xforms
v0.16.0
Published
Extra transducers for Clojurescript
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xforms
More transducers and reducing functions for Clojure(script)!
Transducers can be classified in three groups: regular ones, higher-order ones (which accept other transducers as arguments) and aggrerators (transdcuers which emit only 1 item out no matter how many went in). Aggregators generally only make sense in the context of a higher-order transducer.
In net.cgrand.xforms
:
- regular ones:
partition
(1 arg),reductions
,for
,take-last
,drop-last
,sort
,sort-by
,wrap
,window
andwindow-by-time
- higher-order ones:
by-key
,into-by-key
,multiplex
,transjuxt
,partition
(2+ args) - aggregators:
reduce
,into
,without
,transjuxt
,last
,count
,avg
,sd
,min
,minimum
,max
,maximum
,str
In net.cgrand.xforms.io
:
sh
to use any process as a transducer
Reducing functions
- in
net.cgrand.xforms.rfs
:min
,minimum
,max
,maximum
,str
,str!
,avg
,sd
,last
andsome
. - in
net.cgrand.xforms.io
:line-out
andedn-out
.
(in net.cgrand.xforms
)
Transducing contexts:
- in
net.cgrand.xforms
:transjuxt
(for performing several transductions in a single pass),iterator
(clojure only),into
,without
,count
,str
(2 args) andsome
. - in
net.cgrand.xforms.io
:line-out
(3+ args) andedn-out
(3+ args). - in
net.cgrand.xforms.nodejs.stream
:transformer
.
Reducible views (in net.cgrand.xforms.io
): lines-in
and edn-in
.
Note: it should always be safe to update to the latest xforms version; short of bugfixes, breaking changes are avoided.
Usage
Add this dependency to your project:
[net.cgrand/xforms "0.16.0"]
=> (require '[net.cgrand.xforms :as x])
str
and str!
are two reducing functions to build Strings and StringBuilders in linear time.
=> (quick-bench (reduce str (range 256)))
Execution time mean : 58,714946 µs
=> (quick-bench (reduce rf/str (range 256)))
Execution time mean : 11,609631 µs
for
is the transducing cousin of clojure.core/for
:
=> (quick-bench (reduce + (for [i (range 128) j (range i)] (* i j))))
Execution time mean : 514,932029 µs
=> (quick-bench (transduce (x/for [i % j (range i)] (* i j)) + 0 (range 128)))
Execution time mean : 373,814060 µs
You can also use for
like clojure.core/for
: (x/for [i (range 128) j (range i)] (* i j))
expands to (eduction (x/for [i % j (range i)] (* i j)) (range 128))
.
by-key
and reduce
are two new transducers. Here is an example usage:
;; reimplementing group-by
(defn my-group-by [kfn coll]
(into {} (x/by-key kfn (x/reduce conj)) coll))
;; let's go transient!
(defn my-group-by [kfn coll]
(into {} (x/by-key kfn (x/into [])) coll))
=> (quick-bench (group-by odd? (range 256)))
Execution time mean : 29,356531 µs
=> (quick-bench (my-group-by odd? (range 256)))
Execution time mean : 20,604297 µs
Like by-key
, partition
also takes a transducer as last argument to allow further computation on the partition.
=> (sequence (x/partition 4 (x/reduce +)) (range 16))
(6 22 38 54)
Padding is achieved as usual:
=> (sequence (x/partition 4 4 (repeat :pad) (x/into [])) (range 9))
([0 1 2 3] [4 5 6 7] [8 :pad :pad :pad])
avg
is a transducer to compute the arithmetic mean. transjuxt
is used to perform several transductions at once.
=> (into {} (x/by-key odd? (x/transjuxt [(x/reduce +) x/avg])) (range 256))
{false [16256 127], true [16384 128]}
=> (into {} (x/by-key odd? (x/transjuxt {:sum (x/reduce +) :mean x/avg :count x/count})) (range 256))
{false {:sum 16256, :mean 127, :count 128}, true {:sum 16384, :mean 128, :count 128}}
window
is a new transducer to efficiently compute a windowed accumulator:
;; sum of last 3 items
=> (sequence (x/window 3 + -) (range 16))
(0 1 3 6 9 12 15 18 21 24 27 30 33 36 39 42)
=> (def nums (repeatedly 8 #(rand-int 42)))
#'user/nums
=> nums
(11 8 32 26 6 10 37 24)
;; avg of last 4 items
=> (sequence
(x/window 4 x/avg #(x/avg %1 %2 -1))
nums)
(11 19/2 17 77/4 18 37/2 79/4 77/4)
;; min of last 3 items
=> (sequence
(x/window 3
(fn
([] (sorted-set))
([s] (first s))
([s x] (conj s x)))
disj)
nums)
(11 8 8 8 6 6 6 10)
On Partitioning
Both by-key
and partition
takes a transducer as parameter. This transducer is used to further process each partition.
