Database systems utilize query planners to optimize data retrieval, primarily through two methods: Rule-Based Optimizers (RBO) and Cost-Based Optimizers (CBO).
Rule-Based Optimizer (RBO): This method employs predefined rules to select execution plans, resulting in stable but simplistic query plans. It often struggle with complex queries involving multiple joins but with a document model, the join ordering is solved upfront.
Cost-Based Optimizer (CBO): CBO analyzes data distribution statistics to evaluate potential plans and choose the most cost-effective option. Its reliance on possibly outdated statistics can lead to suboptimal decisions, so gathering statistics is crucial. Planning complex queries can take time, so it either relies on a shared plan cache or switches back to simple genetic algorithms when there are many joins.
MongoDB utilizes a document model that minimizes joins, focusing primarily on selecting the appropriate index. It defers execution decisions until runtime instead of relying on RBO or CBO to pick one. Through a shared plan cache and multi-planner mechanism, MongoDB dynamically evaluates and adjusts query plans for optimal execution.
Let's explain with a simple example and use the most challenging situation for a query planner: column skew, where a field has some unique values and a few popular ones. A business case I encountered was at a coffee capsule vendor. Online customers use their customer ID and order some capsules every three months on average. Shops have a special customer ID and record thousands of orders every day. For a query per customer ID and some other criteria, the index to use must be different, but the application obeys the 'parse one execute many' best practice, and the first who runs determines the execution plan for the others. Tom Kyte told the story of the database being slow when it rains (because the first user to parse the statement depended on a user coming by bike or car).
I'll build a simple example, a collection of ten million documents with two fields: a and b:
a is very selective for a few documents (with value less than 50) but the millions of remaining documents all have the same value of 50. b is uniform, with values from 1 to 10, and good selectivity: one value returns ten documents.Here here how I generated this with a loop on i, a is generated with Math.min(i,50) and b is generated with i%1e6:
// Drop the collection if it already exists
db.franck.drop();
// Insert documents with different data distributions
const bulk = db.franck.initializeUnorderedBulkOp();
const num=1e7;
for (let i = 0; i < num; i++) {
bulk.insert({ a: Math.min(i,50), b: i%1e6 });
}
const r = bulk.execute();
console.log(`Bulk Operation Summary: Inserted: ${r.insertedCount}, Matched: ${r.matchedCount}, Modified: ${r.modifiedCount}, Deleted: ${r.deletedCount}, Upserted: ${r.upsertedCount}`);
This inserted ten million documents:
test> console.log(`Bulk Operation Summary: Inserted: ${r.insertedCount}, Matched: ${r.matchedCount}, Modified: ${r.modifiedCount}, Deleted: ${r.deletedCount}, Upserted: ${r.upsertedCount}`);
Bulk Operation Summary: Inserted: 10000000, Matched: 0, Modified: 0, Deleted: 0, Upserted: 0
As the goal is to show two possible execution plans, I create two indexes, one on each field:
test> db.franck.createIndex({ a: 1 });
a_1
test> db.franck.createIndex({ b: 1 });
b_1
test> // "b" has a good selectivity
test> db.franck.countDocuments({ b: 42 });
10
test> // "a" has a better selectivity when a<50
test> db.franck.countDocuments({ a: 42 });
1
test> // "a" has a very bad selectivity when a=50 (popular value)
test> db.franck.countDocuments({ a: 50 });
9999950
My query will have a predicate on each column. I'll test { a: 42, b: 42 } which returns one document, and { a: 50, b: 42 } which returns ten documents.
