Cypher relationships disconnected from nodes (pointing to nothing). Variable names wrong? - cypher

I'm expecting this script
// $ cd ~/Documents/neo4j-community-2.2.5/bin
// $ ./neo4j-shell -file ~/Documents/neo4j_input/neo4j_queries.txt
//Purge
MATCH ()-[r]-() DELETE r;
MATCH (n) DELETE n;
CREATE (p1:Person { first_name: "Apple", age: 9 });
CREATE (p2:Person { first_name: "Bear", age: 44 });
CREATE (p2)-[x:ISPARENTOF]->(p1);
CREATE (p1)-[x2:ISCHILDOF]->(p2);
to look like this, with the relationships pointing from each person to the other:
-ISCHILDOF->
(p1) (p2)
<-ISPARENTOF-
But instead the relationships are pointing to thin air. What am I missing?

Identifiers are only relevant within the scope of the query. You're executing separate queries.
CREATE (p1:Person { first_name: "Apple", age: 9 });
CREATE (p2:Person { first_name: "Bear", age: 44 });
CREATE (p2)-[x:ISPARENTOF]->(p1);
CREATE (p1)-[x2:ISCHILDOF]->(p2);
In the 3rd and 4th queries, p1 and p2 are not bound to anything. You're creating nodes with no labels and no properties. You just need to remove the semicolons so that it's one query.
CREATE (p1:Person { first_name: "Apple", age: 9 })
CREATE (p2:Person { first_name: "Bear", age: 44 })
CREATE (p2)-[x:ISPARENTOF]->(p1)
CREATE (p1)-[x2:ISCHILDOF]->(p2);
In this query, p1 and p2 are bound when they're created at lines 1 and 2 respectively and used again at lines 4 and 5.

Related

How to return array of objects from other table postgres node js

Parent Table
id
name
1
ben
2
fred
3
david
Child Table
id
name
parent_id
1
sergey
1
2
jake
2
3
rudolp
1
I want to make a get request like this from my node server and this is my expected response.
also can you suggest best practices in this approach, I am thinking of getting all the data/table in server then looping on them to generate the array of objects . Thanks
[
{
id:1
name: "Ben",
childs:[{id: 1, name: "sergey"},{id: 3, name: "rudolp"}]
},
{
id:2
name: "Fred",
childs:[{id: 2, name: "Jake"}]
},
}
]

How to query by multiple conditions in faunadb?

