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datafusion-sqlparse/src/parser/mod.rs

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// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
//! SQL Parser
#[cfg(not(feature = "std"))]
use alloc::{
boxed::Box,
format,
string::{String, ToString},
vec,
vec::Vec,
};
use core::{
fmt::{self, Display},
str::FromStr,
};
use log::debug;
use recursion::RecursionCounter;
use IsLateral::*;
use IsOptional::*;
use crate::ast::helpers::stmt_create_table::{CreateTableBuilder, CreateTableConfiguration};
use crate::ast::*;
use crate::dialect::*;
use crate::keywords::{Keyword, ALL_KEYWORDS};
use crate::tokenizer::*;
mod alter;
#[derive(Debug, Clone, PartialEq, Eq)]
pub enum ParserError {
TokenizerError(String),
ParserError(String),
RecursionLimitExceeded,
}
// avoid clippy type_complexity warnings
type ParsedAction = (Keyword, Option<Vec<Ident>>);
// Use `Parser::expected` instead, if possible
macro_rules! parser_err {
($MSG:expr, $loc:expr) => {
Err(ParserError::ParserError(format!("{}{}", $MSG, $loc)))
};
}
// Returns a successful result if the optional expression is some
macro_rules! return_ok_if_some {
($e:expr) => {{
if let Some(v) = $e {
return Ok(v);
}
}};
}
#[cfg(feature = "std")]
/// Implementation [`RecursionCounter`] if std is available
mod recursion {
use std::cell::Cell;
use std::rc::Rc;
use super::ParserError;
/// Tracks remaining recursion depth. This value is decremented on
/// each call to [`RecursionCounter::try_decrease()`], when it reaches 0 an error will
/// be returned.
///
/// Note: Uses an [`std::rc::Rc`] and [`std::cell::Cell`] in order to satisfy the Rust
/// borrow checker so the automatic [`DepthGuard`] decrement a
/// reference to the counter.
pub(crate) struct RecursionCounter {
remaining_depth: Rc<Cell<usize>>,
}
impl RecursionCounter {
/// Creates a [`RecursionCounter`] with the specified maximum
/// depth
pub fn new(remaining_depth: usize) -> Self {
Self {
remaining_depth: Rc::new(remaining_depth.into()),
}
}
/// Decreases the remaining depth by 1.
///
/// Returns [`Err`] if the remaining depth falls to 0.
///
/// Returns a [`DepthGuard`] which will adds 1 to the
/// remaining depth upon drop;
pub fn try_decrease(&self) -> Result<DepthGuard, ParserError> {
let old_value = self.remaining_depth.get();
// ran out of space
if old_value == 0 {
Err(ParserError::RecursionLimitExceeded)
} else {
self.remaining_depth.set(old_value - 1);
Ok(DepthGuard::new(Rc::clone(&self.remaining_depth)))
}
}
}
/// Guard that increases the remaining depth by 1 on drop
pub struct DepthGuard {
remaining_depth: Rc<Cell<usize>>,
}
impl DepthGuard {
fn new(remaining_depth: Rc<Cell<usize>>) -> Self {
Self { remaining_depth }
}
}
impl Drop for DepthGuard {
fn drop(&mut self) {
let old_value = self.remaining_depth.get();
self.remaining_depth.set(old_value + 1);
}
}
}
#[cfg(not(feature = "std"))]
mod recursion {
/// Implementation [`RecursionCounter`] if std is NOT available (and does not
/// guard against stack overflow).
///
/// Has the same API as the std [`RecursionCounter`] implementation
/// but does not actually limit stack depth.
pub(crate) struct RecursionCounter {}
impl RecursionCounter {
pub fn new(_remaining_depth: usize) -> Self {
Self {}
}
pub fn try_decrease(&self) -> Result<DepthGuard, super::ParserError> {
Ok(DepthGuard {})
}
}
pub struct DepthGuard {}
}
#[derive(PartialEq, Eq)]
pub enum IsOptional {
Optional,
Mandatory,
}
pub enum IsLateral {
Lateral,
NotLateral,
}
pub enum WildcardExpr {
Expr(Expr),
QualifiedWildcard(ObjectName),
Wildcard,
}
impl From<TokenizerError> for ParserError {
fn from(e: TokenizerError) -> Self {
ParserError::TokenizerError(e.to_string())
}
}
impl fmt::Display for ParserError {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
write!(
f,
"sql parser error: {}",
match self {
ParserError::TokenizerError(s) => s,
ParserError::ParserError(s) => s,
ParserError::RecursionLimitExceeded => "recursion limit exceeded",
}
)
}
}
#[cfg(feature = "std")]
impl std::error::Error for ParserError {}
// By default, allow expressions up to this deep before erroring
const DEFAULT_REMAINING_DEPTH: usize = 50;
/// Composite types declarations using angle brackets syntax can be arbitrary
/// nested such that the following declaration is possible:
/// `ARRAY<ARRAY<INT>>`
/// But the tokenizer recognizes the `>>` as a ShiftRight token.
/// We work around that limitation when parsing a data type by accepting
/// either a `>` or `>>` token in such cases, remembering which variant we
/// matched.
/// In the latter case having matched a `>>`, the parent type will not look to
/// match its closing `>` as a result since that will have taken place at the
/// child type.
///
/// See [Parser::parse_data_type] for details
struct MatchedTrailingBracket(bool);
impl From<bool> for MatchedTrailingBracket {
fn from(value: bool) -> Self {
Self(value)
}
}
/// Options that control how the [`Parser`] parses SQL text
#[derive(Debug, Clone, PartialEq, Eq)]
pub struct ParserOptions {
pub trailing_commas: bool,
/// Controls how literal values are unescaped. See
/// [`Tokenizer::with_unescape`] for more details.
pub unescape: bool,
}
impl Default for ParserOptions {
fn default() -> Self {
Self {
trailing_commas: false,
unescape: true,
}
}
}
impl ParserOptions {
/// Create a new [`ParserOptions`]
pub fn new() -> Self {
Default::default()
}
/// Set if trailing commas are allowed.
///
/// If this option is `false` (the default), the following SQL will
/// not parse. If the option is `true`, the SQL will parse.
///
/// ```sql
/// SELECT
/// foo,
/// bar,
/// FROM baz
/// ```
pub fn with_trailing_commas(mut self, trailing_commas: bool) -> Self {
self.trailing_commas = trailing_commas;
self
}
/// Set if literal values are unescaped. Defaults to true. See
/// [`Tokenizer::with_unescape`] for more details.
pub fn with_unescape(mut self, unescape: bool) -> Self {
self.unescape = unescape;
self
}
}
#[derive(Copy, Clone)]
enum ParserState {
/// The default state of the parser.
Normal,
/// The state when parsing a CONNECT BY expression. This allows parsing
/// PRIOR expressions while still allowing prior as an identifier name
/// in other contexts.
ConnectBy,
}
pub struct Parser<'a> {
tokens: Vec<TokenWithLocation>,
/// The index of the first unprocessed token in [`Parser::tokens`].
index: usize,
/// The current state of the parser.
state: ParserState,
/// The current dialect to use.
dialect: &'a dyn Dialect,
/// Additional options that allow you to mix & match behavior
/// otherwise constrained to certain dialects (e.g. trailing
/// commas) and/or format of parse (e.g. unescaping).
options: ParserOptions,
/// Ensure the stack does not overflow by limiting recursion depth.
recursion_counter: RecursionCounter,
}
impl<'a> Parser<'a> {
/// Create a parser for a [`Dialect`]
///
/// See also [`Parser::parse_sql`]
///
/// Example:
/// ```
/// # use sqlparser::{parser::{Parser, ParserError}, dialect::GenericDialect};
/// # fn main() -> Result<(), ParserError> {
/// let dialect = GenericDialect{};
/// let statements = Parser::new(&dialect)
/// .try_with_sql("SELECT * FROM foo")?
/// .parse_statements()?;
/// # Ok(())
/// # }
/// ```
pub fn new(dialect: &'a dyn Dialect) -> Self {
Self {
tokens: vec![],
index: 0,
state: ParserState::Normal,
dialect,
recursion_counter: RecursionCounter::new(DEFAULT_REMAINING_DEPTH),
options: ParserOptions::new().with_trailing_commas(dialect.supports_trailing_commas()),
}
}
/// Specify the maximum recursion limit while parsing.
///
/// [`Parser`] prevents stack overflows by returning
/// [`ParserError::RecursionLimitExceeded`] if the parser exceeds
/// this depth while processing the query.
///
/// Example:
/// ```
/// # use sqlparser::{parser::{Parser, ParserError}, dialect::GenericDialect};
/// # fn main() -> Result<(), ParserError> {
/// let dialect = GenericDialect{};
/// let result = Parser::new(&dialect)
/// .with_recursion_limit(1)
/// .try_with_sql("SELECT * FROM foo WHERE (a OR (b OR (c OR d)))")?
/// .parse_statements();
/// assert_eq!(result, Err(ParserError::RecursionLimitExceeded));
/// # Ok(())
/// # }
/// ```
pub fn with_recursion_limit(mut self, recursion_limit: usize) -> Self {
self.recursion_counter = RecursionCounter::new(recursion_limit);
self
}
/// Specify additional parser options
///
/// [`Parser`] supports additional options ([`ParserOptions`])
/// that allow you to mix & match behavior otherwise constrained
/// to certain dialects (e.g. trailing commas).
///
/// Example:
/// ```
/// # use sqlparser::{parser::{Parser, ParserError, ParserOptions}, dialect::GenericDialect};
/// # fn main() -> Result<(), ParserError> {
/// let dialect = GenericDialect{};
/// let options = ParserOptions::new()
/// .with_trailing_commas(true)
/// .with_unescape(false);
/// let result = Parser::new(&dialect)
/// .with_options(options)
/// .try_with_sql("SELECT a, b, COUNT(*), FROM foo GROUP BY a, b,")?
/// .parse_statements();
/// assert!(matches!(result, Ok(_)));
/// # Ok(())
/// # }
/// ```
pub fn with_options(mut self, options: ParserOptions) -> Self {
self.options = options;
self
}
/// Reset this parser to parse the specified token stream
pub fn with_tokens_with_locations(mut self, tokens: Vec<TokenWithLocation>) -> Self {
self.tokens = tokens;
self.index = 0;
self
}
/// Reset this parser state to parse the specified tokens
pub fn with_tokens(self, tokens: Vec<Token>) -> Self {
// Put in dummy locations
let tokens_with_locations: Vec<TokenWithLocation> = tokens
.into_iter()
.map(|token| TokenWithLocation {
token,
location: Location { line: 0, column: 0 },
})
.collect();
self.with_tokens_with_locations(tokens_with_locations)
}
/// Tokenize the sql string and sets this [`Parser`]'s state to
/// parse the resulting tokens
///
/// Returns an error if there was an error tokenizing the SQL string.
///
/// See example on [`Parser::new()`] for an example
pub fn try_with_sql(self, sql: &str) -> Result<Self, ParserError> {
debug!("Parsing sql '{}'...", sql);
let tokens = Tokenizer::new(self.dialect, sql)
.with_unescape(self.options.unescape)
.tokenize_with_location()?;
Ok(self.with_tokens_with_locations(tokens))
}
/// Parse potentially multiple statements
///
/// Example
/// ```
/// # use sqlparser::{parser::{Parser, ParserError}, dialect::GenericDialect};
/// # fn main() -> Result<(), ParserError> {
/// let dialect = GenericDialect{};
/// let statements = Parser::new(&dialect)
/// // Parse a SQL string with 2 separate statements
/// .try_with_sql("SELECT * FROM foo; SELECT * FROM bar;")?
/// .parse_statements()?;
/// assert_eq!(statements.len(), 2);
/// # Ok(())
/// # }
/// ```
pub fn parse_statements(&mut self) -> Result<Vec<Statement>, ParserError> {
let mut stmts = Vec::new();
let mut expecting_statement_delimiter = false;
loop {
// ignore empty statements (between successive statement delimiters)
while self.consume_token(&Token::SemiColon) {
expecting_statement_delimiter = false;
}
match self.peek_token().token {
Token::EOF => break,
// end of statement
Token::Word(word) => {
if expecting_statement_delimiter && word.keyword == Keyword::END {
break;
}
}
_ => {}
}
if expecting_statement_delimiter {
return self.expected("end of statement", self.peek_token());
}
let statement = self.parse_statement()?;
stmts.push(statement);
expecting_statement_delimiter = true;
}
Ok(stmts)
}
/// Convenience method to parse a string with one or more SQL
/// statements into produce an Abstract Syntax Tree (AST).
///
/// Example
/// ```
/// # use sqlparser::{parser::{Parser, ParserError}, dialect::GenericDialect};
/// # fn main() -> Result<(), ParserError> {
/// let dialect = GenericDialect{};
/// let statements = Parser::parse_sql(
/// &dialect, "SELECT * FROM foo"
/// )?;
/// assert_eq!(statements.len(), 1);
/// # Ok(())
/// # }
/// ```
pub fn parse_sql(dialect: &dyn Dialect, sql: &str) -> Result<Vec<Statement>, ParserError> {
Parser::new(dialect).try_with_sql(sql)?.parse_statements()
}
/// Parse a single top-level statement (such as SELECT, INSERT, CREATE, etc.),
/// stopping before the statement separator, if any.
pub fn parse_statement(&mut self) -> Result<Statement, ParserError> {
let _guard = self.recursion_counter.try_decrease()?;
// allow the dialect to override statement parsing
if let Some(statement) = self.dialect.parse_statement(self) {
return statement;
}
let next_token = self.next_token();
match &next_token.token {
Token::Word(w) => match w.keyword {
Keyword::KILL => Ok(self.parse_kill()?),
Keyword::FLUSH => Ok(self.parse_flush()?),
Keyword::DESC => Ok(self.parse_explain(DescribeAlias::Desc)?),
Keyword::DESCRIBE => Ok(self.parse_explain(DescribeAlias::Describe)?),
Keyword::EXPLAIN => Ok(self.parse_explain(DescribeAlias::Explain)?),
Keyword::ANALYZE => Ok(self.parse_analyze()?),
Keyword::SELECT | Keyword::WITH | Keyword::VALUES => {
self.prev_token();
Ok(Statement::Query(self.parse_boxed_query()?))
}
Keyword::TRUNCATE => Ok(self.parse_truncate()?),
Keyword::ATTACH => {
if dialect_of!(self is DuckDbDialect) {
Ok(self.parse_attach_duckdb_database()?)
} else {
Ok(self.parse_attach_database()?)
}
}
Keyword::DETACH if dialect_of!(self is DuckDbDialect | GenericDialect) => {
Ok(self.parse_detach_duckdb_database()?)
}
Keyword::MSCK => Ok(self.parse_msck()?),
Keyword::CREATE => Ok(self.parse_create()?),
Keyword::CACHE => Ok(self.parse_cache_table()?),
Keyword::DROP => Ok(self.parse_drop()?),
Keyword::DISCARD => Ok(self.parse_discard()?),
Keyword::DECLARE => Ok(self.parse_declare()?),
Keyword::FETCH => Ok(self.parse_fetch_statement()?),
Keyword::DELETE => Ok(self.parse_delete()?),
Keyword::INSERT => Ok(self.parse_insert()?),
Keyword::REPLACE => Ok(self.parse_replace()?),
Keyword::UNCACHE => Ok(self.parse_uncache_table()?),
Keyword::UPDATE => Ok(self.parse_update()?),
Keyword::ALTER => Ok(self.parse_alter()?),
Keyword::CALL => Ok(self.parse_call()?),
Keyword::COPY => Ok(self.parse_copy()?),
Keyword::CLOSE => Ok(self.parse_close()?),
Keyword::SET => Ok(self.parse_set()?),
Keyword::SHOW => Ok(self.parse_show()?),
Keyword::USE => Ok(self.parse_use()?),
Keyword::GRANT => Ok(self.parse_grant()?),
Keyword::REVOKE => Ok(self.parse_revoke()?),
Keyword::START => Ok(self.parse_start_transaction()?),
// `BEGIN` is a nonstandard but common alias for the
// standard `START TRANSACTION` statement. It is supported
// by at least PostgreSQL and MySQL.
Keyword::BEGIN => Ok(self.parse_begin()?),
// `END` is a nonstandard but common alias for the
// standard `COMMIT TRANSACTION` statement. It is supported
// by PostgreSQL.
Keyword::END => Ok(self.parse_end()?),
Keyword::SAVEPOINT => Ok(self.parse_savepoint()?),
Keyword::RELEASE => Ok(self.parse_release()?),
Keyword::COMMIT => Ok(self.parse_commit()?),
Keyword::ROLLBACK => Ok(self.parse_rollback()?),
Keyword::ASSERT => Ok(self.parse_assert()?),
// `PREPARE`, `EXECUTE` and `DEALLOCATE` are Postgres-specific
// syntaxes. They are used for Postgres prepared statement.
Keyword::DEALLOCATE => Ok(self.parse_deallocate()?),
Keyword::EXECUTE => Ok(self.parse_execute()?),
Keyword::PREPARE => Ok(self.parse_prepare()?),
Keyword::MERGE => Ok(self.parse_merge()?),
// `PRAGMA` is sqlite specific https://www.sqlite.org/pragma.html
Keyword::PRAGMA => Ok(self.parse_pragma()?),
Keyword::UNLOAD => Ok(self.parse_unload()?),
// `INSTALL` is duckdb specific https://duckdb.org/docs/extensions/overview
Keyword::INSTALL if dialect_of!(self is DuckDbDialect | GenericDialect) => {
Ok(self.parse_install()?)
}
// `LOAD` is duckdb specific https://duckdb.org/docs/extensions/overview
Keyword::LOAD if dialect_of!(self is DuckDbDialect | GenericDialect) => {
Ok(self.parse_load()?)
}
// `OPTIMIZE` is clickhouse specific https://clickhouse.tech/docs/en/sql-reference/statements/optimize/
Keyword::OPTIMIZE if dialect_of!(self is ClickHouseDialect | GenericDialect) => {
Ok(self.parse_optimize_table()?)
}
_ => self.expected("an SQL statement", next_token),
},
Token::LParen => {
self.prev_token();
Ok(Statement::Query(self.parse_boxed_query()?))
}
_ => self.expected("an SQL statement", next_token),
}
}
pub fn parse_flush(&mut self) -> Result<Statement, ParserError> {
let mut channel = None;
let mut tables: Vec<ObjectName> = vec![];
let mut read_lock = false;
let mut export = false;
if !dialect_of!(self is MySqlDialect | GenericDialect) {
return parser_err!("Unsupported statement FLUSH", self.peek_token().location);
}
let location = if self.parse_keyword(Keyword::NO_WRITE_TO_BINLOG) {
Some(FlushLocation::NoWriteToBinlog)
} else if self.parse_keyword(Keyword::LOCAL) {
Some(FlushLocation::Local)
} else {
None
};
let object_type = if self.parse_keywords(&[Keyword::BINARY, Keyword::LOGS]) {
FlushType::BinaryLogs
} else if self.parse_keywords(&[Keyword::ENGINE, Keyword::LOGS]) {
FlushType::EngineLogs
} else if self.parse_keywords(&[Keyword::ERROR, Keyword::LOGS]) {
FlushType::ErrorLogs
} else if self.parse_keywords(&[Keyword::GENERAL, Keyword::LOGS]) {
FlushType::GeneralLogs
} else if self.parse_keywords(&[Keyword::HOSTS]) {
FlushType::Hosts
} else if self.parse_keyword(Keyword::PRIVILEGES) {
FlushType::Privileges
} else if self.parse_keyword(Keyword::OPTIMIZER_COSTS) {
FlushType::OptimizerCosts
} else if self.parse_keywords(&[Keyword::RELAY, Keyword::LOGS]) {
if self.parse_keywords(&[Keyword::FOR, Keyword::CHANNEL]) {
channel = Some(self.parse_object_name(false).unwrap().to_string());
}
FlushType::RelayLogs
} else if self.parse_keywords(&[Keyword::SLOW, Keyword::LOGS]) {
FlushType::SlowLogs
} else if self.parse_keyword(Keyword::STATUS) {
FlushType::Status
} else if self.parse_keyword(Keyword::USER_RESOURCES) {
FlushType::UserResources
} else if self.parse_keywords(&[Keyword::LOGS]) {
FlushType::Logs
} else if self.parse_keywords(&[Keyword::TABLES]) {
loop {
let next_token = self.next_token();
match &next_token.token {
Token::Word(w) => match w.keyword {
Keyword::WITH => {
read_lock = self.parse_keywords(&[Keyword::READ, Keyword::LOCK]);
}
Keyword::FOR => {
export = self.parse_keyword(Keyword::EXPORT);
}
Keyword::NoKeyword => {
self.prev_token();
tables = self.parse_comma_separated(|p| p.parse_object_name(false))?;
}
_ => {}
},
_ => {
break;
}
}
}
FlushType::Tables
} else {
return self.expected(
"BINARY LOGS, ENGINE LOGS, ERROR LOGS, GENERAL LOGS, HOSTS, LOGS, PRIVILEGES, OPTIMIZER_COSTS,\
RELAY LOGS [FOR CHANNEL channel], SLOW LOGS, STATUS, USER_RESOURCES",
self.peek_token(),
);
};
Ok(Statement::Flush {
object_type,
location,
channel,
read_lock,
export,
tables,
})
}
pub fn parse_msck(&mut self) -> Result<Statement, ParserError> {
let repair = self.parse_keyword(Keyword::REPAIR);
self.expect_keyword(Keyword::TABLE)?;
let table_name = self.parse_object_name(false)?;
let partition_action = self
.maybe_parse(|parser| {
let pa = match parser.parse_one_of_keywords(&[
Keyword::ADD,
Keyword::DROP,
Keyword::SYNC,
]) {
Some(Keyword::ADD) => Some(AddDropSync::ADD),
Some(Keyword::DROP) => Some(AddDropSync::DROP),
Some(Keyword::SYNC) => Some(AddDropSync::SYNC),
_ => None,
};
parser.expect_keyword(Keyword::PARTITIONS)?;
Ok(pa)
})
.unwrap_or_default();
Ok(Statement::Msck {
repair,
table_name,
partition_action,
})
}
pub fn parse_truncate(&mut self) -> Result<Statement, ParserError> {
let table = self.parse_keyword(Keyword::TABLE);
let table_name = self.parse_object_name(false)?;
let mut partitions = None;
if self.parse_keyword(Keyword::PARTITION) {
self.expect_token(&Token::LParen)?;
partitions = Some(self.parse_comma_separated(Parser::parse_expr)?);
self.expect_token(&Token::RParen)?;
}
Ok(Statement::Truncate {
table_name,
partitions,
table,
})
}
pub fn parse_attach_duckdb_database_options(
&mut self,
) -> Result<Vec<AttachDuckDBDatabaseOption>, ParserError> {
if !self.consume_token(&Token::LParen) {
return Ok(vec![]);
}
let mut options = vec![];
loop {
if self.parse_keyword(Keyword::READ_ONLY) {
let boolean = if self.parse_keyword(Keyword::TRUE) {
Some(true)
} else if self.parse_keyword(Keyword::FALSE) {
Some(false)
} else {
None
};
options.push(AttachDuckDBDatabaseOption::ReadOnly(boolean));
} else if self.parse_keyword(Keyword::TYPE) {
let ident = self.parse_identifier(false)?;
options.push(AttachDuckDBDatabaseOption::Type(ident));
} else {
return self.expected("expected one of: ), READ_ONLY, TYPE", self.peek_token());
};
if self.consume_token(&Token::RParen) {
return Ok(options);
} else if self.consume_token(&Token::Comma) {
continue;
} else {
return self.expected("expected one of: ')', ','", self.peek_token());
}
}
}
pub fn parse_attach_duckdb_database(&mut self) -> Result<Statement, ParserError> {
let database = self.parse_keyword(Keyword::DATABASE);
let if_not_exists = self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
let database_path = self.parse_identifier(false)?;
let database_alias = if self.parse_keyword(Keyword::AS) {
Some(self.parse_identifier(false)?)
} else {
None
};
let attach_options = self.parse_attach_duckdb_database_options()?;
Ok(Statement::AttachDuckDBDatabase {
if_not_exists,
database,
database_path,
database_alias,
attach_options,
})
}
pub fn parse_detach_duckdb_database(&mut self) -> Result<Statement, ParserError> {
let database = self.parse_keyword(Keyword::DATABASE);
let if_exists = self.parse_keywords(&[Keyword::IF, Keyword::EXISTS]);
let database_alias = self.parse_identifier(false)?;
Ok(Statement::DetachDuckDBDatabase {
if_exists,
database,
database_alias,
})
}
pub fn parse_attach_database(&mut self) -> Result<Statement, ParserError> {
let database = self.parse_keyword(Keyword::DATABASE);
let database_file_name = self.parse_expr()?;
self.expect_keyword(Keyword::AS)?;
let schema_name = self.parse_identifier(false)?;
Ok(Statement::AttachDatabase {
database,
schema_name,
database_file_name,
})
}
pub fn parse_analyze(&mut self) -> Result<Statement, ParserError> {
self.expect_keyword(Keyword::TABLE)?;
let table_name = self.parse_object_name(false)?;
let mut for_columns = false;
let mut cache_metadata = false;
let mut noscan = false;
let mut partitions = None;
let mut compute_statistics = false;
let mut columns = vec![];
loop {
match self.parse_one_of_keywords(&[
Keyword::PARTITION,
Keyword::FOR,
Keyword::CACHE,
Keyword::NOSCAN,
Keyword::COMPUTE,
]) {
Some(Keyword::PARTITION) => {
self.expect_token(&Token::LParen)?;
partitions = Some(self.parse_comma_separated(Parser::parse_expr)?);
self.expect_token(&Token::RParen)?;
}
Some(Keyword::NOSCAN) => noscan = true,
Some(Keyword::FOR) => {
self.expect_keyword(Keyword::COLUMNS)?;
columns = self
.maybe_parse(|parser| {
parser.parse_comma_separated(|p| p.parse_identifier(false))
})
.unwrap_or_default();
for_columns = true
}
Some(Keyword::CACHE) => {
self.expect_keyword(Keyword::METADATA)?;
cache_metadata = true
}
Some(Keyword::COMPUTE) => {
self.expect_keyword(Keyword::STATISTICS)?;
compute_statistics = true
}
_ => break,
}
}
Ok(Statement::Analyze {
table_name,
for_columns,
columns,
partitions,
cache_metadata,
noscan,
compute_statistics,
})
}
/// Parse a new expression including wildcard & qualified wildcard.
pub fn parse_wildcard_expr(&mut self) -> Result<Expr, ParserError> {
let index = self.index;
let next_token = self.next_token();
match next_token.token {
t @ (Token::Word(_) | Token::SingleQuotedString(_)) => {
if self.peek_token().token == Token::Period {
let mut id_parts: Vec<Ident> = vec![match t {
Token::Word(w) => w.to_ident(),
Token::SingleQuotedString(s) => Ident::with_quote('\'', s),
_ => unreachable!(), // We matched above
}];
while self.consume_token(&Token::Period) {
let next_token = self.next_token();
match next_token.token {
Token::Word(w) => id_parts.push(w.to_ident()),
Token::SingleQuotedString(s) => {
// SQLite has single-quoted identifiers
id_parts.push(Ident::with_quote('\'', s))
}
Token::Mul => {
return Ok(Expr::QualifiedWildcard(ObjectName(id_parts)));
}
_ => {
return self
.expected("an identifier or a '*' after '.'", next_token);
}
}
}
}
}
Token::Mul => {
return Ok(Expr::Wildcard);
}
_ => (),
};
self.index = index;
self.parse_expr()
}
/// Parse a new expression.
pub fn parse_expr(&mut self) -> Result<Expr, ParserError> {
let _guard = self.recursion_counter.try_decrease()?;
self.parse_subexpr(self.dialect.prec_unknown())
}
/// Parse tokens until the precedence changes.
pub fn parse_subexpr(&mut self, precedence: u8) -> Result<Expr, ParserError> {
debug!("parsing expr");
let mut expr = self.parse_prefix()?;
debug!("prefix: {:?}", expr);
loop {
let next_precedence = self.get_next_precedence()?;
debug!("next precedence: {:?}", next_precedence);
if precedence >= next_precedence {
break;
}
expr = self.parse_infix(expr, next_precedence)?;
}
Ok(expr)
}
pub fn parse_interval_expr(&mut self) -> Result<Expr, ParserError> {
let precedence = self.dialect.prec_unknown();
let mut expr = self.parse_prefix()?;
loop {
let next_precedence = self.get_next_interval_precedence()?;
if precedence >= next_precedence {
break;
}
expr = self.parse_infix(expr, next_precedence)?;
}
Ok(expr)
}
/// Get the precedence of the next token, with AND, OR, and XOR.
pub fn get_next_interval_precedence(&self) -> Result<u8, ParserError> {
let token = self.peek_token();
match token.token {
Token::Word(w) if w.keyword == Keyword::AND => Ok(self.dialect.prec_unknown()),
Token::Word(w) if w.keyword == Keyword::OR => Ok(self.dialect.prec_unknown()),
Token::Word(w) if w.keyword == Keyword::XOR => Ok(self.dialect.prec_unknown()),
_ => self.get_next_precedence(),
}
}
pub fn parse_assert(&mut self) -> Result<Statement, ParserError> {
let condition = self.parse_expr()?;
let message = if self.parse_keyword(Keyword::AS) {
Some(self.parse_expr()?)
} else {
None
};
Ok(Statement::Assert { condition, message })
}
pub fn parse_savepoint(&mut self) -> Result<Statement, ParserError> {
let name = self.parse_identifier(false)?;
Ok(Statement::Savepoint { name })
}
pub fn parse_release(&mut self) -> Result<Statement, ParserError> {
let _ = self.parse_keyword(Keyword::SAVEPOINT);
let name = self.parse_identifier(false)?;
Ok(Statement::ReleaseSavepoint { name })
}
/// Parse an expression prefix.
pub fn parse_prefix(&mut self) -> Result<Expr, ParserError> {
// allow the dialect to override prefix parsing
if let Some(prefix) = self.dialect.parse_prefix(self) {
return prefix;
}
// PostgreSQL allows any string literal to be preceded by a type name, indicating that the
// string literal represents a literal of that type. Some examples:
//
// DATE '2020-05-20'
// TIMESTAMP WITH TIME ZONE '2020-05-20 7:43:54'
// BOOL 'true'
//
// The first two are standard SQL, while the latter is a PostgreSQL extension. Complicating
// matters is the fact that INTERVAL string literals may optionally be followed by special
// keywords, e.g.:
//
// INTERVAL '7' DAY
//
// Note also that naively `SELECT date` looks like a syntax error because the `date` type
// name is not followed by a string literal, but in fact in PostgreSQL it is a valid
// expression that should parse as the column name "date".
let loc = self.peek_token().location;
return_ok_if_some!(self.maybe_parse(|parser| {
match parser.parse_data_type()? {
DataType::Interval => parser.parse_interval(),
// PostgreSQL allows almost any identifier to be used as custom data type name,
// and we support that in `parse_data_type()`. But unlike Postgres we don't
// have a list of globally reserved keywords (since they vary across dialects),
// so given `NOT 'a' LIKE 'b'`, we'd accept `NOT` as a possible custom data type
// name, resulting in `NOT 'a'` being recognized as a `TypedString` instead of
// an unary negation `NOT ('a' LIKE 'b')`. To solve this, we don't accept the
// `type 'string'` syntax for the custom data types at all.
DataType::Custom(..) => parser_err!("dummy", loc),
data_type => Ok(Expr::TypedString {
data_type,
value: parser.parse_literal_string()?,
}),
}
}));
let next_token = self.next_token();
let expr = match next_token.token {
Token::Word(w) => match w.keyword {
Keyword::TRUE | Keyword::FALSE | Keyword::NULL => {
self.prev_token();
Ok(Expr::Value(self.parse_value()?))
