn test_bug2() {
let vals = &[340282366920938463463374607431768211455u128];
let _data = test_aux_vals(vals);
}
#[test]
fn test_bug3() {
let vals = &[340282366920938463463374607431768211454];
let _data = test_aux_vals(vals);
}
#[test]
fn test_bug4() {
let vals = &[340282366920938463463374607431768211455, 0];
let _data = test_aux_vals(vals);
}
#[test]
fn test_first_large_gaps() {
let vals = &[1_000_000_000u128; 100];
let _data = test_aux_vals(vals);
}
use proptest::prelude::*;
fn num_strategy() -> impl Strategy<Value = u128> {
prop_oneof![
1 => prop::num::u128::ANY.prop_map(|num| u128::MAX - (num % 10) ),
1 => prop::num::u128::ANY.prop_map(|num| i64::MAX as u128 + 5 - (num % 10) ),
1 => prop::num::u128::ANY.prop_map(|num| i128::MAX as u128 + 5 - (num % 10) ),
1 => prop::num::u128::ANY.prop_map(|num| num % 10 ),
20 => prop::num::u128::ANY,
]
}
proptest! {
#![proptest_config(ProptestConfig::with_cases(10))]
#[test]
fn compress_decompress_random(vals in proptest::collection::vec(num_strategy() , 1..1000)) {
let _data = test_aux_vals(&vals);
}
}
}
// TODO reenable what can be reenabled.
// #[cfg(test)]
// mod tests {
//
// use super::*;
// use crate::column::format_version::read_format_version;
// use crate::column::column_footer::read_null_index_footer;
// use crate::column::serialize::U128Header;
// use crate::column::{open_u128, serialize_u128};
//
// #[test]
// fn compact_space_test() {
// let ips = &[
// 2u128, 4u128, 1000, 1001, 1002, 1003, 1004, 1005, 1008, 1010, 1012, 1260,
// ]
// .into_iter()
// .collect();
// let compact_space = get_compact_space(ips, ips.len() as u32, 11);
// let amplitude = compact_space.amplitude_compact_space();
// assert_eq!(amplitude, 17);
// assert_eq!(1, compact_space.u128_to_compact(2).unwrap());
// assert_eq!(2, compact_space.u128_to_compact(3).unwrap());
// assert_eq!(compact_space.u128_to_compact(100).unwrap_err(), 1);
//
// for (num1, num2) in (0..3).tuple_windows() {
// assert_eq!(
// compact_space.get_range_mapping(num1).compact_end() + 1,
// compact_space.get_range_mapping(num2).compact_start
// );
// }
//
// let mut output: Vec<u8> = Vec::new();
// compact_space.serialize(&mut output).unwrap();
//
// assert_eq!(
// compact_space,
// CompactSpace::deserialize(&mut &output[..]).unwrap()
// );
//
// for ip in ips {
// let compact = compact_space.u128_to_compact(*ip).unwrap();
// assert_eq!(compact_space.compact_to_u128(compact), *ip);
// }
// }
//
// #[test]
// fn compact_space_amplitude_test() {
// let ips = &[100000u128, 1000000].into_iter().collect();
// let compact_space = get_compact_space(ips, ips.len() as u32, 1);
// let amplitude = compact_space.amplitude_compact_space();
// assert_eq!(amplitude, 2);
// }
//
// fn test_all(mut data: OwnedBytes, expected: &[u128]) {
// let _header = U128Header::deserialize(&mut data);
// let decompressor = CompactSpaceDecompressor::open(data).unwrap();
// for (idx, expected_val) in expected.iter().cloned().enumerate() {
// let val = decompressor.get(idx as u32);
// assert_eq!(val, expected_val);
//
// let test_range = |range: RangeInclusive<u128>| {
// let expected_positions = expected
// .iter()
// .positions(|val| range.contains(val))
// .map(|pos| pos as u32)
// .collect::<Vec<_>>();
// let mut positions = Vec::new();
// decompressor.get_positions_for_value_range(
// range,
// 0..decompressor.num_vals(),
// &mut positions,
// );
// assert_eq!(positions, expected_positions);
// };
//
// test_range(expected_val.saturating_sub(1)..=expected_val);
// test_range(expected_val..=expected_val);
// test_range(expected_val..=expected_val.saturating_add(1));
// test_range(expected_val.saturating_sub(1)..=expected_val.saturating_add(1));
// }
// }
//
// fn test_aux_vals(u128_vals: &[u128]) -> OwnedBytes {
// let mut out = Vec::new();
// serialize_u128(
// || u128_vals.iter().cloned(),
// u128_vals.len() as u32,
// &mut out,
// )
// .unwrap();
//
// let data = OwnedBytes::new(out);
// let (data, _format_version) = read_format_version(data).unwrap();
// let (data, _null_index_footer) = read_null_index_footer(data).unwrap();
// test_all(data.clone(), u128_vals);
//
// data
// }
//
// #[test]
// fn test_range_1() {
// let vals = &[
// 1u128,
// 100u128,
// 3u128,
// 99999u128,
// 100000u128,
// 100001u128,
// 4_000_211_221u128,
// 4_000_211_222u128,
// 333u128,
// ];
// let mut data = test_aux_vals(vals);
//
// let _header = U128Header::deserialize(&mut data);
// let decomp = CompactSpaceDecompressor::open(data).unwrap();
// let complete_range = 0..vals.len() as u32;
// for (pos, val) in vals.iter().enumerate() {
// let val = *val;
// let pos = pos as u32;
// let mut positions = Vec::new();
// decomp.get_positions_for_value_range(val..=val, pos..pos + 1, &mut positions);
// assert_eq!(positions, vec![pos]);
// }
//
// handle docid range out of bounds
// let positions: Vec<u32> = get_positions_for_value_range_helper(&decomp, 0..=1, 1..u32::MAX);
// assert!(positions.is_empty());
//
// let positions =
// get_positions_for_value_range_helper(&decomp, 0..=1, complete_range.clone());
// assert_eq!(positions, vec![0]);
// let positions =
// get_positions_for_value_range_helper(&decomp, 0..=2, complete_range.clone());
// assert_eq!(positions, vec![0]);
// let positions =
// get_positions_for_value_range_helper(&decomp, 0..=3, complete_range.clone());
// assert_eq!(positions, vec![0, 2]);
// assert_eq!(
// get_positions_for_value_range_helper(
// &decomp,
// 99999u128..=99999u128,
// complete_range.clone()
// ),
// vec![3]
// );
// assert_eq!(
// get_positions_for_value_range_helper(
// &decomp,
// 99999u128..=100000u128,
// complete_range.clone()
// ),
// vec![3, 4]
// );
// assert_eq!(
// get_positions_for_value_range_helper(
// &decomp,
// 99998u128..=100000u128,
// complete_range.clone()
// ),
// vec![3, 4]
// );
// assert_eq!(
// &get_positions_for_value_range_helper(
// &decomp,
// 99998u128..=99999u128,
// complete_range.clone()
// ),
// &[3]
// );
// assert!(get_positions_for_value_range_helper(
// &decomp,
// 99998u128..=99998u128,
// complete_range.clone()
// )
// .is_empty());
// assert_eq!(
// &get_positions_for_value_range_helper(
// &decomp,
// 333u128..=333u128,
// complete_range.clone()
// ),
// &[8]
// );
// assert_eq!(
// &get_positions_for_value_range_helper(
// &decomp,
// 332u128..=333u128,
// complete_range.clone()
// ),
// &[8]
// );
// assert_eq!(
// &get_positions_for_value_range_helper(
// &decomp,
// 332u128..=334u128,
// complete_range.clone()
// ),
// &[8]
// );
// assert_eq!(
// &get_positions_for_value_range_helper(
// &decomp,
// 333u128..=334u128,
// complete_range.clone()
// ),
// &[8]
// );
//
// assert_eq!(
// &get_positions_for_value_range_helper(
// &decomp,
// 4_000_211_221u128..=5_000_000_000u128,
// complete_range
// ),
// &[6, 7]
// );
// }
//
// #[test]
// fn test_empty() {
// let vals = &[];
// let data = test_aux_vals(vals);
// let _decomp = CompactSpaceDecompressor::open(data).unwrap();
// }
//
// #[test]
// fn test_range_2() {
// let vals = &[
// 100u128,
// 99999u128,
// 100000u128,
// 100001u128,
// 4_000_211_221u128,
// 4_000_211_222u128,
// 333u128,
// ];
// let mut data = test_aux_vals(vals);
// let _header = U128Header::deserialize(&mut data);
// let decomp = CompactSpaceDecompressor::open(data).unwrap();
// let complete_range = 0..vals.len() as u32;
// assert!(
// &get_positions_for_value_range_helper(&decomp, 0..=5, complete_range.clone())
// .is_empty(),
// );
// assert_eq!(
// &get_positions_for_value_range_helper(&decomp, 0..=100, complete_range.clone()),
// &[0]
// );
// assert_eq!(
// &get_positions_for_value_range_helper(&decomp, 0..=105, complete_range),
// &[0]
// );
// }
//
// fn get_positions_for_value_range_helper<C: Column<T> + ?Sized, T: PartialOrd>(
// column: &C,
// value_range: RangeInclusive<T>,
// doc_id_range: Range<u32>,
// ) -> Vec<u32> {
// let mut positions = Vec::new();
// column.get_docids_for_value_range(value_range, doc_id_range, &mut positions);
// positions
// }
//
// #[test]
// fn test_range_3() {
// let vals = &[
// 200u128,
// 201,
// 202,
// 203,
// 204,
// 204,
// 206,
// 207,
// 208,
// 209,
// 210,
// 1_000_000,
// 5_000_000_000,
// ];
// let mut out = Vec::new();
// serialize_u128(|| vals.iter().cloned(), vals.len() as u32, &mut out).unwrap();
// let decomp = open_u128::<u128>(OwnedBytes::new(out)).unwrap();
// let complete_range = 0..vals.len() as u32;
//
// assert_eq!(
// get_positions_for_value_range_helper(&*decomp, 199..=200, complete_range.clone()),
// vec![0]
// );
//
// assert_eq!(
// get_positions_for_value_range_helper(&*decomp, 199..=201, complete_range.clone()),
// vec![0, 1]
// );
//
// assert_eq!(
// get_positions_for_value_range_helper(&*decomp, 200..=200, complete_range.clone()),
// vec![0]
// );
//
// assert_eq!(
// get_positions_for_value_range_helper(&*decomp, 1_000_000..=1_000_000, complete_range),
// vec![11]
// );
// }
//
// #[test]
// fn test_bug1() {
// let vals = &[9223372036854775806];
// let _data = test_aux_vals(vals);
// }
//
// #[test]
// fn test_bug2() {
// let vals = &[340282366920938463463374607431768211455u128];
// let _data = test_aux_vals(vals);
// }
//
// #[test]
// fn test_bug3() {
// let vals = &[340282366920938463463374607431768211454];
// let _data = test_aux_vals(vals);
// }
//
// #[test]
// fn test_bug4() {
// let vals = &[340282366920938463463374607431768211455, 0];
// let _data = test_aux_vals(vals);
// }
//
// #[test]
// fn test_first_large_gaps() {
// let vals = &[1_000_000_000u128; 100];
// let _data = test_aux_vals(vals);
// }
// use itertools::Itertools;
// use proptest::prelude::*;
//
// fn num_strategy() -> impl Strategy<Value = u128> {
// prop_oneof![
// 1 => prop::num::u128::ANY.prop_map(|num| u128::MAX - (num % 10) ),
// 1 => prop::num::u128::ANY.prop_map(|num| i64::MAX as u128 + 5 - (num % 10) ),
// 1 => prop::num::u128::ANY.prop_map(|num| i128::MAX as u128 + 5 - (num % 10) ),
// 1 => prop::num::u128::ANY.prop_map(|num| num % 10 ),
// 20 => prop::num::u128::ANY,
// ]
// }
//
// proptest! {
// #![proptest_config(ProptestConfig::with_cases(10))]
//
// #[test]
// fn compress_decompress_random(vals in proptest::collection::vec(num_strategy()
// , 1..1000)) {
// let _data = test_aux_vals(&vals);
// }
// }
// }
//

222
columnar/src/column_values/main.rs Normal file
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@@ -0,0 +1,222 @@
#[macro_use]
extern crate prettytable;
use std::collections::HashSet;
use std::env;
use std::io::BufRead;
use std::net::{IpAddr, Ipv6Addr};
use std::str::FromStr;
use common::OwnedBytes;
use fastfield_codecs::{open_u128, serialize_u128, Column, FastFieldCodecType, VecColumn};
use itertools::Itertools;
use measure_time::print_time;
use prettytable::{Cell, Row, Table};
fn print_set_stats(ip_addrs: &[u128]) {
println!("NumIps\t{}", ip_addrs.len());
let ip_addr_set: HashSet<u128> = ip_addrs.iter().cloned().collect();
println!("NumUniqueIps\t{}", ip_addr_set.len());
let ratio_unique = ip_addr_set.len() as f64 / ip_addrs.len() as f64;
println!("RatioUniqueOverTotal\t{ratio_unique:.4}");
// histogram
let mut ip_addrs = ip_addrs.to_vec();
ip_addrs.sort();
let mut cnts: Vec<usize> = ip_addrs
.into_iter()
.dedup_with_count()
.map(|(cnt, _)| cnt)
.collect();
cnts.sort();
let top_256_cnt: usize = cnts.iter().rev().take(256).sum();
let top_128_cnt: usize = cnts.iter().rev().take(128).sum();
let top_64_cnt: usize = cnts.iter().rev().take(64).sum();
let top_8_cnt: usize = cnts.iter().rev().take(8).sum();
let total: usize = cnts.iter().sum();
println!("{}", total);
println!("{}", top_256_cnt);
println!("{}", top_128_cnt);
println!("Percentage Top8 {:02}", top_8_cnt as f32 / total as f32);
println!("Percentage Top64 {:02}", top_64_cnt as f32 / total as f32);
println!("Percentage Top128 {:02}", top_128_cnt as f32 / total as f32);
println!("Percentage Top256 {:02}", top_256_cnt as f32 / total as f32);
let mut cnts: Vec<(usize, usize)> = cnts.into_iter().dedup_with_count().collect();
cnts.sort_by(|a, b| {
if a.1 == b.1 {
a.0.cmp(&b.0)
} else {
b.1.cmp(&a.1)
}
});
}
fn ip_dataset() -> Vec<u128> {
let mut ip_addr_v4 = 0;
let stdin = std::io::stdin();
let ip_addrs: Vec<u128> = stdin
.lock()
.lines()
.flat_map(|line| {
let line = line.unwrap();
let line = line.trim();
let ip_addr = IpAddr::from_str(line.trim()).ok()?;
if ip_addr.is_ipv4() {
ip_addr_v4 += 1;
}
let ip_addr_v6: Ipv6Addr = match ip_addr {
IpAddr::V4(v4) => v4.to_ipv6_mapped(),
IpAddr::V6(v6) => v6,
};
Some(ip_addr_v6)
})
.map(|ip_v6| u128::from_be_bytes(ip_v6.octets()))
.collect();
println!("IpAddrsAny\t{}", ip_addrs.len());
println!("IpAddrsV4\t{}", ip_addr_v4);
ip_addrs
}
fn bench_ip() {
let dataset = ip_dataset();
print_set_stats(&dataset);
// Chunks
{
let mut data = vec![];
for dataset in dataset.chunks(500_000) {
serialize_u128(|| dataset.iter().cloned(), dataset.len() as u32, &mut data).unwrap();
}
let compression = data.len() as f64 / (dataset.len() * 16) as f64;
println!("Compression 50_000 chunks {:.4}", compression);
println!(
"Num Bits per elem {:.2}",
(data.len() * 8) as f32 / dataset.len() as f32
);
}
let mut data = vec![];
{
print_time!("creation");
serialize_u128(|| dataset.iter().cloned(), dataset.len() as u32, &mut data).unwrap();
}
let compression = data.len() as f64 / (dataset.len() * 16) as f64;
println!("Compression {:.2}", compression);
println!(
"Num Bits per elem {:.2}",
(data.len() * 8) as f32 / dataset.len() as f32
);
let decompressor = open_u128::<u128>(OwnedBytes::new(data)).unwrap();
// Sample some ranges
let mut doc_values = Vec::new();
for value in dataset.iter().take(1110).skip(1100).cloned() {
doc_values.clear();
print_time!("get range");
decompressor.get_docids_for_value_range(
value..=value,
0..decompressor.num_vals(),
&mut doc_values,
);
println!("{:?}", doc_values.len());
}
}
fn main() {
if env::args().nth(1).unwrap() == "bench_ip" {
bench_ip();
return;
}
let mut table = Table::new();
// Add a row per time
table.add_row(row!["", "Compression Ratio", "Compression Estimation"]);
for (data, data_set_name) in get_codec_test_data_sets() {
let results: Vec<(f32, f32, FastFieldCodecType)> = [
serialize_with_codec(&data, FastFieldCodecType::Bitpacked),
serialize_with_codec(&data, FastFieldCodecType::Linear),
serialize_with_codec(&data, FastFieldCodecType::BlockwiseLinear),
]
.into_iter()
.flatten()
.collect();
let best_compression_ratio_codec = results
.iter()
.min_by(|&res1, &res2| res1.partial_cmp(res2).unwrap())
.cloned()
.unwrap();
table.add_row(Row::new(vec![Cell::new(data_set_name).style_spec("Bbb")]));
for (est, comp, codec_type) in results {
let est_cell = est.to_string();
let ratio_cell = comp.to_string();
let style = if comp == best_compression_ratio_codec.1 {
"Fb"
} else {
""
};
table.add_row(Row::new(vec![
Cell::new(&format!("{codec_type:?}")).style_spec("bFg"),
Cell::new(&ratio_cell).style_spec(style),
Cell::new(&est_cell).style_spec(""),
]));
}
}
table.printstd();
}
pub fn get_codec_test_data_sets() -> Vec<(Vec<u64>, &'static str)> {
let mut data_and_names = vec![];
let data = (1000..=200_000_u64).collect::<Vec<_>>();
data_and_names.push((data, "Autoincrement"));
let mut current_cumulative = 0;
let data = (1..=200_000_u64)
.map(|num| {
let num = (num as f32 + num as f32).log10() as u64;
current_cumulative += num;
current_cumulative
})
.collect::<Vec<_>>();
// let data = (1..=200000_u64).map(|num| num + num).collect::<Vec<_>>();
data_and_names.push((data, "Monotonically increasing concave"));
let mut current_cumulative = 0;
let data = (1..=200_000_u64)
.map(|num| {
let num = (200_000.0 - num as f32).log10() as u64;
current_cumulative += num;
current_cumulative
})
.collect::<Vec<_>>();
data_and_names.push((data, "Monotonically increasing convex"));
let data = (1000..=200_000_u64)
.map(|num| num + rand::random::<u8>() as u64)
.collect::<Vec<_>>();
data_and_names.push((data, "Almost monotonically increasing"));
data_and_names
}
pub fn serialize_with_codec(
data: &[u64],
codec_type: FastFieldCodecType,
) -> Option<(f32, f32, FastFieldCodecType)> {
let col = VecColumn::from(data);
let estimation = fastfield_codecs::estimate(&col, codec_type)?;
let mut out = Vec::new();
fastfield_codecs::serialize(&col, &mut out, &[codec_type]).ok()?;
let actual_compression = out.len() as f32 / (col.num_vals() * 8) as f32;
Some((estimation, actual_compression, codec_type))
}

41
columnar/src/column_values/merge.rs
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@@ -1,41 +0,0 @@
use std::fmt::Debug;
use std::sync::Arc;
use crate::iterable::Iterable;
use crate::{ColumnIndex, ColumnValues, MergeRowOrder};
pub(crate) struct MergedColumnValues<'a, T> {
pub(crate) column_indexes: &'a [Option<ColumnIndex>],
pub(crate) column_values: &'a [Option<Arc<dyn ColumnValues<T>>>],
pub(crate) merge_row_order: &'a MergeRowOrder,
}
impl<'a, T: Copy + PartialOrd + Debug> Iterable<T> for MergedColumnValues<'a, T> {
fn boxed_iter(&self) -> Box<dyn Iterator<Item = T> + '_> {
match self.merge_row_order {
MergeRowOrder::Stack(_) => Box::new(
self.column_values
.iter()
.flatten()
.flat_map(|column_value| column_value.iter()),
),
MergeRowOrder::Shuffled(shuffle_merge_order) => Box::new(
shuffle_merge_order
.iter_new_to_old_row_addrs()
.flat_map(|row_addr| {
let column_index =
self.column_indexes[row_addr.segment_ord as usize].as_ref()?;
let column_values =
self.column_values[row_addr.segment_ord as usize].as_ref()?;
let value_range = column_index.value_row_ids(row_addr.row_id);
Some((value_range, column_values))
})
.flat_map(|(value_range, column_values)| {
value_range
.into_iter()
.map(|val| column_values.get_val(val))
}),
),
}
}
}

343
columnar/src/column_values/mod.rs
View File

@@ -1,4 +1,5 @@
#![warn(missing_docs)]
#![cfg_attr(all(feature = "unstable", test), feature(test))]
//! # `fastfield_codecs`
//!
@@ -7,214 +8,206 @@
//! - Monotonically map values to u64/u128
use std::fmt::Debug;
use std::ops::{Range, RangeInclusive};
use std::io;
use std::io::Write;
use std::sync::Arc;
use common::{BinarySerializable, OwnedBytes};
use compact_space::CompactSpaceDecompressor;
pub use monotonic_mapping::{MonotonicallyMappableToU64, StrictlyMonotonicFn};
use monotonic_mapping::{StrictlyMonotonicMappingInverter, StrictlyMonotonicMappingToInternal};
pub use monotonic_mapping_u128::MonotonicallyMappableToU128;
use serialize::U128Header;
mod merge;
mod compact_space;
pub(crate) mod monotonic_mapping;
pub(crate) mod monotonic_mapping_u128;
mod stats;
mod u128_based;
mod u64_based;
mod vec_column;
pub(crate) mod u64_based;
mod monotonic_column;
mod column;
pub mod serialize;
pub(crate) use merge::MergedColumnValues;
pub use stats::ColumnStats;
pub use u128_based::{open_u128_mapped, serialize_column_values_u128};
pub use serialize::serialize_column_values_u128;
pub use stats::Stats;
pub use u64_based::{
load_u64_based_column_values, serialize_and_load_u64_based_column_values,
serialize_u64_based_column_values, CodecType, ALL_U64_CODEC_TYPES,
};
pub use vec_column::VecColumn;
pub use self::monotonic_column::monotonic_map_column;
use crate::RowId;
pub use self::column::{monotonic_map_column, ColumnValues, IterColumn, VecColumn};
/// `ColumnValues` provides access to a dense field column.
///
/// `Column` are just a wrapper over `ColumnValues` and a `ColumnIndex`.
///
/// Any methods with a default and specialized implementation need to be called in the
/// wrappers that implement the trait: Arc and MonotonicMappingColumn
pub trait ColumnValues<T: PartialOrd = u64>: Send + Sync {
/// Return the value associated with the given idx.
///
/// This accessor should return as fast as possible.
///
/// # Panics
///
/// May panic if `idx` is greater than the column length.
fn get_val(&self, idx: u32) -> T;
#[derive(PartialEq, Eq, PartialOrd, Ord, Debug, Clone, Copy)]
#[repr(u8)]
/// Available codecs to use to encode the u128 (via [`MonotonicallyMappableToU128`]) converted data.
pub enum U128FastFieldCodecType {
/// This codec takes a large number space (u128) and reduces it to a compact number space, by
/// removing the holes.
CompactSpace = 1,
}
/// Allows to push down multiple fetch calls, to avoid dynamic dispatch overhead.
///
/// idx and output should have the same length
///
/// # Panics
///
/// May panic if `idx` is greater than the column length.
fn get_vals(&self, idx: &[u32], output: &mut [T]) {
assert!(idx.len() == output.len());
for (out, idx) in output.iter_mut().zip(idx.iter()) {
*out = self.get_val(*idx as u32);
}
impl BinarySerializable for U128FastFieldCodecType {
fn serialize<W: Write + ?Sized>(&self, wrt: &mut W) -> io::Result<()> {
self.to_code().serialize(wrt)
}
/// Fills an output buffer with the fast field values
/// associated with the `DocId` going from
/// `start` to `start + output.len()`.
///
/// # Panics
///
/// Must panic if `start + output.len()` is greater than
/// the segment's `maxdoc`.
#[inline(always)]
fn get_range(&self, start: u64, output: &mut [T]) {
for (out, idx) in output.iter_mut().zip(start..) {
*out = self.get_val(idx as u32);
}
}
/// Get the row ids of values which are in the provided value range.
///
/// Note that position == docid for single value fast fields
#[inline(always)]
fn get_row_ids_for_value_range(
&self,
value_range: RangeInclusive<T>,
row_id_range: Range<RowId>,
row_id_hits: &mut Vec<RowId>,
) {
let row_id_range = row_id_range.start..row_id_range.end.min(self.num_vals());
for idx in row_id_range.start..row_id_range.end {
let val = self.get_val(idx);
if value_range.contains(&val) {
row_id_hits.push(idx);
}
}
}
/// Returns the minimum value for this fast field.
///
/// This min_value may not be exact.
/// For instance, the min value does not take in account of possible
/// deleted document. All values are however guaranteed to be higher than
/// `.min_value()`.
fn min_value(&self) -> T;
/// Returns the maximum value for this fast field.
///
/// This max_value may not be exact.
/// For instance, the max value does not take in account of possible
/// deleted document. All values are however guaranteed to be higher than
/// `.max_value()`.
fn max_value(&self) -> T;
/// The number of values in the column.
fn num_vals(&self) -> u32;
/// Returns a iterator over the data
fn iter<'a>(&'a self) -> Box<dyn Iterator<Item = T> + 'a> {
Box::new((0..self.num_vals()).map(|idx| self.get_val(idx)))
fn deserialize<R: io::Read>(reader: &mut R) -> io::Result<Self> {
let code = u8::deserialize(reader)?;
let codec_type: Self = Self::from_code(code)
.ok_or_else(|| io::Error::new(io::ErrorKind::InvalidData, "Unknown code `{code}.`"))?;
Ok(codec_type)
}
}
impl<T: Copy + PartialOrd + Debug> ColumnValues<T> for Arc<dyn ColumnValues<T>> {
#[inline(always)]
fn get_val(&self, idx: u32) -> T {
self.as_ref().get_val(idx)
impl U128FastFieldCodecType {
pub(crate) fn to_code(self) -> u8 {
self as u8
}
#[inline(always)]
fn min_value(&self) -> T {
self.as_ref().min_value()
}
#[inline(always)]
fn max_value(&self) -> T {
self.as_ref().max_value()
}
#[inline(always)]
fn num_vals(&self) -> u32 {
self.as_ref().num_vals()
}
#[inline(always)]
fn iter<'b>(&'b self) -> Box<dyn Iterator<Item = T> + 'b> {
self.as_ref().iter()
}
#[inline(always)]
fn get_range(&self, start: u64, output: &mut [T]) {
self.as_ref().get_range(start, output)
}
#[inline(always)]
fn get_row_ids_for_value_range(
&self,
range: RangeInclusive<T>,
doc_id_range: Range<u32>,
positions: &mut Vec<u32>,
) {
self.as_ref()
.get_row_ids_for_value_range(range, doc_id_range, positions)
pub(crate) fn from_code(code: u8) -> Option<Self> {
match code {
1 => Some(Self::CompactSpace),
_ => None,
}
}
}
/// Wraps an cloneable iterator into a `Column`.
pub struct IterColumn<T>(T);
/// Returns the correct codec reader wrapped in the `Arc` for the data.
pub fn open_u128_mapped<T: MonotonicallyMappableToU128 + Debug>(
mut bytes: OwnedBytes,
) -> io::Result<Arc<dyn ColumnValues<T>>> {
let header = U128Header::deserialize(&mut bytes)?;
assert_eq!(header.codec_type, U128FastFieldCodecType::CompactSpace);
let reader = CompactSpaceDecompressor::open(bytes)?;
impl<T> From<T> for IterColumn<T>
where T: Iterator + Clone + ExactSizeIterator
{
fn from(iter: T) -> Self {
IterColumn(iter)
}
}
impl<T> ColumnValues<T::Item> for IterColumn<T>
where
T: Iterator + Clone + ExactSizeIterator + Send + Sync,
T::Item: PartialOrd + Debug,
{
fn get_val(&self, idx: u32) -> T::Item {
self.0.clone().nth(idx as usize).unwrap()
}
fn min_value(&self) -> T::Item {
self.0.clone().next().unwrap()
}
fn max_value(&self) -> T::Item {
self.0.clone().last().unwrap()
}
fn num_vals(&self) -> u32 {
self.0.len() as u32
}
fn iter(&self) -> Box<dyn Iterator<Item = T::Item> + '_> {
Box::new(self.0.clone())
}
let inverted: StrictlyMonotonicMappingInverter<StrictlyMonotonicMappingToInternal<T>> =
StrictlyMonotonicMappingToInternal::<T>::new().into();
Ok(Arc::new(monotonic_map_column(reader, inverted)))
}
#[cfg(all(test, feature = "unstable"))]
mod bench;
mod bench {
use std::sync::Arc;
use common::OwnedBytes;
use rand::rngs::StdRng;
use rand::{Rng, SeedableRng};
use test::{self, Bencher};
#[cfg(test)]
mod tests {
use super::*;
#[test]
fn test_range_as_col() {
let col = IterColumn::from(10..100);
assert_eq!(col.num_vals(), 90);
assert_eq!(col.max_value(), 99);
fn get_data() -> Vec<u64> {
let mut rng = StdRng::seed_from_u64(2u64);
let mut data: Vec<_> = (100..55000_u64)
.map(|num| num + rng.gen::<u8>() as u64)
.collect();
data.push(99_000);
data.insert(1000, 2000);
data.insert(2000, 100);
data.insert(3000, 4100);
data.insert(4000, 100);
data.insert(5000, 800);
data
}
#[inline(never)]
fn value_iter() -> impl Iterator<Item = u64> {
0..20_000
}
fn get_reader_for_bench<Codec: FastFieldCodec>(data: &[u64]) -> Codec::Reader {
let mut bytes = Vec::new();
let min_value = *data.iter().min().unwrap();
let data = data.iter().map(|el| *el - min_value).collect::<Vec<_>>();
let col = VecColumn::from(&data);
let normalized_header = NormalizedHeader {
num_vals: col.num_vals(),
max_value: col.max_value(),
};
Codec::serialize(&VecColumn::from(&data), &mut bytes).unwrap();
Codec::open_from_bytes(OwnedBytes::new(bytes), normalized_header).unwrap()
}
fn bench_get<Codec: FastFieldCodec>(b: &mut Bencher, data: &[u64]) {
let col = get_reader_for_bench::<Codec>(data);
b.iter(|| {
let mut sum = 0u64;
for pos in value_iter() {
let val = col.get_val(pos as u32);
sum = sum.wrapping_add(val);
}
sum
});
}
#[inline(never)]
fn bench_get_dynamic_helper(b: &mut Bencher, col: Arc<dyn ColumnValues>) {
b.iter(|| {
let mut sum = 0u64;
for pos in value_iter() {
let val = col.get_val(pos as u32);
sum = sum.wrapping_add(val);
}
sum
});
}
fn bench_get_dynamic<Codec: FastFieldCodec>(b: &mut Bencher, data: &[u64]) {
let col = Arc::new(get_reader_for_bench::<Codec>(data));
bench_get_dynamic_helper(b, col);
}
fn bench_create<Codec: FastFieldCodec>(b: &mut Bencher, data: &[u64]) {
let min_value = *data.iter().min().unwrap();
let data = data.iter().map(|el| *el - min_value).collect::<Vec<_>>();
let mut bytes = Vec::new();
b.iter(|| {
bytes.clear();
Codec::serialize(&VecColumn::from(&data), &mut bytes).unwrap();
});
}
#[bench]
fn bench_fastfield_bitpack_create(b: &mut Bencher) {
let data: Vec<_> = get_data();
bench_create::<BitpackedCodec>(b, &data);
}
#[bench]
fn bench_fastfield_linearinterpol_create(b: &mut Bencher) {
let data: Vec<_> = get_data();
bench_create::<LinearCodec>(b, &data);
}
#[bench]
fn bench_fastfield_multilinearinterpol_create(b: &mut Bencher) {
let data: Vec<_> = get_data();
bench_create::<BlockwiseLinearCodec>(b, &data);
}
#[bench]
fn bench_fastfield_bitpack_get(b: &mut Bencher) {
let data: Vec<_> = get_data();
bench_get::<BitpackedCodec>(b, &data);
}
#[bench]
fn bench_fastfield_bitpack_get_dynamic(b: &mut Bencher) {
let data: Vec<_> = get_data();
bench_get_dynamic::<BitpackedCodec>(b, &data);
}
#[bench]
fn bench_fastfield_linearinterpol_get(b: &mut Bencher) {
let data: Vec<_> = get_data();
bench_get::<LinearCodec>(b, &data);
}
#[bench]
fn bench_fastfield_linearinterpol_get_dynamic(b: &mut Bencher) {
let data: Vec<_> = get_data();
bench_get_dynamic::<LinearCodec>(b, &data);
}
#[bench]
fn bench_fastfield_multilinearinterpol_get(b: &mut Bencher) {
let data: Vec<_> = get_data();
bench_get::<BlockwiseLinearCodec>(b, &data);
}
#[bench]
fn bench_fastfield_multilinearinterpol_get_dynamic(b: &mut Bencher) {
let data: Vec<_> = get_data();
bench_get_dynamic::<BlockwiseLinearCodec>(b, &data);
}
}

