Funciones aritméticas
Todas las funciones aritméticas de Cloud Firestore con compatibilidad con MongoDB tienen los siguientes comportamientos:
- Se evalúa como
NULLsi alguno de los parámetros de entrada esNULL. - Se evalúa como
NaNsi alguno de los argumentos esNaN. - Genera un error si se produce un desbordamiento o subdesbordamiento.
Además, cuando una función aritmética toma varios argumentos numéricos de diferentes tipos
(por ejemplo, add(5.0, 6)), Cloud Firestore con compatibilidad con MongoDB convierte implícitamente
los argumentos al tipo de entrada más amplio. Si solo se proporcionan entradas INT32, el tipo de datos que se devuelve será INT64.
| Nombre | Descripción |
ABS
|
Devuelve el valor absoluto de un number.
|
ADD
|
Devuelve el valor de x + y.
|
SUBTRACT
|
Devuelve el valor de x - y.
|
MULTIPLY
|
Devuelve el valor de x * y.
|
DIVIDE
|
Devuelve el valor de x / y.
|
MOD
|
Devuelve el resto de la división de x / y.
|
CEIL
|
Devuelve el límite superior de un number
|
FLOOR
|
Devuelve el límite inferior de un number
|
ROUND
|
Redondea un number a places decimales
|
POW
|
Devuelve el valor de base^exponent.
|
SQRT
|
Devuelve la raíz cuadrada de un number
|
EXP
|
Devuelve el número de Euler elevado a la potencia de exponent
|
LN
|
Devuelve el logaritmo natural de un number
|
LOG
|
Devuelve el logaritmo de un number
|
LOG10
|
Devuelve el logaritmo de un number en base 10
|
RAND
|
Devuelve un número de punto flotante pseudoaleatorio. |
ABS
Sintaxis:
abs[N <: INT32 | INT64 | FLOAT64](number: N) -> N
Descripción:
Devuelve el valor absoluto de un number.
- Se arroja un error cuando la función desbordaría un valor de
INT32oINT64.
Ejemplos:
| número | abs(number) |
|---|---|
| 10 | 10 |
| -10 | 10 |
| 10L | 10L |
| -0.0 | 0.0 |
| 10.5 | 10.5 |
| -10.5 | 10.5 |
| -231 | [error] |
| -263 | [error] |
AGREGAR
Sintaxis:
add[N <: INT32 | INT64 | FLOAT64](x: N, y: N) -> N
Descripción:
Devuelve el valor de x + y.
Ejemplos:
| x | y | add(x, y) |
|---|---|---|
| 20 | 3 | 23 |
| 10.0 | 1 | 11.0 |
| 22.5 | 2.0 | 24.5 |
| INT64.MAX | 1 | [error] |
| INT64.MIN | -1 | [error] |
Node.js
const result = await db.pipeline() .collection("books") .select(field("soldBooks").add(field("unsoldBooks")).as("totalBooks")) .execute();
Web
const result = await execute(db.pipeline() .collection("books") .select(field("soldBooks").add(field("unsoldBooks")).as("totalBooks")) );
Swift
let result = try await db.pipeline() .collection("books") .select([Field("soldBooks").add(Field("unsoldBooks")).as("totalBooks")]) .execute()
Kotlin
val result = db.pipeline() .collection("books") .select(Expression.add(field("soldBooks"), field("unsoldBooks")).alias("totalBooks")) .execute()
Java
Task<Pipeline.Snapshot> result = db.pipeline() .collection("books") .select(Expression.add(field("soldBooks"), field("unsoldBooks")).alias("totalBooks")) .execute();
Python
from google.cloud.firestore_v1.pipeline_expressions import Field result = ( client.pipeline() .collection("books") .select(Field.of("soldBooks").add(Field.of("unsoldBooks")).as_("totalBooks")) .execute() )
Java
Pipeline.Snapshot result = firestore .pipeline() .collection("books") .select(add(field("soldBooks"), field("unsoldBooks")).as("totalBooks")) .execute() .get();
SUBTRACT
Sintaxis:
subtract[N <: INT32 | INT64 | FLOAT64](x: N, y: N) -> N
Descripción:
Devuelve el valor de x - y.