}
Keyword::CURRENT_CATALOG
| Keyword::CURRENT_USER
| Keyword::SESSION_USER
| Keyword::USER
if dialect_of!(self is PostgreSqlDialect | GenericDialect) =>
{
Ok(Expr::Function(Function {
name: ObjectName(vec![w.to_ident()]),
parameters: FunctionArguments::None,
args: FunctionArguments::None,
null_treatment: None,
filter: None,
over: None,
within_group: vec![],
}))
}
Keyword::CURRENT_TIMESTAMP
| Keyword::CURRENT_TIME
| Keyword::CURRENT_DATE
| Keyword::LOCALTIME
| Keyword::LOCALTIMESTAMP => {
self.parse_time_functions(ObjectName(vec![w.to_ident()]))
}
Keyword::CASE => self.parse_case_expr(),
Keyword::CONVERT => self.parse_convert_expr(),
Keyword::CAST => self.parse_cast_expr(CastKind::Cast),
Keyword::TRY_CAST => self.parse_cast_expr(CastKind::TryCast),
Keyword::SAFE_CAST => self.parse_cast_expr(CastKind::SafeCast),
Keyword::EXISTS
// Support parsing Databricks has a function named `exists`.
if !dialect_of!(self is DatabricksDialect)
|| matches!(
self.peek_nth_token(1).token,
Token::Word(Word {
keyword: Keyword::SELECT | Keyword::WITH,
..
})
) =>
{
self.parse_exists_expr(false)
}
Keyword::EXTRACT => self.parse_extract_expr(),
Keyword::CEIL => self.parse_ceil_floor_expr(true),
Keyword::FLOOR => self.parse_ceil_floor_expr(false),
Keyword::POSITION if self.peek_token().token == Token::LParen => {
self.parse_position_expr(w.to_ident())
}
Keyword::SUBSTRING => self.parse_substring_expr(),
Keyword::OVERLAY => self.parse_overlay_expr(),
Keyword::TRIM => self.parse_trim_expr(),
Keyword::INTERVAL => self.parse_interval(),
// Treat ARRAY[1,2,3] as an array [1,2,3], otherwise try as subquery or a function call
Keyword::ARRAY if self.peek_token() == Token::LBracket => {
self.expect_token(&Token::LBracket)?;
self.parse_array_expr(true)
}
Keyword::ARRAY
if self.peek_token() == Token::LParen
&& !dialect_of!(self is ClickHouseDialect | DatabricksDialect) =>
{
self.expect_token(&Token::LParen)?;
let query = self.parse_boxed_query()?;
self.expect_token(&Token::RParen)?;
Ok(Expr::Function(Function {
name: ObjectName(vec![w.to_ident()]),
parameters: FunctionArguments::None,
args: FunctionArguments::Subquery(query),
filter: None,
null_treatment: None,
over: None,
within_group: vec![],
}))
}
Keyword::NOT => self.parse_not(),
Keyword::MATCH if dialect_of!(self is MySqlDialect | GenericDialect) => {
self.parse_match_against()
}
Keyword::STRUCT if dialect_of!(self is BigQueryDialect | GenericDialect) => {
self.prev_token();
self.parse_bigquery_struct_literal()
}
Keyword::PRIOR if matches!(self.state, ParserState::ConnectBy) => {
let expr = self.parse_subexpr(self.dialect.prec_value(Precedence::PlusMinus))?;
Ok(Expr::Prior(Box::new(expr)))
}
Keyword::MAP if self.peek_token() == Token::LBrace && self.dialect.support_map_literal_syntax() => {
self.parse_duckdb_map_literal()
}
// Here `w` is a word, check if it's a part of a multipart
// identifier, a function call, or a simple identifier:
_ => match self.peek_token().token {
Token::LParen | Token::Period => {
let mut id_parts: Vec<Ident> = vec![w.to_ident()];
let mut ends_with_wildcard = false;
while self.consume_token(&Token::Period) {
let next_token = self.next_token();
match next_token.token {
Token::Word(w) => id_parts.push(w.to_ident()),
Token::Mul => {
// Postgres explicitly allows funcnm(tablenm.*) and the
// function array_agg traverses this control flow
if dialect_of!(self is PostgreSqlDialect) {
ends_with_wildcard = true;
break;
} else {
return self
.expected("an identifier after '.'", next_token);
}
}
Token::SingleQuotedString(s) => {
id_parts.push(Ident::with_quote('\'', s))
}
_ => {
return self
.expected("an identifier or a '*' after '.'", next_token);
}
}
}
if ends_with_wildcard {
Ok(Expr::QualifiedWildcard(ObjectName(id_parts)))
} else if self.consume_token(&Token::LParen) {
if dialect_of!(self is SnowflakeDialect | MsSqlDialect)
&& self.consume_tokens(&[Token::Plus, Token::RParen])
{
Ok(Expr::OuterJoin(Box::new(
match <[Ident; 1]>::try_from(id_parts) {
Ok([ident]) => Expr::Identifier(ident),
Err(parts) => Expr::CompoundIdentifier(parts),
},
)))
} else {
self.prev_token();
self.parse_function(ObjectName(id_parts))
}
} else {
Ok(Expr::CompoundIdentifier(id_parts))
}
}
// string introducer https://dev.mysql.com/doc/refman/8.0/en/charset-introducer.html
Token::SingleQuotedString(_)
| Token::DoubleQuotedString(_)
| Token::HexStringLiteral(_)
if w.value.starts_with('_') =>
{
Ok(Expr::IntroducedString {
introducer: w.value,
value: self.parse_introduced_string_value()?,
})
}
Token::Arrow if self.dialect.supports_lambda_functions() => {
self.expect_token(&Token::Arrow)?;
return Ok(Expr::Lambda(LambdaFunction {
params: OneOrManyWithParens::One(w.to_ident()),
body: Box::new(self.parse_expr()?),
}));
}
_ => Ok(Expr::Identifier(w.to_ident())),
},
}, // End of Token::Word
// array `[1, 2, 3]`
Token::LBracket => self.parse_array_expr(false),
tok @ Token::Minus | tok @ Token::Plus => {
let op = if tok == Token::Plus {
UnaryOperator::Plus
} else {
UnaryOperator::Minus
};
Ok(Expr::UnaryOp {
op,
expr: Box::new(
self.parse_subexpr(self.dialect.prec_value(Precedence::MulDivModOp))?,
),
})
}
tok @ Token::DoubleExclamationMark
| tok @ Token::PGSquareRoot
| tok @ Token::PGCubeRoot
| tok @ Token::AtSign
| tok @ Token::Tilde
if dialect_of!(self is PostgreSqlDialect) =>
{
let op = match tok {
Token::DoubleExclamationMark => UnaryOperator::PGPrefixFactorial,
Token::PGSquareRoot => UnaryOperator::PGSquareRoot,
Token::PGCubeRoot => UnaryOperator::PGCubeRoot,
Token::AtSign => UnaryOperator::PGAbs,
Token::Tilde => UnaryOperator::PGBitwiseNot,
_ => unreachable!(),
};
Ok(Expr::UnaryOp {
op,
expr: Box::new(
self.parse_subexpr(self.dialect.prec_value(Precedence::PlusMinus))?,
),
})
}
Token::EscapedStringLiteral(_) if dialect_of!(self is PostgreSqlDialect | GenericDialect) =>
{
self.prev_token();
Ok(Expr::Value(self.parse_value()?))
}
Token::UnicodeStringLiteral(_) => {
self.prev_token();
Ok(Expr::Value(self.parse_value()?))
}
Token::Number(_, _)
| Token::SingleQuotedString(_)
| Token::DoubleQuotedString(_)
| Token::TripleSingleQuotedString(_)
| Token::TripleDoubleQuotedString(_)
| Token::DollarQuotedString(_)
| Token::SingleQuotedByteStringLiteral(_)
| Token::DoubleQuotedByteStringLiteral(_)
| Token::TripleSingleQuotedByteStringLiteral(_)
| Token::TripleDoubleQuotedByteStringLiteral(_)
| Token::SingleQuotedRawStringLiteral(_)
| Token::DoubleQuotedRawStringLiteral(_)
| Token::TripleSingleQuotedRawStringLiteral(_)
| Token::TripleDoubleQuotedRawStringLiteral(_)
| Token::NationalStringLiteral(_)
| Token::HexStringLiteral(_) => {
self.prev_token();
Ok(Expr::Value(self.parse_value()?))
}
Token::LParen => {
let expr = if let Some(expr) = self.try_parse_expr_sub_query()? {
expr
} else if let Some(lambda) = self.try_parse_lambda() {
return Ok(lambda);
} else {
let exprs = self.parse_comma_separated(Parser::parse_expr)?;
match exprs.len() {
0 => unreachable!(), // parse_comma_separated ensures 1 or more
1 => Expr::Nested(Box::new(exprs.into_iter().next().unwrap())),
_ => Expr::Tuple(exprs),
}
};
self.expect_token(&Token::RParen)?;
if !self.consume_token(&Token::Period) {
Ok(expr)
} else {
let tok = self.next_token();
let key = match tok.token {
Token::Word(word) => word.to_ident(),
_ => {
return parser_err!(
format!("Expected identifier, found: {tok}"),
tok.location
)
}
};
Ok(Expr::CompositeAccess {
expr: Box::new(expr),
key,
})
}
}
Token::Placeholder(_) | Token::Colon | Token::AtSign => {
self.prev_token();
Ok(Expr::Value(self.parse_value()?))
}
Token::LBrace if self.dialect.supports_dictionary_syntax() => {
self.prev_token();
self.parse_duckdb_struct_literal()
}
_ => self.expected("an expression:", next_token),
}?;
if self.parse_keyword(Keyword::COLLATE) {
Ok(Expr::Collate {
expr: Box::new(expr),
collation: self.parse_object_name(false)?,
})
} else {
Ok(expr)
}
}
fn try_parse_expr_sub_query(&mut self) -> Result<Option<Expr>, ParserError> {
if self
.parse_one_of_keywords(&[Keyword::SELECT, Keyword::WITH])
.is_none()
{
return Ok(None);
}
self.prev_token();
Ok(Some(Expr::Subquery(self.parse_boxed_query()?)))
}
fn try_parse_lambda(&mut self) -> Option<Expr> {
if !self.dialect.supports_lambda_functions() {
return None;
}
self.maybe_parse(|p| {
let params = p.parse_comma_separated(|p| p.parse_identifier(false))?;
p.expect_token(&Token::RParen)?;
p.expect_token(&Token::Arrow)?;
let expr = p.parse_expr()?;
Ok(Expr::Lambda(LambdaFunction {
params: OneOrManyWithParens::Many(params),
body: Box::new(expr),
}))
})
}
pub fn parse_function(&mut self, name: ObjectName) -> Result<Expr, ParserError> {
self.expect_token(&Token::LParen)?;
// Snowflake permits a subquery to be passed as an argument without
// an enclosing set of parens if it's the only argument.
if dialect_of!(self is SnowflakeDialect)
&& self
.parse_one_of_keywords(&[Keyword::WITH, Keyword::SELECT])
.is_some()
{
self.prev_token();
let subquery = self.parse_boxed_query()?;
self.expect_token(&Token::RParen)?;
return Ok(Expr::Function(Function {
name,
parameters: FunctionArguments::None,
args: FunctionArguments::Subquery(subquery),
filter: None,
null_treatment: None,
over: None,
within_group: vec![],
}));
}
let mut args = self.parse_function_argument_list()?;
let mut parameters = FunctionArguments::None;
// ClickHouse aggregations support parametric functions like `HISTOGRAM(0.5, 0.6)(x, y)`
// which (0.5, 0.6) is a parameter to the function.
if dialect_of!(self is ClickHouseDialect | GenericDialect)
&& self.consume_token(&Token::LParen)
{
parameters = FunctionArguments::List(args);
args = self.parse_function_argument_list()?;
}
let within_group = if self.parse_keywords(&[Keyword::WITHIN, Keyword::GROUP]) {
self.expect_token(&Token::LParen)?;
self.expect_keywords(&[Keyword::ORDER, Keyword::BY])?;
let order_by = self.parse_comma_separated(Parser::parse_order_by_expr)?;
self.expect_token(&Token::RParen)?;
order_by
} else {
vec![]
};
let filter = if self.dialect.supports_filter_during_aggregation()
&& self.parse_keyword(Keyword::FILTER)
&& self.consume_token(&Token::LParen)
&& self.parse_keyword(Keyword::WHERE)
{
let filter = Some(Box::new(self.parse_expr()?));
self.expect_token(&Token::RParen)?;
filter
} else {
None
};
// Syntax for null treatment shows up either in the args list
// or after the function call, but not both.
let null_treatment = if args
.clauses
.iter()
.all(|clause| !matches!(clause, FunctionArgumentClause::IgnoreOrRespectNulls(_)))
{
self.parse_null_treatment()?
} else {
None
};
let over = if self.parse_keyword(Keyword::OVER) {
if self.consume_token(&Token::LParen) {
let window_spec = self.parse_window_spec()?;
Some(WindowType::WindowSpec(window_spec))
} else {
Some(WindowType::NamedWindow(self.parse_identifier(false)?))
}
} else {
None
};
Ok(Expr::Function(Function {
name,
parameters,
args: FunctionArguments::List(args),
null_treatment,
filter,
over,
within_group,
}))
}
/// Optionally parses a null treatment clause.
fn parse_null_treatment(&mut self) -> Result<Option<NullTreatment>, ParserError> {
match self.parse_one_of_keywords(&[Keyword::RESPECT, Keyword::IGNORE]) {
Some(keyword) => {
self.expect_keyword(Keyword::NULLS)?;
Ok(match keyword {
Keyword::RESPECT => Some(NullTreatment::RespectNulls),
Keyword::IGNORE => Some(NullTreatment::IgnoreNulls),
_ => None,
})
}
None => Ok(None),
}
}
pub fn parse_time_functions(&mut self, name: ObjectName) -> Result<Expr, ParserError> {
let args = if self.consume_token(&Token::LParen) {
FunctionArguments::List(self.parse_function_argument_list()?)
} else {
FunctionArguments::None
};
Ok(Expr::Function(Function {
name,
parameters: FunctionArguments::None,
args,
filter: None,
over: None,
null_treatment: None,
within_group: vec![],
}))
}
pub fn parse_window_frame_units(&mut self) -> Result<WindowFrameUnits, ParserError> {
let next_token = self.next_token();
match &next_token.token {
Token::Word(w) => match w.keyword {
Keyword::ROWS => Ok(WindowFrameUnits::Rows),
Keyword::RANGE => Ok(WindowFrameUnits::Range),
Keyword::GROUPS => Ok(WindowFrameUnits::Groups),
_ => self.expected("ROWS, RANGE, GROUPS", next_token)?,
},
_ => self.expected("ROWS, RANGE, GROUPS", next_token),
}
}
pub fn parse_window_frame(&mut self) -> Result<WindowFrame, ParserError> {
let units = self.parse_window_frame_units()?;
let (start_bound, end_bound) = if self.parse_keyword(Keyword::BETWEEN) {
let start_bound = self.parse_window_frame_bound()?;
self.expect_keyword(Keyword::AND)?;
let end_bound = Some(self.parse_window_frame_bound()?);
(start_bound, end_bound)
} else {
(self.parse_window_frame_bound()?, None)
};
Ok(WindowFrame {
units,
start_bound,
end_bound,
})
}
/// Parse `CURRENT ROW` or `{ <positive number> | UNBOUNDED } { PRECEDING | FOLLOWING }`
pub fn parse_window_frame_bound(&mut self) -> Result<WindowFrameBound, ParserError> {
if self.parse_keywords(&[Keyword::CURRENT, Keyword::ROW]) {
Ok(WindowFrameBound::CurrentRow)
} else {
let rows = if self.parse_keyword(Keyword::UNBOUNDED) {
None
} else {
Some(Box::new(match self.peek_token().token {
Token::SingleQuotedString(_) => self.parse_interval()?,
_ => self.parse_expr()?,
}))
};
if self.parse_keyword(Keyword::PRECEDING) {
Ok(WindowFrameBound::Preceding(rows))
} else if self.parse_keyword(Keyword::FOLLOWING) {
Ok(WindowFrameBound::Following(rows))
} else {
self.expected("PRECEDING or FOLLOWING", self.peek_token())
}
}
}
/// Parse a group by expr. Group by expr can be one of group sets, roll up, cube, or simple expr.
fn parse_group_by_expr(&mut self) -> Result<Expr, ParserError> {
if self.dialect.supports_group_by_expr() {
if self.parse_keywords(&[Keyword::GROUPING, Keyword::SETS]) {
self.expect_token(&Token::LParen)?;
let result = self.parse_comma_separated(|p| p.parse_tuple(false, true))?;
self.expect_token(&Token::RParen)?;
Ok(Expr::GroupingSets(result))
} else if self.parse_keyword(Keyword::CUBE) {
self.expect_token(&Token::LParen)?;
let result = self.parse_comma_separated(|p| p.parse_tuple(true, true))?;
self.expect_token(&Token::RParen)?;
Ok(Expr::Cube(result))
} else if self.parse_keyword(Keyword::ROLLUP) {
self.expect_token(&Token::LParen)?;
let result = self.parse_comma_separated(|p| p.parse_tuple(true, true))?;
self.expect_token(&Token::RParen)?;
Ok(Expr::Rollup(result))
} else if self.consume_tokens(&[Token::LParen, Token::RParen]) {
// PostgreSQL allow to use empty tuple as a group by expression,
// e.g. `GROUP BY (), name`. Please refer to GROUP BY Clause section in
// [PostgreSQL](https://www.postgresql.org/docs/16/sql-select.html)
Ok(Expr::Tuple(vec![]))
} else {
self.parse_expr()
}
} else {
// TODO parse rollup for other dialects
self.parse_expr()
}
}
/// Parse a tuple with `(` and `)`.
/// If `lift_singleton` is true, then a singleton tuple is lifted to a tuple of length 1, otherwise it will fail.
/// If `allow_empty` is true, then an empty tuple is allowed.
fn parse_tuple(
&mut self,
lift_singleton: bool,
allow_empty: bool,
) -> Result<Vec<Expr>, ParserError> {
if lift_singleton {
if self.consume_token(&Token::LParen) {
let result = if allow_empty && self.consume_token(&Token::RParen) {
vec![]
} else {
let result = self.parse_comma_separated(Parser::parse_expr)?;
self.expect_token(&Token::RParen)?;
result
};
Ok(result)
} else {
Ok(vec![self.parse_expr()?])
}
} else {
self.expect_token(&Token::LParen)?;
let result = if allow_empty && self.consume_token(&Token::RParen) {
vec![]
} else {
let result = self.parse_comma_separated(Parser::parse_expr)?;
self.expect_token(&Token::RParen)?;
result
};
Ok(result)
}
}
pub fn parse_case_expr(&mut self) -> Result<Expr, ParserError> {
let mut operand = None;
if !self.parse_keyword(Keyword::WHEN) {
operand = Some(Box::new(self.parse_expr()?));
self.expect_keyword(Keyword::WHEN)?;
}
let mut conditions = vec![];
let mut results = vec![];
loop {
conditions.push(self.parse_expr()?);
self.expect_keyword(Keyword::THEN)?;
results.push(self.parse_expr()?);
if !self.parse_keyword(Keyword::WHEN) {
break;
}
}
let else_result = if self.parse_keyword(Keyword::ELSE) {
Some(Box::new(self.parse_expr()?))
} else {
None
};
self.expect_keyword(Keyword::END)?;
Ok(Expr::Case {
operand,
conditions,
results,
else_result,
})
}
pub fn parse_optional_cast_format(&mut self) -> Result<Option<CastFormat>, ParserError> {
if self.parse_keyword(Keyword::FORMAT) {
let value = self.parse_value()?;
match self.parse_optional_time_zone()? {
Some(tz) => Ok(Some(CastFormat::ValueAtTimeZone(value, tz))),
None => Ok(Some(CastFormat::Value(value))),
}
} else {
Ok(None)
}
}
pub fn parse_optional_time_zone(&mut self) -> Result<Option<Value>, ParserError> {
if self.parse_keywords(&[Keyword::AT, Keyword::TIME, Keyword::ZONE]) {
self.parse_value().map(Some)
} else {
Ok(None)
}
}
/// mssql-like convert function
fn parse_mssql_convert(&mut self) -> Result<Expr, ParserError> {
self.expect_token(&Token::LParen)?;
let data_type = self.parse_data_type()?;
self.expect_token(&Token::Comma)?;
let expr = self.parse_expr()?;
let styles = if self.consume_token(&Token::Comma) {
self.parse_comma_separated(Parser::parse_expr)?
} else {
Default::default()
};
self.expect_token(&Token::RParen)?;
Ok(Expr::Convert {
expr: Box::new(expr),
data_type: Some(data_type),
charset: None,
target_before_value: true,
styles,
})
}
/// Parse a SQL CONVERT function:
/// - `CONVERT('héhé' USING utf8mb4)` (MySQL)
/// - `CONVERT('héhé', CHAR CHARACTER SET utf8mb4)` (MySQL)
/// - `CONVERT(DECIMAL(10, 5), 42)` (MSSQL) - the type comes first
pub fn parse_convert_expr(&mut self) -> Result<Expr, ParserError> {
if self.dialect.convert_type_before_value() {
return self.parse_mssql_convert();
}
self.expect_token(&Token::LParen)?;
let expr = self.parse_expr()?;
if self.parse_keyword(Keyword::USING) {
let charset = self.parse_object_name(false)?;
self.expect_token(&Token::RParen)?;
return Ok(Expr::Convert {
expr: Box::new(expr),
data_type: None,
charset: Some(charset),
target_before_value: false,
styles: vec![],
});
}
self.expect_token(&Token::Comma)?;
let data_type = self.parse_data_type()?;
let charset = if self.parse_keywords(&[Keyword::CHARACTER, Keyword::SET]) {
Some(self.parse_object_name(false)?)
} else {
None
};
self.expect_token(&Token::RParen)?;
Ok(Expr::Convert {
expr: Box::new(expr),
data_type: Some(data_type),
charset,
target_before_value: false,
styles: vec![],
})
}
/// Parse a SQL CAST function e.g. `CAST(expr AS FLOAT)`
pub fn parse_cast_expr(&mut self, kind: CastKind) -> Result<Expr, ParserError> {
self.expect_token(&Token::LParen)?;
let expr = self.parse_expr()?;
self.expect_keyword(Keyword::AS)?;
let data_type = self.parse_data_type()?;
let format = self.parse_optional_cast_format()?;
self.expect_token(&Token::RParen)?;
Ok(Expr::Cast {
kind,
expr: Box::new(expr),
data_type,
format,
})
}
/// Parse a SQL EXISTS expression e.g. `WHERE EXISTS(SELECT ...)`.
pub fn parse_exists_expr(&mut self, negated: bool) -> Result<Expr, ParserError> {
self.expect_token(&Token::LParen)?;
let exists_node = Expr::Exists {
negated,
subquery: self.parse_boxed_query()?,
};
self.expect_token(&Token::RParen)?;
Ok(exists_node)
}
pub fn parse_extract_expr(&mut self) -> Result<Expr, ParserError> {
self.expect_token(&Token::LParen)?;
let field = self.parse_date_time_field()?;
let syntax = if self.parse_keyword(Keyword::FROM) {
ExtractSyntax::From
} else if self.consume_token(&Token::Comma)
&& dialect_of!(self is SnowflakeDialect | GenericDialect)
{
ExtractSyntax::Comma
} else {
return Err(ParserError::ParserError(
"Expected 'FROM' or ','".to_string(),
));
};
let expr = self.parse_expr()?;
self.expect_token(&Token::RParen)?;
Ok(Expr::Extract {
field,
expr: Box::new(expr),
syntax,
})
}
pub fn parse_ceil_floor_expr(&mut self, is_ceil: bool) -> Result<Expr, ParserError> {
self.expect_token(&Token::LParen)?;
let expr = self.parse_expr()?;
// Parse `CEIL/FLOOR(expr)`
let field = if self.parse_keyword(Keyword::TO) {
// Parse `CEIL/FLOOR(expr TO DateTimeField)`
CeilFloorKind::DateTimeField(self.parse_date_time_field()?)
} else if self.consume_token(&Token::Comma) {
// Parse `CEIL/FLOOR(expr, scale)`
match self.parse_value()? {
Value::Number(n, s) => CeilFloorKind::Scale(Value::Number(n, s)),
_ => {
return Err(ParserError::ParserError(
"Scale field can only be of number type".to_string(),
))
}
}
} else {
CeilFloorKind::DateTimeField(DateTimeField::NoDateTime)
};
self.expect_token(&Token::RParen)?;
if is_ceil {
Ok(Expr::Ceil {
expr: Box::new(expr),
field,
})
} else {
Ok(Expr::Floor {
expr: Box::new(expr),
field,
})
}
}
pub fn parse_position_expr(&mut self, ident: Ident) -> Result<Expr, ParserError> {
let between_prec = self.dialect.prec_value(Precedence::Between);
let position_expr = self.maybe_parse(|p| {
// PARSE SELECT POSITION('@' in field)
p.expect_token(&Token::LParen)?;
// Parse the subexpr till the IN keyword
let expr = p.parse_subexpr(between_prec)?;
p.expect_keyword(Keyword::IN)?;
let from = p.parse_expr()?;
p.expect_token(&Token::RParen)?;
Ok(Expr::Position {
expr: Box::new(expr),
r#in: Box::new(from),
})
});
match position_expr {
Some(expr) => Ok(expr),
// Snowflake supports `position` as an ordinary function call
// without the special `IN` syntax.
None => self.parse_function(ObjectName(vec![ident])),
}
}
pub fn parse_substring_expr(&mut self) -> Result<Expr, ParserError> {
// PARSE SUBSTRING (EXPR [FROM 1] [FOR 3])
self.expect_token(&Token::LParen)?;
let expr = self.parse_expr()?;
let mut from_expr = None;
let special = self.consume_token(&Token::Comma);
if special || self.parse_keyword(Keyword::FROM) {
from_expr = Some(self.parse_expr()?);
}
let mut to_expr = None;
if self.parse_keyword(Keyword::FOR) || self.consume_token(&Token::Comma) {
to_expr = Some(self.parse_expr()?);
}
self.expect_token(&Token::RParen)?;
Ok(Expr::Substring {
expr: Box::new(expr),
substring_from: from_expr.map(Box::new),
substring_for: to_expr.map(Box::new),
special,
})
}
pub fn parse_overlay_expr(&mut self) -> Result<Expr, ParserError> {
// PARSE OVERLAY (EXPR PLACING EXPR FROM 1 [FOR 3])
self.expect_token(&Token::LParen)?;
let expr = self.parse_expr()?;
self.expect_keyword(Keyword::PLACING)?;
let what_expr = self.parse_expr()?;
self.expect_keyword(Keyword::FROM)?;
let from_expr = self.parse_expr()?;
let mut for_expr = None;
if self.parse_keyword(Keyword::FOR) {
for_expr = Some(self.parse_expr()?);
}
self.expect_token(&Token::RParen)?;
Ok(Expr::Overlay {
expr: Box::new(expr),
overlay_what: Box::new(what_expr),
overlay_from: Box::new(from_expr),
overlay_for: for_expr.map(Box::new),
})
}
/// ```sql
/// TRIM ([WHERE] ['text' FROM] 'text')
/// TRIM ('text')
/// TRIM(<expr>, [, characters]) -- only Snowflake or BigQuery
/// ```
pub fn parse_trim_expr(&mut self) -> Result<Expr, ParserError> {
self.expect_token(&Token::LParen)?;
let mut trim_where = None;
if let Token::Word(word) = self.peek_token().token {
if [Keyword::BOTH, Keyword::LEADING, Keyword::TRAILING]
.iter()
.any(|d| word.keyword == *d)
{
trim_where = Some(self.parse_trim_where()?);
}
}
let expr = self.parse_expr()?;
if self.parse_keyword(Keyword::FROM) {
let trim_what = Box::new(expr);
let expr = self.parse_expr()?;
self.expect_token(&Token::RParen)?;
Ok(Expr::Trim {
expr: Box::new(expr),
trim_where,
trim_what: Some(trim_what),
trim_characters: None,
})
} else if self.consume_token(&Token::Comma)
&& dialect_of!(self is SnowflakeDialect | BigQueryDialect | GenericDialect)
{
let characters = self.parse_comma_separated(Parser::parse_expr)?;
self.expect_token(&Token::RParen)?;
Ok(Expr::Trim {
expr: Box::new(expr),
trim_where: None,
trim_what: None,
trim_characters: Some(characters),
})
} else {
self.expect_token(&Token::RParen)?;
Ok(Expr::Trim {
expr: Box::new(expr),
trim_where,
trim_what: None,
trim_characters: None,
})
}
}
pub fn parse_trim_where(&mut self) -> Result<TrimWhereField, ParserError> {
let next_token = self.next_token();
match &next_token.token {
Token::Word(w) => match w.keyword {
Keyword::BOTH => Ok(TrimWhereField::Both),
Keyword::LEADING => Ok(TrimWhereField::Leading),
Keyword::TRAILING => Ok(TrimWhereField::Trailing),
_ => self.expected("trim_where field", next_token)?,
},
_ => self.expected("trim_where field", next_token),
}
}
/// Parses an array expression `[ex1, ex2, ..]`
/// if `named` is `true`, came from an expression like `ARRAY[ex1, ex2]`
pub fn parse_array_expr(&mut self, named: bool) -> Result<Expr, ParserError> {
let exprs = self.parse_comma_separated0(Parser::parse_expr, Token::RBracket)?;
self.expect_token(&Token::RBracket)?;
Ok(Expr::Array(Array { elem: exprs, named }))
}
pub fn parse_listagg_on_overflow(&mut self) -> Result<Option<ListAggOnOverflow>, ParserError> {
if self.parse_keywords(&[Keyword::ON, Keyword::OVERFLOW]) {
if self.parse_keyword(Keyword::ERROR) {
Ok(Some(ListAggOnOverflow::Error))
} else {
self.expect_keyword(Keyword::TRUNCATE)?;
let filler = match self.peek_token().token {
Token::Word(w)
if w.keyword == Keyword::WITH || w.keyword == Keyword::WITHOUT =>
{
None
}
Token::SingleQuotedString(_)
| Token::EscapedStringLiteral(_)
| Token::UnicodeStringLiteral(_)
| Token::NationalStringLiteral(_)
| Token::HexStringLiteral(_) => Some(Box::new(self.parse_expr()?)),
_ => self.expected(
"either filler, WITH, or WITHOUT in LISTAGG",
self.peek_token(),
)?,
};
let with_count = self.parse_keyword(Keyword::WITH);
if !with_count && !self.parse_keyword(Keyword::WITHOUT) {
self.expected("either WITH or WITHOUT in LISTAGG", self.peek_token())?;
}
self.expect_keyword(Keyword::COUNT)?;
Ok(Some(ListAggOnOverflow::Truncate { filler, with_count }))
}
} else {
Ok(None)
}
}
// This function parses date/time fields for the EXTRACT function-like
// operator, interval qualifiers, and the ceil/floor operations.