120
columnar/src/column_values/monotonic_column.rs
View File

@@ -1,120 +0,0 @@
use std::fmt::Debug;
use std::marker::PhantomData;
use std::ops::{Range, RangeInclusive};
use crate::column_values::monotonic_mapping::StrictlyMonotonicFn;
use crate::ColumnValues;
struct MonotonicMappingColumn<C, T, Input> {
from_column: C,
monotonic_mapping: T,
_phantom: PhantomData<Input>,
}
/// Creates a view of a column transformed by a strictly monotonic mapping. See
/// [`StrictlyMonotonicFn`].
///
/// E.g. apply a gcd monotonic_mapping([100, 200, 300]) == [1, 2, 3]
/// monotonic_mapping.mapping() is expected to be injective, and we should always have
/// monotonic_mapping.inverse(monotonic_mapping.mapping(el)) == el
///
/// The inverse of the mapping is required for:
/// `fn get_positions_for_value_range(&self, range: RangeInclusive<T>) -> Vec<u64> `
/// The user provides the original value range and we need to monotonic map them in the same way the
/// serialization does before calling the underlying column.
///
/// Note that when opening a codec, the monotonic_mapping should be the inverse of the mapping
/// during serialization. And therefore the monotonic_mapping_inv when opening is the same as
/// monotonic_mapping during serialization.
pub fn monotonic_map_column<C, T, Input, Output>(
from_column: C,
monotonic_mapping: T,
) -> impl ColumnValues<Output>
where
C: ColumnValues<Input>,
T: StrictlyMonotonicFn<Input, Output> + Send + Sync,
Input: PartialOrd + Debug + Send + Sync + Clone,
Output: PartialOrd + Debug + Send + Sync + Clone,
{
MonotonicMappingColumn {
from_column,
monotonic_mapping,
_phantom: PhantomData,
}
}
impl<C, T, Input, Output> ColumnValues<Output> for MonotonicMappingColumn<C, T, Input>
where
C: ColumnValues<Input>,
T: StrictlyMonotonicFn<Input, Output> + Send + Sync,
Input: PartialOrd + Send + Debug + Sync + Clone,
Output: PartialOrd + Send + Debug + Sync + Clone,
{
#[inline]
fn get_val(&self, idx: u32) -> Output {
let from_val = self.from_column.get_val(idx);
self.monotonic_mapping.mapping(from_val)
}
fn min_value(&self) -> Output {
let from_min_value = self.from_column.min_value();
self.monotonic_mapping.mapping(from_min_value)
}
fn max_value(&self) -> Output {
let from_max_value = self.from_column.max_value();
self.monotonic_mapping.mapping(from_max_value)
}
fn num_vals(&self) -> u32 {
self.from_column.num_vals()
}
fn iter(&self) -> Box<dyn Iterator<Item = Output> + '_> {
Box::new(
self.from_column
.iter()
.map(|el| self.monotonic_mapping.mapping(el)),
)
}
fn get_row_ids_for_value_range(
&self,
range: RangeInclusive<Output>,
doc_id_range: Range<u32>,
positions: &mut Vec<u32>,
) {
self.from_column.get_row_ids_for_value_range(
self.monotonic_mapping.inverse(range.start().clone())
..=self.monotonic_mapping.inverse(range.end().clone()),
doc_id_range,
positions,
)
}
// We voluntarily do not implement get_range as it yields a regression,
// and we do not have any specialized implementation anyway.
}
#[cfg(test)]
mod tests {
use super::*;
use crate::column_values::monotonic_mapping::{
StrictlyMonotonicMappingInverter, StrictlyMonotonicMappingToInternal,
};
use crate::column_values::VecColumn;
#[test]
fn test_monotonic_mapping_iter() {
let vals: Vec<u64> = (0..100u64).map(|el| el * 10).collect();
let col = VecColumn::from(&vals);
let mapped = monotonic_map_column(
col,
StrictlyMonotonicMappingInverter::from(StrictlyMonotonicMappingToInternal::<i64>::new()),
);
let val_i64s: Vec<u64> = mapped.iter().collect();
for i in 0..100 {
assert_eq!(val_i64s[i as usize], mapped.get_val(i));
}
}
}

76
columnar/src/column_values/monotonic_mapping.rs
View File

@@ -1,7 +1,7 @@
use std::fmt::Debug;
use std::marker::PhantomData;
use common::DateTime;
use fastdivide::DividerU64;
use super::MonotonicallyMappableToU128;
use crate::RowId;
@@ -112,6 +112,65 @@ where T: MonotonicallyMappableToU64
}
}
/// Mapping dividing by gcd and a base value.
///
/// The function is assumed to be only called on values divided by passed
/// gcd value. (It is necessary for the function to be monotonic.)
pub(crate) struct StrictlyMonotonicMappingToInternalGCDBaseval {
gcd_divider: DividerU64,
gcd: u64,
min_value: u64,
}
impl StrictlyMonotonicMappingToInternalGCDBaseval {
pub(crate) fn new(gcd: u64, min_value: u64) -> Self {
let gcd_divider = DividerU64::divide_by(gcd);
Self {
gcd_divider,
gcd,
min_value,
}
}
}
impl<External: MonotonicallyMappableToU64> StrictlyMonotonicFn<External, u64>
for StrictlyMonotonicMappingToInternalGCDBaseval
{
#[inline(always)]
fn mapping(&self, inp: External) -> u64 {
self.gcd_divider
.divide(External::to_u64(inp) - self.min_value)
}
#[inline(always)]
fn inverse(&self, out: u64) -> External {
External::from_u64(self.min_value + out * self.gcd)
}
}
/// Strictly monotonic mapping with a base value.
pub(crate) struct StrictlyMonotonicMappingToInternalBaseval {
min_value: u64,
}
impl StrictlyMonotonicMappingToInternalBaseval {
#[inline(always)]
pub(crate) fn new(min_value: u64) -> Self {
Self { min_value }
}
}
impl<External: MonotonicallyMappableToU64> StrictlyMonotonicFn<External, u64>
for StrictlyMonotonicMappingToInternalBaseval
{
#[inline(always)]
fn mapping(&self, val: External) -> u64 {
External::to_u64(val) - self.min_value
}
#[inline(always)]
fn inverse(&self, val: u64) -> External {
External::from_u64(self.min_value + val)
}
}
impl MonotonicallyMappableToU64 for u64 {
#[inline(always)]
fn to_u64(self) -> u64 {
@@ -136,15 +195,17 @@ impl MonotonicallyMappableToU64 for i64 {
}
}
impl MonotonicallyMappableToU64 for DateTime {
impl MonotonicallyMappableToU64 for crate::DateTime {
#[inline(always)]
fn to_u64(self) -> u64 {
common::i64_to_u64(self.into_timestamp_micros())
common::i64_to_u64(self.timestamp_micros)
}
#[inline(always)]
fn from_u64(val: u64) -> Self {
DateTime::from_timestamp_micros(common::u64_to_i64(val))
crate::DateTime {
timestamp_micros: common::u64_to_i64(val),
}
}
}
@@ -200,6 +261,13 @@ mod tests {
// TODO
// identity mapping
// test_round_trip(&StrictlyMonotonicMappingToInternal::<u128>::new(), 100u128);
// base value to i64 round trip
let mapping = StrictlyMonotonicMappingToInternalBaseval::new(100);
test_round_trip::<_, _, u64>(&mapping, 100i64);
// base value and gcd to u64 round trip
let mapping = StrictlyMonotonicMappingToInternalGCDBaseval::new(10, 100);
test_round_trip::<_, _, u64>(&mapping, 100u64);
}
fn test_round_trip<T: StrictlyMonotonicFn<K, L>, K: std::fmt::Debug + Eq + Copy, L>(

88
columnar/src/column_values/u128_based/mod.rs → columnar/src/column_values/serialize.rs
View File

@@ -1,19 +1,25 @@
use std::fmt::Debug;
use std::io;
use std::io::Write;
use std::sync::Arc;
mod compact_space;
use common::{BinarySerializable, VInt};
use common::{BinarySerializable, OwnedBytes, VInt};
use compact_space::{CompactSpaceCompressor, CompactSpaceDecompressor};
use crate::column_values::monotonic_map_column;
use crate::column_values::monotonic_mapping::{
StrictlyMonotonicMappingInverter, StrictlyMonotonicMappingToInternal,
};
use crate::column_values::compact_space::CompactSpaceCompressor;
use crate::column_values::U128FastFieldCodecType;
use crate::iterable::Iterable;
use crate::{ColumnValues, MonotonicallyMappableToU128};
use crate::MonotonicallyMappableToU128;
/// The normalized header gives some parameters after applying the following
/// normalization of the vector:
/// `val -> (val - min_value) / gcd`
///
/// By design, after normalization, `min_value = 0` and `gcd = 1`.
#[derive(Debug, Copy, Clone)]
pub struct NormalizedHeader {
/// The number of values in the underlying column.
pub num_vals: u32,
/// The max value of the underlying column.
pub max_value: u64,
}
#[derive(Debug, Copy, Clone, PartialEq, Eq)]
pub(crate) struct U128Header {
@@ -41,18 +47,20 @@ impl BinarySerializable for U128Header {
/// Serializes u128 values with the compact space codec.
pub fn serialize_column_values_u128<T: MonotonicallyMappableToU128>(
iterable: &dyn Iterable<T>,
num_vals: u32,
output: &mut impl io::Write,
) -> io::Result<()> {
let header = U128Header {
num_vals,
codec_type: U128FastFieldCodecType::CompactSpace,
};
header.serialize(output)?;
let compressor = CompactSpaceCompressor::train_from(
iterable
.boxed_iter()
.map(MonotonicallyMappableToU128::to_u128),
num_vals,
);
let header = U128Header {
num_vals: compressor.num_vals(),
codec_type: U128FastFieldCodecType::CompactSpace,
};
header.serialize(output)?;
compressor.compress_into(
iterable
.boxed_iter()
@@ -62,57 +70,11 @@ pub fn serialize_column_values_u128<T: MonotonicallyMappableToU128>(
Ok(())
}
#[derive(PartialEq, Eq, PartialOrd, Ord, Debug, Clone, Copy)]
#[repr(u8)]
/// Available codecs to use to encode the u128 (via [`MonotonicallyMappableToU128`]) converted data.
pub(crate) enum U128FastFieldCodecType {
/// This codec takes a large number space (u128) and reduces it to a compact number space, by
/// removing the holes.
CompactSpace = 1,
}
impl BinarySerializable for U128FastFieldCodecType {
fn serialize<W: Write + ?Sized>(&self, wrt: &mut W) -> io::Result<()> {
self.to_code().serialize(wrt)
}
fn deserialize<R: io::Read>(reader: &mut R) -> io::Result<Self> {
let code = u8::deserialize(reader)?;
let codec_type: Self = Self::from_code(code)
.ok_or_else(|| io::Error::new(io::ErrorKind::InvalidData, "Unknown code `{code}.`"))?;
Ok(codec_type)
}
}
impl U128FastFieldCodecType {
pub(crate) fn to_code(self) -> u8 {
self as u8
}
pub(crate) fn from_code(code: u8) -> Option<Self> {
match code {
1 => Some(Self::CompactSpace),
_ => None,
}
}
}
/// Returns the correct codec reader wrapped in the `Arc` for the data.
pub fn open_u128_mapped<T: MonotonicallyMappableToU128 + Debug>(
mut bytes: OwnedBytes,
) -> io::Result<Arc<dyn ColumnValues<T>>> {
let header = U128Header::deserialize(&mut bytes)?;
assert_eq!(header.codec_type, U128FastFieldCodecType::CompactSpace);
let reader = CompactSpaceDecompressor::open(bytes)?;
let inverted: StrictlyMonotonicMappingInverter<StrictlyMonotonicMappingToInternal<T>> =
StrictlyMonotonicMappingToInternal::<T>::new().into();
Ok(Arc::new(monotonic_map_column(reader, inverted)))
}
#[cfg(test)]
pub mod tests {
use super::*;
use crate::column_values::u64_based::{
serialize_and_load_u64_based_column_values, serialize_u64_based_column_values,
self, serialize_and_load_u64_based_column_values, serialize_u64_based_column_values,
ALL_U64_CODEC_TYPES,
};
use crate::column_values::CodecType;

27
columnar/src/column_values/stats.rs
View File

@@ -6,28 +6,21 @@ use common::{BinarySerializable, VInt};
use crate::RowId;
/// Column statistics.
#[derive(Debug, Clone, Eq, PartialEq)]
pub struct ColumnStats {
/// GCD of the elements `el - min(column)`.
pub struct Stats {
pub gcd: NonZeroU64,
/// Minimum value of the column.
pub min_value: u64,
/// Maximum value of the column.
pub max_value: u64,
/// Number of rows in the column.
pub num_rows: RowId,
}
impl ColumnStats {
/// Amplitude of value.
/// Difference between the maximum and the minimum value.
impl Stats {
pub fn amplitude(&self) -> u64 {
self.max_value - self.min_value
}
}
impl BinarySerializable for ColumnStats {
impl BinarySerializable for Stats {
fn serialize<W: Write + ?Sized>(&self, writer: &mut W) -> io::Result<()> {
VInt(self.min_value).serialize(writer)?;
VInt(self.gcd.get()).serialize(writer)?;
@@ -44,7 +37,7 @@ impl BinarySerializable for ColumnStats {
let amplitude = VInt::deserialize(reader)?.0 * gcd.get();
let max_value = min_value + amplitude;
let num_rows = VInt::deserialize(reader)?.0 as RowId;
Ok(ColumnStats {
Ok(Stats {
min_value,
max_value,
num_rows,
@@ -59,21 +52,21 @@ mod tests {
use common::BinarySerializable;
use crate::column_values::ColumnStats;
use crate::column_values::Stats;
#[track_caller]
fn test_stats_ser_deser_aux(stats: &ColumnStats, num_bytes: usize) {
fn test_stats_ser_deser_aux(stats: &Stats, num_bytes: usize) {
let mut buffer: Vec<u8> = Vec::new();
stats.serialize(&mut buffer).unwrap();
assert_eq!(buffer.len(), num_bytes);
let deser_stats = ColumnStats::deserialize(&mut &buffer[..]).unwrap();
let deser_stats = Stats::deserialize(&mut &buffer[..]).unwrap();
assert_eq!(stats, &deser_stats);
}
#[test]
fn test_stats_serialization() {
test_stats_ser_deser_aux(
&(ColumnStats {
&(Stats {
gcd: NonZeroU64::new(3).unwrap(),
min_value: 1,
max_value: 3001,
@@ -82,7 +75,7 @@ mod tests {
5,
);
test_stats_ser_deser_aux(
&(ColumnStats {
&(Stats {
gcd: NonZeroU64::new(1_000).unwrap(),
min_value: 1,
max_value: 3001,
@@ -91,7 +84,7 @@ mod tests {
5,
);
test_stats_ser_deser_aux(
&(ColumnStats {
&(Stats {
gcd: NonZeroU64::new(1).unwrap(),
min_value: 0,
max_value: 0,

16
columnar/src/column_values/u64_based/bitpacked.rs
View File

@@ -4,7 +4,7 @@ use common::{BinarySerializable, OwnedBytes};
use fastdivide::DividerU64;
use tantivy_bitpacker::{compute_num_bits, BitPacker, BitUnpacker};
use crate::column_values::u64_based::{ColumnCodec, ColumnCodecEstimator, ColumnStats};
use crate::column_values::u64_based::{ColumnCodec, ColumnCodecEstimator, Stats};
use crate::{ColumnValues, RowId};
/// Depending on the field type, a different
@@ -13,7 +13,7 @@ use crate::{ColumnValues, RowId};
pub struct BitpackedReader {
data: OwnedBytes,
bit_unpacker: BitUnpacker,
stats: ColumnStats,
stats: Stats,
}
impl ColumnValues for BitpackedReader {
@@ -36,7 +36,7 @@ impl ColumnValues for BitpackedReader {
}
}
fn num_bits(stats: &ColumnStats) -> u8 {
fn num_bits(stats: &Stats) -> u8 {
compute_num_bits(stats.amplitude() / stats.gcd)
}
@@ -46,14 +46,14 @@ pub struct BitpackedCodecEstimator;
impl ColumnCodecEstimator for BitpackedCodecEstimator {
fn collect(&mut self, _value: u64) {}
fn estimate(&self, stats: &ColumnStats) -> Option<u64> {
fn estimate(&self, stats: &Stats) -> Option<u64> {
let num_bits_per_value = num_bits(stats);
Some(stats.num_bytes() + (stats.num_rows as u64 * (num_bits_per_value as u64) + 7) / 8)
}
fn serialize(
&self,
stats: &ColumnStats,
stats: &Stats,
vals: &mut dyn Iterator<Item = u64>,
wrt: &mut dyn Write,
) -> io::Result<()> {
@@ -72,12 +72,12 @@ impl ColumnCodecEstimator for BitpackedCodecEstimator {
pub struct BitpackedCodec;
impl ColumnCodec for BitpackedCodec {
type ColumnValues = BitpackedReader;
type Reader = BitpackedReader;
type Estimator = BitpackedCodecEstimator;
/// Opens a fast field given a file.
fn load(mut data: OwnedBytes) -> io::Result<Self::ColumnValues> {
let stats = ColumnStats::deserialize(&mut data)?;
fn load(mut data: OwnedBytes) -> io::Result<Self::Reader> {
let stats = Stats::deserialize(&mut data)?;
let num_bits = num_bits(&stats);
let bit_unpacker = BitUnpacker::new(num_bits);
Ok(BitpackedReader {

18
columnar/src/column_values/u64_based/blockwise_linear.rs
View File

@@ -7,7 +7,7 @@ use fastdivide::DividerU64;
use tantivy_bitpacker::{compute_num_bits, BitPacker, BitUnpacker};
use crate::column_values::u64_based::line::Line;
use crate::column_values::u64_based::{ColumnCodec, ColumnCodecEstimator, ColumnStats};
use crate::column_values::u64_based::{ColumnCodec, ColumnCodecEstimator, Stats};
use crate::column_values::{ColumnValues, VecColumn};
use crate::MonotonicallyMappableToU64;
@@ -84,7 +84,7 @@ impl ColumnCodecEstimator for BlockwiseLinearEstimator {
self.block.clear();
}
}
fn estimate(&self, stats: &ColumnStats) -> Option<u64> {
fn estimate(&self, stats: &Stats) -> Option<u64> {
let mut estimate = 4 + stats.num_bytes() + self.meta_num_bytes + self.values_num_bytes;
if stats.gcd.get() > 1 {
let estimate_gain_from_gcd =
@@ -100,7 +100,7 @@ impl ColumnCodecEstimator for BlockwiseLinearEstimator {
fn serialize(
&self,
stats: &ColumnStats,
stats: &Stats,
mut vals: &mut dyn Iterator<Item = u64>,
wrt: &mut dyn Write,
) -> io::Result<()> {
@@ -165,12 +165,12 @@ impl ColumnCodecEstimator for BlockwiseLinearEstimator {
pub struct BlockwiseLinearCodec;
impl ColumnCodec<u64> for BlockwiseLinearCodec {
type ColumnValues = BlockwiseLinearReader;
type Reader = BlockwiseLinearReader;
type Estimator = BlockwiseLinearEstimator;
fn load(mut bytes: OwnedBytes) -> io::Result<Self::ColumnValues> {
let stats = ColumnStats::deserialize(&mut bytes)?;
fn load(mut bytes: OwnedBytes) -> io::Result<Self::Reader> {
let stats = Stats::deserialize(&mut bytes)?;
let footer_len: u32 = (&bytes[bytes.len() - 4..]).deserialize()?;
let footer_offset = bytes.len() - 4 - footer_len as usize;
let (data, mut footer) = bytes.split(footer_offset);
@@ -195,14 +195,14 @@ impl ColumnCodec<u64> for BlockwiseLinearCodec {
pub struct BlockwiseLinearReader {
blocks: Arc<[Block]>,
data: OwnedBytes,
stats: ColumnStats,
stats: Stats,
}
impl ColumnValues for BlockwiseLinearReader {
#[inline(always)]
fn get_val(&self, idx: u32) -> u64 {
let block_id = (idx / BLOCK_SIZE) as usize;
let idx_within_block = idx % BLOCK_SIZE;
let block_id = (idx / BLOCK_SIZE as u32) as usize;
let idx_within_block = idx % (BLOCK_SIZE as u32);
let block = &self.blocks[block_id];
let interpoled_val: u64 = block.line.eval(idx_within_block);
let block_bytes = &self.data[block.data_start_offset..];

13
columnar/src/column_values/u64_based/line.rs
View File

@@ -67,6 +67,19 @@ impl Line {
self.intercept.wrapping_add(linear_part)
}
// Same as train, but the intercept is only estimated from provided sample positions
pub fn estimate(sample_positions_and_values: &[(u64, u64)]) -> Self {
let first_val = sample_positions_and_values[0].1;
let last_val = sample_positions_and_values[sample_positions_and_values.len() - 1].1;
let num_vals = sample_positions_and_values[sample_positions_and_values.len() - 1].0 + 1;
Self::train_from(
first_val,
last_val,
num_vals as u32,
sample_positions_and_values.iter().cloned(),
)
}
// Intercept is only computed from provided positions
pub fn train_from(
first_val: u64,

16
columnar/src/column_values/u64_based/linear.rs
View File

@@ -5,9 +5,9 @@ use tantivy_bitpacker::{compute_num_bits, BitPacker, BitUnpacker};
use super::line::Line;
use super::ColumnValues;
use crate::column_values::u64_based::{ColumnCodec, ColumnCodecEstimator, ColumnStats};
use crate::column_values::u64_based::{ColumnCodec, ColumnCodecEstimator, Stats};
use crate::column_values::VecColumn;
use crate::RowId;
use crate::{MonotonicallyMappableToU64, RowId};
const HALF_SPACE: u64 = u64::MAX / 2;
const LINE_ESTIMATION_BLOCK_LEN: usize = 512;
@@ -18,7 +18,7 @@ const LINE_ESTIMATION_BLOCK_LEN: usize = 512;
pub struct LinearReader {
data: OwnedBytes,
linear_params: LinearParams,
stats: ColumnStats,
stats: Stats,
}
impl ColumnValues for LinearReader {
@@ -106,7 +106,7 @@ impl ColumnCodecEstimator for LinearCodecEstimator {
}
}
fn estimate(&self, stats: &ColumnStats) -> Option<u64> {
fn estimate(&self, stats: &Stats) -> Option<u64> {
let line = self.line?;
let amplitude = self.max_deviation - self.min_deviation;
let num_bits = compute_num_bits(amplitude);
@@ -123,7 +123,7 @@ impl ColumnCodecEstimator for LinearCodecEstimator {
fn serialize(
&self,
stats: &ColumnStats,
stats: &Stats,
vals: &mut dyn Iterator<Item = u64>,
wrt: &mut dyn io::Write,
) -> io::Result<()> {
@@ -184,12 +184,12 @@ impl LinearCodecEstimator {
}
impl ColumnCodec for LinearCodec {
type ColumnValues = LinearReader;
type Reader = LinearReader;
type Estimator = LinearCodecEstimator;
fn load(mut data: OwnedBytes) -> io::Result<Self::ColumnValues> {
let stats = ColumnStats::deserialize(&mut data)?;
fn load(mut data: OwnedBytes) -> io::Result<Self::Reader> {
let stats = Stats::deserialize(&mut data)?;
let linear_params = LinearParams::deserialize(&mut data)?;
Ok(LinearReader {
stats,

54
columnar/src/column_values/u64_based/mod.rs
View File

@@ -13,61 +13,35 @@ use common::{BinarySerializable, OwnedBytes};
use crate::column_values::monotonic_mapping::{
StrictlyMonotonicMappingInverter, StrictlyMonotonicMappingToInternal,
};
pub use crate::column_values::u64_based::bitpacked::BitpackedCodec;
pub use crate::column_values::u64_based::blockwise_linear::BlockwiseLinearCodec;
pub use crate::column_values::u64_based::linear::LinearCodec;
pub use crate::column_values::u64_based::stats_collector::StatsCollector;
use crate::column_values::{monotonic_map_column, ColumnStats};
use crate::column_values::u64_based::bitpacked::BitpackedCodec;
use crate::column_values::u64_based::blockwise_linear::BlockwiseLinearCodec;
use crate::column_values::u64_based::linear::LinearCodec;
use crate::column_values::u64_based::stats_collector::StatsCollector;
use crate::column_values::{monotonic_map_column, Stats};
use crate::iterable::Iterable;
use crate::{ColumnValues, MonotonicallyMappableToU64};
/// A `ColumnCodecEstimator` is in charge of gathering all
/// data required to serialize a column.
///
/// This happens during a first pass on data of the column elements.
/// During that pass, all column estimators receive a call to their
/// `.collect(el)`.
///
/// After this first pass, finalize is called.
/// `.estimate(..)` then should return an accurate estimation of the
/// size of the serialized column (were we to pick this codec.).
/// `.serialize(..)` then serializes the column using this codec.
pub trait ColumnCodecEstimator<T = u64>: 'static {
/// Records a new value for estimation.
/// This method will be called for each element of the column during
/// `estimation`.
fn collect(&mut self, value: u64);
/// Finalizes the first pass phase.
fn estimate(&self, stats: &Stats) -> Option<u64>;
fn finalize(&mut self) {}
/// Returns an accurate estimation of the number of bytes that will
/// be used to represent this column.
fn estimate(&self, stats: &ColumnStats) -> Option<u64>;
/// Serializes the column using the given codec.
/// This constitutes a second pass over the columns values.
fn serialize(
&self,
stats: &ColumnStats,
stats: &Stats,
vals: &mut dyn Iterator<Item = T>,
wrt: &mut dyn io::Write,
) -> io::Result<()>;
}
/// A column codec describes a colunm serialization format.
pub trait ColumnCodec<T: PartialOrd = u64> {
/// Specialized `ColumnValues` type.
type ColumnValues: ColumnValues<T> + 'static;
/// `Estimator` for the given codec.
type Reader: ColumnValues<T> + 'static;
type Estimator: ColumnCodecEstimator + Default;
/// Loads a column that has been serialized using this codec.
fn load(bytes: OwnedBytes) -> io::Result<Self::ColumnValues>;
fn load(bytes: OwnedBytes) -> io::Result<Self::Reader>;
/// Returns an estimator.
fn estimator() -> Self::Estimator {
Self::Estimator::default()
}
/// Returns a boxed estimator.
fn boxed_estimator() -> Box<dyn ColumnCodecEstimator> {
Box::new(Self::estimator())
}
@@ -88,7 +62,6 @@ pub enum CodecType {
BlockwiseLinear = 2u8,
}
/// List of all available u64-base codecs.
pub const ALL_U64_CODEC_TYPES: [CodecType; 3] = [
CodecType::Bitpacked,
CodecType::Linear,
@@ -133,7 +106,6 @@ fn load_specific_codec<C: ColumnCodec, T: MonotonicallyMappableToU64>(
}
impl CodecType {
/// Returns a boxed codec estimator associated to a given `CodecType`.
pub fn estimator(&self) -> Box<dyn ColumnCodecEstimator> {
match self {
CodecType::Bitpacked => BitpackedCodec::boxed_estimator(),
@@ -143,8 +115,7 @@ impl CodecType {
}
}
/// Serializes a given column of u64-mapped values.
pub fn serialize_u64_based_column_values<T: MonotonicallyMappableToU64>(
pub fn serialize_u64_based_column_values<'a, T: MonotonicallyMappableToU64>(
vals: &dyn Iterable<T>,
codec_types: &[CodecType],
wrt: &mut dyn Write,
@@ -185,14 +156,11 @@ pub fn serialize_u64_based_column_values<T: MonotonicallyMappableToU64>(
Ok(())
}
/// Load u64-based column values.
///
/// This method first identifies the codec off the first byte.
pub fn load_u64_based_column_values<T: MonotonicallyMappableToU64>(
mut bytes: OwnedBytes,
) -> io::Result<Arc<dyn ColumnValues<T>>> {
let codec_type: CodecType = bytes
.first()
.get(0)
.copied()
.and_then(CodecType::try_from_code)
.ok_or_else(|| io::Error::new(io::ErrorKind::InvalidData, "Failed to read codec type"))?;

22
columnar/src/column_values/u64_based/stats_collector.rs
View File

@@ -2,7 +2,7 @@ use std::num::NonZeroU64;
use fastdivide::DividerU64;
use crate::column_values::ColumnStats;
use crate::column_values::Stats;
use crate::RowId;
/// Compute the gcd of two non null numbers.
@@ -33,14 +33,14 @@ pub struct StatsCollector {
}
impl StatsCollector {
pub fn stats(&self) -> ColumnStats {
pub fn stats(&self) -> Stats {
let (min_value, max_value) = self.min_max_opt.unwrap_or((0u64, 0u64));
let increment_gcd = if let Some((increment_gcd, _)) = self.increment_gcd_opt {
increment_gcd
} else {
NonZeroU64::new(1u64).unwrap()
};
ColumnStats {
Stats {
min_value,
max_value,
num_rows: self.num_rows,
@@ -97,9 +97,9 @@ mod tests {
use std::num::NonZeroU64;
use crate::column_values::u64_based::stats_collector::{compute_gcd, StatsCollector};
use crate::column_values::u64_based::ColumnStats;
use crate::column_values::u64_based::Stats;
fn compute_stats(vals: impl Iterator<Item = u64>) -> ColumnStats {
fn compute_stats(vals: impl Iterator<Item = u64>) -> Stats {
let mut stats_collector = StatsCollector::default();
for val in vals {
stats_collector.collect(val);
@@ -144,7 +144,7 @@ mod tests {
fn test_stats() {
assert_eq!(
compute_stats([].into_iter()),
ColumnStats {
Stats {
gcd: NonZeroU64::new(1).unwrap(),
min_value: 0,
max_value: 0,
@@ -153,7 +153,7 @@ mod tests {
);
assert_eq!(
compute_stats([0, 1].into_iter()),
ColumnStats {
Stats {
gcd: NonZeroU64::new(1).unwrap(),
min_value: 0,
max_value: 1,
@@ -162,7 +162,7 @@ mod tests {
);
assert_eq!(
compute_stats([0, 1].into_iter()),
ColumnStats {
Stats {
gcd: NonZeroU64::new(1).unwrap(),
min_value: 0,
max_value: 1,
@@ -171,7 +171,7 @@ mod tests {
);
assert_eq!(
compute_stats([10, 20, 30].into_iter()),
ColumnStats {
Stats {
gcd: NonZeroU64::new(10).unwrap(),
min_value: 10,
max_value: 30,
@@ -180,7 +180,7 @@ mod tests {
);
assert_eq!(
compute_stats([10, 50, 10, 30].into_iter()),
ColumnStats {
Stats {
gcd: NonZeroU64::new(20).unwrap(),
min_value: 10,
max_value: 50,
@@ -189,7 +189,7 @@ mod tests {
);
assert_eq!(
compute_stats([10, 0, 30].into_iter()),
ColumnStats {
Stats {
gcd: NonZeroU64::new(10).unwrap(),
min_value: 0,
max_value: 30,

60
columnar/src/column_values/u64_based/tests.rs
View File

@@ -1,6 +1,6 @@
use proptest::prelude::*;
use proptest::strategy::Strategy;
use proptest::{num, prop_oneof, proptest};
use proptest::{prop_oneof, proptest};
#[test]
fn test_serialize_and_load_simple() {
@@ -19,62 +19,6 @@ fn test_serialize_and_load_simple() {
assert_eq!(col.get_val(1), 2);
assert_eq!(col.get_val(2), 5);
}
#[test]
fn test_empty_column_i64() {
let vals: [i64; 0] = [];
let mut num_acceptable_codecs = 0;
for codec in ALL_U64_CODEC_TYPES {
let mut buffer = Vec::new();
if serialize_u64_based_column_values(&&vals[..], &[codec], &mut buffer).is_err() {
continue;
}
num_acceptable_codecs += 1;
let col = load_u64_based_column_values::<i64>(OwnedBytes::new(buffer)).unwrap();
assert_eq!(col.num_vals(), 0);
assert_eq!(col.min_value(), i64::MIN);
assert_eq!(col.max_value(), i64::MIN);
}
assert!(num_acceptable_codecs > 0);
}
#[test]
fn test_empty_column_u64() {
let vals: [u64; 0] = [];
let mut num_acceptable_codecs = 0;
for codec in ALL_U64_CODEC_TYPES {
let mut buffer = Vec::new();
if serialize_u64_based_column_values(&&vals[..], &[codec], &mut buffer).is_err() {
continue;
}
num_acceptable_codecs += 1;
let col = load_u64_based_column_values::<u64>(OwnedBytes::new(buffer)).unwrap();
assert_eq!(col.num_vals(), 0);
assert_eq!(col.min_value(), u64::MIN);
assert_eq!(col.max_value(), u64::MIN);
}
assert!(num_acceptable_codecs > 0);
}
#[test]
fn test_empty_column_f64() {
let vals: [f64; 0] = [];
let mut num_acceptable_codecs = 0;
for codec in ALL_U64_CODEC_TYPES {
let mut buffer = Vec::new();
if serialize_u64_based_column_values(&&vals[..], &[codec], &mut buffer).is_err() {
continue;
}
num_acceptable_codecs += 1;
let col = load_u64_based_column_values::<f64>(OwnedBytes::new(buffer)).unwrap();
assert_eq!(col.num_vals(), 0);
// FIXME. f64::MIN would be better!
assert!(col.min_value().is_nan());
assert!(col.max_value().is_nan());
}
assert!(num_acceptable_codecs > 0);
}
pub(crate) fn create_and_validate<TColumnCodec: ColumnCodec>(
vals: &[u64],
name: &str,
@@ -116,7 +60,7 @@ pub(crate) fn create_and_validate<TColumnCodec: ColumnCodec>(
.map(|(pos, _)| pos as u32)
.collect();
let mut positions = Vec::new();
reader.get_row_ids_for_value_range(
reader.get_docids_for_value_range(
vals[test_rand_idx]..=vals[test_rand_idx],
0..vals.len() as u32,
&mut positions,