I'll look at the statistics executions with profiling and at the query plan cache, so I reset them in my lab:
db.franck.getPlanCache().clear();
db.franck.getPlanCache().list();
db.setProfilingLevel(0);
db.system.profile.drop();
I set profiling, and I run a first execution that returns one document:
test> db.setProfilingLevel(2 );
{ was: 0, slowms: 0, sampleRate: 1, ok: 1 }
test> db.franck.find({ a: 42, b: 42 });
[ { _id: ObjectId('67d34e6128ca7c6f95a00acb'), a: 42, b: 42 } ]
test> db.setProfilingLevel(0);
{ was: 2, slowms: 0, sampleRate: 1, ok: 1 }
The initial execution of the MongoDB query planner generated all possible plans stored in the cache: one plan executes an IXSCAN on index a, another performs an IXSCAN on index b, and a third combines both indexes with an AND_SORTED operation:
test> db.franck.getPlanCache().list();
[
{
version: '1',
queryHash: '20F294D4',
planCacheKey: '2AAF6E88',
isActive: false,
works: Long('2'),
timeOfCreation: ISODate('2025-03-13T21:43:31.189Z'),
createdFromQuery: { query: { a: 42, b: 42 }, sort: {}, projection: {} },
cachedPlan: {
stage: 'FETCH',
filter: { b: { '$eq': 42 } },
inputStage: {
stage: 'IXSCAN',
keyPattern: { a: 1 },
indexName: 'a_1',
isMultiKey: false,
multiKeyPaths: { a: [] },
isUnique: false,
isSparse: false,
isPartial: false,
indexVersion: 2,
direction: 'forward',
indexBounds: { a: [ '[42, 42]' ] }
}
},
creationExecStats: [
{
nReturned: 1,
executionTimeMillisEstimate: 0,
totalKeysExamined: 1,
totalDocsExamined: 1,
executionStages: {
stage: 'FETCH',
filter: { b: { '$eq': 42 } },
nReturned: 1,
executionTimeMillisEstimate: 0,
works: 2,
advanced: 1,
needTime: 0,
needYield: 0,
saveState: 0,
restoreState: 0,
isEOF: 1,
docsExamined: 1,
alreadyHasObj: 0,
inputStage: {
stage: 'IXSCAN',
nReturned: 1,
executionTimeMillisEstimate: 0,
works: 2,
advanced: 1,
needTime: 0,
needYield: 0,
saveState: 0,
restoreState: 0,
isEOF: 1,
keyPattern: { a: 1 },
indexName: 'a_1',
isMultiKey: false,
multiKeyPaths: { a: [] },
isUnique: false,
isSparse: false,
isPartial: false,
indexVersion: 2,
direction: 'forward',
indexBounds: { a: [Array] },
keysExamined: 1,
seeks: 1,
dupsTested: 0,
dupsDropped: 0
}
}
},
{
nReturned: 1,
executionTimeMillisEstimate: 0,
totalKeysExamined: 2,
totalDocsExamined: 2,
executionStages: {
stage: 'FETCH',
filter: { a: { '$eq': 42 } },
nReturned: 1,
executionTimeMillisEstimate: 0,
works: 2,
advanced: 1,
needTime: 1,
needYield: 0,
saveState: 0,
restoreState: 0,
isEOF: 0,
docsExamined: 2,
alreadyHasObj: 0,
inputStage: {
stage: 'IXSCAN',
nReturned: 2,
executionTimeMillisEstimate: 0,
works: 2,
advanced: 2,
needTime: 0,
needYield: 0,
saveState: 0,
restoreState: 0,
isEOF: 0,
keyPattern: { b: 1 },
indexName: 'b_1',
isMultiKey: false,
multiKeyPaths: { b: [] },
isUnique: false,
isSparse: false,
isPartial: false,
indexVersion: 2,
direction: 'forward',
indexBounds: { b: [Array] },
keysExamined: 2,
seeks: 1,
dupsTested: 0,
dupsDropped: 0
}
}
},
{
nReturned: 1,
executionTimeMillisEstimate: 0,
totalKeysExamined: 2,
totalDocsExamined: 1,
executionStages: {
stage: 'FETCH',
filter: { '$and': [ [Object], [Object] ] },
nReturned: 1,
executionTimeMillisEstimate: 0,
works: 2,
advanced: 1,
needTime: 1,
needYield: 0,
saveState: 0,
restoreState: 0,
isEOF: 0,
docsExamined: 1,
alreadyHasObj: 0,
inputStage: {
stage: 'AND_SORTED',
nReturned: 1,
executionTimeMillisEstimate: 0,
works: 2,
advanced: 1,
needTime: 1,
needYield: 0,
saveState: 0,
restoreState: 0,
isEOF: 0,
failedAnd_0: 0,
failedAnd_1: 0,
inputStages: [ [Object], [Object] ]
}
}
}
],
candidatePlanScores: [ 2.5002, 1.5002, 1.5001 ],
indexFilterSet: false,
estimatedSizeBytes: Long('4693'),
host: '4b49f6ca6400:27017'
}
]
Those plans were evaluated (creationExecStats) with { a: { '$eq': 42 } and { b: { '$eq': 42 } and scored. The best score goes to the most selective one, the index on a, which examines one key and fetches one document.
