Caching (aka memoization) is very powerful optimization technique - however it only makes sense when maintaining the cache itself and looking up cached results is cheaper than performing computation itself again. You don't need WASM to speed up JS
Blazing fast usage-tracking based selection and memoization library, which always works....
Read me - How I wrote the worldβs fastest memoization library
Reselect? Memoize-one? Most of memoization libraries remembers the parameters you provided, not what you did inside. Sometimes is not easy to achive high cache hit ratio. Sometimes you have to think about how to properly dissolve computation into the memoizable parts.
I don't want to think how to use memoization, I want to use memoization!
Memoize-state is built to memoize more complex situations, even the ones which are faster to recompute, than to deside that recalculation is not needed. Just because one cheap computation can cause a redraw/reflow/recomputation cascade for a whole application.
Lets imagine some complex function.
const fn = memoize(
(number, state, string) => ({result: state[string] number})
)
let firstValue = fn(1, { value: 1, otherValue : 1 }, 'value'); // first call
firstValue === fn(1, { value: 1, otherValue : 2 }, 'value'); // "nothing" changed
firstValue === fn(1, { value: 1, somethingElse: 3 }, 'value'); // "nothing" changed
firstValue !== fn(2, { value: 1, somethingElse: 3 }, 'value'); // something important changed
All ordinal memoization libraries will drop cache each time, as long state
is different each time.
More of it - they will return a unique object each time, as long the function is returning a new object each time.
But not today!
Memoize-state memoizes tracks used state parts, using the same magic, as you can find in MobX or immer.
It will know, that it should react only on some state.value1
change, but not value2
. Perfect.
Now you able just to write functions AS YOU WANT. Memoize-state will detect all really used arguments, variables and keys, and then - react only to the right changes.
- React-memoize - magic memoization for React, componentWillReceiveProps optimization, selection from context, whole SFC memoization.
- beautiful-react-redux - instant memoization for React-Redux
- why-did-you-update-redux - selector quiality checker
- react-tracked - React Context API made using the same principles.
- your project!
memoizeState(function, options)
- creates memoized variant of a function.
- Name, length (argument count), and any other own key will be transferred to memoized result
- If argument is an object - memoize will perform
proxyequal
comparison, resulting true, of you did no access any object member - If argument is not an object - memoize will compare values.
- result function will have
cacheStatistics
method. JFYI.
cacheSize
, default 1. The size of the cache.shallowCheck
, default true. Perform shallow equal between arguments.equalCheck
, default true. Perform deep proxyequal comparision.strictArity
, default false. Limit arguments count to the function default.nestedEquality
, default true. Keep the object equality for sub-proxies.safe
, default false. Activate thesafe
memoization mode. See below.
You know - it should be a pure function, returning the same results for the same arguments.
mapStateToProps, should be strict equal across the different calls
mapStateToProps(state) === mapStateToProps(state)
or, at least, shallow equal
shallowEqual(mapStateToProps(state), mapStateToProps(state))
.
Creating good memoization function, using reselect, avoiding side-effects - it could be hard. I know.
Memoize-state was created to solve this case, especially this case.
Memoize-state will track the way you USE the state.
const state = {
branch1: {...},
branch2: {someKey1:1, someKey2: 2}
}
const aFunction = (state) => state.branch2.someKey2 && Math.random();
const fastFunction = memoize(aFunction);
After the first launch memoize-state will detect the used parts of a state, and then react only for changes inside them
const result1 = fastFunction(state);
// result1 - some random. 42 for example
const result2 = fastFunction({branch2: {someKey2:2}})
// result2 - the same value! A new state is `proxyequal` to the old
const result3 = fastFunction({branch2: {someKey2:3}})
// result3 - is the NEW, at last.
- Wrap mapStateToProps by
memoize
- Choose the memoization options (unsafe by default).
import memoize from 'memoize-state';
const mapStateToProps = memoize((state, props) => {
//....
