import type { OperationNodeSource } from '../operation-node/operation-node-source.js'; import type { CompiledQuery } from '../query-compiler/compiled-query.js'; import { type SelectExpression, type SelectCallback } from '../parser/select-parser.js'; import { type InsertExpression } from '../parser/insert-values-parser.js'; import { InsertQueryNode } from '../operation-node/insert-query-node.js'; import { QueryNode } from '../operation-node/query-node.js'; import type { NarrowPartial, SimplifyResult, SimplifySingleResult } from '../util/type-utils.js'; import { type UpdateObjectExpression } from '../parser/update-set-parser.js'; import type { Compilable } from '../util/compilable.js'; import type { QueryExecutor } from '../query-executor/query-executor.js'; import type { QueryId } from '../util/query-id.js'; import { InsertResult } from './insert-result.js'; import type { KyselyPlugin } from '../plugin/kysely-plugin.js'; import type { ReturningAllRow, ReturningCallbackRow, ReturningRow } from '../parser/returning-parser.js'; import { type NoResultErrorConstructor } from './no-result-error.js'; import { type ExpressionOrFactory } from '../parser/expression-parser.js'; import type { ReturningInterface } from './returning-interface.js'; import { OnConflictBuilder, type OnConflictDatabase, type OnConflictDoNothingBuilder, type OnConflictTables, type OnConflictUpdateBuilder } from './on-conflict-builder.js'; import type { Selectable } from '../util/column-type.js'; import type { Explainable, ExplainFormat } from '../util/explainable.js'; import type { Expression } from '../expression/expression.js'; import type { KyselyTypeError } from '../util/type-error.js'; import type { Streamable } from '../util/streamable.js'; import type { OutputCallback, OutputExpression, OutputInterface, SelectExpressionFromOutputCallback, SelectExpressionFromOutputExpression } from './output-interface.js'; export declare class InsertQueryBuilder implements ReturningInterface, OutputInterface, OperationNodeSource, Compilable, Explainable, Streamable { #private; constructor(props: InsertQueryBuilderProps); /** * Sets the values to insert for an {@link Kysely.insertInto | insert} query. * * This method takes an object whose keys are column names and values are * values to insert. In addition to the column's type, the values can be * raw {@link sql} snippets or select queries. * * You must provide all fields you haven't explicitly marked as nullable * or optional using {@link Generated} or {@link ColumnType}. * * The return value of an `insert` query is an instance of {@link InsertResult}. The * {@link InsertResult.insertId | insertId} field holds the auto incremented primary * key if the database returned one. * * On PostgreSQL and some other dialects, you need to call `returning` to get * something out of the query. * * Also see the {@link expression} method for inserting the result of a select * query or any other expression. * * ### Examples * * * * Insert a single row: * * ```ts * const result = await db * .insertInto('person') * .values({ * first_name: 'Jennifer', * last_name: 'Aniston', * age: 40 * }) * .executeTakeFirst() * * // `insertId` is only available on dialects that * // automatically return the id of the inserted row * // such as MySQL and SQLite. On PostgreSQL, for example, * // you need to add a `returning` clause to the query to * // get anything out. See the "returning data" example. * console.log(result.insertId) * ``` * * The generated SQL (MySQL): * * ```sql * insert into `person` (`first_name`, `last_name`, `age`) values (?, ?, ?) * ``` * * * * On dialects that support it (for example PostgreSQL) you can insert multiple * rows by providing an array. Note that the return value is once again very * dialect-specific. Some databases may only return the id of the *last* inserted * row and some return nothing at all unless you call `returning`. * * ```ts * await db * .insertInto('person') * .values([{ * first_name: 'Jennifer', * last_name: 'Aniston', * age: 40, * }, { * first_name: 'Arnold', * last_name: 'Schwarzenegger', * age: 70, * }]) * .execute() * ``` * * The generated SQL (PostgreSQL): * * ```sql * insert into "person" ("first_name", "last_name", "age") values (($1, $2, $3), ($4, $5, $6)) * ``` * * * * On supported dialects like PostgreSQL you need to chain `returning` to the query to get * the inserted row's columns (or any other expression) as the return value. `returning` * works just like `select`. Refer to `select` method's examples and documentation for * more info. * * ```ts * const result = await db * .insertInto('person') * .values({ * first_name: 'Jennifer', * last_name: 'Aniston', * age: 40, * }) * .returning(['id', 'first_name as name']) * .executeTakeFirstOrThrow() * ``` * * The generated SQL (PostgreSQL): * * ```sql * insert into "person" ("first_name", "last_name", "age") values ($1, $2, $3) returning "id", "first_name" as "name" * ``` * * * * In addition to primitives, the values can also be arbitrary expressions. * You can build the expressions by using a callback and calling the methods * on the expression builder passed to it: * * ```ts * import { sql } from 'kysely' * * const ani = "Ani" * const ston = "ston" * * const result = await db * .insertInto('person') * .values(({ ref, selectFrom, fn }) => ({ * first_name: 'Jennifer', * last_name: sql`concat(${ani}, ${ston})`, * middle_name: ref('first_name'), * age: selectFrom('person') * .select(fn.avg('age').as('avg_age')), * })) * .executeTakeFirst() * ``` * * The generated SQL (PostgreSQL): * * ```sql * insert into "person" ( * "first_name", * "last_name", * "middle_name", * "age" * ) * values ( * $1, * concat($2, $3), * "first_name", * (select avg("age") as "avg_age" from "person") * ) * ``` * * You can also use the callback version of subqueries or raw expressions: * * ```ts * await db.with('jennifer', (db) => db * .selectFrom('person') * .where('first_name', '=', 'Jennifer') * .select(['id', 'first_name', 'gender']) * .limit(1) * ).insertInto('pet').values((eb) => ({ * owner_id: eb.selectFrom('jennifer').select('id'), * name: eb.selectFrom('jennifer').select('first_name'), * species: 'cat', * })) * .execute() * ``` * * The generated SQL (PostgreSQL): * * ```sql * with "jennifer" as ( * select "id", "first_name", "gender" * from "person" * where "first_name" = $1 * limit $2 * ) * insert into "pet" ("owner_id", "name", "species") * values ( * (select "id" from "jennifer"), * (select "first_name" from "jennifer"), * $3 * ) * ``` */ values(insert: InsertExpression): InsertQueryBuilder; /** * Sets the columns to insert. * * The {@link values} method sets both the columns and the values and this method * is not needed. But if you are using the {@link expression} method, you can use * this method to set the columns to insert. * * ### Examples * * ```ts * await db.insertInto('person') * .columns(['first_name']) * .expression((eb) => eb.selectFrom('pet').select('pet.name')) * .execute() * ``` * * The generated SQL (PostgreSQL): * * ```sql * insert into "person" ("first_name") * select "pet"."name" from "pet" * ``` */ columns(columns: ReadonlyArray): InsertQueryBuilder; /** * Insert an arbitrary expression. For example the result of a select query. * * ### Examples * * * * You can create an `INSERT INTO SELECT FROM` query using the `expression` method. * This API doesn't follow our WYSIWYG principles and might be a bit difficult to * remember. The reasons for this design stem from implementation difficulties. * * ```ts * const result = await db.insertInto('person') * .columns(['first_name', 'last_name', 'age']) * .expression((eb) => eb * .selectFrom('pet') * .select((eb) => [ * 'pet.name', * eb.val('Petson').as('last_name'), * eb.lit(7).as('age'), * ]) * ) * .execute() * ``` * * The generated SQL (PostgreSQL): * * ```sql * insert into "person" ("first_name", "last_name", "age") * select "pet"."name", $1 as "last_name", 7 as "age from "pet" * ``` */ expression(expression: ExpressionOrFactory): InsertQueryBuilder; /** * Creates an `insert into "person" default values` query. * * ### Examples * * ```ts * await db.insertInto('person') * .defaultValues() * .execute() * ``` * * The generated SQL (PostgreSQL): * * ```sql * insert into "person" default values * ``` */ defaultValues(): InsertQueryBuilder; /** * This can be used to add any additional SQL to the end of the query. * * ### Examples * * ```ts * import { sql } from 'kysely' * * await db.insertInto('person') * .values({ * first_name: 'John', * last_name: 'Doe', * gender: 'male', * }) * .modifyEnd(sql`-- This is a comment`) * .execute() * ``` * * The generated SQL (MySQL): * * ```sql * insert into `person` ("first_name", "last_name", "gender") * values (?, ?, ?) -- This is a comment * ``` */ modifyEnd(modifier: Expression): InsertQueryBuilder; /** * Changes an `insert into` query to an `insert ignore into` query. * * This is only supported by some dialects like MySQL. * * To avoid a footgun, when invoked with the SQLite dialect, this method will * be handled like {@link orIgnore}. See also, {@link orAbort}, {@link orFail}, * {@link orReplace}, and {@link orRollback}. * * If you use the ignore modifier, ignorable errors that occur while executing the * insert statement are ignored. For example, without ignore, a row that duplicates * an existing unique index or primary key value in the table causes a duplicate-key * error and the statement is aborted. With ignore, the row is discarded and no error * occurs. * * ### Examples * * ```ts * await db.insertInto('person') * .ignore() * .values({ * first_name: 'John', * last_name: 'Doe', * gender: 'female', * }) * .execute() * ``` * * The generated SQL (MySQL): * * ```sql * insert ignore into `person` (`first_name`, `last_name`, `gender`) values (?, ?, ?) * ``` * * The generated SQL (SQLite): * * ```sql * insert or ignore into "person" ("first_name", "last_name", "gender") values (?, ?, ?) * ``` */ ignore(): InsertQueryBuilder; /** * Changes an `insert into` query to an `insert or ignore into` query. * * This is only supported by some dialects like SQLite. * * To avoid a footgun, when invoked with the MySQL dialect, this method will * be handled like {@link ignore}. * * See also, {@link orAbort}, {@link orFail}, {@link orReplace}, and {@link orRollback}. * * ### Examples * * ```ts * await db.insertInto('person') * .orIgnore() * .values({ * first_name: 'John', * last_name: 'Doe', * gender: 'female', * }) * .execute() * ``` * * The generated SQL (SQLite): * * ```sql * insert or ignore into "person" ("first_name", "last_name", "gender") values (?, ?, ?) * ``` * * The generated SQL (MySQL): * * ```sql * insert ignore into `person` (`first_name`, `last_name`, `gender`) values (?, ?, ?) * ``` */ orIgnore(): InsertQueryBuilder; /** * Changes an `insert into` query to an `insert or abort into` query. * * This is only supported by some dialects like SQLite. * * See also, {@link orIgnore}, {@link orFail}, {@link orReplace}, and {@link orRollback}. * * ### Examples * * ```ts * await db.insertInto('person') * .orAbort() * .values({ * first_name: 'John', * last_name: 'Doe', * gender: 'female', * }) * .execute() * ``` * * The generated SQL (SQLite): * * ```sql * insert or abort into "person" ("first_name", "last_name", "gender") values (?, ?, ?) * ``` */ orAbort(): InsertQueryBuilder; /** * Changes an `insert into` query to an `insert or fail into` query. * * This is only supported by some dialects like SQLite. * * See also, {@link orIgnore}, {@link orAbort}, {@link orReplace}, and {@link orRollback}. * * ### Examples * * ```ts * await db.insertInto('person') * .orFail() * .values({ * first_name: 'John', * last_name: 'Doe', * gender: 'female', * }) * .execute() * ``` * * The generated SQL (SQLite): * * ```sql * insert or fail