I run the same nine more times:
db.setProfilingLevel(2 );
db.franck.find({ a: 42, b: 42 });
db.franck.find({ a: 42, b: 42 });
db.franck.find({ a: 42, b: 42 });
db.franck.find({ a: 42, b: 42 });
db.franck.find({ a: 42, b: 42 });
db.franck.find({ a: 42, b: 42 });
db.franck.find({ a: 42, b: 42 });
db.franck.find({ a: 42, b: 42 });
db.franck.find({ a: 42, b: 42 });
db.setProfilingLevel(0);
I extract some interesting information from the profiling of those ten executions:
test> db.system.profile.find({ ns: "test.franck" }).sort({ ts: 1 }).limit(100).forEach((doc) => { if (doc.execStats) console.log(`${doc.ts.toISOString().slice(11, 23)} works: ${doc.execStats.works.toString().padStart(5)} keys: ${doc.keysExamined.toString().padStart(5)} docs: ${doc.docsExamined.toString().padStart(5)} ret: ${doc.nreturned.toString().padStart(5)} ${doc.execStats.stage.padStart(12)} ${doc.planSummary.padStart(12)} exec(plan): ${doc.millis.toString().padStart(5)}ms (${doc.planningTimeMicros.toString().padStart(8)}us) query/plan ${doc.queryHash}/${doc.planCacheKey} ${doc.queryFramework} ${doc.fromPlanCache ? 'fromPlanCache ' : ''}${doc.fromMultiPlanner ? 'fromMultiPlanner ' : ''}${doc.replanned ? doc.replanReason : ''}`); });
21:43:31.191 works: 3 keys: 1 docs: 1 ret: 1 FETCH IXSCAN { a: 1 } exec(plan): 7ms ( 7063us) query/plan 20F294D4/2AAF6E88 classic fromMultiPlanner
21:56:49.938 works: 3 keys: 1 docs: 1 ret: 1 FETCH IXSCAN { a: 1 } exec(plan): 9ms ( 8899us) query/plan 20F294D4/2AAF6E88 classic fromMultiPlanner
21:56:49.982 works: 2 keys: 1 docs: 1 ret: 1 CACHED_PLAN IXSCAN { a: 1 } exec(plan): 1ms ( 1264us) query/plan 20F294D4/2AAF6E88 classic fromPlanCache
21:56:50.014 works: 2 keys: 1 docs: 1 ret: 1 CACHED_PLAN IXSCAN { a: 1 } exec(plan): 0ms ( 233us) query/plan 20F294D4/2AAF6E88 classic fromPlanCache
21:56:50.053 works: 2 keys: 1 docs: 1 ret: 1 CACHED_PLAN IXSCAN { a: 1 } exec(plan): 0ms ( 240us) query/plan 20F294D4/2AAF6E88 classic fromPlanCache
21:56:50.085 works: 2 keys: 1 docs: 1 ret: 1 CACHED_PLAN IXSCAN { a: 1 } exec(plan): 0ms ( 235us) query/plan 20F294D4/2AAF6E88 classic fromPlanCache
21:56:50.108 works: 2 keys: 1 docs: 1 ret: 1 CACHED_PLAN IXSCAN { a: 1 } exec(plan): 0ms ( 254us) query/plan 20F294D4/2AAF6E88 classic fromPlanCache
21:56:50.133 works: 2 keys: 1 docs: 1 ret: 1 CACHED_PLAN IXSCAN { a: 1 } exec(plan): 0ms ( 230us) query/plan 20F294D4/2AAF6E88 classic fromPlanCache
21:56:50.157 works: 2 keys: 1 docs: 1 ret: 1 CACHED_PLAN IXSCAN { a: 1 } exec(plan): 0ms ( 246us) query/plan 20F294D4/2AAF6E88 classic fromPlanCache
21:56:50.188 works: 2 keys: 1 docs: 1 ret: 1 CACHED_PLAN IXSCAN { a: 1 } exec(plan): 0ms ( 246us) query/plan 20F294D4/2AAF6E88 classic fromPlanCache
In the first two executions, all plans were evaluated using the Multi-Planner. From the third execution onward, only the winning plan from the Plan Cache was executed, resulting in decreased execution time, including planning time. The best index, which was fully executed, is the one on a.
I execute the same query shape but with a different value, for wich I know that the index on a is not good:
db.setProfilingLevel(2);
db.franck.find({ a: 50, b<... (truncated)
(With apologies to Terry Pratchett)
Ponder Stibbons sat in the shadowy recesses of the Uncommon Room, clutching a lukewarm cup of tea and the last vestiges of his patience. Across from him, the Dean, wrapped in his usual self-satisfaction, puffed his pipe and surveyed the room as if it were all a great and glorious joke that he alone understood.