Ejemplos:
| x | y | subtract(x, y) |
|---|---|---|
| 20 | 3 | 17 |
| 10.0 | 1 | 9.0 |
| 22.5 | 2.0 | 20.5 |
| INT64.MAX | -1 | [error] |
| INT64.MIN | 1 | [error] |
Node.js
const storeCredit = 7; const result = await db.pipeline() .collection("books") .select(field("price").subtract(constant(storeCredit)).as("totalCost")) .execute();
Web
const storeCredit = 7; const result = await execute(db.pipeline() .collection("books") .select(field("price").subtract(constant(storeCredit)).as("totalCost")) );
Swift
let storeCredit = 7 let result = try await db.pipeline() .collection("books") .select([Field("price").subtract(Constant(storeCredit)).as("totalCost")]) .execute()
Kotlin
val storeCredit = 7 val result = db.pipeline() .collection("books") .select(Expression.subtract(field("price"), storeCredit).alias("totalCost")) .execute()
Java
int storeCredit = 7; Task<Pipeline.Snapshot> result = db.pipeline() .collection("books") .select(Expression.subtract(field("price"), storeCredit).alias("totalCost")) .execute();
Python
from google.cloud.firestore_v1.pipeline_expressions import Field store_credit = 7 result = ( client.pipeline() .collection("books") .select(Field.of("price").subtract(store_credit).as_("totalCost")) .execute() )
Java
int storeCredit = 7; Pipeline.Snapshot result = firestore .pipeline() .collection("books") .select(subtract(field("price"), storeCredit).as("totalCost")) .execute() .get();
MULTIPLY
Sintaxis:
multiply[N <: INT32 | INT64 | FLOAT64](x: N, y: N) -> N
Descripción:
Devuelve el valor de x * y.
Ejemplos:
| x | y | multiply(x, y) |
|---|---|---|
| 20 | 3 | 60 |
| 10.0 | 1 | 10.0 |
| 22.5 | 2.0 | 45.0 |
| INT64.MAX | 2 | [error] |
| INT64.MIN | 2 | [error] |
| FLOAT64.MAX | FLOAT64.MAX | +inf |
Node.js
const result = await db.pipeline() .collection("books") .select(field("price").multiply(field("soldBooks")).as("revenue")) .execute();
Web
const result = await execute(db.pipeline() .collection("books") .select(field("price").multiply(field("soldBooks")).as("revenue")) );
Swift
let result = try await db.pipeline() .collection("books") .select([Field("price").multiply(Field("soldBooks")).as("revenue")]) .execute()
Kotlin
val result = db.pipeline() .collection("books") .select(Expression.multiply(field("price"), field("soldBooks")).alias("revenue")) .execute()
Java
Task<Pipeline.Snapshot> result = db.pipeline() .collection("books") .select(Expression.multiply(field("price"), field("soldBooks")).alias("revenue")) .execute();
Python
from google.cloud.firestore_v1.pipeline_expressions import Field result = ( client.pipeline() .collection("books") .select(Field.of("price").multiply(Field.of("soldBooks")).as_("revenue")) .execute() )
Java
Pipeline.Snapshot result = firestore .pipeline() .collection("books") .select(multiply(field("price"), field("soldBooks")).as("revenue")) .execute() .get();
DIVIDE
Sintaxis:
divide[N <: INT32 | INT64 | FLOAT64](x: N, y: N) -> N
Descripción:
Devuelve el valor de x / y. La división de números enteros se trunca.