52
columnar/src/column_values/vec_column.rs
View File

@@ -1,52 +0,0 @@
use std::fmt::Debug;
use tantivy_bitpacker::minmax;
use crate::ColumnValues;
/// VecColumn provides `Column` over a slice.
pub struct VecColumn<'a, T = u64> {
pub(crate) values: &'a [T],
pub(crate) min_value: T,
pub(crate) max_value: T,
}
impl<'a, T: Copy + PartialOrd + Send + Sync + Debug> ColumnValues<T> for VecColumn<'a, T> {
fn get_val(&self, position: u32) -> T {
self.values[position as usize]
}
fn iter(&self) -> Box<dyn Iterator<Item = T> + '_> {
Box::new(self.values.iter().copied())
}
fn min_value(&self) -> T {
self.min_value
}
fn max_value(&self) -> T {
self.max_value
}
fn num_vals(&self) -> u32 {
self.values.len() as u32
}
fn get_range(&self, start: u64, output: &mut [T]) {
output.copy_from_slice(&self.values[start as usize..][..output.len()])
}
}
impl<'a, T: Copy + PartialOrd + Default, V> From<&'a V> for VecColumn<'a, T>
where V: AsRef<[T]> + ?Sized
{
fn from(values: &'a V) -> Self {
let values = values.as_ref();
let (min_value, max_value) = minmax(values.iter().copied()).unwrap_or_default();
Self {
values,
min_value,
max_value,
}
}
}

97
columnar/src/columnar/column_type.rs
View File

@@ -1,27 +1,27 @@
use std::fmt::Debug;
use std::net::Ipv6Addr;
use serde::{Deserialize, Serialize};
use crate::value::NumericalType;
use crate::InvalidData;
/// The column type represents the column type.
/// Any changes need to be propagated to `COLUMN_TYPES`.
#[derive(Hash, Eq, PartialEq, Debug, Clone, Copy, Ord, PartialOrd, Serialize, Deserialize)]
/// The column type represents the column type and can fit on 6-bits.
///
/// - bits[0..3]: Column category type.
/// - bits[3..6]: Numerical type if necessary.
#[derive(Hash, Eq, PartialEq, Debug, Clone, Copy, Ord, PartialOrd)]
#[repr(u8)]
pub enum ColumnType {
I64 = 0u8,
U64 = 1u8,
F64 = 2u8,
Bytes = 3u8,
Str = 4u8,
Bool = 5u8,
IpAddr = 6u8,
DateTime = 7u8,
Bytes = 10u8,
Str = 14u8,
Bool = 18u8,
IpAddr = 22u8,
DateTime = 26u8,
}
// The order needs to match _exactly_ the order in the enum
#[cfg(test)]
const COLUMN_TYPES: [ColumnType; 8] = [
ColumnType::I64,
ColumnType::U64,
@@ -39,7 +39,18 @@ impl ColumnType {
}
pub(crate) fn try_from_code(code: u8) -> Result<ColumnType, InvalidData> {
COLUMN_TYPES.get(code as usize).copied().ok_or(InvalidData)
use ColumnType::*;
match code {
0u8 => Ok(I64),
1u8 => Ok(U64),
2u8 => Ok(F64),
10u8 => Ok(Bytes),
14u8 => Ok(Str),
18u8 => Ok(Bool),
22u8 => Ok(IpAddr),
26u8 => Ok(Self::DateTime),
_ => Err(InvalidData),
}
}
}
@@ -113,7 +124,7 @@ impl HasAssociatedColumnType for bool {
}
}
impl HasAssociatedColumnType for common::DateTime {
impl HasAssociatedColumnType for crate::DateTime {
fn column_type() -> ColumnType {
ColumnType::DateTime
}
@@ -132,20 +143,70 @@ impl HasAssociatedColumnType for Ipv6Addr {
}
}
/// Column types are grouped into different categories that
/// corresponds to the different types of `JsonValue` types.
///
/// The columnar writer will apply coercion rules to make sure that
/// at most one column exist per `ColumnTypeCategory`.
///
/// See also [README.md].
#[derive(Copy, Clone, Ord, PartialOrd, Eq, PartialEq, Hash, Debug)]
#[repr(u8)]
pub enum ColumnTypeCategory {
Bool,
Str,
Numerical,
DateTime,
Bytes,
IpAddr,
}
impl From<ColumnType> for ColumnTypeCategory {
fn from(column_type: ColumnType) -> Self {
match column_type {
ColumnType::I64 => ColumnTypeCategory::Numerical,
ColumnType::U64 => ColumnTypeCategory::Numerical,
ColumnType::F64 => ColumnTypeCategory::Numerical,
ColumnType::Bytes => ColumnTypeCategory::Bytes,
ColumnType::Str => ColumnTypeCategory::Str,
ColumnType::Bool => ColumnTypeCategory::Bool,
ColumnType::IpAddr => ColumnTypeCategory::IpAddr,
ColumnType::DateTime => ColumnTypeCategory::DateTime,
}
}
}
#[cfg(test)]
mod tests {
use std::collections::HashSet;
use super::*;
use crate::Cardinality;
#[test]
fn test_column_type_to_code() {
for (code, expected_column_type) in super::COLUMN_TYPES.iter().copied().enumerate() {
if let Ok(column_type) = ColumnType::try_from_code(code as u8) {
assert_eq!(column_type, expected_column_type);
let mut column_type_set: HashSet<ColumnType> = HashSet::new();
for code in u8::MIN..=u8::MAX {
if let Ok(column_type) = ColumnType::try_from_code(code) {
assert_eq!(column_type.to_code(), code);
assert!(column_type_set.insert(column_type));
}
}
for code in COLUMN_TYPES.len() as u8..=u8::MAX {
assert!(ColumnType::try_from_code(code).is_err());
assert_eq!(column_type_set.len(), super::COLUMN_TYPES.len());
}
#[test]
fn test_column_category_sort_consistent_with_column_type_sort() {
// This is a very important property because we
// we need to serialize colunmn in the right order.
let mut column_types: Vec<ColumnType> = super::COLUMN_TYPES.iter().copied().collect();
column_types.sort_by_key(|col| col.to_code());
let column_categories: Vec<ColumnTypeCategory> = column_types
.into_iter()
.map(ColumnTypeCategory::from)
.collect();
for (prev, next) in column_categories.iter().zip(column_categories.iter()) {
assert!(prev <= next);
}
}

6
columnar/src/columnar/format_version.rs
View File

@@ -4,7 +4,7 @@ pub const VERSION_FOOTER_NUM_BYTES: usize = MAGIC_BYTES.len() + std::mem::size_o
/// We end the file by these 4 bytes just to somewhat identify that
/// this is indeed a columnar file.
const MAGIC_BYTES: [u8; 4] = [2, 113, 119, 66];
const MAGIC_BYTES: [u8; 4] = [2, 113, 119, 066];
pub fn footer() -> [u8; VERSION_FOOTER_NUM_BYTES] {
let mut footer_bytes = [0u8; VERSION_FOOTER_NUM_BYTES];
@@ -27,8 +27,8 @@ pub enum Version {
}
impl Version {
fn to_bytes(self) -> [u8; 4] {
(self as u32).to_le_bytes()
fn to_bytes(&self) -> [u8; 4] {
(*self as u32).to_le_bytes()
}
fn try_from_bytes(bytes: [u8; 4]) -> Result<Version, InvalidData> {

152
columnar/src/columnar/merge/merge_dict_column.rs
View File

@@ -1,130 +1,68 @@
use std::io::{self, Write};
use common::{BitSet, CountingWriter, ReadOnlyBitSet};
use common::CountingWriter;
use sstable::{SSTable, TermOrdinal};
use super::term_merger::TermMerger;
use crate::column::serialize_column_mappable_to_u64;
use crate::column_index::SerializableColumnIndex;
use crate::iterable::Iterable;
use crate::{BytesColumn, MergeRowOrder, ShuffleMergeOrder};
use crate::BytesColumn;
// Serialize [Dictionary, Column, dictionary num bytes U32::LE]
// Column: [Column Index, Column Values, column index num bytes U32::LE]
pub fn merge_bytes_or_str_column(
column_index: SerializableColumnIndex<'_>,
bytes_columns: &[Option<BytesColumn>],
merge_row_order: &MergeRowOrder,
bytes_columns: &[BytesColumn],
output: &mut impl Write,
) -> io::Result<()> {
// Serialize dict and generate mapping for values
let mut output = CountingWriter::wrap(output);
// TODO !!! Remove useless terms.
let term_ord_mapping = serialize_merged_dict(bytes_columns, merge_row_order, &mut output)?;
let term_ord_mapping = serialize_merged_dict(bytes_columns, &mut output)?;
let dictionary_num_bytes: u32 = output.written_bytes() as u32;
let output = output.finish();
let remapped_term_ordinals_values = RemappedTermOrdinalsValues {
bytes_columns,
term_ord_mapping: &term_ord_mapping,
merge_row_order,
};
serialize_column_mappable_to_u64(column_index, &remapped_term_ordinals_values, output)?;
// serialize_bytes_or_str_column(column_index, bytes_columns, &term_ord_mapping, output)?;
output.write_all(&dictionary_num_bytes.to_le_bytes())?;
Ok(())
}
struct RemappedTermOrdinalsValues<'a> {
bytes_columns: &'a [Option<BytesColumn>],
bytes_columns: &'a [BytesColumn],
term_ord_mapping: &'a TermOrdinalMapping,
merge_row_order: &'a MergeRowOrder,
}
impl<'a> Iterable for RemappedTermOrdinalsValues<'a> {
fn boxed_iter(&self) -> Box<dyn Iterator<Item = u64> + '_> {
match self.merge_row_order {
MergeRowOrder::Stack(_) => self.boxed_iter_stacked(),
MergeRowOrder::Shuffled(shuffle_merge_order) => {
self.boxed_iter_shuffled(shuffle_merge_order)
}
}
}
}
impl<'a> RemappedTermOrdinalsValues<'a> {
fn boxed_iter_stacked(&self) -> Box<dyn Iterator<Item = u64> + '_> {
let iter = self
.bytes_columns
.iter()
.enumerate()
.flat_map(|(segment_ord, byte_column)| {
let segment_ord = self.term_ord_mapping.get_segment(segment_ord as u32);
byte_column.iter().flat_map(move |bytes_column| {
bytes_column
.ords()
.values
.iter()
.map(move |term_ord| segment_ord[term_ord as usize])
})
let segment_ord = self.term_ord_mapping.get_segment(segment_ord);
byte_column
.ords()
.values
.iter()
.map(move |term_ord| segment_ord[term_ord as usize])
});
// TODO see if we can better decompose the mapping / and the stacking
Box::new(iter)
}
fn boxed_iter_shuffled<'b>(
&'b self,
shuffle_merge_order: &'b ShuffleMergeOrder,
) -> Box<dyn Iterator<Item = u64> + 'b> {
Box::new(
shuffle_merge_order
.iter_new_to_old_row_addrs()
.flat_map(move |old_addr| {
let segment_ord = self.term_ord_mapping.get_segment(old_addr.segment_ord);
self.bytes_columns[old_addr.segment_ord as usize]
.as_ref()
.into_iter()
.flat_map(move |bytes_column| {
bytes_column
.term_ords(old_addr.row_id)
.map(|old_term_ord: u64| segment_ord[old_term_ord as usize])
})
}),
)
}
}
fn compute_term_bitset(column: &BytesColumn, row_bitset: &ReadOnlyBitSet) -> BitSet {
let num_terms = column.dictionary().num_terms();
let mut term_bitset = BitSet::with_max_value(num_terms as u32);
for row_id in row_bitset.iter() {
for term_ord in column.term_ord_column.values_for_doc(row_id) {
term_bitset.insert(term_ord as u32);
}
}
term_bitset
}
fn is_term_present(bitsets: &[Option<BitSet>], term_merger: &TermMerger) -> bool {
for (segment_ord, from_term_ord) in term_merger.matching_segments() {
if let Some(bitset) = bitsets[segment_ord].as_ref() {
if bitset.contains(from_term_ord as u32) {
return true;
}
} else {
return true;
}
}
false
}
fn serialize_merged_dict(
bytes_columns: &[Option<BytesColumn>],
merge_row_order: &MergeRowOrder,
bytes_columns: &[BytesColumn],
output: &mut impl Write,
) -> io::Result<TermOrdinalMapping> {
let mut term_ord_mapping = TermOrdinalMapping::default();
let mut field_term_streams = Vec::new();
for column in bytes_columns.iter().flatten() {
for column in bytes_columns {
term_ord_mapping.add_segment(column.dictionary.num_terms());
let terms = column.dictionary.stream()?;
field_term_streams.push(terms);
@@ -133,57 +71,21 @@ fn serialize_merged_dict(
let mut merged_terms = TermMerger::new(field_term_streams);
let mut sstable_builder = sstable::VoidSSTable::writer(output);
// TODO support complex `merge_row_order`.
match merge_row_order {
MergeRowOrder::Stack(_) => {
let mut current_term_ord = 0;
while merged_terms.advance() {
let term_bytes: &[u8] = merged_terms.key();
sstable_builder.insert(term_bytes, &())?;
for (segment_ord, from_term_ord) in merged_terms.matching_segments() {
term_ord_mapping.register_from_to(segment_ord, from_term_ord, current_term_ord);
}
current_term_ord += 1;
}
sstable_builder.finish()?;
}
MergeRowOrder::Shuffled(shuffle_merge_order) => {
assert_eq!(shuffle_merge_order.alive_bitsets.len(), bytes_columns.len());
let mut term_bitsets: Vec<Option<BitSet>> = Vec::with_capacity(bytes_columns.len());
for (alive_bitset_opt, bytes_column_opt) in shuffle_merge_order
.alive_bitsets
.iter()
.zip(bytes_columns.iter())
{
match (alive_bitset_opt, bytes_column_opt) {
(Some(alive_bitset), Some(bytes_column)) => {
let term_bitset = compute_term_bitset(bytes_column, alive_bitset);
term_bitsets.push(Some(term_bitset));
}
_ => {
term_bitsets.push(None);
}
}
}
let mut current_term_ord = 0;
while merged_terms.advance() {
let term_bytes: &[u8] = merged_terms.key();
if !is_term_present(&term_bitsets[..], &merged_terms) {
continue;
}
sstable_builder.insert(term_bytes, &())?;
for (segment_ord, from_term_ord) in merged_terms.matching_segments() {
term_ord_mapping.register_from_to(segment_ord, from_term_ord, current_term_ord);
}
current_term_ord += 1;
}
sstable_builder.finish()?;
let mut current_term_ord = 0;
while merged_terms.advance() {
let term_bytes: &[u8] = merged_terms.key();
sstable_builder.insert(term_bytes, &())?;
for (segment_ord, from_term_ord) in merged_terms.matching_segments() {
term_ord_mapping.register_from_to(segment_ord, from_term_ord, current_term_ord);
}
current_term_ord += 1;
}
sstable_builder.finish()?;
Ok(term_ord_mapping)
}
#[derive(Default, Debug)]
#[derive(Default)]
struct TermOrdinalMapping {
per_segment_new_term_ordinals: Vec<Vec<TermOrdinal>>,
}
@@ -191,14 +93,14 @@ struct TermOrdinalMapping {
impl TermOrdinalMapping {
fn add_segment(&mut self, max_term_ord: usize) {
self.per_segment_new_term_ordinals
.push(vec![TermOrdinal::default(); max_term_ord]);
.push(vec![TermOrdinal::default(); max_term_ord as usize]);
}
fn register_from_to(&mut self, segment_ord: usize, from_ord: TermOrdinal, to_ord: TermOrdinal) {
self.per_segment_new_term_ordinals[segment_ord][from_ord as usize] = to_ord;
}
fn get_segment(&self, segment_ord: u32) -> &[TermOrdinal] {
&(self.per_segment_new_term_ordinals[segment_ord as usize])[..]
fn get_segment(&self, segment_ord: usize) -> &[TermOrdinal] {
&(self.per_segment_new_term_ordinals[segment_ord])[..]
}
}

72
columnar/src/columnar/merge/merge_mapping.rs
View File

@@ -1,8 +1,6 @@
use std::ops::Range;
use common::{BitSet, OwnedBytes, ReadOnlyBitSet};
use crate::{ColumnarReader, RowAddr, RowId};
use crate::{column, ColumnarReader, RowId};
pub struct StackMergeOrder {
// This does not start at 0. The first row is the number of
@@ -44,75 +42,19 @@ pub enum MergeRowOrder {
/// rows [r0..n_row_0) contains the row of columnar_readers[0], in ordder
/// rows [n_row_0..n_row_0 + n_row_1 contains the row of columnar_readers[1], in order.
/// ..
/// No documents is deleted.
Stack(StackMergeOrder),
/// Some more complex mapping, that may interleaves rows from the different readers and
/// drop rows, or do both.
Shuffled(ShuffleMergeOrder),
}
impl From<StackMergeOrder> for MergeRowOrder {
fn from(stack_merge_order: StackMergeOrder) -> MergeRowOrder {
MergeRowOrder::Stack(stack_merge_order)
}
}
impl From<ShuffleMergeOrder> for MergeRowOrder {
fn from(shuffle_merge_order: ShuffleMergeOrder) -> MergeRowOrder {
MergeRowOrder::Shuffled(shuffle_merge_order)
}
/// Some more complex mapping, that can interleaves rows from the different readers and
/// possibly drop rows.
Complex(()),
}
impl MergeRowOrder {
pub fn num_rows(&self) -> RowId {
match self {
MergeRowOrder::Stack(stack_row_order) => stack_row_order.num_rows(),
MergeRowOrder::Shuffled(complex_mapping) => complex_mapping.num_rows(),
MergeRowOrder::Complex(_) => {
todo!()
}
}
}
}
pub struct ShuffleMergeOrder {
pub new_row_id_to_old_row_id: Vec<RowAddr>,
pub alive_bitsets: Vec<Option<ReadOnlyBitSet>>,
}
impl ShuffleMergeOrder {
pub fn for_test(
segment_num_rows: &[RowId],
new_row_id_to_old_row_id: Vec<RowAddr>,
) -> ShuffleMergeOrder {
let mut alive_bitsets: Vec<BitSet> = segment_num_rows
.iter()
.map(|&num_rows| BitSet::with_max_value(num_rows))
.collect();
for &RowAddr {
segment_ord,
row_id,
} in &new_row_id_to_old_row_id
{
alive_bitsets[segment_ord as usize].insert(row_id);
}
let alive_bitsets: Vec<Option<ReadOnlyBitSet>> = alive_bitsets
.into_iter()
.map(|alive_bitset| {
let mut buffer = Vec::new();
alive_bitset.serialize(&mut buffer).unwrap();
let data = OwnedBytes::new(buffer);
Some(ReadOnlyBitSet::open(data))
})
.collect();
ShuffleMergeOrder {
new_row_id_to_old_row_id,
alive_bitsets,
}
}
pub fn num_rows(&self) -> RowId {
self.new_row_id_to_old_row_id.len() as RowId
}
pub fn iter_new_to_old_row_addrs(&self) -> impl Iterator<Item = RowAddr> + '_ {
self.new_row_id_to_old_row_id.iter().copied()
}
}

348
columnar/src/columnar/merge/mod.rs
View File

@@ -2,95 +2,42 @@ mod merge_dict_column;
mod merge_mapping;
mod term_merger;
// mod sorted_doc_id_column;
use std::collections::{BTreeMap, HashMap, HashSet};
use std::io;
use std::net::Ipv6Addr;
use std::sync::Arc;
pub use merge_mapping::{MergeRowOrder, ShuffleMergeOrder, StackMergeOrder};
pub use merge_mapping::{MergeRowOrder, StackMergeOrder};
use super::writer::ColumnarSerializer;
use crate::column::{serialize_column_mappable_to_u128, serialize_column_mappable_to_u64};
use crate::column_values::MergedColumnValues;
use crate::column_index::stack_column_index;
use crate::columnar::column_type::ColumnTypeCategory;
use crate::columnar::merge::merge_dict_column::merge_bytes_or_str_column;
use crate::columnar::writer::CompatibleNumericalTypes;
use crate::columnar::ColumnarReader;
use crate::dynamic_column::DynamicColumn;
use crate::{
BytesColumn, Column, ColumnIndex, ColumnType, ColumnValues, NumericalType, NumericalValue,
BytesColumn, Column, ColumnIndex, ColumnType, ColumnValues, MonotonicallyMappableToU128,
NumericalType, NumericalValue,
};
/// Column types are grouped into different categories.
/// After merge, all columns belonging to the same category are coerced to
/// the same column type.
///
/// In practise, today, only Numerical colummns are coerced into one type today.
///
/// See also [README.md].
#[derive(Copy, Clone, Eq, PartialEq, Hash, Debug)]
enum ColumnTypeCategory {
Bool,
Str,
Numerical,
DateTime,
Bytes,
IpAddr,
}
impl From<ColumnType> for ColumnTypeCategory {
fn from(column_type: ColumnType) -> Self {
match column_type {
ColumnType::I64 => ColumnTypeCategory::Numerical,
ColumnType::U64 => ColumnTypeCategory::Numerical,
ColumnType::F64 => ColumnTypeCategory::Numerical,
ColumnType::Bytes => ColumnTypeCategory::Bytes,
ColumnType::Str => ColumnTypeCategory::Str,
ColumnType::Bool => ColumnTypeCategory::Bool,
ColumnType::IpAddr => ColumnTypeCategory::IpAddr,
ColumnType::DateTime => ColumnTypeCategory::DateTime,
}
}
}
/// Merge several columnar table together.
///
/// If several columns with the same name are conflicting with the numerical types in the
/// input columnars, the first type compatible out of i64, u64, f64 in that order will be used.
///
/// `require_columns` makes it possible to ensure that some columns will be present in the
/// resulting columnar. When a required column is a numerical column type, one of two things can
/// happen:
/// - If the required column type is compatible with all of the input columnar, the resulsting
/// merged
/// columnar will simply coerce the input column and use the required column type.
/// - If the required column type is incompatible with one of the input columnar, the merged
/// will fail with an InvalidData error.
///
/// `merge_row_order` makes it possible to remove or reorder row in the resulting
/// `Columnar` table.
///
/// Reminder: a string and a numerical column may bare the same column name. This is not
/// considered a conflict.
pub fn merge_columnar(
columnar_readers: &[&ColumnarReader],
required_columns: &[(String, ColumnType)],
merge_row_order: MergeRowOrder,
mapping: MergeRowOrder,
output: &mut impl io::Write,
) -> io::Result<()> {
let mut serializer = ColumnarSerializer::new(output);
let columns_to_merge = group_columns_for_merge(columnar_readers, required_columns)?;
let columns_to_merge = group_columns_for_merge(columnar_readers)?;
for ((column_name, column_type), columns) in columns_to_merge {
let mut column_serializer =
serializer.serialize_column(column_name.as_bytes(), column_type);
merge_column(
column_type,
columns,
&merge_row_order,
&mut column_serializer,
)?;
merge_column(column_type, columns, &mapping, &mut column_serializer)?;
}
serializer.finalize(merge_row_order.num_rows())?;
serializer.finalize(mapping.num_rows())?;
Ok(())
}
@@ -106,7 +53,7 @@ fn dynamic_column_to_u64_monotonic(dynamic_column: DynamicColumn) -> Option<Colu
}
}
fn merge_column(
pub fn merge_column(
column_type: ColumnType,
columns: Vec<Option<DynamicColumn>>,
merge_row_order: &MergeRowOrder,
@@ -119,256 +66,159 @@ fn merge_column(
| ColumnType::DateTime
| ColumnType::Bool => {
let mut column_indexes: Vec<Option<ColumnIndex>> = Vec::with_capacity(columns.len());
let mut column_values: Vec<Option<Arc<dyn ColumnValues>>> =
Vec::with_capacity(columns.len());
let mut column_values: Vec<Arc<dyn ColumnValues>> = Vec::with_capacity(columns.len());
for dynamic_column_opt in columns {
if let Some(Column { idx, values }) =
dynamic_column_opt.and_then(dynamic_column_to_u64_monotonic)
{
column_indexes.push(Some(idx));
column_values.push(Some(values));
column_values.push(values);
} else {
column_indexes.push(None);
column_values.push(None);
}
}
let merged_column_index =
crate::column_index::merge_column_index(&column_indexes[..], merge_row_order);
let merge_column_values = MergedColumnValues {
column_indexes: &column_indexes[..],
column_values: &column_values[..],
merge_row_order,
};
serialize_column_mappable_to_u64(merged_column_index, &merge_column_values, wrt)?;
crate::column_index::stack_column_index(&column_indexes[..], merge_row_order);
serialize_column_mappable_to_u64(merged_column_index, &&column_values[..], wrt)?;
}
ColumnType::IpAddr => {
let mut column_indexes: Vec<Option<ColumnIndex>> = Vec::with_capacity(columns.len());
let mut column_values: Vec<Option<Arc<dyn ColumnValues<Ipv6Addr>>>> =
let mut column_values: Vec<Arc<dyn ColumnValues<Ipv6Addr>>> =
Vec::with_capacity(columns.len());
let mut num_values = 0;
for dynamic_column_opt in columns {
if let Some(DynamicColumn::IpAddr(Column { idx, values })) = dynamic_column_opt {
num_values += values.num_vals();
column_indexes.push(Some(idx));
column_values.push(Some(values));
column_values.push(values);
} else {
column_indexes.push(None);
column_values.push(None);
}
}
let merged_column_index =
crate::column_index::merge_column_index(&column_indexes[..], merge_row_order);
let merge_column_values = MergedColumnValues {
column_indexes: &column_indexes[..],
column_values: &column_values,
merge_row_order,
};
serialize_column_mappable_to_u128(merged_column_index, &merge_column_values, wrt)?;
crate::column_index::stack_column_index(&column_indexes[..], merge_row_order);
serialize_column_mappable_to_u128(
merged_column_index,
&&column_values[..],
num_values,
wrt,
)?;
}
ColumnType::Bytes | ColumnType::Str => {
let mut column_indexes: Vec<Option<ColumnIndex>> = Vec::with_capacity(columns.len());
let mut bytes_columns: Vec<Option<BytesColumn>> = Vec::with_capacity(columns.len());
let mut bytes_columns: Vec<BytesColumn> = Vec::with_capacity(columns.len());
for dynamic_column_opt in columns {
match dynamic_column_opt {
Some(DynamicColumn::Str(str_column)) => {
column_indexes.push(Some(str_column.term_ord_column.idx.clone()));
bytes_columns.push(Some(str_column.into()));
bytes_columns.push(str_column.into());
}
Some(DynamicColumn::Bytes(bytes_column)) => {
column_indexes.push(Some(bytes_column.term_ord_column.idx.clone()));
bytes_columns.push(Some(bytes_column));
}
_ => {
column_indexes.push(None);
bytes_columns.push(None);
bytes_columns.push(bytes_column);
}
_ => column_indexes.push(None),
}
}
let merged_column_index =
crate::column_index::merge_column_index(&column_indexes[..], merge_row_order);
merge_bytes_or_str_column(merged_column_index, &bytes_columns, merge_row_order, wrt)?;
crate::column_index::stack_column_index(&column_indexes[..], merge_row_order);
merge_bytes_or_str_column(merged_column_index, &bytes_columns, wrt)?;
}
}
Ok(())
}
struct GroupedColumns {
required_column_type: Option<ColumnType>,
columns: Vec<Option<DynamicColumn>>,
column_category: ColumnTypeCategory,
}
impl GroupedColumns {
fn for_category(column_category: ColumnTypeCategory, num_columnars: usize) -> Self {
GroupedColumns {
required_column_type: None,
columns: vec![None; num_columnars],
column_category,
}
}
/// Set the dynamic column for a given columnar.
fn set_column(&mut self, columnar_id: usize, column: DynamicColumn) {
self.columns[columnar_id] = Some(column);
}
/// Force the existence of a column, as well as its type.
fn require_type(&mut self, required_type: ColumnType) -> io::Result<()> {
if let Some(existing_required_type) = self.required_column_type {
if existing_required_type == required_type {
// This was just a duplicate in the `required_columns`.
// Nothing to do.
return Ok(());
} else {
return Err(io::Error::new(
io::ErrorKind::InvalidInput,
"Required column conflicts with another required column of the same type \
category.",
));
}
}
self.required_column_type = Some(required_type);
Ok(())
}
/// Returns the column type after merge.
///
/// This method does not check if the column types can actually be coerced to
/// this type.
fn column_type_after_merge(&self) -> ColumnType {
if let Some(required_type) = self.required_column_type {
return required_type;
}
let column_type: HashSet<ColumnType> = self
.columns
.iter()
.flatten()
.map(|column| column.column_type())
.collect();
if column_type.len() == 1 {
return column_type.into_iter().next().unwrap();
}
// At the moment, only the numerical categorical column type has more than one possible
// column type.
assert_eq!(self.column_category, ColumnTypeCategory::Numerical);
merged_numerical_columns_type(self.columns.iter().flatten()).into()
}
}
/// Returns the type of the merged numerical column.
///
/// This function picks the first numerical type out of i64, u64, f64 (order matters
/// here), that is compatible with all the `columns`.
///
/// # Panics
/// Panics if one of the column is not numerical.
fn merged_numerical_columns_type<'a>(
columns: impl Iterator<Item = &'a DynamicColumn>,
) -> NumericalType {
let mut compatible_numerical_types = CompatibleNumericalTypes::default();
for column in columns {
let (min_value, max_value) =
min_max_if_numerical(column).expect("All columns re required to be numerical");
compatible_numerical_types.accept_value(min_value);
compatible_numerical_types.accept_value(max_value);
}
compatible_numerical_types.to_numerical_type()
}
#[allow(clippy::type_complexity)]
fn group_columns_for_merge(
columnar_readers: &[&ColumnarReader],
required_columns: &[(String, ColumnType)],
) -> io::Result<BTreeMap<(String, ColumnType), Vec<Option<DynamicColumn>>>> {
// Each column name may have multiple types of column associated.
// For merging we are interested in the same column type category since they can be merged.
let mut columns_grouped: HashMap<(String, ColumnTypeCategory), GroupedColumns> = HashMap::new();
let mut columns_grouped: HashMap<(String, ColumnTypeCategory), Vec<Option<DynamicColumn>>> =
HashMap::new();
for &(ref column_name, column_type) in required_columns {
columns_grouped
.entry((column_name.clone(), column_type.into()))
.or_insert_with(|| {
GroupedColumns::for_category(column_type.into(), columnar_readers.len())
})
.require_type(column_type)?;
}
let num_columnars = columnar_readers.len();
for (columnar_id, columnar_reader) in columnar_readers.iter().enumerate() {
let column_name_and_handle = columnar_reader.list_columns()?;
for (column_name, handle) in column_name_and_handle {
let column_category: ColumnTypeCategory = handle.column_type().into();
let column_type_category: ColumnTypeCategory = handle.column_type().into();
let columns = columns_grouped
.entry((column_name, column_type_category))
.or_insert_with(|| vec![None; num_columnars]);
let column = handle.open()?;
columns_grouped
.entry((column_name, column_category))
.or_insert_with(|| {
GroupedColumns::for_category(column_category, columnar_readers.len())
})
.set_column(columnar_id, column);
columns[columnar_id] = Some(column);
}
}
let mut merge_columns: BTreeMap<(String, ColumnType), Vec<Option<DynamicColumn>>> =
Default::default();
BTreeMap::default();
for ((column_name, _), mut grouped_columns) in columns_grouped {
let column_type = grouped_columns.column_type_after_merge();
coerce_columns(column_type, &mut grouped_columns.columns)?;
merge_columns.insert((column_name, column_type), grouped_columns.columns);
for ((column_name, col_category), mut columns) in columns_grouped {
if col_category == ColumnTypeCategory::Numerical {
coerce_numerical_columns_to_same_type(&mut columns);
}
let column_type = columns
.iter()
.flatten()
.map(|col| col.column_type())
.next()
.unwrap();
merge_columns.insert((column_name, column_type), columns);
}
Ok(merge_columns)
}
fn coerce_columns(
column_type: ColumnType,
columns: &mut [Option<DynamicColumn>],
) -> io::Result<()> {
/// Coerce a set of numerical columns to the same type.
///
/// If all columns are already from the same type, keep this type
/// (even if they could all be coerced to i64).
fn coerce_numerical_columns_to_same_type(columns: &mut [Option<DynamicColumn>]) {
let mut column_types: HashSet<NumericalType> = HashSet::default();
let mut compatible_numerical_types = CompatibleNumericalTypes::default();
for column in columns.iter().flatten() {
let min_value: NumericalValue;
let max_value: NumericalValue;
match column {
DynamicColumn::I64(column) => {
min_value = column.min_value().into();
max_value = column.max_value().into();
}
DynamicColumn::U64(column) => {
min_value = column.min_value().into();
max_value = column.min_value().into();
}
DynamicColumn::F64(column) => {
min_value = column.min_value().into();
max_value = column.min_value().into();
}
DynamicColumn::Bool(_)
| DynamicColumn::IpAddr(_)
| DynamicColumn::DateTime(_)
| DynamicColumn::Bytes(_)
| DynamicColumn::Str(_) => {
panic!("We expected only numerical columns.");
}
}
column_types.insert(column.column_type().numerical_type().unwrap());
compatible_numerical_types.accept_value(min_value);
compatible_numerical_types.accept_value(max_value);
}
if column_types.len() <= 1 {
// No need to do anything. The columns are already all from the same type.
// This is necessary to let use force a given type.
// TODO This works in a world where we do not allow a change of schema,
// but in the future, we will have to pass some kind of schema to enforce
// the logic.
return;
}
let coerce_type = compatible_numerical_types.to_numerical_type();
for column_opt in columns.iter_mut() {
if let Some(column) = column_opt.take() {
*column_opt = Some(coerce_column(column_type, column)?);
*column_opt = column.coerce_numerical(coerce_type);
}
}
Ok(())
}
fn coerce_column(column_type: ColumnType, column: DynamicColumn) -> io::Result<DynamicColumn> {
if let Some(numerical_type) = column_type.numerical_type() {
column
.coerce_numerical(numerical_type)
.ok_or_else(|| io::Error::new(io::ErrorKind::InvalidInput, ""))
} else {
if column.column_type() != column_type {
return Err(io::Error::new(
io::ErrorKind::InvalidInput,
format!(
"Cannot coerce column of type `{:?}` to `{column_type:?}`",
column.column_type()
),
));
}
Ok(column)
}
}
/// Returns the (min, max) of a column provided it is numerical (i64, u64. f64).
///
/// The min and the max are simply the numerical value as defined by `ColumnValue::min_value()`,
/// and `ColumnValue::max_value()`.
///
/// It is important to note that these values are only guaranteed to be lower/upper bound
/// (as opposed to min/max value).
/// If a column is empty, the min and max values are currently set to 0.
fn min_max_if_numerical(column: &DynamicColumn) -> Option<(NumericalValue, NumericalValue)> {
match column {
DynamicColumn::I64(column) => Some((column.min_value().into(), column.max_value().into())),
DynamicColumn::U64(column) => Some((column.min_value().into(), column.min_value().into())),
DynamicColumn::F64(column) => Some((column.min_value().into(), column.min_value().into())),
DynamicColumn::Bool(_)
| DynamicColumn::IpAddr(_)
| DynamicColumn::DateTime(_)
| DynamicColumn::Bytes(_)
| DynamicColumn::Str(_) => None,
}
}
#[cfg(test)]