"Leaving?" the Dean spluttered, when Ponder finally managed to slide the conversation in that direction. "What do you mean, leaving? Where would you even go?"
"Industry," said Ponder, trying not to make it sound like a curse. "Databases. Big ones."
The Dean blinked. "But we have databases here. The Archchancellor’s hat alone contains centuries of magical indexing..."
"Yes, but in the real world, we use them to actually store and retrieve information, not just argue about what information is worth storing in the first place," Ponder snapped. "And I’ll be paid properly."
"Pah," scoffed the Dean. "The true academic mind isn’t in it for the money."
"Yes, I noticed that," Ponder said. "But, funnily enough, the people running the place seem to be. We have more suits than I can count, and none of them seem to know how to count. We used to do research, but now we do ‘strategic impact planning’ and ‘value-oriented magical development initiatives’."
The Dean made a valiant effort at looking wise. "Well, you have to admit, Stibbons, there’s no point in just doing magic for magic’s sake."
"Then what’s the point of this place?" Ponder snapped. "If we’re not here to push the boundaries of knowledge, then we’re just a very exclusive, very inefficient vocational school for people too dim-witted to teach themselves. The students don’t want to learn magic, they want to finish a course of study in three semesters so they can get a cushy post enchanting chairs for the Patrician’s office."
The Dean waved a hand vaguely. "That’s always been the case."
"It wasn’t always quite this blatant," Ponder retorted. "Back in the day, we had time to actually think about things, research things, discuss things. Now it’s all quotas, reviews, assessments! And if the students don’t like you, they file complaints! Whining course reviews! As if the study of magic were meant to be… comfortable! We used to throw fireballs at people! Now we have to ‘create a nurturing environment for knowledge acquisition’."
"Ah," said the Dean, puffing his pipe. "Well, times change."
"Not here, they don’t," said Ponder bitterly. "That’s the whole problem. The world outside moves forward while we shuffle our papers and complain that we don’t have enough funding to investigate basic transmutation spells."
The Dean chuckled. "You always were an idealist, Stibbons. Research takes time. Why, I myself have been preparing to write a paper on the comparative metaphysical mass of a thaum for—"
"Twenty years!" snapped Ponder. "And you’ve produced nothing!"
"Ah, but when I do…" The Dean waggled his fingers mysteriously.
"And even if you did, it wouldn’t get published," Ponder continued. "Do you know what happens to papers these days? You send them off, wait a year, and then get them back covered in cryptic, punishing comments from anonymous reviewers who seem to hate the very idea of scholarship."
"Ah yes, peer review!" said the Dean enthusiastically. "Ensuring the highest quality!"
"Ensuring nobody gets anything done!" Ponder snapped. "It’s not review, it’s ritualized academic hazing. Half the time the reviewers are just competitors trying to torpedo your work so their own gets published first. It’s like trying to hold a debate where the other side gets to set your chair on fire before you start speaking."
"Ah, well," the Dean said philosophically. "At least we all suffer equally."
"No, we don’t!" Ponder threw up his hands. "It’s a zero-sum game! Everyone hoards their ideas because collaboration just means giving someone else ammunition to shoot down your next grant proposal! We’re supposed to be discovering new knowledge, and instead we spend all our time writing meticulously worded rebuttals to complaints about our font choice."
"Well, I suppose that’s just how academia works," the Dean said, smiling in what he clearly thought was a reassuring way.
Ponder sighed. "You know what’s coming, don’t you? The golems are already doing spellwork. Automated spell matrices. Soon, students won’t even need to be here. They’ll just buy the knowledge in convenient pre-packaged modules."
"Nonsense," the Dean huffed. "You can’t replace a wizard with a machine."
"That’s exactly what I thought," said Ponder. "Until I have seen them in the wild. It turned out you very well can."
The Dean froze. "What?"
"Oh yes. A spell-engine that automates theorem derivation and spell stabilization. Does in minutes what takes us years. Accurate, tireless, and best of all, doesn’t insist on being called ‘Professor’."
The Dean was pale. "But… but the prestige, Stibbons! The robes! The titles! The long lunches!"
"Industry has long lunches too," said Ponder. "And they reimburse you in two days instead of two months."
The Dean looked positively ill. "And you’re going to… what? Spend your days solving real problems? Making a tangible difference?"
