地理位置查询

许多应用都有按实际地理位置编入索引的文档。例如,您的应用可能允许用户浏览他们当前所在位置附近的商店。

解决方案:Geohash

Geohash 是用于将 (latitude, longitude) 对编码为单个 Base32 字符串的体系。在 Geohash 体系中,世界被划分为一个矩形网格。Geohash 字符串的每个字符都指定了前缀哈希值 32 个细分中的其中一个。例如,Geohash abcd 是完全涵盖在更大的 Geohash abc 范围之内的 32 个四字符哈希值的其中之一。

两个哈希值之间的共同前缀越长,彼此就越近。例如,abcdefabcdegabcdff 更近。但是,反之却不成立!两个地理区域可能会非常近,却拥有截然不同的 Geohash:

间隔很远的 Geohash

我们可以使用 Geohash 按地理位置在 Cloud Firestore 中高效存储和查询文档,这只需要有一个编入索引的字段。

安装帮助程序库

创建和解析 Geohash 涉及一些复杂的数学概念,因此我们构建了帮助程序库,以抽象化 Android、Apple 和 Web 上最棘手的部分:

Web

// Install from NPM. If you prefer to use a static .js file visit
// https://github.com/firebase/geofire-js/releases and download
// geofire-common.min.js from the latest version
npm install --save geofire-common

Web

// Install from NPM. If you prefer to use a static .js file visit
// https://github.com/firebase/geofire-js/releases and download
// geofire-common.min.js from the latest version
npm install --save geofire-common

Swift

注意:此产品不适用于 watchOS 和 App Clip 目标。
// 将其添加到您的 Podfile pod“GeoFire/Utils”

Kotlin+KTX

// Add this to your app/build.gradle
implementation 'com.firebase:geofire-android-common:3.2.0'

Java

// Add this to your app/build.gradle
implementation 'com.firebase:geofire-android-common:3.1.0'

存储 Geohash

对于您要按地理位置编制索引的每个文档,您需要存储一个 Geohash 字段:

Web

import { doc, updateDoc } from 'firebase/firestore';

// Compute the GeoHash for a lat/lng point
const lat = 51.5074;
const lng = 0.1278;
const hash = geofire.geohashForLocation([lat, lng]);

// Add the hash and the lat/lng to the document. We will use the hash
// for queries and the lat/lng for distance comparisons.
const londonRef = doc(db, 'cities', 'LON');
await updateDoc(londonRef, {
  geohash: hash,
  lat: lat,
  lng: lng
});

Web

// Compute the GeoHash for a lat/lng point
const lat = 51.5074;
const lng = 0.1278;
const hash = geofire.geohashForLocation([lat, lng]);

// Add the hash and the lat/lng to the document. We will use the hash
// for queries and the lat/lng for distance comparisons.
const londonRef = db.collection('cities').doc('LON');
londonRef.update({
  geohash: hash,
  lat: lat,
  lng: lng
}).then(() => {
  // ...
});

Swift

注意:此产品不适用于 watchOS 和 App Clip 目标。
// Compute the GeoHash for a lat/lng point
let latitude = 51.5074
let longitude = 0.12780
let location = CLLocationCoordinate2D(latitude: latitude, longitude: longitude)

let hash = GFUtils.geoHash(forLocation: location)

// Add the hash and the lat/lng to the document. We will use the hash
// for queries and the lat/lng for distance comparisons.
let documentData: [String: Any] = [
  "geohash": hash,
  "lat": latitude,
  "lng": longitude
]

let londonRef = db.collection("cities").document("LON")
londonRef.updateData(documentData) { error in
  // ...
}

Kotlin+KTX

// Compute the GeoHash for a lat/lng point
val lat = 51.5074
val lng = 0.1278
val hash = GeoFireUtils.getGeoHashForLocation(GeoLocation(lat, lng))

// Add the hash and the lat/lng to the document. We will use the hash
// for queries and the lat/lng for distance comparisons.
val updates: MutableMap<String, Any> = mutableMapOf(
    "geohash" to hash,
    "lat" to lat,
    "lng" to lng,
)
val londonRef = db.collection("cities").document("LON")
londonRef.update(updates)
    .addOnCompleteListener {
        // ...
    }

Java

// Compute the GeoHash for a lat/lng point
double lat = 51.5074;
double lng = 0.1278;
String hash = GeoFireUtils.getGeoHashForLocation(new GeoLocation(lat, lng));