Ejemplos:
| x | y | divide(x, y) |
|---|---|---|
| 20 | 3 | 6 |
| 10.0 | 3 | 3.333… |
| 22.5 | 2 | 11.25 |
| 10 | 0 | [error] |
| 1.0 | 0.0 | +inf |
| -1.0 | 0.0 | -inf |
Node.js
const result = await db.pipeline() .collection("books") .select(field("ratings").divide(field("soldBooks")).as("reviewRate")) .execute();
Web
const result = await execute(db.pipeline() .collection("books") .select(field("ratings").divide(field("soldBooks")).as("reviewRate")) );
Swift
let result = try await db.pipeline() .collection("books") .select([Field("ratings").divide(Field("soldBooks")).as("reviewRate")]) .execute()
Kotlin
val result = db.pipeline() .collection("books") .select(Expression.divide(field("ratings"), field("soldBooks")).alias("reviewRate")) .execute()
Java
Task<Pipeline.Snapshot> result = db.pipeline() .collection("books") .select(Expression.divide(field("ratings"), field("soldBooks")).alias("reviewRate")) .execute();
Python
from google.cloud.firestore_v1.pipeline_expressions import Field result = ( client.pipeline() .collection("books") .select(Field.of("ratings").divide(Field.of("soldBooks")).as_("reviewRate")) .execute() )
Java
Pipeline.Snapshot result = firestore .pipeline() .collection("books") .select(divide(field("ratings"), field("soldBooks")).as("reviewRate")) .execute() .get();
MOD
Sintaxis:
mod[N <: INT32 | INT64 | FLOAT64](x: N, y: N) -> N
Descripción:
Devuelve el resto de x / y.
- Muestra un
errorcuandoyes cero para los tipos de números enteros (INT64). - Devuelve
NaNcuandoyes cero para los tipos de números de punto flotante (FLOAT64).
Ejemplos:
| x | y | mod(x, y) |
|---|---|---|
| 20 | 3 | 2 |
| -10 | 3 | -1 |
| 10 | -3 | 1 |
| -10 | -3 | -1 |
| 10 | 1 | 0 |
| 22.5 | 2 | 0.5 |
| 22.5 | 0.0 | NaN |
| 25 | 0 | [error] |
Node.js
const displayCapacity = 1000; const result = await db.pipeline() .collection("books") .select(field("unsoldBooks").mod(constant(displayCapacity)).as("warehousedBooks")) .execute();
Web
const displayCapacity = 1000; const result = await execute(db.pipeline() .collection("books") .select(field("unsoldBooks").mod(constant(displayCapacity)).as("warehousedBooks")) );
Swift
let displayCapacity = 1000 let result = try await db.pipeline() .collection("books") .select([Field("unsoldBooks").mod(Constant(displayCapacity)).as("warehousedBooks")]) .execute()
Kotlin
val displayCapacity = 1000 val result = db.pipeline() .collection("books") .select(Expression.mod(field("unsoldBooks"), displayCapacity).alias("warehousedBooks")) .execute()
Java
int displayCapacity = 1000; Task<Pipeline.Snapshot> result = db.pipeline() .collection("books") .select(Expression.mod(field("unsoldBooks"), displayCapacity).alias("warehousedBooks")) .execute();
Python
from google.cloud.firestore_v1.pipeline_expressions import Field display_capacity = 1000 result = ( client.pipeline() .collection("books") .select(Field.of("unsoldBooks").mod(display_capacity).as_("warehousedBooks")) .execute() )
Java
int displayCapacity = 1000; Pipeline.Snapshot result = firestore .pipeline() .collection("books") .select(mod(field("unsoldBooks"), displayCapacity).as("warehousedBooks")) .execute() .get();
CEIL
Sintaxis:
ceil[N <: INT32 | INT64 | FLOAT64](number: N) -> N
Descripción:
Devuelve el valor numérico más pequeño que no es menor que number.