107
columnar/src/columnar/merge/sorted_doc_id_column.rs Normal file
View File

@@ -0,0 +1,107 @@
use std::sync::Arc;
use fastfield_codecs::Column;
use itertools::Itertools;
use crate::indexer::doc_id_mapping::SegmentDocIdMapping;
use crate::SegmentReader;
pub(crate) struct RemappedDocIdColumn<'a> {
doc_id_mapping: &'a SegmentDocIdMapping,
fast_field_readers: Vec<Arc<dyn Column<u64>>>,
min_value: u64,
max_value: u64,
num_vals: u32,
}
fn compute_min_max_val(
u64_reader: &dyn Column<u64>,
segment_reader: &SegmentReader,
) -> Option<(u64, u64)> {
if segment_reader.max_doc() == 0 {
return None;
}
if segment_reader.alive_bitset().is_none() {
// no deleted documents,
// we can use the previous min_val, max_val.
return Some((u64_reader.min_value(), u64_reader.max_value()));
}
// some deleted documents,
// we need to recompute the max / min
segment_reader
.doc_ids_alive()
.map(|doc_id| u64_reader.get_val(doc_id))
.minmax()
.into_option()
}
impl<'a> RemappedDocIdColumn<'a> {
pub(crate) fn new(
readers: &'a [SegmentReader],
doc_id_mapping: &'a SegmentDocIdMapping,
field: &str,
) -> Self {
let (min_value, max_value) = readers
.iter()
.filter_map(|reader| {
let u64_reader: Arc<dyn Column<u64>> =
reader.fast_fields().typed_fast_field_reader(field).expect(
"Failed to find a reader for single fast field. This is a tantivy bug and \
it should never happen.",
);
compute_min_max_val(&*u64_reader, reader)
})
.reduce(|a, b| (a.0.min(b.0), a.1.max(b.1)))
.expect("Unexpected error, empty readers in IndexMerger");
let fast_field_readers = readers
.iter()
.map(|reader| {
let u64_reader: Arc<dyn Column<u64>> =
reader.fast_fields().typed_fast_field_reader(field).expect(
"Failed to find a reader for single fast field. This is a tantivy bug and \
it should never happen.",
);
u64_reader
})
.collect::<Vec<_>>();
RemappedDocIdColumn {
doc_id_mapping,
fast_field_readers,
min_value,
max_value,
num_vals: doc_id_mapping.len() as u32,
}
}
}
impl<'a> Column for RemappedDocIdColumn<'a> {
fn get_val(&self, _doc: u32) -> u64 {
unimplemented!()
}
fn iter(&self) -> Box<dyn Iterator<Item = u64> + '_> {
Box::new(
self.doc_id_mapping
.iter_old_doc_addrs()
.map(|old_doc_addr| {
let fast_field_reader =
&self.fast_field_readers[old_doc_addr.segment_ord as usize];
fast_field_reader.get_val(old_doc_addr.doc_id)
}),
)
}
fn min_value(&self) -> u64 {
self.min_value
}
fn max_value(&self) -> u64 {
self.max_value
}
fn num_vals(&self) -> u32 {
self.num_vals
}
}

169
columnar/src/columnar/merge/sorted_doc_id_multivalue_column.rs Normal file
View File

@@ -0,0 +1,169 @@
use std::cmp;
use fastfield_codecs::Column;
use super::flat_map_with_buffer::FlatMapWithBufferIter;
use crate::fastfield::{MultiValueIndex, MultiValuedFastFieldReader};
use crate::indexer::doc_id_mapping::SegmentDocIdMapping;
use crate::{DocAddress, SegmentReader};
pub(crate) struct RemappedDocIdMultiValueColumn<'a> {
doc_id_mapping: &'a SegmentDocIdMapping,
fast_field_readers: Vec<MultiValuedFastFieldReader<u64>>,
min_value: u64,
max_value: u64,
num_vals: u32,
}
impl<'a> RemappedDocIdMultiValueColumn<'a> {
pub(crate) fn new(
readers: &'a [SegmentReader],
doc_id_mapping: &'a SegmentDocIdMapping,
field: &str,
) -> Self {
// Our values are bitpacked and we need to know what should be
// our bitwidth and our minimum value before serializing any values.
//
// Computing those is non-trivial if some documents are deleted.
// We go through a complete first pass to compute the minimum and the
// maximum value and initialize our Serializer.
let mut num_vals = 0;
let mut min_value = u64::MAX;
let mut max_value = u64::MIN;
let mut vals = Vec::new();
let mut fast_field_readers = Vec::with_capacity(readers.len());
for reader in readers {
let ff_reader: MultiValuedFastFieldReader<u64> = reader
.fast_fields()
.typed_fast_field_multi_reader::<u64>(field)
.expect(
"Failed to find multivalued fast field reader. This is a bug in tantivy. \
Please report.",
);
for doc in reader.doc_ids_alive() {
ff_reader.get_vals(doc, &mut vals);
for &val in &vals {
min_value = cmp::min(val, min_value);
max_value = cmp::max(val, max_value);
}
num_vals += vals.len();
}
fast_field_readers.push(ff_reader);
// TODO optimize when no deletes
}
if min_value > max_value {
min_value = 0;
max_value = 0;
}
RemappedDocIdMultiValueColumn {
doc_id_mapping,
fast_field_readers,
min_value,
max_value,
num_vals: num_vals as u32,
}
}
}
impl<'a> Column for RemappedDocIdMultiValueColumn<'a> {
fn get_val(&self, _pos: u32) -> u64 {
unimplemented!()
}
fn iter(&self) -> Box<dyn Iterator<Item = u64> + '_> {
Box::new(
self.doc_id_mapping
.iter_old_doc_addrs()
.flat_map_with_buffer(|old_doc_addr: DocAddress, buffer| {
let ff_reader = &self.fast_field_readers[old_doc_addr.segment_ord as usize];
ff_reader.get_vals(old_doc_addr.doc_id, buffer);
}),
)
}
fn min_value(&self) -> u64 {
self.min_value
}
fn max_value(&self) -> u64 {
self.max_value
}
fn num_vals(&self) -> u32 {
self.num_vals
}
}
pub(crate) struct RemappedDocIdMultiValueIndexColumn<'a> {
doc_id_mapping: &'a SegmentDocIdMapping,
multi_value_length_readers: Vec<&'a MultiValueIndex>,
min_value: u64,
max_value: u64,
num_vals: u32,
}
impl<'a> RemappedDocIdMultiValueIndexColumn<'a> {
pub(crate) fn new(
segment_and_ff_readers: &'a [(&'a SegmentReader, &'a MultiValueIndex)],
doc_id_mapping: &'a SegmentDocIdMapping,
) -> Self {
// We go through a complete first pass to compute the minimum and the
// maximum value and initialize our Column.
let mut num_vals = 0;
let min_value = 0;
let mut max_value = 0;
let mut multi_value_length_readers = Vec::with_capacity(segment_and_ff_readers.len());
for segment_and_ff_reader in segment_and_ff_readers {
let segment_reader = segment_and_ff_reader.0;
let multi_value_length_reader = segment_and_ff_reader.1;
if !segment_reader.has_deletes() {
max_value += multi_value_length_reader.total_num_vals() as u64;
} else {
for doc in segment_reader.doc_ids_alive() {
max_value += multi_value_length_reader.num_vals_for_doc(doc) as u64;
}
}
num_vals += segment_reader.num_docs();
multi_value_length_readers.push(multi_value_length_reader);
}
// The value range is always get_val(doc)..get_val(doc + 1)
num_vals += 1;
Self {
doc_id_mapping,
multi_value_length_readers,
min_value,
max_value,
num_vals,
}
}
}
impl<'a> Column for RemappedDocIdMultiValueIndexColumn<'a> {
fn get_val(&self, _pos: u32) -> u64 {
unimplemented!()
}
fn iter(&self) -> Box<dyn Iterator<Item = u64> + '_> {
let mut offset = 0;
Box::new(
std::iter::once(0).chain(self.doc_id_mapping.iter_old_doc_addrs().map(
move |old_doc_addr| {
let ff_reader =
&self.multi_value_length_readers[old_doc_addr.segment_ord as usize];
offset += ff_reader.num_vals_for_doc(old_doc_addr.doc_id);
offset as u64
},
)),
)
}
fn min_value(&self) -> u64 {
self.min_value
}
fn max_value(&self) -> u64 {
self.max_value
}
fn num_vals(&self) -> u32 {
self.num_vals
}
}

86
columnar/src/columnar/merge/tests.rs
View File

@@ -12,7 +12,7 @@ fn make_columnar<T: Into<NumericalValue> + HasAssociatedColumnType + Copy>(
}
let mut buffer: Vec<u8> = Vec::new();
dataframe_writer
.serialize(vals.len() as RowId, None, &mut buffer)
.serialize(vals.len() as RowId, &mut buffer)
.unwrap();
ColumnarReader::open(buffer).unwrap()
}
@@ -24,7 +24,7 @@ fn test_column_coercion_to_u64() {
// u64 type
let columnar2 = make_columnar("numbers", &[u64::MAX]);
let column_map: BTreeMap<(String, ColumnType), Vec<Option<DynamicColumn>>> =
group_columns_for_merge(&[&columnar1, &columnar2], &[]).unwrap();
group_columns_for_merge(&[&columnar1, &columnar2]).unwrap();
assert_eq!(column_map.len(), 1);
assert!(column_map.contains_key(&("numbers".to_string(), ColumnType::U64)));
}
@@ -34,7 +34,7 @@ fn test_column_no_coercion_if_all_the_same() {
let columnar1 = make_columnar("numbers", &[1u64]);
let columnar2 = make_columnar("numbers", &[2u64]);
let column_map: BTreeMap<(String, ColumnType), Vec<Option<DynamicColumn>>> =
group_columns_for_merge(&[&columnar1, &columnar2], &[]).unwrap();
group_columns_for_merge(&[&columnar1, &columnar2]).unwrap();
assert_eq!(column_map.len(), 1);
assert!(column_map.contains_key(&("numbers".to_string(), ColumnType::U64)));
}
@@ -44,74 +44,17 @@ fn test_column_coercion_to_i64() {
let columnar1 = make_columnar("numbers", &[-1i64]);
let columnar2 = make_columnar("numbers", &[2u64]);
let column_map: BTreeMap<(String, ColumnType), Vec<Option<DynamicColumn>>> =
group_columns_for_merge(&[&columnar1, &columnar2], &[]).unwrap();
group_columns_for_merge(&[&columnar1, &columnar2]).unwrap();
assert_eq!(column_map.len(), 1);
assert!(column_map.contains_key(&("numbers".to_string(), ColumnType::I64)));
}
#[test]
fn test_impossible_coercion_returns_an_error() {
let columnar1 = make_columnar("numbers", &[u64::MAX]);
let group_error =
group_columns_for_merge(&[&columnar1], &[("numbers".to_string(), ColumnType::I64)])
.map(|_| ())
.unwrap_err();
assert_eq!(group_error.kind(), io::ErrorKind::InvalidInput);
}
#[test]
fn test_group_columns_with_required_column() {
let columnar1 = make_columnar("numbers", &[1i64]);
let columnar2 = make_columnar("numbers", &[2u64]);
let column_map: BTreeMap<(String, ColumnType), Vec<Option<DynamicColumn>>> =
group_columns_for_merge(
&[&columnar1, &columnar2],
&[("numbers".to_string(), ColumnType::U64)],
)
.unwrap();
assert_eq!(column_map.len(), 1);
assert!(column_map.contains_key(&("numbers".to_string(), ColumnType::U64)));
}
#[test]
fn test_group_columns_required_column_with_no_existing_columns() {
let columnar1 = make_columnar("numbers", &[2u64]);
let columnar2 = make_columnar("numbers", &[2u64]);
let column_map: BTreeMap<(String, ColumnType), Vec<Option<DynamicColumn>>> =
group_columns_for_merge(
&[&columnar1, &columnar2],
&[("required_col".to_string(), ColumnType::Str)],
)
.unwrap();
assert_eq!(column_map.len(), 2);
let columns = column_map
.get(&("required_col".to_string(), ColumnType::Str))
.unwrap();
assert_eq!(columns.len(), 2);
assert!(columns[0].is_none());
assert!(columns[1].is_none());
}
#[test]
fn test_group_columns_required_column_is_above_all_columns_have_the_same_type_rule() {
let columnar1 = make_columnar("numbers", &[2i64]);
let columnar2 = make_columnar("numbers", &[2i64]);
let column_map: BTreeMap<(String, ColumnType), Vec<Option<DynamicColumn>>> =
group_columns_for_merge(
&[&columnar1, &columnar2],
&[("numbers".to_string(), ColumnType::U64)],
)
.unwrap();
assert_eq!(column_map.len(), 1);
assert!(column_map.contains_key(&("numbers".to_string(), ColumnType::U64)));
}
#[test]
fn test_missing_column() {
let columnar1 = make_columnar("numbers", &[-1i64]);
let columnar2 = make_columnar("numbers2", &[2u64]);
let column_map: BTreeMap<(String, ColumnType), Vec<Option<DynamicColumn>>> =
group_columns_for_merge(&[&columnar1, &columnar2], &[]).unwrap();
group_columns_for_merge(&[&columnar1, &columnar2]).unwrap();
assert_eq!(column_map.len(), 2);
assert!(column_map.contains_key(&("numbers".to_string(), ColumnType::I64)));
{
@@ -147,9 +90,7 @@ fn make_numerical_columnar_multiple_columns(
.max()
.unwrap_or(0u32);
let mut buffer: Vec<u8> = Vec::new();
dataframe_writer
.serialize(num_rows, None, &mut buffer)
.unwrap();
dataframe_writer.serialize(num_rows, &mut buffer).unwrap();
ColumnarReader::open(buffer).unwrap()
}
@@ -158,7 +99,7 @@ fn make_byte_columnar_multiple_columns(columns: &[(&str, &[&[&[u8]]])]) -> Colum
for (column_name, column_values) in columns {
for (row_id, vals) in column_values.iter().enumerate() {
for val in vals.iter() {
dataframe_writer.record_bytes(row_id as u32, column_name, val);
dataframe_writer.record_bytes(row_id as u32, column_name, *val);
}
}
}
@@ -168,9 +109,7 @@ fn make_byte_columnar_multiple_columns(columns: &[(&str, &[&[&[u8]]])]) -> Colum
.max()
.unwrap_or(0u32);
let mut buffer: Vec<u8> = Vec::new();
dataframe_writer
.serialize(num_rows, None, &mut buffer)
.unwrap();
dataframe_writer.serialize(num_rows, &mut buffer).unwrap();
ColumnarReader::open(buffer).unwrap()
}
@@ -179,7 +118,7 @@ fn make_text_columnar_multiple_columns(columns: &[(&str, &[&[&str]])]) -> Column
for (column_name, column_values) in columns {
for (row_id, vals) in column_values.iter().enumerate() {
for val in vals.iter() {
dataframe_writer.record_str(row_id as u32, column_name, val);
dataframe_writer.record_str(row_id as u32, column_name, *val);
}
}
}
@@ -189,9 +128,7 @@ fn make_text_columnar_multiple_columns(columns: &[(&str, &[&[&str]])]) -> Column
.max()
.unwrap_or(0u32);
let mut buffer: Vec<u8> = Vec::new();
dataframe_writer
.serialize(num_rows, None, &mut buffer)
.unwrap();
dataframe_writer.serialize(num_rows, &mut buffer).unwrap();
ColumnarReader::open(buffer).unwrap()
}
@@ -208,7 +145,6 @@ fn test_merge_columnar_numbers() {
let stack_merge_order = StackMergeOrder::stack(columnars);
crate::columnar::merge_columnar(
columnars,
&[],
MergeRowOrder::Stack(stack_merge_order),
&mut buffer,
)
@@ -234,7 +170,6 @@ fn test_merge_columnar_texts() {
let stack_merge_order = StackMergeOrder::stack(columnars);
crate::columnar::merge_columnar(
columnars,
&[],
MergeRowOrder::Stack(stack_merge_order),
&mut buffer,
)
@@ -279,7 +214,6 @@ fn test_merge_columnar_byte() {
let stack_merge_order = StackMergeOrder::stack(columnars);
crate::columnar::merge_columnar(
columnars,
&[],
MergeRowOrder::Stack(stack_merge_order),
&mut buffer,
)

1
columnar/src/columnar/merge_index.rs Normal file
View File

@@ -0,0 +1 @@

3
columnar/src/columnar/mod.rs
View File

@@ -1,10 +1,11 @@
mod column_type;
mod format_version;
mod merge;
mod merge_index;
mod reader;
mod writer;
pub use column_type::{ColumnType, HasAssociatedColumnType};
pub use merge::{merge_columnar, MergeRowOrder, ShuffleMergeOrder, StackMergeOrder};
pub use merge::{merge_columnar, MergeRowOrder, StackMergeOrder};
pub use reader::ColumnarReader;
pub use writer::ColumnarWriter;

83
columnar/src/columnar/reader/mod.rs
View File

@@ -21,32 +21,6 @@ pub struct ColumnarReader {
num_rows: RowId,
}
/// Functions by both the async/sync code listing columns.
/// It takes a stream from the column sstable and return the list of
/// `DynamicColumn` available in it.
fn read_all_columns_in_stream(
mut stream: sstable::Streamer<'_, RangeSSTable>,
column_data: &FileSlice,
) -> io::Result<Vec<DynamicColumnHandle>> {
let mut results = Vec::new();
while stream.advance() {
let key_bytes: &[u8] = stream.key();
let Some(column_code) = key_bytes.last().copied() else {
return Err(io_invalid_data("Empty column name.".to_string()));
};
let column_type = ColumnType::try_from_code(column_code)
.map_err(|_| io_invalid_data(format!("Unknown column code `{column_code}`")))?;
let range = stream.value();
let file_slice = column_data.slice(range.start as usize..range.end as usize);
let dynamic_column_handle = DynamicColumnHandle {
file_slice,
column_type,
};
results.push(dynamic_column_handle);
}
Ok(results)
}
impl ColumnarReader {
/// Opens a new Columnar file.
pub fn open<F>(file_slice: F) -> io::Result<ColumnarReader>
@@ -102,7 +76,11 @@ impl ColumnarReader {
Ok(results)
}
fn stream_for_column_range(&self, column_name: &str) -> sstable::StreamerBuilder<RangeSSTable> {
/// Get all columns for the given column name.
///
/// There can be more than one column associated to a given column name, provided they have
/// different types.
pub fn read_columns(&self, column_name: &str) -> io::Result<Vec<DynamicColumnHandle>> {
// Each column is a associated to a given `column_key`,
// that starts by `column_name\0column_header`.
//
@@ -111,35 +89,36 @@ impl ColumnarReader {
//
// This is in turn equivalent to searching for the range
// `[column_name,\0`..column_name\1)`.
// TODO can we get some more generic `prefix(..)` logic in the dictionary.
// TODO can we get some more generic `prefix(..)` logic in the dictioanry.
let mut start_key = column_name.to_string();
start_key.push('\0');
let mut end_key = column_name.to_string();
end_key.push(1u8 as char);
self.column_dictionary
let mut stream = self
.column_dictionary
.range()
.ge(start_key.as_bytes())
.lt(end_key.as_bytes())
}
pub async fn read_columns_async(
&self,
column_name: &str,
) -> io::Result<Vec<DynamicColumnHandle>> {
let stream = self
.stream_for_column_range(column_name)
.into_stream_async()
.await?;
read_all_columns_in_stream(stream, &self.column_data)
}
/// Get all columns for the given column name.
///
/// There can be more than one column associated to a given column name, provided they have
/// different types.
pub fn read_columns(&self, column_name: &str) -> io::Result<Vec<DynamicColumnHandle>> {
let stream = self.stream_for_column_range(column_name).into_stream()?;
read_all_columns_in_stream(stream, &self.column_data)
.into_stream()?;
let mut results = Vec::new();
while stream.advance() {
let key_bytes: &[u8] = stream.key();
assert!(key_bytes.starts_with(start_key.as_bytes()));
let column_code: u8 = key_bytes.last().cloned().unwrap();
let column_type = ColumnType::try_from_code(column_code)
.map_err(|_| io_invalid_data(format!("Unknown column code `{column_code}`")))?;
let range = stream.value().clone();
let file_slice = self
.column_data
.slice(range.start as usize..range.end as usize);
let dynamic_column_handle = DynamicColumnHandle {
file_slice,
column_type,
};
results.push(dynamic_column_handle);
}
Ok(results)
}
/// Return the number of columns in the columnar.
@@ -158,7 +137,7 @@ mod tests {
columnar_writer.record_column_type("col1", ColumnType::Str, false);
columnar_writer.record_column_type("col2", ColumnType::U64, false);
let mut buffer = Vec::new();
columnar_writer.serialize(1, None, &mut buffer).unwrap();
columnar_writer.serialize(1, &mut buffer).unwrap();
let columnar = ColumnarReader::open(buffer).unwrap();
let columns = columnar.list_columns().unwrap();
assert_eq!(columns.len(), 2);
@@ -174,7 +153,7 @@ mod tests {
columnar_writer.record_column_type("count", ColumnType::U64, false);
columnar_writer.record_numerical(1, "count", 1u64);
let mut buffer = Vec::new();
columnar_writer.serialize(2, None, &mut buffer).unwrap();
columnar_writer.serialize(2, &mut buffer).unwrap();
let columnar = ColumnarReader::open(buffer).unwrap();
let columns = columnar.list_columns().unwrap();
assert_eq!(columns.len(), 1);
@@ -183,7 +162,7 @@ mod tests {
}
#[test]
#[should_panic(expected = "Input type forbidden")]
#[should_panic(expect = "Input type forbidden")]
fn test_list_columns_strict_typing_panics_on_wrong_types() {
let mut columnar_writer = ColumnarWriter::default();
columnar_writer.record_column_type("count", ColumnType::U64, false);

4
columnar/src/columnar/writer/column_operation.rs
View File

@@ -310,7 +310,7 @@ mod tests {
buffer.extend_from_slice(b"234234");
let mut bytes = &buffer[..];
let serdeser_symbol = ColumnOperation::deserialize(&mut bytes).unwrap();
assert_eq!(bytes.len() + buf.as_ref().len(), buffer.len());
assert_eq!(bytes.len() + buf.as_ref().len() as usize, buffer.len());
assert_eq!(column_op, serdeser_symbol);
}
@@ -341,7 +341,7 @@ mod tests {
fn test_column_operation_unordered_aux(val: u32, expected_len: usize) {
let column_op = ColumnOperation::Value(UnorderedId(val));
let minibuf = column_op.serialize();
assert_eq!({ minibuf.as_ref().len() }, expected_len);
assert_eq!(minibuf.as_ref().len() as usize, expected_len);
let mut buf = minibuf.as_ref().to_vec();
buf.extend_from_slice(&[2, 2, 2, 2, 2, 2]);
let mut cursor = &buf[..];

39
columnar/src/columnar/writer/column_writers.rs
View File

@@ -41,31 +41,10 @@ impl ColumnWriter {
pub(super) fn operation_iterator<'a, V: SymbolValue>(
&self,
arena: &MemoryArena,
old_to_new_ids_opt: Option<&[RowId]>,
buffer: &'a mut Vec<u8>,
) -> impl Iterator<Item = ColumnOperation<V>> + 'a {
buffer.clear();
self.values.read_to_end(arena, buffer);
if let Some(old_to_new_ids) = old_to_new_ids_opt {
// TODO avoid the extra deserialization / serialization.
let mut sorted_ops: Vec<(RowId, ColumnOperation<V>)> = Vec::new();
let mut new_doc = 0u32;
let mut cursor = &buffer[..];
for op in std::iter::from_fn(|| ColumnOperation::<V>::deserialize(&mut cursor)) {
if let ColumnOperation::NewDoc(doc) = &op {
new_doc = old_to_new_ids[*doc as usize];
sorted_ops.push((new_doc, ColumnOperation::NewDoc(new_doc)));
} else {
sorted_ops.push((new_doc, op));
}
}
// stable sort is crucial here.
sorted_ops.sort_by_key(|(new_doc_id, _)| *new_doc_id);
buffer.clear();
for (_, op) in sorted_ops {
buffer.extend_from_slice(op.serialize().as_ref());
}
}
let mut cursor: &[u8] = &buffer[..];
std::iter::from_fn(move || ColumnOperation::deserialize(&mut cursor))
}
@@ -210,12 +189,10 @@ impl CompatibleNumericalTypes {
}
impl NumericalColumnWriter {
pub fn numerical_type(&self) -> NumericalType {
self.compatible_numerical_types.to_numerical_type()
}
pub fn cardinality(&self, num_docs: RowId) -> Cardinality {
self.column_writer.get_cardinality(num_docs)
pub fn column_type_and_cardinality(&self, num_docs: RowId) -> (NumericalType, Cardinality) {
let numerical_type = self.compatible_numerical_types.to_numerical_type();
let cardinality = self.column_writer.get_cardinality(num_docs);
(numerical_type, cardinality)
}
pub fn record_numerical_value(
@@ -231,11 +208,9 @@ impl NumericalColumnWriter {
pub(super) fn operation_iterator<'a>(
self,
arena: &MemoryArena,
old_to_new_ids: Option<&[RowId]>,
buffer: &'a mut Vec<u8>,
) -> impl Iterator<Item = ColumnOperation<NumericalValue>> + 'a {
self.column_writer
.operation_iterator(arena, old_to_new_ids, buffer)
self.column_writer.operation_iterator(arena, buffer)
}
}
@@ -276,11 +251,9 @@ impl StrOrBytesColumnWriter {
pub(super) fn operation_iterator<'a>(
&self,
arena: &MemoryArena,
old_to_new_ids: Option<&[RowId]>,
byte_buffer: &'a mut Vec<u8>,
) -> impl Iterator<Item = ColumnOperation<UnorderedId>> + 'a {
self.column_writer
.operation_iterator(arena, old_to_new_ids, byte_buffer)
self.column_writer.operation_iterator(arena, byte_buffer)
}
}