// Add the hash and the lat/lng to the document. We will use the hash
// for queries and the lat/lng for distance comparisons.
Map<String, Object> updates = new HashMap<>();
updates.put("geohash", hash);
updates.put("lat", lat);
updates.put("lng", lng);

DocumentReference londonRef = db.collection("cities").document("LON");
londonRef.update(updates)
        .addOnCompleteListener(new OnCompleteListener<Void>() {
            @Override
            public void onComplete(@NonNull Task<Void> task) {
                // ...
            }
        });

查询 Geohash

Geohash 可让我们针对 Geohash 字段加入一组查询来进行大致的区域查询,然后再过滤掉一些假正例:

Web

import { collection, query, orderBy, startAt, endAt, getDocs } from 'firebase/firestore';

// Find cities within 50km of London
const center = [51.5074, 0.1278];
const radiusInM = 50 * 1000;

// Each item in 'bounds' represents a startAt/endAt pair. We have to issue
// a separate query for each pair. There can be up to 9 pairs of bounds
// depending on overlap, but in most cases there are 4.
const bounds = geofire.geohashQueryBounds(center, radiusInM);
const promises = [];
for (const b of bounds) {
  const q = query(
    collection(db, 'cities'), 
    orderBy('geohash'), 
    startAt(b[0]), 
    endAt(b[1]));

  promises.push(getDocs(q));
}

// Collect all the query results together into a single list
const snapshots = await Promise.all(promises);

const matchingDocs = [];
for (const snap of snapshots) {
  for (const doc of snap.docs) {
    const lat = doc.get('lat');
    const lng = doc.get('lng');

    // We have to filter out a few false positives due to GeoHash
    // accuracy, but most will match
    const distanceInKm = geofire.distanceBetween([lat, lng], center);
    const distanceInM = distanceInKm * 1000;
    if (distanceInM <= radiusInM) {
      matchingDocs.push(doc);
    }
  }
}

Web

// Find cities within 50km of London
const center = [51.5074, 0.1278];
const radiusInM = 50 * 1000;

// Each item in 'bounds' represents a startAt/endAt pair. We have to issue
// a separate query for each pair. There can be up to 9 pairs of bounds
// depending on overlap, but in most cases there are 4.
const bounds = geofire.geohashQueryBounds(center, radiusInM);
const promises = [];
for (const b of bounds) {
  const q = db.collection('cities')
    .orderBy('geohash')
    .startAt(b[0])
    .endAt(b[1]);

  promises.push(q.get());
}

// Collect all the query results together into a single list
Promise.all(promises).then((snapshots) => {
  const matchingDocs = [];

  for (const snap of snapshots) {
    for (const doc of snap.docs) {
      const lat = doc.get('lat');
      const lng = doc.get('lng');

      // We have to filter out a few false positives due to GeoHash
      // accuracy, but most will match
      const distanceInKm = geofire.distanceBetween([lat, lng], center);
      const distanceInM = distanceInKm * 1000;
      if (distanceInM <= radiusInM) {
        matchingDocs.push(doc);
      }
    }
  }

  return matchingDocs;
}).then((matchingDocs) => {
  // Process the matching documents
  // ...
});

Swift

注意:此产品不适用于 watchOS 和 App Clip 目标。
// Find cities within 50km of London
let center = CLLocationCoordinate2D(latitude: 51.5074, longitude: 0.1278)
let radiusInM: Double = 50 * 1000

// Each item in 'bounds' represents a startAt/endAt pair. We have to issue
// a separate query for each pair. There can be up to 9 pairs of bounds
// depending on overlap, but in most cases there are 4.
let queryBounds = GFUtils.queryBounds(forLocation: center,
                                      withRadius: radiusInM)
let queries = queryBounds.map { bound -> Query in
  return db.collection("cities")
    .order(by: "geohash")
    .start(at: [bound.startValue])
    .end(at: [bound.endValue])
}

@Sendable func fetchMatchingDocs(from query: Query,
                       center: CLLocationCoordinate2D,
                       radiusInMeters: Double) async throws -> [QueryDocumentSnapshot] {
  let snapshot = try await query.getDocuments()
  // Collect all the query results together into a single list
  return snapshot.documents.filter { document in
    let lat = document.data()["lat"] as? Double ?? 0
    let lng = document.data()["lng"] as? Double ?? 0
    let coordinates = CLLocation(latitude: lat, longitude: lng)
    let centerPoint = CLLocation(latitude: center.latitude, longitude: center.longitude)

    // We have to filter out a few false positives due to GeoHash accuracy, but
    // most will match
    let distance = GFUtils.distance(from: centerPoint, to: coordinates)
    return distance <= radiusInM
  }
}