Ejemplos:
| número | ceil(number) |
|---|---|
| 20 | 20 |
| 10 | 10 |
| 0 | 0 |
| 24L | 24L |
| -0.4 | -0.0 |
| 0.4 | 1.0 |
| 22.5 | 23.0 |
+inf |
+inf |
-inf |
-inf |
Node.js
const booksPerShelf = 100; const result = await db.pipeline() .collection("books") .select( field("unsoldBooks").divide(constant(booksPerShelf)).ceil().as("requiredShelves") ) .execute();
Web
const booksPerShelf = 100; const result = await execute(db.pipeline() .collection("books") .select( field("unsoldBooks").divide(constant(booksPerShelf)).ceil().as("requiredShelves") ) );
Swift
let booksPerShelf = 100 let result = try await db.pipeline() .collection("books") .select([ Field("unsoldBooks").divide(Constant(booksPerShelf)).ceil().as("requiredShelves") ]) .execute()
Kotlin
val booksPerShelf = 100 val result = db.pipeline() .collection("books") .select( Expression.divide(field("unsoldBooks"), booksPerShelf).ceil().alias("requiredShelves") ) .execute()
Java
int booksPerShelf = 100; Task<Pipeline.Snapshot> result = db.pipeline() .collection("books") .select( Expression.divide(field("unsoldBooks"), booksPerShelf).ceil().alias("requiredShelves") ) .execute();
Python
from google.cloud.firestore_v1.pipeline_expressions import Field books_per_shelf = 100 result = ( client.pipeline() .collection("books") .select( Field.of("unsoldBooks") .divide(books_per_shelf) .ceil() .as_("requiredShelves") ) .execute() )
Java
int booksPerShelf = 100; Pipeline.Snapshot result = firestore .pipeline() .collection("books") .select(ceil(divide(field("unsoldBooks"), booksPerShelf)).as("requiredShelves")) .execute() .get();
FLOOR
Sintaxis:
floor[N <: INT32 | INT64 | FLOAT64](number: N) -> N
Descripción:
Devuelve el valor numérico más grande que no es mayor que number.
Ejemplos:
| número | floor(number) |
|---|---|
| 20 | 20 |
| 10 | 10 |
| 0 | 0 |
| 2147483648 | 2147483648 |
| -0.4 | -1.0 |
| 0.4 | 0.0 |
| 22.5 | 22.0 |
+inf |
+inf |
-inf |
-inf |
Node.js
const result = await db.pipeline() .collection("books") .addFields( field("wordCount").divide(field("pages")).floor().as("wordsPerPage") ) .execute();
Web
const result = await execute(db.pipeline() .collection("books") .addFields( field("wordCount").divide(field("pages")).floor().as("wordsPerPage") ) );
Swift
let result = try await db.pipeline() .collection("books") .addFields([ Field("wordCount").divide(Field("pages")).floor().as("wordsPerPage") ]) .execute()
Kotlin
val result = db.pipeline() .collection("books") .addFields( Expression.divide(field("wordCount"), field("pages")).floor().alias("wordsPerPage") ) .execute()
Java
Task<Pipeline.Snapshot> result = db.pipeline() .collection("books") .addFields( Expression.divide(field("wordCount"), field("pages")).floor().alias("wordsPerPage") ) .execute();
Python
from google.cloud.firestore_v1.pipeline_expressions import Field result = ( client.pipeline() .collection("books") .add_fields( Field.of("wordCount").divide(Field.of("pages")).floor().as_("wordsPerPage") ) .execute() )
Java
Pipeline.Snapshot result = firestore .pipeline() .collection("books") .addFields(floor(divide(field("wordCount"), field("pages"))).as("wordsPerPage")) .execute() .get();
ROUND
Sintaxis:
round[N <: INT32 | INT64 | FLOAT64 | DECIMAL128](number: N) -> N
round[N <: INT32 | INT64 | FLOAT64 | DECIMAL128](number: N, places: INT64) -> N
Descripción:
Redondea places dígitos de un number. Redondea los dígitos a la derecha del punto decimal si places es positivo y a la izquierda del punto decimal si es negativo.
- Si solo se proporciona
number, se redondea al valor entero más cercano. - Redondea en dirección opuesta al cero en los casos de punto medio.
- Se arroja un
errorsi el redondeo con un valor deplacesnegativo genera un desbordamiento.