});
You can use compose(flow, flowRight) to pipe result from one memoized function to another. But better to use flow
! All functions accepts Object as input and return __Object as output.
import {memoizedFlow, memoizedFlowRight, memoizedPipe, memoizedCompose} from 'memoize-state';
// memoizedFlow will merge result with the current input
// thus you can not import and not return all the keys
// and memoization will work
const sequence = memoizedFlow([
({a,b}) => ({sumAB: a b}),
({a,c}) => ({sumAC: a c}),
({sumAB, sumAC}) => ({result: sumAB sumAC})
]);
sequence({a:1, b:1, c:1}) === ({a:1, b:1, c:1, sumAB: 2, sumAC: 2, result: 4})
//----------------
import flow from 'lodash.flow';
// You have to rethrow all the variables you might need in the future
// and memoization will not properly work, as long step2 will be regenerated then you will change b
// as long it depends on sumAB from step1
const sequence = flow([
({a,b, c}) => ({sumAB: a b, a,c}),
({a,c, sumAB}) => ({sumAC: a c, sumAB}),
({sumAB, sumAC}) => ({result: sumAB sumAC})
]);
sequence({a:1, b:1, c:1}) === ({result: 4})
memoizedFlow
is equal tomemoizedPipe
, and applies functions from first to last.memoizedFlowRight
is equal tomemoizedCompose
, and applies functions from last to right(right).
You also could use memoize-state to double check your selectors.
import {shouldBePure} from 'memoize-state';
const mapStateToProps = shouldBePure((state, props) => {
//....
});
// then it will log all situations, when result was not shallow equal to the old one, but should.
shouldBePure
will deactivate itself in production
env. Use shallBePure
if you need it always enabled.
Not all functions could be safely
memoized. Just not all of them.
The wrapped function have to be pure.
let cache = 0;
const func = (state) => (cache || cache = state.a);
const memoizedState = memoize(func);
memoizedState({a:1}); // will return 1 AND fill up the cache
memoizedState({a:2}); // will return 1 FROM cache, and dont read anything from state
memoizedState({a:3}); // memoize state saw, that you dont read anything from a state.
// and will ignore __ANY__ changes. __FOREVER__!
PS: this would not happened if state.a is a object. Memoize-state will understand the case, when you are returning a part of a state
It's easy to fix - memoize(func, { safe: true })
, but func will be called twice to detect internal memoization.
In case of internal memoization safe-memoize will deactivate itself.
Check performed only twice. Once on execution, and once on first cached result. In both cases wrapped function should return the "same" result.
Yes, you could.
But memoize-state could disable another underlying memoizations libraries.
Not everything is simple. Memoize-state works on copies of original object, returning the original object, if you have returned a copy.
That means - if you get an array. sort it and return result - you will return unsorted result.
Input has to be immutable
, don't sort it, don't mutate it, don't forget to Array.slice().
but you are the right person to watch over it.
Uses ES6 Proxy
underneath to detect used branches of a state (as MobX
).
Removes all the magic from result value.
Should be slower than "manual" __reselect__ors, but faster than anything else.
We have a performance test, according to the results -
- memoize-state is not slower than major competitors, and 10-100x times faster, for the "state" cases.
- lodash.memoize and fast-memoize could not handle big states as input.
- memoize-one should be super fast, but it is not
But the major difference is
- memoize-one are having highest hitratio, than means - it were able to "memoize" most of the cases
function of 3 arguments, all unchanged
base x 10230 ops/sec Β±2.63% (5 runs sampled) hitratio 0% 5700 /5700
memoize-one x 24150462 ops/sec Β±3.02% (6 runs sampled) hitratio 100% 1 /14019795
lodash.memoize x 2954428 ops/sec Β±4.02% (6 runs sampled) hitratio 100% 1 /15818699
fast-memoize x 1065755 ops/sec Β±3.22% (6 runs sampled) hitratio 100% 1 /16243313
memoize-state x 4910783 ops/sec Β±2.55% (5 runs sampled) hitratio 100% 1 /18929141
Fastest is memoize-one
function of 1 arguments, object unchanged
base x 408704195 ops/sec Β±0.55% (5 runs sampled) hitratio 100% 0 /188881067
memoize-one x 77024718 ops/sec Β±1.78% (6 runs sampled) hitratio 100% 0 /221442642
lodash.memoize x 3776797 ops/sec Β±1.55% (6 runs sampled) hitratio 100% 0 /223654022
fast-memoize x 75375793 ops/sec Β±3.08% (6 runs sampled) hitratio 100% 0 /267664702
memoize-state x 5690401 ops/sec Β±3.77% (5 runs sampled) hitratio 100% 0 /271589669
Fastest is base
function of 1 arguments, object unchanged
base x 398167311 ops/sec Β±0.50% (6 runs sampled) hitratio 100% 0 /190155405