"Yes."
"But… how will you cope?" The Dean’s voice was faint. "Without the endless meetings? The unread grant proposals? The departmental infighting over whose name goes first on a paper no one will read?"
Ponder stood, dusted off his robes, and picked up his satchel. "I think I’ll manage."
MongoDB is the standard API for document databases, and some cloud providers have created services with a similar API. AWS and Azure call theirs 'DocumentDB', and Oracle provides the MongoDB API as a proxy on top of its SQL database. These databases offer a subset of features from past versions of MongoDB, but user experience and performance are also crucial.
Oracle claims better performance, but their tests lack real-world queries. I will utilize their "autonomous" managed service to compare execution plans and identify which minimizes unnecessary reads in a common OLTP use case - where clause and pagination.
TL;DR: MongoDB has better performance, and more indexing possibilities.
I used a simple schema of orders and order lines, ideal for a document model. I illustrated it with UML notation to distinguish strong and weak entities, representing the association as a composition (⬧-).
In a SQL database, a one-to-many relationship between orders and line items requires two tables because the the first normal form. In MongoDB, a composition relationship allows the weak entity (Order Detail) to be embedded within the strong entity (Order) as an array, simplifying data management and enhancing performance, as we will see when indexing it.
I will insert orders with few attributes. The country and creation date are fields in Order. The line number, product, and quantity are fields of Detail, which is an embedded array in Order:
+--------------------------+
| Order |
+--------------------------+
| country_id: Number |
| created_at: Date |
| details: Array |
| +----------------------+ |
| | Detail | |
| +----------------------+ |
| | line: Number | |
| | product_id: Number | |
| | quantity: Number | |
| +----------------------+ |
+--------------------------+
I generated one million documents for my example. I'll focus on predictable metrics like the number of documents examined rather than execution time, so that it can be easily reproduced with a small dataset. To simulate products with fluctuating popularity, I use a randomized logarithmic value to create product IDs:
const bulkOps = [];
for (let i = 0; i < 1000000; i++) {
const orderDetails = [];
for (let line = 1; line <= 10; line++) {
orderDetails.push({
line: line,
product_id: Math.floor(Math.log2(1 + i * Math.random())),
quantity: Math.floor(100 * Math.random()),
});
}
bulkOps.push({
insertOne: {
document: {
country_id: Math.floor(10 * Math.random()),
created_at: new Date(),
order_details: orderDetails
}
}
});
}
db.orders.bulkWrite(bulkOps).insertedCount;
Users seek insights into product usage through a query for the most recent orders that include a specific product, in a specific country. Following the ESR rule, I created an index with equality fields in front of the key, followed by the fields for ordering results.
db.orders.createIndex( {
"country_id": 1,
"order_details.product_id": 1,
"created_at": -1
});
I queried the ten last orders in country 1 including product 5:
print(
db.orders.find({
country_id: 1,
order_details: { $elemMatch: { product_id: 5 } }
}).sort({ created_at: -1 }).limit(10)
);
The user can analyze this data to understand the last orders for this product.
I query the execution plan for this query:
print(
db.orders.find( {
country_id: 1,
order_details: { $elemMatch: { product_id: 5 } }
}).sort({ created_at: -1 }).limit(10)
.explain("executionStats")
);
When using the "MongoDB API for Oracle Database," the query is re-written to SQL since the collection resides in SQL tables with OSON data type, employing internal functions to simulate MongoDB BSON document. The explain() method reveals the executed queries:
This is interresting to understand how storing JSON in SQL databases is different from using MongoDB and requires an emulation layer that generates complex non-standard SQL. Unfortunately, this does not show execution statistics.
To gain more insights, I gathered the SQL statement from V$SQL and ran it with the MONITOR hint to generate a SQL Monitor report:
select /*+ FIRST_ROWS(10) MONITOR */ "DATA",rawtohex("RESID"),"ETAG"
from "ORA"."orders"
where JSON_EXISTS("DATA"
,'$?( (@.country_id.numberOnly() == $B0) &&
( exists(@.order_details[*]?( (@.product_id.numberOnly() == $B1) )) ) )' passing 1 as "B0", 5 as "B1" type(strict))
order by JSON_QUERY("DATA", '$.created_at[*].max()') desc nulls last
fetch next 10 rows only
;
Here is the SQL Monitor report:
"orders"."SYS_NC00005$" = SYS_CONS_ANY_SCALAR(1, 3) AND "orders"."SYS_NC00006$" = SYS_CONS_ANY_SCALAR(5, 3).More operations occur to transform this result into MongoDB-compatible documents, but this happens on 10 documents as it occurs after the limit (COUNT STOPKEY). What is more problematic is what happens before, unnecessary work: read, hash, and sort the rows that do not participate to the result. It is 276 instead of 10 in this small example, but can be more in a larger database. The SORT ORDER BY is a blocking operation that must read all rows before being able to output one.