172
columnar/src/columnar/writer/mod.rs
View File

@@ -16,7 +16,7 @@ use crate::column_index::SerializableColumnIndex;
use crate::column_values::{
ColumnValues, MonotonicallyMappableToU128, MonotonicallyMappableToU64, VecColumn,
};
use crate::columnar::column_type::ColumnType;
use crate::columnar::column_type::{ColumnType, ColumnTypeCategory};
use crate::columnar::writer::column_writers::{
ColumnWriter, NumericalColumnWriter, StrOrBytesColumnWriter,
};
@@ -45,9 +45,8 @@ struct SpareBuffers {
/// columnar_writer.record_str(1u32 /* doc id */, "product_name", "Apple");
/// columnar_writer.record_numerical(0u32 /* doc id */, "price", 10.5f64); //< uh oh we ended up mixing integer and floats.
/// let mut wrt: Vec<u8> = Vec::new();
/// columnar_writer.serialize(2u32, None, &mut wrt).unwrap();
/// columnar_writer.serialize(2u32, &mut wrt).unwrap();
/// ```
#[derive(Default)]
pub struct ColumnarWriter {
numerical_field_hash_map: ArenaHashMap,
datetime_field_hash_map: ArenaHashMap,
@@ -61,6 +60,22 @@ pub struct ColumnarWriter {
buffers: SpareBuffers,
}
impl Default for ColumnarWriter {
fn default() -> Self {
ColumnarWriter {
numerical_field_hash_map: ArenaHashMap::new(10_000),
bool_field_hash_map: ArenaHashMap::new(10_000),
ip_addr_field_hash_map: ArenaHashMap::new(10_000),
bytes_field_hash_map: ArenaHashMap::new(10_000),
str_field_hash_map: ArenaHashMap::new(10_000),
datetime_field_hash_map: ArenaHashMap::new(10_000),
dictionaries: Vec::new(),
arena: MemoryArena::default(),
buffers: SpareBuffers::default(),
}
}
}
#[inline]
fn mutate_or_create_column<V, TMutator>(
arena_hash_map: &mut ArenaHashMap,
@@ -89,48 +104,6 @@ impl ColumnarWriter {
+ self.datetime_field_hash_map.mem_usage()
}
/// Returns the list of doc ids from 0..num_docs sorted by the `sort_field`
/// column.
///
/// If the column is multivalued, use the first value for scoring.
/// If no value is associated to a specific row, the document is assigned
/// the lowest possible score.
///
/// The sort applied is stable.
pub fn sort_order(&self, sort_field: &str, num_docs: RowId, reversed: bool) -> Vec<u32> {
let Some(numerical_col_writer) =
self.numerical_field_hash_map.get::<NumericalColumnWriter>(sort_field.as_bytes()) else {
return Vec::new();
};
let mut symbols_buffer = Vec::new();
let mut values = Vec::new();
let mut last_doc_opt: Option<RowId> = None;
for op in numerical_col_writer.operation_iterator(&self.arena, None, &mut symbols_buffer) {
match op {
ColumnOperation::NewDoc(doc) => {
last_doc_opt = Some(doc);
}
ColumnOperation::Value(numerical_value) => {
if let Some(last_doc) = last_doc_opt {
let score: f32 = f64::coerce(numerical_value) as f32;
values.push((score, last_doc));
}
}
}
}
for doc in values.len() as u32..num_docs {
values.push((0.0f32, doc));
}
values.sort_by(|(left_score, _), (right_score, _)| {
if reversed {
right_score.partial_cmp(left_score).unwrap()
} else {
left_score.partial_cmp(right_score).unwrap()
}
});
values.into_iter().map(|(_score, doc)| doc).collect()
}
/// Records a column type. This is useful to bypass the coercion process,
/// makes sure the empty is present in the resulting columnar, or set
/// the `sort_values_within_row`.
@@ -251,15 +224,11 @@ impl ColumnarWriter {
});
}
pub fn record_datetime(&mut self, doc: RowId, column_name: &str, datetime: common::DateTime) {
pub fn record_datetime(&mut self, doc: RowId, column_name: &str, datetime: crate::DateTime) {
let (hash_map, arena) = (&mut self.datetime_field_hash_map, &mut self.arena);
mutate_or_create_column(hash_map, column_name, |column_opt: Option<ColumnWriter>| {
let mut column: ColumnWriter = column_opt.unwrap_or_default();
column.record(
doc,
NumericalValue::I64(datetime.into_timestamp_micros()),
arena,
);
column.record(doc, NumericalValue::I64(datetime.timestamp_micros), arena);
column
});
}
@@ -309,47 +278,37 @@ impl ColumnarWriter {
},
);
}
pub fn serialize(
&mut self,
num_docs: RowId,
old_to_new_row_ids: Option<&[RowId]>,
wrt: &mut dyn io::Write,
) -> io::Result<()> {
pub fn serialize(&mut self, num_docs: RowId, wrt: &mut dyn io::Write) -> io::Result<()> {
let mut serializer = ColumnarSerializer::new(wrt);
let mut columns: Vec<(&[u8], ColumnType, Addr)> = self
let mut columns: Vec<(&[u8], ColumnTypeCategory, Addr)> = self
.numerical_field_hash_map
.iter()
.map(|(column_name, addr, _)| {
let numerical_column_writer: NumericalColumnWriter =
self.numerical_field_hash_map.read(addr);
let column_type = numerical_column_writer.numerical_type().into();
(column_name, column_type, addr)
})
.map(|(column_name, addr, _)| (column_name, ColumnTypeCategory::Numerical, addr))
.collect();
columns.extend(
self.bytes_field_hash_map
.iter()
.map(|(term, addr, _)| (term, ColumnType::Bytes, addr)),
.map(|(term, addr, _)| (term, ColumnTypeCategory::Bytes, addr)),
);
columns.extend(
self.str_field_hash_map
.iter()
.map(|(column_name, addr, _)| (column_name, ColumnType::Str, addr)),
.map(|(column_name, addr, _)| (column_name, ColumnTypeCategory::Str, addr)),
);
columns.extend(
self.bool_field_hash_map
.iter()
.map(|(column_name, addr, _)| (column_name, ColumnType::Bool, addr)),
.map(|(column_name, addr, _)| (column_name, ColumnTypeCategory::Bool, addr)),
);
columns.extend(
self.ip_addr_field_hash_map
.iter()
.map(|(column_name, addr, _)| (column_name, ColumnType::IpAddr, addr)),
.map(|(column_name, addr, _)| (column_name, ColumnTypeCategory::IpAddr, addr)),
);
columns.extend(
self.datetime_field_hash_map
.iter()
.map(|(column_name, addr, _)| (column_name, ColumnType::DateTime, addr)),
.map(|(column_name, addr, _)| (column_name, ColumnTypeCategory::DateTime, addr)),
);
columns.sort_unstable_by_key(|(column_name, col_type, _)| (*column_name, *col_type));
@@ -357,24 +316,20 @@ impl ColumnarWriter {
let mut symbol_byte_buffer: Vec<u8> = Vec::new();
for (column_name, column_type, addr) in columns {
match column_type {
ColumnType::Bool => {
ColumnTypeCategory::Bool => {
let column_writer: ColumnWriter = self.bool_field_hash_map.read(addr);
let cardinality = column_writer.get_cardinality(num_docs);
let mut column_serializer =
serializer.serialize_column(column_name, column_type);
serializer.serialize_column(column_name, ColumnType::Bool);
serialize_bool_column(
cardinality,
num_docs,
column_writer.operation_iterator(
arena,
old_to_new_row_ids,
&mut symbol_byte_buffer,
),
column_writer.operation_iterator(arena, &mut symbol_byte_buffer),
buffers,
&mut column_serializer,
)?;
}
ColumnType::IpAddr => {
ColumnTypeCategory::IpAddr => {
let column_writer: ColumnWriter = self.ip_addr_field_hash_map.read(addr);
let cardinality = column_writer.get_cardinality(num_docs);
let mut column_serializer =
@@ -382,64 +337,50 @@ impl ColumnarWriter {
serialize_ip_addr_column(
cardinality,
num_docs,
column_writer.operation_iterator(
arena,
old_to_new_row_ids,
&mut symbol_byte_buffer,
),
column_writer.operation_iterator(arena, &mut symbol_byte_buffer),
buffers,
&mut column_serializer,
)?;
}
ColumnType::Bytes | ColumnType::Str => {
let str_or_bytes_column_writer: StrOrBytesColumnWriter =
if column_type == ColumnType::Bytes {
self.bytes_field_hash_map.read(addr)
ColumnTypeCategory::Bytes | ColumnTypeCategory::Str => {
let (column_type, str_column_writer): (ColumnType, StrOrBytesColumnWriter) =
if column_type == ColumnTypeCategory::Bytes {
(ColumnType::Bytes, self.bytes_field_hash_map.read(addr))
} else {
self.str_field_hash_map.read(addr)
(ColumnType::Str, self.str_field_hash_map.read(addr))
};
let dictionary_builder =
&dictionaries[str_or_bytes_column_writer.dictionary_id as usize];
let cardinality = str_or_bytes_column_writer
.column_writer
.get_cardinality(num_docs);
&dictionaries[str_column_writer.dictionary_id as usize];
let cardinality = str_column_writer.column_writer.get_cardinality(num_docs);
let mut column_serializer =
serializer.serialize_column(column_name, column_type);
serialize_bytes_or_str_column(
cardinality,
num_docs,
str_or_bytes_column_writer.sort_values_within_row,
str_column_writer.sort_values_within_row,
dictionary_builder,
str_or_bytes_column_writer.operation_iterator(
arena,
old_to_new_row_ids,
&mut symbol_byte_buffer,
),
str_column_writer.operation_iterator(arena, &mut symbol_byte_buffer),
buffers,
&mut column_serializer,
)?;
}
ColumnType::F64 | ColumnType::I64 | ColumnType::U64 => {
ColumnTypeCategory::Numerical => {
let numerical_column_writer: NumericalColumnWriter =
self.numerical_field_hash_map.read(addr);
let cardinality = numerical_column_writer.cardinality(num_docs);
let (numerical_type, cardinality) =
numerical_column_writer.column_type_and_cardinality(num_docs);
let mut column_serializer =
serializer.serialize_column(column_name, column_type);
let numerical_type = column_type.numerical_type().unwrap();
serializer.serialize_column(column_name, ColumnType::from(numerical_type));
serialize_numerical_column(
cardinality,
num_docs,
numerical_type,
numerical_column_writer.operation_iterator(
arena,
old_to_new_row_ids,
&mut symbol_byte_buffer,
),
numerical_column_writer.operation_iterator(arena, &mut symbol_byte_buffer),
buffers,
&mut column_serializer,
)?;
}
ColumnType::DateTime => {
ColumnTypeCategory::DateTime => {
let column_writer: ColumnWriter = self.datetime_field_hash_map.read(addr);
let cardinality = column_writer.get_cardinality(num_docs);
let mut column_serializer =
@@ -448,11 +389,7 @@ impl ColumnarWriter {
cardinality,
num_docs,
NumericalType::I64,
column_writer.operation_iterator(
arena,
old_to_new_row_ids,
&mut symbol_byte_buffer,
),
column_writer.operation_iterator(arena, &mut symbol_byte_buffer),
buffers,
&mut column_serializer,
)?;
@@ -651,12 +588,13 @@ where
crate::column::serialize_column_mappable_to_u128(
serializable_column_index,
&&values[..],
values.len() as u32,
&mut wrt,
)?;
Ok(())
}
fn sort_values_within_row_in_place(multivalued_index: &[RowId], values: &mut [u64]) {
fn sort_values_within_row_in_place(multivalued_index: &[RowId], values: &mut Vec<u64>) {
let mut start_index: usize = 0;
for end_index in multivalued_index.iter().copied() {
let end_index = end_index as usize;
@@ -761,7 +699,7 @@ mod tests {
assert_eq!(column_writer.get_cardinality(3), Cardinality::Full);
let mut buffer = Vec::new();
let symbols: Vec<ColumnOperation<NumericalValue>> = column_writer
.operation_iterator(&arena, None, &mut buffer)
.operation_iterator(&mut arena, &mut buffer)
.collect();
assert_eq!(symbols.len(), 6);
assert!(matches!(symbols[0], ColumnOperation::NewDoc(0u32)));
@@ -790,7 +728,7 @@ mod tests {
assert_eq!(column_writer.get_cardinality(3), Cardinality::Optional);
let mut buffer = Vec::new();
let symbols: Vec<ColumnOperation<NumericalValue>> = column_writer
.operation_iterator(&arena, None, &mut buffer)
.operation_iterator(&mut arena, &mut buffer)
.collect();
assert_eq!(symbols.len(), 4);
assert!(matches!(symbols[0], ColumnOperation::NewDoc(1u32)));
@@ -813,7 +751,7 @@ mod tests {
assert_eq!(column_writer.get_cardinality(2), Cardinality::Optional);
let mut buffer = Vec::new();
let symbols: Vec<ColumnOperation<NumericalValue>> = column_writer
.operation_iterator(&arena, None, &mut buffer)
.operation_iterator(&mut arena, &mut buffer)
.collect();
assert_eq!(symbols.len(), 2);
assert!(matches!(symbols[0], ColumnOperation::NewDoc(0u32)));
@@ -832,7 +770,7 @@ mod tests {
assert_eq!(column_writer.get_cardinality(1), Cardinality::Multivalued);
let mut buffer = Vec::new();
let symbols: Vec<ColumnOperation<NumericalValue>> = column_writer
.operation_iterator(&arena, None, &mut buffer)
.operation_iterator(&mut arena, &mut buffer)
.collect();
assert_eq!(symbols.len(), 3);
assert!(matches!(symbols[0], ColumnOperation::NewDoc(0u32)));

14
columnar/src/columnar/writer/value_index.rs
View File

@@ -29,7 +29,7 @@ pub struct OptionalIndexBuilder {
}
impl OptionalIndexBuilder {
pub fn finish(&mut self, num_rows: RowId) -> impl Iterable<RowId> + '_ {
pub fn finish<'a>(&'a mut self, num_rows: RowId) -> impl Iterable<RowId> + 'a {
debug_assert!(self
.docs
.last()
@@ -150,7 +150,11 @@ mod tests {
multivalued_value_index_builder.record_row(2u32);
multivalued_value_index_builder.record_value();
assert_eq!(
multivalued_value_index_builder.finish(4u32).to_vec(),
multivalued_value_index_builder
.finish(4u32)
.iter()
.copied()
.collect::<Vec<u32>>(),
vec![0, 0, 2, 3, 3]
);
multivalued_value_index_builder.reset();
@@ -158,7 +162,11 @@ mod tests {
multivalued_value_index_builder.record_value();
multivalued_value_index_builder.record_value();
assert_eq!(
multivalued_value_index_builder.finish(4u32).to_vec(),
multivalued_value_index_builder
.finish(4u32)
.iter()
.copied()
.collect::<Vec<u32>>(),
vec![0, 0, 0, 2, 2]
);
}

27
columnar/src/dynamic_column.rs
View File

@@ -3,12 +3,12 @@ use std::net::Ipv6Addr;
use std::sync::Arc;
use common::file_slice::FileSlice;
use common::{DateTime, HasLen, OwnedBytes};
use common::{HasLen, OwnedBytes};
use crate::column::{BytesColumn, Column, StrColumn};
use crate::column_values::{monotonic_map_column, StrictlyMonotonicFn};
use crate::columnar::ColumnType;
use crate::{Cardinality, NumericalType};
use crate::{Cardinality, DateTime, NumericalType};
#[derive(Clone)]
pub enum DynamicColumn {
@@ -166,9 +166,9 @@ impl StrictlyMonotonicFn<i64, u64> for MapI64ToU64 {
macro_rules! static_dynamic_conversions {
($typ:ty, $enum_name:ident) => {
impl From<DynamicColumn> for Option<$typ> {
fn from(dynamic_column: DynamicColumn) -> Option<$typ> {
if let DynamicColumn::$enum_name(col) = dynamic_column {
impl Into<Option<$typ>> for DynamicColumn {
fn into(self) -> Option<$typ> {
if let DynamicColumn::$enum_name(col) = self {
Some(col)
} else {
None
@@ -188,7 +188,7 @@ static_dynamic_conversions!(Column<bool>, Bool);
static_dynamic_conversions!(Column<u64>, U64);
static_dynamic_conversions!(Column<i64>, I64);
static_dynamic_conversions!(Column<f64>, F64);
static_dynamic_conversions!(Column<DateTime>, DateTime);
static_dynamic_conversions!(Column<crate::DateTime>, DateTime);
static_dynamic_conversions!(StrColumn, Str);
static_dynamic_conversions!(BytesColumn, Bytes);
static_dynamic_conversions!(Column<Ipv6Addr>, IpAddr);
@@ -206,9 +206,10 @@ impl DynamicColumnHandle {
self.open_internal(column_bytes)
}
#[doc(hidden)]
pub fn file_slice(&self) -> &FileSlice {
&self.file_slice
// TODO rename load_async
pub async fn open_async(&self) -> io::Result<DynamicColumn> {
let column_bytes: OwnedBytes = self.file_slice.read_bytes_async().await?;
self.open_internal(column_bytes)
}
/// Returns the `u64` fast field reader reader associated with `fields` of types
@@ -234,15 +235,17 @@ impl DynamicColumnHandle {
fn open_internal(&self, column_bytes: OwnedBytes) -> io::Result<DynamicColumn> {
let dynamic_column: DynamicColumn = match self.column_type {
ColumnType::Bytes => crate::column::open_column_bytes(column_bytes)?.into(),
ColumnType::Str => crate::column::open_column_str(column_bytes)?.into(),
ColumnType::Bytes => {
crate::column::open_column_bytes::<BytesColumn>(column_bytes)?.into()
}
ColumnType::Str => crate::column::open_column_bytes::<StrColumn>(column_bytes)?.into(),
ColumnType::I64 => crate::column::open_column_u64::<i64>(column_bytes)?.into(),
ColumnType::U64 => crate::column::open_column_u64::<u64>(column_bytes)?.into(),
ColumnType::F64 => crate::column::open_column_u64::<f64>(column_bytes)?.into(),
ColumnType::Bool => crate::column::open_column_u64::<bool>(column_bytes)?.into(),
ColumnType::IpAddr => crate::column::open_column_u128::<Ipv6Addr>(column_bytes)?.into(),
ColumnType::DateTime => {
crate::column::open_column_u64::<DateTime>(column_bytes)?.into()
crate::column::open_column_u64::<crate::DateTime>(column_bytes)?.into()
}
};
Ok(dynamic_column)

15
columnar/src/lib.rs
View File

@@ -24,7 +24,7 @@ pub use column_index::ColumnIndex;
pub use column_values::{ColumnValues, MonotonicallyMappableToU128, MonotonicallyMappableToU64};
pub use columnar::{
merge_columnar, ColumnType, ColumnarReader, ColumnarWriter, HasAssociatedColumnType,
MergeRowOrder, ShuffleMergeOrder, StackMergeOrder,
MergeRowOrder, StackMergeOrder,
};
use sstable::VoidSSTable;
pub use value::{NumericalType, NumericalValue};
@@ -32,18 +32,13 @@ pub use value::{NumericalType, NumericalValue};
pub use self::dynamic_column::{DynamicColumn, DynamicColumnHandle};
pub type RowId = u32;
pub type DocId = u32;
#[derive(Clone, Copy)]
pub struct RowAddr {
pub segment_ord: u32,
pub row_id: RowId,
}
pub use sstable::Dictionary;
pub type Streamer<'a> = sstable::Streamer<'a, VoidSSTable>;
pub use common::DateTime;
#[derive(Clone, Copy, PartialOrd, PartialEq, Default, Debug)]
pub struct DateTime {
pub timestamp_micros: i64,
}
#[derive(Copy, Clone, Debug)]
pub struct InvalidData;

18
columnar/src/tests.rs
View File

@@ -12,7 +12,7 @@ fn test_dataframe_writer_str() {
dataframe_writer.record_str(1u32, "my_string", "hello");
dataframe_writer.record_str(3u32, "my_string", "helloeee");
let mut buffer: Vec<u8> = Vec::new();
dataframe_writer.serialize(5, None, &mut buffer).unwrap();
dataframe_writer.serialize(5, &mut buffer).unwrap();
let columnar = ColumnarReader::open(buffer).unwrap();
assert_eq!(columnar.num_columns(), 1);
let cols: Vec<DynamicColumnHandle> = columnar.read_columns("my_string").unwrap();
@@ -26,7 +26,7 @@ fn test_dataframe_writer_bytes() {
dataframe_writer.record_bytes(1u32, "my_string", b"hello");
dataframe_writer.record_bytes(3u32, "my_string", b"helloeee");
let mut buffer: Vec<u8> = Vec::new();
dataframe_writer.serialize(5, None, &mut buffer).unwrap();
dataframe_writer.serialize(5, &mut buffer).unwrap();
let columnar = ColumnarReader::open(buffer).unwrap();
assert_eq!(columnar.num_columns(), 1);
let cols: Vec<DynamicColumnHandle> = columnar.read_columns("my_string").unwrap();
@@ -40,7 +40,7 @@ fn test_dataframe_writer_bool() {
dataframe_writer.record_bool(1u32, "bool.value", false);
dataframe_writer.record_bool(3u32, "bool.value", true);
let mut buffer: Vec<u8> = Vec::new();
dataframe_writer.serialize(5, None, &mut buffer).unwrap();
dataframe_writer.serialize(5, &mut buffer).unwrap();
let columnar = ColumnarReader::open(buffer).unwrap();
assert_eq!(columnar.num_columns(), 1);
let cols: Vec<DynamicColumnHandle> = columnar.read_columns("bool.value").unwrap();
@@ -63,7 +63,7 @@ fn test_dataframe_writer_u64_multivalued() {
dataframe_writer.record_numerical(6u32, "divisor", 2u64);
dataframe_writer.record_numerical(6u32, "divisor", 3u64);
let mut buffer: Vec<u8> = Vec::new();
dataframe_writer.serialize(7, None, &mut buffer).unwrap();
dataframe_writer.serialize(7, &mut buffer).unwrap();
let columnar = ColumnarReader::open(buffer).unwrap();
assert_eq!(columnar.num_columns(), 1);
let cols: Vec<DynamicColumnHandle> = columnar.read_columns("divisor").unwrap();
@@ -75,7 +75,7 @@ fn test_dataframe_writer_u64_multivalued() {
divisor_col.get_cardinality(),
crate::Cardinality::Multivalued
);
assert_eq!(divisor_col.num_docs(), 7);
assert_eq!(divisor_col.num_rows(), 7);
}
#[test]
@@ -84,7 +84,7 @@ fn test_dataframe_writer_ip_addr() {
dataframe_writer.record_ip_addr(1, "ip_addr", Ipv6Addr::from_u128(1001));
dataframe_writer.record_ip_addr(3, "ip_addr", Ipv6Addr::from_u128(1050));
let mut buffer: Vec<u8> = Vec::new();
dataframe_writer.serialize(5, None, &mut buffer).unwrap();
dataframe_writer.serialize(5, &mut buffer).unwrap();
let columnar = ColumnarReader::open(buffer).unwrap();
assert_eq!(columnar.num_columns(), 1);
let cols: Vec<DynamicColumnHandle> = columnar.read_columns("ip_addr").unwrap();
@@ -113,7 +113,7 @@ fn test_dataframe_writer_numerical() {
dataframe_writer.record_numerical(2u32, "srical.value", NumericalValue::U64(13u64));
dataframe_writer.record_numerical(4u32, "srical.value", NumericalValue::U64(15u64));
let mut buffer: Vec<u8> = Vec::new();
dataframe_writer.serialize(6, None, &mut buffer).unwrap();
dataframe_writer.serialize(6, &mut buffer).unwrap();
let columnar = ColumnarReader::open(buffer).unwrap();
assert_eq!(columnar.num_columns(), 1);
let cols: Vec<DynamicColumnHandle> = columnar.read_columns("srical.value").unwrap();
@@ -144,7 +144,7 @@ fn test_dictionary_encoded_str() {
columnar_writer.record_str(3, "my.column", "c");
columnar_writer.record_str(3, "my.column2", "different_column!");
columnar_writer.record_str(4, "my.column", "b");
columnar_writer.serialize(5, None, &mut buffer).unwrap();
columnar_writer.serialize(5, &mut buffer).unwrap();
let columnar_reader = ColumnarReader::open(buffer).unwrap();
assert_eq!(columnar_reader.num_columns(), 2);
let col_handles = columnar_reader.read_columns("my.column").unwrap();
@@ -176,7 +176,7 @@ fn test_dictionary_encoded_bytes() {
columnar_writer.record_bytes(3, "my.column", b"c");
columnar_writer.record_bytes(3, "my.column2", b"different_column!");
columnar_writer.record_bytes(4, "my.column", b"b");
columnar_writer.serialize(5, None, &mut buffer).unwrap();
columnar_writer.serialize(5, &mut buffer).unwrap();
let columnar_reader = ColumnarReader::open(buffer).unwrap();
assert_eq!(columnar_reader.num_columns(), 2);
let col_handles = columnar_reader.read_columns("my.column").unwrap();

6
columnar/src/value.rs
View File

@@ -1,5 +1,3 @@
use common::DateTime;
use crate::InvalidData;
#[derive(Copy, Clone, PartialEq, Debug)]
@@ -106,10 +104,10 @@ impl Coerce for f64 {
}
}
impl Coerce for DateTime {
impl Coerce for crate::DateTime {
fn coerce(value: NumericalValue) -> Self {
let timestamp_micros = i64::coerce(value);
DateTime::from_timestamp_micros(timestamp_micros)
crate::DateTime { timestamp_micros }
}
}

3
common/Cargo.toml
View File

@@ -13,10 +13,9 @@ repository = "https://github.com/quickwit-oss/tantivy"
# See more keys and their definitions at https://doc.rust-lang.org/cargo/reference/manifest.html
[dependencies]
byteorder = "1.4.3"
ownedbytes = { version= "0.5", path="../ownedbytes" }
async-trait = "0.1"
time = { version = "0.3.10", features = ["serde-well-known"] }
serde = { version = "1.0.136", features = ["derive"] }
[dev-dependencies]
proptest = "1.0.0"

136
common/src/datetime.rs
View File

@@ -1,136 +0,0 @@
use std::fmt;
use serde::{Deserialize, Serialize};
use time::format_description::well_known::Rfc3339;
use time::{OffsetDateTime, PrimitiveDateTime, UtcOffset};
/// DateTime Precision
#[derive(
Clone, Copy, Debug, Hash, PartialEq, Eq, PartialOrd, Ord, Serialize, Deserialize, Default,
)]
#[serde(rename_all = "lowercase")]
pub enum DatePrecision {
/// Seconds precision
#[default]
Seconds,
/// Milli-seconds precision.
Milliseconds,
/// Micro-seconds precision.
Microseconds,
}
/// A date/time value with microsecond precision.
///
/// This timestamp does not carry any explicit time zone information.
/// Users are responsible for applying the provided conversion
/// functions consistently. Internally the time zone is assumed
/// to be UTC, which is also used implicitly for JSON serialization.
///
/// All constructors and conversions are provided as explicit
/// functions and not by implementing any `From`/`Into` traits
/// to prevent unintended usage.
#[derive(Clone, Default, Copy, PartialEq, Eq, PartialOrd, Ord, Hash)]
pub struct DateTime {
// Timestamp in microseconds.
pub(crate) timestamp_micros: i64,
}
impl DateTime {
/// Create new from UNIX timestamp in seconds
pub const fn from_timestamp_secs(seconds: i64) -> Self {
Self {
timestamp_micros: seconds * 1_000_000,
}
}
/// Create new from UNIX timestamp in milliseconds
pub const fn from_timestamp_millis(milliseconds: i64) -> Self {
Self {
timestamp_micros: milliseconds * 1_000,
}
}
/// Create new from UNIX timestamp in microseconds.
pub const fn from_timestamp_micros(microseconds: i64) -> Self {
Self {
timestamp_micros: microseconds,
}
}
/// Create new from `OffsetDateTime`
///
/// The given date/time is converted to UTC and the actual
/// time zone is discarded.
pub const fn from_utc(dt: OffsetDateTime) -> Self {
let timestamp_micros = dt.unix_timestamp() * 1_000_000 + dt.microsecond() as i64;
Self { timestamp_micros }
}
/// Create new from `PrimitiveDateTime`
///
/// Implicitly assumes that the given date/time is in UTC!
/// Otherwise the original value must only be reobtained with
/// [`Self::into_primitive()`].
pub fn from_primitive(dt: PrimitiveDateTime) -> Self {
Self::from_utc(dt.assume_utc())
}
/// Convert to UNIX timestamp in seconds.
pub const fn into_timestamp_secs(self) -> i64 {
self.timestamp_micros / 1_000_000
}
/// Convert to UNIX timestamp in milliseconds.
pub const fn into_timestamp_millis(self) -> i64 {
self.timestamp_micros / 1_000
}
/// Convert to UNIX timestamp in microseconds.
pub const fn into_timestamp_micros(self) -> i64 {
self.timestamp_micros
}
/// Convert to UTC `OffsetDateTime`
pub fn into_utc(self) -> OffsetDateTime {
let timestamp_nanos = self.timestamp_micros as i128 * 1000;
let utc_datetime = OffsetDateTime::from_unix_timestamp_nanos(timestamp_nanos)
.expect("valid UNIX timestamp");
debug_assert_eq!(UtcOffset::UTC, utc_datetime.offset());
utc_datetime
}
/// Convert to `OffsetDateTime` with the given time zone
pub fn into_offset(self, offset: UtcOffset) -> OffsetDateTime {
self.into_utc().to_offset(offset)
}
/// Convert to `PrimitiveDateTime` without any time zone
///
/// The value should have been constructed with [`Self::from_primitive()`].
/// Otherwise the time zone is implicitly assumed to be UTC.
pub fn into_primitive(self) -> PrimitiveDateTime {
let utc_datetime = self.into_utc();
// Discard the UTC time zone offset
debug_assert_eq!(UtcOffset::UTC, utc_datetime.offset());
PrimitiveDateTime::new(utc_datetime.date(), utc_datetime.time())
}
/// Truncates the microseconds value to the corresponding precision.
pub fn truncate(self, precision: DatePrecision) -> Self {
let truncated_timestamp_micros = match precision {
DatePrecision::Seconds => (self.timestamp_micros / 1_000_000) * 1_000_000,
DatePrecision::Milliseconds => (self.timestamp_micros / 1_000) * 1_000,
DatePrecision::Microseconds => self.timestamp_micros,
};
Self {
timestamp_micros: truncated_timestamp_micros,
}
}
}
impl fmt::Debug for DateTime {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
let utc_rfc3339 = self.into_utc().format(&Rfc3339).map_err(|_| fmt::Error)?;
f.write_str(&utc_rfc3339)
}
}

35
common/src/lib.rs
View File

@@ -2,15 +2,15 @@
use std::ops::Deref;
pub use byteorder::LittleEndian as Endianness;
mod bitset;
mod datetime;
pub mod file_slice;
mod group_by;
mod serialize;
mod vint;
mod writer;
pub use bitset::*;
pub use datetime::{DatePrecision, DateTime};
pub use group_by::GroupByIteratorExtended;
pub use ownedbytes::{OwnedBytes, StableDeref};
pub use serialize::{BinarySerializable, DeserializeFrom, FixedSize};
@@ -107,21 +107,6 @@ pub fn u64_to_f64(val: u64) -> f64 {
})
}
/// Replaces a given byte in the `bytes` slice of bytes.
///
/// This function assumes that the needle is rarely contained in the bytes string
/// and offers a fast path if the needle is not present.
pub fn replace_in_place(needle: u8, replacement: u8, bytes: &mut [u8]) {
if !bytes.contains(&needle) {
return;
}
for b in bytes {
if *b == needle {
*b = replacement;
}
}
}
#[cfg(test)]
pub mod test {
@@ -186,20 +171,4 @@ pub mod test {
assert!(f64_to_u64(-2.0) < f64_to_u64(1.0));
assert!(f64_to_u64(-2.0) < f64_to_u64(-1.5));
}
#[test]
fn test_replace_in_place() {
let test_aux = |before_replacement: &[u8], expected: &[u8]| {
let mut bytes: Vec<u8> = before_replacement.to_vec();
super::replace_in_place(b'b', b'c', &mut bytes);
assert_eq!(&bytes[..], expected);
};
test_aux(b"", b"");
test_aux(b"b", b"c");
test_aux(b"baaa", b"caaa");
test_aux(b"aaab", b"aaac");
test_aux(b"aaabaa", b"aaacaa");
test_aux(b"aaaaaa", b"aaaaaa");
test_aux(b"bbbb", b"cccc");
}
}

58
common/src/serialize.rs
View File

@@ -1,7 +1,9 @@
use std::io::{Read, Write};
use std::{fmt, io};
use crate::VInt;
use byteorder::{ReadBytesExt, WriteBytesExt};
use crate::{Endianness, VInt};
#[derive(Default)]
struct Counter(u64);
@@ -105,13 +107,11 @@ impl<Left: BinarySerializable + FixedSize, Right: BinarySerializable + FixedSize
impl BinarySerializable for u32 {
fn serialize<W: Write + ?Sized>(&self, writer: &mut W) -> io::Result<()> {
writer.write_all(&self.to_le_bytes())
writer.write_u32::<Endianness>(*self)
}
fn deserialize<R: Read>(reader: &mut R) -> io::Result<u32> {
let mut buf = [0u8; 4];
reader.read_exact(&mut buf)?;
Ok(u32::from_le_bytes(buf))
reader.read_u32::<Endianness>()
}
}
@@ -121,13 +121,11 @@ impl FixedSize for u32 {
impl BinarySerializable for u16 {
fn serialize<W: Write + ?Sized>(&self, writer: &mut W) -> io::Result<()> {
writer.write_all(&self.to_le_bytes())
writer.write_u16::<Endianness>(*self)
}
fn deserialize<R: Read>(reader: &mut R) -> io::Result<u16> {
let mut buf = [0u8; 2];
reader.read_exact(&mut buf)?;
Ok(Self::from_le_bytes(buf))
reader.read_u16::<Endianness>()
}
}
@@ -137,12 +135,10 @@ impl FixedSize for u16 {
impl BinarySerializable for u64 {
fn serialize<W: Write + ?Sized>(&self, writer: &mut W) -> io::Result<()> {
writer.write_all(&self.to_le_bytes())
writer.write_u64::<Endianness>(*self)
}
fn deserialize<R: Read>(reader: &mut R) -> io::Result<Self> {
let mut buf = [0u8; 8];
reader.read_exact(&mut buf)?;
Ok(Self::from_le_bytes(buf))
reader.read_u64::<Endianness>()
}
}
@@ -152,12 +148,10 @@ impl FixedSize for u64 {
impl BinarySerializable for u128 {
fn serialize<W: Write + ?Sized>(&self, writer: &mut W) -> io::Result<()> {
writer.write_all(&self.to_le_bytes())
writer.write_u128::<Endianness>(*self)
}
fn deserialize<R: Read>(reader: &mut R) -> io::Result<Self> {
let mut buf = [0u8; 16];
reader.read_exact(&mut buf)?;
Ok(Self::from_le_bytes(buf))
reader.read_u128::<Endianness>()
}
}
@@ -167,12 +161,10 @@ impl FixedSize for u128 {
impl BinarySerializable for f32 {
fn serialize<W: Write + ?Sized>(&self, writer: &mut W) -> io::Result<()> {
writer.write_all(&self.to_le_bytes())
writer.write_f32::<Endianness>(*self)
}
fn deserialize<R: Read>(reader: &mut R) -> io::Result<Self> {
let mut buf = [0u8; 4];
reader.read_exact(&mut buf)?;
Ok(Self::from_le_bytes(buf))
reader.read_f32::<Endianness>()
}
}
@@ -182,12 +174,10 @@ impl FixedSize for f32 {
impl BinarySerializable for i64 {
fn serialize<W: Write + ?Sized>(&self, writer: &mut W) -> io::Result<()> {
writer.write_all(&self.to_le_bytes())
writer.write_i64::<Endianness>(*self)
}
fn deserialize<R: Read>(reader: &mut R) -> io::Result<Self> {
let mut buf = [0u8; Self::SIZE_IN_BYTES];
reader.read_exact(&mut buf)?;
Ok(Self::from_le_bytes(buf))
reader.read_i64::<Endianness>()
}
}
@@ -197,12 +187,10 @@ impl FixedSize for i64 {
impl BinarySerializable for f64 {
fn serialize<W: Write + ?Sized>(&self, writer: &mut W) -> io::Result<()> {
writer.write_all(&self.to_le_bytes())
writer.write_f64::<Endianness>(*self)
}
fn deserialize<R: Read>(reader: &mut R) -> io::Result<Self> {
let mut buf = [0u8; Self::SIZE_IN_BYTES];
reader.read_exact(&mut buf)?;
Ok(Self::from_le_bytes(buf))
reader.read_f64::<Endianness>()
}
}
@@ -212,12 +200,10 @@ impl FixedSize for f64 {
impl BinarySerializable for u8 {
fn serialize<W: Write + ?Sized>(&self, writer: &mut W) -> io::Result<()> {
writer.write_all(&self.to_le_bytes())
writer.write_u8(*self)
}
fn deserialize<R: Read>(reader: &mut R) -> io::Result<Self> {
let mut buf = [0u8; Self::SIZE_IN_BYTES];
reader.read_exact(&mut buf)?;
Ok(Self::from_le_bytes(buf))
fn deserialize<R: Read>(reader: &mut R) -> io::Result<u8> {
reader.read_u8()
}
}
@@ -227,10 +213,10 @@ impl FixedSize for u8 {
impl BinarySerializable for bool {
fn serialize<W: Write + ?Sized>(&self, writer: &mut W) -> io::Result<()> {
(*self as u8).serialize(writer)
writer.write_u8(u8::from(*self))
}
fn deserialize<R: Read>(reader: &mut R) -> io::Result<bool> {
let val = u8::deserialize(reader)?;
let val = reader.read_u8()?;
match val {
0 => Ok(false),
1 => Ok(true),

4
common/src/vint.rs
View File

@@ -1,6 +1,8 @@
use std::io;
use std::io::{Read, Write};
use byteorder::{ByteOrder, LittleEndian};
use super::BinarySerializable;
/// Variable int serializes a u128 number
@@ -125,7 +127,7 @@ pub fn serialize_vint_u32(val: u32, buf: &mut [u8; 8]) -> &[u8] {
5,
),
};
buf.copy_from_slice(&res.to_le_bytes());
LittleEndian::write_u64(&mut buf[..], res);
&buf[0..num_bytes]
}

130
examples-disabled/aggregation.rs Normal file
View File

@@ -0,0 +1,130 @@
// # Aggregation example
//
// This example shows how you can use built-in aggregations.
// We will use range buckets and compute the average in each bucket.
//
use serde_json::Value;
use tantivy::aggregation::agg_req::{
Aggregation, Aggregations, BucketAggregation, BucketAggregationType, MetricAggregation,
RangeAggregation,
};
use tantivy::aggregation::agg_result::AggregationResults;
use tantivy::aggregation::metric::AverageAggregation;
use tantivy::aggregation::AggregationCollector;
use tantivy::query::TermQuery;
use tantivy::schema::{self, IndexRecordOption, Schema, TextFieldIndexing};
use tantivy::{doc, Index, Term};
fn main() -> tantivy::Result<()> {
let mut schema_builder = Schema::builder();
let text_fieldtype = schema::TextOptions::default()
.set_indexing_options(
TextFieldIndexing::default().set_index_option(IndexRecordOption::WithFreqs),
)
.set_stored();
let text_field = schema_builder.add_text_field("text", text_fieldtype);
let score_fieldtype =
crate::schema::NumericOptions::default().set_fast();
let highscore_field = schema_builder.add_f64_field("highscore", score_fieldtype.clone());
let price_field = schema_builder.add_f64_field("price", score_fieldtype);
let schema = schema_builder.build();
// # Indexing documents
//
// Lets index a bunch of documents for this example.
let index = Index::create_in_ram(schema);
let mut index_writer = index.writer(50_000_000)?;
// writing the segment
index_writer.add_document(doc!(
text_field => "cool",
highscore_field => 1f64,
price_field => 0f64,
))?;
index_writer.add_document(doc!(
text_field => "cool",
highscore_field => 3f64,
price_field => 1f64,
))?;
index_writer.add_document(doc!(
text_field => "cool",
highscore_field => 5f64,
price_field => 1f64,
))?;
index_writer.add_document(doc!(
text_field => "nohit",
highscore_field => 6f64,
price_field => 2f64,
))?;
index_writer.add_document(doc!(
text_field => "cool",
highscore_field => 7f64,
price_field => 2f64,
))?;
index_writer.commit()?;
index_writer.add_document(doc!(
text_field => "cool",
highscore_field => 11f64,
price_field => 10f64,
))?;
index_writer.add_document(doc!(
text_field => "cool",
highscore_field => 14f64,
price_field => 15f64,
))?;
index_writer.add_document(doc!(
text_field => "cool",
highscore_field => 15f64,
price_field => 20f64,
))?;
index_writer.commit()?;
let reader = index.reader()?;
let text_field = reader.searcher().schema().get_field("text").unwrap();
let term_query = TermQuery::new(
Term::from_field_text(text_field, "cool"),
IndexRecordOption::Basic,
);
let sub_agg_req_1: Aggregations = vec![(
"average_price".to_string(),
Aggregation::Metric(MetricAggregation::Average(
AverageAggregation::from_field_name("price".to_string()),
)),
)]
.into_iter()
.collect();
let agg_req_1: Aggregations = vec![(
"score_ranges".to_string(),
Aggregation::Bucket(BucketAggregation {
bucket_agg: BucketAggregationType::Range(RangeAggregation {
field: "highscore".to_string(),
ranges: vec![
(-1f64..9f64).into(),
(9f64..14f64).into(),
(14f64..20f64).into(),
],
..Default::default()
}),
sub_aggregation: sub_agg_req_1,
}),
)]
.into_iter()
.collect();
let collector = AggregationCollector::from_aggs(agg_req_1, None, index.schema());
let searcher = reader.searcher();
let agg_res: AggregationResults = searcher.search(&term_query, &collector).unwrap();
let res: Value = serde_json::to_value(agg_res)?;
println!("{}", serde_json::to_string_pretty(&res)?);
Ok(())
}

0
examples/basic_search.rs → examples-disabled/basic_search.rs
View File

20
examples/custom_collector.rs → examples-disabled/custom_collector.rs
View File

@@ -7,7 +7,9 @@
// Of course, you can have a look at the tantivy's built-in collectors
// such as the `CountCollector` for more examples.
use columnar::Column;
use std::sync::Arc;
use fastfield_codecs::Column;
// ---
// Importing tantivy...
use tantivy::collector::{Collector, SegmentCollector};
@@ -95,7 +97,7 @@ impl Collector for StatsCollector {
}
struct StatsSegmentCollector {
fast_field_reader: Column,
fast_field_reader: Arc<dyn Column<u64>>,
stats: Stats,
}
@@ -103,14 +105,10 @@ impl SegmentCollector for StatsSegmentCollector {
type Fruit = Option<Stats>;
fn collect(&mut self, doc: u32, _score: Score) {
// Since we know the values are single value, we could call `first_or_default_col` on the
// column and fetch single values.
for value in self.fast_field_reader.values_for_doc(doc) {
let value = value as f64;
self.stats.count += 1;
self.stats.sum += value;
self.stats.squared_sum += value * value;
}
let value = self.fast_field_reader.get_val(doc) as f64;
self.stats.count += 1;
self.stats.sum += value;
self.stats.squared_sum += value * value;
}
fn harvest(self) -> <Self as SegmentCollector>::Fruit {
@@ -171,7 +169,7 @@ fn main() -> tantivy::Result<()> {
let searcher = reader.searcher();
let query_parser = QueryParser::for_index(&index, vec![product_name, product_description]);
// here we want to search for `broom` and use `StatsCollector` on the hits.
// here we want to get a hit on the 'ken' in Frankenstein
let query = query_parser.parse_query("broom")?;
if let Some(stats) =
searcher.search(&query, &StatsCollector::with_field("price".to_string()))?