Ejemplos:
| número | places | round(number, places) |
|---|---|---|
| 15.5 | 0 | 16.0 |
| -15.5 | 0 | -16.0 |
| 15 | 1 | 15 |
| 15 | 0 | 15 |
| 15 | -1 | 20 |
| 15 | -2 | 0 |
| 15.48924 | 1 | 15.5 |
| 231-1 | -1 | [error] |
| 263-1L | -1 | [error] |
Node.js
const result = await db.pipeline() .collection("books") .select(field("soldBooks").multiply(field("price")).round().as("partialRevenue")) .aggregate(field("partialRevenue").sum().as("totalRevenue")) .execute();
Web
const result = await execute(db.pipeline() .collection("books") .select(field("soldBooks").multiply(field("price")).round().as("partialRevenue")) .aggregate(field("partialRevenue").sum().as("totalRevenue")) );
Swift
let result = try await db.pipeline() .collection("books") .select([Field("soldBooks").multiply(Field("price")).round().as("partialRevenue")]) .aggregate([Field("partialRevenue").sum().as("totalRevenue")]) .execute()
Kotlin
val result = db.pipeline() .collection("books") .select(Expression.multiply(field("soldBooks"), field("price")).round().alias("partialRevenue")) .aggregate(AggregateFunction.sum("partialRevenue").alias("totalRevenue")) .execute()
Java
Task<Pipeline.Snapshot> result = db.pipeline() .collection("books") .select(Expression.multiply(field("soldBooks"), field("price")).round().alias("partialRevenue")) .aggregate(AggregateFunction.sum("partialRevenue").alias("totalRevenue")) .execute();
Python
from google.cloud.firestore_v1.pipeline_expressions import Field result = ( client.pipeline() .collection("books") .select( Field.of("soldBooks") .multiply(Field.of("price")) .round() .as_("partialRevenue") ) .aggregate(Field.of("partialRevenue").sum().as_("totalRevenue")) .execute() )
Java
Pipeline.Snapshot result = firestore .pipeline() .collection("books") .select(round(multiply(field("soldBooks"), field("price"))).as("partialRevenue")) .aggregate(sum("partialRevenue").as("totalRevenue")) .execute() .get();
POW
Sintaxis:
pow(base: FLOAT64, exponent: FLOAT64) -> FLOAT64
Descripción:
Devuelve el valor de base elevado a la potencia de exponent.
Muestra un error si
base <= 0yexponentson negativos.Para cualquier
exponent,pow(1, exponent)es 1.Para cualquier
base,pow(base, 0)es 1.
Ejemplos:
| base | exponente | pow(base, exponent) |
|---|---|---|
| 2 | 3 | 8.0 |
| 2 | -3 | 0.125 |
+inf |
0 | 1.0 |
| 1 | +inf |
1.0 |
| -1 | 0.5 | [error] |
| 0 | -1 | [error] |
Node.js
const googleplex = { latitude: 37.4221, longitude: 122.0853 }; const result = await db.pipeline() .collection("cities") .addFields( field("lat").subtract(constant(googleplex.latitude)) .multiply(111 /* km per degree */) .pow(2) .as("latitudeDifference"), field("lng").subtract(constant(googleplex.longitude)) .multiply(111 /* km per degree */) .pow(2) .as("longitudeDifference") ) .select( field("latitudeDifference").add(field("longitudeDifference")).sqrt() // Inaccurate for large distances or close to poles .as("approximateDistanceToGoogle") ) .execute();
Web
const googleplex = { latitude: 37.4221, longitude: 122.0853 }; const result = await execute(db.pipeline() .collection("cities") .addFields( field("lat").subtract(constant(googleplex.latitude)) .multiply(111 /* km per degree */) .pow(2) .as("latitudeDifference"), field("lng").subtract(constant(googleplex.longitude)) .multiply(111 /* km per degree */) .pow(2) .as("longitudeDifference") ) .select( field("latitudeDifference").add(field("longitudeDifference")).sqrt() // Inaccurate for large distances or close to poles .as("approximateDistanceToGoogle") ) );