// EXTRACT supports a wider set of date/time fields than interval qualifiers,
// so this function may need to be split in two.
pub fn parse_date_time_field(&mut self) -> Result<DateTimeField, ParserError> {
let next_token = self.next_token();
match &next_token.token {
Token::Word(w) => match w.keyword {
Keyword::YEAR => Ok(DateTimeField::Year),
Keyword::MONTH => Ok(DateTimeField::Month),
Keyword::WEEK => {
let week_day = if dialect_of!(self is BigQueryDialect | GenericDialect)
&& self.consume_token(&Token::LParen)
{
let week_day = self.parse_identifier(false)?;
self.expect_token(&Token::RParen)?;
Some(week_day)
} else {
None
};
Ok(DateTimeField::Week(week_day))
}
Keyword::DAY => Ok(DateTimeField::Day),
Keyword::DAYOFWEEK => Ok(DateTimeField::DayOfWeek),
Keyword::DAYOFYEAR => Ok(DateTimeField::DayOfYear),
Keyword::DATE => Ok(DateTimeField::Date),
Keyword::DATETIME => Ok(DateTimeField::Datetime),
Keyword::HOUR => Ok(DateTimeField::Hour),
Keyword::MINUTE => Ok(DateTimeField::Minute),
Keyword::SECOND => Ok(DateTimeField::Second),
Keyword::CENTURY => Ok(DateTimeField::Century),
Keyword::DECADE => Ok(DateTimeField::Decade),
Keyword::DOY => Ok(DateTimeField::Doy),
Keyword::DOW => Ok(DateTimeField::Dow),
Keyword::EPOCH => Ok(DateTimeField::Epoch),
Keyword::ISODOW => Ok(DateTimeField::Isodow),
Keyword::ISOYEAR => Ok(DateTimeField::Isoyear),
Keyword::ISOWEEK => Ok(DateTimeField::IsoWeek),
Keyword::JULIAN => Ok(DateTimeField::Julian),
Keyword::MICROSECOND => Ok(DateTimeField::Microsecond),
Keyword::MICROSECONDS => Ok(DateTimeField::Microseconds),
Keyword::MILLENIUM => Ok(DateTimeField::Millenium),
Keyword::MILLENNIUM => Ok(DateTimeField::Millennium),
Keyword::MILLISECOND => Ok(DateTimeField::Millisecond),
Keyword::MILLISECONDS => Ok(DateTimeField::Milliseconds),
Keyword::NANOSECOND => Ok(DateTimeField::Nanosecond),
Keyword::NANOSECONDS => Ok(DateTimeField::Nanoseconds),
Keyword::QUARTER => Ok(DateTimeField::Quarter),
Keyword::TIME => Ok(DateTimeField::Time),
Keyword::TIMEZONE => Ok(DateTimeField::Timezone),
Keyword::TIMEZONE_ABBR => Ok(DateTimeField::TimezoneAbbr),
Keyword::TIMEZONE_HOUR => Ok(DateTimeField::TimezoneHour),
Keyword::TIMEZONE_MINUTE => Ok(DateTimeField::TimezoneMinute),
Keyword::TIMEZONE_REGION => Ok(DateTimeField::TimezoneRegion),
_ if dialect_of!(self is SnowflakeDialect | GenericDialect) => {
self.prev_token();
let custom = self.parse_identifier(false)?;
Ok(DateTimeField::Custom(custom))
}
_ => self.expected("date/time field", next_token),
},
Token::SingleQuotedString(_) if dialect_of!(self is SnowflakeDialect | GenericDialect) =>
{
self.prev_token();
let custom = self.parse_identifier(false)?;
Ok(DateTimeField::Custom(custom))
}
_ => self.expected("date/time field", next_token),
}
}
pub fn parse_not(&mut self) -> Result<Expr, ParserError> {
match self.peek_token().token {
Token::Word(w) => match w.keyword {
Keyword::EXISTS => {
let negated = true;
let _ = self.parse_keyword(Keyword::EXISTS);
self.parse_exists_expr(negated)
}
_ => Ok(Expr::UnaryOp {
op: UnaryOperator::Not,
expr: Box::new(
self.parse_subexpr(self.dialect.prec_value(Precedence::UnaryNot))?,
),
}),
},
_ => Ok(Expr::UnaryOp {
op: UnaryOperator::Not,
expr: Box::new(self.parse_subexpr(self.dialect.prec_value(Precedence::UnaryNot))?),
}),
}
}
/// Parses fulltext expressions [`sqlparser::ast::Expr::MatchAgainst`]
///
/// # Errors
/// This method will raise an error if the column list is empty or with invalid identifiers,
/// the match expression is not a literal string, or if the search modifier is not valid.
pub fn parse_match_against(&mut self) -> Result<Expr, ParserError> {
let columns = self.parse_parenthesized_column_list(Mandatory, false)?;
self.expect_keyword(Keyword::AGAINST)?;
self.expect_token(&Token::LParen)?;
// MySQL is too permissive about the value, IMO we can't validate it perfectly on syntax level.
let match_value = self.parse_value()?;
let in_natural_language_mode_keywords = &[
Keyword::IN,
Keyword::NATURAL,
Keyword::LANGUAGE,
Keyword::MODE,
];
let with_query_expansion_keywords = &[Keyword::WITH, Keyword::QUERY, Keyword::EXPANSION];
let in_boolean_mode_keywords = &[Keyword::IN, Keyword::BOOLEAN, Keyword::MODE];
let opt_search_modifier = if self.parse_keywords(in_natural_language_mode_keywords) {
if self.parse_keywords(with_query_expansion_keywords) {
Some(SearchModifier::InNaturalLanguageModeWithQueryExpansion)
} else {
Some(SearchModifier::InNaturalLanguageMode)
}
} else if self.parse_keywords(in_boolean_mode_keywords) {
Some(SearchModifier::InBooleanMode)
} else if self.parse_keywords(with_query_expansion_keywords) {
Some(SearchModifier::WithQueryExpansion)
} else {
None
};
self.expect_token(&Token::RParen)?;
Ok(Expr::MatchAgainst {
columns,
match_value,
opt_search_modifier,
})
}
/// Parse an `INTERVAL` expression.
///
/// Some syntactically valid intervals:
///
/// ```sql
/// 1. INTERVAL '1' DAY
/// 2. INTERVAL '1-1' YEAR TO MONTH
/// 3. INTERVAL '1' SECOND
/// 4. INTERVAL '1:1:1.1' HOUR (5) TO SECOND (5)
/// 5. INTERVAL '1.1' SECOND (2, 2)
/// 6. INTERVAL '1:1' HOUR (5) TO MINUTE (5)
/// 7. (MySql & BigQuery only): INTERVAL 1 DAY
/// ```
///
/// Note that we do not currently attempt to parse the quoted value.
pub fn parse_interval(&mut self) -> Result<Expr, ParserError> {
// The SQL standard allows an optional sign before the value string, but
// it is not clear if any implementations support that syntax, so we
// don't currently try to parse it. (The sign can instead be included
// inside the value string.)
// The first token in an interval is a string literal which specifies
// the duration of the interval.
let value = self.parse_interval_expr()?;
// Following the string literal is a qualifier which indicates the units
// of the duration specified in the string literal.
//
// Note that PostgreSQL allows omitting the qualifier, so we provide
// this more general implementation.
let leading_field = match self.peek_token().token {
Token::Word(kw)
if [
Keyword::YEAR,
Keyword::MONTH,
Keyword::WEEK,
Keyword::DAY,
Keyword::HOUR,
Keyword::MINUTE,
Keyword::SECOND,
Keyword::CENTURY,
Keyword::DECADE,
Keyword::DOW,
Keyword::DOY,
Keyword::EPOCH,
Keyword::ISODOW,
Keyword::ISOYEAR,
Keyword::JULIAN,
Keyword::MICROSECOND,
Keyword::MICROSECONDS,
Keyword::MILLENIUM,
Keyword::MILLENNIUM,
Keyword::MILLISECOND,
Keyword::MILLISECONDS,
Keyword::NANOSECOND,
Keyword::NANOSECONDS,
Keyword::QUARTER,
Keyword::TIMEZONE,
Keyword::TIMEZONE_HOUR,
Keyword::TIMEZONE_MINUTE,
]
.iter()
.any(|d| kw.keyword == *d) =>
{
Some(self.parse_date_time_field()?)
}
_ => None,
};
let (leading_precision, last_field, fsec_precision) =
if leading_field == Some(DateTimeField::Second) {
// SQL mandates special syntax for `SECOND TO SECOND` literals.
// Instead of
// `SECOND [(<leading precision>)] TO SECOND[(<fractional seconds precision>)]`
// one must use the special format:
// `SECOND [( <leading precision> [ , <fractional seconds precision>] )]`
let last_field = None;
let (leading_precision, fsec_precision) = self.parse_optional_precision_scale()?;
(leading_precision, last_field, fsec_precision)
} else {
let leading_precision = self.parse_optional_precision()?;
if self.parse_keyword(Keyword::TO) {
let last_field = Some(self.parse_date_time_field()?);
let fsec_precision = if last_field == Some(DateTimeField::Second) {
self.parse_optional_precision()?
} else {
None
};
(leading_precision, last_field, fsec_precision)
} else {
(leading_precision, None, None)
}
};
Ok(Expr::Interval(Interval {
value: Box::new(value),
leading_field,
leading_precision,
last_field,
fractional_seconds_precision: fsec_precision,
}))
}
/// Bigquery specific: Parse a struct literal
/// Syntax
/// ```sql
/// -- typed
/// STRUCT<[field_name] field_type, ...>( expr1 [, ... ])
/// -- typeless
/// STRUCT( expr1 [AS field_name] [, ... ])
/// ```
fn parse_bigquery_struct_literal(&mut self) -> Result<Expr, ParserError> {
let (fields, trailing_bracket) =
self.parse_struct_type_def(Self::parse_struct_field_def)?;
if trailing_bracket.0 {
return parser_err!("unmatched > in STRUCT literal", self.peek_token().location);
}
self.expect_token(&Token::LParen)?;
let values = self
.parse_comma_separated(|parser| parser.parse_struct_field_expr(!fields.is_empty()))?;
self.expect_token(&Token::RParen)?;
Ok(Expr::Struct { values, fields })
}
/// Parse an expression value for a bigquery struct [1]
/// Syntax
/// ```sql
/// expr [AS name]
/// ```
///
/// Parameter typed_syntax is set to true if the expression
/// is to be parsed as a field expression declared using typed
/// struct syntax [2], and false if using typeless struct syntax [3].
///
/// [1]: https://cloud.google.com/bigquery/docs/reference/standard-sql/data-types#constructing_a_struct
/// [2]: https://cloud.google.com/bigquery/docs/reference/standard-sql/data-types#typed_struct_syntax
/// [3]: https://cloud.google.com/bigquery/docs/reference/standard-sql/data-types#typeless_struct_syntax
fn parse_struct_field_expr(&mut self, typed_syntax: bool) -> Result<Expr, ParserError> {
let expr = self.parse_expr()?;
if self.parse_keyword(Keyword::AS) {
if typed_syntax {
return parser_err!("Typed syntax does not allow AS", {
self.prev_token();
self.peek_token().location
});
}
let field_name = self.parse_identifier(false)?;
Ok(Expr::Named {
expr: expr.into(),
name: field_name,
})
} else {
Ok(expr)
}
}
/// Parse a Struct type definition as a sequence of field-value pairs.
/// The syntax of the Struct elem differs by dialect so it is customised
/// by the `elem_parser` argument.
///
/// Syntax
/// ```sql
/// Hive:
/// STRUCT<field_name: field_type>
///
/// BigQuery:
/// STRUCT<[field_name] field_type>
/// ```
fn parse_struct_type_def<F>(
&mut self,
mut elem_parser: F,
) -> Result<(Vec<StructField>, MatchedTrailingBracket), ParserError>
where
F: FnMut(&mut Parser<'a>) -> Result<(StructField, MatchedTrailingBracket), ParserError>,
{
let start_token = self.peek_token();
self.expect_keyword(Keyword::STRUCT)?;
// Nothing to do if we have no type information.
if Token::Lt != self.peek_token() {
return Ok((Default::default(), false.into()));
}
self.next_token();
let mut field_defs = vec![];
let trailing_bracket = loop {
let (def, trailing_bracket) = elem_parser(self)?;
field_defs.push(def);
if !self.consume_token(&Token::Comma) {
break trailing_bracket;
}
// Angle brackets are balanced so we only expect the trailing `>>` after
// we've matched all field types for the current struct.
// e.g. this is invalid syntax `STRUCT<STRUCT<INT>>>, INT>(NULL)`
if trailing_bracket.0 {
return parser_err!("unmatched > in STRUCT definition", start_token.location);
}
};
Ok((
field_defs,
self.expect_closing_angle_bracket(trailing_bracket)?,
))
}
/// Duckdb Struct Data Type <https://duckdb.org/docs/sql/data_types/struct.html#retrieving-from-structs>
fn parse_duckdb_struct_type_def(&mut self) -> Result<Vec<StructField>, ParserError> {
self.expect_keyword(Keyword::STRUCT)?;
self.expect_token(&Token::LParen)?;
let struct_body = self.parse_comma_separated(|parser| {
let field_name = parser.parse_identifier(false)?;
let field_type = parser.parse_data_type()?;
Ok(StructField {
field_name: Some(field_name),
field_type,
})
});
self.expect_token(&Token::RParen)?;
struct_body
}
/// Parse a field definition in a [struct] or [tuple].
/// Syntax:
///
/// ```sql
/// [field_name] field_type
/// ```
///
/// [struct]: https://cloud.google.com/bigquery/docs/reference/standard-sql/data-types#declaring_a_struct_type
/// [tuple]: https://clickhouse.com/docs/en/sql-reference/data-types/tuple
fn parse_struct_field_def(
&mut self,
) -> Result<(StructField, MatchedTrailingBracket), ParserError> {
// Look beyond the next item to infer whether both field name
// and type are specified.
let is_anonymous_field = !matches!(
(self.peek_nth_token(0).token, self.peek_nth_token(1).token),
(Token::Word(_), Token::Word(_))
);
let field_name = if is_anonymous_field {
None
} else {
Some(self.parse_identifier(false)?)
};
let (field_type, trailing_bracket) = self.parse_data_type_helper()?;
Ok((
StructField {
field_name,
field_type,
},
trailing_bracket,
))
}
/// DuckDB specific: Parse a Union type definition as a sequence of field-value pairs.
///
/// Syntax:
///
/// ```sql
/// UNION(field_name field_type[,...])
/// ```
///
/// [1]: https://duckdb.org/docs/sql/data_types/union.html
fn parse_union_type_def(&mut self) -> Result<Vec<UnionField>, ParserError> {
self.expect_keyword(Keyword::UNION)?;
self.expect_token(&Token::LParen)?;
let fields = self.parse_comma_separated(|p| {
Ok(UnionField {
field_name: p.parse_identifier(false)?,
field_type: p.parse_data_type()?,
})
})?;
self.expect_token(&Token::RParen)?;
Ok(fields)
}
/// DuckDB specific: Parse a duckdb [dictionary]
///
/// Syntax:
///
/// ```sql
/// {'field_name': expr1[, ... ]}
/// ```
///
/// [dictionary]: https://duckdb.org/docs/sql/data_types/struct#creating-structs
fn parse_duckdb_struct_literal(&mut self) -> Result<Expr, ParserError> {
self.expect_token(&Token::LBrace)?;
let fields = self.parse_comma_separated(Self::parse_duckdb_dictionary_field)?;
self.expect_token(&Token::RBrace)?;
Ok(Expr::Dictionary(fields))
}
/// Parse a field for a duckdb [dictionary]
///
/// Syntax
///
/// ```sql
/// 'name': expr
/// ```
///
/// [dictionary]: https://duckdb.org/docs/sql/data_types/struct#creating-structs
fn parse_duckdb_dictionary_field(&mut self) -> Result<DictionaryField, ParserError> {
let key = self.parse_identifier(false)?;
self.expect_token(&Token::Colon)?;
let expr = self.parse_expr()?;
Ok(DictionaryField {
key,
value: Box::new(expr),
})
}
/// DuckDB specific: Parse a duckdb [map]
///
/// Syntax:
///
/// ```sql
/// Map {key1: value1[, ... ]}
/// ```
///
/// [map]: https://duckdb.org/docs/sql/data_types/map.html#creating-maps
fn parse_duckdb_map_literal(&mut self) -> Result<Expr, ParserError> {
self.expect_token(&Token::LBrace)?;
let fields = self.parse_comma_separated0(Self::parse_duckdb_map_field, Token::RBrace)?;
self.expect_token(&Token::RBrace)?;
Ok(Expr::Map(Map { entries: fields }))
}
/// Parse a field for a duckdb [map]
///
/// Syntax
///
/// ```sql
/// key: value
/// ```
///
/// [map]: https://duckdb.org/docs/sql/data_types/map.html#creating-maps
fn parse_duckdb_map_field(&mut self) -> Result<MapEntry, ParserError> {
let key = self.parse_expr()?;
self.expect_token(&Token::Colon)?;
let value = self.parse_expr()?;
Ok(MapEntry {
key: Box::new(key),
value: Box::new(value),
})
}
/// Parse clickhouse [map]
///
/// Syntax
///
/// ```sql
/// Map(key_data_type, value_data_type)
/// ```
///
/// [map]: https://clickhouse.com/docs/en/sql-reference/data-types/map
fn parse_click_house_map_def(&mut self) -> Result<(DataType, DataType), ParserError> {
self.expect_keyword(Keyword::MAP)?;
self.expect_token(&Token::LParen)?;
let key_data_type = self.parse_data_type()?;
self.expect_token(&Token::Comma)?;
let value_data_type = self.parse_data_type()?;
self.expect_token(&Token::RParen)?;
Ok((key_data_type, value_data_type))
}
/// Parse clickhouse [tuple]
///
/// Syntax
///
/// ```sql
/// Tuple([field_name] field_type, ...)
/// ```
///
/// [tuple]: https://clickhouse.com/docs/en/sql-reference/data-types/tuple
fn parse_click_house_tuple_def(&mut self) -> Result<Vec<StructField>, ParserError> {
self.expect_keyword(Keyword::TUPLE)?;
self.expect_token(&Token::LParen)?;
let mut field_defs = vec![];
loop {
let (def, _) = self.parse_struct_field_def()?;
field_defs.push(def);
if !self.consume_token(&Token::Comma) {
break;
}
}
self.expect_token(&Token::RParen)?;
Ok(field_defs)
}
/// For nested types that use the angle bracket syntax, this matches either
/// `>`, `>>` or nothing depending on which variant is expected (specified by the previously
/// matched `trailing_bracket` argument). It returns whether there is a trailing
/// left to be matched - (i.e. if '>>' was matched).
fn expect_closing_angle_bracket(
&mut self,
trailing_bracket: MatchedTrailingBracket,
) -> Result<MatchedTrailingBracket, ParserError> {
let trailing_bracket = if !trailing_bracket.0 {
match self.peek_token().token {
Token::Gt => {
self.next_token();
false.into()
}
Token::ShiftRight => {
self.next_token();
true.into()
}
_ => return self.expected(">", self.peek_token()),
}
} else {
false.into()
};
Ok(trailing_bracket)
}
/// Parse an operator following an expression
pub fn parse_infix(&mut self, expr: Expr, precedence: u8) -> Result<Expr, ParserError> {
// allow the dialect to override infix parsing
if let Some(infix) = self.dialect.parse_infix(self, &expr, precedence) {
return infix;
}
let mut tok = self.next_token();
let regular_binary_operator = match &mut tok.token {
Token::Spaceship => Some(BinaryOperator::Spaceship),
Token::DoubleEq => Some(BinaryOperator::Eq),
Token::Eq => Some(BinaryOperator::Eq),
Token::Neq => Some(BinaryOperator::NotEq),
Token::Gt => Some(BinaryOperator::Gt),
Token::GtEq => Some(BinaryOperator::GtEq),
Token::Lt => Some(BinaryOperator::Lt),
Token::LtEq => Some(BinaryOperator::LtEq),
Token::Plus => Some(BinaryOperator::Plus),
Token::Minus => Some(BinaryOperator::Minus),
Token::Mul => Some(BinaryOperator::Multiply),
Token::Mod => Some(BinaryOperator::Modulo),
Token::StringConcat => Some(BinaryOperator::StringConcat),
Token::Pipe => Some(BinaryOperator::BitwiseOr),
Token::Caret => {
// In PostgreSQL, ^ stands for the exponentiation operation,
// and # stands for XOR. See https://www.postgresql.org/docs/current/functions-math.html
if dialect_of!(self is PostgreSqlDialect) {
Some(BinaryOperator::PGExp)
} else {
Some(BinaryOperator::BitwiseXor)
}
}
Token::Ampersand => Some(BinaryOperator::BitwiseAnd),
Token::Div => Some(BinaryOperator::Divide),
Token::DuckIntDiv if dialect_of!(self is DuckDbDialect | GenericDialect) => {
Some(BinaryOperator::DuckIntegerDivide)
}
Token::ShiftLeft if dialect_of!(self is PostgreSqlDialect | DuckDbDialect | GenericDialect) => {
Some(BinaryOperator::PGBitwiseShiftLeft)
}
Token::ShiftRight if dialect_of!(self is PostgreSqlDialect | DuckDbDialect | GenericDialect) => {
Some(BinaryOperator::PGBitwiseShiftRight)
}
Token::Sharp if dialect_of!(self is PostgreSqlDialect) => {
Some(BinaryOperator::PGBitwiseXor)
}
Token::Overlap if dialect_of!(self is PostgreSqlDialect | GenericDialect) => {
Some(BinaryOperator::PGOverlap)
}
Token::CaretAt if dialect_of!(self is PostgreSqlDialect | GenericDialect) => {
Some(BinaryOperator::PGStartsWith)
}
Token::Tilde => Some(BinaryOperator::PGRegexMatch),
Token::TildeAsterisk => Some(BinaryOperator::PGRegexIMatch),
Token::ExclamationMarkTilde => Some(BinaryOperator::PGRegexNotMatch),
Token::ExclamationMarkTildeAsterisk => Some(BinaryOperator::PGRegexNotIMatch),
Token::DoubleTilde => Some(BinaryOperator::PGLikeMatch),
Token::DoubleTildeAsterisk => Some(BinaryOperator::PGILikeMatch),
Token::ExclamationMarkDoubleTilde => Some(BinaryOperator::PGNotLikeMatch),
Token::ExclamationMarkDoubleTildeAsterisk => Some(BinaryOperator::PGNotILikeMatch),
Token::Arrow => Some(BinaryOperator::Arrow),
Token::LongArrow => Some(BinaryOperator::LongArrow),
Token::HashArrow => Some(BinaryOperator::HashArrow),
Token::HashLongArrow => Some(BinaryOperator::HashLongArrow),
Token::AtArrow => Some(BinaryOperator::AtArrow),
Token::ArrowAt => Some(BinaryOperator::ArrowAt),
Token::HashMinus => Some(BinaryOperator::HashMinus),
Token::AtQuestion => Some(BinaryOperator::AtQuestion),
Token::AtAt => Some(BinaryOperator::AtAt),
Token::Question => Some(BinaryOperator::Question),
Token::QuestionAnd => Some(BinaryOperator::QuestionAnd),
Token::QuestionPipe => Some(BinaryOperator::QuestionPipe),
Token::CustomBinaryOperator(s) => Some(BinaryOperator::Custom(core::mem::take(s))),
Token::Word(w) => match w.keyword {
Keyword::AND => Some(BinaryOperator::And),
Keyword::OR => Some(BinaryOperator::Or),
Keyword::XOR => Some(BinaryOperator::Xor),
Keyword::OPERATOR if dialect_of!(self is PostgreSqlDialect | GenericDialect) => {
self.expect_token(&Token::LParen)?;
// there are special rules for operator names in
// postgres so we can not use 'parse_object'
// or similar.
// See https://www.postgresql.org/docs/current/sql-createoperator.html
let mut idents = vec![];
loop {
idents.push(self.next_token().to_string());
if !self.consume_token(&Token::Period) {
break;
}
}
self.expect_token(&Token::RParen)?;
Some(BinaryOperator::PGCustomBinaryOperator(idents))
}
_ => None,
},
_ => None,
};
if let Some(op) = regular_binary_operator {
if let Some(keyword) = self.parse_one_of_keywords(&[Keyword::ANY, Keyword::ALL]) {
self.expect_token(&Token::LParen)?;
let right = self.parse_subexpr(precedence)?;
self.expect_token(&Token::RParen)?;
if !matches!(
op,
BinaryOperator::Gt
| BinaryOperator::Lt
| BinaryOperator::GtEq
| BinaryOperator::LtEq
| BinaryOperator::Eq
| BinaryOperator::NotEq
) {
return parser_err!(
format!(
"Expected one of [=, >, <, =>, =<, !=] as comparison operator, found: {op}"
),
tok.location
);
};
Ok(match keyword {
Keyword::ALL => Expr::AllOp {
left: Box::new(expr),
compare_op: op,
right: Box::new(right),
},
Keyword::ANY => Expr::AnyOp {
left: Box::new(expr),
compare_op: op,
right: Box::new(right),
},
_ => unreachable!(),
})
} else {
Ok(Expr::BinaryOp {
left: Box::new(expr),
op,
right: Box::new(self.parse_subexpr(precedence)?),
})
}
} else if let Token::Word(w) = &tok.token {
match w.keyword {
Keyword::IS => {
if self.parse_keyword(Keyword::NULL) {
Ok(Expr::IsNull(Box::new(expr)))
} else if self.parse_keywords(&[Keyword::NOT, Keyword::NULL]) {
Ok(Expr::IsNotNull(Box::new(expr)))
} else if self.parse_keywords(&[Keyword::TRUE]) {
Ok(Expr::IsTrue(Box::new(expr)))
} else if self.parse_keywords(&[Keyword::NOT, Keyword::TRUE]) {
Ok(Expr::IsNotTrue(Box::new(expr)))
} else if self.parse_keywords(&[Keyword::FALSE]) {
Ok(Expr::IsFalse(Box::new(expr)))
} else if self.parse_keywords(&[Keyword::NOT, Keyword::FALSE]) {
Ok(Expr::IsNotFalse(Box::new(expr)))
} else if self.parse_keywords(&[Keyword::UNKNOWN]) {
Ok(Expr::IsUnknown(Box::new(expr)))
} else if self.parse_keywords(&[Keyword::NOT, Keyword::UNKNOWN]) {
Ok(Expr::IsNotUnknown(Box::new(expr)))
} else if self.parse_keywords(&[Keyword::DISTINCT, Keyword::FROM]) {
let expr2 = self.parse_expr()?;
Ok(Expr::IsDistinctFrom(Box::new(expr), Box::new(expr2)))
} else if self.parse_keywords(&[Keyword::NOT, Keyword::DISTINCT, Keyword::FROM])
{
let expr2 = self.parse_expr()?;
Ok(Expr::IsNotDistinctFrom(Box::new(expr), Box::new(expr2)))
} else {
self.expected(
"[NOT] NULL or TRUE|FALSE or [NOT] DISTINCT FROM after IS",
self.peek_token(),
)
}
}
Keyword::AT => {
self.expect_keywords(&[Keyword::TIME, Keyword::ZONE])?;
Ok(Expr::AtTimeZone {
timestamp: Box::new(expr),
time_zone: Box::new(self.parse_subexpr(precedence)?),
})
}
Keyword::NOT
| Keyword::IN
| Keyword::BETWEEN
| Keyword::LIKE
| Keyword::ILIKE
| Keyword::SIMILAR
| Keyword::REGEXP
| Keyword::RLIKE => {
self.prev_token();
let negated = self.parse_keyword(Keyword::NOT);
let regexp = self.parse_keyword(Keyword::REGEXP);
let rlike = self.parse_keyword(Keyword::RLIKE);
if regexp || rlike {
Ok(Expr::RLike {
negated,
expr: Box::new(expr),
pattern: Box::new(
self.parse_subexpr(self.dialect.prec_value(Precedence::Like))?,
),
regexp,
})
} else if self.parse_keyword(Keyword::IN) {
self.parse_in(expr, negated)
} else if self.parse_keyword(Keyword::BETWEEN) {
self.parse_between(expr, negated)
} else if self.parse_keyword(Keyword::LIKE) {
Ok(Expr::Like {
negated,
expr: Box::new(expr),
pattern: Box::new(
self.parse_subexpr(self.dialect.prec_value(Precedence::Like))?,
),
escape_char: self.parse_escape_char()?,
})
} else if self.parse_keyword(Keyword::ILIKE) {
Ok(Expr::ILike {
negated,
expr: Box::new(expr),
pattern: Box::new(
self.parse_subexpr(self.dialect.prec_value(Precedence::Like))?,
),
escape_char: self.parse_escape_char()?,
})
} else if self.parse_keywords(&[Keyword::SIMILAR, Keyword::TO]) {
Ok(Expr::SimilarTo {
negated,
expr: Box::new(expr),
pattern: Box::new(
self.parse_subexpr(self.dialect.prec_value(Precedence::Like))?,
),
escape_char: self.parse_escape_char()?,
})
} else {
self.expected("IN or BETWEEN after NOT", self.peek_token())
}
}
// Can only happen if `get_next_precedence` got out of sync with this function
_ => parser_err!(
format!("No infix parser for token {:?}", tok.token),
tok.location
),
}
} else if Token::DoubleColon == tok {
Ok(Expr::Cast {
kind: CastKind::DoubleColon,
expr: Box::new(expr),
data_type: self.parse_data_type()?,
format: None,
})
} else if Token::ExclamationMark == tok {
// PostgreSQL factorial operation
Ok(Expr::UnaryOp {
op: UnaryOperator::PGPostfixFactorial,
expr: Box::new(expr),
})
} else if Token::LBracket == tok {
if dialect_of!(self is PostgreSqlDialect | DuckDbDialect | GenericDialect) {
self.parse_subscript(expr)
} else if dialect_of!(self is SnowflakeDialect) {
self.prev_token();
self.parse_json_access(expr)
} else {
self.parse_map_access(expr)
}
} else if dialect_of!(self is SnowflakeDialect | GenericDialect) && Token::Colon == tok {
self.prev_token();
self.parse_json_access(expr)
} else {
// Can only happen if `get_next_precedence` got out of sync with this function
parser_err!(
format!("No infix parser for token {:?}", tok.token),
tok.location
)
}
}
/// Parse the `ESCAPE CHAR` portion of `LIKE`, `ILIKE`, and `SIMILAR TO`
pub fn parse_escape_char(&mut self) -> Result<Option<String>, ParserError> {
if self.parse_keyword(Keyword::ESCAPE) {
Ok(Some(self.parse_literal_string()?))
} else {
Ok(None)
}
}
/// Parses an array subscript like
/// * `[:]`
/// * `[l]`
/// * `[l:]`
/// * `[:u]`
/// * `[l:u]`
/// * `[l:u:s]`
///
/// Parser is right after `[`
fn parse_subscript_inner(&mut self) -> Result<Subscript, ParserError> {
// at either `<lower>:(rest)` or `:(rest)]`
let lower_bound = if self.consume_token(&Token::Colon) {
None
} else {
Some(self.parse_expr()?)
};
// check for end
if self.consume_token(&Token::RBracket) {
if let Some(lower_bound) = lower_bound {
return Ok(Subscript::Index { index: lower_bound });
};
return Ok(Subscript::Slice {
lower_bound,
upper_bound: None,
stride: None,
});
}
// consume the `:`
if lower_bound.is_some() {
self.expect_token(&Token::Colon)?;
}
// we are now at either `]`, `<upper>(rest)]`
let upper_bound = if self.consume_token(&Token::RBracket) {
return Ok(Subscript::Slice {
lower_bound,
upper_bound: None,
stride: None,
});
} else {
Some(self.parse_expr()?)
};
// check for end
if self.consume_token(&Token::RBracket) {
return Ok(Subscript::Slice {
lower_bound,
upper_bound,
stride: None,
});
}
// we are now at `:]` or `:stride]`
self.expect_token(&Token::Colon)?;
let stride = if self.consume_token(&Token::RBracket) {
None
} else {
Some(self.parse_expr()?)
};
if stride.is_some() {
self.expect_token(&Token::RBracket)?;
}
Ok(Subscript::Slice {
lower_bound,
upper_bound,
stride,
})
}
/// Parses an array subscript like `[1:3]`
///
/// Parser is right after `[`
pub fn parse_subscript(&mut self, expr: Expr) -> Result<Expr, ParserError> {
let subscript = self.parse_subscript_inner()?;
Ok(Expr::Subscript {
expr: Box::new(expr),
subscript: Box::new(subscript),
})
}
fn parse_json_path_object_key(&mut self) -> Result<JsonPathElem, ParserError> {
let token = self.next_token();
match token.token {
Token::Word(Word {
value,
// path segments in SF dot notation can be unquoted or double-quoted
quote_style: quote_style @ (Some('"') | None),
// some experimentation suggests that snowflake permits
// any keyword here unquoted.
keyword: _,
}) => Ok(JsonPathElem::Dot {
key: value,
quoted: quote_style.is_some(),
}),
// This token should never be generated on snowflake or generic
// dialects, but we handle it just in case this is used on future
// dialects.