Oracle Database's index usage does not adhere to the MongoDB ESR (Equality, Sort, Range) rule. It only utilized index scans for the equality predicates, country_id and product_id, rendering the created_at field ineffective and failing to prevent a blocking sort operation. This occurs on 276 rows in this small example, but it can impacts more in a production database.
Since the index is only part of the filtering process, the execution plan may switch to another index. For example, an index starting with created_at could assist with sort().limit(), but may read too many countries and products.
The result from Oracle Database is compatible with MongoDB, but the performance and scalability is not.
Here is the execution plan on a real MongoDB database - I've run it on an Atlas free cluster:
db> print(
... db.orders.find( {
... country_id: 1,
... order_details: { $elemMatch: { product_id: 5 } }
... }).sort({ created_at: -1 }).limit(10)
... .explain("executionStats").executionStats
... );
{
executionSuccess: true,
nReturned: 10,
executionTimeMillis: 0,
totalKeysExamined: 10,
totalDocsExamined: 10,
executionStages: {
isCached: false,
stage: 'LIMIT',
nReturned: 10,
executionTimeMillisEstimate: 0,
works: 11,
advanced: 10,
needTime: 0,
needYield: 0,
saveState: 0,
restoreState: 0,
isEOF: 1,
limitAmount: 10,
inputStage: {
stage: 'FETCH',
filter: {
order_details: { '$elemMatch': { product_id: { '$eq': 5 } } }
},
nReturned: 10,
executionTimeMillisEstimate: 0,
works: 10,
advanced: 10,
needTime: 0,
needYield: 0,
saveState: 0,
restoreState: 0,
isEOF: 0,
docsExamined: 10,
alreadyHasObj: 0,
inputStage: {
stage: 'IXSCAN',
nReturned: 10,
executionTimeMillisEstimate: 0,
works: 10,
advanced: 10,
needTime: 0,
needYield: 0,
saveState: 0,
restoreState: 0,
isEOF: 0,
keyPattern: {
country_id: 1,
'order_details.product_id': 1,
created_at: -1
},
indexName: 'country_id_1_order_details.product_id_1_created_at_-1',
isMultiKey: true,
multiKeyPaths: {
country_id: [],
'order_details.product_id': [ 'order_details' ],
created_at: []
},
isUnique: false,
isSparse: false,
isPartial: false,
indexVersion: 2,
direction: 'forward',
indexBounds: {
country_id: [ '[1, 1]' ],
'order_details.product_id': [ '[5, 5]' ],
created_at: [ '[MaxKey, MinKey]' ]
},
keysExamined: 10,
seeks: 1,
dupsTested: 10,
dupsDropped: 0
}
}
}
}
Here MongoDB didn't read more rows than necessary:
stage: 'IXSCAN') with a single access (seeks: 1) to the values of the equality condition.keysExamined: 10) needed for the result.This is summarized by:
executionSuccess: true,
nReturned: 10,
totalKeysExamined: 10,
totalDocsExamined: 10,
When the number of keys examined matches the number of documents returned, it indicates optimal execution with no unnecessary operations.
This alignment ensures efficiency in processing, as all examined keys are relevant to the returned documents.
You can also look at the visual execution plan in MongoDB Compass:
Using document data modeling and MongoDB indexes allows you to access only the necessary data, ensuring that query costs are directly related to the results obtained.
In a SQL database, the Orders - Order Details example requires two tables and a join to filter results. The join itself may not be too expensive, but SQL databases lack multi-table indexes. They do unnecessary work reading and joining rows that will be discarded later.
The document model, with embedded entities, allows for comprehensive indexing, offering optimal access unlike normalized tables in relational databases. MongoDB shines with indexes that follow Equality, Sort, and Range, and they can cover documents and sub-documents, with multiple keys per document.
While some SQL databases have copied the MongoDB API to provide better developer experience to those who are not SQL experts, they do not gain the same benefits as MongoDB, provide fewer indexing possibilities, and incur additional operations when executing queries.