Swift
let googleplex = CLLocation(latitude: 37.4221, longitude: 122.0853) let result = try await db.pipeline() .collection("cities") .addFields([ Field("lat").subtract(Constant(googleplex.coordinate.latitude)) .multiply(111 /* km per degree */) .pow(2) .as("latitudeDifference"), Field("lng").subtract(Constant(googleplex.coordinate.latitude)) .multiply(111 /* km per degree */) .pow(2) .as("longitudeDifference") ]) .select([ Field("latitudeDifference").add(Field("longitudeDifference")).sqrt() // Inaccurate for large distances or close to poles .as("approximateDistanceToGoogle") ]) .execute()
Kotlin
val googleplex = GeoPoint(37.4221, -122.0853) val result = db.pipeline() .collection("cities") .addFields( field("lat").subtract(googleplex.latitude) .multiply(111 /* km per degree */) .pow(2) .alias("latitudeDifference"), field("lng").subtract(googleplex.longitude) .multiply(111 /* km per degree */) .pow(2) .alias("longitudeDifference") ) .select( field("latitudeDifference").add(field("longitudeDifference")).sqrt() // Inaccurate for large distances or close to poles .alias("approximateDistanceToGoogle") ) .execute()
Java
GeoPoint googleplex = new GeoPoint(37.4221, -122.0853); Task<Pipeline.Snapshot> result = db.pipeline() .collection("cities") .addFields( field("lat").subtract(googleplex.getLatitude()) .multiply(111 /* km per degree */) .pow(2) .alias("latitudeDifference"), field("lng").subtract(googleplex.getLongitude()) .multiply(111 /* km per degree */) .pow(2) .alias("longitudeDifference") ) .select( field("latitudeDifference").add(field("longitudeDifference")).sqrt() // Inaccurate for large distances or close to poles .alias("approximateDistanceToGoogle") ) .execute();
Python
from google.cloud.firestore_v1.pipeline_expressions import Field googleplexLat = 37.4221 googleplexLng = -122.0853 result = ( client.pipeline() .collection("cities") .add_fields( Field.of("lat") .subtract(googleplexLat) .multiply(111) # km per degree .pow(2) .as_("latitudeDifference"), Field.of("lng") .subtract(googleplexLng) .multiply(111) # km per degree .pow(2) .as_("longitudeDifference"), ) .select( Field.of("latitudeDifference") .add(Field.of("longitudeDifference")) .sqrt() # Inaccurate for large distances or close to poles .as_("approximateDistanceToGoogle") ) .execute() )
Java
double googleplexLat = 37.4221; double googleplexLng = -122.0853; Pipeline.Snapshot result = firestore .pipeline() .collection("cities") .addFields( pow(multiply(subtract(field("lat"), googleplexLat), 111), 2) .as("latitudeDifference"), pow(multiply(subtract(field("lng"), googleplexLng), 111), 2) .as("longitudeDifference")) .select( sqrt(add(field("latitudeDifference"), field("longitudeDifference"))) // Inaccurate for large distances or close to poles .as("approximateDistanceToGoogle")) .execute() .get();
SQRT
Sintaxis:
sqrt[N <: FLOAT64 | DECIMAL128](number: N) -> N
Descripción:
Devuelve la raíz cuadrada de un number.
- Muestra un
errorsinumberes negativo.
