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Design Ride Dispatch (Uber/Lyft) - SystemRound

Design Ride Dispatch (Uber/Lyft)

hardSystem design45 min5 stagesPro

Asked atUberLyftDoorDashGoogleGrabAmazonInstacart

Design the dispatch core of a ride-hailing service. Drivers stream GPS continuously; a rider requests a ride and the system finds nearby available drivers, matches one, and tracks the trip. The hard parts are the firehose of location updates (~1M+/sec) and the geospatial query — given a point, find the closest available drivers in milliseconds — at city scale, in dense areas, without ever handing the same driver to two riders.

Best after a few full reps. Expect follow-up questions, edge cases, and deeper trade-off discussion.

What this problem tests

Core EndpointsReal-time ChannelCorrectness & AuthCore ComponentsLocation Write PathMatch Read Path

Round shape

5 stages

Time budget

45 min

Feedback loop

Grade anytime

Guided practice·Primary loop

Guided practice

Workspace-first, hints visible, stage retry available. The cheap, repeatable loop — build the answer shape before you take it under pressure.

Stage-by-stage workspace instead of a blank page.
Grade one stage or the whole answer whenever you want.
Compare your reasoning against reference criteria and model answers.

Solve once, compare against the checklist, then come back to the weak stage instead of starting over.

Mock interview·Pressure test

Mock interview

Strict timer, hints hidden, debrief deferred to the end. Use this once you can already structure a clean answer and want to pressure-test pacing and pushback.

Best once the answer shape is already in your head.
Pressure-test pacing, pushback handling, and communication.
Use diagnosis after the interview for exact misses and next study steps.

Best after one structured rep · timed · focused on pacing and communication.

Requirements

This is the framing pass. A strong answer quickly defines what the system must do, what quality bar it has to hit, and the numbers that will justify the rest of the design.

First 5 min of the round

What must exist

Functional Requirements

6 items

1A rider requests a ride from a pickup location

2Match the rider to a nearby available driver

3Drivers stream GPS continuously; track their location

4Trip lifecycle: requested → matched → en route → in progress → completed

5Driver accept/decline of an offered trip

6Below the line: surge pricing, pooled rides, navigation/routing

What good looks like

Non-Functional Requirements

5 items

1Match p99 < ~2s; the nearby-driver geo query well under 200ms

2A driver must never be matched to two riders — the assignment is strongly consistent

3Very high write throughput for location updates

4Geographic skew — airports/downtowns are extremely dense; the rural tail is sparse

5High availability on the matching path

Numbers to anchor the design

Scale Estimation

4 items

15M drivers × a ping every 4s ≈ 1.25M location writes/sec → this firehose cannot hit a durable SQL DB

220M rides/day ÷ 86,400 ≈ 230/sec average, ~5K/sec at peak

3Live location: 5M drivers × ~100 bytes ≈ ~500 MB → fits in memory, ephemeral

4Each request → one nearby-driver query (plus retries on decline)

How the round unfolds

Each stage has a distinct job. Treat them like separate deliverables instead of one giant answer, and the round becomes much easier to navigate.

4 design stages · 40 pts after framing

🔌

Stage 2~5 min10 pts

API Design

Define the contract clearly: the endpoints, auth boundary, error semantics, and the one or two decisions that matter most.

What you should produce

Define the interface. What endpoints handle requesting a ride and the high-frequency driver location update? How do the apps get real-time updates?

Strong answers cover

Core EndpointsReal-time ChannelCorrectness & Auth

🏗️

Stage 3~10 min10 pts

High-Level Architecture

Lay out the main components and trace the write path, read path, and any async path cleanly.

What you should walk through

Walk me through the architecture.

Strong answers cover

Core ComponentsLocation Write PathMatch Read Path

💾

Stage 4~10 min10 pts

Data Model & Storage

Pick the store, show the schema or key model, and explain why that storage choice fits the access pattern.

What you should lock in

Get concrete about storage.

Strong answers cover

Geo Index StructureStores & EphemeralityPartitioning

📈

Stage 5~15 min10 pts

Scaling & Deep Dive

Name the first bottleneck, failure modes, and the trade-offs that keep the system fast and reliable under pressure.

What you should pressure-test

Now the deep dive. Two crux topics: hot cells (dense areas) and double-dispatch (two riders, one driver). Then cover the location write storm and f...

Strong answers cover

Hot CellsDouble-Dispatch ConsistencyWrite Storm & Reliability

What a strong first rep looks like

Scope clearly

Translate the prompt into concrete requirements, scale, and trade-offs before drawing architecture.

Stay stage-specific

Give APIs in the API stage, data models in the storage stage, and failure modes in scaling. Don't blur them together.

Iterate fast

Grade early, compare to the reference reasoning criteria, fix the biggest misses, and re-submit the weak stage instead of starting over.