Token::DoubleQuotedString(key) => Ok(JsonPathElem::Dot { key, quoted: true }),
_ => self.expected("variant object key name", token),
}
}
fn parse_json_access(&mut self, expr: Expr) -> Result<Expr, ParserError> {
let mut path = Vec::new();
loop {
match self.next_token().token {
Token::Colon if path.is_empty() => {
path.push(self.parse_json_path_object_key()?);
}
Token::Period if !path.is_empty() => {
path.push(self.parse_json_path_object_key()?);
}
Token::LBracket => {
let key = self.parse_expr()?;
self.expect_token(&Token::RBracket)?;
path.push(JsonPathElem::Bracket { key });
}
_ => {
self.prev_token();
break;
}
};
}
debug_assert!(!path.is_empty());
Ok(Expr::JsonAccess {
value: Box::new(expr),
path: JsonPath { path },
})
}
pub fn parse_map_access(&mut self, expr: Expr) -> Result<Expr, ParserError> {
let key = self.parse_expr()?;
self.expect_token(&Token::RBracket)?;
let mut keys = vec![MapAccessKey {
key,
syntax: MapAccessSyntax::Bracket,
}];
loop {
let key = match self.peek_token().token {
Token::LBracket => {
self.next_token(); // consume `[`
let key = self.parse_expr()?;
self.expect_token(&Token::RBracket)?;
MapAccessKey {
key,
syntax: MapAccessSyntax::Bracket,
}
}
// Access on BigQuery nested and repeated expressions can
// mix notations in the same expression.
// https://cloud.google.com/bigquery/docs/nested-repeated#query_nested_and_repeated_columns
Token::Period if dialect_of!(self is BigQueryDialect) => {
self.next_token(); // consume `.`
MapAccessKey {
key: self.parse_expr()?,
syntax: MapAccessSyntax::Period,
}
}
_ => break,
};
keys.push(key);
}
Ok(Expr::MapAccess {
column: Box::new(expr),
keys,
})
}
/// Parses the parens following the `[ NOT ] IN` operator.
pub fn parse_in(&mut self, expr: Expr, negated: bool) -> Result<Expr, ParserError> {
// BigQuery allows `IN UNNEST(array_expression)`
// https://cloud.google.com/bigquery/docs/reference/standard-sql/operators#in_operators
if self.parse_keyword(Keyword::UNNEST) {
self.expect_token(&Token::LParen)?;
let array_expr = self.parse_expr()?;
self.expect_token(&Token::RParen)?;
return Ok(Expr::InUnnest {
expr: Box::new(expr),
array_expr: Box::new(array_expr),
negated,
});
}
self.expect_token(&Token::LParen)?;
let in_op = if self.parse_keyword(Keyword::SELECT) || self.parse_keyword(Keyword::WITH) {
self.prev_token();
Expr::InSubquery {
expr: Box::new(expr),
subquery: self.parse_boxed_query()?,
negated,
}
} else {
Expr::InList {
expr: Box::new(expr),
list: if self.dialect.supports_in_empty_list() {
self.parse_comma_separated0(Parser::parse_expr, Token::RParen)?
} else {
self.parse_comma_separated(Parser::parse_expr)?
},
negated,
}
};
self.expect_token(&Token::RParen)?;
Ok(in_op)
}
/// Parses `BETWEEN <low> AND <high>`, assuming the `BETWEEN` keyword was already consumed.
pub fn parse_between(&mut self, expr: Expr, negated: bool) -> Result<Expr, ParserError> {
// Stop parsing subexpressions for <low> and <high> on tokens with
// precedence lower than that of `BETWEEN`, such as `AND`, `IS`, etc.
let low = self.parse_subexpr(self.dialect.prec_value(Precedence::Between))?;
self.expect_keyword(Keyword::AND)?;
let high = self.parse_subexpr(self.dialect.prec_value(Precedence::Between))?;
Ok(Expr::Between {
expr: Box::new(expr),
negated,
low: Box::new(low),
high: Box::new(high),
})
}
/// Parse a postgresql casting style which is in the form of `expr::datatype`.
pub fn parse_pg_cast(&mut self, expr: Expr) -> Result<Expr, ParserError> {
Ok(Expr::Cast {
kind: CastKind::DoubleColon,
expr: Box::new(expr),
data_type: self.parse_data_type()?,
format: None,
})
}
/// Get the precedence of the next token
pub fn get_next_precedence(&self) -> Result<u8, ParserError> {
self.dialect.get_next_precedence_default(self)
}
/// Return the first non-whitespace token that has not yet been processed
/// (or None if reached end-of-file)
pub fn peek_token(&self) -> TokenWithLocation {
self.peek_nth_token(0)
}
/// Returns the `N` next non-whitespace tokens that have not yet been
/// processed.
///
/// Example:
/// ```rust
/// # use sqlparser::dialect::GenericDialect;
/// # use sqlparser::parser::Parser;
/// # use sqlparser::keywords::Keyword;
/// # use sqlparser::tokenizer::{Token, Word};
/// let dialect = GenericDialect {};
/// let mut parser = Parser::new(&dialect).try_with_sql("ORDER BY foo, bar").unwrap();
///
/// // Note that Rust infers the number of tokens to peek based on the
/// // length of the slice pattern!
/// assert!(matches!(
/// parser.peek_tokens(),
/// [
/// Token::Word(Word { keyword: Keyword::ORDER, .. }),
/// Token::Word(Word { keyword: Keyword::BY, .. }),
/// ]
/// ));
/// ```
pub fn peek_tokens<const N: usize>(&self) -> [Token; N] {
self.peek_tokens_with_location()
.map(|with_loc| with_loc.token)
}
/// Returns the `N` next non-whitespace tokens with locations that have not
/// yet been processed.
///
/// See [`Self::peek_token`] for an example.
pub fn peek_tokens_with_location<const N: usize>(&self) -> [TokenWithLocation; N] {
let mut index = self.index;
core::array::from_fn(|_| loop {
let token = self.tokens.get(index);
index += 1;
if let Some(TokenWithLocation {
token: Token::Whitespace(_),
location: _,
}) = token
{
continue;
}
break token.cloned().unwrap_or(TokenWithLocation {
token: Token::EOF,
location: Location { line: 0, column: 0 },
});
})
}
/// Return nth non-whitespace token that has not yet been processed
pub fn peek_nth_token(&self, mut n: usize) -> TokenWithLocation {
let mut index = self.index;
loop {
index += 1;
match self.tokens.get(index - 1) {
Some(TokenWithLocation {
token: Token::Whitespace(_),
location: _,
}) => continue,
non_whitespace => {
if n == 0 {
return non_whitespace.cloned().unwrap_or(TokenWithLocation {
token: Token::EOF,
location: Location { line: 0, column: 0 },
});
}
n -= 1;
}
}
}
}
/// Return the first token, possibly whitespace, that has not yet been processed
/// (or None if reached end-of-file).
pub fn peek_token_no_skip(&self) -> TokenWithLocation {
self.peek_nth_token_no_skip(0)
}
/// Return nth token, possibly whitespace, that has not yet been processed.
pub fn peek_nth_token_no_skip(&self, n: usize) -> TokenWithLocation {
self.tokens
.get(self.index + n)
.cloned()
.unwrap_or(TokenWithLocation {
token: Token::EOF,
location: Location { line: 0, column: 0 },
})
}
/// Return the first non-whitespace token that has not yet been processed
/// (or None if reached end-of-file) and mark it as processed. OK to call
/// repeatedly after reaching EOF.
pub fn next_token(&mut self) -> TokenWithLocation {
loop {
self.index += 1;
match self.tokens.get(self.index - 1) {
Some(TokenWithLocation {
token: Token::Whitespace(_),
location: _,
}) => continue,
token => {
return token
.cloned()
.unwrap_or_else(|| TokenWithLocation::wrap(Token::EOF))
}
}
}
}
/// Return the first unprocessed token, possibly whitespace.
pub fn next_token_no_skip(&mut self) -> Option<&TokenWithLocation> {
self.index += 1;
self.tokens.get(self.index - 1)
}
/// Push back the last one non-whitespace token. Must be called after
/// `next_token()`, otherwise might panic. OK to call after
/// `next_token()` indicates an EOF.
pub fn prev_token(&mut self) {
loop {
assert!(self.index > 0);
self.index -= 1;
if let Some(TokenWithLocation {
token: Token::Whitespace(_),
location: _,
}) = self.tokens.get(self.index)
{
continue;
}
return;
}
}
/// Report `found` was encountered instead of `expected`
pub fn expected<T>(&self, expected: &str, found: TokenWithLocation) -> Result<T, ParserError> {
parser_err!(
format!("Expected: {expected}, found: {found}"),
found.location
)
}
/// If the current token is the `expected` keyword, consume it and returns
/// true. Otherwise, no tokens are consumed and returns false.
#[must_use]
pub fn parse_keyword(&mut self, expected: Keyword) -> bool {
match self.peek_token().token {
Token::Word(w) if expected == w.keyword => {
self.next_token();
true
}
_ => false,
}
}
/// If the current token is the `expected` keyword followed by
/// specified tokens, consume them and returns true.
/// Otherwise, no tokens are consumed and returns false.
///
/// Note that if the length of `tokens` is too long, this function will
/// not be efficient as it does a loop on the tokens with `peek_nth_token`
/// each time.
pub fn parse_keyword_with_tokens(&mut self, expected: Keyword, tokens: &[Token]) -> bool {
match self.peek_token().token {
Token::Word(w) if expected == w.keyword => {
for (idx, token) in tokens.iter().enumerate() {
if self.peek_nth_token(idx + 1).token != *token {
return false;
}
}
// consume all tokens
for _ in 0..(tokens.len() + 1) {
self.next_token();
}
true
}
_ => false,
}
}
/// If the current and subsequent tokens exactly match the `keywords`
/// sequence, consume them and returns true. Otherwise, no tokens are
/// consumed and returns false
#[must_use]
pub fn parse_keywords(&mut self, keywords: &[Keyword]) -> bool {
let index = self.index;
for &keyword in keywords {
if !self.parse_keyword(keyword) {
// println!("parse_keywords aborting .. did not find {:?}", keyword);
// reset index and return immediately
self.index = index;
return false;
}
}
true
}
/// If the current token is one of the given `keywords`, consume the token
/// and return the keyword that matches. Otherwise, no tokens are consumed
/// and returns [`None`].
#[must_use]
pub fn parse_one_of_keywords(&mut self, keywords: &[Keyword]) -> Option<Keyword> {
match self.peek_token().token {
Token::Word(w) => {
keywords
.iter()
.find(|keyword| **keyword == w.keyword)
.map(|keyword| {
self.next_token();
*keyword
})
}
_ => None,
}
}
/// If the current token is one of the expected keywords, consume the token
/// and return the keyword that matches. Otherwise, return an error.
pub fn expect_one_of_keywords(&mut self, keywords: &[Keyword]) -> Result<Keyword, ParserError> {
if let Some(keyword) = self.parse_one_of_keywords(keywords) {
Ok(keyword)
} else {
let keywords: Vec<String> = keywords.iter().map(|x| format!("{x:?}")).collect();
self.expected(
&format!("one of {}", keywords.join(" or ")),
self.peek_token(),
)
}
}
/// If the current token is the `expected` keyword, consume the token.
/// Otherwise, return an error.
pub fn expect_keyword(&mut self, expected: Keyword) -> Result<(), ParserError> {
if self.parse_keyword(expected) {
Ok(())
} else {
self.expected(format!("{:?}", &expected).as_str(), self.peek_token())
}
}
/// If the current and subsequent tokens exactly match the `keywords`
/// sequence, consume them and returns Ok. Otherwise, return an Error.
pub fn expect_keywords(&mut self, expected: &[Keyword]) -> Result<(), ParserError> {
for &kw in expected {
self.expect_keyword(kw)?;
}
Ok(())
}
/// Consume the next token if it matches the expected token, otherwise return false
#[must_use]
pub fn consume_token(&mut self, expected: &Token) -> bool {
if self.peek_token() == *expected {
self.next_token();
true
} else {
false
}
}
/// If the current and subsequent tokens exactly match the `tokens`
/// sequence, consume them and returns true. Otherwise, no tokens are
/// consumed and returns false
#[must_use]
pub fn consume_tokens(&mut self, tokens: &[Token]) -> bool {
let index = self.index;
for token in tokens {
if !self.consume_token(token) {
self.index = index;
return false;
}
}
true
}
/// Bail out if the current token is not an expected keyword, or consume it if it is
pub fn expect_token(&mut self, expected: &Token) -> Result<(), ParserError> {
if self.consume_token(expected) {
Ok(())
} else {
self.expected(&expected.to_string(), self.peek_token())
}
}
fn parse<T: FromStr>(s: String, loc: Location) -> Result<T, ParserError>
where
<T as FromStr>::Err: Display,
{
s.parse::<T>().map_err(|e| {
ParserError::ParserError(format!(
"Could not parse '{s}' as {}: {e}{loc}",
core::any::type_name::<T>()
))
})
}
/// Parse a comma-separated list of 1+ SelectItem
pub fn parse_projection(&mut self) -> Result<Vec<SelectItem>, ParserError> {
// BigQuery and Snowflake allow trailing commas, but only in project lists
// e.g. `SELECT 1, 2, FROM t`
// https://cloud.google.com/bigquery/docs/reference/standard-sql/lexical#trailing_commas
// https://docs.snowflake.com/en/release-notes/2024/8_11#select-supports-trailing-commas
//
// This pattern could be captured better with RAII type semantics, but it's quite a bit of
// code to add for just one case, so we'll just do it manually here.
let old_value = self.options.trailing_commas;
self.options.trailing_commas |= self.dialect.supports_projection_trailing_commas();
let ret = self.parse_comma_separated(|p| p.parse_select_item());
self.options.trailing_commas = old_value;
ret
}
pub fn parse_actions_list(&mut self) -> Result<Vec<ParsedAction>, ParserError> {
let mut values = vec![];
loop {
values.push(self.parse_grant_permission()?);
if !self.consume_token(&Token::Comma) {
break;
} else if self.options.trailing_commas {
match self.peek_token().token {
Token::Word(kw) if kw.keyword == Keyword::ON => {
break;
}
Token::RParen
| Token::SemiColon
| Token::EOF
| Token::RBracket
| Token::RBrace => break,
_ => continue,
}
}
}
Ok(values)
}
/// Parse the comma of a comma-separated syntax element.
/// Returns true if there is a next element
fn is_parse_comma_separated_end(&mut self) -> bool {
if !self.consume_token(&Token::Comma) {
true
} else if self.options.trailing_commas {
let token = self.peek_token().token;
match token {
Token::Word(ref kw)
if keywords::RESERVED_FOR_COLUMN_ALIAS.contains(&kw.keyword) =>
{
true
}
Token::RParen | Token::SemiColon | Token::EOF | Token::RBracket | Token::RBrace => {
true
}
_ => false,
}
} else {
false
}
}
/// Parse a comma-separated list of 1+ items accepted by `F`
pub fn parse_comma_separated<T, F>(&mut self, mut f: F) -> Result<Vec<T>, ParserError>
where
F: FnMut(&mut Parser<'a>) -> Result<T, ParserError>,
{
let mut values = vec![];
loop {
values.push(f(self)?);
if self.is_parse_comma_separated_end() {
break;
}
}
Ok(values)
}
/// Parse a keyword-separated list of 1+ items accepted by `F`
pub fn parse_keyword_separated<T, F>(
&mut self,
keyword: Keyword,
mut f: F,
) -> Result<Vec<T>, ParserError>
where
F: FnMut(&mut Parser<'a>) -> Result<T, ParserError>,
{
let mut values = vec![];
loop {
values.push(f(self)?);
if !self.parse_keyword(keyword) {
break;
}
}
Ok(values)
}
pub fn parse_parenthesized<T, F>(&mut self, mut f: F) -> Result<T, ParserError>
where
F: FnMut(&mut Parser<'a>) -> Result<T, ParserError>,
{
self.expect_token(&Token::LParen)?;
let res = f(self)?;
self.expect_token(&Token::RParen)?;
Ok(res)
}
/// Parse a comma-separated list of 0+ items accepted by `F`
/// * `end_token` - expected end token for the closure (e.g. [Token::RParen], [Token::RBrace] ...)
pub fn parse_comma_separated0<T, F>(
&mut self,
f: F,
end_token: Token,
) -> Result<Vec<T>, ParserError>
where
F: FnMut(&mut Parser<'a>) -> Result<T, ParserError>,
{
if self.peek_token().token == end_token {
return Ok(vec![]);
}
if self.options.trailing_commas && self.peek_tokens() == [Token::Comma, end_token] {
let _ = self.consume_token(&Token::Comma);
return Ok(vec![]);
}
self.parse_comma_separated(f)
}
/// Run a parser method `f`, reverting back to the current position if unsuccessful.
#[must_use]
pub fn maybe_parse<T, F>(&mut self, mut f: F) -> Option<T>
where
F: FnMut(&mut Parser) -> Result<T, ParserError>,
{
let index = self.index;
if let Ok(t) = f(self) {
Some(t)
} else {
self.index = index;
None
}
}
/// Parse either `ALL`, `DISTINCT` or `DISTINCT ON (...)`. Returns [`None`] if `ALL` is parsed
/// and results in a [`ParserError`] if both `ALL` and `DISTINCT` are found.
pub fn parse_all_or_distinct(&mut self) -> Result<Option<Distinct>, ParserError> {
let loc = self.peek_token().location;
let all = self.parse_keyword(Keyword::ALL);
let distinct = self.parse_keyword(Keyword::DISTINCT);
if !distinct {
return Ok(None);
}
if all {
return parser_err!("Cannot specify both ALL and DISTINCT".to_string(), loc);
}
let on = self.parse_keyword(Keyword::ON);
if !on {
return Ok(Some(Distinct::Distinct));
}
self.expect_token(&Token::LParen)?;
let col_names = if self.consume_token(&Token::RParen) {
self.prev_token();
Vec::new()
} else {
self.parse_comma_separated(Parser::parse_expr)?
};
self.expect_token(&Token::RParen)?;
Ok(Some(Distinct::On(col_names)))
}
/// Parse a SQL CREATE statement
pub fn parse_create(&mut self) -> Result<Statement, ParserError> {
let or_replace = self.parse_keywords(&[Keyword::OR, Keyword::REPLACE]);
let or_alter = self.parse_keywords(&[Keyword::OR, Keyword::ALTER]);
let local = self.parse_one_of_keywords(&[Keyword::LOCAL]).is_some();
let global = self.parse_one_of_keywords(&[Keyword::GLOBAL]).is_some();
let transient = self.parse_one_of_keywords(&[Keyword::TRANSIENT]).is_some();
let global: Option<bool> = if global {
Some(true)
} else if local {
Some(false)
} else {
None
};
let temporary = self
.parse_one_of_keywords(&[Keyword::TEMP, Keyword::TEMPORARY])
.is_some();
let persistent = dialect_of!(self is DuckDbDialect)
&& self.parse_one_of_keywords(&[Keyword::PERSISTENT]).is_some();
if self.parse_keyword(Keyword::TABLE) {
self.parse_create_table(or_replace, temporary, global, transient)
} else if self.parse_keyword(Keyword::MATERIALIZED) || self.parse_keyword(Keyword::VIEW) {
self.prev_token();
self.parse_create_view(or_replace, temporary)
} else if self.parse_keyword(Keyword::EXTERNAL) {
self.parse_create_external_table(or_replace)
} else if self.parse_keyword(Keyword::FUNCTION) {
self.parse_create_function(or_replace, temporary)
} else if self.parse_keyword(Keyword::TRIGGER) {
self.parse_create_trigger(or_replace, false)
} else if self.parse_keywords(&[Keyword::CONSTRAINT, Keyword::TRIGGER]) {
self.parse_create_trigger(or_replace, true)
} else if self.parse_keyword(Keyword::MACRO) {
self.parse_create_macro(or_replace, temporary)
} else if self.parse_keyword(Keyword::SECRET) {
self.parse_create_secret(or_replace, temporary, persistent)
} else if or_replace {
self.expected(
"[EXTERNAL] TABLE or [MATERIALIZED] VIEW or FUNCTION after CREATE OR REPLACE",
self.peek_token(),
)
} else if self.parse_keyword(Keyword::EXTENSION) {
self.parse_create_extension()
} else if self.parse_keyword(Keyword::INDEX) {
self.parse_create_index(false)
} else if self.parse_keywords(&[Keyword::UNIQUE, Keyword::INDEX]) {
self.parse_create_index(true)
} else if self.parse_keyword(Keyword::VIRTUAL) {
self.parse_create_virtual_table()
} else if self.parse_keyword(Keyword::SCHEMA) {
self.parse_create_schema()
} else if self.parse_keyword(Keyword::DATABASE) {
self.parse_create_database()
} else if self.parse_keyword(Keyword::ROLE) {
self.parse_create_role()
} else if self.parse_keyword(Keyword::SEQUENCE) {
self.parse_create_sequence(temporary)
} else if self.parse_keyword(Keyword::TYPE) {
self.parse_create_type()
} else if self.parse_keyword(Keyword::PROCEDURE) {
self.parse_create_procedure(or_alter)
} else {
self.expected("an object type after CREATE", self.peek_token())
}
}
/// See [DuckDB Docs](https://duckdb.org/docs/sql/statements/create_secret.html) for more details.
pub fn parse_create_secret(
&mut self,
or_replace: bool,
temporary: bool,
persistent: bool,
) -> Result<Statement, ParserError> {
let if_not_exists = self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
let mut storage_specifier = None;
let mut name = None;
if self.peek_token() != Token::LParen {
if self.parse_keyword(Keyword::IN) {
storage_specifier = self.parse_identifier(false).ok()
} else {
name = self.parse_identifier(false).ok();
}
// Storage specifier may follow the name
if storage_specifier.is_none()
&& self.peek_token() != Token::LParen
&& self.parse_keyword(Keyword::IN)
{
storage_specifier = self.parse_identifier(false).ok();
}
}
self.expect_token(&Token::LParen)?;
self.expect_keyword(Keyword::TYPE)?;
let secret_type = self.parse_identifier(false)?;
let mut options = Vec::new();
if self.consume_token(&Token::Comma) {
options.append(&mut self.parse_comma_separated(|p| {
let key = p.parse_identifier(false)?;
let value = p.parse_identifier(false)?;
Ok(SecretOption { key, value })
})?);
}
self.expect_token(&Token::RParen)?;
let temp = match (temporary, persistent) {
(true, false) => Some(true),
(false, true) => Some(false),
(false, false) => None,
_ => self.expected("TEMPORARY or PERSISTENT", self.peek_token())?,
};
Ok(Statement::CreateSecret {
or_replace,
temporary: temp,
if_not_exists,
name,
storage_specifier,
secret_type,
options,
})
}
/// Parse a CACHE TABLE statement
pub fn parse_cache_table(&mut self) -> Result<Statement, ParserError> {
let (mut table_flag, mut options, mut has_as, mut query) = (None, vec![], false, None);
if self.parse_keyword(Keyword::TABLE) {
let table_name = self.parse_object_name(false)?;
if self.peek_token().token != Token::EOF {
if let Token::Word(word) = self.peek_token().token {
if word.keyword == Keyword::OPTIONS {
options = self.parse_options(Keyword::OPTIONS)?
}
};
if self.peek_token().token != Token::EOF {
let (a, q) = self.parse_as_query()?;
has_as = a;
query = Some(q);
}
Ok(Statement::Cache {
table_flag,
table_name,
has_as,
options,
query,
})
} else {
Ok(Statement::Cache {
table_flag,
table_name,
has_as,
options,
query,
})
}
} else {
table_flag = Some(self.parse_object_name(false)?);
if self.parse_keyword(Keyword::TABLE) {
let table_name = self.parse_object_name(false)?;
if self.peek_token() != Token::EOF {
if let Token::Word(word) = self.peek_token().token {
if word.keyword == Keyword::OPTIONS {
options = self.parse_options(Keyword::OPTIONS)?
}
};
if self.peek_token() != Token::EOF {
let (a, q) = self.parse_as_query()?;
has_as = a;
query = Some(q);
}
Ok(Statement::Cache {
table_flag,
table_name,
has_as,
options,
query,
})
} else {
Ok(Statement::Cache {
table_flag,
table_name,
has_as,
options,
query,
})
}
} else {
if self.peek_token() == Token::EOF {
self.prev_token();
}
self.expected("a `TABLE` keyword", self.peek_token())
}
}
}
/// Parse 'AS' before as query,such as `WITH XXX AS SELECT XXX` oer `CACHE TABLE AS SELECT XXX`
pub fn parse_as_query(&mut self) -> Result<(bool, Query), ParserError> {
match self.peek_token().token {
Token::Word(word) => match word.keyword {
Keyword::AS => {
self.next_token();
Ok((true, self.parse_query()?))
}
_ => Ok((false, self.parse_query()?)),
},
_ => self.expected("a QUERY statement", self.peek_token()),
}
}
/// Parse a UNCACHE TABLE statement
pub fn parse_uncache_table(&mut self) -> Result<Statement, ParserError> {
self.expect_keyword(Keyword::TABLE)?;
let if_exists = self.parse_keywords(&[Keyword::IF, Keyword::EXISTS]);
let table_name = self.parse_object_name(false)?;
Ok(Statement::UNCache {
table_name,
if_exists,
})
}
/// SQLite-specific `CREATE VIRTUAL TABLE`
pub fn parse_create_virtual_table(&mut self) -> Result<Statement, ParserError> {
self.expect_keyword(Keyword::TABLE)?;
let if_not_exists = self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
let table_name = self.parse_object_name(false)?;
self.expect_keyword(Keyword::USING)?;
let module_name = self.parse_identifier(false)?;
// SQLite docs note that module "arguments syntax is sufficiently
// general that the arguments can be made to appear as column
// definitions in a traditional CREATE TABLE statement", but
// we don't implement that.
let module_args = self.parse_parenthesized_column_list(Optional, false)?;
Ok(Statement::CreateVirtualTable {
name: table_name,
if_not_exists,
module_name,
module_args,
})
}
pub fn parse_create_schema(&mut self) -> Result<Statement, ParserError> {
let if_not_exists = self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
let schema_name = self.parse_schema_name()?;
Ok(Statement::CreateSchema {
schema_name,
if_not_exists,
})
}
fn parse_schema_name(&mut self) -> Result<SchemaName, ParserError> {
if self.parse_keyword(Keyword::AUTHORIZATION) {
Ok(SchemaName::UnnamedAuthorization(
self.parse_identifier(false)?,
))
} else {
let name = self.parse_object_name(false)?;
if self.parse_keyword(Keyword::AUTHORIZATION) {
Ok(SchemaName::NamedAuthorization(
name,
self.parse_identifier(false)?,
))
} else {
Ok(SchemaName::Simple(name))
}
}
}
pub fn parse_create_database(&mut self) -> Result<Statement, ParserError> {
let ine = self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
let db_name = self.parse_object_name(false)?;
let mut location = None;
let mut managed_location = None;
loop {
match self.parse_one_of_keywords(&[Keyword::LOCATION, Keyword::MANAGEDLOCATION]) {
Some(Keyword::LOCATION) => location = Some(self.parse_literal_string()?),
Some(Keyword::MANAGEDLOCATION) => {
managed_location = Some(self.parse_literal_string()?)
}
_ => break,
}
}
Ok(Statement::CreateDatabase {
db_name,
if_not_exists: ine,
location,
managed_location,
})
}
pub fn parse_optional_create_function_using(
&mut self,
) -> Result<Option<CreateFunctionUsing>, ParserError> {
if !self.parse_keyword(Keyword::USING) {
return Ok(None);
};
let keyword =
self.expect_one_of_keywords(&[Keyword::JAR, Keyword::FILE, Keyword::ARCHIVE])?;
let uri = self.parse_literal_string()?;
match keyword {
Keyword::JAR => Ok(Some(CreateFunctionUsing::Jar(uri))),
Keyword::FILE => Ok(Some(CreateFunctionUsing::File(uri))),
Keyword::ARCHIVE => Ok(Some(CreateFunctionUsing::Archive(uri))),
_ => self.expected(
"JAR, FILE or ARCHIVE, got {:?}",
TokenWithLocation::wrap(Token::make_keyword(format!("{keyword:?}").as_str())),
),
}
}
pub fn parse_create_function(
&mut self,
or_replace: bool,
temporary: bool,
) -> Result<Statement, ParserError> {
if dialect_of!(self is HiveDialect) {
self.parse_hive_create_function(or_replace, temporary)
} else if dialect_of!(self is PostgreSqlDialect | GenericDialect) {
self.parse_postgres_create_function(or_replace, temporary)
} else if dialect_of!(self is DuckDbDialect) {
self.parse_create_macro(or_replace, temporary)
} else if dialect_of!(self is BigQueryDialect) {
self.parse_bigquery_create_function(or_replace, temporary)
} else {
self.prev_token();
self.expected("an object type after CREATE", self.peek_token())
}
}
/// Parse `CREATE FUNCTION` for [Postgres]
///
/// [Postgres]: https://www.postgresql.org/docs/15/sql-createfunction.html
fn parse_postgres_create_function(
&mut self,
or_replace: bool,
temporary: bool,
) -> Result<Statement, ParserError> {
let name = self.parse_object_name(false)?;
self.expect_token(&Token::LParen)?;
let args = if self.consume_token(&Token::RParen) {
self.prev_token();
None
} else {
Some(self.parse_comma_separated(Parser::parse_function_arg)?)
};
self.expect_token(&Token::RParen)?;
let return_type = if self.parse_keyword(Keyword::RETURNS) {
Some(self.parse_data_type()?)