Ejemplos:
| número | sqrt(number) |
|---|---|
| 25 | 5.0 |
| 12.002 | 3.464… |
| 0.0 | 0.0 |
NaN |
NaN |
+inf |
+inf |
-inf |
[error] |
x < 0 |
[error] |
Node.js
const googleplex = { latitude: 37.4221, longitude: 122.0853 }; const result = await db.pipeline() .collection("cities") .addFields( field("lat").subtract(constant(googleplex.latitude)) .multiply(111 /* km per degree */) .pow(2) .as("latitudeDifference"), field("lng").subtract(constant(googleplex.longitude)) .multiply(111 /* km per degree */) .pow(2) .as("longitudeDifference") ) .select( field("latitudeDifference").add(field("longitudeDifference")).sqrt() // Inaccurate for large distances or close to poles .as("approximateDistanceToGoogle") ) .execute();
Web
const googleplex = { latitude: 37.4221, longitude: 122.0853 }; const result = await execute(db.pipeline() .collection("cities") .addFields( field("lat").subtract(constant(googleplex.latitude)) .multiply(111 /* km per degree */) .pow(2) .as("latitudeDifference"), field("lng").subtract(constant(googleplex.longitude)) .multiply(111 /* km per degree */) .pow(2) .as("longitudeDifference") ) .select( field("latitudeDifference").add(field("longitudeDifference")).sqrt() // Inaccurate for large distances or close to poles .as("approximateDistanceToGoogle") ) );
Swift
let googleplex = CLLocation(latitude: 37.4221, longitude: 122.0853) let result = try await db.pipeline() .collection("cities") .addFields([ Field("lat").subtract(Constant(googleplex.coordinate.latitude)) .multiply(111 /* km per degree */) .pow(2) .as("latitudeDifference"), Field("lng").subtract(Constant(googleplex.coordinate.latitude)) .multiply(111 /* km per degree */) .pow(2) .as("longitudeDifference") ]) .select([ Field("latitudeDifference").add(Field("longitudeDifference")).sqrt() // Inaccurate for large distances or close to poles .as("approximateDistanceToGoogle") ]) .execute()
Kotlin
val googleplex = GeoPoint(37.4221, -122.0853) val result = db.pipeline() .collection("cities") .addFields( field("lat").subtract(googleplex.latitude) .multiply(111 /* km per degree */) .pow(2) .alias("latitudeDifference"), field("lng").subtract(googleplex.longitude) .multiply(111 /* km per degree */) .pow(2) .alias("longitudeDifference") ) .select( field("latitudeDifference").add(field("longitudeDifference")).sqrt() // Inaccurate for large distances or close to poles .alias("approximateDistanceToGoogle") ) .execute()
Java
GeoPoint googleplex = new GeoPoint(37.4221, -122.0853); Task<Pipeline.Snapshot> result = db.pipeline() .collection("cities") .addFields( field("lat").subtract(googleplex.getLatitude()) .multiply(111 /* km per degree */) .pow(2) .alias("latitudeDifference"), field("lng").subtract(googleplex.getLongitude()) .multiply(111 /* km per degree */) .pow(2) .alias("longitudeDifference") ) .select( field("latitudeDifference").add(field("longitudeDifference")).sqrt() // Inaccurate for large distances or close to poles .alias("approximateDistanceToGoogle") ) .execute();
Python
from google.cloud.firestore_v1.pipeline_expressions import Field googleplexLat = 37.4221 googleplexLng = -122.0853 result = ( client.pipeline() .collection("cities") .add_fields( Field.of("lat") .subtract(googleplexLat) .multiply(111) # km per degree .pow(2) .as_("latitudeDifference"), Field.of("lng") .subtract(googleplexLng) .multiply(111) # km per degree .pow(2) .as_("longitudeDifference"), ) .select( Field.of("latitudeDifference") .add(Field.of("longitudeDifference")) .sqrt() # Inaccurate for large distances or close to poles .as_("approximateDistanceToGoogle") ) .execute() )
Java
double googleplexLat = 37.4221; double googleplexLng = -122.0853; Pipeline.Snapshot result = firestore .pipeline() .collection("cities") .addFields( pow(multiply(subtract(field("lat"), googleplexLat), 111), 2) .as("latitudeDifference"), pow(multiply(subtract(field("lng"), googleplexLng), 111), 2) .as("longitudeDifference")) .select( sqrt(add(field("latitudeDifference"), field("longitudeDifference"))) // Inaccurate for large distances or close to poles .as("approximateDistanceToGoogle")) .execute() .get();
EXP
Sintaxis:
exp(exponent: FLOAT64) -> FLOAT64
Descripción:
Devuelve el valor del número de Euler elevado a la potencia de exponent, también llamado función exponencial natural.