I try to improve my understanding of FaunaDB.
I have a collection that contains records like:
{
"ref": Ref(Collection("regions"), "261442015390073344"),
"ts": 1587576285055000,
"data": {
"name": "italy",
"attributes": {
"amenities": {
"camping": 1,
"swimming": 7,
"hiking": 3,
"culture": 7,
"nightlife": 10,
"budget": 6
}
}
}
}
I would like to query in a flexible way by different attributes like:
data.attributes.amenities.camping > 5
data.attributes.amenities.camping > 5 AND data.attributes.amenities.hiking > 6
data.attributes.amenities.camping < 6 AND data.attributes.amenities.culture > 6 AND hiking > 5 AND ...
I created an index containing all attributes, but I don't know how to do greater equals filtering in an index that contains multiple terms.
My fallback would be to create an index for each attribute and use Intersection to get the records that are in all subqueries that I want to check, but this feels somehow wrong:
The query: budget >= 6 AND camping >=8 would be:
Index:
{
name: "all_regions_by_all_attributes",
unique: false,
serialized: true,
source: "regions",
terms: [],
values: [
{
field: ["data", "attributes", "amenities", "culture"]
},
{
field: ["data", "attributes", "amenities", "hiking"]
},
{
field: ["data", "attributes", "amenities", "swimming"]
},
{
field: ["data", "attributes", "amenities", "budget"]
},
{
field: ["data", "attributes", "amenities", "nightlife"]
},
{
field: ["data", "attributes", "amenities", "camping"]
},
{
field: ["ref"]
}
]
}
Query:
Map(
Paginate(
Intersection(
Range(Match(Index("all_regions_by_all_attributes")), [0, 0, 0, 6, 0, 8], [10, 10, 10, 10, 10, 10]),
)
),
Lambda(
["culture", "hiking", "swimming", "budget", "nightlife", "camping", "ref"],
Get(Var("ref"))
)
)
This approach has the following disadvantages:
It does not work like expected, if for example the first (culture) attribute is in this range, but the second (hiking) not, then I would still get a return values
It causes a lot of reads due to the reference that I need to follow for each result.
Is it possible to store all values in this kind of index that would contain all the data? I know I can just add more values to the index and access them. But this would mean I have to create a new index as soon as we add more fields to the entity. But maybe this is a common thing.
thanks in advance
Thanks for your question. Ben already wrote out a complete example that shows what you can do and I'll base myself on his recommendations and try to clarify further.
FaunaDB's FQL is quite powerful which means there are multiple ways to do that, yet with such power comes a small learning curve so I'm happy to help :). The reason it took a while to answer this question is that such an elaborate answer actually deserves a complete blog post. Well, I've never written a blog post in Stack Overflow, there is a first for everything!
There are three ways to do 'compound range-like queries' but there is one way that will be most performant for your use-case and we'll see that the first approach is actually not entirely what you need. Spoiler, the third option we describe here is what you need.
Preparation - Let's throw in some data just like Ben did
I'll keep it in one collection to keep it simpler and am using the JavaScript flavour of the Fauna Query Language here. There is a good reason to separate data in a second collection though which is related to your second map/get question (see the end of this answer)
Create the collection
CreateCollection({ name: 'place' })
Throw in some data
Do(
Select(
['ref'],
Create(Collection('place'), {
data: {
name: 'mullion',
focus: 'team-building',
camping: 1,
swimming: 7,
hiking: 3,
culture: 7,
nightlife: 10,
budget: 6
}
})
),
Select(
['ref'],
Create(Collection('place'), {
data: {
name: 'church covet',
focus: 'private',
camping: 1,
swimming: 7,
hiking: 9,
culture: 7,
nightlife: 10,
budget: 6
}
})
),
Select(
['ref'],
Create(Collection('place'), {
data: {
name: 'the great outdoors',
focus: 'private',
camping: 5,
swimming: 3,
hiking: 2,
culture: 1,
nightlife: 9,
budget: 3
}
})
)
)
OPTION 1: Composite indexes with multiple values
We can put as many terms as values in an index and use Match and Range to query those. However! Range probably gives you something different than you would expect if you use multiple values. Range gives you exactly what the index does and the index sorts values lexically. If we look at the example of Range in the docs we see an example there which we can extend upon for multiple values.
Imagine we would have an index with two values and we write:
Range(Match(Index('people_by_age_first')), [80, 'Leslie'], [92, 'Marvin'])
Then the result will be what you see on the left and not what you see on the right. This is a very scalable behaviour and exposes the raw-power without overhead of the underlying index but is not exactly what you are looking for!
So let's move on to another solution!
OPTION 2: First Range, then Filter
Another quite flexible solution is to use Range and then Filter. This however is a less good idea in case you are filtering out a lot with filter since your pages will become more empty. Imagine that you have 10 items in a page after the 'Range' and use filter, then you will end up with pages of 2, 5, 4 elements depending on what is filtered out. This is a great idea however if one of these properties has such a high cardinality that it will filter out most of entities. E.g. imagine everything is timestamped, you want to first get a date range and then continue filtering something that will only eliminate a small percentage of the resultset. I believe that in your case all of these values are quite equal so this the third solution (see lower) will be the best for you.