} else {
None
};
#[derive(Default)]
struct Body {
language: Option<Ident>,
behavior: Option<FunctionBehavior>,
function_body: Option<CreateFunctionBody>,
called_on_null: Option<FunctionCalledOnNull>,
parallel: Option<FunctionParallel>,
}
let mut body = Body::default();
loop {
fn ensure_not_set<T>(field: &Option<T>, name: &str) -> Result<(), ParserError> {
if field.is_some() {
return Err(ParserError::ParserError(format!(
"{name} specified more than once",
)));
}
Ok(())
}
if self.parse_keyword(Keyword::AS) {
ensure_not_set(&body.function_body, "AS")?;
body.function_body = Some(CreateFunctionBody::AsBeforeOptions(
self.parse_create_function_body_string()?,
));
} else if self.parse_keyword(Keyword::LANGUAGE) {
ensure_not_set(&body.language, "LANGUAGE")?;
body.language = Some(self.parse_identifier(false)?);
} else if self.parse_keyword(Keyword::IMMUTABLE) {
ensure_not_set(&body.behavior, "IMMUTABLE | STABLE | VOLATILE")?;
body.behavior = Some(FunctionBehavior::Immutable);
} else if self.parse_keyword(Keyword::STABLE) {
ensure_not_set(&body.behavior, "IMMUTABLE | STABLE | VOLATILE")?;
body.behavior = Some(FunctionBehavior::Stable);
} else if self.parse_keyword(Keyword::VOLATILE) {
ensure_not_set(&body.behavior, "IMMUTABLE | STABLE | VOLATILE")?;
body.behavior = Some(FunctionBehavior::Volatile);
} else if self.parse_keywords(&[
Keyword::CALLED,
Keyword::ON,
Keyword::NULL,
Keyword::INPUT,
]) {
ensure_not_set(
&body.called_on_null,
"CALLED ON NULL INPUT | RETURNS NULL ON NULL INPUT | STRICT",
)?;
body.called_on_null = Some(FunctionCalledOnNull::CalledOnNullInput);
} else if self.parse_keywords(&[
Keyword::RETURNS,
Keyword::NULL,
Keyword::ON,
Keyword::NULL,
Keyword::INPUT,
]) {
ensure_not_set(
&body.called_on_null,
"CALLED ON NULL INPUT | RETURNS NULL ON NULL INPUT | STRICT",
)?;
body.called_on_null = Some(FunctionCalledOnNull::ReturnsNullOnNullInput);
} else if self.parse_keyword(Keyword::STRICT) {
ensure_not_set(
&body.called_on_null,
"CALLED ON NULL INPUT | RETURNS NULL ON NULL INPUT | STRICT",
)?;
body.called_on_null = Some(FunctionCalledOnNull::Strict);
} else if self.parse_keyword(Keyword::PARALLEL) {
ensure_not_set(&body.parallel, "PARALLEL { UNSAFE | RESTRICTED | SAFE }")?;
if self.parse_keyword(Keyword::UNSAFE) {
body.parallel = Some(FunctionParallel::Unsafe);
} else if self.parse_keyword(Keyword::RESTRICTED) {
body.parallel = Some(FunctionParallel::Restricted);
} else if self.parse_keyword(Keyword::SAFE) {
body.parallel = Some(FunctionParallel::Safe);
} else {
return self.expected("one of UNSAFE | RESTRICTED | SAFE", self.peek_token());
}
} else if self.parse_keyword(Keyword::RETURN) {
ensure_not_set(&body.function_body, "RETURN")?;
body.function_body = Some(CreateFunctionBody::Return(self.parse_expr()?));
} else {
break;
}
}
Ok(Statement::CreateFunction {
or_replace,
temporary,
name,
args,
return_type,
behavior: body.behavior,
called_on_null: body.called_on_null,
parallel: body.parallel,
language: body.language,
function_body: body.function_body,
if_not_exists: false,
using: None,
determinism_specifier: None,
options: None,
remote_connection: None,
})
}
/// Parse `CREATE FUNCTION` for [Hive]
///
/// [Hive]: https://cwiki.apache.org/confluence/display/hive/languagemanual+ddl#LanguageManualDDL-Create/Drop/ReloadFunction
fn parse_hive_create_function(
&mut self,
or_replace: bool,
temporary: bool,
) -> Result<Statement, ParserError> {
let name = self.parse_object_name(false)?;
self.expect_keyword(Keyword::AS)?;
let as_ = self.parse_create_function_body_string()?;
let using = self.parse_optional_create_function_using()?;
Ok(Statement::CreateFunction {
or_replace,
temporary,
name,
function_body: Some(CreateFunctionBody::AsBeforeOptions(as_)),
using,
if_not_exists: false,
args: None,
return_type: None,
behavior: None,
called_on_null: None,
parallel: None,
language: None,
determinism_specifier: None,
options: None,
remote_connection: None,
})
}
/// Parse `CREATE FUNCTION` for [BigQuery]
///
/// [BigQuery]: https://cloud.google.com/bigquery/docs/reference/standard-sql/data-definition-language#create_function_statement
fn parse_bigquery_create_function(
&mut self,
or_replace: bool,
temporary: bool,
) -> Result<Statement, ParserError> {
let if_not_exists = self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
let name = self.parse_object_name(false)?;
let parse_function_param =
|parser: &mut Parser| -> Result<OperateFunctionArg, ParserError> {
let name = parser.parse_identifier(false)?;
let data_type = parser.parse_data_type()?;
Ok(OperateFunctionArg {
mode: None,
name: Some(name),
data_type,
default_expr: None,
})
};
self.expect_token(&Token::LParen)?;
let args = self.parse_comma_separated0(parse_function_param, Token::RParen)?;
self.expect_token(&Token::RParen)?;
let return_type = if self.parse_keyword(Keyword::RETURNS) {
Some(self.parse_data_type()?)
} else {
None
};
let determinism_specifier = if self.parse_keyword(Keyword::DETERMINISTIC) {
Some(FunctionDeterminismSpecifier::Deterministic)
} else if self.parse_keywords(&[Keyword::NOT, Keyword::DETERMINISTIC]) {
Some(FunctionDeterminismSpecifier::NotDeterministic)
} else {
None
};
let language = if self.parse_keyword(Keyword::LANGUAGE) {
Some(self.parse_identifier(false)?)
} else {
None
};
let remote_connection =
if self.parse_keywords(&[Keyword::REMOTE, Keyword::WITH, Keyword::CONNECTION]) {
Some(self.parse_object_name(false)?)
} else {
None
};
// `OPTIONS` may come before of after the function body but
// may be specified at most once.
let mut options = self.maybe_parse_options(Keyword::OPTIONS)?;
let function_body = if remote_connection.is_none() {
self.expect_keyword(Keyword::AS)?;
let expr = self.parse_expr()?;
if options.is_none() {
options = self.maybe_parse_options(Keyword::OPTIONS)?;
Some(CreateFunctionBody::AsBeforeOptions(expr))
} else {
Some(CreateFunctionBody::AsAfterOptions(expr))
}
} else {
None
};
Ok(Statement::CreateFunction {
or_replace,
temporary,
if_not_exists,
name,
args: Some(args),
return_type,
function_body,
language,
determinism_specifier,
options,
remote_connection,
using: None,
behavior: None,
called_on_null: None,
parallel: None,
})
}
fn parse_function_arg(&mut self) -> Result<OperateFunctionArg, ParserError> {
let mode = if self.parse_keyword(Keyword::IN) {
Some(ArgMode::In)
} else if self.parse_keyword(Keyword::OUT) {
Some(ArgMode::Out)
} else if self.parse_keyword(Keyword::INOUT) {
Some(ArgMode::InOut)
} else {
None
};
// parse: [ argname ] argtype
let mut name = None;
let mut data_type = self.parse_data_type()?;
if let DataType::Custom(n, _) = &data_type {
// the first token is actually a name
name = Some(n.0[0].clone());
data_type = self.parse_data_type()?;
}
let default_expr = if self.parse_keyword(Keyword::DEFAULT) || self.consume_token(&Token::Eq)
{
Some(self.parse_expr()?)
} else {
None
};
Ok(OperateFunctionArg {
mode,
name,
data_type,
default_expr,
})
}
/// Parse statements of the DropTrigger type such as:
///
/// ```sql
/// DROP TRIGGER [ IF EXISTS ] name ON table_name [ CASCADE | RESTRICT ]
/// ```
pub fn parse_drop_trigger(&mut self) -> Result<Statement, ParserError> {
if !dialect_of!(self is PostgreSqlDialect | GenericDialect) {
self.prev_token();
return self.expected("an object type after DROP", self.peek_token());
}
let if_exists = self.parse_keywords(&[Keyword::IF, Keyword::EXISTS]);
let trigger_name = self.parse_object_name(false)?;
self.expect_keyword(Keyword::ON)?;
let table_name = self.parse_object_name(false)?;
let option = self
.parse_one_of_keywords(&[Keyword::CASCADE, Keyword::RESTRICT])
.map(|keyword| match keyword {
Keyword::CASCADE => ReferentialAction::Cascade,
Keyword::RESTRICT => ReferentialAction::Restrict,
_ => unreachable!(),
});
Ok(Statement::DropTrigger {
if_exists,
trigger_name,
table_name,
option,
})
}
pub fn parse_create_trigger(
&mut self,
or_replace: bool,
is_constraint: bool,
) -> Result<Statement, ParserError> {
if !dialect_of!(self is PostgreSqlDialect | GenericDialect) {
self.prev_token();
return self.expected("an object type after CREATE", self.peek_token());
}
let name = self.parse_object_name(false)?;
let period = self.parse_trigger_period()?;
let events = self.parse_keyword_separated(Keyword::OR, Parser::parse_trigger_event)?;
self.expect_keyword(Keyword::ON)?;
let table_name = self.parse_object_name(false)?;
let referenced_table_name = if self.parse_keyword(Keyword::FROM) {
self.parse_object_name(true).ok()
} else {
None
};
let characteristics = self.parse_constraint_characteristics()?;
let mut referencing = vec![];
if self.parse_keyword(Keyword::REFERENCING) {
while let Some(refer) = self.parse_trigger_referencing()? {
referencing.push(refer);
}
}
self.expect_keyword(Keyword::FOR)?;
let include_each = self.parse_keyword(Keyword::EACH);
let trigger_object =
match self.expect_one_of_keywords(&[Keyword::ROW, Keyword::STATEMENT])? {
Keyword::ROW => TriggerObject::Row,
Keyword::STATEMENT => TriggerObject::Statement,
_ => unreachable!(),
};
let condition = self
.parse_keyword(Keyword::WHEN)
.then(|| self.parse_expr())
.transpose()?;
self.expect_keyword(Keyword::EXECUTE)?;
let exec_body = self.parse_trigger_exec_body()?;
Ok(Statement::CreateTrigger {
or_replace,
is_constraint,
name,
period,
events,
table_name,
referenced_table_name,
referencing,
trigger_object,
include_each,
condition,
exec_body,
characteristics,
})
}
pub fn parse_trigger_period(&mut self) -> Result<TriggerPeriod, ParserError> {
Ok(
match self.expect_one_of_keywords(&[
Keyword::BEFORE,
Keyword::AFTER,
Keyword::INSTEAD,
])? {
Keyword::BEFORE => TriggerPeriod::Before,
Keyword::AFTER => TriggerPeriod::After,
Keyword::INSTEAD => self
.expect_keyword(Keyword::OF)
.map(|_| TriggerPeriod::InsteadOf)?,
_ => unreachable!(),
},
)
}
pub fn parse_trigger_event(&mut self) -> Result<TriggerEvent, ParserError> {
Ok(
match self.expect_one_of_keywords(&[
Keyword::INSERT,
Keyword::UPDATE,
Keyword::DELETE,
Keyword::TRUNCATE,
])? {
Keyword::INSERT => TriggerEvent::Insert,
Keyword::UPDATE => {
if self.parse_keyword(Keyword::OF) {
let cols = self.parse_comma_separated(|ident| {
Parser::parse_identifier(ident, false)
})?;
TriggerEvent::Update(cols)
} else {
TriggerEvent::Update(vec![])
}
}
Keyword::DELETE => TriggerEvent::Delete,
Keyword::TRUNCATE => TriggerEvent::Truncate,
_ => unreachable!(),
},
)
}
pub fn parse_trigger_referencing(&mut self) -> Result<Option<TriggerReferencing>, ParserError> {
let refer_type = match self.parse_one_of_keywords(&[Keyword::OLD, Keyword::NEW]) {
Some(Keyword::OLD) if self.parse_keyword(Keyword::TABLE) => {
TriggerReferencingType::OldTable
}
Some(Keyword::NEW) if self.parse_keyword(Keyword::TABLE) => {
TriggerReferencingType::NewTable
}
_ => {
return Ok(None);
}
};
let is_as = self.parse_keyword(Keyword::AS);
let transition_relation_name = self.parse_object_name(false)?;
Ok(Some(TriggerReferencing {
refer_type,
is_as,
transition_relation_name,
}))
}
pub fn parse_trigger_exec_body(&mut self) -> Result<TriggerExecBody, ParserError> {
Ok(TriggerExecBody {
exec_type: match self
.expect_one_of_keywords(&[Keyword::FUNCTION, Keyword::PROCEDURE])?
{
Keyword::FUNCTION => TriggerExecBodyType::Function,
Keyword::PROCEDURE => TriggerExecBodyType::Procedure,
_ => unreachable!(),
},
func_desc: self.parse_function_desc()?,
})
}
pub fn parse_create_macro(
&mut self,
or_replace: bool,
temporary: bool,
) -> Result<Statement, ParserError> {
if dialect_of!(self is DuckDbDialect | GenericDialect) {
let name = self.parse_object_name(false)?;
self.expect_token(&Token::LParen)?;
let args = if self.consume_token(&Token::RParen) {
self.prev_token();
None
} else {
Some(self.parse_comma_separated(Parser::parse_macro_arg)?)
};
self.expect_token(&Token::RParen)?;
self.expect_keyword(Keyword::AS)?;
Ok(Statement::CreateMacro {
or_replace,
temporary,
name,
args,
definition: if self.parse_keyword(Keyword::TABLE) {
MacroDefinition::Table(self.parse_query()?)
} else {
MacroDefinition::Expr(self.parse_expr()?)
},
})
} else {
self.prev_token();
self.expected("an object type after CREATE", self.peek_token())
}
}
fn parse_macro_arg(&mut self) -> Result<MacroArg, ParserError> {
let name = self.parse_identifier(false)?;
let default_expr =
if self.consume_token(&Token::Assignment) || self.consume_token(&Token::RArrow) {
Some(self.parse_expr()?)
} else {
None
};
Ok(MacroArg { name, default_expr })
}
pub fn parse_create_external_table(
&mut self,
or_replace: bool,
) -> Result<Statement, ParserError> {
self.expect_keyword(Keyword::TABLE)?;
let if_not_exists = self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
let table_name = self.parse_object_name(false)?;
let (columns, constraints) = self.parse_columns()?;
let hive_distribution = self.parse_hive_distribution()?;
let hive_formats = self.parse_hive_formats()?;
let file_format = if let Some(ff) = &hive_formats.storage {
match ff {
HiveIOFormat::FileFormat { format } => Some(*format),
_ => None,
}
} else {
None
};
let location = hive_formats.location.clone();
let table_properties = self.parse_options(Keyword::TBLPROPERTIES)?;
Ok(CreateTableBuilder::new(table_name)
.columns(columns)
.constraints(constraints)
.hive_distribution(hive_distribution)
.hive_formats(Some(hive_formats))
.table_properties(table_properties)
.or_replace(or_replace)
.if_not_exists(if_not_exists)
.external(true)
.file_format(file_format)
.location(location)
.build())
}
pub fn parse_file_format(&mut self) -> Result<FileFormat, ParserError> {
let next_token = self.next_token();
match &next_token.token {
Token::Word(w) => match w.keyword {
Keyword::AVRO => Ok(FileFormat::AVRO),
Keyword::JSONFILE => Ok(FileFormat::JSONFILE),
Keyword::ORC => Ok(FileFormat::ORC),
Keyword::PARQUET => Ok(FileFormat::PARQUET),
Keyword::RCFILE => Ok(FileFormat::RCFILE),
Keyword::SEQUENCEFILE => Ok(FileFormat::SEQUENCEFILE),
Keyword::TEXTFILE => Ok(FileFormat::TEXTFILE),
_ => self.expected("fileformat", next_token),
},
_ => self.expected("fileformat", next_token),
}
}
pub fn parse_analyze_format(&mut self) -> Result<AnalyzeFormat, ParserError> {
let next_token = self.next_token();
match &next_token.token {
Token::Word(w) => match w.keyword {
Keyword::TEXT => Ok(AnalyzeFormat::TEXT),
Keyword::GRAPHVIZ => Ok(AnalyzeFormat::GRAPHVIZ),
Keyword::JSON => Ok(AnalyzeFormat::JSON),
_ => self.expected("fileformat", next_token),
},
_ => self.expected("fileformat", next_token),
}
}
pub fn parse_create_view(
&mut self,
or_replace: bool,
temporary: bool,
) -> Result<Statement, ParserError> {
let materialized = self.parse_keyword(Keyword::MATERIALIZED);
self.expect_keyword(Keyword::VIEW)?;
let if_not_exists = dialect_of!(self is BigQueryDialect|SQLiteDialect|GenericDialect)
&& self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
// Many dialects support `OR ALTER` right after `CREATE`, but we don't (yet).
// ANSI SQL and Postgres support RECURSIVE here, but we don't support it either.
let allow_unquoted_hyphen = dialect_of!(self is BigQueryDialect);
let name = self.parse_object_name(allow_unquoted_hyphen)?;
let columns = self.parse_view_columns()?;
let mut options = CreateTableOptions::None;
let with_options = self.parse_options(Keyword::WITH)?;
if !with_options.is_empty() {
options = CreateTableOptions::With(with_options);
}
let cluster_by = if self.parse_keyword(Keyword::CLUSTER) {
self.expect_keyword(Keyword::BY)?;
self.parse_parenthesized_column_list(Optional, false)?
} else {
vec![]
};
if dialect_of!(self is BigQueryDialect | GenericDialect) {
if let Some(opts) = self.maybe_parse_options(Keyword::OPTIONS)? {
if !opts.is_empty() {
options = CreateTableOptions::Options(opts);
}
};
}
let to = if dialect_of!(self is ClickHouseDialect | GenericDialect)
&& self.parse_keyword(Keyword::TO)
{
Some(self.parse_object_name(false)?)
} else {
None
};
let comment = if dialect_of!(self is SnowflakeDialect | GenericDialect)
&& self.parse_keyword(Keyword::COMMENT)
{
self.expect_token(&Token::Eq)?;
let next_token = self.next_token();
match next_token.token {
Token::SingleQuotedString(str) => Some(str),
_ => self.expected("string literal", next_token)?,
}
} else {
None
};
self.expect_keyword(Keyword::AS)?;
let query = self.parse_boxed_query()?;
// Optional `WITH [ CASCADED | LOCAL ] CHECK OPTION` is widely supported here.
let with_no_schema_binding = dialect_of!(self is RedshiftSqlDialect | GenericDialect)
&& self.parse_keywords(&[
Keyword::WITH,
Keyword::NO,
Keyword::SCHEMA,
Keyword::BINDING,
]);
Ok(Statement::CreateView {
name,
columns,
query,
materialized,
or_replace,
options,
cluster_by,
comment,
with_no_schema_binding,
if_not_exists,
temporary,
to,
})
}
pub fn parse_create_role(&mut self) -> Result<Statement, ParserError> {
let if_not_exists = self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
let names = self.parse_comma_separated(|p| p.parse_object_name(false))?;
let _ = self.parse_keyword(Keyword::WITH); // [ WITH ]
let optional_keywords = if dialect_of!(self is MsSqlDialect) {
vec![Keyword::AUTHORIZATION]
} else if dialect_of!(self is PostgreSqlDialect) {
vec![
Keyword::LOGIN,
Keyword::NOLOGIN,
Keyword::INHERIT,
Keyword::NOINHERIT,
Keyword::BYPASSRLS,
Keyword::NOBYPASSRLS,
Keyword::PASSWORD,
Keyword::CREATEDB,
Keyword::NOCREATEDB,
Keyword::CREATEROLE,
Keyword::NOCREATEROLE,
Keyword::SUPERUSER,
Keyword::NOSUPERUSER,
Keyword::REPLICATION,
Keyword::NOREPLICATION,
Keyword::CONNECTION,
Keyword::VALID,
Keyword::IN,
Keyword::ROLE,
Keyword::ADMIN,
Keyword::USER,
]
} else {
vec![]
};
// MSSQL
let mut authorization_owner = None;
// Postgres
let mut login = None;
let mut inherit = None;
let mut bypassrls = None;
let mut password = None;
let mut create_db = None;
let mut create_role = None;
let mut superuser = None;
let mut replication = None;
let mut connection_limit = None;
let mut valid_until = None;
let mut in_role = vec![];
let mut in_group = vec![];
let mut role = vec![];
let mut user = vec![];
let mut admin = vec![];
while let Some(keyword) = self.parse_one_of_keywords(&optional_keywords) {
let loc = self
.tokens
.get(self.index - 1)
.map_or(Location { line: 0, column: 0 }, |t| t.location);
match keyword {
Keyword::AUTHORIZATION => {
if authorization_owner.is_some() {
parser_err!("Found multiple AUTHORIZATION", loc)
} else {
authorization_owner = Some(self.parse_object_name(false)?);
Ok(())
}
}
Keyword::LOGIN | Keyword::NOLOGIN => {
if login.is_some() {
parser_err!("Found multiple LOGIN or NOLOGIN", loc)
} else {
login = Some(keyword == Keyword::LOGIN);
Ok(())
}
}
Keyword::INHERIT | Keyword::NOINHERIT => {
if inherit.is_some() {
parser_err!("Found multiple INHERIT or NOINHERIT", loc)
} else {
inherit = Some(keyword == Keyword::INHERIT);
Ok(())
}
}
Keyword::BYPASSRLS | Keyword::NOBYPASSRLS => {
if bypassrls.is_some() {
parser_err!("Found multiple BYPASSRLS or NOBYPASSRLS", loc)
} else {
bypassrls = Some(keyword == Keyword::BYPASSRLS);
Ok(())
}
}
Keyword::CREATEDB | Keyword::NOCREATEDB => {
if create_db.is_some() {
parser_err!("Found multiple CREATEDB or NOCREATEDB", loc)
} else {
create_db = Some(keyword == Keyword::CREATEDB);
Ok(())
}
}
Keyword::CREATEROLE | Keyword::NOCREATEROLE => {
if create_role.is_some() {
parser_err!("Found multiple CREATEROLE or NOCREATEROLE", loc)
} else {
create_role = Some(keyword == Keyword::CREATEROLE);
Ok(())
}
}
Keyword::SUPERUSER | Keyword::NOSUPERUSER => {
if superuser.is_some() {
parser_err!("Found multiple SUPERUSER or NOSUPERUSER", loc)
} else {
superuser = Some(keyword == Keyword::SUPERUSER);
Ok(())
}
}
Keyword::REPLICATION | Keyword::NOREPLICATION => {
if replication.is_some() {
parser_err!("Found multiple REPLICATION or NOREPLICATION", loc)
} else {
replication = Some(keyword == Keyword::REPLICATION);
Ok(())
}
}
Keyword::PASSWORD => {
if password.is_some() {
parser_err!("Found multiple PASSWORD", loc)
} else {
password = if self.parse_keyword(Keyword::NULL) {
Some(Password::NullPassword)
} else {
Some(Password::Password(Expr::Value(self.parse_value()?)))
};
Ok(())
}
}
Keyword::CONNECTION => {
self.expect_keyword(Keyword::LIMIT)?;
if connection_limit.is_some() {
parser_err!("Found multiple CONNECTION LIMIT", loc)
} else {
connection_limit = Some(Expr::Value(self.parse_number_value()?));
Ok(())
}
}
Keyword::VALID => {
self.expect_keyword(Keyword::UNTIL)?;
if valid_until.is_some() {
parser_err!("Found multiple VALID UNTIL", loc)
} else {
valid_until = Some(Expr::Value(self.parse_value()?));
Ok(())
}
}
Keyword::IN => {
if self.parse_keyword(Keyword::ROLE) {
if !in_role.is_empty() {
parser_err!("Found multiple IN ROLE", loc)
} else {
in_role = self.parse_comma_separated(|p| p.parse_identifier(false))?;
Ok(())
}
} else if self.parse_keyword(Keyword::GROUP) {
if !in_group.is_empty() {
parser_err!("Found multiple IN GROUP", loc)
} else {
in_group = self.parse_comma_separated(|p| p.parse_identifier(false))?;
Ok(())
}
} else {
self.expected("ROLE or GROUP after IN", self.peek_token())
}
}
Keyword::ROLE => {
if !role.is_empty() {
parser_err!("Found multiple ROLE", loc)
} else {
role = self.parse_comma_separated(|p| p.parse_identifier(false))?;
Ok(())
}
}
Keyword::USER => {
if !user.is_empty() {
parser_err!("Found multiple USER", loc)
} else {
user = self.parse_comma_separated(|p| p.parse_identifier(false))?;
Ok(())
}
}
Keyword::ADMIN => {
if !admin.is_empty() {
parser_err!("Found multiple ADMIN", loc)
} else {
admin = self.parse_comma_separated(|p| p.parse_identifier(false))?;
Ok(())
}
}
_ => break,
}?
}
Ok(Statement::CreateRole {
names,
if_not_exists,
login,
inherit,
bypassrls,
password,
create_db,
create_role,
replication,
superuser,
connection_limit,
valid_until,
in_role,
in_group,
role,
user,
admin,
authorization_owner,
})
}
pub fn parse_drop(&mut self) -> Result<Statement, ParserError> {
// MySQL dialect supports `TEMPORARY`
let temporary = dialect_of!(self is MySqlDialect | GenericDialect | DuckDbDialect)
&& self.parse_keyword(Keyword::TEMPORARY);
let persistent = dialect_of!(self is DuckDbDialect)
&& self.parse_one_of_keywords(&[Keyword::PERSISTENT]).is_some();
let object_type = if self.parse_keyword(Keyword::TABLE) {
ObjectType::Table
} else if self.parse_keyword(Keyword::VIEW) {
ObjectType::View
} else if self.parse_keyword(Keyword::INDEX) {
ObjectType::Index
} else if self.parse_keyword(Keyword::ROLE) {
ObjectType::Role
} else if self.parse_keyword(Keyword::SCHEMA) {
ObjectType::Schema
} else if self.parse_keyword(Keyword::SEQUENCE) {
ObjectType::Sequence
} else if self.parse_keyword(Keyword::STAGE) {
ObjectType::Stage
} else if self.parse_keyword(Keyword::FUNCTION) {
return self.parse_drop_function();
} else if self.parse_keyword(Keyword::PROCEDURE) {
return self.parse_drop_procedure();
} else if self.parse_keyword(Keyword::SECRET) {
return self.parse_drop_secret(temporary, persistent);
} else if self.parse_keyword(Keyword::TRIGGER) {
return self.parse_drop_trigger();
} else {
return self.expected(
"TABLE, VIEW, INDEX, ROLE, SCHEMA, FUNCTION, PROCEDURE, STAGE, TRIGGER, SECRET or SEQUENCE after DROP",
self.peek_token(),
);
};
// Many dialects support the non-standard `IF EXISTS` clause and allow
// specifying multiple objects to delete in a single statement
let if_exists = self.parse_keywords(&[Keyword::IF, Keyword::EXISTS]);
let names = self.parse_comma_separated(|p| p.parse_object_name(false))?;
let loc = self.peek_token().location;
let cascade = self.parse_keyword(Keyword::CASCADE);
let restrict = self.parse_keyword(Keyword::RESTRICT);
let purge = self.parse_keyword(Keyword::PURGE);
if cascade && restrict {
return parser_err!("Cannot specify both CASCADE and RESTRICT in DROP", loc);
}
if object_type == ObjectType::Role && (cascade || restrict || purge) {
return parser_err!(
"Cannot specify CASCADE, RESTRICT, or PURGE in DROP ROLE",
loc
);
}
Ok(Statement::Drop {
object_type,
if_exists,
names,
cascade,
restrict,
purge,
temporary,
})
}
/// ```sql
/// DROP FUNCTION [ IF EXISTS ] name [ ( [ [ argmode ] [ argname ] argtype [, ...] ] ) ] [, ...]
/// [ CASCADE | RESTRICT ]
/// ```
fn parse_drop_function(&mut self) -> Result<Statement, ParserError> {
let if_exists = self.parse_keywords(&[Keyword::IF, Keyword::EXISTS]);
let func_desc = self.parse_comma_separated(Parser::parse_function_desc)?;
let option = match self.parse_one_of_keywords(&[Keyword::CASCADE, Keyword::RESTRICT]) {
Some(Keyword::CASCADE) => Some(ReferentialAction::Cascade),
Some(Keyword::RESTRICT) => Some(ReferentialAction::Restrict),
_ => None,
};
Ok(Statement::DropFunction {
if_exists,
func_desc,
option,
})
}
/// ```sql
/// DROP PROCEDURE [ IF EXISTS ] name [ ( [ [ argmode ] [ argname ] argtype [, ...] ] ) ] [, ...]
/// [ CASCADE | RESTRICT ]
/// ```
fn parse_drop_procedure(&mut self) -> Result<Statement, ParserError> {
let if_exists = self.parse_keywords(&[Keyword::IF, Keyword::EXISTS]);
let proc_desc = self.parse_comma_separated(Parser::parse_function_desc)?;
let option = match self.parse_one_of_keywords(&[Keyword::CASCADE, Keyword::RESTRICT]) {
Some(Keyword::CASCADE) => Some(ReferentialAction::Cascade),
Some(Keyword::RESTRICT) => Some(ReferentialAction::Restrict),
Some(_) => unreachable!(), // parse_one_of_keywords does not return other keywords
None => None,
};
Ok(Statement::DropProcedure {
if_exists,
proc_desc,
option,
})
}
fn parse_function_desc(&mut self) -> Result<FunctionDesc, ParserError> {
let name = self.parse_object_name(false)?;
let args = if self.consume_token(&Token::LParen) {
if self.consume_token(&Token::RParen) {
None
} else {
let args = self.parse_comma_separated(Parser::parse_function_arg)?;
self.expect_token(&Token::RParen)?;
Some(args)
}
} else {
None
};
Ok(FunctionDesc { name, args })
}
/// See [DuckDB Docs](https://duckdb.org/docs/sql/statements/create_secret.html) for more details.
fn parse_drop_secret(
&mut self,
temporary: bool,
persistent: bool,
) -> Result<Statement, ParserError> {
let if_exists = self.parse_keywords(&[Keyword::IF, Keyword::EXISTS]);
let name = self.parse_identifier(false)?;
let storage_specifier = if self.parse_keyword(Keyword::FROM) {
self.parse_identifier(false).ok()
} else {
None
};
let temp = match (temporary, persistent) {
(true, false) => Some(true),
(false, true) => Some(false),
(false, false) => None,
_ => self.expected("TEMPORARY or PERSISTENT", self.peek_token())?,
};
Ok(Statement::DropSecret {
if_exists,
temporary: temp,
name,
storage_specifier,
})
}
/// Parse a `DECLARE` statement.
///
/// ```sql
/// DECLARE name [ BINARY ] [ ASENSITIVE | INSENSITIVE ] [ [ NO ] SCROLL ]
/// CURSOR [ { WITH | WITHOUT } HOLD ] FOR query
/// ```
///
/// The syntax can vary significantly between warehouses. See the grammar
/// on the warehouse specific function in such cases.
pub fn parse_declare(&mut self) -> Result<Statement, ParserError> {
if dialect_of!(self is BigQueryDialect) {
return self.parse_big_query_declare();
}
if dialect_of!(self is SnowflakeDialect) {
return self.parse_snowflake_declare();
}
if dialect_of!(self is MsSqlDialect) {
return self.parse_mssql_declare();
}
let name = self.parse_identifier(false)?;
let binary = Some(self.parse_keyword(Keyword::BINARY));
let sensitive = if self.parse_keyword(Keyword::INSENSITIVE) {
Some(true)
} else if self.parse_keyword(Keyword::ASENSITIVE) {
Some(false)
} else {
None
};
let scroll = if self.parse_keyword(Keyword::SCROLL) {
Some(true)
} else if self.parse_keywords(&[Keyword::NO, Keyword::SCROLL]) {
Some(false)
} else {
None
};
self.expect_keyword(Keyword::CURSOR)?;
let declare_type = Some(DeclareType::Cursor);
let hold = match self.parse_one_of_keywords(&[Keyword::WITH, Keyword::WITHOUT]) {
Some(keyword) => {
self.expect_keyword(Keyword::HOLD)?;
match keyword {
Keyword::WITH => Some(true),
Keyword::WITHOUT => Some(false),
_ => unreachable!(),
}
}
None => None,
};
self.expect_keyword(Keyword::FOR)?;
let query = Some(self.parse_boxed_query()?);
Ok(Statement::Declare {
stmts: vec![Declare {
names: vec![name],
data_type: None,
assignment: None,
declare_type,
binary,
sensitive,
scroll,
hold,
for_query: query,
}],
})
}
/// Parse a [BigQuery] `DECLARE` statement.
///
/// Syntax:
/// ```text
/// DECLARE variable_name[, ...] [{ <variable_type> | <DEFAULT expression> }];
/// ```
/// [BigQuery]: https://cloud.google.com/bigquery/docs/reference/standard-sql/procedural-language#declare
pub fn parse_big_query_declare(&mut self) -> Result<Statement, ParserError> {
let names = self.parse_comma_separated(|parser| Parser::parse_identifier(parser, false))?;
let data_type = match self.peek_token().token {
Token::Word(w) if w.keyword == Keyword::DEFAULT => None,
_ => Some(self.parse_data_type()?),
};
let expr = if data_type.is_some() {
if self.parse_keyword(Keyword::DEFAULT) {
Some(self.parse_expr()?)
} else {
None
}
} else {
// If no variable type - default expression must be specified, per BQ docs.
// i.e `DECLARE foo;` is invalid.
self.expect_keyword(Keyword::DEFAULT)?;
Some(self.parse_expr()?)
};
Ok(Statement::Declare {
stmts: vec![Declare {
names,
data_type,
assignment: expr.map(|expr| DeclareAssignment::Default(Box::new(expr))),
declare_type: None,
binary: None,
sensitive: None,
scroll: None,
hold: None,
for_query: None,
}],
})
}
/// Parse a [Snowflake] `DECLARE` statement.