Ejemplos:
| exponente | exp(exponent) |
|---|---|
| 0.0 | 1.0 |
| 10 | e^10 (FLOAT64) |
+inf |
+inf |
-inf |
0 |
Node.js
const result = await db.pipeline() .collection("books") .select(field("rating").exp().as("expRating")) .execute();
Web
const result = await execute(db.pipeline() .collection("books") .select(field("rating").exp().as("expRating")) );
Swift
let result = try await db.pipeline() .collection("books") .select([Field("rating").exp().as("expRating")]) .execute()
Kotlin
val result = db.pipeline() .collection("books") .select(field("rating").exp().alias("expRating")) .execute()
Java
Task<Pipeline.Snapshot> result = db.pipeline() .collection("books") .select(field("rating").exp().alias("expRating")) .execute();
Python
from google.cloud.firestore_v1.pipeline_expressions import Field result = ( client.pipeline() .collection("books") .select(Field.of("rating").exp().as_("expRating")) .execute() )
Java
Pipeline.Snapshot result = firestore .pipeline() .collection("books") .select(exp(field("rating")).as("expRating")) .execute() .get();
LN
Sintaxis:
ln(number: FLOAT64) -> FLOAT64
Descripción:
Devuelve el logaritmo natural de number. Esta función es equivalente a log(number).
Ejemplos:
| número | ln(number) |
|---|---|
| 1 | 0.0 |
| 2L | 0.693... |
| 1.0 | 0.0 |
e (FLOAT64) |
1.0 |
-inf |
NaN |
+inf |
+inf |
x <= 0 |
[error] |
Node.js
const result = await db.pipeline() .collection("books") .select(field("rating").ln().as("lnRating")) .execute();
Web
const result = await execute(db.pipeline() .collection("books") .select(field("rating").ln().as("lnRating")) );
Swift
let result = try await db.pipeline() .collection("books") .select([Field("rating").ln().as("lnRating")]) .execute()
Kotlin
val result = db.pipeline() .collection("books") .select(field("rating").ln().alias("lnRating")) .execute()
Java
Task<Pipeline.Snapshot> result = db.pipeline() .collection("books") .select(field("rating").ln().alias("lnRating")) .execute();
Python
from google.cloud.firestore_v1.pipeline_expressions import Field result = ( client.pipeline() .collection("books") .select(Field.of("rating").ln().as_("lnRating")) .execute() )
Java
Pipeline.Snapshot result = firestore .pipeline() .collection("books") .select(ln(field("rating")).as("lnRating")) .execute() .get();
LOG
Sintaxis:
log(number: FLOAT64, base: FLOAT64) -> FLOAT64
log(number: FLOAT64) -> FLOAT64
Descripción:
Devuelve el logaritmo de number en base base.
- Si solo se proporciona
number, devuelve el logaritmo denumberenbase(sinónimo deln(number)).
Ejemplos:
| número | base | log(number, base) |
|---|---|---|
| 100 | 10 | 2.0 |
-inf |
Numeric |
NaN |
Numeric. |
+inf |
NaN |
number <= 0 |
Numeric |
[error] |
Numeric |
base <= 0 |
[error] |
Numeric |
1.0 | [error] |
LOG10
Sintaxis:
log10(x: FLOAT64) -> FLOAT64
Descripción:
Devuelve el logaritmo de number en base 10.
Ejemplos:
| número | log10(number) |
|---|---|
| 100 | 2.0 |
-inf |
NaN |
+inf |
+inf |
x <= 0 |
[error] |
RAND
Sintaxis:
rand() -> FLOAT64
Descripción:
Devuelve un número de punto flotante pseudoaleatorio, elegido de forma uniforme entre 0.0 (inclusive) y 1.0 (exclusive).