We could in this case just throw all values in so that they all get returned which avoids a Get. For example, let's say that 'camping' is our most important filter.
CreateIndex({
name: 'all_camping_first',
source: Collection('place'),
values: [
{ field: ['data', 'camping'] },
// and the rest will not be used for filter
// but we want to return them to avoid Map/Get
{ field: ['data', 'swimming'] },
{ field: ['data', 'hiking'] },
{ field: ['data', 'culture'] },
{ field: ['data', 'nightlife'] },
{ field: ['data', 'budget'] },
{ field: ['data', 'name'] },
{ field: ['data', 'focus'] },
]
})
You can now write a query that just gets a range based on the camping value:
Paginate(Range(Match('all_camping_first'), [1], [3]))
Which should return two elements (the third has camping === 5)
Now imagine that we want to filter over these and we set our pages small to avoid unnecessary work
Filter(
Paginate(Range(Match('all_camping_first'), [1], [3]), { size: 2 }),
Lambda(
['camping', 'swimming', 'hiking', 'culture', 'nightlife', 'budget', 'name', 'focus'],
And(GTE(Var('hiking'), 0), GTE(7, Var('hiking')))
)
)
Since I want to be clear on both the advantages as disadvantages of each approach, let's show exactly how filter works by adding another one that has attributes that match our query.
Create(Collection('place'), {
data: {
name: 'the safari',
focus: 'team-building',
camping: 1,
swimming: 9,
hiking: 2,
culture: 4,
nightlife: 3,
budget: 10
}
})
Running the same query:
Filter(
Paginate(Range(Match('all_camping_first'), [1], [3]), { size: 2 }),
Lambda(
['camping', 'swimming', 'hiking', 'culture', 'nightlife', 'budget', 'name', 'focus'],
And(GTE(Var('hiking'), 0), GTE(7, Var('hiking')))
)
)
Now still returns only one value but provides you with an 'after' cursor that points to the next page. You might think: "huh? My page size was 2?". Well that's because Filter works after Pagination and your page originally had two entities from which one got filtered out. So you are left with a page of 1 value and a pointer to the next page.
{
"after": [
...
],
"data": [
[
1,
7,
3,
7,
10,
6,
"mullion",
"team-building"
]
]
You could also opt to Filter directly on the SetRef as well and only paginate afterwards. In that case, the size of your pages will contain the required size. However, keep in mind that this is an O(n) operation on the amount of elements that comes back from Range. Range uses an index but from the moment you use Filter, it will loop over each of the elements.
OPTION 3: Indexes on one value + Intersections!
This is the best solution for your use-case but it requires a bit more understanding and an intermediate index.
When we look at the doc examples for intersection we see this example:
Paginate(
Intersection(
Match(q.Index('spells_by_element'), 'fire'),
Match(q.Index('spells_by_element'), 'water'),
)
)
This works because it's two times the same index and that means that **the results are similar values ** (references in this case).
Let's say we add a few indexes.
CreateIndex({
name: 'by_camping',
source: Collection('place'),
values: [
{ field: ['data', 'camping']}, {field: ['ref']}
]
})
CreateIndex({
name: 'by_swimming',
source: Collection('place'),
values: [
{ field: ['data', 'swimming']}, {field: ['ref']}
]
})
CreateIndex({
name: 'by_hiking',
source: Collection('place'),
values: [
{ field: ['data', 'hiking']}, {field: ['ref']}
]
})
We can intersect on them now but it will not give us the right result. For example... let's call this:
Paginate(
Intersection(
Range(Match(Index("by_camping")), [3], []),
Range(Match(Index("by_swimming")), [3], [])
)
)
The result is empty. Although we had one with swimming 3 and camping 5.
That is exactly the problem. If swimming and camping were both the same value we would get a result. So it's important to notice that Intersection intersects the values, so that includes both the camping/swimming value as well as the reference. That means that we have to drop the value since we only need the reference. The way to do that before pagination is with a join, Essentially we are going to join with another index that is going to just.. return the ref (not specifying values defaults to only the ref)
CreateIndex({
name: 'ref_by_ref',
source: Collection('place'),
terms: [{field: ['ref']}]
})
This join looks as follows
Paginate(Join(
Range(Match(Index('by_camping')), [4], [9]),
Lambda(['value', 'ref'], Match(Index('ref_by_ref'), Var('ref'))
)))
Here we just took the result of Match(Index('by_camping')) and just dropped the value by joining with an index that only returns the ref. Now let's combine this and just do an AND kind of range query ;)
Paginate(Intersection(
Join(
Range(Match(Index('by_camping')), [1], [3]),
Lambda(['value', 'ref'], Match(Index('ref_by_ref'), Var('ref'))
)),
Join(
Range(Match(Index('by_hiking')), [0], [7]),
Lambda(['value', 'ref'], Match(Index('ref_by_ref'), Var('ref'))
))
))
The result is two values, and both in the same page!
Note that you can easily extend or compose FQL by just using the native language (in this case JS) to make this look much nicer (note I didn't test this piece of code)