///
/// Syntax:
/// ```text
/// DECLARE
/// [{ <variable_declaration>
/// | <cursor_declaration>
/// | <resultset_declaration>
/// | <exception_declaration> }; ... ]
///
/// <variable_declaration>
/// <variable_name> [<type>] [ { DEFAULT | := } <expression>]
///
/// <cursor_declaration>
/// <cursor_name> CURSOR FOR <query>
///
/// <resultset_declaration>
/// <resultset_name> RESULTSET [ { DEFAULT | := } ( <query> ) ] ;
///
/// <exception_declaration>
/// <exception_name> EXCEPTION [ ( <exception_number> , '<exception_message>' ) ] ;
/// ```
///
/// [Snowflake]: https://docs.snowflake.com/en/sql-reference/snowflake-scripting/declare
pub fn parse_snowflake_declare(&mut self) -> Result<Statement, ParserError> {
let mut stmts = vec![];
loop {
let name = self.parse_identifier(false)?;
let (declare_type, for_query, assigned_expr, data_type) =
if self.parse_keyword(Keyword::CURSOR) {
self.expect_keyword(Keyword::FOR)?;
match self.peek_token().token {
Token::Word(w) if w.keyword == Keyword::SELECT => (
Some(DeclareType::Cursor),
Some(self.parse_boxed_query()?),
None,
None,
),
_ => (
Some(DeclareType::Cursor),
None,
Some(DeclareAssignment::For(Box::new(self.parse_expr()?))),
None,
),
}
} else if self.parse_keyword(Keyword::RESULTSET) {
let assigned_expr = if self.peek_token().token != Token::SemiColon {
self.parse_snowflake_variable_declaration_expression()?
} else {
// Nothing more to do. The statement has no further parameters.
None
};
(Some(DeclareType::ResultSet), None, assigned_expr, None)
} else if self.parse_keyword(Keyword::EXCEPTION) {
let assigned_expr = if self.peek_token().token == Token::LParen {
Some(DeclareAssignment::Expr(Box::new(self.parse_expr()?)))
} else {
// Nothing more to do. The statement has no further parameters.
None
};
(Some(DeclareType::Exception), None, assigned_expr, None)
} else {
// Without an explicit keyword, the only valid option is variable declaration.
let (assigned_expr, data_type) = if let Some(assigned_expr) =
self.parse_snowflake_variable_declaration_expression()?
{
(Some(assigned_expr), None)
} else if let Token::Word(_) = self.peek_token().token {
let data_type = self.parse_data_type()?;
(
self.parse_snowflake_variable_declaration_expression()?,
Some(data_type),
)
} else {
(None, None)
};
(None, None, assigned_expr, data_type)
};
let stmt = Declare {
names: vec![name],
data_type,
assignment: assigned_expr,
declare_type,
binary: None,
sensitive: None,
scroll: None,
hold: None,
for_query,
};
stmts.push(stmt);
if self.consume_token(&Token::SemiColon) {
match self.peek_token().token {
Token::Word(w)
if ALL_KEYWORDS
.binary_search(&w.value.to_uppercase().as_str())
.is_err() =>
{
// Not a keyword - start of a new declaration.
continue;
}
_ => {
// Put back the semicolon, this is the end of the DECLARE statement.
self.prev_token();
}
}
}
break;
}
Ok(Statement::Declare { stmts })
}
/// Parse a [MsSql] `DECLARE` statement.
///
/// Syntax:
/// ```text
/// DECLARE
// {
// { @local_variable [AS] data_type [ = value ] }
// | { @cursor_variable_name CURSOR }
// } [ ,...n ]
/// ```
/// [MsSql]: https://learn.microsoft.com/en-us/sql/t-sql/language-elements/declare-local-variable-transact-sql?view=sql-server-ver16
pub fn parse_mssql_declare(&mut self) -> Result<Statement, ParserError> {
let mut stmts = vec![];
loop {
let name = {
let ident = self.parse_identifier(false)?;
if !ident.value.starts_with('@') {
Err(ParserError::TokenizerError(
"Invalid MsSql variable declaration.".to_string(),
))
} else {
Ok(ident)
}
}?;
let (declare_type, data_type) = match self.peek_token().token {
Token::Word(w) => match w.keyword {
Keyword::CURSOR => {
self.next_token();
(Some(DeclareType::Cursor), None)
}
Keyword::AS => {
self.next_token();
(None, Some(self.parse_data_type()?))
}
_ => (None, Some(self.parse_data_type()?)),
},
_ => (None, Some(self.parse_data_type()?)),
};
let assignment = self.parse_mssql_variable_declaration_expression()?;
stmts.push(Declare {
names: vec![name],
data_type,
assignment,
declare_type,
binary: None,
sensitive: None,
scroll: None,
hold: None,
for_query: None,
});
if self.next_token() != Token::Comma {
break;
}
}
Ok(Statement::Declare { stmts })
}
/// Parses the assigned expression in a variable declaration.
///
/// Syntax:
/// ```text
/// [ { DEFAULT | := } <expression>]
/// ```
/// <https://docs.snowflake.com/en/sql-reference/snowflake-scripting/declare#variable-declaration-syntax>
pub fn parse_snowflake_variable_declaration_expression(
&mut self,
) -> Result<Option<DeclareAssignment>, ParserError> {
Ok(match self.peek_token().token {
Token::Word(w) if w.keyword == Keyword::DEFAULT => {
self.next_token(); // Skip `DEFAULT`
Some(DeclareAssignment::Default(Box::new(self.parse_expr()?)))
}
Token::Assignment => {
self.next_token(); // Skip `:=`
Some(DeclareAssignment::DuckAssignment(Box::new(
self.parse_expr()?,
)))
}
_ => None,
})
}
/// Parses the assigned expression in a variable declaration.
///
/// Syntax:
/// ```text
/// [ = <expression>]
/// ```
pub fn parse_mssql_variable_declaration_expression(
&mut self,
) -> Result<Option<DeclareAssignment>, ParserError> {
Ok(match self.peek_token().token {
Token::Eq => {
self.next_token(); // Skip `=`
Some(DeclareAssignment::MsSqlAssignment(Box::new(
self.parse_expr()?,
)))
}
_ => None,
})
}
// FETCH [ direction { FROM | IN } ] cursor INTO target;
pub fn parse_fetch_statement(&mut self) -> Result<Statement, ParserError> {
let direction = if self.parse_keyword(Keyword::NEXT) {
FetchDirection::Next
} else if self.parse_keyword(Keyword::PRIOR) {
FetchDirection::Prior
} else if self.parse_keyword(Keyword::FIRST) {
FetchDirection::First
} else if self.parse_keyword(Keyword::LAST) {
FetchDirection::Last
} else if self.parse_keyword(Keyword::ABSOLUTE) {
FetchDirection::Absolute {
limit: self.parse_number_value()?,
}
} else if self.parse_keyword(Keyword::RELATIVE) {
FetchDirection::Relative {
limit: self.parse_number_value()?,
}
} else if self.parse_keyword(Keyword::FORWARD) {
if self.parse_keyword(Keyword::ALL) {
FetchDirection::ForwardAll
} else {
FetchDirection::Forward {
// TODO: Support optional
limit: Some(self.parse_number_value()?),
}
}
} else if self.parse_keyword(Keyword::BACKWARD) {
if self.parse_keyword(Keyword::ALL) {
FetchDirection::BackwardAll
} else {
FetchDirection::Backward {
// TODO: Support optional
limit: Some(self.parse_number_value()?),
}
}
} else if self.parse_keyword(Keyword::ALL) {
FetchDirection::All
} else {
FetchDirection::Count {
limit: self.parse_number_value()?,
}
};
self.expect_one_of_keywords(&[Keyword::FROM, Keyword::IN])?;
let name = self.parse_identifier(false)?;
let into = if self.parse_keyword(Keyword::INTO) {
Some(self.parse_object_name(false)?)
} else {
None
};
Ok(Statement::Fetch {
name,
direction,
into,
})
}
pub fn parse_discard(&mut self) -> Result<Statement, ParserError> {
let object_type = if self.parse_keyword(Keyword::ALL) {
DiscardObject::ALL
} else if self.parse_keyword(Keyword::PLANS) {
DiscardObject::PLANS
} else if self.parse_keyword(Keyword::SEQUENCES) {
DiscardObject::SEQUENCES
} else if self.parse_keyword(Keyword::TEMP) || self.parse_keyword(Keyword::TEMPORARY) {
DiscardObject::TEMP
} else {
return self.expected(
"ALL, PLANS, SEQUENCES, TEMP or TEMPORARY after DISCARD",
self.peek_token(),
);
};
Ok(Statement::Discard { object_type })
}
pub fn parse_create_index(&mut self, unique: bool) -> Result<Statement, ParserError> {
let concurrently = self.parse_keyword(Keyword::CONCURRENTLY);
let if_not_exists = self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
let index_name = if if_not_exists || !self.parse_keyword(Keyword::ON) {
let index_name = self.parse_object_name(false)?;
self.expect_keyword(Keyword::ON)?;
Some(index_name)
} else {
None
};
let table_name = self.parse_object_name(false)?;
let using = if self.parse_keyword(Keyword::USING) {
Some(self.parse_identifier(false)?)
} else {
None
};
self.expect_token(&Token::LParen)?;
let columns = self.parse_comma_separated(Parser::parse_order_by_expr)?;
self.expect_token(&Token::RParen)?;
let include = if self.parse_keyword(Keyword::INCLUDE) {
self.expect_token(&Token::LParen)?;
let columns = self.parse_comma_separated(|p| p.parse_identifier(false))?;
self.expect_token(&Token::RParen)?;
columns
} else {
vec![]
};
let nulls_distinct = if self.parse_keyword(Keyword::NULLS) {
let not = self.parse_keyword(Keyword::NOT);
self.expect_keyword(Keyword::DISTINCT)?;
Some(!not)
} else {
None
};
let predicate = if self.parse_keyword(Keyword::WHERE) {
Some(self.parse_expr()?)
} else {
None
};
Ok(Statement::CreateIndex(CreateIndex {
name: index_name,
table_name,
using,
columns,
unique,
concurrently,
if_not_exists,
include,
nulls_distinct,
predicate,
}))
}
pub fn parse_create_extension(&mut self) -> Result<Statement, ParserError> {
let if_not_exists = self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
let name = self.parse_identifier(false)?;
let (schema, version, cascade) = if self.parse_keyword(Keyword::WITH) {
let schema = if self.parse_keyword(Keyword::SCHEMA) {
Some(self.parse_identifier(false)?)
} else {
None
};
let version = if self.parse_keyword(Keyword::VERSION) {
Some(self.parse_identifier(false)?)
} else {
None
};
let cascade = self.parse_keyword(Keyword::CASCADE);
(schema, version, cascade)
} else {
(None, None, false)
};
Ok(Statement::CreateExtension {
name,
if_not_exists,
schema,
version,
cascade,
})
}
//TODO: Implement parsing for Skewed and Clustered
pub fn parse_hive_distribution(&mut self) -> Result<HiveDistributionStyle, ParserError> {
if self.parse_keywords(&[Keyword::PARTITIONED, Keyword::BY]) {
self.expect_token(&Token::LParen)?;
let columns = self.parse_comma_separated(Parser::parse_column_def)?;
self.expect_token(&Token::RParen)?;
Ok(HiveDistributionStyle::PARTITIONED { columns })
} else {
Ok(HiveDistributionStyle::NONE)
}
}
pub fn parse_hive_formats(&mut self) -> Result<HiveFormat, ParserError> {
let mut hive_format = HiveFormat::default();
loop {
match self.parse_one_of_keywords(&[
Keyword::ROW,
Keyword::STORED,
Keyword::LOCATION,
Keyword::WITH,
]) {
Some(Keyword::ROW) => {
hive_format.row_format = Some(self.parse_row_format()?);
}
Some(Keyword::STORED) => {
self.expect_keyword(Keyword::AS)?;
if self.parse_keyword(Keyword::INPUTFORMAT) {
let input_format = self.parse_expr()?;
self.expect_keyword(Keyword::OUTPUTFORMAT)?;
let output_format = self.parse_expr()?;
hive_format.storage = Some(HiveIOFormat::IOF {
input_format,
output_format,
});
} else {
let format = self.parse_file_format()?;
hive_format.storage = Some(HiveIOFormat::FileFormat { format });
}
}
Some(Keyword::LOCATION) => {
hive_format.location = Some(self.parse_literal_string()?);
}
Some(Keyword::WITH) => {
self.prev_token();
let properties = self
.parse_options_with_keywords(&[Keyword::WITH, Keyword::SERDEPROPERTIES])?;
if !properties.is_empty() {
hive_format.serde_properties = Some(properties);
} else {
break;
}
}
None => break,
_ => break,
}
}
Ok(hive_format)
}
pub fn parse_row_format(&mut self) -> Result<HiveRowFormat, ParserError> {
self.expect_keyword(Keyword::FORMAT)?;
match self.parse_one_of_keywords(&[Keyword::SERDE, Keyword::DELIMITED]) {
Some(Keyword::SERDE) => {
let class = self.parse_literal_string()?;
Ok(HiveRowFormat::SERDE { class })
}
_ => {
let mut row_delimiters = vec![];
loop {
match self.parse_one_of_keywords(&[
Keyword::FIELDS,
Keyword::COLLECTION,
Keyword::MAP,
Keyword::LINES,
Keyword::NULL,
]) {
Some(Keyword::FIELDS) => {
if self.parse_keywords(&[Keyword::TERMINATED, Keyword::BY]) {
row_delimiters.push(HiveRowDelimiter {
delimiter: HiveDelimiter::FieldsTerminatedBy,
char: self.parse_identifier(false)?,
});
if self.parse_keywords(&[Keyword::ESCAPED, Keyword::BY]) {
row_delimiters.push(HiveRowDelimiter {
delimiter: HiveDelimiter::FieldsEscapedBy,
char: self.parse_identifier(false)?,
});
}
} else {
break;
}
}
Some(Keyword::COLLECTION) => {
if self.parse_keywords(&[
Keyword::ITEMS,
Keyword::TERMINATED,
Keyword::BY,
]) {
row_delimiters.push(HiveRowDelimiter {
delimiter: HiveDelimiter::CollectionItemsTerminatedBy,
char: self.parse_identifier(false)?,
});
} else {
break;
}
}
Some(Keyword::MAP) => {
if self.parse_keywords(&[
Keyword::KEYS,
Keyword::TERMINATED,
Keyword::BY,
]) {
row_delimiters.push(HiveRowDelimiter {
delimiter: HiveDelimiter::MapKeysTerminatedBy,
char: self.parse_identifier(false)?,
});
} else {
break;
}
}
Some(Keyword::LINES) => {
if self.parse_keywords(&[Keyword::TERMINATED, Keyword::BY]) {
row_delimiters.push(HiveRowDelimiter {
delimiter: HiveDelimiter::LinesTerminatedBy,
char: self.parse_identifier(false)?,
});
} else {
break;
}
}
Some(Keyword::NULL) => {
if self.parse_keywords(&[Keyword::DEFINED, Keyword::AS]) {
row_delimiters.push(HiveRowDelimiter {
delimiter: HiveDelimiter::NullDefinedAs,
char: self.parse_identifier(false)?,
});
} else {
break;
}
}
_ => {
break;
}
}
}
Ok(HiveRowFormat::DELIMITED {
delimiters: row_delimiters,
})
}
}
}
fn parse_optional_on_cluster(&mut self) -> Result<Option<Ident>, ParserError> {
if self.parse_keywords(&[Keyword::ON, Keyword::CLUSTER]) {
Ok(Some(self.parse_identifier(false)?))
} else {
Ok(None)
}
}
pub fn parse_create_table(
&mut self,
or_replace: bool,
temporary: bool,
global: Option<bool>,
transient: bool,
) -> Result<Statement, ParserError> {
let allow_unquoted_hyphen = dialect_of!(self is BigQueryDialect);
let if_not_exists = self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
let table_name = self.parse_object_name(allow_unquoted_hyphen)?;
// Clickhouse has `ON CLUSTER 'cluster'` syntax for DDLs
let on_cluster = self.parse_optional_on_cluster()?;
let like = if self.parse_keyword(Keyword::LIKE) || self.parse_keyword(Keyword::ILIKE) {
self.parse_object_name(allow_unquoted_hyphen).ok()
} else {
None
};
let clone = if self.parse_keyword(Keyword::CLONE) {
self.parse_object_name(allow_unquoted_hyphen).ok()
} else {
None
};
// parse optional column list (schema)
let (columns, constraints) = self.parse_columns()?;
// SQLite supports `WITHOUT ROWID` at the end of `CREATE TABLE`
let without_rowid = self.parse_keywords(&[Keyword::WITHOUT, Keyword::ROWID]);
let hive_distribution = self.parse_hive_distribution()?;
let hive_formats = self.parse_hive_formats()?;
// PostgreSQL supports `WITH ( options )`, before `AS`
let with_options = self.parse_options(Keyword::WITH)?;
let table_properties = self.parse_options(Keyword::TBLPROPERTIES)?;
let engine = if self.parse_keyword(Keyword::ENGINE) {
self.expect_token(&Token::Eq)?;
let next_token = self.next_token();
match next_token.token {
Token::Word(w) => {
let name = w.value;
let parameters = if self.peek_token() == Token::LParen {
Some(self.parse_parenthesized_identifiers()?)
} else {
None
};
Some(TableEngine { name, parameters })
}
_ => self.expected("identifier", next_token)?,
}
} else {
None
};
let auto_increment_offset = if self.parse_keyword(Keyword::AUTO_INCREMENT) {
let _ = self.consume_token(&Token::Eq);
let next_token = self.next_token();
match next_token.token {
Token::Number(s, _) => Some(Self::parse::<u32>(s, next_token.location)?),
_ => self.expected("literal int", next_token)?,
}
} else {
None
};
// ClickHouse supports `PRIMARY KEY`, before `ORDER BY`
// https://clickhouse.com/docs/en/sql-reference/statements/create/table#primary-key
let primary_key = if dialect_of!(self is ClickHouseDialect | GenericDialect)
&& self.parse_keywords(&[Keyword::PRIMARY, Keyword::KEY])
{
Some(Box::new(self.parse_expr()?))
} else {
None
};
let order_by = if self.parse_keywords(&[Keyword::ORDER, Keyword::BY]) {
if self.consume_token(&Token::LParen) {
let columns = if self.peek_token() != Token::RParen {
self.parse_comma_separated(|p| p.parse_expr())?
} else {
vec![]
};
self.expect_token(&Token::RParen)?;
Some(OneOrManyWithParens::Many(columns))
} else {
Some(OneOrManyWithParens::One(self.parse_expr()?))
}
} else {
None
};
let create_table_config = self.parse_optional_create_table_config()?;
let default_charset = if self.parse_keywords(&[Keyword::DEFAULT, Keyword::CHARSET]) {
self.expect_token(&Token::Eq)?;
let next_token = self.next_token();
match next_token.token {
Token::Word(w) => Some(w.value),
_ => self.expected("identifier", next_token)?,
}
} else {
None
};
let collation = if self.parse_keywords(&[Keyword::COLLATE]) {
self.expect_token(&Token::Eq)?;
let next_token = self.next_token();
match next_token.token {
Token::Word(w) => Some(w.value),
_ => self.expected("identifier", next_token)?,
}
} else {
None
};
let on_commit: Option<OnCommit> =
if self.parse_keywords(&[Keyword::ON, Keyword::COMMIT, Keyword::DELETE, Keyword::ROWS])
{
Some(OnCommit::DeleteRows)
} else if self.parse_keywords(&[
Keyword::ON,
Keyword::COMMIT,
Keyword::PRESERVE,
Keyword::ROWS,
]) {
Some(OnCommit::PreserveRows)
} else if self.parse_keywords(&[Keyword::ON, Keyword::COMMIT, Keyword::DROP]) {
Some(OnCommit::Drop)
} else {
None
};
let strict = self.parse_keyword(Keyword::STRICT);
let comment = if self.parse_keyword(Keyword::COMMENT) {
let _ = self.consume_token(&Token::Eq);
let next_token = self.next_token();
match next_token.token {
Token::SingleQuotedString(str) => Some(CommentDef::WithoutEq(str)),
_ => self.expected("comment", next_token)?,
}
} else {
None
};
// Parse optional `AS ( query )`
let query = if self.parse_keyword(Keyword::AS) {
Some(self.parse_boxed_query()?)
} else {
None
};
Ok(CreateTableBuilder::new(table_name)
.temporary(temporary)
.columns(columns)
.constraints(constraints)
.with_options(with_options)
.table_properties(table_properties)
.or_replace(or_replace)
.if_not_exists(if_not_exists)
.transient(transient)
.hive_distribution(hive_distribution)
.hive_formats(Some(hive_formats))
.global(global)
.query(query)
.without_rowid(without_rowid)
.like(like)
.clone_clause(clone)
.engine(engine)
.comment(comment)
.auto_increment_offset(auto_increment_offset)
.order_by(order_by)
.default_charset(default_charset)
.collation(collation)
.on_commit(on_commit)
.on_cluster(on_cluster)
.partition_by(create_table_config.partition_by)
.cluster_by(create_table_config.cluster_by)
.options(create_table_config.options)
.primary_key(primary_key)
.strict(strict)
.build())
}
/// Parse configuration like partitioning, clustering information during the table creation.
///
/// [BigQuery](https://cloud.google.com/bigquery/docs/reference/standard-sql/data-definition-language#syntax_2)
/// [PostgreSQL](https://www.postgresql.org/docs/current/ddl-partitioning.html)
fn parse_optional_create_table_config(
&mut self,
) -> Result<CreateTableConfiguration, ParserError> {
let partition_by = if dialect_of!(self is BigQueryDialect | PostgreSqlDialect | GenericDialect)
&& self.parse_keywords(&[Keyword::PARTITION, Keyword::BY])
{
Some(Box::new(self.parse_expr()?))
} else {
None
};
let mut cluster_by = None;
let mut options = None;
if dialect_of!(self is BigQueryDialect | GenericDialect) {
if self.parse_keywords(&[Keyword::CLUSTER, Keyword::BY]) {
cluster_by = Some(WrappedCollection::NoWrapping(
self.parse_comma_separated(|p| p.parse_identifier(false))?,
));
};
if let Token::Word(word) = self.peek_token().token {
if word.keyword == Keyword::OPTIONS {
options = Some(self.parse_options(Keyword::OPTIONS)?);
}
};
}
Ok(CreateTableConfiguration {
partition_by,
cluster_by,
options,
})
}
pub fn parse_optional_procedure_parameters(
&mut self,
) -> Result<Option<Vec<ProcedureParam>>, ParserError> {
let mut params = vec![];
if !self.consume_token(&Token::LParen) || self.consume_token(&Token::RParen) {
return Ok(Some(params));
}
loop {
if let Token::Word(_) = self.peek_token().token {
params.push(self.parse_procedure_param()?)
}
let comma = self.consume_token(&Token::Comma);
if self.consume_token(&Token::RParen) {
// allow a trailing comma, even though it's not in standard
break;
} else if !comma {
return self.expected("',' or ')' after parameter definition", self.peek_token());
}
}
Ok(Some(params))
}
pub fn parse_columns(&mut self) -> Result<(Vec<ColumnDef>, Vec<TableConstraint>), ParserError> {
let mut columns = vec![];
let mut constraints = vec![];
if !self.consume_token(&Token::LParen) || self.consume_token(&Token::RParen) {
return Ok((columns, constraints));
}
loop {
if let Some(constraint) = self.parse_optional_table_constraint()? {
constraints.push(constraint);
} else if let Token::Word(_) = self.peek_token().token {
columns.push(self.parse_column_def()?);
} else {
return self.expected("column name or constraint definition", self.peek_token());
}
let comma = self.consume_token(&Token::Comma);
let rparen = self.peek_token().token == Token::RParen;
if !comma && !rparen {
return self.expected("',' or ')' after column definition", self.peek_token());
};
if rparen && (!comma || self.options.trailing_commas) {
let _ = self.consume_token(&Token::RParen);
break;
}
}
Ok((columns, constraints))
}
pub fn parse_procedure_param(&mut self) -> Result<ProcedureParam, ParserError> {
let name = self.parse_identifier(false)?;
let data_type = self.parse_data_type()?;
Ok(ProcedureParam { name, data_type })
}
pub fn parse_column_def(&mut self) -> Result<ColumnDef, ParserError> {
let name = self.parse_identifier(false)?;
let data_type = if self.is_column_type_sqlite_unspecified() {
DataType::Unspecified
} else {
self.parse_data_type()?
};
let mut collation = if self.parse_keyword(Keyword::COLLATE) {
Some(self.parse_object_name(false)?)
} else {
None
};
let mut options = vec![];
loop {
if self.parse_keyword(Keyword::CONSTRAINT) {
let name = Some(self.parse_identifier(false)?);
if let Some(option) = self.parse_optional_column_option()? {
options.push(ColumnOptionDef { name, option });
} else {
return self.expected(
"constraint details after CONSTRAINT <name>",
self.peek_token(),
);
}
} else if let Some(option) = self.parse_optional_column_option()? {
options.push(ColumnOptionDef { name: None, option });
} else if dialect_of!(self is MySqlDialect | GenericDialect)
&& self.parse_keyword(Keyword::COLLATE)
{
collation = Some(self.parse_object_name(false)?);
} else {
break;
};
}
Ok(ColumnDef {
name,
data_type,
collation,
options,
})
}
fn is_column_type_sqlite_unspecified(&mut self) -> bool {
if dialect_of!(self is SQLiteDialect) {
match self.peek_token().token {
Token::Word(word) => matches!(
word.keyword,
Keyword::CONSTRAINT
| Keyword::PRIMARY
| Keyword::NOT
| Keyword::UNIQUE
| Keyword::CHECK
| Keyword::DEFAULT
| Keyword::COLLATE
| Keyword::REFERENCES
| Keyword::GENERATED
| Keyword::AS
),
_ => true, // e.g. comma immediately after column name
}
} else {
false
}
}
pub fn parse_optional_column_option(&mut self) -> Result<Option<ColumnOption>, ParserError> {
if self.parse_keywords(&[Keyword::CHARACTER, Keyword::SET]) {
Ok(Some(ColumnOption::CharacterSet(
self.parse_object_name(false)?,
)))
} else if self.parse_keywords(&[Keyword::NOT, Keyword::NULL]) {
Ok(Some(ColumnOption::NotNull))
} else if self.parse_keywords(&[Keyword::COMMENT]) {
let next_token = self.next_token();
match next_token.token {
Token::SingleQuotedString(value, ..) => Ok(Some(ColumnOption::Comment(value))),
_ => self.expected("string", next_token),
}
} else if self.parse_keyword(Keyword::NULL) {
Ok(Some(ColumnOption::Null))
} else if self.parse_keyword(Keyword::DEFAULT) {
Ok(Some(ColumnOption::Default(self.parse_expr()?)))
} else if dialect_of!(self is ClickHouseDialect| GenericDialect)
&& self.parse_keyword(Keyword::MATERIALIZED)
{
Ok(Some(ColumnOption::Materialized(self.parse_expr()?)))
} else if dialect_of!(self is ClickHouseDialect| GenericDialect)
&& self.parse_keyword(Keyword::ALIAS)
{
Ok(Some(ColumnOption::Alias(self.parse_expr()?)))
} else if dialect_of!(self is ClickHouseDialect| GenericDialect)
&& self.parse_keyword(Keyword::EPHEMERAL)
{
// The expression is optional for the EPHEMERAL syntax, so we need to check
// if the column definition has remaining tokens before parsing the expression.
if matches!(self.peek_token().token, Token::Comma | Token::RParen) {
Ok(Some(ColumnOption::Ephemeral(None)))
} else {
Ok(Some(ColumnOption::Ephemeral(Some(self.parse_expr()?))))
}
} else if self.parse_keywords(&[Keyword::PRIMARY, Keyword::KEY]) {
let characteristics = self.parse_constraint_characteristics()?;
Ok(Some(ColumnOption::Unique {
is_primary: true,
characteristics,
}))
} else if self.parse_keyword(Keyword::UNIQUE) {
let characteristics = self.parse_constraint_characteristics()?;
Ok(Some(ColumnOption::Unique {
is_primary: false,
characteristics,
}))
} else if self.parse_keyword(Keyword::REFERENCES) {
let foreign_table = self.parse_object_name(false)?;
// PostgreSQL allows omitting the column list and
// uses the primary key column of the foreign table by default
let referred_columns = self.parse_parenthesized_column_list(Optional, false)?;
let mut on_delete = None;
let mut on_update = None;
loop {
if on_delete.is_none() && self.parse_keywords(&[Keyword::ON, Keyword::DELETE]) {
on_delete = Some(self.parse_referential_action()?);
} else if on_update.is_none()
&& self.parse_keywords(&[Keyword::ON, Keyword::UPDATE])
{
on_update = Some(self.parse_referential_action()?);
} else {
break;
}
}
let characteristics = self.parse_constraint_characteristics()?;
Ok(Some(ColumnOption::ForeignKey {
foreign_table,
referred_columns,
on_delete,
on_update,
characteristics,
}))
} else if self.parse_keyword(Keyword::CHECK) {
self.expect_token(&Token::LParen)?;
let expr = self.parse_expr()?;
self.expect_token(&Token::RParen)?;
Ok(Some(ColumnOption::Check(expr)))
} else if self.parse_keyword(Keyword::AUTO_INCREMENT)
&& dialect_of!(self is MySqlDialect | GenericDialect)
{
// Support AUTO_INCREMENT for MySQL
Ok(Some(ColumnOption::DialectSpecific(vec![
Token::make_keyword("AUTO_INCREMENT"),
])))
} else if self.parse_keyword(Keyword::AUTOINCREMENT)
&& dialect_of!(self is SQLiteDialect | GenericDialect)
{
// Support AUTOINCREMENT for SQLite
Ok(Some(ColumnOption::DialectSpecific(vec![
Token::make_keyword("AUTOINCREMENT"),
])))
} else if self.parse_keywords(&[Keyword::ON, Keyword::UPDATE])
&& dialect_of!(self is MySqlDialect | GenericDialect)
{
let expr = self.parse_expr()?;
Ok(Some(ColumnOption::OnUpdate(expr)))
} else if self.parse_keyword(Keyword::GENERATED) {
self.parse_optional_column_option_generated()
} else if dialect_of!(self is BigQueryDialect | GenericDialect)
&& self.parse_keyword(Keyword::OPTIONS)
{
self.prev_token();
Ok(Some(ColumnOption::Options(
self.parse_options(Keyword::OPTIONS)?,
)))
} else if self.parse_keyword(Keyword::AS)
&& dialect_of!(self is MySqlDialect | SQLiteDialect | DuckDbDialect | GenericDialect)
{
self.parse_optional_column_option_as()
} else {
Ok(None)
}
}
fn parse_optional_column_option_generated(
&mut self,
) -> Result<Option<ColumnOption>, ParserError> {
if self.parse_keywords(&[Keyword::ALWAYS, Keyword::AS, Keyword::IDENTITY]) {
let mut sequence_options = vec![];
if self.expect_token(&Token::LParen).is_ok() {
sequence_options = self.parse_create_sequence_options()?;
self.expect_token(&Token::RParen)?;
}
Ok(Some(ColumnOption::Generated {
generated_as: GeneratedAs::Always,
sequence_options: Some(sequence_options),
generation_expr: None,
generation_expr_mode: None,
generated_keyword: true,
}))
} else if self.parse_keywords(&[
Keyword::BY,
Keyword::DEFAULT,
Keyword::AS,
Keyword::IDENTITY,
]) {
let mut sequence_options = vec![];
if self.expect_token(&Token::LParen).is_ok() {
sequence_options = self.parse_create_sequence_options()?;
self.expect_token(&Token::RParen)?;
}
Ok(Some(ColumnOption::Generated {
generated_as: GeneratedAs::ByDefault,
sequence_options: Some(sequence_options),
generation_expr: None,
generation_expr_mode: None,
generated_keyword: true,
}))
} else if self.parse_keywords(&[Keyword::ALWAYS, Keyword::AS]) {
if self.expect_token(&Token::LParen).is_ok() {
let expr = self.parse_expr()?;
self.expect_token(&Token::RParen)?;
let (gen_as, expr_mode) = if self.parse_keywords(&[Keyword::STORED]) {
Ok((
GeneratedAs::ExpStored,
Some(GeneratedExpressionMode::Stored),
))
} else if dialect_of!(self is PostgreSqlDialect) {
// Postgres' AS IDENTITY branches are above, this one needs STORED
self.expected("STORED", self.peek_token())
} else if self.parse_keywords(&[Keyword::VIRTUAL]) {
Ok((GeneratedAs::Always, Some(GeneratedExpressionMode::Virtual)))
} else {
Ok((GeneratedAs::Always, None))
}?;
Ok(Some(ColumnOption::Generated {
generated_as: gen_as,
sequence_options: None,
generation_expr: Some(expr),
generation_expr_mode: expr_mode,
generated_keyword: true,
}))
} else {
Ok(None)
}
} else {
Ok(None)
}
}
fn parse_optional_column_option_as(&mut self) -> Result<Option<ColumnOption>, ParserError> {
// Some DBs allow 'AS (expr)', shorthand for GENERATED ALWAYS AS
self.expect_token(&Token::LParen)?;
let expr = self.parse_expr()?;
self.expect_token(&Token::RParen)?;
let (gen_as, expr_mode) = if self.parse_keywords(&[Keyword::STORED]) {
(
GeneratedAs::ExpStored,
Some(GeneratedExpressionMode::Stored),
)
} else if self.parse_keywords(&[Keyword::VIRTUAL]) {
(GeneratedAs::Always, Some(GeneratedExpressionMode::Virtual))
} else {
(GeneratedAs::Always, None)
};
Ok(Some(ColumnOption::Generated {
generated_as: gen_as,
sequence_options: None,
generation_expr: Some(expr),
generation_expr_mode: expr_mode,
generated_keyword: false,
}))
}
pub fn parse_referential_action(&mut self) -> Result<ReferentialAction, ParserError> {
if self.parse_keyword(Keyword::RESTRICT) {
Ok(ReferentialAction::Restrict)
} else if self.parse_keyword(Keyword::CASCADE) {
Ok(ReferentialAction::Cascade)
} else if self.parse_keywords(&[Keyword::SET, Keyword::NULL]) {
Ok(ReferentialAction::SetNull)
} else if self.parse_keywords(&[Keyword::NO, Keyword::ACTION]) {
Ok(ReferentialAction::NoAction)
} else if self.parse_keywords(&[Keyword::SET, Keyword::DEFAULT]) {
Ok(ReferentialAction::SetDefault)
} else {
self.expected(
"one of RESTRICT, CASCADE, SET NULL, NO ACTION or SET DEFAULT",
self.peek_token(),
)
}
}
pub fn parse_constraint_characteristics(
&mut self,
) -> Result<Option<ConstraintCharacteristics>, ParserError> {
let mut cc = ConstraintCharacteristics::default();
loop {
if cc.deferrable.is_none() && self.parse_keywords(&[Keyword::NOT, Keyword::DEFERRABLE])
{
cc.deferrable = Some(false);
} else if cc.deferrable.is_none() && self.parse_keyword(Keyword::DEFERRABLE) {
cc.deferrable = Some(true);
} else if cc.initially.is_none() && self.parse_keyword(Keyword::INITIALLY) {
if self.parse_keyword(Keyword::DEFERRED) {
cc.initially = Some(DeferrableInitial::Deferred);
} else if self.parse_keyword(Keyword::IMMEDIATE) {
cc.initially = Some(DeferrableInitial::Immediate);
} else {
self.expected("one of DEFERRED or IMMEDIATE", self.peek_token())?;
}
} else if cc.enforced.is_none() && self.parse_keyword(Keyword::ENFORCED) {
cc.enforced = Some(true);
} else if cc.enforced.is_none()
&& self.parse_keywords(&[Keyword::NOT, Keyword::ENFORCED])
{
cc.enforced = Some(false);
} else {
break;
}
}
if cc.deferrable.is_some() || cc.initially.is_some() || cc.enforced.is_some() {
Ok(Some(cc))
} else {
Ok(None)
}
}
pub fn parse_optional_table_constraint(
&mut self,
) -> Result<Option<TableConstraint>, ParserError> {
let name = if self.parse_keyword(Keyword::CONSTRAINT) {
Some(self.parse_identifier(false)?)