4
examples/custom_tokenizer.rs → examples-disabled/custom_tokenizer.rs
View File

@@ -1,7 +1,7 @@
// # Defining a tokenizer pipeline
//
// In this example, we'll see how to define a tokenizer
// by creating a custom `NgramTokenizer`.
// In this example, we'll see how to define a tokenizer pipeline
// by aligning a bunch of `TokenFilter`.
use tantivy::collector::TopDocs;
use tantivy::query::QueryParser;
use tantivy::schema::*;

8
examples/date_time_field.rs → examples-disabled/date_time_field.rs
View File

@@ -14,7 +14,6 @@ fn main() -> tantivy::Result<()> {
.set_stored()
.set_fast()
.set_precision(tantivy::DatePrecision::Seconds);
// Add `occurred_at` date field type
let occurred_at = schema_builder.add_date_field("occurred_at", opts);
let event_type = schema_builder.add_text_field("event", STRING | STORED);
let schema = schema_builder.build();
@@ -23,7 +22,6 @@ fn main() -> tantivy::Result<()> {
let index = Index::create_in_ram(schema.clone());
let mut index_writer = index.writer(50_000_000)?;
// The dates are passed as string in the RFC3339 format
let doc = schema.parse_document(
r#"{
"occurred_at": "2022-06-22T12:53:50.53Z",
@@ -43,16 +41,14 @@ fn main() -> tantivy::Result<()> {
let reader = index.reader()?;
let searcher = reader.searcher();
// # Search
// # Default fields: event_type
let query_parser = QueryParser::for_index(&index, vec![event_type]);
{
// Simple exact search on the date
let query = query_parser.parse_query("occurred_at:\"2022-06-22T12:53:50.53Z\"")?;
let query = query_parser.parse_query("event:comment")?;
let count_docs = searcher.search(&*query, &TopDocs::with_limit(5))?;
assert_eq!(count_docs.len(), 1);
}
{
// Range query on the date field
let query = query_parser
.parse_query(r#"occurred_at:[2022-06-22T12:58:00Z TO 2022-06-23T00:00:00Z}"#)?;
let count_docs = searcher.search(&*query, &TopDocs::with_limit(4))?;

0
examples/deleting_updating_documents.rs → examples-disabled/deleting_updating_documents.rs
View File

4
examples/faceted_search.rs → examples-disabled/faceted_search.rs
View File

@@ -71,7 +71,7 @@ fn main() -> tantivy::Result<()> {
let reader = index.reader()?;
let searcher = reader.searcher();
{
let mut facet_collector = FacetCollector::for_field("classification");
let mut facet_collector = FacetCollector::for_field(classification);
facet_collector.add_facet("/Felidae");
let facet_counts = searcher.search(&AllQuery, &facet_collector)?;
// This lists all of the facet counts, right below "/Felidae".
@@ -97,7 +97,7 @@ fn main() -> tantivy::Result<()> {
let facet = Facet::from("/Felidae/Pantherinae");
let facet_term = Term::from_facet(classification, &facet);
let facet_term_query = TermQuery::new(facet_term, IndexRecordOption::Basic);
let mut facet_collector = FacetCollector::for_field("classification");
let mut facet_collector = FacetCollector::for_field(classification);
facet_collector.add_facet("/Felidae/Pantherinae");
let facet_counts = searcher.search(&facet_term_query, &facet_collector)?;
let facets: Vec<(&Facet, u64)> = facet_counts.get("/Felidae/Pantherinae").collect();

20
examples/faceted_search_with_tweaked_score.rs → examples-disabled/faceted_search_with_tweaked_score.rs
View File

@@ -1,12 +1,3 @@
// # Faceted Search With Tweak Score
//
// This example covers the faceted search functionalities of
// tantivy.
//
// We will :
// - define a text field "name" in our schema
// - define a facet field "classification" in our schema
use std::collections::HashSet;
use tantivy::collector::TopDocs;
@@ -64,9 +55,8 @@ fn main() -> tantivy::Result<()> {
.collect(),
);
let top_docs_by_custom_score =
// Call TopDocs with a custom tweak score
TopDocs::with_limit(2).tweak_score(move |segment_reader: &SegmentReader| {
let ingredient_reader = segment_reader.facet_reader("ingredient").unwrap();
let ingredient_reader = segment_reader.facet_reader(ingredient).unwrap();
let facet_dict = ingredient_reader.facet_dict();
let query_ords: HashSet<u64> = facets
@@ -74,10 +64,12 @@ fn main() -> tantivy::Result<()> {
.filter_map(|key| facet_dict.term_ord(key.encoded_str()).unwrap())
.collect();
let mut facet_ords_buffer: Vec<u64> = Vec::with_capacity(20);
move |doc: DocId, original_score: Score| {
// Update the original score with a tweaked score
let missing_ingredients = ingredient_reader
.facet_ords(doc)
ingredient_reader.facet_ords(doc, &mut facet_ords_buffer);
let missing_ingredients = facet_ords_buffer
.iter()
.filter(|ord| !query_ords.contains(ord))
.count();
let tweak = 1.0 / 4_f32.powi(missing_ingredients as i32);

0
examples/integer_range_search.rs → examples-disabled/integer_range_search.rs
View File

73
examples-disabled/ip_field.rs Normal file
View File

@@ -0,0 +1,73 @@
// # IP Address example
//
// This example shows how the ip field can be used
// with IpV6 and IpV4.
use tantivy::collector::{Count, TopDocs};
use tantivy::query::QueryParser;
use tantivy::schema::{Schema, FAST, INDEXED, STORED, STRING};
use tantivy::Index;
fn main() -> tantivy::Result<()> {
// # Defining the schema
let mut schema_builder = Schema::builder();
let event_type = schema_builder.add_text_field("event_type", STRING | STORED);
let ip = schema_builder.add_ip_addr_field("ip", STORED | INDEXED | FAST);
let schema = schema_builder.build();
// # Indexing documents
let index = Index::create_in_ram(schema.clone());
let mut index_writer = index.writer(50_000_000)?;
let doc = schema.parse_document(
r#"{
"ip": "192.168.0.33",
"event_type": "login"
}"#,
)?;
index_writer.add_document(doc)?;
let doc = schema.parse_document(
r#"{
"ip": "192.168.0.80",
"event_type": "checkout"
}"#,
)?;
index_writer.add_document(doc)?;
let doc = schema.parse_document(
r#"{
"ip": "2001:0db8:85a3:0000:0000:8a2e:0370:7334",
"event_type": "checkout"
}"#,
)?;
index_writer.add_document(doc)?;
index_writer.commit()?;
let reader = index.reader()?;
let searcher = reader.searcher();
let query_parser = QueryParser::for_index(&index, vec![event_type, ip]);
{
let query = query_parser.parse_query("ip:[192.168.0.0 TO 192.168.0.100]")?;
let count_docs = searcher.search(&*query, &TopDocs::with_limit(5))?;
assert_eq!(count_docs.len(), 2);
}
{
let query = query_parser.parse_query("ip:[192.168.1.0 TO 192.168.1.100]")?;
let count_docs = searcher.search(&*query, &TopDocs::with_limit(2))?;
assert_eq!(count_docs.len(), 0);
}
{
let query = query_parser.parse_query("ip:192.168.0.80")?;
let count_docs = searcher.search(&*query, &Count)?;
assert_eq!(count_docs, 1);
}
{
// IpV6 needs to be escaped because it contains `:`
let query = query_parser.parse_query("ip:\"2001:0db8:85a3:0000:0000:8a2e:0370:7334\"")?;
let count_docs = searcher.search(&*query, &Count)?;
assert_eq!(count_docs, 1);
}
Ok(())
}

0
examples/iterating_docs_and_positions.rs → examples-disabled/iterating_docs_and_positions.rs
View File

0
examples/json_field.rs → examples-disabled/json_field.rs
View File

0
examples/index_from_multiple_threads.rs → examples-disabled/multiple_producer.rs
View File

0
examples/pre_tokenized_text.rs → examples-disabled/pre_tokenized_text.rs
View File

0
examples/snippet.rs → examples-disabled/snippet.rs
View File

0
examples/stop_words.rs → examples-disabled/stop_words.rs
View File

14
examples/warmer.rs → examples-disabled/warmer.rs
View File

@@ -17,6 +17,7 @@ use tantivy::{
type ProductId = u64;
/// Price
type Price = u32;
pub trait PriceFetcher: Send + Sync + 'static {
@@ -47,10 +48,7 @@ impl Warmer for DynamicPriceColumn {
fn warm(&self, searcher: &Searcher) -> tantivy::Result<()> {
for segment in searcher.segment_readers() {
let key = (segment.segment_id(), segment.delete_opstamp());
let product_id_reader = segment
.fast_fields()
.u64(&self.field)?
.first_or_default_col(0);
let product_id_reader = segment.fast_fields().u64(&self.field)?;
let product_ids: Vec<ProductId> = segment
.doc_ids_alive()
.map(|doc| product_id_reader.get_val(doc))
@@ -89,10 +87,10 @@ impl Warmer for DynamicPriceColumn {
}
}
// For the sake of this example, the table is just an editable HashMap behind a RwLock.
// This map represents a map (ProductId -> Price)
//
// In practise, it could be fetching things from an external service, like a SQL table.
/// For the sake of this example, the table is just an editable HashMap behind a RwLock.
/// This map represents a map (ProductId -> Price)
///
/// In practise, it could be fetching things from an external service, like a SQL table.
#[derive(Default, Clone)]
pub struct ExternalPriceTable {
prices: Arc<RwLock<HashMap<ProductId, Price>>>,

0
examples/index_with_json.rs → examples-disabled/working_with_json.rs
View File

319
examples/aggregation.rs
View File

@@ -1,319 +0,0 @@
// # Aggregation example
//
// This example shows how you can use built-in aggregations.
// We will use nested aggregations with buckets and metrics:
// - Range buckets and compute the average in each bucket.
// - Term aggregation and compute the min price in each bucket
// ---
use serde_json::{Deserializer, Value};
use tantivy::aggregation::agg_req::{
Aggregation, Aggregations, BucketAggregation, BucketAggregationType, MetricAggregation,
RangeAggregation,
};
use tantivy::aggregation::agg_result::AggregationResults;
use tantivy::aggregation::bucket::RangeAggregationRange;
use tantivy::aggregation::metric::AverageAggregation;
use tantivy::aggregation::AggregationCollector;
use tantivy::query::AllQuery;
use tantivy::schema::{self, IndexRecordOption, Schema, TextFieldIndexing, FAST};
use tantivy::Index;
fn main() -> tantivy::Result<()> {
// # Create Schema
//
// Lets create a schema for a footwear shop, with 4 fields: name, category, stock and price.
// category, stock and price will be fast fields as that's the requirement
// for aggregation queries.
//
let mut schema_builder = Schema::builder();
// In preparation of the `TermsAggregation`, the category field is configured with:
// - `set_fast`
// - `raw` tokenizer
//
// The tokenizer is set to "raw", because the fast field uses the same dictionary as the
// inverted index. (This behaviour will change in tantivy 0.20, where the fast field will
// always be raw tokenized independent from the regular tokenizing)
//
let text_fieldtype = schema::TextOptions::default()
.set_indexing_options(
TextFieldIndexing::default()
.set_index_option(IndexRecordOption::WithFreqs)
.set_tokenizer("raw"),
)
.set_fast()
.set_stored();
schema_builder.add_text_field("category", text_fieldtype);
schema_builder.add_f64_field("stock", FAST);
schema_builder.add_f64_field("price", FAST);
let schema = schema_builder.build();
// # Indexing documents
//
// Lets index a bunch of documents for this example.
let index = Index::create_in_ram(schema.clone());
let data = r#"{
"name": "Almond Toe Court Shoes, Patent Black",
"category": "Womens Footwear",
"price": 99.00,
"stock": 5
}
{
"name": "Suede Shoes, Blue",
"category": "Womens Footwear",
"price": 42.00,
"stock": 4
}
{
"name": "Leather Driver Saddle Loafers, Tan",
"category": "Mens Footwear",
"price": 34.00,
"stock": 12
}
{
"name": "Flip Flops, Red",
"category": "Mens Footwear",
"price": 19.00,
"stock": 6
}
{
"name": "Flip Flops, Blue",
"category": "Mens Footwear",
"price": 19.00,
"stock": 0
}
{
"name": "Gold Button Cardigan, Black",
"category": "Womens Casualwear",
"price": 167.00,
"stock": 6
}
{
"name": "Cotton Shorts, Medium Red",
"category": "Womens Casualwear",
"price": 30.00,
"stock": 5
}
{
"name": "Fine Stripe Short SleeveShirt, Grey",
"category": "Mens Casualwear",
"price": 49.99,
"stock": 9
}
{
"name": "Fine Stripe Short SleeveShirt, Green",
"category": "Mens Casualwear",
"price": 49.99,
"offer": 39.99,
"stock": 9
}
{
"name": "Sharkskin Waistcoat, Charcoal",
"category": "Mens Formalwear",
"price": 75.00,
"stock": 2
}
{
"name": "Lightweight Patch PocketBlazer, Deer",
"category": "Mens Formalwear",
"price": 175.50,
"stock": 1
}
{
"name": "Bird Print Dress, Black",
"category": "Womens Formalwear",
"price": 270.00,
"stock": 10
}
{
"name": "Mid Twist Cut-Out Dress, Pink",
"category": "Womens Formalwear",
"price": 540.00,
"stock": 5
}"#;
let stream = Deserializer::from_str(data).into_iter::<Value>();
let mut index_writer = index.writer(50_000_000)?;
let mut num_indexed = 0;
for value in stream {
let doc = schema.parse_document(&serde_json::to_string(&value.unwrap())?)?;
index_writer.add_document(doc)?;
num_indexed += 1;
if num_indexed > 4 {
// Writing the first segment
index_writer.commit()?;
}
}
// Writing the second segment
index_writer.commit()?;
// We have two segments now. The `AggregationCollector` will run the aggregation on each
// segment and then merge the results into an `IntermediateAggregationResult`.
let reader = index.reader()?;
let searcher = reader.searcher();
// ---
// # Aggregation Query
//
//
// We can construct the query by building the request structure or by deserializing from JSON.
// The JSON API is more stable and therefore recommended.
//
// ## Request 1
let agg_req_str = r#"
{
"group_by_stock": {
"aggs": {
"average_price": { "avg": { "field": "price" } }
},
"range": {
"field": "stock",
"ranges": [
{ "key": "few", "to": 1.0 },
{ "key": "some", "from": 1.0, "to": 10.0 },
{ "key": "many", "from": 10.0 }
]
}
}
} "#;
// In this Aggregation we want to get the average price for different groups, depending on how
// many items are in stock. We define custom ranges `few`, `some`, `many` via the
// range aggregation.
// For every bucket we want the average price, so we create a nested metric aggregation on the
// range bucket aggregation. Only buckets support nested aggregations.
// ### Request JSON API
//
let agg_req: Aggregations = serde_json::from_str(agg_req_str)?;
let collector = AggregationCollector::from_aggs(agg_req, None);
let agg_res: AggregationResults = searcher.search(&AllQuery, &collector).unwrap();
let res2: Value = serde_json::to_value(agg_res)?;
// ### Request Rust API
//
// This is exactly the same request as above, but via the rust structures.
//
let agg_req: Aggregations = vec![(
"group_by_stock".to_string(),
Aggregation::Bucket(BucketAggregation {
bucket_agg: BucketAggregationType::Range(RangeAggregation {
field: "stock".to_string(),
ranges: vec![
RangeAggregationRange {
key: Some("few".into()),
from: None,
to: Some(1f64),
},
RangeAggregationRange {
key: Some("some".into()),
from: Some(1f64),
to: Some(10f64),
},
RangeAggregationRange {
key: Some("many".into()),
from: Some(10f64),
to: None,
},
],
..Default::default()
}),
sub_aggregation: vec![(
"average_price".to_string(),
Aggregation::Metric(MetricAggregation::Average(
AverageAggregation::from_field_name("price".to_string()),
)),
)]
.into_iter()
.collect(),
}),
)]
.into_iter()
.collect();
let collector = AggregationCollector::from_aggs(agg_req, None);
// We use the `AllQuery` which will pass all documents to the AggregationCollector.
let agg_res: AggregationResults = searcher.search(&AllQuery, &collector).unwrap();
let res1: Value = serde_json::to_value(agg_res)?;
// ### Aggregation Result
//
// The resulting structure deserializes in the same JSON format as elastic search.
//
let expected_res = r#"
{
"group_by_stock":{
"buckets":[
{"average_price":{"value":19.0},"doc_count":1,"key":"few","to":1.0},
{"average_price":{"value":124.748},"doc_count":10,"from":1.0,"key":"some","to":10.0},
{"average_price":{"value":152.0},"doc_count":2,"from":10.0,"key":"many"}
]
}
}
"#;
let expected_json: Value = serde_json::from_str(expected_res)?;
assert_eq!(expected_json, res1);
assert_eq!(expected_json, res2);
// ### Request 2
//
// Now we are interested in the minimum price per category, so we create a bucket per
// category via `TermsAggregation`. We are interested in the highest minimum prices, and set the
// order of the buckets `"order": { "min_price": "desc" }` to be sorted by the the metric of
// the sub aggregation. (awesome)
//
let agg_req_str = r#"
{
"min_price_per_category": {
"aggs": {
"min_price": { "min": { "field": "price" } }
},
"terms": {
"field": "category",
"min_doc_count": 1,
"order": { "min_price": "desc" }
}
}
} "#;
let agg_req: Aggregations = serde_json::from_str(agg_req_str)?;
let collector = AggregationCollector::from_aggs(agg_req, None);
let agg_res: AggregationResults = searcher.search(&AllQuery, &collector).unwrap();
let res: Value = serde_json::to_value(agg_res)?;
// Minimum price per category, sorted by minimum price descending
//
// As you can see, the starting prices for `Formalwear` are higher than `Casualwear`.
//
let expected_res = r#"
{
"min_price_per_category": {
"buckets": [
{ "doc_count": 2, "key": "Womens Formalwear", "min_price": { "value": 270.0 } },
{ "doc_count": 2, "key": "Mens Formalwear", "min_price": { "value": 75.0 } },
{ "doc_count": 2, "key": "Mens Casualwear", "min_price": { "value": 49.99 } },
{ "doc_count": 2, "key": "Womens Footwear", "min_price": { "value": 42.0 } },
{ "doc_count": 2, "key": "Womens Casualwear", "min_price": { "value": 30.0 } },
{ "doc_count": 3, "key": "Mens Footwear", "min_price": { "value": 19.0 } }
],
"sum_other_doc_count": 0
}
}
"#;
let expected_json: Value = serde_json::from_str(expected_res)?;
assert_eq!(expected_json, res);
Ok(())
}

167
examples/fuzzy_search.rs
View File

@@ -1,167 +0,0 @@
// # Basic Example
//
// This example covers the basic functionalities of
// tantivy.
//
// We will :
// - define our schema
// - create an index in a directory
// - index a few documents into our index
// - search for the best document matching a basic query
// - retrieve the best document's original content.
// ---
// Importing tantivy...
use tantivy::collector::{Count, TopDocs};
use tantivy::query::FuzzyTermQuery;
use tantivy::schema::*;
use tantivy::{doc, Index, ReloadPolicy};
use tempfile::TempDir;
fn main() -> tantivy::Result<()> {
// Let's create a temporary directory for the
// sake of this example
let index_path = TempDir::new()?;
// # Defining the schema
//
// The Tantivy index requires a very strict schema.
// The schema declares which fields are in the index,
// and for each field, its type and "the way it should
// be indexed".
// First we need to define a schema ...
let mut schema_builder = Schema::builder();
// Our first field is title.
// We want full-text search for it, and we also want
// to be able to retrieve the document after the search.
//
// `TEXT | STORED` is some syntactic sugar to describe
// that.
//
// `TEXT` means the field should be tokenized and indexed,
// along with its term frequency and term positions.
//
// `STORED` means that the field will also be saved
// in a compressed, row-oriented key-value store.
// This store is useful for reconstructing the
// documents that were selected during the search phase.
let title = schema_builder.add_text_field("title", TEXT | STORED);
let schema = schema_builder.build();
// # Indexing documents
//
// Let's create a brand new index.
//
// This will actually just save a meta.json
// with our schema in the directory.
let index = Index::create_in_dir(&index_path, schema.clone())?;
// To insert a document we will need an index writer.
// There must be only one writer at a time.
// This single `IndexWriter` is already
// multithreaded.
//
// Here we give tantivy a budget of `50MB`.
// Using a bigger memory_arena for the indexer may increase
// throughput, but 50 MB is already plenty.
let mut index_writer = index.writer(50_000_000)?;
// Let's index our documents!
// We first need a handle on the title and the body field.
// ### Adding documents
//
index_writer.add_document(doc!(
title => "The Name of the Wind",
))?;
index_writer.add_document(doc!(
title => "The Diary of Muadib",
))?;
index_writer.add_document(doc!(
title => "A Dairy Cow",
))?;
index_writer.add_document(doc!(
title => "The Diary of a Young Girl",
))?;
index_writer.commit()?;
// ### Committing
//
// At this point our documents are not searchable.
//
//
// We need to call `.commit()` explicitly to force the
// `index_writer` to finish processing the documents in the queue,
// flush the current index to the disk, and advertise
// the existence of new documents.
//
// This call is blocking.
index_writer.commit()?;
// If `.commit()` returns correctly, then all of the
// documents that have been added are guaranteed to be
// persistently indexed.
//
// In the scenario of a crash or a power failure,
// tantivy behaves as if it has rolled back to its last
// commit.
// # Searching
//
// ### Searcher
//
// A reader is required first in order to search an index.
// It acts as a `Searcher` pool that reloads itself,
// depending on a `ReloadPolicy`.
//
// For a search server you will typically create one reader for the entire lifetime of your
// program, and acquire a new searcher for every single request.
//
// In the code below, we rely on the 'ON_COMMIT' policy: the reader
// will reload the index automatically after each commit.
let reader = index
.reader_builder()
.reload_policy(ReloadPolicy::OnCommit)
.try_into()?;
// We now need to acquire a searcher.
//
// A searcher points to a snapshotted, immutable version of the index.
//
// Some search experience might require more than
// one query. Using the same searcher ensures that all of these queries will run on the
// same version of the index.
//
// Acquiring a `searcher` is very cheap.
//
// You should acquire a searcher every time you start processing a request and
// and release it right after your query is finished.
let searcher = reader.searcher();
// ### FuzzyTermQuery
{
let term = Term::from_field_text(title, "Diary");
let query = FuzzyTermQuery::new(term, 2, true);
let (top_docs, count) = searcher
.search(&query, &(TopDocs::with_limit(5), Count))
.unwrap();
assert_eq!(count, 3);
assert_eq!(top_docs.len(), 3);
for (score, doc_address) in top_docs {
let retrieved_doc = searcher.doc(doc_address)?;
// Note that the score is not lower for the fuzzy hit.
// There's an issue open for that: https://github.com/quickwit-oss/tantivy/issues/563
println!("score {score:?} doc {}", schema.to_json(&retrieved_doc));
// score 1.0 doc {"title":["The Diary of Muadib"]}
//
// score 1.0 doc {"title":["The Diary of a Young Girl"]}
//
// score 1.0 doc {"title":["A Dairy Cow"]}
}
}
Ok(())
}

107
examples/ip_field.rs
View File

@@ -1,107 +0,0 @@
// # IP Address example
//
// This example shows how the ip field can be used
// with IpV6 and IpV4.
use tantivy::collector::{Count, TopDocs};
use tantivy::query::QueryParser;
use tantivy::schema::{Schema, FAST, INDEXED, STORED, STRING};
use tantivy::Index;
fn main() -> tantivy::Result<()> {
// # Defining the schema
// We set the IP field as `INDEXED`, so it can be searched
// `FAST` will create a fast field. The fast field will be used to execute search queries.
// `FAST` is not a requirement for range queries, it can also be executed on the inverted index
// which is created by `INDEXED`.
let mut schema_builder = Schema::builder();
let event_type = schema_builder.add_text_field("event_type", STRING | STORED);
let ip = schema_builder.add_ip_addr_field("ip", STORED | INDEXED | FAST);
let schema = schema_builder.build();
// # Indexing documents
let index = Index::create_in_ram(schema.clone());
let mut index_writer = index.writer(50_000_000)?;
// ### IPv4
// Adding documents that contain an IPv4 address. Notice that the IP addresses are passed as
// `String`. Since the field is of type ip, we parse the IP address from the string and store it
// internally as IPv6.
let doc = schema.parse_document(
r#"{
"ip": "192.168.0.33",
"event_type": "login"
}"#,
)?;
index_writer.add_document(doc)?;
let doc = schema.parse_document(
r#"{
"ip": "192.168.0.80",
"event_type": "checkout"
}"#,
)?;
index_writer.add_document(doc)?;
// ### IPv6
// Adding a document that contains an IPv6 address.
let doc = schema.parse_document(
r#"{
"ip": "2001:0db8:85a3:0000:0000:8a2e:0370:7334",
"event_type": "checkout"
}"#,
)?;
index_writer.add_document(doc)?;
// Commit will create a segment containing our documents.
index_writer.commit()?;
let reader = index.reader()?;
let searcher = reader.searcher();
// # Search
// Range queries on IPv4. Since we created a fast field, the fast field will be used to execute
// the search.
// ### Range Queries
let query_parser = QueryParser::for_index(&index, vec![event_type, ip]);
{
// Inclusive range queries
let query = query_parser.parse_query("ip:[192.168.0.80 TO 192.168.0.100]")?;
let count_docs = searcher.search(&*query, &TopDocs::with_limit(5))?;
assert_eq!(count_docs.len(), 1);
}
{
// Exclusive range queries
let query = query_parser.parse_query("ip:{192.168.0.80 TO 192.168.1.100]")?;
let count_docs = searcher.search(&*query, &TopDocs::with_limit(2))?;
assert_eq!(count_docs.len(), 0);
}
{
// Find docs with IP addresses smaller equal 192.168.1.100
let query = query_parser.parse_query("ip:[* TO 192.168.1.100]")?;
let count_docs = searcher.search(&*query, &TopDocs::with_limit(2))?;
assert_eq!(count_docs.len(), 2);
}
{
// Find docs with IP addresses smaller than 192.168.1.100
let query = query_parser.parse_query("ip:[* TO 192.168.1.100}")?;
let count_docs = searcher.search(&*query, &TopDocs::with_limit(2))?;
assert_eq!(count_docs.len(), 2);
}
// ### Exact Queries
// Exact search on IPv4.
{
let query = query_parser.parse_query("ip:192.168.0.80")?;
let count_docs = searcher.search(&*query, &Count)?;
assert_eq!(count_docs, 1);
}
// Exact search on IPv6.
// IpV6 addresses need to be quoted because they contain `:`
{
let query = query_parser.parse_query("ip:\"2001:0db8:85a3:0000:0000:8a2e:0370:7334\"")?;
let count_docs = searcher.search(&*query, &Count)?;
assert_eq!(count_docs, 1);
}
Ok(())
}