It's worth noting that all transformed outputs are subsequently interleaved. See:
=> (sequence (x/partition 2 1 identity) (range 8))
(0 1 1 2 2 3 3 4 4 5 5 6 6 7)
=> (sequence (x/by-key odd? identity) (range 8))
([false 0] [true 1] [false 2] [true 3] [false 4] [true 5] [false 6] [true 7])
That's why most of the time the last stage of the sub-transducer will be an aggregator like x/reduce
or x/into
:
=> (sequence (x/partition 2 1 (x/into [])) (range 8))
([0 1] [1 2] [2 3] [3 4] [4 5] [5 6] [6 7])
=> (sequence (x/by-key odd? (x/into [])) (range 8))
([false [0 2 4 6]] [true [1 3 5 7]])
Simple examples
(group-by kf coll)
is (into {} (x/by-key kf (x/into []) coll))
.
(plumbing/map-vals f m)
is (into {} (x/by-key (map f)) m)
.
My faithful (reduce-by kf f init coll)
is now (into {} (x/by-key kf (x/reduce f init)))
.
(frequencies coll)
is (into {} (x/by-key identity x/count) coll)
.
On key-value pairs
Clojure reduce-kv
is able to reduce key value pairs without allocating vectors or map entries: the key and value
are passed as second and third arguments of the reducing function.
Xforms allows a reducing function to advertise its support for key value pairs (3-arg arity) by implementing the KvRfable
protocol (in practice using the kvrf
macro).
Several xforms transducers and transducing contexts leverage reduce-kv
and kvrf
. When these functions are used together, pairs can be transformed without being allocated.
;; plain old sequences
=> (let [m (zipmap (range 1e5) (range 1e5))]
(crit/quick-bench
(into {}
(for [[k v] m]
[k (inc v)]))))
Evaluation count : 12 in 6 samples of 2 calls.
Execution time mean : 55,150081 ms
Execution time std-deviation : 1,397185 ms
;; x/for but pairs are allocated (because of into)
=> (let [m (zipmap (range 1e5) (range 1e5))]
(crit/quick-bench
(into {}
(x/for [[k v] _]
[k (inc v)])
m)))
Evaluation count : 18 in 6 samples of 3 calls.
Execution time mean : 39,119387 ms
Execution time std-deviation : 1,456902 ms
;; x/for but no pairs are allocated (thanks to x/into)
=> (let [m (zipmap (range 1e5) (range 1e5))]
(crit/quick-bench (x/into {}
(x/for [[k v] %]
[k (inc v)])
m)))
Evaluation count : 24 in 6 samples of 4 calls.
Execution time mean : 24,276790 ms
Execution time std-deviation : 364,932996 µs
Changelog
0.9.5
- Short (up to 4) literal collections (or literal collections with
:unroll
metadata) in collection positions inx/for
are unrolled. This means that the collection is not allocated. If it's a collection of pairs (e.g. maps), pairs themselves won't be allocated.
0.9.4
- Add
x/into-by-key
short hand
0.7.2
- Fix transients perf issue in Clojurescript
0.7.1
- Works with Clojurescript (even self-hosted).
0.7.0
- Added 2-arg arity to
x/count
where it acts as a transducing context e.g.(x/count (filter odd?) (range 10))
- Preserve type hints in
x/for
(and generally withkvrf
).
0.6.0
- Added
x/reductions
- Now if the first collection expression in
x/for
is not a placeholder thenx/for
works likex/for
but returns an eduction and performs all iterations using reduce.
License
Copyright © 2015-2016 Christophe Grand
Distributed under the Eclipse Public License either version 1.0 or (at your option) any later version.