} else {
None
};
let next_token = self.next_token();
match next_token.token {
Token::Word(w) if w.keyword == Keyword::UNIQUE => {
let index_type_display = self.parse_index_type_display();
if !dialect_of!(self is GenericDialect | MySqlDialect)
&& !index_type_display.is_none()
{
return self
.expected("`index_name` or `(column_name [, ...])`", self.peek_token());
}
// optional index name
let index_name = self.parse_optional_indent();
let index_type = self.parse_optional_using_then_index_type()?;
let columns = self.parse_parenthesized_column_list(Mandatory, false)?;
let index_options = self.parse_index_options()?;
let characteristics = self.parse_constraint_characteristics()?;
Ok(Some(TableConstraint::Unique {
name,
index_name,
index_type_display,
index_type,
columns,
index_options,
characteristics,
}))
}
Token::Word(w) if w.keyword == Keyword::PRIMARY => {
// after `PRIMARY` always stay `KEY`
self.expect_keyword(Keyword::KEY)?;
// optional index name
let index_name = self.parse_optional_indent();
let index_type = self.parse_optional_using_then_index_type()?;
let columns = self.parse_parenthesized_column_list(Mandatory, false)?;
let index_options = self.parse_index_options()?;
let characteristics = self.parse_constraint_characteristics()?;
Ok(Some(TableConstraint::PrimaryKey {
name,
index_name,
index_type,
columns,
index_options,
characteristics,
}))
}
Token::Word(w) if w.keyword == Keyword::FOREIGN => {
self.expect_keyword(Keyword::KEY)?;
let columns = self.parse_parenthesized_column_list(Mandatory, false)?;
self.expect_keyword(Keyword::REFERENCES)?;
let foreign_table = self.parse_object_name(false)?;
let referred_columns = self.parse_parenthesized_column_list(Mandatory, false)?;
let mut on_delete = None;
let mut on_update = None;
loop {
if on_delete.is_none() && self.parse_keywords(&[Keyword::ON, Keyword::DELETE]) {
on_delete = Some(self.parse_referential_action()?);
} else if on_update.is_none()
&& self.parse_keywords(&[Keyword::ON, Keyword::UPDATE])
{
on_update = Some(self.parse_referential_action()?);
} else {
break;
}
}
let characteristics = self.parse_constraint_characteristics()?;
Ok(Some(TableConstraint::ForeignKey {
name,
columns,
foreign_table,
referred_columns,
on_delete,
on_update,
characteristics,
}))
}
Token::Word(w) if w.keyword == Keyword::CHECK => {
self.expect_token(&Token::LParen)?;
let expr = Box::new(self.parse_expr()?);
self.expect_token(&Token::RParen)?;
Ok(Some(TableConstraint::Check { name, expr }))
}
Token::Word(w)
if (w.keyword == Keyword::INDEX || w.keyword == Keyword::KEY)
&& dialect_of!(self is GenericDialect | MySqlDialect)
&& name.is_none() =>
{
let display_as_key = w.keyword == Keyword::KEY;
let name = match self.peek_token().token {
Token::Word(word) if word.keyword == Keyword::USING => None,
_ => self.parse_optional_indent(),
};
let index_type = self.parse_optional_using_then_index_type()?;
let columns = self.parse_parenthesized_column_list(Mandatory, false)?;
Ok(Some(TableConstraint::Index {
display_as_key,
name,
index_type,
columns,
}))
}
Token::Word(w)
if (w.keyword == Keyword::FULLTEXT || w.keyword == Keyword::SPATIAL)
&& dialect_of!(self is GenericDialect | MySqlDialect) =>
{
if let Some(name) = name {
return self.expected(
"FULLTEXT or SPATIAL option without constraint name",
TokenWithLocation {
token: Token::make_keyword(&name.to_string()),
location: next_token.location,
},
);
}
let fulltext = w.keyword == Keyword::FULLTEXT;
let index_type_display = self.parse_index_type_display();
let opt_index_name = self.parse_optional_indent();
let columns = self.parse_parenthesized_column_list(Mandatory, false)?;
Ok(Some(TableConstraint::FulltextOrSpatial {
fulltext,
index_type_display,
opt_index_name,
columns,
}))
}
_ => {
if name.is_some() {
self.expected("PRIMARY, UNIQUE, FOREIGN, or CHECK", next_token)
} else {
self.prev_token();
Ok(None)
}
}
}
}
pub fn maybe_parse_options(
&mut self,
keyword: Keyword,
) -> Result<Option<Vec<SqlOption>>, ParserError> {
if let Token::Word(word) = self.peek_token().token {
if word.keyword == keyword {
return Ok(Some(self.parse_options(keyword)?));
}
};
Ok(None)
}
pub fn parse_options(&mut self, keyword: Keyword) -> Result<Vec<SqlOption>, ParserError> {
if self.parse_keyword(keyword) {
self.expect_token(&Token::LParen)?;
let options = self.parse_comma_separated(Parser::parse_sql_option)?;
self.expect_token(&Token::RParen)?;
Ok(options)
} else {
Ok(vec![])
}
}
pub fn parse_options_with_keywords(
&mut self,
keywords: &[Keyword],
) -> Result<Vec<SqlOption>, ParserError> {
if self.parse_keywords(keywords) {
self.expect_token(&Token::LParen)?;
let options = self.parse_comma_separated(Parser::parse_sql_option)?;
self.expect_token(&Token::RParen)?;
Ok(options)
} else {
Ok(vec![])
}
}
pub fn parse_index_type(&mut self) -> Result<IndexType, ParserError> {
if self.parse_keyword(Keyword::BTREE) {
Ok(IndexType::BTree)
} else if self.parse_keyword(Keyword::HASH) {
Ok(IndexType::Hash)
} else {
self.expected("index type {BTREE | HASH}", self.peek_token())
}
}
/// Parse [USING {BTREE | HASH}]
pub fn parse_optional_using_then_index_type(
&mut self,
) -> Result<Option<IndexType>, ParserError> {
if self.parse_keyword(Keyword::USING) {
Ok(Some(self.parse_index_type()?))
} else {
Ok(None)
}
}
/// Parse `[ident]`, mostly `ident` is name, like:
/// `window_name`, `index_name`, ...
pub fn parse_optional_indent(&mut self) -> Option<Ident> {
self.maybe_parse(|parser| parser.parse_identifier(false))
}
#[must_use]
pub fn parse_index_type_display(&mut self) -> KeyOrIndexDisplay {
if self.parse_keyword(Keyword::KEY) {
KeyOrIndexDisplay::Key
} else if self.parse_keyword(Keyword::INDEX) {
KeyOrIndexDisplay::Index
} else {
KeyOrIndexDisplay::None
}
}
pub fn parse_optional_index_option(&mut self) -> Result<Option<IndexOption>, ParserError> {
if let Some(index_type) = self.parse_optional_using_then_index_type()? {
Ok(Some(IndexOption::Using(index_type)))
} else if self.parse_keyword(Keyword::COMMENT) {
let s = self.parse_literal_string()?;
Ok(Some(IndexOption::Comment(s)))
} else {
Ok(None)
}
}
pub fn parse_index_options(&mut self) -> Result<Vec<IndexOption>, ParserError> {
let mut options = Vec::new();
loop {
match self.parse_optional_index_option()? {
Some(index_option) => options.push(index_option),
None => return Ok(options),
}
}
}
pub fn parse_sql_option(&mut self) -> Result<SqlOption, ParserError> {
let name = self.parse_identifier(false)?;
self.expect_token(&Token::Eq)?;
let value = self.parse_expr()?;
Ok(SqlOption { name, value })
}
pub fn parse_partition(&mut self) -> Result<Partition, ParserError> {
self.expect_token(&Token::LParen)?;
let partitions = self.parse_comma_separated(Parser::parse_expr)?;
self.expect_token(&Token::RParen)?;
Ok(Partition::Partitions(partitions))
}
pub fn parse_alter_table_operation(&mut self) -> Result<AlterTableOperation, ParserError> {
let operation = if self.parse_keyword(Keyword::ADD) {
if let Some(constraint) = self.parse_optional_table_constraint()? {
AlterTableOperation::AddConstraint(constraint)
} else {
let if_not_exists =
self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
let mut new_partitions = vec![];
loop {
if self.parse_keyword(Keyword::PARTITION) {
new_partitions.push(self.parse_partition()?);
} else {
break;
}
}
if !new_partitions.is_empty() {
AlterTableOperation::AddPartitions {
if_not_exists,
new_partitions,
}
} else {
let column_keyword = self.parse_keyword(Keyword::COLUMN);
let if_not_exists = if dialect_of!(self is PostgreSqlDialect | BigQueryDialect | DuckDbDialect | GenericDialect)
{
self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS])
|| if_not_exists
} else {
false
};
let column_def = self.parse_column_def()?;
let column_position = self.parse_column_position()?;
AlterTableOperation::AddColumn {
column_keyword,
if_not_exists,
column_def,
column_position,
}
}
}
} else if self.parse_keyword(Keyword::RENAME) {
if dialect_of!(self is PostgreSqlDialect) && self.parse_keyword(Keyword::CONSTRAINT) {
let old_name = self.parse_identifier(false)?;
self.expect_keyword(Keyword::TO)?;
let new_name = self.parse_identifier(false)?;
AlterTableOperation::RenameConstraint { old_name, new_name }
} else if self.parse_keyword(Keyword::TO) {
let table_name = self.parse_object_name(false)?;
AlterTableOperation::RenameTable { table_name }
} else {
let _ = self.parse_keyword(Keyword::COLUMN); // [ COLUMN ]
let old_column_name = self.parse_identifier(false)?;
self.expect_keyword(Keyword::TO)?;
let new_column_name = self.parse_identifier(false)?;
AlterTableOperation::RenameColumn {
old_column_name,
new_column_name,
}
}
} else if self.parse_keyword(Keyword::DISABLE) {
if self.parse_keywords(&[Keyword::ROW, Keyword::LEVEL, Keyword::SECURITY]) {
AlterTableOperation::DisableRowLevelSecurity {}
} else if self.parse_keyword(Keyword::RULE) {
let name = self.parse_identifier(false)?;
AlterTableOperation::DisableRule { name }
} else if self.parse_keyword(Keyword::TRIGGER) {
let name = self.parse_identifier(false)?;
AlterTableOperation::DisableTrigger { name }
} else {
return self.expected(
"ROW LEVEL SECURITY, RULE, or TRIGGER after DISABLE",
self.peek_token(),
);
}
} else if self.parse_keyword(Keyword::ENABLE) {
if self.parse_keywords(&[Keyword::ALWAYS, Keyword::RULE]) {
let name = self.parse_identifier(false)?;
AlterTableOperation::EnableAlwaysRule { name }
} else if self.parse_keywords(&[Keyword::ALWAYS, Keyword::TRIGGER]) {
let name = self.parse_identifier(false)?;
AlterTableOperation::EnableAlwaysTrigger { name }
} else if self.parse_keywords(&[Keyword::ROW, Keyword::LEVEL, Keyword::SECURITY]) {
AlterTableOperation::EnableRowLevelSecurity {}
} else if self.parse_keywords(&[Keyword::REPLICA, Keyword::RULE]) {
let name = self.parse_identifier(false)?;
AlterTableOperation::EnableReplicaRule { name }
} else if self.parse_keywords(&[Keyword::REPLICA, Keyword::TRIGGER]) {
let name = self.parse_identifier(false)?;
AlterTableOperation::EnableReplicaTrigger { name }
} else if self.parse_keyword(Keyword::RULE) {
let name = self.parse_identifier(false)?;
AlterTableOperation::EnableRule { name }
} else if self.parse_keyword(Keyword::TRIGGER) {
let name = self.parse_identifier(false)?;
AlterTableOperation::EnableTrigger { name }
} else {
return self.expected(
"ALWAYS, REPLICA, ROW LEVEL SECURITY, RULE, or TRIGGER after ENABLE",
self.peek_token(),
);
}
} else if self.parse_keyword(Keyword::DROP) {
if self.parse_keywords(&[Keyword::IF, Keyword::EXISTS, Keyword::PARTITION]) {
self.expect_token(&Token::LParen)?;
let partitions = self.parse_comma_separated(Parser::parse_expr)?;
self.expect_token(&Token::RParen)?;
AlterTableOperation::DropPartitions {
partitions,
if_exists: true,
}
} else if self.parse_keyword(Keyword::PARTITION) {
self.expect_token(&Token::LParen)?;
let partitions = self.parse_comma_separated(Parser::parse_expr)?;
self.expect_token(&Token::RParen)?;
AlterTableOperation::DropPartitions {
partitions,
if_exists: false,
}
} else if self.parse_keyword(Keyword::CONSTRAINT) {
let if_exists = self.parse_keywords(&[Keyword::IF, Keyword::EXISTS]);
let name = self.parse_identifier(false)?;
let cascade = self.parse_keyword(Keyword::CASCADE);
AlterTableOperation::DropConstraint {
if_exists,
name,
cascade,
}
} else if self.parse_keywords(&[Keyword::PRIMARY, Keyword::KEY])
&& dialect_of!(self is MySqlDialect | GenericDialect)
{
AlterTableOperation::DropPrimaryKey
} else {
let _ = self.parse_keyword(Keyword::COLUMN); // [ COLUMN ]
let if_exists = self.parse_keywords(&[Keyword::IF, Keyword::EXISTS]);
let column_name = self.parse_identifier(false)?;
let cascade = self.parse_keyword(Keyword::CASCADE);
AlterTableOperation::DropColumn {
column_name,
if_exists,
cascade,
}
}
} else if self.parse_keyword(Keyword::PARTITION) {
self.expect_token(&Token::LParen)?;
let before = self.parse_comma_separated(Parser::parse_expr)?;
self.expect_token(&Token::RParen)?;
self.expect_keyword(Keyword::RENAME)?;
self.expect_keywords(&[Keyword::TO, Keyword::PARTITION])?;
self.expect_token(&Token::LParen)?;
let renames = self.parse_comma_separated(Parser::parse_expr)?;
self.expect_token(&Token::RParen)?;
AlterTableOperation::RenamePartitions {
old_partitions: before,
new_partitions: renames,
}
} else if self.parse_keyword(Keyword::CHANGE) {
let _ = self.parse_keyword(Keyword::COLUMN); // [ COLUMN ]
let old_name = self.parse_identifier(false)?;
let new_name = self.parse_identifier(false)?;
let data_type = self.parse_data_type()?;
let mut options = vec![];
while let Some(option) = self.parse_optional_column_option()? {
options.push(option);
}
let column_position = self.parse_column_position()?;
AlterTableOperation::ChangeColumn {
old_name,
new_name,
data_type,
options,
column_position,
}
} else if self.parse_keyword(Keyword::MODIFY) {
let _ = self.parse_keyword(Keyword::COLUMN); // [ COLUMN ]
let col_name = self.parse_identifier(false)?;
let data_type = self.parse_data_type()?;
let mut options = vec![];
while let Some(option) = self.parse_optional_column_option()? {
options.push(option);
}
let column_position = self.parse_column_position()?;
AlterTableOperation::ModifyColumn {
col_name,
data_type,
options,
column_position,
}
} else if self.parse_keyword(Keyword::ALTER) {
let _ = self.parse_keyword(Keyword::COLUMN); // [ COLUMN ]
let column_name = self.parse_identifier(false)?;
let is_postgresql = dialect_of!(self is PostgreSqlDialect);
let op: AlterColumnOperation = if self.parse_keywords(&[
Keyword::SET,
Keyword::NOT,
Keyword::NULL,
]) {
AlterColumnOperation::SetNotNull {}
} else if self.parse_keywords(&[Keyword::DROP, Keyword::NOT, Keyword::NULL]) {
AlterColumnOperation::DropNotNull {}
} else if self.parse_keywords(&[Keyword::SET, Keyword::DEFAULT]) {
AlterColumnOperation::SetDefault {
value: self.parse_expr()?,
}
} else if self.parse_keywords(&[Keyword::DROP, Keyword::DEFAULT]) {
AlterColumnOperation::DropDefault {}
} else if self.parse_keywords(&[Keyword::SET, Keyword::DATA, Keyword::TYPE])
|| (is_postgresql && self.parse_keyword(Keyword::TYPE))
{
let data_type = self.parse_data_type()?;
let using = if is_postgresql && self.parse_keyword(Keyword::USING) {
Some(self.parse_expr()?)
} else {
None
};
AlterColumnOperation::SetDataType { data_type, using }
} else if self.parse_keywords(&[Keyword::ADD, Keyword::GENERATED]) {
let generated_as = if self.parse_keyword(Keyword::ALWAYS) {
Some(GeneratedAs::Always)
} else if self.parse_keywords(&[Keyword::BY, Keyword::DEFAULT]) {
Some(GeneratedAs::ByDefault)
} else {
None
};
self.expect_keywords(&[Keyword::AS, Keyword::IDENTITY])?;
let mut sequence_options: Option<Vec<SequenceOptions>> = None;
if self.peek_token().token == Token::LParen {
self.expect_token(&Token::LParen)?;
sequence_options = Some(self.parse_create_sequence_options()?);
self.expect_token(&Token::RParen)?;
}
AlterColumnOperation::AddGenerated {
generated_as,
sequence_options,
}
} else {
let message = if is_postgresql {
"SET/DROP NOT NULL, SET DEFAULT, SET DATA TYPE, or ADD GENERATED after ALTER COLUMN"
} else {
"SET/DROP NOT NULL, SET DEFAULT, or SET DATA TYPE after ALTER COLUMN"
};
return self.expected(message, self.peek_token());
};
AlterTableOperation::AlterColumn { column_name, op }
} else if self.parse_keyword(Keyword::SWAP) {
self.expect_keyword(Keyword::WITH)?;
let table_name = self.parse_object_name(false)?;
AlterTableOperation::SwapWith { table_name }
} else if dialect_of!(self is PostgreSqlDialect | GenericDialect)
&& self.parse_keywords(&[Keyword::OWNER, Keyword::TO])
{
let new_owner = match self.parse_one_of_keywords(&[Keyword::CURRENT_USER, Keyword::CURRENT_ROLE, Keyword::SESSION_USER]) {
Some(Keyword::CURRENT_USER) => Owner::CurrentUser,
Some(Keyword::CURRENT_ROLE) => Owner::CurrentRole,
Some(Keyword::SESSION_USER) => Owner::SessionUser,
Some(_) => unreachable!(),
None => {
match self.parse_identifier(false) {
Ok(ident) => Owner::Ident(ident),
Err(e) => {
return Err(ParserError::ParserError(format!("Expected: CURRENT_USER, CURRENT_ROLE, SESSION_USER or identifier after OWNER TO. {e}")))
}
}
},
};
AlterTableOperation::OwnerTo { new_owner }
} else if dialect_of!(self is ClickHouseDialect|GenericDialect)
&& self.parse_keyword(Keyword::ATTACH)
{
AlterTableOperation::AttachPartition {
partition: self.parse_part_or_partition()?,
}
} else if dialect_of!(self is ClickHouseDialect|GenericDialect)
&& self.parse_keyword(Keyword::DETACH)
{
AlterTableOperation::DetachPartition {
partition: self.parse_part_or_partition()?,
}
} else if dialect_of!(self is ClickHouseDialect|GenericDialect)
&& self.parse_keyword(Keyword::FREEZE)
{
let partition = self.parse_part_or_partition()?;
let with_name = if self.parse_keyword(Keyword::WITH) {
self.expect_keyword(Keyword::NAME)?;
Some(self.parse_identifier(false)?)
} else {
None
};
AlterTableOperation::FreezePartition {
partition,
with_name,
}
} else if dialect_of!(self is ClickHouseDialect|GenericDialect)
&& self.parse_keyword(Keyword::UNFREEZE)
{
let partition = self.parse_part_or_partition()?;
let with_name = if self.parse_keyword(Keyword::WITH) {
self.expect_keyword(Keyword::NAME)?;
Some(self.parse_identifier(false)?)
} else {
None
};
AlterTableOperation::UnfreezePartition {
partition,
with_name,
}
} else {
let options: Vec<SqlOption> =
self.parse_options_with_keywords(&[Keyword::SET, Keyword::TBLPROPERTIES])?;
if !options.is_empty() {
AlterTableOperation::SetTblProperties {
table_properties: options,
}
} else {
return self.expected(
"ADD, RENAME, PARTITION, SWAP, DROP, or SET TBLPROPERTIES after ALTER TABLE",
self.peek_token(),
);
}
};
Ok(operation)
}
fn parse_part_or_partition(&mut self) -> Result<Partition, ParserError> {
let keyword = self.expect_one_of_keywords(&[Keyword::PART, Keyword::PARTITION])?;
match keyword {
Keyword::PART => Ok(Partition::Part(self.parse_expr()?)),
Keyword::PARTITION => Ok(Partition::Expr(self.parse_expr()?)),
// unreachable because expect_one_of_keywords used above
_ => unreachable!(),
}
}
pub fn parse_alter(&mut self) -> Result<Statement, ParserError> {
let object_type = self.expect_one_of_keywords(&[
Keyword::VIEW,
Keyword::TABLE,
Keyword::INDEX,
Keyword::ROLE,
])?;
match object_type {
Keyword::VIEW => self.parse_alter_view(),
Keyword::TABLE => {
let if_exists = self.parse_keywords(&[Keyword::IF, Keyword::EXISTS]);
let only = self.parse_keyword(Keyword::ONLY); // [ ONLY ]
let table_name = self.parse_object_name(false)?;
let on_cluster = self.parse_optional_on_cluster()?;
let operations = self.parse_comma_separated(Parser::parse_alter_table_operation)?;
let mut location = None;
if self.parse_keyword(Keyword::LOCATION) {
location = Some(HiveSetLocation {
has_set: false,
location: self.parse_identifier(false)?,
});
} else if self.parse_keywords(&[Keyword::SET, Keyword::LOCATION]) {
location = Some(HiveSetLocation {
has_set: true,
location: self.parse_identifier(false)?,
});
}
Ok(Statement::AlterTable {
name: table_name,
if_exists,
only,
operations,
location,
on_cluster,
})
}
Keyword::INDEX => {
let index_name = self.parse_object_name(false)?;
let operation = if self.parse_keyword(Keyword::RENAME) {
if self.parse_keyword(Keyword::TO) {
let index_name = self.parse_object_name(false)?;
AlterIndexOperation::RenameIndex { index_name }
} else {
return self.expected("TO after RENAME", self.peek_token());
}
} else {
return self.expected("RENAME after ALTER INDEX", self.peek_token());
};
Ok(Statement::AlterIndex {
name: index_name,
operation,
})
}
Keyword::ROLE => self.parse_alter_role(),
// unreachable because expect_one_of_keywords used above
_ => unreachable!(),
}
}
pub fn parse_alter_view(&mut self) -> Result<Statement, ParserError> {
let name = self.parse_object_name(false)?;
let columns = self.parse_parenthesized_column_list(Optional, false)?;
let with_options = self.parse_options(Keyword::WITH)?;
self.expect_keyword(Keyword::AS)?;
let query = self.parse_boxed_query()?;
Ok(Statement::AlterView {
name,
columns,
query,
with_options,
})
}
/// Parse a `CALL procedure_name(arg1, arg2, ...)`
/// or `CALL procedure_name` statement
pub fn parse_call(&mut self) -> Result<Statement, ParserError> {
let object_name = self.parse_object_name(false)?;
if self.peek_token().token == Token::LParen {
match self.parse_function(object_name)? {
Expr::Function(f) => Ok(Statement::Call(f)),
other => parser_err!(
format!("Expected a simple procedure call but found: {other}"),
self.peek_token().location
),
}
} else {
Ok(Statement::Call(Function {
name: object_name,
parameters: FunctionArguments::None,
args: FunctionArguments::None,
over: None,
filter: None,
null_treatment: None,
within_group: vec![],
}))
}
}
/// Parse a copy statement
pub fn parse_copy(&mut self) -> Result<Statement, ParserError> {
let source;
if self.consume_token(&Token::LParen) {
source = CopySource::Query(self.parse_boxed_query()?);
self.expect_token(&Token::RParen)?;
} else {
let table_name = self.parse_object_name(false)?;
let columns = self.parse_parenthesized_column_list(Optional, false)?;
source = CopySource::Table {
table_name,
columns,
};
}
let to = match self.parse_one_of_keywords(&[Keyword::FROM, Keyword::TO]) {
Some(Keyword::FROM) => false,
Some(Keyword::TO) => true,
_ => self.expected("FROM or TO", self.peek_token())?,
};
if !to {
// Use a separate if statement to prevent Rust compiler from complaining about
// "if statement in this position is unstable: https://github.com/rust-lang/rust/issues/53667"
if let CopySource::Query(_) = source {
return Err(ParserError::ParserError(
"COPY ... FROM does not support query as a source".to_string(),
));
}
}
let target = if self.parse_keyword(Keyword::STDIN) {
CopyTarget::Stdin
} else if self.parse_keyword(Keyword::STDOUT) {
CopyTarget::Stdout
} else if self.parse_keyword(Keyword::PROGRAM) {
CopyTarget::Program {
command: self.parse_literal_string()?,
}
} else {
CopyTarget::File {
filename: self.parse_literal_string()?,
}
};
let _ = self.parse_keyword(Keyword::WITH); // [ WITH ]
let mut options = vec![];
if self.consume_token(&Token::LParen) {
options = self.parse_comma_separated(Parser::parse_copy_option)?;
self.expect_token(&Token::RParen)?;
}
let mut legacy_options = vec![];
while let Some(opt) = self.maybe_parse(|parser| parser.parse_copy_legacy_option()) {
legacy_options.push(opt);
}
let values = if let CopyTarget::Stdin = target {
self.expect_token(&Token::SemiColon)?;
self.parse_tsv()
} else {
vec![]
};
Ok(Statement::Copy {
source,
to,
target,
options,
legacy_options,
values,
})
}
pub fn parse_close(&mut self) -> Result<Statement, ParserError> {
let cursor = if self.parse_keyword(Keyword::ALL) {
CloseCursor::All
} else {
let name = self.parse_identifier(false)?;
CloseCursor::Specific { name }
};
Ok(Statement::Close { cursor })
}
fn parse_copy_option(&mut self) -> Result<CopyOption, ParserError> {
let ret = match self.parse_one_of_keywords(&[
Keyword::FORMAT,
Keyword::FREEZE,
Keyword::DELIMITER,
Keyword::NULL,
Keyword::HEADER,
Keyword::QUOTE,
Keyword::ESCAPE,
Keyword::FORCE_QUOTE,
Keyword::FORCE_NOT_NULL,
Keyword::FORCE_NULL,
Keyword::ENCODING,
]) {
Some(Keyword::FORMAT) => CopyOption::Format(self.parse_identifier(false)?),
Some(Keyword::FREEZE) => CopyOption::Freeze(!matches!(
self.parse_one_of_keywords(&[Keyword::TRUE, Keyword::FALSE]),
Some(Keyword::FALSE)
)),
Some(Keyword::DELIMITER) => CopyOption::Delimiter(self.parse_literal_char()?),
Some(Keyword::NULL) => CopyOption::Null(self.parse_literal_string()?),
Some(Keyword::HEADER) => CopyOption::Header(!matches!(
self.parse_one_of_keywords(&[Keyword::TRUE, Keyword::FALSE]),
Some(Keyword::FALSE)
)),
Some(Keyword::QUOTE) => CopyOption::Quote(self.parse_literal_char()?),
Some(Keyword::ESCAPE) => CopyOption::Escape(self.parse_literal_char()?),
Some(Keyword::FORCE_QUOTE) => {
CopyOption::ForceQuote(self.parse_parenthesized_column_list(Mandatory, false)?)
}
Some(Keyword::FORCE_NOT_NULL) => {
CopyOption::ForceNotNull(self.parse_parenthesized_column_list(Mandatory, false)?)
}
Some(Keyword::FORCE_NULL) => {
CopyOption::ForceNull(self.parse_parenthesized_column_list(Mandatory, false)?)