const DropAllButRef = function(RangeMatch) {
return Join(
RangeMatch,
Lambda(['value', 'ref'], Match(Index('ref_by_ref'), Var('ref'))
))
}
Paginate(Intersection(
DropAllButRef (Range(Match(Index('by_camping')), [1], [3])),
DropAllButRef (Range(Match(Index('by_hiking')), [0], [7]))
))
And a final extension, this only returns indexes so you'll need to map get. There is of course a way around this if you really want to by.. just using another index :)
const index = CreateIndex({
name: 'all_values_by_ref',
source: Collection('place'),
values: [
{ field: ['data', 'camping'] },
{ field: ['data', 'swimming'] },
{ field: ['data', 'hiking'] },
{ field: ['data', 'culture'] },
{ field: ['data', 'nightlife'] },
{ field: ['data', 'budget'] },
{ field: ['data', 'name'] },
{ field: ['data', 'focus'] }
],
terms: [
{ field: ['ref'] }
]
})
Now you have the range query, will get everything without a map/get:
Paginate(
Intersection(
Join(
Range(Match(Index('by_camping')), [1], [3]),
Lambda(['value', 'ref'], Match(Index('all_values_by_ref'), Var('ref'))
)),
Join(
Range(Match(Index('by_hiking')), [0], [7]),
Lambda(['value', 'ref'], Match(Index('all_values_by_ref'), Var('ref'))
))
)
)
With this join approach you could even do range indexes on different collections as long as you join them to the same reference before intersecting! Pretty cool huh?
Can I store more values in the index?
Yes you can, indexes in FaunaDB are views, so let's call them indiviews. It's a tradeoff, essentially you are exchanging compute for storage. By making a view with many values you get very fast access to a certain subset of your data. But there is another tradeoff and that is flexibility. You can not just go adding elements since that would require you to rewrite your whole index. In that case you will have to make a new index and wait for it to build if you have much data (and yes, that is quite common) and make sure that the queries you do (look at the lambda parameters in map filter) match your new index. You can always delete the other index afterwards. Just using Map/Get will be more flexible, everything in databases is a tradeoff and FaunaDB gives you both options :). I would suggest to use such an approach from the moment your datamodel is fixed and you see a specific part in your app that you want to optimise.
Avoiding MapGet
The second question on Map/Get requires some explanation. Separating out the values that you will search on from the places (as Ben did) is a great idea if you want to use Join to get the actual places more efficiently. This will not require a Map Get and therefore cost you far less reads but do notice that Join is rather a traverse (it'll replace the current references with the target references it joins to) so if you need both the values and the actual place data in one object at the end of your query than you will require Map/Get. Look at it from this perspective, indexes are ridiculously cheap in terms of reads and you can go quite far with those but for some operations there is just no way around Map/Get, Get is still only 1 read. Given that you get 100 000 for free per day that is still not expensive :). You could keep your pages also relatively small (size parameter in paginate) to make sure you don't do unnecessary gets unless your users or app requires more pages.
For people reading this that do not know this yet:
1 index page === 1 read
1 get === 1 read
Final notes
We can and will make this easier in the future. However, note that you are working with a scalable distributed database and often these things are just not even possible in other solutions or very inefficient. FaunaDB provides you with very powerful structures and raw access to how indexes work and gives you many options. It does not try to be clever for you behind the scenes as this might result in very inefficient queries in case we get it wrong (that would be a bummer in a scalable pay-as-you-go system).
There are a couple of misconceptions that I think are leading you astray. The most important one: Match(Index($x)) generates a set reference, which is an ordered set of tuples. The tuples correspond to the array of fields that are present in the values section of an index. By default this will just be a one-tuple containing a reference to a document in the collection selected by the index. Range operates on a set reference and knows nothing about the terms used to the select the returned set ref. So how do we compose the query?
Starting from first principles. Lets imagine we just had this stuff in memory. If we had a set of (attribute, scores) ordered by attribute, score then taking only those where attribute == $attribute would get us close, and then filtering by score > $score would get us what we wanted. This corresponds exactly to a range query over scores with attributes as terms, assuming we modeled the attribute value pairs as documents. We can also embed pointers back to the location so we can retrieve that as well in the same query. Enough chatter, lets do it:
First stop: our collections.
jnr> CreateCollection({name: "place_attribute"})
{
ref: Collection("place_attribute"),
ts: 1588528443250000,
history_days: 30,
name: 'place_attribute'
}
jnr> CreateCollection({name: "place"})
{
ref: Collection("place"),
ts: 1588528453350000,
history_days: 30,
name: 'place'
}
Next up some data. We'll chose a couple of places and give them some attributes.