62
src/aggregation/agg_req.rs
View File

@@ -50,7 +50,7 @@ use std::collections::{HashMap, HashSet};
use serde::{Deserialize, Serialize};
pub use super::bucket::RangeAggregation;
use super::bucket::{DateHistogramAggregationReq, HistogramAggregation, TermsAggregation};
use super::bucket::{HistogramAggregation, TermsAggregation};
use super::metric::{
AverageAggregation, CountAggregation, MaxAggregation, MinAggregation, StatsAggregation,
SumAggregation,
@@ -110,13 +110,10 @@ impl BucketAggregationInternal {
_ => None,
}
}
pub(crate) fn as_histogram(&self) -> crate::Result<Option<HistogramAggregation>> {
pub(crate) fn as_histogram(&self) -> Option<&HistogramAggregation> {
match &self.bucket_agg {
BucketAggregationType::Histogram(histogram) => Ok(Some(histogram.clone())),
BucketAggregationType::DateHistogram(histogram) => {
Ok(Some(histogram.to_histogram_req()?))
}
_ => Ok(None),
BucketAggregationType::Histogram(histogram) => Some(histogram),
_ => None,
}
}
pub(crate) fn as_term(&self) -> Option<&TermsAggregation> {
@@ -127,6 +124,15 @@ impl BucketAggregationInternal {
}
}
/// Extract all fields, where the term directory is used in the tree.
pub fn get_term_dict_field_names(aggs: &Aggregations) -> HashSet<String> {
let mut term_dict_field_names = Default::default();
for el in aggs.values() {
el.get_term_dict_field_names(&mut term_dict_field_names)
}
term_dict_field_names
}
/// Extract all fast field names used in the tree.
pub fn get_fast_field_names(aggs: &Aggregations) -> HashSet<String> {
let mut fast_field_names = Default::default();
@@ -149,12 +155,16 @@ pub enum Aggregation {
}
impl Aggregation {
fn get_term_dict_field_names(&self, term_field_names: &mut HashSet<String>) {
if let Aggregation::Bucket(bucket) = self {
bucket.get_term_dict_field_names(term_field_names)
}
}
fn get_fast_field_names(&self, fast_field_names: &mut HashSet<String>) {
match self {
Aggregation::Bucket(bucket) => bucket.get_fast_field_names(fast_field_names),
Aggregation::Metric(metric) => {
fast_field_names.insert(metric.get_fast_field_name().to_string());
}
Aggregation::Metric(metric) => metric.get_fast_field_names(fast_field_names),
}
}
}
@@ -183,9 +193,14 @@ pub struct BucketAggregation {
}
impl BucketAggregation {
fn get_term_dict_field_names(&self, term_dict_field_names: &mut HashSet<String>) {
if let BucketAggregationType::Terms(terms) = &self.bucket_agg {
term_dict_field_names.insert(terms.field.to_string());
}
term_dict_field_names.extend(get_term_dict_field_names(&self.sub_aggregation));
}
fn get_fast_field_names(&self, fast_field_names: &mut HashSet<String>) {
let fast_field_name = self.bucket_agg.get_fast_field_name();
fast_field_names.insert(fast_field_name.to_string());
self.bucket_agg.get_fast_field_names(fast_field_names);
fast_field_names.extend(get_fast_field_names(&self.sub_aggregation));
}
}
@@ -199,22 +214,20 @@ pub enum BucketAggregationType {
/// Put data into buckets of user-defined ranges.
#[serde(rename = "histogram")]
Histogram(HistogramAggregation),
/// Put data into buckets of user-defined ranges.
#[serde(rename = "date_histogram")]
DateHistogram(DateHistogramAggregationReq),
/// Put data into buckets of terms.
#[serde(rename = "terms")]
Terms(TermsAggregation),
}
impl BucketAggregationType {
fn get_fast_field_name(&self) -> &str {
fn get_fast_field_names(&self, fast_field_names: &mut HashSet<String>) {
match self {
BucketAggregationType::Terms(terms) => terms.field.as_str(),
BucketAggregationType::Range(range) => range.field.as_str(),
BucketAggregationType::Histogram(histogram) => histogram.field.as_str(),
BucketAggregationType::DateHistogram(histogram) => histogram.field.as_str(),
}
BucketAggregationType::Terms(terms) => fast_field_names.insert(terms.field.to_string()),
BucketAggregationType::Range(range) => fast_field_names.insert(range.field.to_string()),
BucketAggregationType::Histogram(histogram) => {
fast_field_names.insert(histogram.field.to_string())
}
};
}
}
@@ -249,15 +262,16 @@ pub enum MetricAggregation {
}
impl MetricAggregation {
fn get_fast_field_name(&self) -> &str {
match self {
fn get_fast_field_names(&self, fast_field_names: &mut HashSet<String>) {
let fast_field_name = match self {
MetricAggregation::Average(avg) => avg.field_name(),
MetricAggregation::Count(count) => count.field_name(),
MetricAggregation::Max(max) => max.field_name(),
MetricAggregation::Min(min) => min.field_name(),
MetricAggregation::Stats(stats) => stats.field_name(),
MetricAggregation::Sum(sum) => sum.field_name(),
}
};
fast_field_names.insert(fast_field_name.to_string());
}
}

105
src/aggregation/agg_req_with_accessor.rs
View File

@@ -2,20 +2,21 @@
use std::rc::Rc;
use std::sync::atomic::AtomicU32;
use std::sync::Arc;
use columnar::{Column, ColumnType, StrColumn};
use fastfield_codecs::Column;
use super::agg_req::{Aggregation, Aggregations, BucketAggregationType, MetricAggregation};
use super::bucket::{
DateHistogramAggregationReq, HistogramAggregation, RangeAggregation, TermsAggregation,
};
use super::bucket::{HistogramAggregation, RangeAggregation, TermsAggregation};
use super::metric::{
AverageAggregation, CountAggregation, MaxAggregation, MinAggregation, StatsAggregation,
SumAggregation,
};
use super::segment_agg_result::BucketCount;
use super::VecWithNames;
use crate::{SegmentReader, TantivyError};
use crate::fastfield::{type_and_cardinality, MultiValuedFastFieldReader};
use crate::schema::Type;
use crate::{InvertedIndexReader, SegmentReader, TantivyError};
#[derive(Clone, Default)]
pub(crate) struct AggregationsWithAccessor {
@@ -36,13 +37,39 @@ impl AggregationsWithAccessor {
}
}
#[derive(Clone)]
pub(crate) enum FastFieldAccessor {
Multi(MultiValuedFastFieldReader<u64>),
Single(Arc<dyn Column<u64>>),
}
impl FastFieldAccessor {
pub fn as_single(&self) -> Option<&dyn Column<u64>> {
match self {
FastFieldAccessor::Multi(_) => None,
FastFieldAccessor::Single(reader) => Some(&**reader),
}
}
pub fn into_single(self) -> Option<Arc<dyn Column<u64>>> {
match self {
FastFieldAccessor::Multi(_) => None,
FastFieldAccessor::Single(reader) => Some(reader),
}
}
pub fn as_multi(&self) -> Option<&MultiValuedFastFieldReader<u64>> {
match self {
FastFieldAccessor::Multi(reader) => Some(reader),
FastFieldAccessor::Single(_) => None,
}
}
}
#[derive(Clone)]
pub struct BucketAggregationWithAccessor {
/// In general there can be buckets without fast field access, e.g. buckets that are created
/// based on search terms. So eventually this needs to be Option or moved.
pub(crate) accessor: Column<u64>,
pub(crate) str_dict_column: Option<StrColumn>,
pub(crate) field_type: ColumnType,
pub(crate) accessor: FastFieldAccessor,
pub(crate) inverted_index: Option<Arc<InvertedIndexReader>>,
pub(crate) field_type: Type,
pub(crate) bucket_agg: BucketAggregationType,
pub(crate) sub_aggregation: AggregationsWithAccessor,
pub(crate) bucket_count: BucketCount,
@@ -56,23 +83,20 @@ impl BucketAggregationWithAccessor {
bucket_count: Rc<AtomicU32>,
max_bucket_count: u32,
) -> crate::Result<BucketAggregationWithAccessor> {
let mut str_dict_column = None;
let mut inverted_index = None;
let (accessor, field_type) = match &bucket {
BucketAggregationType::Range(RangeAggregation {
field: field_name, ..
}) => get_ff_reader_and_validate(reader, field_name)?,
}) => get_ff_reader_and_validate(reader, field_name, Cardinality::SingleValue)?,
BucketAggregationType::Histogram(HistogramAggregation {
field: field_name, ..
}) => get_ff_reader_and_validate(reader, field_name)?,
BucketAggregationType::DateHistogram(DateHistogramAggregationReq {
field: field_name,
..
}) => get_ff_reader_and_validate(reader, field_name)?,
}) => get_ff_reader_and_validate(reader, field_name, Cardinality::SingleValue)?,
BucketAggregationType::Terms(TermsAggregation {
field: field_name, ..
}) => {
str_dict_column = reader.fast_fields().str(field_name)?;
get_ff_reader_and_validate(reader, field_name)?
let field = reader.schema().get_field(field_name)?;
inverted_index = Some(reader.inverted_index(field)?);
get_ff_reader_and_validate(reader, field_name, Cardinality::MultiValues)?
}
};
let sub_aggregation = sub_aggregation.clone();
@@ -86,7 +110,7 @@ impl BucketAggregationWithAccessor {
max_bucket_count,
)?,
bucket_agg: bucket.clone(),
str_dict_column,
inverted_index,
bucket_count: BucketCount {
bucket_count,
max_bucket_count,
@@ -99,8 +123,8 @@ impl BucketAggregationWithAccessor {
#[derive(Clone)]
pub struct MetricAggregationWithAccessor {
pub metric: MetricAggregation,
pub field_type: ColumnType,
pub accessor: Column<u64>,
pub field_type: Type,
pub accessor: Arc<dyn Column>,
}
impl MetricAggregationWithAccessor {
@@ -115,10 +139,13 @@ impl MetricAggregationWithAccessor {
| MetricAggregation::Min(MinAggregation { field: field_name })
| MetricAggregation::Stats(StatsAggregation { field: field_name })
| MetricAggregation::Sum(SumAggregation { field: field_name }) => {
let (accessor, field_type) = get_ff_reader_and_validate(reader, field_name)?;
let (accessor, field_type) =
get_ff_reader_and_validate(reader, field_name, Cardinality::SingleValue)?;
Ok(MetricAggregationWithAccessor {
accessor,
accessor: accessor
.into_single()
.expect("unexpected fast field cardinality"),
field_type,
metric: metric.clone(),
})
@@ -163,12 +190,32 @@ pub(crate) fn get_aggs_with_accessor_and_validate(
fn get_ff_reader_and_validate(
reader: &SegmentReader,
field_name: &str,
) -> crate::Result<(columnar::Column<u64>, ColumnType)> {
cardinality: Cardinality,
) -> crate::Result<(FastFieldAccessor, Type)> {
let field = reader.schema().get_field(field_name)?;
let field_type = reader.schema().get_field_entry(field).field_type();
if let Some((_ff_type, field_cardinality)) = type_and_cardinality(field_type) {
if cardinality != field_cardinality {
return Err(TantivyError::InvalidArgument(format!(
"Invalid field cardinality on field {} expected {:?}, but got {:?}",
field_name, cardinality, field_cardinality
)));
}
} else {
return Err(TantivyError::InvalidArgument(format!(
"Only fast fields of type f64, u64, i64 are supported, but got {:?} ",
field_type.value_type()
)));
};
let ff_fields = reader.fast_fields();
let ff_field_with_type = ff_fields
.u64_lenient_with_type(field_name)?
.ok_or_else(|| {
TantivyError::InvalidArgument(format!("No fast field found for field: {}", field_name))
})?;
Ok(ff_field_with_type)
match cardinality {
Cardinality::SingleValue => ff_fields
.u64_lenient(field_name)
.map(|field| (FastFieldAccessor::Single(field), field_type.value_type())),
Cardinality::MultiValues => ff_fields
.u64s_lenient(field_name)
.map(|field| (FastFieldAccessor::Multi(field), field_type.value_type())),
}
}

8
src/aggregation/agg_result.rs
View File

@@ -12,6 +12,7 @@ use super::bucket::GetDocCount;
use super::intermediate_agg_result::{IntermediateBucketResult, IntermediateMetricResult};
use super::metric::{SingleMetricResult, Stats};
use super::Key;
use crate::schema::Schema;
use crate::TantivyError;
#[derive(Clone, Default, Debug, PartialEq, Serialize, Deserialize)]
@@ -153,9 +154,12 @@ pub enum BucketResult {
}
impl BucketResult {
pub(crate) fn empty_from_req(req: &BucketAggregationInternal) -> crate::Result<Self> {
pub(crate) fn empty_from_req(
req: &BucketAggregationInternal,
schema: &Schema,
) -> crate::Result<Self> {
let empty_bucket = IntermediateBucketResult::empty_from_req(&req.bucket_agg);
empty_bucket.into_final_bucket_result(req)
empty_bucket.into_final_bucket_result(req, schema)
}
}

1174
src/aggregation/agg_tests.rs
View File

File diff suppressed because it is too large Load Diff

475
src/aggregation/bucket/histogram/date_histogram.rs
View File

@@ -1,475 +0,0 @@
use serde::{Deserialize, Serialize};
use super::{HistogramAggregation, HistogramBounds};
use crate::aggregation::AggregationError;
/// DateHistogramAggregation is similar to `HistogramAggregation`, but it can only be used with date
/// type.
///
/// Currently only **fixed time** intervals are supported. Calendar-aware time intervals are not
/// supported.
///
/// Like the histogram, values are rounded down into the closest bucket.
///
/// For this calculation all fastfield values are converted to f64.
///
/// # Limitations/Compatibility
/// Only fixed time intervals are supported.
///
/// # JSON Format
/// ```json
/// {
/// "prices": {
/// "date_histogram": {
/// "field": "price",
/// "fixed_interval": "30d"
/// }
/// }
/// }
/// ```
///
/// Response
/// See [`BucketEntry`](crate::aggregation::agg_result::BucketEntry)
#[derive(Clone, Debug, Default, PartialEq, Serialize, Deserialize)]
pub struct DateHistogramAggregationReq {
#[doc(hidden)]
/// Only for validation
interval: Option<String>,
#[doc(hidden)]
/// Only for validation
date_interval: Option<String>,
/// The field to aggregate on.
pub field: String,
/// The format to format dates.
pub format: Option<String>,
/// The interval to chunk your data range. Each bucket spans a value range of
/// [0..fixed_interval). Accepted values
///
/// Fixed intervals are configured with the `fixed_interval` parameter.
/// In contrast to calendar-aware intervals, fixed intervals are a fixed number of SI units and
/// never deviate, regardless of where they fall on the calendar. One second is always
/// composed of 1000ms. This allows fixed intervals to be specified in any multiple of the
/// supported units. However, it means fixed intervals cannot express other units such as
/// months, since the duration of a month is not a fixed quantity. Attempting to specify a
/// calendar interval like month or quarter will return an Error.
///
/// The accepted units for fixed intervals are:
/// * `ms`: milliseconds
/// * `s`: seconds. Defined as 1000 milliseconds each.
/// * `m`: minutes. Defined as 60 seconds each (60_000 milliseconds).
/// * `h`: hours. Defined as 60 minutes each (3_600_000 milliseconds).
/// * `d`: days. Defined as 24 hours (86_400_000 milliseconds).
///
/// Fractional time values are not supported, but you can address this by shifting to another
/// time unit (e.g., `1.5h` could instead be specified as `90m`).
pub fixed_interval: String,
/// Intervals implicitly defines an absolute grid of buckets `[interval * k, interval * (k +
/// 1))`.
pub offset: Option<String>,
/// The minimum number of documents in a bucket to be returned. Defaults to 0.
pub min_doc_count: Option<u64>,
/// Limits the data range to `[min, max]` closed interval.
///
/// This can be used to filter values if they are not in the data range.
///
/// hard_bounds only limits the buckets, to force a range set both extended_bounds and
/// hard_bounds to the same range.
///
/// Needs to be provided as timestamp in microseconds precision.
///
/// ## Example
/// ```json
/// {
/// "sales_over_time": {
/// "date_histogram": {
/// "field": "dates",
/// "interval": "1d",
/// "hard_bounds": {
/// "min": 0,
/// "max": 1420502400000000
/// }
/// }
/// }
/// }
/// ```
pub hard_bounds: Option<HistogramBounds>,
/// Can be set to extend your bounds. The range of the buckets is by default defined by the
/// data range of the values of the documents. As the name suggests, this can only be used to
/// extend the value range. If the bounds for min or max are not extending the range, the value
/// has no effect on the returned buckets.
///
/// Cannot be set in conjunction with min_doc_count > 0, since the empty buckets from extended
/// bounds would not be returned.
pub extended_bounds: Option<HistogramBounds>,
/// Whether to return the buckets as a hash map
#[serde(default)]
pub keyed: bool,
}
impl DateHistogramAggregationReq {
pub(crate) fn to_histogram_req(&self) -> crate::Result<HistogramAggregation> {
self.validate()?;
Ok(HistogramAggregation {
field: self.field.to_string(),
interval: parse_into_microseconds(&self.fixed_interval)? as f64,
offset: self
.offset
.as_ref()
.map(|offset| parse_offset_into_microseconds(offset))
.transpose()?
.map(|el| el as f64),
min_doc_count: self.min_doc_count,
hard_bounds: None,
extended_bounds: None,
keyed: self.keyed,
})
}
fn validate(&self) -> crate::Result<()> {
if self.interval.is_some() {
return Err(crate::TantivyError::InvalidArgument(format!(
"`interval` parameter {:?} in date histogram is unsupported, only \
`fixed_interval` is supported",
self.interval
)));
}
if self.format.is_some() {
return Err(crate::TantivyError::InvalidArgument(
"format parameter on date_histogram is unsupported".to_string(),
));
}
if self.date_interval.is_some() {
return Err(crate::TantivyError::InvalidArgument(
"date_interval in date histogram is unsupported, only `fixed_interval` is \
supported"
.to_string(),
));
}
parse_into_microseconds(&self.fixed_interval)?;
Ok(())
}
}
#[derive(Debug, Clone, PartialEq, Eq, Error)]
/// Errors when parsing the fixed interval for `DateHistogramAggregationReq`.
pub enum DateHistogramParseError {
/// Unit not recognized in passed String
#[error("Unit not recognized in passed String {0:?}")]
UnitNotRecognized(String),
/// Number not found in passed String
#[error("Number not found in passed String {0:?}")]
NumberMissing(String),
/// Unit not found in passed String
#[error("Unit not found in passed String {0:?}")]
UnitMissing(String),
/// Offset invalid
#[error("passed offset is invalid {0:?}")]
InvalidOffset(String),
}
fn parse_offset_into_microseconds(input: &str) -> Result<i64, AggregationError> {
let is_sign = |byte| &[byte] == b"-" || &[byte] == b"+";
if input.is_empty() {
return Err(DateHistogramParseError::InvalidOffset(input.to_string()).into());
}
let has_sign = is_sign(input.as_bytes()[0]);
if has_sign {
let (sign, input) = input.split_at(1);
let val = parse_into_microseconds(input)?;
if sign == "-" {
Ok(-val)
} else {
Ok(val)
}
} else {
parse_into_microseconds(input)
}
}
fn parse_into_microseconds(input: &str) -> Result<i64, AggregationError> {
let split_boundary = input
.as_bytes()
.iter()
.take_while(|byte| byte.is_ascii_digit())
.count();
let (number, unit) = input.split_at(split_boundary);
if number.is_empty() {
return Err(DateHistogramParseError::NumberMissing(input.to_string()).into());
}
if unit.is_empty() {
return Err(DateHistogramParseError::UnitMissing(input.to_string()).into());
}
let number: i64 = number
.parse()
// Technically this should never happen, but there was a bug
// here and being defensive does not hurt.
.map_err(|_err| DateHistogramParseError::NumberMissing(input.to_string()))?;
let multiplier_from_unit = match unit {
"ms" => 1,
"s" => 1000,
"m" => 60 * 1000,
"h" => 60 * 60 * 1000,
"d" => 24 * 60 * 60 * 1000,
_ => return Err(DateHistogramParseError::UnitNotRecognized(unit.to_string()).into()),
};
Ok(number * multiplier_from_unit * 1000)
}
#[cfg(test)]
mod tests {
use pretty_assertions::assert_eq;
use super::*;
use crate::aggregation::agg_req::Aggregations;
use crate::aggregation::tests::exec_request;
use crate::indexer::NoMergePolicy;
use crate::schema::{Schema, FAST};
use crate::Index;
#[test]
fn test_parse_into_microseconds() {
assert_eq!(parse_into_microseconds("1m").unwrap(), 60_000_000);
assert_eq!(parse_into_microseconds("2m").unwrap(), 120_000_000);
assert_eq!(
parse_into_microseconds("2y").unwrap_err(),
DateHistogramParseError::UnitNotRecognized("y".to_string()).into()
);
assert_eq!(
parse_into_microseconds("2000").unwrap_err(),
DateHistogramParseError::UnitMissing("2000".to_string()).into()
);
assert_eq!(
parse_into_microseconds("ms").unwrap_err(),
DateHistogramParseError::NumberMissing("ms".to_string()).into()
);
}
#[test]
fn test_parse_offset_into_microseconds() {
assert_eq!(parse_offset_into_microseconds("1m").unwrap(), 60_000_000);
assert_eq!(parse_offset_into_microseconds("+1m").unwrap(), 60_000_000);
assert_eq!(parse_offset_into_microseconds("-1m").unwrap(), -60_000_000);
assert_eq!(parse_offset_into_microseconds("2m").unwrap(), 120_000_000);
assert_eq!(parse_offset_into_microseconds("+2m").unwrap(), 120_000_000);
assert_eq!(parse_offset_into_microseconds("-2m").unwrap(), -120_000_000);
assert_eq!(parse_offset_into_microseconds("-2ms").unwrap(), -2_000);
assert_eq!(
parse_offset_into_microseconds("2y").unwrap_err(),
DateHistogramParseError::UnitNotRecognized("y".to_string()).into()
);
assert_eq!(
parse_offset_into_microseconds("2000").unwrap_err(),
DateHistogramParseError::UnitMissing("2000".to_string()).into()
);
assert_eq!(
parse_offset_into_microseconds("ms").unwrap_err(),
DateHistogramParseError::NumberMissing("ms".to_string()).into()
);
}
#[test]
fn test_parse_into_milliseconds_do_not_accept_non_ascii() {
assert!(parse_into_microseconds("m").is_err());
}
pub fn get_test_index_from_docs(
merge_segments: bool,
segment_and_docs: &[Vec<&str>],
) -> crate::Result<Index> {
let mut schema_builder = Schema::builder();
schema_builder.add_date_field("date", FAST);
schema_builder.add_text_field("text", FAST);
let schema = schema_builder.build();
let index = Index::create_in_ram(schema.clone());
{
let mut index_writer = index.writer_with_num_threads(1, 30_000_000)?;
index_writer.set_merge_policy(Box::new(NoMergePolicy));
for values in segment_and_docs {
for doc_str in values {
let doc = schema.parse_document(doc_str)?;
index_writer.add_document(doc)?;
}
// writing the segment
index_writer.commit()?;
}
}
if merge_segments {
let segment_ids = index
.searchable_segment_ids()
.expect("Searchable segments failed.");
if segment_ids.len() > 1 {
let mut index_writer = index.writer_for_tests()?;
index_writer.merge(&segment_ids).wait()?;
index_writer.wait_merging_threads()?;
}
}
Ok(index)
}
#[test]
fn histogram_test_date_force_merge_segments() -> crate::Result<()> {
histogram_test_date_merge_segments(true)
}
#[test]
fn histogram_test_date() -> crate::Result<()> {
histogram_test_date_merge_segments(false)
}
fn histogram_test_date_merge_segments(merge_segments: bool) -> crate::Result<()> {
let docs = vec![
vec![r#"{ "date": "2015-01-01T12:10:30Z", "text": "aaa" }"#],
vec![r#"{ "date": "2015-01-01T11:11:30Z", "text": "bbb" }"#],
vec![r#"{ "date": "2015-01-02T00:00:00Z", "text": "bbb" }"#],
vec![r#"{ "date": "2015-01-06T00:00:00Z", "text": "ccc" }"#],
];
let index = get_test_index_from_docs(merge_segments, &docs)?;
// 30day + offset
let elasticsearch_compatible_json = json!(
{
"sales_over_time": {
"date_histogram": {
"field": "date",
"fixed_interval": "30d",
"offset": "-4d"
}
}
}
);
let agg_req: Aggregations =
serde_json::from_str(&serde_json::to_string(&elasticsearch_compatible_json).unwrap())
.unwrap();
let res = exec_request(agg_req, &index)?;
let expected_res = json!({
"sales_over_time" : {
"buckets" : [
{
"key_as_string" : "2015-01-01T00:00:00Z",
"key" : 1420070400000000.0,
"doc_count" : 4
}
]
}
});
assert_eq!(res, expected_res);
// 30day + offset + sub_agg
let elasticsearch_compatible_json = json!(
{
"sales_over_time": {
"date_histogram": {
"field": "date",
"fixed_interval": "30d",
"offset": "-4d"
},
"aggs": {
"texts": {
"terms": {"field": "text"}
}
}
}
}
);
let agg_req: Aggregations =
serde_json::from_str(&serde_json::to_string(&elasticsearch_compatible_json).unwrap())
.unwrap();
let res = exec_request(agg_req, &index)?;
println!("{}", serde_json::to_string_pretty(&res).unwrap());
let expected_res = json!({
"sales_over_time" : {
"buckets" : [
{
"key_as_string" : "2015-01-01T00:00:00Z",
"key" : 1420070400000000.0,
"doc_count" : 4,
"texts": {
"buckets": [
{
"doc_count": 2,
"key": "bbb"
},
{
"doc_count": 1,
"key": "ccc"
},
{
"doc_count": 1,
"key": "aaa"
}
],
"doc_count_error_upper_bound": 0,
"sum_other_doc_count": 0
}
}
]
}
});
assert_eq!(res, expected_res);
// 1day
let elasticsearch_compatible_json = json!(
{
"sales_over_time": {
"date_histogram": {
"field": "date",
"fixed_interval": "1d"
}
}
}
);
let agg_req: Aggregations =
serde_json::from_str(&serde_json::to_string(&elasticsearch_compatible_json).unwrap())
.unwrap();
let res = exec_request(agg_req, &index)?;
let expected_res = json!( {
"sales_over_time": {
"buckets": [
{
"doc_count": 2,
"key": 1420070400000000.0,
"key_as_string": "2015-01-01T00:00:00Z"
},
{
"doc_count": 1,
"key": 1420156800000000.0,
"key_as_string": "2015-01-02T00:00:00Z"
},
{
"doc_count": 0,
"key": 1420243200000000.0,
"key_as_string": "2015-01-03T00:00:00Z"
},
{
"doc_count": 0,
"key": 1420329600000000.0,
"key_as_string": "2015-01-04T00:00:00Z"
},
{
"doc_count": 0,
"key": 1420416000000000.0,
"key_as_string": "2015-01-05T00:00:00Z"
},
{
"doc_count": 1,
"key": 1420502400000000.0,
"key_as_string": "2015-01-06T00:00:00Z"
}
]
}
});
assert_eq!(res, expected_res);
Ok(())
}
}