into "person" ("first_name", "last_name", "gender") values (?, ?, ?) * ``` */ orFail(): InsertQueryBuilder; /** * Changes an `insert into` query to an `insert or replace into` query. * * This is only supported by some dialects like SQLite. * * You can also use {@link Kysely.replaceInto} to achieve the same result. * * See also, {@link orIgnore}, {@link orAbort}, {@link orFail}, and {@link orRollback}. * * ### Examples * * ```ts * await db.insertInto('person') * .orReplace() * .values({ * first_name: 'John', * last_name: 'Doe', * gender: 'female', * }) * .execute() * ``` * * The generated SQL (SQLite): * * ```sql * insert or replace into "person" ("first_name", "last_name", "gender") values (?, ?, ?) * ``` */ orReplace(): InsertQueryBuilder; /** * Changes an `insert into` query to an `insert or rollback into` query. * * This is only supported by some dialects like SQLite. * * See also, {@link orIgnore}, {@link orAbort}, {@link orFail}, and {@link orReplace}. * * ### Examples * * ```ts * await db.insertInto('person') * .orRollback() * .values({ * first_name: 'John', * last_name: 'Doe', * gender: 'female', * }) * .execute() * ``` * * The generated SQL (SQLite): * * ```sql * insert or rollback into "person" ("first_name", "last_name", "gender") values (?, ?, ?) * ``` */ orRollback(): InsertQueryBuilder; /** * Changes an `insert into` query to an `insert top into` query. * * `top` clause is only supported by some dialects like MS SQL Server. * * ### Examples * * Insert the first 5 rows: * * ```ts * import { sql } from 'kysely' * * await db.insertInto('person') * .top(5) * .columns(['first_name', 'gender']) * .expression( * (eb) => eb.selectFrom('pet').select(['name', sql.lit('other').as('gender')]) * ) * .execute() * ``` * * The generated SQL (MS SQL Server): * * ```sql * insert top(5) into "person" ("first_name", "gender") select "name", 'other' as "gender" from "pet" * ``` * * Insert the first 50 percent of rows: * * ```ts * import { sql } from 'kysely' * * await db.insertInto('person') * .top(50, 'percent') * .columns(['first_name', 'gender']) * .expression( * (eb) => eb.selectFrom('pet').select(['name', sql.lit('other').as('gender')]) * ) * .execute() * ``` * * The generated SQL (MS SQL Server): * * ```sql * insert top(50) percent into "person" ("first_name", "gender") select "name", 'other' as "gender" from "pet" * ``` */ top(expression: number | bigint, modifiers?: 'percent'): InsertQueryBuilder; /** * Adds an `on conflict` clause to the query. * * `on conflict` is only supported by some dialects like PostgreSQL and SQLite. On MySQL * you can use {@link ignore} and {@link onDuplicateKeyUpdate} to achieve similar results. * * ### Examples * * ```ts * await db * .insertInto('pet') * .values({ * name: 'Catto', * species: 'cat', * owner_id: 3, * }) * .onConflict((oc) => oc * .column('name') * .doUpdateSet({ species: 'hamster' }) * ) * .execute() * ``` * * The generated SQL (PostgreSQL): * * ```sql * insert into "pet" ("name", "species", "owner_id") * values ($1, $2, $3) * on conflict ("name") * do update set "species" = $4 * ``` * * You can provide the name of the constraint instead of a column name: * * ```ts * await db * .insertInto('pet') * .values({ * name: 'Catto', * species: 'cat', * owner_id: 3, * }) * .onConflict((oc) => oc * .constraint('pet_name_key') * .doUpdateSet({ species: 'hamster' }) * ) * .execute() * ``` * * The generated SQL (PostgreSQL): * * ```sql * insert into "pet" ("name", "species", "owner_id") * values ($1, $2, $3) * on conflict on constraint "pet_name_key" * do update set "species" = $4 * ``` * * You can also specify an expression as the conflict target in case * the unique index is an expression index: * * ```ts * import { sql } from 'kysely' * * await db * .insertInto('pet') * .values({ * name: 'Catto', * species: 'cat', * owner_id: 3, * }) * .onConflict((oc) => oc * .expression(sql`lower(name)`) * .doUpdateSet({ species: 'hamster' }) * ) * .execute() * ``` * * The generated SQL (PostgreSQL): * * ```sql * insert into "pet" ("name", "species", "owner_id") * values ($1, $2, $3) * on conflict (lower(name)) * do update set "species" = $4 * ``` * * You can add a filter for the update statement like this: * * ```ts * await db * .insertInto('pet') * .values({ * name: 'Catto', * species: 'cat', * owner_id: 3, * }) * .onConflict((oc) => oc * .column('name') * .doUpdateSet({ species: 'hamster' }) * .where('excluded.name', '!