jnr> Create(Collection("place"), {data: {"name": "mullion"}})
jnr> Create(Collection("place"), {data: {"name": "church cove"}})
jnr> Create(Collection("place_attribute"), {data: {"attribute": "swimming", "score": 3, "place": Ref(Collection("place"), 264525084639625739)}})
jnr> Create(Collection("place_attribute"), {data: {"attribute": "hiking", "score": 1, "place": Ref(Collection("place"), 264525084639625739)}})
jnr> Create(Collection("place_attribute"), {data: {"attribute": "hiking", "score": 7, "place": Ref(Collection("place"), 264525091487875586)}})
Now for the more interesting part. The index.
jnr> CreateIndex({name: "attr_score", source: Collection("place_attribute"), terms:[{"field":["data", "attribute"]}], values:[{"field": ["data", "score"]}, {"field": ["data", "place"]}]})
{
ref: Index("attr_score"),
ts: 1588529816460000,
active: true,
serialized: true,
name: 'attr_score',
source: Collection("place_attribute"),
terms: [ { field: [ 'data', 'attribute' ] } ],
values: [ { field: [ 'data', 'score' ] }, { field: [ 'data', 'place' ] } ],
partitions: 1
}
Ok. A simple query. Who has Hiking?
jnr> Paginate(Match(Index("attr_score"), "hiking"))
{
data: [
[ 1, Ref(Collection("place"), "264525084639625730") ],
[ 7, Ref(Collection("place"), "264525091487875600") ]
]
}
Without too much imagination one could sneak a Get call into that to pull the place out.
What about only hiking with a score over 5? We have an ordered set of tuples, so just supplying the first component (the score) is enough to get us what we want.
jnr> Paginate(Range(Match(Index("attr_score"), "hiking"), [5], null))
{ data: [ [ 7, Ref(Collection("place"), "264525091487875600") ] ] }
What about a compound condition? Hiking under 5 and swimming (any score). This is where things take a bit of a turn. We want to model conjunction, which in fauna means intersecting sets. The problem we have is that up until now we have been using an index that returns the score as well as the place ref. For intersection to work we need just the refs. Time for a sleight of hand:
jnr> Get(Index("doc_by_doc"))
{
ref: Index("doc_by_doc"),
ts: 1588530936380000,
active: true,
serialized: true,
name: 'doc_by_doc',
source: Collection("place"),
terms: [ { field: [ 'ref' ] } ],
partitions: 1
}
What's the point of such an index you ask? Well we can use it to drop any data we like from any index and be left with just the refs via join. This gives us the place refs with a hiking score less than 5 (the empty array sorts before anything, so works as a placeholder for a lower bound).
jnr> Paginate(Join(Range(Match(Index("attr_score"), "hiking"), [], [5]), Lambda(["s", "p"], Match(Index("doc_by_doc"), Var("p")))))
{ data: [ Ref(Collection("place"), "264525084639625739") ] }
So finally the piece de resistance: all places with swimming and (hiking < 5):
jnr> Let({
... hiking: Join(Range(Match(Index("attr_score"), "hiking"), [], [5]), Lambda(["s", "p"], Match(Index("doc_by_doc"), Var("p")))),
... swimming: Join(Match(Index("attr_score"), "swimming"), Lambda(["s", "p"], Match(Index("doc_by_doc"), Var("p"))))
... },
... Map(Paginate(Intersection(Var("hiking"), Var("swimming"))), Lambda("ref", Get(Var("ref"))))
... )
{
data: [
{
ref: Ref(Collection("place"), "264525084639625739"),
ts: 1588529629270000,
data: { name: 'mullion' }
}
]
}
Tada. This could be neatened up a lot with a couple of udfs, exercise left to the reader. Conditions involving or can be managed with union in much the same way.
Easy way to query with the multiple conditions I think with the query it with documents differences, In my solutions it is like:
const response = await client.query(
q.Let(
{
activeUsers: q.Difference(
q.Match(q.Index("allUsers")),
q.Match(q.Index("usersByStatus"), "ARCHIVE")
),
paginatedDocuments: q.Map(
q.Paginate(q.Var("activeUsers"), {
size,
before: reqBefore,
after: reqAfter
}),
q.Lambda("x", q.Get(q.Var("x")))
),
total: q.Count(q.Var("activeUsers"))
},
{
documents: q.Var("paginatedDocuments"),
total: q.Var("total")
}
)
);
const {
documents: {
data: dbData = [],
before: dbBefore = [],
after: dbAfter = []
} = {},
total = 0
} = response || {};
const respBefore = dbBefore[0]?.value?.id || null;
const respAfter = dbAfter[0]?.value?.id || null;
const data = await dbData.map((userData) => {
const {
ref: { id = null } = {},
data: { firstName = "", lastName = "" }
} = userData;
return {
id,
firstName,
lastName
};
});
So in the query builder you can filter each nested document in variable in Let section by the index that you want.
Here is the another variant of filtering, in SQL looks like:
SELECT * FROM clients WHERE salary > 2000 AND age > 30;
For fauna query:
const response = await client.query(
q.Let(
{
allClients: q.Match(q.Index("allClients")),
filteredClients: q.Filter(
q.Var("allClients"),
q.Lambda(
"client",
q.And(
q.GT(q.Select(["data", "salary"], q.Get(q.Var("client"))), 2000),
q.GT(q.Select(["data", "age"], q.Get(q.Var("client"))), 30)
)
)
),
paginatedDocuments: q.Map(
q.Paginate(q.Var("filteredClients")),
q.Lambda("x", q.Get(q.Var("x")))
),
total: q.Count(q.Var("filteredClients"))
},
{
documents: q.Var("paginatedDocuments"),
total: q.Var("total")
}
)
);
This is some kind of filtering in javascript where the condition if returns true so it will be in the result of the response. Example:
const filteredClients = allClients.filter((client) => {
const { salary, age } = client;
return ( salary > 2000 ) && (age > 30)
})