// After all callbacks have executed, matchingDocs contains the result. Note that this code
// executes all queries serially, which may not be optimal for performance.
do {
  let matchingDocs = try await withThrowingTaskGroup(of: [QueryDocumentSnapshot].self) { group -> [QueryDocumentSnapshot] in
    for query in queries {
      group.addTask {
        try await fetchMatchingDocs(from: query, center: center, radiusInMeters: radiusInM)
      }
    }
    var matchingDocs = [QueryDocumentSnapshot]()
    for try await documents in group {
      matchingDocs.append(contentsOf: documents)
    }
    return matchingDocs
  }

  print("Docs matching geoquery: \(matchingDocs)")
} catch {
  print("Unable to fetch snapshot data. \(error)")
}

Kotlin+KTX

// Find cities within 50km of London
val center = GeoLocation(51.5074, 0.1278)
val radiusInM = 50.0 * 1000.0

// Each item in 'bounds' represents a startAt/endAt pair. We have to issue
// a separate query for each pair. There can be up to 9 pairs of bounds
// depending on overlap, but in most cases there are 4.
val bounds = GeoFireUtils.getGeoHashQueryBounds(center, radiusInM)
val tasks: MutableList<Task<QuerySnapshot>> = ArrayList()
for (b in bounds) {
    val q = db.collection("cities")
        .orderBy("geohash")
        .startAt(b.startHash)
        .endAt(b.endHash)
    tasks.add(q.get())
}

// Collect all the query results together into a single list
Tasks.whenAllComplete(tasks)
    .addOnCompleteListener {
        val matchingDocs: MutableList<DocumentSnapshot> = ArrayList()
        for (task in tasks) {
            val snap = task.result
            for (doc in snap!!.documents) {
                val lat = doc.getDouble("lat")!!
                val lng = doc.getDouble("lng")!!

                // We have to filter out a few false positives due to GeoHash
                // accuracy, but most will match
                val docLocation = GeoLocation(lat, lng)
                val distanceInM = GeoFireUtils.getDistanceBetween(docLocation, center)
                if (distanceInM <= radiusInM) {
                    matchingDocs.add(doc)
                }
            }
        }

        // matchingDocs contains the results
        // ...
    }

Java

// Find cities within 50km of London
final GeoLocation center = new GeoLocation(51.5074, 0.1278);
final double radiusInM = 50 * 1000;

// Each item in 'bounds' represents a startAt/endAt pair. We have to issue
// a separate query for each pair. There can be up to 9 pairs of bounds
// depending on overlap, but in most cases there are 4.
List<GeoQueryBounds> bounds = GeoFireUtils.getGeoHashQueryBounds(center, radiusInM);
final List<Task<QuerySnapshot>> tasks = new ArrayList<>();
for (GeoQueryBounds b : bounds) {
    Query q = db.collection("cities")
            .orderBy("geohash")
            .startAt(b.startHash)
            .endAt(b.endHash);

    tasks.add(q.get());
}

// Collect all the query results together into a single list
Tasks.whenAllComplete(tasks)
        .addOnCompleteListener(new OnCompleteListener<List<Task<?>>>() {
            @Override
            public void onComplete(@NonNull Task<List<Task<?>>> t) {
                List<DocumentSnapshot> matchingDocs = new ArrayList<>();

                for (Task<QuerySnapshot> task : tasks) {
                    QuerySnapshot snap = task.getResult();
                    for (DocumentSnapshot doc : snap.getDocuments()) {
                        double lat = doc.getDouble("lat");
                        double lng = doc.getDouble("lng");

                        // We have to filter out a few false positives due to GeoHash
                        // accuracy, but most will match
                        GeoLocation docLocation = new GeoLocation(lat, lng);
                        double distanceInM = GeoFireUtils.getDistanceBetween(docLocation, center);
                        if (distanceInM <= radiusInM) {
                            matchingDocs.add(doc);
                        }
                    }
                }

                // matchingDocs contains the results
                // ...
            }
        });

限制

使用 Geohash 查询地理位置可为我们带来一些新的功能,但这种方式自身也有一些限制:

  • 假正例 - 通过 Geohash 查询不精确,而且您必须在客户端过滤掉假正例结果。这些额外的读取操作会增加应用的成本和延迟时间。
  • 边缘用例 - 此查询方法依靠的是估算经度线/纬度线之间的距离。当位置接近北极或南极时,这种估算的结果准确度会下降,这意味着 Geohash 查询在极限纬度上会有更多的假正例。