=', 'Catto') * ) * .execute() * ``` * * The generated SQL (PostgreSQL): * * ```sql * insert into "pet" ("name", "species", "owner_id") * values ($1, $2, $3) * on conflict ("name") * do update set "species" = $4 * where "excluded"."name" != $5 * ``` * * You can create an `on conflict do nothing` clauses like this: * * ```ts * await db * .insertInto('pet') * .values({ * name: 'Catto', * species: 'cat', * owner_id: 3, * }) * .onConflict((oc) => oc * .column('name') * .doNothing() * ) * .execute() * ``` * * The generated SQL (PostgreSQL): * * ```sql * insert into "pet" ("name", "species", "owner_id") * values ($1, $2, $3) * on conflict ("name") do nothing * ``` * * You can refer to the columns of the virtual `excluded` table * in a type-safe way using a callback and the `ref` method of * `ExpressionBuilder`: * * ```ts * await db.insertInto('person') * .values({ * id: 1, * first_name: 'John', * last_name: 'Doe', * gender: 'male', * }) * .onConflict(oc => oc * .column('id') * .doUpdateSet({ * first_name: (eb) => eb.ref('excluded.first_name'), * last_name: (eb) => eb.ref('excluded.last_name') * }) * ) * .execute() * ``` * * The generated SQL (PostgreSQL): * * ```sql * insert into "person" ("id", "first_name", "last_name", "gender") * values ($1, $2, $3, $4) * on conflict ("id") * do update set * "first_name" = "excluded"."first_name", * "last_name" = "excluded"."last_name" * ``` */ onConflict(callback: (builder: OnConflictBuilder) => OnConflictUpdateBuilder, OnConflictTables> | OnConflictDoNothingBuilder): InsertQueryBuilder; /** * Adds `on duplicate key update` to the query. * * If you specify `on duplicate key update`, and a row is inserted that would cause * a duplicate value in a unique index or primary key, an update of the old row occurs. * * This is only implemented by some dialects like MySQL. On most dialects you should * use {@link onConflict} instead. * * ### Examples * * ```ts * await db * .insertInto('person') * .values({ * id: 1, * first_name: 'John', * last_name: 'Doe', * gender: 'male', * }) * .onDuplicateKeyUpdate({ updated_at: new Date().toISOString() }) * .execute() * ``` * * The generated SQL (MySQL): * * ```sql * insert into `person` (`id`, `first_name`, `last_name`, `gender`) * values (?, ?, ?, ?) * on duplicate key update `updated_at` = ? * ``` */ onDuplicateKeyUpdate(update: UpdateObjectExpression): InsertQueryBuilder; /** * Allows you to return data from modified rows. * * On supported databases like PostgreSQL, this method can be chained to * `insert`, `update`, `delete` and `merge` queries to return data. * * Also see the {@link returningAll} method. * * ### Examples * * Return one column: * * ```ts * const { id } = await db * .insertInto('person') * .values({ * first_name: 'Jennifer', * last_name: 'Aniston' * }) * .returning('id') * .executeTakeFirstOrThrow() * ``` * * Return multiple columns: * * ```ts * const { id, last_name } = await db * .insertInto('person') * .values({ * first_name: 'Jennifer', * last_name: 'Aniston' * }) * .returning(['id', 'last_name']) * .executeTakeFirstOrThrow() * ``` * * Return arbitrary expressions: * * ```ts * import { sql } from 'kysely' * * const { id, full_name, first_pet_id } = await db * .insertInto('person') * .values({ * first_name: 'Jennifer', * last_name: 'Aniston' * }) * .returning((eb) => [ * 'id as id', * sql`concat(first_name, ' ', last_name)`.as('full_name'), * eb.selectFrom('pet').select('pet.id').limit(1).as('first_pet_id') * ]) * .executeTakeFirstOrThrow() * ``` */ returning>(selections: ReadonlyArray): InsertQueryBuilder>; returning>(callback: CB): InsertQueryBuilder>; returning>(selection: SE): InsertQueryBuilder>; /** * Adds a `returning *` to an insert/update/delete/merge query on databases * that support `returning` such as PostgreSQL. * * Also see the {@link returning} method. */ returningAll(): InsertQueryBuilder>; /** * Allows you to return data from modified rows. * * On supported databases like MS SQL Server (MSSQL), this method can be chained * to `insert`, `update`, `delete` and `merge` queries to return data. * * Also see the {@link outputAll} method. * * ### Examples * * Return one column: * * ```ts * const { id } = await db * .insertInto('person') * .output('inserted.id') * .values({ * first_name: 'Jennifer', * last_name: 'Aniston', * gender: 'female', * }) * .executeTakeFirstOrThrow() * ``` * * The generated SQL (MSSQL): * * ```sql * insert into "person" ("first_name", "last_name", "gender") * output "inserted"."id" * values (@1, @2, @3) * ``` * * Return multiple columns: * * ```ts * const { old_first_name, old_last_name, new_first_name, new_last_name } = await db * .updateTable('person') * .set({ first_name: 'John', last_name: 'Doe' }) * .output([ * 'deleted.first_name as old_first_name', * 'deleted.last_name as old_last_name', * 'inserted.first_name as new_first_name', * 'inserted.last_name as new_last_name', * ]) * .where('created_at', '<', new Date()) * .executeTakeFirstOrThrow() * ``` * * The generated SQL (MSSQL): * * ```sql * update "person" * set "first_name" = @1, "last_name" = @2 * output "deleted"."first_name" as "old_first_name", * "deleted"."last_name" as "old_last_name", * "inserted"."first_name" as "new_first_name", * "inserted"."last_name" as "new_last_name" * where "created_at" < @3 * ``` * * Return arbitrary expressions: * * ```ts * import { sql } from 'kysely' * * const { full_name } = await db * .deleteFrom('person') * .output((eb) => sql`concat(${eb.ref('deleted.first_name')}, ' ', ${eb.ref('deleted.last_name')})`.as('full_name')) * .where('created_at', '<', new Date()) * .executeTakeFirstOrThrow() * ``` * * The generated SQL (MSSQL): * * ```sql * delete from "person" * output concat("deleted"."first_name", ' ', "deleted"."last_name") as "full_name" * where "created_at" < @1 * ``` * * Return the action performed on the row: * * ```ts * await db * .mergeInto('person') * .using('pet', 'pet.owner_id', 'person.id') * .whenMatched() * .thenDelete() * .whenNotMatched() * .thenInsertValues({ * first_name: 'John', * last_name: 'Doe', * gender: 'male' * }) * .output([ * 'inserted.id as inserted_id', * 'deleted.id as deleted_id', * ]) * .execute() * ``` * * The generated SQL (MSSQL): * * ```sql * merge into "person" * using "pet" on "pet"."owner_id" = "person"."id" * when matched then delete * when not matched then * insert ("first_name", "last_name", "gender") * values (@1, @2, @3) * output "inserted"."id" as "inserted_id", "deleted"."id" as "deleted_id" * ``` * */ output>(selections: readonly OE[]): InsertQueryBuilder>>; output>(callback: CB): InsertQueryBuilder>>; output>(selection: OE): InsertQueryBuilder>>; /** * Adds an `output {prefix}.*` to an `insert`/`update`/`delete`/`merge` query on databases * that support `output` such as MS SQL Server (MSSQL). * * Also see the {@link output} method. */ outputAll(table: 'inserted'): InsertQueryBuilder>; /** * Clears all `returning` clauses from the query. * * ### Examples * * ```ts * await db.insertInto('person') * .values({ first_name: 'James', last_name: 'Smith', gender: 'male' }) * .returning(['first_name']) * .clearReturning() * .execute() * ``` * * The generated SQL(PostgreSQL): * * ```sql * insert into "person" ("first_name", "last_name", "gender") values ($1, $2, $3) * ``` */ clearReturning(): InsertQueryBuilder; /** * Simply calls the provided function passing `this` as the only argument. `$call` returns * what the provided function returns. * * If you want to conditionally call a method on `this`, see * the {@link $if} method. * * ### Examples * * The next example uses a helper function `log` to log a query: * * ```ts * import type { Compilable } from 'kysely' * * function log(qb: T): T { * console.log(qb.compile()) * return qb * } * * await db.insertInto('person') * .values({ first_name: 'John', last_name: 'Doe', gender: 'male' }) * .