526
src/aggregation/bucket/histogram/histogram.rs
View File

@@ -1,11 +1,9 @@
use std::cmp::Ordering;
use std::fmt::Display;
use columnar::ColumnType;
use fastfield_codecs::Column;
use itertools::Itertools;
use rustc_hash::FxHashMap;
use serde::{Deserialize, Serialize};
use tantivy_bitpacker::minmax;
use crate::aggregation::agg_req::AggregationsInternal;
use crate::aggregation::agg_req_with_accessor::{
@@ -15,10 +13,9 @@ use crate::aggregation::agg_result::BucketEntry;
use crate::aggregation::intermediate_agg_result::{
IntermediateAggregationResults, IntermediateBucketResult, IntermediateHistogramBucketEntry,
};
use crate::aggregation::segment_agg_result::{
build_segment_agg_collector, SegmentAggregationCollector,
};
use crate::aggregation::{f64_from_fastfield_u64, format_date, VecWithNames};
use crate::aggregation::segment_agg_result::SegmentAggregationResultsCollector;
use crate::aggregation::{f64_from_fastfield_u64, format_date};
use crate::schema::{Schema, Type};
use crate::{DocId, TantivyError};
/// Histogram is a bucket aggregation, where buckets are created dynamically for given `interval`.
@@ -65,6 +62,7 @@ use crate::{DocId, TantivyError};
///
/// Response
/// See [`BucketEntry`](crate::aggregation::agg_result::BucketEntry)
#[derive(Clone, Debug, Default, PartialEq, Serialize, Deserialize)]
pub struct HistogramAggregation {
/// The field to aggregate on.
@@ -177,7 +175,7 @@ impl HistogramBounds {
}
}
#[derive(Default, Clone, Debug, PartialEq)]
#[derive(Clone, Debug, PartialEq)]
pub(crate) struct SegmentHistogramBucketEntry {
pub key: f64,
pub doc_count: u64,
@@ -186,7 +184,7 @@ pub(crate) struct SegmentHistogramBucketEntry {
impl SegmentHistogramBucketEntry {
pub(crate) fn into_intermediate_bucket_entry(
self,
sub_aggregation: Box<dyn SegmentAggregationCollector>,
sub_aggregation: SegmentAggregationResultsCollector,
agg_with_accessor: &AggregationsWithAccessor,
) -> crate::Result<IntermediateHistogramBucketEntry> {
Ok(IntermediateHistogramBucketEntry {
@@ -200,88 +198,17 @@ impl SegmentHistogramBucketEntry {
/// The collector puts values from the fast field into the correct buckets and does a conversion to
/// the correct datatype.
#[derive(Clone, Debug)]
#[derive(Clone, Debug, PartialEq)]
pub struct SegmentHistogramCollector {
/// The buckets containing the aggregation data.
buckets: FxHashMap<i64, SegmentHistogramBucketEntry>,
sub_aggregations: FxHashMap<i64, Box<dyn SegmentAggregationCollector>>,
sub_aggregation_blueprint: Option<Box<dyn SegmentAggregationCollector>>,
column_type: ColumnType,
buckets: Vec<SegmentHistogramBucketEntry>,
sub_aggregations: Option<Vec<SegmentAggregationResultsCollector>>,
field_type: Type,
interval: f64,
offset: f64,
min_doc_count: u64,
first_bucket_num: i64,
bounds: HistogramBounds,
accessor_idx: usize,
}
impl SegmentAggregationCollector for SegmentHistogramCollector {
fn into_intermediate_aggregations_result(
self: Box<Self>,
agg_with_accessor: &AggregationsWithAccessor,
) -> crate::Result<IntermediateAggregationResults> {
let name = agg_with_accessor.buckets.keys[self.accessor_idx].to_string();
let agg_with_accessor = &agg_with_accessor.buckets.values[self.accessor_idx];
let bucket = self.into_intermediate_bucket_result(agg_with_accessor)?;
let buckets = Some(VecWithNames::from_entries(vec![(name, bucket)]));
Ok(IntermediateAggregationResults {
metrics: None,
buckets,
})
}
fn collect(
&mut self,
doc: crate::DocId,
agg_with_accessor: &AggregationsWithAccessor,
) -> crate::Result<()> {
self.collect_block(&[doc], agg_with_accessor)
}
fn collect_block(
&mut self,
docs: &[crate::DocId],
agg_with_accessor: &AggregationsWithAccessor,
) -> crate::Result<()> {
let accessor = &agg_with_accessor.buckets.values[self.accessor_idx].accessor;
let sub_aggregation_accessor =
&agg_with_accessor.buckets.values[self.accessor_idx].sub_aggregation;
let bounds = self.bounds;
let interval = self.interval;
let offset = self.offset;
let get_bucket_pos = |val| (get_bucket_pos_f64(val, interval, offset) as i64);
for doc in docs {
for val in accessor.values_for_doc(*doc) {
let val = self.f64_from_fastfield_u64(val);
let bucket_pos = get_bucket_pos(val);
if bounds.contains(val) {
self.increment_bucket(
bucket_pos,
*doc,
sub_aggregation_accessor,
interval,
offset,
)?;
}
}
}
Ok(())
}
fn flush(&mut self, agg_with_accessor: &AggregationsWithAccessor) -> crate::Result<()> {
let sub_aggregation_accessor =
&agg_with_accessor.buckets.values[self.accessor_idx].sub_aggregation;
for sub_aggregation in self.sub_aggregations.values_mut() {
sub_aggregation.flush(sub_aggregation_accessor)?;
}
Ok(())
}
}
impl SegmentHistogramCollector {
@@ -289,96 +216,254 @@ impl SegmentHistogramCollector {
self,
agg_with_accessor: &BucketAggregationWithAccessor,
) -> crate::Result<IntermediateBucketResult> {
let mut buckets = Vec::with_capacity(self.buckets.len());
// Compute the number of buckets to validate against max num buckets
// Note: We use min_doc_count here, but it's only an lowerbound here, since were are on the
// intermediate level and after merging the number of documents of a bucket could exceed
// `min_doc_count`.
{
let cut_off_buckets_front = self
.buckets
.iter()
.take_while(|bucket| bucket.doc_count <= self.min_doc_count)
.count();
let cut_off_buckets_back = self.buckets[cut_off_buckets_front..]
.iter()
.rev()
.take_while(|bucket| bucket.doc_count <= self.min_doc_count)
.count();
let estimate_num_buckets =
self.buckets.len() - cut_off_buckets_front - cut_off_buckets_back;
if self.sub_aggregation_blueprint.is_some() {
for (bucket_pos, bucket) in self.buckets.into_iter() {
let bucket_res = bucket.into_intermediate_bucket_entry(
self.sub_aggregations.get(&bucket_pos).unwrap().clone(),
&agg_with_accessor.sub_aggregation,
);
agg_with_accessor
.bucket_count
.add_count(estimate_num_buckets as u32);
agg_with_accessor.bucket_count.validate_bucket_count()?;
}
let mut buckets = Vec::with_capacity(
self.buckets
.iter()
.filter(|bucket| bucket.doc_count != 0)
.count(),
);
// Below we remove empty buckets for two reasons
// 1. To reduce the size of the intermediate result, which may be passed on the wire.
// 2. To mimic elasticsearch, there are no empty buckets at the start and end.
//
// Empty buckets may be added later again in the final result, depending on the request.
if let Some(sub_aggregations) = self.sub_aggregations {
for bucket_res in self
.buckets
.into_iter()
.zip(sub_aggregations.into_iter())
.filter(|(bucket, _sub_aggregation)| bucket.doc_count != 0)
.map(|(bucket, sub_aggregation)| {
bucket.into_intermediate_bucket_entry(
sub_aggregation,
&agg_with_accessor.sub_aggregation,
)
})
{
buckets.push(bucket_res?);
}
} else {
buckets.extend(self.buckets.into_values().map(|bucket| bucket.into()));
buckets.extend(
self.buckets
.into_iter()
.filter(|bucket| bucket.doc_count != 0)
.map(|bucket| bucket.into()),
);
};
buckets.sort_unstable_by(|b1, b2| b1.key.partial_cmp(&b2.key).unwrap_or(Ordering::Equal));
Ok(IntermediateBucketResult::Histogram {
buckets,
column_type: Some(self.column_type),
})
Ok(IntermediateBucketResult::Histogram { buckets })
}
pub(crate) fn from_req_and_validate(
req: &HistogramAggregation,
sub_aggregation: &AggregationsWithAccessor,
field_type: ColumnType,
accessor_idx: usize,
field_type: Type,
accessor: &dyn Column<u64>,
) -> crate::Result<Self> {
req.validate()?;
let min = f64_from_fastfield_u64(accessor.min_value(), &field_type);
let max = f64_from_fastfield_u64(accessor.max_value(), &field_type);
let sub_aggregation_blueprint = if sub_aggregation.is_empty() {
let (min, max) = get_req_min_max(req, Some((min, max)));
// We compute and generate the buckets range (min, max) based on the request and the min
// max in the fast field, but this is likely not ideal when this is a subbucket, where many
// unnecessary buckets may be generated.
let buckets = generate_buckets(req, min, max);
let sub_aggregations = if sub_aggregation.is_empty() {
None
} else {
let sub_aggregation = build_segment_agg_collector(sub_aggregation)?;
Some(sub_aggregation)
let sub_aggregation =
SegmentAggregationResultsCollector::from_req_and_validate(sub_aggregation)?;
Some(buckets.iter().map(|_| sub_aggregation.clone()).collect())
};
let buckets = buckets
.iter()
.map(|bucket| SegmentHistogramBucketEntry {
key: *bucket,
doc_count: 0,
})
.collect();
let first_bucket_num =
get_bucket_num_f64(min, req.interval, req.offset.unwrap_or(0.0)) as i64;
let bounds = req.hard_bounds.unwrap_or(HistogramBounds {
min: f64::MIN,
max: f64::MAX,
});
Ok(Self {
buckets: Default::default(),
column_type: field_type,
buckets,
field_type,
interval: req.interval,
offset: req.offset.unwrap_or(0.0),
first_bucket_num,
bounds,
sub_aggregations: Default::default(),
sub_aggregation_blueprint,
accessor_idx,
sub_aggregations,
min_doc_count: req.min_doc_count(),
})
}
#[inline]
fn increment_bucket(
pub(crate) fn collect_block(
&mut self,
bucket_pos: i64,
doc: DocId,
bucket_with_accessor: &AggregationsWithAccessor,
interval: f64,
offset: f64,
doc: &[DocId],
bucket_with_accessor: &BucketAggregationWithAccessor,
force_flush: bool,
) -> crate::Result<()> {
let bucket = self.buckets.entry(bucket_pos).or_insert_with(|| {
let key = get_bucket_key_from_pos(bucket_pos as f64, interval, offset);
SegmentHistogramBucketEntry { key, doc_count: 0 }
});
bucket.doc_count += 1;
if let Some(sub_aggregation_blueprint) = self.sub_aggregation_blueprint.as_mut() {
self.sub_aggregations
.entry(bucket_pos)
.or_insert_with(|| sub_aggregation_blueprint.clone())
.collect(doc, bucket_with_accessor)?;
let bounds = self.bounds;
let interval = self.interval;
let offset = self.offset;
let first_bucket_num = self.first_bucket_num;
let get_bucket_num =
|val| (get_bucket_num_f64(val, interval, offset) as i64 - first_bucket_num) as usize;
let accessor = bucket_with_accessor
.accessor
.as_single()
.expect("unexpected fast field cardinatility");
let mut iter = doc.chunks_exact(4);
for docs in iter.by_ref() {
let val0 = self.f64_from_fastfield_u64(accessor.get_val(docs[0]));
let val1 = self.f64_from_fastfield_u64(accessor.get_val(docs[1]));
let val2 = self.f64_from_fastfield_u64(accessor.get_val(docs[2]));
let val3 = self.f64_from_fastfield_u64(accessor.get_val(docs[3]));
let bucket_pos0 = get_bucket_num(val0);
let bucket_pos1 = get_bucket_num(val1);
let bucket_pos2 = get_bucket_num(val2);
let bucket_pos3 = get_bucket_num(val3);
self.increment_bucket_if_in_bounds(
val0,
&bounds,
bucket_pos0,
docs[0],
&bucket_with_accessor.sub_aggregation,
)?;
self.increment_bucket_if_in_bounds(
val1,
&bounds,
bucket_pos1,
docs[1],
&bucket_with_accessor.sub_aggregation,
)?;
self.increment_bucket_if_in_bounds(
val2,
&bounds,
bucket_pos2,
docs[2],
&bucket_with_accessor.sub_aggregation,
)?;
self.increment_bucket_if_in_bounds(
val3,
&bounds,
bucket_pos3,
docs[3],
&bucket_with_accessor.sub_aggregation,
)?;
}
for &doc in iter.remainder() {
let val = f64_from_fastfield_u64(accessor.get_val(doc), &self.field_type);
if !bounds.contains(val) {
continue;
}
let bucket_pos = (get_bucket_num_f64(val, self.interval, self.offset) as i64
- self.first_bucket_num) as usize;
debug_assert_eq!(
self.buckets[bucket_pos].key,
get_bucket_val(val, self.interval, self.offset)
);
self.increment_bucket(bucket_pos, doc, &bucket_with_accessor.sub_aggregation)?;
}
if force_flush {
if let Some(sub_aggregations) = self.sub_aggregations.as_mut() {
for sub_aggregation in sub_aggregations {
sub_aggregation
.flush_staged_docs(&bucket_with_accessor.sub_aggregation, force_flush)?;
}
}
}
Ok(())
}
#[inline]
fn increment_bucket_if_in_bounds(
&mut self,
val: f64,
bounds: &HistogramBounds,
bucket_pos: usize,
doc: DocId,
bucket_with_accessor: &AggregationsWithAccessor,
) -> crate::Result<()> {
if bounds.contains(val) {
debug_assert_eq!(
self.buckets[bucket_pos].key,
get_bucket_val(val, self.interval, self.offset)
);
self.increment_bucket(bucket_pos, doc, bucket_with_accessor)?;
}
Ok(())
}
#[inline]
fn increment_bucket(
&mut self,
bucket_pos: usize,
doc: DocId,
bucket_with_accessor: &AggregationsWithAccessor,
) -> crate::Result<()> {
let bucket = &mut self.buckets[bucket_pos];
bucket.doc_count += 1;
if let Some(sub_aggregation) = self.sub_aggregations.as_mut() {
sub_aggregation[bucket_pos].collect(doc, bucket_with_accessor)?;
}
Ok(())
}
fn f64_from_fastfield_u64(&self, val: u64) -> f64 {
f64_from_fastfield_u64(val, &self.column_type)
f64_from_fastfield_u64(val, &self.field_type)
}
}
#[inline]
fn get_bucket_pos_f64(val: f64, interval: f64, offset: f64) -> f64 {
fn get_bucket_num_f64(val: f64, interval: f64, offset: f64) -> f64 {
((val - offset) / interval).floor()
}
#[inline]
fn get_bucket_key_from_pos(bucket_pos: f64, interval: f64, offset: f64) -> f64 {
fn get_bucket_val(val: f64, interval: f64, offset: f64) -> f64 {
let bucket_pos = get_bucket_num_f64(val, interval, offset);
bucket_pos * interval + offset
}
@@ -387,14 +472,19 @@ fn intermediate_buckets_to_final_buckets_fill_gaps(
buckets: Vec<IntermediateHistogramBucketEntry>,
histogram_req: &HistogramAggregation,
sub_aggregation: &AggregationsInternal,
schema: &Schema,
) -> crate::Result<Vec<BucketEntry>> {
// Generate the full list of buckets without gaps.
//
// The bounds are the min max from the current buckets, optionally extended by
// extended_bounds from the request
let min_max = minmax(buckets.iter().map(|bucket| bucket.key));
// TODO add memory check
let min_max = if buckets.is_empty() {
None
} else {
let min = buckets[0].key;
let max = buckets[buckets.len() - 1].key;
Some((min, max))
};
let fill_gaps_buckets = generate_buckets_with_opt_minmax(histogram_req, min_max);
let empty_sub_aggregation = IntermediateAggregationResults::empty_from_req(sub_aggregation);
@@ -423,33 +513,43 @@ fn intermediate_buckets_to_final_buckets_fill_gaps(
sub_aggregation: empty_sub_aggregation.clone(),
},
})
.map(|intermediate_bucket| intermediate_bucket.into_final_bucket_entry(sub_aggregation))
.map(|intermediate_bucket| {
intermediate_bucket.into_final_bucket_entry(sub_aggregation, schema)
})
.collect::<crate::Result<Vec<_>>>()
}
// Convert to BucketEntry
pub(crate) fn intermediate_histogram_buckets_to_final_buckets(
buckets: Vec<IntermediateHistogramBucketEntry>,
column_type: Option<ColumnType>,
histogram_req: &HistogramAggregation,
sub_aggregation: &AggregationsInternal,
schema: &Schema,
) -> crate::Result<Vec<BucketEntry>> {
let mut buckets = if histogram_req.min_doc_count() == 0 {
// With min_doc_count != 0, we may need to add buckets, so that there are no
// gaps, since intermediate result does not contain empty buckets (filtered to
// reduce serialization size).
intermediate_buckets_to_final_buckets_fill_gaps(buckets, histogram_req, sub_aggregation)?
intermediate_buckets_to_final_buckets_fill_gaps(
buckets,
histogram_req,
sub_aggregation,
schema,
)?
} else {
buckets
.into_iter()
.filter(|histogram_bucket| histogram_bucket.doc_count >= histogram_req.min_doc_count())
.map(|histogram_bucket| histogram_bucket.into_final_bucket_entry(sub_aggregation))
.map(|histogram_bucket| {
histogram_bucket.into_final_bucket_entry(sub_aggregation, schema)
})
.collect::<crate::Result<Vec<_>>>()?
};
// If we have a date type on the histogram buckets, we add the `key_as_string` field as rfc339
if column_type == Some(ColumnType::DateTime) {
let field = schema.get_field(&histogram_req.field)?;
if schema.get_field_entry(field).field_type().is_date() {
for bucket in buckets.iter_mut() {
if let crate::aggregation::Key::F64(val) = bucket.key {
let key_as_string = format_date(val as i64)?;
@@ -480,6 +580,12 @@ fn get_req_min_max(req: &HistogramAggregation, min_max: Option<(f64, f64)>) -> (
(min, max)
}
/// Generates buckets with req.interval
/// range is computed for provided min_max and request extended_bounds/hard_bounds
pub(crate) fn generate_buckets(req: &HistogramAggregation, min: f64, max: f64) -> Vec<f64> {
generate_buckets_with_opt_minmax(req, Some((min, max)))
}
/// Generates buckets with req.interval
/// Range is computed for provided min_max and request extended_bounds/hard_bounds
/// returns empty vec when there is no range to span
@@ -490,8 +596,8 @@ pub(crate) fn generate_buckets_with_opt_minmax(
let (min, max) = get_req_min_max(req, min_max);
let offset = req.offset.unwrap_or(0.0);
let first_bucket_num = get_bucket_pos_f64(min, req.interval, offset) as i64;
let last_bucket_num = get_bucket_pos_f64(max, req.interval, offset) as i64;
let first_bucket_num = get_bucket_num_f64(min, req.interval, offset) as i64;
let last_bucket_num = get_bucket_num_f64(max, req.interval, offset) as i64;
let mut buckets = Vec::with_capacity((first_bucket_num..=last_bucket_num).count());
for bucket_pos in first_bucket_num..=last_bucket_num {
let bucket_key = bucket_pos as f64 * req.interval + offset;
@@ -501,6 +607,118 @@ pub(crate) fn generate_buckets_with_opt_minmax(
buckets
}
#[test]
fn generate_buckets_test() {
let histogram_req = HistogramAggregation {
field: "dummy".to_string(),
interval: 2.0,
..Default::default()
};
let buckets = generate_buckets(&histogram_req, 0.0, 10.0);
assert_eq!(buckets, vec![0.0, 2.0, 4.0, 6.0, 8.0, 10.0]);
let buckets = generate_buckets(&histogram_req, 2.5, 5.5);
assert_eq!(buckets, vec![2.0, 4.0]);
// Single bucket
let buckets = generate_buckets(&histogram_req, 0.5, 0.75);
assert_eq!(buckets, vec![0.0]);
// With offset
let histogram_req = HistogramAggregation {
field: "dummy".to_string(),
interval: 2.0,
offset: Some(0.5),
..Default::default()
};
let buckets = generate_buckets(&histogram_req, 0.0, 10.0);
assert_eq!(buckets, vec![-1.5, 0.5, 2.5, 4.5, 6.5, 8.5]);
let buckets = generate_buckets(&histogram_req, 2.5, 5.5);
assert_eq!(buckets, vec![2.5, 4.5]);
// Single bucket
let buckets = generate_buckets(&histogram_req, 0.5, 0.75);
assert_eq!(buckets, vec![0.5]);
// no bucket
let buckets = generate_buckets(&histogram_req, f64::MAX, f64::MIN);
assert_eq!(buckets, vec![] as Vec<f64>);
// With extended_bounds
let histogram_req = HistogramAggregation {
field: "dummy".to_string(),
interval: 2.0,
extended_bounds: Some(HistogramBounds {
min: 0.0,
max: 10.0,
}),
..Default::default()
};
let buckets = generate_buckets(&histogram_req, 0.0, 10.0);
assert_eq!(buckets, vec![0.0, 2.0, 4.0, 6.0, 8.0, 10.0]);
let buckets = generate_buckets(&histogram_req, 2.5, 5.5);
assert_eq!(buckets, vec![0.0, 2.0, 4.0, 6.0, 8.0, 10.0]);
// Single bucket, but extended_bounds
let buckets = generate_buckets(&histogram_req, 0.5, 0.75);
assert_eq!(buckets, vec![0.0, 2.0, 4.0, 6.0, 8.0, 10.0]);
// no bucket, but extended_bounds
let buckets = generate_buckets(&histogram_req, f64::MAX, f64::MIN);
assert_eq!(buckets, vec![0.0, 2.0, 4.0, 6.0, 8.0, 10.0]);
// With invalid extended_bounds
let histogram_req = HistogramAggregation {
field: "dummy".to_string(),
interval: 2.0,
extended_bounds: Some(HistogramBounds { min: 3.0, max: 5.0 }),
..Default::default()
};
let buckets = generate_buckets(&histogram_req, 0.0, 10.0);
assert_eq!(buckets, vec![0.0, 2.0, 4.0, 6.0, 8.0, 10.0]);
// With hard_bounds reducing
let histogram_req = HistogramAggregation {
field: "dummy".to_string(),
interval: 2.0,
hard_bounds: Some(HistogramBounds { min: 3.0, max: 5.0 }),
..Default::default()
};
let buckets = generate_buckets(&histogram_req, 0.0, 10.0);
assert_eq!(buckets, vec![2.0, 4.0]);
// With hard_bounds, extending has no effect
let histogram_req = HistogramAggregation {
field: "dummy".to_string(),
interval: 2.0,
hard_bounds: Some(HistogramBounds {
min: 0.0,
max: 10.0,
}),
..Default::default()
};
let buckets = generate_buckets(&histogram_req, 2.5, 5.5);
assert_eq!(buckets, vec![2.0, 4.0]);
// Blubber
let histogram_req = HistogramAggregation {
field: "dummy".to_string(),
interval: 2.0,
..Default::default()
};
let buckets = generate_buckets(&histogram_req, 4.0, 10.0);
assert_eq!(buckets, vec![4.0, 6.0, 8.0, 10.0]);
}
#[cfg(test)]
mod tests {
@@ -1321,4 +1539,36 @@ mod tests {
Ok(())
}
#[test]
fn histogram_test_max_buckets_segments() -> crate::Result<()> {
let values = vec![0.0, 70000.0];
let index = get_test_index_from_values(true, &values)?;
let agg_req: Aggregations = vec![(
"my_interval".to_string(),
Aggregation::Bucket(BucketAggregation {
bucket_agg: BucketAggregationType::Histogram(HistogramAggregation {
field: "score_f64".to_string(),
interval: 1.0,
..Default::default()
}),
sub_aggregation: Default::default(),
}),
)]
.into_iter()
.collect();
let res = exec_request(agg_req, &index);
assert_eq!(
res.unwrap_err().to_string(),
"An invalid argument was passed: 'Aborting aggregation because too many buckets were \
created'"
.to_string()
);
Ok(())
}
}

2
src/aggregation/bucket/histogram/mod.rs
View File

@@ -1,4 +1,2 @@
mod date_histogram;
mod histogram;
pub use date_histogram::*;
pub use histogram::*;

16
src/aggregation/bucket/mod.rs
View File

@@ -21,25 +21,28 @@ use serde::{de, Deserialize, Deserializer, Serialize, Serializer};
pub use term_agg::*;
/// Order for buckets in a bucket aggregation.
#[derive(Clone, Copy, Debug, PartialEq, Serialize, Deserialize, Default)]
#[derive(Clone, Copy, Debug, PartialEq, Serialize, Deserialize)]
pub enum Order {
/// Asc order
#[serde(rename = "asc")]
Asc,
/// Desc order
#[serde(rename = "desc")]
#[default]
Desc,
}
impl Default for Order {
fn default() -> Self {
Order::Desc
}
}
#[derive(Clone, Debug, PartialEq)]
/// Order property by which to apply the order
#[derive(Default)]
pub enum OrderTarget {
/// The key of the bucket
Key,
/// The doc count of the bucket
#[default]
Count,
/// Order by value of the sub aggregation metric with identified by given `String`.
///
@@ -47,6 +50,11 @@ pub enum OrderTarget {
SubAggregation(String),
}
impl Default for OrderTarget {
fn default() -> Self {
OrderTarget::Count
}
}
impl From<&str> for OrderTarget {
fn from(val: &str) -> Self {
match val {

251
src/aggregation/bucket/range.rs
View File

@@ -1,22 +1,22 @@
use std::fmt::Debug;
use std::ops::Range;
use columnar::{ColumnType, MonotonicallyMappableToU64};
use fastfield_codecs::MonotonicallyMappableToU64;
use rustc_hash::FxHashMap;
use serde::{Deserialize, Serialize};
use crate::aggregation::agg_req_with_accessor::AggregationsWithAccessor;
use crate::aggregation::agg_req_with_accessor::{
AggregationsWithAccessor, BucketAggregationWithAccessor,
};
use crate::aggregation::intermediate_agg_result::{
IntermediateAggregationResults, IntermediateBucketResult, IntermediateRangeBucketEntry,
IntermediateRangeBucketResult,
};
use crate::aggregation::segment_agg_result::{
build_segment_agg_collector, BucketCount, SegmentAggregationCollector,
IntermediateBucketResult, IntermediateRangeBucketEntry, IntermediateRangeBucketResult,
};
use crate::aggregation::segment_agg_result::{BucketCount, SegmentAggregationResultsCollector};
use crate::aggregation::{
f64_from_fastfield_u64, f64_to_fastfield_u64, format_date, Key, SerializedKey, VecWithNames,
f64_from_fastfield_u64, f64_to_fastfield_u64, format_date, Key, SerializedKey,
};
use crate::TantivyError;
use crate::schema::Type;
use crate::{DocId, TantivyError};
/// Provide user-defined buckets to aggregate on.
/// Two special buckets will automatically be created to cover the whole range of values.
@@ -114,7 +114,7 @@ impl From<Range<u64>> for InternalRangeAggregationRange {
}
}
#[derive(Clone, Debug)]
#[derive(Clone, Debug, PartialEq)]
pub(crate) struct SegmentRangeAndBucketEntry {
range: Range<u64>,
bucket: SegmentRangeBucketEntry,
@@ -122,19 +122,18 @@ pub(crate) struct SegmentRangeAndBucketEntry {
/// The collector puts values from the fast field into the correct buckets and does a conversion to
/// the correct datatype.
#[derive(Clone, Debug)]
#[derive(Clone, Debug, PartialEq)]
pub struct SegmentRangeCollector {
/// The buckets containing the aggregation data.
buckets: Vec<SegmentRangeAndBucketEntry>,
column_type: ColumnType,
pub(crate) accessor_idx: usize,
field_type: Type,
}
#[derive(Clone)]
#[derive(Clone, PartialEq)]
pub(crate) struct SegmentRangeBucketEntry {
pub key: Key,
pub doc_count: u64,
pub sub_aggregation: Option<Box<dyn SegmentAggregationCollector>>,
pub sub_aggregation: Option<SegmentAggregationResultsCollector>,
/// The from range of the bucket. Equals `f64::MIN` when `None`.
pub from: Option<f64>,
/// The to range of the bucket. Equals `f64::MAX` when `None`. Open interval, `to` is not
@@ -173,14 +172,12 @@ impl SegmentRangeBucketEntry {
}
}
impl SegmentAggregationCollector for SegmentRangeCollector {
fn into_intermediate_aggregations_result(
self: Box<Self>,
agg_with_accessor: &AggregationsWithAccessor,
) -> crate::Result<IntermediateAggregationResults> {
let field_type = self.column_type;
let name = agg_with_accessor.buckets.keys[self.accessor_idx].to_string();
let sub_agg = &agg_with_accessor.buckets.values[self.accessor_idx].sub_aggregation;
impl SegmentRangeCollector {
pub fn into_intermediate_bucket_result(
self,
agg_with_accessor: &BucketAggregationWithAccessor,
) -> crate::Result<IntermediateBucketResult> {
let field_type = self.field_type;
let buckets: FxHashMap<SerializedKey, IntermediateRangeBucketEntry> = self
.buckets
@@ -190,77 +187,21 @@ impl SegmentAggregationCollector for SegmentRangeCollector {
range_to_string(&range_bucket.range, &field_type)?,
range_bucket
.bucket
.into_intermediate_bucket_entry(sub_agg)?,
.into_intermediate_bucket_entry(&agg_with_accessor.sub_aggregation)?,
))
})
.collect::<crate::Result<_>>()?;
let bucket = IntermediateBucketResult::Range(IntermediateRangeBucketResult {
buckets,
column_type: Some(self.column_type),
});
let buckets = Some(VecWithNames::from_entries(vec![(name, bucket)]));
Ok(IntermediateAggregationResults {
metrics: None,
buckets,
})
Ok(IntermediateBucketResult::Range(
IntermediateRangeBucketResult { buckets },
))
}
fn collect(
&mut self,
doc: crate::DocId,
agg_with_accessor: &AggregationsWithAccessor,
) -> crate::Result<()> {
self.collect_block(&[doc], agg_with_accessor)
}
fn collect_block(
&mut self,
docs: &[crate::DocId],
agg_with_accessor: &AggregationsWithAccessor,
) -> crate::Result<()> {
let accessor = &agg_with_accessor.buckets.values[self.accessor_idx].accessor;
let sub_aggregation_accessor =
&agg_with_accessor.buckets.values[self.accessor_idx].sub_aggregation;
for doc in docs {
for val in accessor.values_for_doc(*doc) {
let bucket_pos = self.get_bucket_pos(val);
let bucket = &mut self.buckets[bucket_pos];
bucket.bucket.doc_count += 1;
if let Some(sub_aggregation) = &mut bucket.bucket.sub_aggregation {
sub_aggregation.collect(*doc, sub_aggregation_accessor)?;
}
}
}
Ok(())
}
fn flush(&mut self, agg_with_accessor: &AggregationsWithAccessor) -> crate::Result<()> {
let sub_aggregation_accessor =
&agg_with_accessor.buckets.values[self.accessor_idx].sub_aggregation;
for bucket in self.buckets.iter_mut() {
if let Some(sub_agg) = bucket.bucket.sub_aggregation.as_mut() {
sub_agg.flush(sub_aggregation_accessor)?;
}
}
Ok(())
}
}
impl SegmentRangeCollector {
pub(crate) fn from_req_and_validate(
req: &RangeAggregation,
sub_aggregation: &AggregationsWithAccessor,
bucket_count: &BucketCount,
field_type: ColumnType,
accessor_idx: usize,
field_type: Type,
) -> crate::Result<Self> {
// The range input on the request is f64.
// We need to convert to u64 ranges, because we read the values as u64.
@@ -286,7 +227,9 @@ impl SegmentRangeCollector {
let sub_aggregation = if sub_aggregation.is_empty() {
None
} else {
Some(build_segment_agg_collector(sub_aggregation)?)
Some(SegmentAggregationResultsCollector::from_req_and_validate(
sub_aggregation,
)?)
};
Ok(SegmentRangeAndBucketEntry {
@@ -307,11 +250,69 @@ impl SegmentRangeCollector {
Ok(SegmentRangeCollector {
buckets,
column_type: field_type,
accessor_idx,
field_type,
})
}
#[inline]
pub(crate) fn collect_block(
&mut self,
doc: &[DocId],
bucket_with_accessor: &BucketAggregationWithAccessor,
force_flush: bool,
) -> crate::Result<()> {
let mut iter = doc.chunks_exact(4);
let accessor = bucket_with_accessor
.accessor
.as_single()
.expect("unexpected fast field cardinality");
for docs in iter.by_ref() {
let val1 = accessor.get_val(docs[0]);
let val2 = accessor.get_val(docs[1]);
let val3 = accessor.get_val(docs[2]);
let val4 = accessor.get_val(docs[3]);
let bucket_pos1 = self.get_bucket_pos(val1);
let bucket_pos2 = self.get_bucket_pos(val2);
let bucket_pos3 = self.get_bucket_pos(val3);
let bucket_pos4 = self.get_bucket_pos(val4);
self.increment_bucket(bucket_pos1, docs[0], &bucket_with_accessor.sub_aggregation)?;
self.increment_bucket(bucket_pos2, docs[1], &bucket_with_accessor.sub_aggregation)?;
self.increment_bucket(bucket_pos3, docs[2], &bucket_with_accessor.sub_aggregation)?;
self.increment_bucket(bucket_pos4, docs[3], &bucket_with_accessor.sub_aggregation)?;
}
for &doc in iter.remainder() {
let val = accessor.get_val(doc);
let bucket_pos = self.get_bucket_pos(val);
self.increment_bucket(bucket_pos, doc, &bucket_with_accessor.sub_aggregation)?;
}
if force_flush {
for bucket in &mut self.buckets {
if let Some(sub_aggregation) = &mut bucket.bucket.sub_aggregation {
sub_aggregation
.flush_staged_docs(&bucket_with_accessor.sub_aggregation, force_flush)?;
}
}
}
Ok(())
}
#[inline]
fn increment_bucket(
&mut self,
bucket_pos: usize,
doc: DocId,
bucket_with_accessor: &AggregationsWithAccessor,
) -> crate::Result<()> {
let bucket = &mut self.buckets[bucket_pos];
bucket.bucket.doc_count += 1;
if let Some(sub_aggregation) = &mut bucket.bucket.sub_aggregation {
sub_aggregation.collect(doc, bucket_with_accessor)?;
}
Ok(())
}
#[inline]
fn get_bucket_pos(&self, val: u64) -> usize {
let pos = self
@@ -337,7 +338,7 @@ impl SegmentRangeCollector {
/// more computational expensive when many documents are hit.
fn to_u64_range(
range: &RangeAggregationRange,
field_type: &ColumnType,
field_type: &Type,
) -> crate::Result<InternalRangeAggregationRange> {
let start = if let Some(from) = range.from {
f64_to_fastfield_u64(from, field_type)
@@ -363,7 +364,7 @@ fn to_u64_range(
/// beginning and end and filling gaps.
fn extend_validate_ranges(
buckets: &[RangeAggregationRange],
field_type: &ColumnType,
field_type: &Type,
) -> crate::Result<Vec<InternalRangeAggregationRange>> {
let mut converted_buckets = buckets
.iter()
@@ -405,16 +406,13 @@ fn extend_validate_ranges(
Ok(converted_buckets)
}
pub(crate) fn range_to_string(
range: &Range<u64>,
field_type: &ColumnType,
) -> crate::Result<String> {
pub(crate) fn range_to_string(range: &Range<u64>, field_type: &Type) -> crate::Result<String> {
// is_start is there for malformed requests, e.g. ig the user passes the range u64::MIN..0.0,
// it should be rendered as "*-0" and not "*-*"
let to_str = |val: u64, is_start: bool| {
if (is_start && val == u64::MIN) || (!is_start && val == u64::MAX) {
Ok("*".to_string())
} else if *field_type == ColumnType::DateTime {
} else if *field_type == Type::Date {
let val = i64::from_u64(val);
format_date(val)
} else {
@@ -429,21 +427,20 @@ pub(crate) fn range_to_string(
))
}
pub(crate) fn range_to_key(range: &Range<u64>, field_type: &ColumnType) -> crate::Result<Key> {
pub(crate) fn range_to_key(range: &Range<u64>, field_type: &Type) -> crate::Result<Key> {
Ok(Key::Str(range_to_string(range, field_type)?))
}
#[cfg(test)]
mod tests {
use columnar::MonotonicallyMappableToU64;
use fastfield_codecs::MonotonicallyMappableToU64;
use serde_json::Value;
use super::*;
use crate::aggregation::agg_req::{
Aggregation, Aggregations, BucketAggregation, BucketAggregationType, MetricAggregation,
Aggregation, Aggregations, BucketAggregation, BucketAggregationType,
};
use crate::aggregation::metric::AverageAggregation;
use crate::aggregation::tests::{
exec_request, exec_request_with_query, get_test_index_2_segments,
get_test_index_with_num_docs,
@@ -451,7 +448,7 @@ mod tests {
pub fn get_collector_from_ranges(
ranges: Vec<RangeAggregationRange>,
field_type: ColumnType,
field_type: Type,
) -> SegmentRangeCollector {
let req = RangeAggregation {
field: "dummy".to_string(),
@@ -464,7 +461,6 @@ mod tests {
&Default::default(),
&Default::default(),
field_type,
0,
)
.expect("unexpected error")
}
@@ -501,47 +497,6 @@ mod tests {
Ok(())
}
#[test]
fn range_fraction_test_with_sub_agg() -> crate::Result<()> {
let index = get_test_index_with_num_docs(false, 100)?;
let sub_agg_req: Aggregations = vec![(
"score_f64".to_string(),
Aggregation::Metric(MetricAggregation::Average(
AverageAggregation::from_field_name("score_f64".to_string()),
)),
)]
.into_iter()
.collect();
let agg_req: Aggregations = vec![(
"range".to_string(),
Aggregation::Bucket(BucketAggregation {
bucket_agg: BucketAggregationType::Range(RangeAggregation {
field: "fraction_f64".to_string(),
ranges: vec![(0f64..0.1f64).into(), (0.1f64..0.2f64).into()],
..Default::default()
}),
sub_aggregation: sub_agg_req,
}),
)]
.into_iter()
.collect();
let res = exec_request_with_query(agg_req, &index, None)?;
assert_eq!(res["range"]["buckets"][0]["key"], "*-0");
assert_eq!(res["range"]["buckets"][0]["doc_count"], 0);
assert_eq!(res["range"]["buckets"][1]["key"], "0-0.1");
assert_eq!(res["range"]["buckets"][1]["doc_count"], 10);
assert_eq!(res["range"]["buckets"][2]["key"], "0.1-0.2");
assert_eq!(res["range"]["buckets"][2]["doc_count"], 10);
assert_eq!(res["range"]["buckets"][3]["key"], "0.2-*");
assert_eq!(res["range"]["buckets"][3]["doc_count"], 80);
Ok(())
}
#[test]
fn range_keyed_buckets_test() -> crate::Result<()> {
let index = get_test_index_with_num_docs(false, 100)?;
@@ -741,7 +696,7 @@ mod tests {
#[test]
fn bucket_test_extend_range_hole() {
let buckets = vec![(10f64..20f64).into(), (30f64..40f64).into()];
let collector = get_collector_from_ranges(buckets, ColumnType::F64);
let collector = get_collector_from_ranges(buckets, Type::F64);
let buckets = collector.buckets;
assert_eq!(buckets[0].range.start, u64::MIN);
@@ -764,7 +719,7 @@ mod tests {
(10f64..20f64).into(),
(20f64..f64::MAX).into(),
];
let collector = get_collector_from_ranges(buckets, ColumnType::F64);
let collector = get_collector_from_ranges(buckets, Type::F64);
let buckets = collector.buckets;
assert_eq!(buckets[0].range.start, u64::MIN);
@@ -779,7 +734,7 @@ mod tests {
#[test]
fn bucket_range_test_negative_vals() {
let buckets = vec![(-10f64..-1f64).into()];
let collector = get_collector_from_ranges(buckets, ColumnType::F64);
let collector = get_collector_from_ranges(buckets, Type::F64);
let buckets = collector.buckets;
assert_eq!(&buckets[0].bucket.key.to_string(), "*--10");
@@ -788,7 +743,7 @@ mod tests {
#[test]
fn bucket_range_test_positive_vals() {
let buckets = vec![(0f64..10f64).into()];
let collector = get_collector_from_ranges(buckets, ColumnType::F64);
let collector = get_collector_from_ranges(buckets, Type::F64);
let buckets = collector.buckets;
assert_eq!(&buckets[0].bucket.key.to_string(), "*-0");
@@ -798,7 +753,7 @@ mod tests {
#[test]
fn range_binary_search_test_u64() {
let check_ranges = |ranges: Vec<RangeAggregationRange>| {
let collector = get_collector_from_ranges(ranges, ColumnType::U64);
let collector = get_collector_from_ranges(ranges, Type::U64);
let search = |val: u64| collector.get_bucket_pos(val);
assert_eq!(search(u64::MIN), 0);
@@ -844,7 +799,7 @@ mod tests {
fn range_binary_search_test_f64() {
let ranges = vec![(10.0..100.0).into()];
let collector = get_collector_from_ranges(ranges, ColumnType::F64);
let collector = get_collector_from_ranges(ranges, Type::F64);
let search = |val: u64| collector.get_bucket_pos(val);
assert_eq!(search(u64::MIN), 0);
@@ -879,7 +834,7 @@ mod bench {
buckets.push((bucket_start..bucket_start + bucket_size as f64).into())
}
get_collector_from_ranges(buckets, ColumnType::U64)
get_collector_from_ranges(buckets, Type::U64)
}
fn get_rand_docs(total_docs: u64, num_docs_returned: u64) -> Vec<u64> {

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