memoize-one x 76062398 ops/sec Β±3.71% (6 runs sampled) hitratio 100% 0 /231172341
lodash.memoize x 3734556 ops/sec Β±6.70% (6 runs sampled) hitratio 100% 0 /233243184
fast-memoize x 37234595 ops/sec Β±2.30% (6 runs sampled) hitratio 100% 0 /250419641
memoize-state x 639290 ops/sec Β±6.09% (6 runs sampled) hitratio 100% 0 /250718787
Fastest is base
function of 2 arguments, providing 3, all unchanged
base x 10426 ops/sec Β±3.01% (6 runs sampled) hitratio 0% 3712 /3712
memoize-one x 24164455 ops/sec Β±6.67% (6 runs sampled) hitratio 100% 1 /15190474
lodash.memoize x 2826340 ops/sec Β±3.44% (6 runs sampled) hitratio 100% 1 /16624930
fast-memoize x 1070852 ops/sec Β±2.70% (6 runs sampled) hitratio 100% 1 /17155394
memoize-state x 4966459 ops/sec Β±1.13% (5 runs sampled) hitratio 100% 1 /19324311
Fastest is memoize-one
function of 3 arguments, all changed / 10
base x 10189 ops/sec Β±3.13% (6 runs sampled) hitratio 0% 3657 /3657
memoize-one x 19842 ops/sec Β±2.73% (6 runs sampled) hitratio 63% 5316 /14288
lodash.memoize x 33160 ops/sec Β±1.45% (5 runs sampled) hitratio 83% 5782 /33561
fast-memoize x 19029 ops/sec Β±6.04% (5 runs sampled) hitratio 86% 6731 /47024
memoize-state x 18527 ops/sec Β±10.56% (5 runs sampled) hitratio 93% 3868 /54760
Fastest is lodash.memoize
function with an object as argument, returning a part
base x 10095 ops/sec Β±3.49% (5 runs sampled) hitratio 0% 4107 /4107
memoize-one x 10054 ops/sec Β±3.14% (6 runs sampled) hitratio 50% 4141 /8249
lodash.memoize x 1695449 ops/sec Β±3.68% (6 runs sampled) hitratio 100% 1 /950379
fast-memoize x 1287216 ops/sec Β±1.29% (6 runs sampled) hitratio 100% 1 /1590863
memoize-state x 1574688 ops/sec Β±2.24% (6 runs sampled) hitratio 100% 1 /2469327
Fastest is lodash.memoize
function with an object as argument, changing value, returning a part
base x 10187 ops/sec Β±1.66% (6 runs sampled) hitratio 0% 4179 /4179
memoize-one x 10205 ops/sec Β±3.96% (6 runs sampled) hitratio 50% 4174 /8354
lodash.memoize x 87943 ops/sec Β±12.70% (5 runs sampled) hitratio 92% 4138 /49727
fast-memoize x 90510 ops/sec Β±1.05% (6 runs sampled) hitratio 96% 3972 /89439
memoize-state x 76372 ops/sec Β±6.67% (6 runs sampled) hitratio 97% 3612 /125554
Fastest is fast-memoize,lodash.memoize
function with an object as argument, changing other value, returning a part
base x 9867 ops/sec Β±7.72% (5 runs sampled) hitratio 0% 4537 /4537
memoize-one x 10066 ops/sec Β±4.24% (5 runs sampled) hitratio 47% 5059 /9597
lodash.memoize x 92596 ops/sec Β±0.61% (6 runs sampled) hitratio 92% 4515 /54745
fast-memoize x 89224 ops/sec Β±1.24% (5 runs sampled) hitratio 96% 3445 /89181
memoize-state x 1469865 ops/sec Β±2.95% (5 runs sampled) hitratio 100% 1 /805990
Fastest is memoize-state
function with 2 objects as argument, changing both value
base x 10127 ops/sec Β±2.21% (5 runs sampled) hitratio 0% 5489 /5489
memoize-one x 10030 ops/sec Β±3.97% (6 runs sampled) hitratio 60% 3702 /9192
lodash.memoize x 9745 ops/sec Β±4.69% (6 runs sampled) hitratio 70% 3997 /13190
fast-memoize x 9268 ops/sec Β±5.04% (5 runs sampled) hitratio 77% 3855 /17046
memoize-state x 63493 ops/sec Β±6.49% (6 runs sampled) hitratio 94% 2736 /44395
Fastest is memoize-state
when changes anything, except the function gonna to consume
base x 9901 ops/sec Β±3.78% (6 runs sampled) hitratio 0% 5121 /5121
memoize-one x 10087 ops/sec Β±2.59% (6 runs sampled) hitratio 57% 3914 /9036
lodash.memoize x 9643 ops/sec Β±1.25% (6 runs sampled) hitratio 67% 4361 /13398
fast-memoize x 9554 ops/sec Β±1.13% (6 runs sampled) hitratio 76% 4228 /17627
memoize-state x 520442 ops/sec Β±1.54% (5 runs sampled) hitratio 100% 1 /270727
Fastest is memoize-state
when state is very big, and you need a small part
base x 10097 ops/sec Β±1.63% (6 runs sampled) hitratio 0% 4428 /4428
memoize-one x 9262 ops/sec Β±6.27% (5 runs sampled) hitratio 53% 3974 /8403
lodash.memoize x 276 ops/sec Β±3.31% (6 runs sampled) hitratio 100% 12 /8516
fast-memoize x 280 ops/sec Β±4.77% (6 runs sampled) hitratio 100% 10 /8615
memoize-state x 83005 ops/sec Β±6.47% (6 runs sampled) hitratio 92% 4042 /49019
Fastest is memoize-state
function fn1(object) {
return object.value
}
// ^^ memoize state will react to any change of .value
function fn2(object) {
return {...object.value}
}
// ^^ memoize state will react to any change of the values inside the .value
// for example, if value contain booleans the X and they Y - they form 4 possible pairs
const superMemoize = memoize(fn2, { cacheSize: 4 });
// ^^ you just got uber function, which will return 4 exactly the same objects
Executing the function against EMPTY function, but triggering most of internal mechanics.