$call(log) * .execute() * ``` */ $call(func: (qb: this) => T): T; /** * Call `func(this)` if `condition` is true. * * This method is especially handy with optional selects. Any `returning` or `returningAll` * method calls add columns as optional fields to the output type when called inside * the `func` callback. This is because we can't know if those selections were actually * made before running the code. * * You can also call any other methods inside the callback. * * ### Examples * * ```ts * import type { NewPerson } from 'type-editor' // imaginary module * * async function insertPerson(values: NewPerson, returnLastName: boolean) { * return await db * .insertInto('person') * .values(values) * .returning(['id', 'first_name']) * .$if(returnLastName, (qb) => qb.returning('last_name')) * .executeTakeFirstOrThrow() * } * ``` * * Any selections added inside the `if` callback will be added as optional fields to the * output type since we can't know if the selections were actually made before running * the code. In the example above the return type of the `insertPerson` function is: * * ```ts * Promise<{ * id: number * first_name: string * last_name?: string * }> * ``` */ $if(condition: boolean, func: (qb: this) => InsertQueryBuilder): O2 extends InsertResult ? InsertQueryBuilder : O2 extends O & infer E ? InsertQueryBuilder> : InsertQueryBuilder>; /** * Change the output type of the query. * * This method call doesn't change the SQL in any way. This methods simply * returns a copy of this `InsertQueryBuilder` with a new output type. */ $castTo(): InsertQueryBuilder; /** * Narrows (parts of) the output type of the query. * * Kysely tries to be as type-safe as possible, but in some cases we have to make * compromises for better maintainability and compilation performance. At present, * Kysely doesn't narrow the output type of the query based on {@link values} input * when using {@link returning} or {@link returningAll}. * * This utility method is very useful for these situations, as it removes unncessary * runtime assertion/guard code. Its input type is limited to the output type * of the query, so you can't add a column that doesn't exist, or change a column's * type to something that doesn't exist in its union type. * * ### Examples * * Turn this code: * * ```ts * import type { Person } from 'type-editor' // imaginary module * * const person = await db.insertInto('person') * .values({ * first_name: 'John', * last_name: 'Doe', * gender: 'male', * nullable_column: 'hell yeah!' * }) * .returningAll() * .executeTakeFirstOrThrow() * * if (isWithNoNullValue(person)) { * functionThatExpectsPersonWithNonNullValue(person) * } * * function isWithNoNullValue(person: Person): person is Person & { nullable_column: string } { * return person.nullable_column != null * } * ``` * * Into this: * * ```ts * import type { NotNull } from 'kysely' * * const person = await db.insertInto('person') * .values({ * first_name: 'John', * last_name: 'Doe', * gender: 'male', * nullable_column: 'hell yeah!' * }) * .returningAll() * .