knex insert multiple rows

I have a problem inserting many rows into postgres db with knex.
I have dynamic number of rows needed to be inserted. The result i expect is:
insert row four times (four is for an example. I dont know exact number of inserts as it comes dynamically from frontend):
field_id will be diffrent in every row: (1,2,3,4) - i have array of these ID's
id_of_product will be always the same
value will be always diffrent: (req.body[id] that comes from Frontend) - ID in brackets is same value as the field_id from an
array
How i can achieve that? I tried looping it with forEach, but it's async operation so i can't use .then() as it will be called four times
Here's what i tried. i dont know how to set field_id and req.body to take it dynamically.
fields = [1,2,3,4]
Expected result:
knex creates 4 inserts as follows:
field_id: 1,
product_id: some static id
value: frontValue[1]
ETC
knex('metadata').insert(
[{ field_id: fields,
product_id: product_id,
value: req.body[fields]
}]
)
If I understand correctly you want to insert 4 records to your metadata table:
{ field_id: 1, product_id: X, value: req.body[1] },
{ field_id: 2, product_id: X, value: req.body[2] },
{ field_id: 3, product_id: X, value: req.body[3] },
{ field_id: 4, product_id: X, value: req.body[4] }
To insert multiple records in the same statement they each need to be separate elements in the array that you supply to Knex (check out the insert docs for additional examples):
const product_id = X;
const fieldsToInsert = fields.map(field =>
({ field_id: field, product_id, value: req.body[field] }));
return knex('metadata').insert(fieldsToInsert)
.then(() => { /* handle success */ })
.catch(() => { /* handle failure */});

Ruby on Rails: ActiveRecord-like queries on non-persisted objects?