base x 244.000.431
memoize-one x 18.150.966
lodash.memoize x 3.941.183
fast-memoize x 34.699.858
memoize-state x 4.615.104
this 4 millions operations per second? A bit more that enough
Memoize-state is not a best fit for a common case. It is designed to handle
- the complex objects
- limited count of stored cache lines (default: 1)
This is a fibonacci test from - fast-memoize. The test uses different performance measuring tool and numbers differs.
β fast-memoize@current β 204,819,529 β Β± 0.85% β 88 β
ββββββββββββββββββββββββββββββΌββββββββββββββΌβββββββββββββββββββββββββββΌββββββββββββββ€
β lru-memoize (single cache) β 84,862,416 β Β± 0.59% β 93 β
ββββββββββββββββββββββββββββββΌββββββββββββββΌβββββββββββββββββββββββββββΌββββββββββββββ€
β iMemoized β 35,008,566 β Β± 1.29% β 90 β
ββββββββββββββββββββββββββββββΌββββββββββββββΌβββββββββββββββββββββββββββΌββββββββββββββ€
β lodash β 24,197,907 β Β± 3.70% β 82 β
ββββββββββββββββββββββββββββββΌββββββββββββββΌβββββββββββββββββββββββββββΌββββββββββββββ€
β underscore β 17,308,464 β Β± 2.79% β 87 β
ββββββββββββββββββββββββββββββΌββββββββββββββΌβββββββββββββββββββββββββββΌββββββββββββββ€
β memoize-state <<---- β 17,175,290 β Β± 0.80% β 87 β
ββββββββββββββββββββββββββββββΌββββββββββββββΌβββββββββββββββββββββββββββΌββββββββββββββ€
β memoizee β 12,908,819 β Β± 2.60% β 78 β
ββββββββββββββββββββββββββββββΌββββββββββββββΌβββββββββββββββββββββββββββΌββββββββββββββ€
β lru-memoize (with limit) β 9,357,237 β Β± 0.47% β 91 β
ββββββββββββββββββββββββββββββΌββββββββββββββΌβββββββββββββββββββββββββββΌββββββββββββββ€
β ramda β 1,323,820 β Β± 0.54% β 92 β
ββββββββββββββββββββββββββββββΌββββββββββββββΌβββββββββββββββββββββββββββΌββββββββββββββ€
β vanilla β 122,835 β Β± 0.72% β 89 β
ββββββββββββββββββββββββββββββ΄ββββββββββββββ΄βββββββββββββββββββββββββββ΄ββββββββββββββ
memoize-state is comparable with lodash and underscore, even in this example.
memoize-state: object spread detected in XXX. Consider refactoring.
Memoize state could not properly work if you "spread" state
const mapStateToProps = ({prop,i,need,...rest}) =>....
//or
const mapStateToProps = (state, props) => ({ ...state, ...props })
//or
const mapState = ({ page, direction, ...state }) => ({
page,
direction,
isLoading: isLoading(state)
})
It will assume, that you need ALL the keys, meanwhile - you could not.
Workaround - refactor the code
const mapState = state => ({
page: state.page,
direction: state.direction,
isLoading: isLoading(state)
})
See issue for more details
IE11/Android compatible. Contains proxy-polyfill inside.
MIT