$narrowType<{ nullable_column: NotNull }>() * .executeTakeFirstOrThrow() * * functionThatExpectsPersonWithNonNullValue(person) * ``` */ $narrowType(): InsertQueryBuilder>; /** * Asserts that query's output row type equals the given type `T`. * * This method can be used to simplify excessively complex types to make TypeScript happy * and much faster. * * Kysely uses complex type magic to achieve its type safety. This complexity is sometimes too much * for TypeScript and you get errors like this: * * ``` * error TS2589: Type instantiation is excessively deep and possibly infinite. * ``` * * In these case you can often use this method to help TypeScript a little bit. When you use this * method to assert the output type of a query, Kysely can drop the complex output type that * consists of multiple nested helper types and replace it with the simple asserted type. * * Using this method doesn't reduce type safety at all. You have to pass in a type that is * structurally equal to the current type. * * ### Examples * * ```ts * import type { NewPerson, NewPet, Species } from 'type-editor' // imaginary module * * async function insertPersonAndPet(person: NewPerson, pet: Omit) { * return await db * .with('new_person', (qb) => qb * .insertInto('person') * .values(person) * .returning('id') * .$assertType<{ id: number }>() * ) * .with('new_pet', (qb) => qb * .insertInto('pet') * .values((eb) => ({ * owner_id: eb.selectFrom('new_person').select('id'), * ...pet * })) * .returning(['name as pet_name', 'species']) * .$assertType<{ pet_name: string, species: Species }>() * ) * .selectFrom(['new_person', 'new_pet']) * .selectAll() * .executeTakeFirstOrThrow() * } * ``` */ $assertType(): O extends T ? InsertQueryBuilder : KyselyTypeError<`$assertType() call failed: The type passed in is not equal to the output type of the query.`>; /** * Returns a copy of this InsertQueryBuilder instance with the given plugin installed. */ withPlugin(plugin: KyselyPlugin): InsertQueryBuilder; toOperationNode(): InsertQueryNode; compile(): CompiledQuery; /** * Executes the query and returns an array of rows. * * Also see the {@link executeTakeFirst} and {@link executeTakeFirstOrThrow} methods. */ execute(): Promise[]>; /** * Executes the query and returns the first result or undefined if * the query returned no result. */ executeTakeFirst(): Promise>; /** * Executes the query and returns the first result or throws if * the query returned no result. * * By default an instance of {@link NoResultError} is thrown, but you can * provide a custom error class, or callback as the only argument to throw a different * error. */ executeTakeFirstOrThrow(errorConstructor?: NoResultErrorConstructor | ((node: QueryNode) => Error)): Promise>; /** * Executes the query and streams the rows. * * The optional argument `chunkSize` defines how many rows to fetch from the database * at a time. It only affects some dialects like PostgreSQL that support it. * * ### Examples * * ```ts * const stream = db * .selectFrom('person') * .select(['first_name', 'last_name']) * .where('gender', '=', 'other') * .stream() * * for await (const person of stream) { * console.log(person.first_name) * * if (person.last_name === 'Something') { * // Breaking or returning before the stream has ended will release * // the database connection and invalidate the stream. * break * } * } * ``` */ stream(chunkSize?: number): AsyncIterableIterator; /** * Executes query with `explain` statement before the main query. * * ```ts * const explained = await db * .selectFrom('person') * .where('gender', '=', 'female') * .selectAll() * .explain('json') * ``` * * The generated SQL (MySQL): * * ```sql * explain format=json select * from `person` where `gender` = ? * ``` * * You can also execute `explain analyze` statements. * * ```ts * import { sql } from 'kysely' * * const explained = await db * .selectFrom('person') * .where('gender', '=', 'female') * .selectAll() * .explain('json', sql`analyze`) * ``` * * The generated SQL (PostgreSQL): * * ```sql * explain (analyze, format json) select * from "person" where "gender" = $1 * ``` */ explain = Record>(format?: ExplainFormat, options?: Expression): Promise; } export interface InsertQueryBuilderProps { readonly queryId: QueryId; readonly queryNode: InsertQueryNode; readonly executor: QueryExecutor; }