In my project, a large number of POROs are composed from various data sources such as external APIs. The objects looks like:
{id: 1, name: 'Peter', age: 8}, {id: 2, name: 'Jack', age: 4}, {id: 3, name: 'Tom', age: 12}
I would like to have an ActiveRecord-like interface to query these objects. Such as Person.where(name: 'Jack') and Person.where("age > ?", 5)
My attempt looks like this:
class Query
def initialize(objs)
#objs = objs
end
def where(name: nil, age: nil)
result = #objs
result = result.select{|x| x.name == name} if name
result = result.select{|x| x.age == age} if age
result
end
end
It works, but I don't think it is a nice solution:
What if there are 20 attributes? The where method can become very long and error-prone.
What about other useful ActiveRecord query? e.g. find, find_by, pluck, order by and many others. Even if I can implement them all, how do I "chain" multiple queries?
Efficiency: How to optimize the queries like the sql query planner?
Most importantly, how do I implement Person.where("age > ?", 5) and other flexible queries?
Am I missing anything? I feel like I am re-inventing the wheel.
I've checked ActiveModel but unfortunately it doesn't have a query system.
Are there any gems out there that can help?
You would probably do well to use an object mapper, for example one from https://www.ruby-toolbox.com/categories/orm. An example implementation is shown at http://rom-rb.org/learn/repositories/reading-simple-objects/, but that is probably overkill for what you're doing.
Hashie has support for methods like deep_find for single objects and deep_locate for collections of objects. deep_locate may work for what you're doing, but keep in mind that a Hashie object will take up more memory than a standard hash.
Example code for deep_locate:
books = [
{
title: "Ruby for beginners",
pages: 120
},
{
title: "CSS for intermediates",
pages: 80
},
{
title: "Collection of ruby books",
books: [
{
title: "Ruby for the rest of us",
pages: 576
}
]
}
]
books.extend(Hashie::Extensions::DeepLocate)
# for ruby 1.9 leave *no* space between the lambda rocket and the braces
# http://ruby-journal.com/becareful-with-space-in-lambda-hash-rocket-syntax-between-ruby-1-dot-9-and-2-dot-0/
books.deep_locate -> (key, value, object) { key == :title && value.include?("Ruby") }
# => [{:title=>"Ruby for beginners", :pages=>120}, {:title=>"Ruby for the rest of us", :pages=>576}]
books.deep_locate -> (key, value, object) { key == :pages && value <= 120 }
# => [{:title=>"Ruby for beginners", :pages=>120}, {:title=>"CSS for intermediates", :pages=>80}]

set two different memory stores for one dojo widget (dijit/form/FilteringSelect) at the same time

I have two different JSON structures. One represent the individual users of the system and other represents groups made of these users. So, I created two memory stores with these (each has different idProperty - userId and groupId, respectively).
I have a filteringSelect dropdown and my requirement is to add both of these as the data store of the list, so that either a valid user or a valid group could be selected from the dropdown.
Two possible ways I could think of doing this :
1) by creating one common memory store of two JSONs - but idProperty is different so not sure how this is possible
2) by adding both the memory stores to the widget but again different idProperty so not sure.
I am very new to using Dojo so any help would be really appreaciated. Thanks in advance!
I think that, if you use a store to represent something (model data), it should be formed so that it can be used properly within a widget.
So in your case I would add both of them to a single store. If they have a different ID (for example when it's a result of a back-end service), then you could map both types of models into a single object structure. For example:
var groups = [{
groupId: 1,
groupName: "Group 1",
users: 10
}, {
groupId: 2,
groupName : "Group 2",
users: 13
}, {
groupId: 3,
groupName : "Group 3",
users: 2
}];
var users = [{
userId: 1,
firstName: "John",
lastName: "Doe"
}, {
userId: 2,
firstName: "Jane",
lastName: "Doe"
}, {
userId: 3,
firstName: "John",
lastName: "Smith"
}];
require(["dojo/store/Memory", "dijit/form/FilteringSelect", "dojo/_base/array", "dojo/domReady!"], function(Memory, FilteringSelect, array) {
var filterData = array.map(groups, function(group) {
return {
id: "GROUP" + group.groupId,
groupId: group.groupId,
name: group.groupName,
type: "group"
};
});
Array.prototype.push.apply(filterData, array.map(users, function(user) {
return {
id: "USER" + user.userId,
userId: user.userId,
name: user.firstName + " " + user.lastName,
type: "user"
};
}));
});
In this example, we have two arrays groups and users, and to merge them I used the map() function of dojo/_base/array and then I concatenated both results.
They still contain their original ID and a type, so you will still be able to reference the original object.
From my previous experiences, I learned that your model data should not represent pure business data, but data that is easily used in the view/user interface.
By giving both arrays a similar object structure, you can easily use them in a dijit/form/FilteringSelect, which you can see here: http://jsfiddle.net/ut5hjbyb/