}
Some(Keyword::ENCODING) => CopyOption::Encoding(self.parse_literal_string()?),
_ => self.expected("option", self.peek_token())?,
};
Ok(ret)
}
fn parse_copy_legacy_option(&mut self) -> Result<CopyLegacyOption, ParserError> {
let ret = match self.parse_one_of_keywords(&[
Keyword::BINARY,
Keyword::DELIMITER,
Keyword::NULL,
Keyword::CSV,
]) {
Some(Keyword::BINARY) => CopyLegacyOption::Binary,
Some(Keyword::DELIMITER) => {
let _ = self.parse_keyword(Keyword::AS); // [ AS ]
CopyLegacyOption::Delimiter(self.parse_literal_char()?)
}
Some(Keyword::NULL) => {
let _ = self.parse_keyword(Keyword::AS); // [ AS ]
CopyLegacyOption::Null(self.parse_literal_string()?)
}
Some(Keyword::CSV) => CopyLegacyOption::Csv({
let mut opts = vec![];
while let Some(opt) =
self.maybe_parse(|parser| parser.parse_copy_legacy_csv_option())
{
opts.push(opt);
}
opts
}),
_ => self.expected("option", self.peek_token())?,
};
Ok(ret)
}
fn parse_copy_legacy_csv_option(&mut self) -> Result<CopyLegacyCsvOption, ParserError> {
let ret = match self.parse_one_of_keywords(&[
Keyword::HEADER,
Keyword::QUOTE,
Keyword::ESCAPE,
Keyword::FORCE,
]) {
Some(Keyword::HEADER) => CopyLegacyCsvOption::Header,
Some(Keyword::QUOTE) => {
let _ = self.parse_keyword(Keyword::AS); // [ AS ]
CopyLegacyCsvOption::Quote(self.parse_literal_char()?)
}
Some(Keyword::ESCAPE) => {
let _ = self.parse_keyword(Keyword::AS); // [ AS ]
CopyLegacyCsvOption::Escape(self.parse_literal_char()?)
}
Some(Keyword::FORCE) if self.parse_keywords(&[Keyword::NOT, Keyword::NULL]) => {
CopyLegacyCsvOption::ForceNotNull(
self.parse_comma_separated(|p| p.parse_identifier(false))?,
)
}
Some(Keyword::FORCE) if self.parse_keywords(&[Keyword::QUOTE]) => {
CopyLegacyCsvOption::ForceQuote(
self.parse_comma_separated(|p| p.parse_identifier(false))?,
)
}
_ => self.expected("csv option", self.peek_token())?,
};
Ok(ret)
}
fn parse_literal_char(&mut self) -> Result<char, ParserError> {
let s = self.parse_literal_string()?;
if s.len() != 1 {
let loc = self
.tokens
.get(self.index - 1)
.map_or(Location { line: 0, column: 0 }, |t| t.location);
return parser_err!(format!("Expect a char, found {s:?}"), loc);
}
Ok(s.chars().next().unwrap())
}
/// Parse a tab separated values in
/// COPY payload
pub fn parse_tsv(&mut self) -> Vec<Option<String>> {
self.parse_tab_value()
}
pub fn parse_tab_value(&mut self) -> Vec<Option<String>> {
let mut values = vec![];
let mut content = String::from("");
while let Some(t) = self.next_token_no_skip().map(|t| &t.token) {
match t {
Token::Whitespace(Whitespace::Tab) => {
values.push(Some(content.to_string()));
content.clear();
}
Token::Whitespace(Whitespace::Newline) => {
values.push(Some(content.to_string()));
content.clear();
}
Token::Backslash => {
if self.consume_token(&Token::Period) {
return values;
}
if let Token::Word(w) = self.next_token().token {
if w.value == "N" {
values.push(None);
}
}
}
_ => {
content.push_str(&t.to_string());
}
}
}
values
}
/// Parse a literal value (numbers, strings, date/time, booleans)
pub fn parse_value(&mut self) -> Result<Value, ParserError> {
let next_token = self.next_token();
let location = next_token.location;
match next_token.token {
Token::Word(w) => match w.keyword {
Keyword::TRUE => Ok(Value::Boolean(true)),
Keyword::FALSE => Ok(Value::Boolean(false)),
Keyword::NULL => Ok(Value::Null),
Keyword::NoKeyword if w.quote_style.is_some() => match w.quote_style {
Some('"') => Ok(Value::DoubleQuotedString(w.value)),
Some('\'') => Ok(Value::SingleQuotedString(w.value)),
_ => self.expected(
"A value?",
TokenWithLocation {
token: Token::Word(w),
location,
},
)?,
},
_ => self.expected(
"a concrete value",
TokenWithLocation {
token: Token::Word(w),
location,
},
),
},
// The call to n.parse() returns a bigdecimal when the
// bigdecimal feature is enabled, and is otherwise a no-op
// (i.e., it returns the input string).
Token::Number(n, l) => Ok(Value::Number(Self::parse(n, location)?, l)),
Token::SingleQuotedString(ref s) => Ok(Value::SingleQuotedString(s.to_string())),
Token::DoubleQuotedString(ref s) => Ok(Value::DoubleQuotedString(s.to_string())),
Token::TripleSingleQuotedString(ref s) => {
Ok(Value::TripleSingleQuotedString(s.to_string()))
}
Token::TripleDoubleQuotedString(ref s) => {
Ok(Value::TripleDoubleQuotedString(s.to_string()))
}
Token::DollarQuotedString(ref s) => Ok(Value::DollarQuotedString(s.clone())),
Token::SingleQuotedByteStringLiteral(ref s) => {
Ok(Value::SingleQuotedByteStringLiteral(s.clone()))
}
Token::DoubleQuotedByteStringLiteral(ref s) => {
Ok(Value::DoubleQuotedByteStringLiteral(s.clone()))
}
Token::TripleSingleQuotedByteStringLiteral(ref s) => {
Ok(Value::TripleSingleQuotedByteStringLiteral(s.clone()))
}
Token::TripleDoubleQuotedByteStringLiteral(ref s) => {
Ok(Value::TripleDoubleQuotedByteStringLiteral(s.clone()))
}
Token::SingleQuotedRawStringLiteral(ref s) => {
Ok(Value::SingleQuotedRawStringLiteral(s.clone()))
}
Token::DoubleQuotedRawStringLiteral(ref s) => {
Ok(Value::DoubleQuotedRawStringLiteral(s.clone()))
}
Token::TripleSingleQuotedRawStringLiteral(ref s) => {
Ok(Value::TripleSingleQuotedRawStringLiteral(s.clone()))
}
Token::TripleDoubleQuotedRawStringLiteral(ref s) => {
Ok(Value::TripleDoubleQuotedRawStringLiteral(s.clone()))
}
Token::NationalStringLiteral(ref s) => Ok(Value::NationalStringLiteral(s.to_string())),
Token::EscapedStringLiteral(ref s) => Ok(Value::EscapedStringLiteral(s.to_string())),
Token::UnicodeStringLiteral(ref s) => Ok(Value::UnicodeStringLiteral(s.to_string())),
Token::HexStringLiteral(ref s) => Ok(Value::HexStringLiteral(s.to_string())),
Token::Placeholder(ref s) => Ok(Value::Placeholder(s.to_string())),
tok @ Token::Colon | tok @ Token::AtSign => {
// Not calling self.parse_identifier(false)? because only in placeholder we want to check numbers as idfentifies
// This because snowflake allows numbers as placeholders
let next_token = self.next_token();
let ident = match next_token.token {
Token::Word(w) => Ok(w.to_ident()),
Token::Number(w, false) => Ok(Ident::new(w)),
_ => self.expected("placeholder", next_token),
}?;
let placeholder = tok.to_string() + &ident.value;
Ok(Value::Placeholder(placeholder))
}
unexpected => self.expected(
"a value",
TokenWithLocation {
token: unexpected,
location,
},
),
}
}
pub fn parse_number_value(&mut self) -> Result<Value, ParserError> {
match self.parse_value()? {
v @ Value::Number(_, _) => Ok(v),
v @ Value::Placeholder(_) => Ok(v),
_ => {
self.prev_token();
self.expected("literal number", self.peek_token())
}
}
}
fn parse_introduced_string_value(&mut self) -> Result<Value, ParserError> {
let next_token = self.next_token();
let location = next_token.location;
match next_token.token {
Token::SingleQuotedString(ref s) => Ok(Value::SingleQuotedString(s.to_string())),
Token::DoubleQuotedString(ref s) => Ok(Value::DoubleQuotedString(s.to_string())),
Token::HexStringLiteral(ref s) => Ok(Value::HexStringLiteral(s.to_string())),
unexpected => self.expected(
"a string value",
TokenWithLocation {
token: unexpected,
location,
},
),
}
}
/// Parse an unsigned literal integer/long
pub fn parse_literal_uint(&mut self) -> Result<u64, ParserError> {
let next_token = self.next_token();
match next_token.token {
Token::Number(s, _) => Self::parse::<u64>(s, next_token.location),
_ => self.expected("literal int", next_token),
}
}
/// Parse the body of a `CREATE FUNCTION` specified as a string.
/// e.g. `CREATE FUNCTION ... AS $$ body $$`.
fn parse_create_function_body_string(&mut self) -> Result<Expr, ParserError> {
let peek_token = self.peek_token();
match peek_token.token {
Token::DollarQuotedString(s) if dialect_of!(self is PostgreSqlDialect | GenericDialect) =>
{
self.next_token();
Ok(Expr::Value(Value::DollarQuotedString(s)))
}
_ => Ok(Expr::Value(Value::SingleQuotedString(
self.parse_literal_string()?,
))),
}
}
/// Parse a literal string
pub fn parse_literal_string(&mut self) -> Result<String, ParserError> {
let next_token = self.next_token();
match next_token.token {
Token::Word(Word {
value,
keyword: Keyword::NoKeyword,
..
}) => Ok(value),
Token::SingleQuotedString(s) => Ok(s),
Token::DoubleQuotedString(s) => Ok(s),
Token::EscapedStringLiteral(s) if dialect_of!(self is PostgreSqlDialect | GenericDialect) => {
Ok(s)
}
Token::UnicodeStringLiteral(s) => Ok(s),
_ => self.expected("literal string", next_token),
}
}
/// Parse a SQL datatype (in the context of a CREATE TABLE statement for example)
pub fn parse_data_type(&mut self) -> Result<DataType, ParserError> {
let (ty, trailing_bracket) = self.parse_data_type_helper()?;
if trailing_bracket.0 {
return parser_err!(
format!("unmatched > after parsing data type {ty}"),
self.peek_token()
);
}
Ok(ty)
}
fn parse_data_type_helper(
&mut self,
) -> Result<(DataType, MatchedTrailingBracket), ParserError> {
let next_token = self.next_token();
let mut trailing_bracket: MatchedTrailingBracket = false.into();
let mut data = match next_token.token {
Token::Word(w) => match w.keyword {
Keyword::BOOLEAN => Ok(DataType::Boolean),
Keyword::BOOL => Ok(DataType::Bool),
Keyword::FLOAT => Ok(DataType::Float(self.parse_optional_precision()?)),
Keyword::REAL => Ok(DataType::Real),
Keyword::FLOAT4 => Ok(DataType::Float4),
Keyword::FLOAT32 => Ok(DataType::Float32),
Keyword::FLOAT64 => Ok(DataType::Float64),
Keyword::FLOAT8 => Ok(DataType::Float8),
Keyword::DOUBLE => {
if self.parse_keyword(Keyword::PRECISION) {
Ok(DataType::DoublePrecision)
} else {
Ok(DataType::Double)
}
}
Keyword::TINYINT => {
let optional_precision = self.parse_optional_precision();
if self.parse_keyword(Keyword::UNSIGNED) {
Ok(DataType::UnsignedTinyInt(optional_precision?))
} else {
Ok(DataType::TinyInt(optional_precision?))
}
}
Keyword::INT2 => {
let optional_precision = self.parse_optional_precision();
if self.parse_keyword(Keyword::UNSIGNED) {
Ok(DataType::UnsignedInt2(optional_precision?))
} else {
Ok(DataType::Int2(optional_precision?))
}
}
Keyword::SMALLINT => {
let optional_precision = self.parse_optional_precision();
if self.parse_keyword(Keyword::UNSIGNED) {
Ok(DataType::UnsignedSmallInt(optional_precision?))
} else {
Ok(DataType::SmallInt(optional_precision?))
}
}
Keyword::MEDIUMINT => {
let optional_precision = self.parse_optional_precision();
if self.parse_keyword(Keyword::UNSIGNED) {
Ok(DataType::UnsignedMediumInt(optional_precision?))
} else {
Ok(DataType::MediumInt(optional_precision?))
}
}
Keyword::INT => {
let optional_precision = self.parse_optional_precision();
if self.parse_keyword(Keyword::UNSIGNED) {
Ok(DataType::UnsignedInt(optional_precision?))
} else {
Ok(DataType::Int(optional_precision?))
}
}
Keyword::INT4 => {
let optional_precision = self.parse_optional_precision();
if self.parse_keyword(Keyword::UNSIGNED) {
Ok(DataType::UnsignedInt4(optional_precision?))
} else {
Ok(DataType::Int4(optional_precision?))
}
}
Keyword::INT8 => {
let optional_precision = self.parse_optional_precision();
if self.parse_keyword(Keyword::UNSIGNED) {
Ok(DataType::UnsignedInt8(optional_precision?))
} else {
Ok(DataType::Int8(optional_precision?))
}
}
Keyword::INT16 => Ok(DataType::Int16),
Keyword::INT32 => Ok(DataType::Int32),
Keyword::INT64 => Ok(DataType::Int64),
Keyword::INT128 => Ok(DataType::Int128),
Keyword::INT256 => Ok(DataType::Int256),
Keyword::INTEGER => {
let optional_precision = self.parse_optional_precision();
if self.parse_keyword(Keyword::UNSIGNED) {
Ok(DataType::UnsignedInteger(optional_precision?))
} else {
Ok(DataType::Integer(optional_precision?))
}
}
Keyword::BIGINT => {
let optional_precision = self.parse_optional_precision();
if self.parse_keyword(Keyword::UNSIGNED) {
Ok(DataType::UnsignedBigInt(optional_precision?))
} else {
Ok(DataType::BigInt(optional_precision?))
}
}
Keyword::UINT8 => Ok(DataType::UInt8),
Keyword::UINT16 => Ok(DataType::UInt16),
Keyword::UINT32 => Ok(DataType::UInt32),
Keyword::UINT64 => Ok(DataType::UInt64),
Keyword::UINT128 => Ok(DataType::UInt128),
Keyword::UINT256 => Ok(DataType::UInt256),
Keyword::VARCHAR => Ok(DataType::Varchar(self.parse_optional_character_length()?)),
Keyword::NVARCHAR => {
Ok(DataType::Nvarchar(self.parse_optional_character_length()?))
}
Keyword::CHARACTER => {
if self.parse_keyword(Keyword::VARYING) {
Ok(DataType::CharacterVarying(
self.parse_optional_character_length()?,
))
} else if self.parse_keywords(&[Keyword::LARGE, Keyword::OBJECT]) {
Ok(DataType::CharacterLargeObject(
self.parse_optional_precision()?,
))
} else {
Ok(DataType::Character(self.parse_optional_character_length()?))
}
}
Keyword::CHAR => {
if self.parse_keyword(Keyword::VARYING) {
Ok(DataType::CharVarying(
self.parse_optional_character_length()?,
))
} else if self.parse_keywords(&[Keyword::LARGE, Keyword::OBJECT]) {
Ok(DataType::CharLargeObject(self.parse_optional_precision()?))
} else {
Ok(DataType::Char(self.parse_optional_character_length()?))
}
}
Keyword::CLOB => Ok(DataType::Clob(self.parse_optional_precision()?)),
Keyword::BINARY => Ok(DataType::Binary(self.parse_optional_precision()?)),
Keyword::VARBINARY => Ok(DataType::Varbinary(self.parse_optional_precision()?)),
Keyword::BLOB => Ok(DataType::Blob(self.parse_optional_precision()?)),
Keyword::BYTES => Ok(DataType::Bytes(self.parse_optional_precision()?)),
Keyword::UUID => Ok(DataType::Uuid),
Keyword::DATE => Ok(DataType::Date),
Keyword::DATE32 => Ok(DataType::Date32),
Keyword::DATETIME => Ok(DataType::Datetime(self.parse_optional_precision()?)),
Keyword::DATETIME64 => {
self.prev_token();
let (precision, time_zone) = self.parse_datetime_64()?;
Ok(DataType::Datetime64(precision, time_zone))
}
Keyword::TIMESTAMP => {
let precision = self.parse_optional_precision()?;
let tz = if self.parse_keyword(Keyword::WITH) {
self.expect_keywords(&[Keyword::TIME, Keyword::ZONE])?;
TimezoneInfo::WithTimeZone
} else if self.parse_keyword(Keyword::WITHOUT) {
self.expect_keywords(&[Keyword::TIME, Keyword::ZONE])?;
TimezoneInfo::WithoutTimeZone
} else {
TimezoneInfo::None
};
Ok(DataType::Timestamp(precision, tz))
}
Keyword::TIMESTAMPTZ => Ok(DataType::Timestamp(
self.parse_optional_precision()?,
TimezoneInfo::Tz,
)),
Keyword::TIME => {
let precision = self.parse_optional_precision()?;
let tz = if self.parse_keyword(Keyword::WITH) {
self.expect_keywords(&[Keyword::TIME, Keyword::ZONE])?;
TimezoneInfo::WithTimeZone
} else if self.parse_keyword(Keyword::WITHOUT) {
self.expect_keywords(&[Keyword::TIME, Keyword::ZONE])?;
TimezoneInfo::WithoutTimeZone
} else {
TimezoneInfo::None
};
Ok(DataType::Time(precision, tz))
}
Keyword::TIMETZ => Ok(DataType::Time(
self.parse_optional_precision()?,
TimezoneInfo::Tz,
)),
// Interval types can be followed by a complicated interval
// qualifier that we don't currently support. See
// parse_interval for a taste.
Keyword::INTERVAL => Ok(DataType::Interval),
Keyword::JSON => Ok(DataType::JSON),
Keyword::JSONB => Ok(DataType::JSONB),
Keyword::REGCLASS => Ok(DataType::Regclass),
Keyword::STRING => Ok(DataType::String(self.parse_optional_precision()?)),
Keyword::FIXEDSTRING => {
self.expect_token(&Token::LParen)?;
let character_length = self.parse_literal_uint()?;
self.expect_token(&Token::RParen)?;
Ok(DataType::FixedString(character_length))
}
Keyword::TEXT => Ok(DataType::Text),
Keyword::BYTEA => Ok(DataType::Bytea),
Keyword::NUMERIC => Ok(DataType::Numeric(
self.parse_exact_number_optional_precision_scale()?,
)),
Keyword::DECIMAL => Ok(DataType::Decimal(
self.parse_exact_number_optional_precision_scale()?,
)),
Keyword::DEC => Ok(DataType::Dec(
self.parse_exact_number_optional_precision_scale()?,
)),
Keyword::BIGNUMERIC => Ok(DataType::BigNumeric(
self.parse_exact_number_optional_precision_scale()?,
)),
Keyword::BIGDECIMAL => Ok(DataType::BigDecimal(
self.parse_exact_number_optional_precision_scale()?,
)),
Keyword::ENUM => Ok(DataType::Enum(self.parse_string_values()?)),
Keyword::SET => Ok(DataType::Set(self.parse_string_values()?)),
Keyword::ARRAY => {
if dialect_of!(self is SnowflakeDialect) {
Ok(DataType::Array(ArrayElemTypeDef::None))
} else if dialect_of!(self is ClickHouseDialect) {
Ok(self.parse_sub_type(|internal_type| {
DataType::Array(ArrayElemTypeDef::Parenthesis(internal_type))
})?)
} else {
self.expect_token(&Token::Lt)?;
let (inside_type, _trailing_bracket) = self.parse_data_type_helper()?;
trailing_bracket = self.expect_closing_angle_bracket(_trailing_bracket)?;
Ok(DataType::Array(ArrayElemTypeDef::AngleBracket(Box::new(
inside_type,
))))
}
}
Keyword::STRUCT if dialect_of!(self is DuckDbDialect) => {
self.prev_token();
let field_defs = self.parse_duckdb_struct_type_def()?;
Ok(DataType::Struct(field_defs, StructBracketKind::Parentheses))
}
Keyword::STRUCT if dialect_of!(self is BigQueryDialect | GenericDialect) => {
self.prev_token();
let (field_defs, _trailing_bracket) =
self.parse_struct_type_def(Self::parse_struct_field_def)?;
trailing_bracket = _trailing_bracket;
Ok(DataType::Struct(
field_defs,
StructBracketKind::AngleBrackets,
))
}
Keyword::UNION if dialect_of!(self is DuckDbDialect | GenericDialect) => {
self.prev_token();
let fields = self.parse_union_type_def()?;
Ok(DataType::Union(fields))
}
Keyword::NULLABLE if dialect_of!(self is ClickHouseDialect | GenericDialect) => {
Ok(self.parse_sub_type(DataType::Nullable)?)
}
Keyword::LOWCARDINALITY if dialect_of!(self is ClickHouseDialect | GenericDialect) => {
Ok(self.parse_sub_type(DataType::LowCardinality)?)
}
Keyword::MAP if dialect_of!(self is ClickHouseDialect | GenericDialect) => {
self.prev_token();
let (key_data_type, value_data_type) = self.parse_click_house_map_def()?;
Ok(DataType::Map(
Box::new(key_data_type),
Box::new(value_data_type),
))
}
Keyword::NESTED if dialect_of!(self is ClickHouseDialect | GenericDialect) => {
self.expect_token(&Token::LParen)?;
let field_defs = self.parse_comma_separated(Parser::parse_column_def)?;
self.expect_token(&Token::RParen)?;
Ok(DataType::Nested(field_defs))
}
Keyword::TUPLE if dialect_of!(self is ClickHouseDialect | GenericDialect) => {
self.prev_token();
let field_defs = self.parse_click_house_tuple_def()?;
Ok(DataType::Tuple(field_defs))
}
Keyword::TRIGGER => Ok(DataType::Trigger),
_ => {
self.prev_token();
let type_name = self.parse_object_name(false)?;
if let Some(modifiers) = self.parse_optional_type_modifiers()? {
Ok(DataType::Custom(type_name, modifiers))
} else {
Ok(DataType::Custom(type_name, vec![]))
}
}
},
_ => self.expected("a data type name", next_token),
}?;
// Parse array data types. Note: this is postgresql-specific and different from
// Keyword::ARRAY syntax from above
while self.consume_token(&Token::LBracket) {
let size = if dialect_of!(self is GenericDialect | DuckDbDialect | PostgreSqlDialect) {
self.maybe_parse(|p| p.parse_literal_uint())
} else {
None
};
self.expect_token(&Token::RBracket)?;
data = DataType::Array(ArrayElemTypeDef::SquareBracket(Box::new(data), size))
}
Ok((data, trailing_bracket))
}
pub fn parse_string_values(&mut self) -> Result<Vec<String>, ParserError> {
self.expect_token(&Token::LParen)?;
let mut values = Vec::new();
loop {
let next_token = self.next_token();
match next_token.token {
Token::SingleQuotedString(value) => values.push(value),
_ => self.expected("a string", next_token)?,
}
let next_token = self.next_token();
match next_token.token {
Token::Comma => (),
Token::RParen => break,
_ => self.expected(", or }", next_token)?,
}
}
Ok(values)
}
/// Strictly parse `identifier AS identifier`
pub fn parse_identifier_with_alias(&mut self) -> Result<IdentWithAlias, ParserError> {
let ident = self.parse_identifier(false)?;
self.expect_keyword(Keyword::AS)?;
let alias = self.parse_identifier(false)?;
Ok(IdentWithAlias { ident, alias })
}
/// Parse `AS identifier` (or simply `identifier` if it's not a reserved keyword)
/// Some examples with aliases: `SELECT 1 foo`, `SELECT COUNT(*) AS cnt`,
/// `SELECT ... FROM t1 foo, t2 bar`, `SELECT ... FROM (...) AS bar`
pub fn parse_optional_alias(
&mut self,
reserved_kwds: &[Keyword],
) -> Result<Option<Ident>, ParserError> {
let after_as = self.parse_keyword(Keyword::AS);
let next_token = self.next_token();
match next_token.token {
// Accept any identifier after `AS` (though many dialects have restrictions on
// keywords that may appear here). If there's no `AS`: don't parse keywords,
// which may start a construct allowed in this position, to be parsed as aliases.
// (For example, in `FROM t1 JOIN` the `JOIN` will always be parsed as a keyword,
// not an alias.)
Token::Word(w) if after_as || !reserved_kwds.contains(&w.keyword) => {
Ok(Some(w.to_ident()))
}
// MSSQL supports single-quoted strings as aliases for columns
// We accept them as table aliases too, although MSSQL does not.
//
// Note, that this conflicts with an obscure rule from the SQL
// standard, which we don't implement:
// https://crate.io/docs/sql-99/en/latest/chapters/07.html#character-string-literal-s
// "[Obscure Rule] SQL allows you to break a long <character
// string literal> up into two or more smaller <character string
// literal>s, split by a <separator> that includes a newline
// character. When it sees such a <literal>, your DBMS will
// ignore the <separator> and treat the multiple strings as
// a single <literal>."
Token::SingleQuotedString(s) => Ok(Some(Ident::with_quote('\'', s))),
// Support for MySql dialect double-quoted string, `AS "HOUR"` for example
Token::DoubleQuotedString(s) => Ok(Some(Ident::with_quote('\"', s))),
_ => {
if after_as {
return self.expected("an identifier after AS", next_token);
}
self.prev_token();
Ok(None) // no alias found
}
}
}
/// Parse `AS identifier` when the AS is describing a table-valued object,
/// like in `... FROM generate_series(1, 10) AS t (col)`. In this case
/// the alias is allowed to optionally name the columns in the table, in
/// addition to the table itself.
pub fn parse_optional_table_alias(
&mut self,
reserved_kwds: &[Keyword],
) -> Result<Option<TableAlias>, ParserError> {
match self.parse_optional_alias(reserved_kwds)? {
Some(name) => {
let columns = self.parse_parenthesized_column_list(Optional, false)?;
Ok(Some(TableAlias { name, columns }))
}
None => Ok(None),
}
}
/// Parse a possibly qualified, possibly quoted identifier, e.g.
/// `foo` or `myschema."table"
///
/// The `in_table_clause` parameter indicates whether the object name is a table in a FROM, JOIN,
/// or similar table clause. Currently, this is used only to support unquoted hyphenated identifiers
/// in this context on BigQuery.
pub fn parse_object_name(&mut self, in_table_clause: bool) -> Result<ObjectName, ParserError> {
let mut idents = vec![];
loop {
idents.push(self.parse_identifier(in_table_clause)?);
if !self.consume_token(&Token::Period) {
break;
}
}
// BigQuery accepts any number of quoted identifiers of a table name.
// https://cloud.google.com/bigquery/docs/reference/standard-sql/lexical#quoted_identifiers
if dialect_of!(self is BigQueryDialect)
&& idents.iter().any(|ident| ident.value.contains('.'))
{
idents = idents
.into_iter()
.flat_map(|ident| {
ident
.value
.split('.')
.map(|value| Ident {
value: value.into(),
quote_style: ident.quote_style,
})
.collect::<Vec<_>>()
})
.collect()
}
Ok(ObjectName(idents))
}
/// Parse identifiers
pub fn parse_identifiers(&mut self) -> Result<Vec<Ident>, ParserError> {
let mut idents = vec![];
loop {
match self.peek_token().token {
Token::Word(w) => {
idents.push(w.to_ident());
}
Token::EOF | Token::Eq => break,
_ => {}
}
self.next_token();
}
Ok(idents)
}
/// Parse identifiers of form ident1[.identN]*
///
/// Similar in functionality to [parse_identifiers], with difference
/// being this function is much more strict about parsing a valid multipart identifier, not
/// allowing extraneous tokens to be parsed, otherwise it fails.
///
/// For example:
///
/// ```rust
/// use sqlparser::ast::Ident;
/// use sqlparser::dialect::GenericDialect;
/// use sqlparser::parser::Parser;
///
/// let dialect = GenericDialect {};
/// let expected = vec![Ident::new("one"), Ident::new("two")];
///
/// // expected usage
/// let sql = "one.two";
/// let mut parser = Parser::new(&dialect).try_with_sql(sql).unwrap();
/// let actual = parser.parse_multipart_identifier().unwrap();
/// assert_eq!(&actual, &expected);
///
/// // parse_identifiers is more loose on what it allows, parsing successfully
/// let sql = "one + two";
/// let mut parser = Parser::new(&dialect).try_with_sql(sql).unwrap();
/// let actual = parser.parse_identifiers().unwrap();
/// assert_eq!(&actual, &expected);
///
/// // expected to strictly fail due to + separator
/// let sql = "one + two";
/// let mut parser = Parser::new(&dialect).try_with_sql(sql).unwrap();
/// let actual = parser.parse_multipart_identifier().unwrap_err();
/// assert_eq!(
/// actual.to_string(),
/// "sql parser error: Unexpected token in identifier: +"
/// );
/// ```
///
/// [parse_identifiers]: Parser::parse_identifiers
pub fn parse_multipart_identifier(&mut self) -> Result<Vec<Ident>, ParserError> {
let mut idents = vec![];
// expecting at least one word for identifier
match self.next_token().token {
Token::Word(w) => idents.push(w.to_ident()),
Token::EOF => {
return Err(ParserError::ParserError(
"Empty input when parsing identifier".to_string(),
))?
}
token => {
return Err(ParserError::ParserError(format!(
"Unexpected token in identifier: {token}"
)))?
}
};
// parse optional next parts if exist
loop {
match self.next_token().token {
// ensure that optional period is succeeded by another identifier
Token::Period => match self.next_token().token {
Token::Word(w) => idents.push(w.to_ident()),
Token::EOF => {
return Err(ParserError::ParserError(
"Trailing period in identifier".to_string(),
))?
}
token => {
return Err(ParserError::ParserError(format!(
"Unexpected token following period in identifier: {token}"
)))?
}
},
Token::EOF => break,
token => {
return Err(ParserError::ParserError(format!(
"Unexpected token in identifier: {token}"
)))?
}
}
}
Ok(idents)
}
/// Parse a simple one-word identifier (possibly quoted, possibly a keyword)
///
/// The `in_table_clause` parameter indicates whether the identifier is a table in a FROM, JOIN, or
/// similar table clause. Currently, this is used only to support unquoted hyphenated identifiers in
// this context on BigQuery.
pub fn parse_identifier(&mut self, in_table_clause: bool) -> Result<Ident, ParserError> {
let next_token = self.next_token();
match next_token.token {
Token::Word(w) => {
let mut ident = w.to_ident();
// On BigQuery, hyphens are permitted in unquoted identifiers inside of a FROM or
// TABLE clause [0].
//
// The first segment must be an ordinary unquoted identifier, e.g. it must not start
// with a digit. Subsequent segments are either must either be valid identifiers or
// integers, e.g. foo-123 is allowed, but foo-123a is not.
//
// [0] https://cloud.google.com/bigquery/docs/reference/standard-sql/lexical
if dialect_of!(self is BigQueryDialect)
&& w.quote_style.is_none()
&& in_table_clause
{
let mut requires_whitespace = false;
while matches!(self.peek_token_no_skip().token, Token::Minus) {
self.next_token();
ident.value.push('-');
let token = self
.next_token_no_skip()
.cloned()
.unwrap_or(TokenWithLocation::wrap(Token::EOF));
requires_whitespace = match token.token {
Token::Word(next_word) if next_word.quote_style.is_none() => {
ident.value.push_str(&next_word.value);
false
}
Token::Number(s, false) if s.chars().all(|c| c.is_ascii_digit()) => {
ident.value.push_str(&s);
true
}
_ => {
return self
.expected("continuation of hyphenated identifier", token);
}
}
}
// If the last segment was a number, we must check that it's followed by whitespace,
// otherwise foo-123a will be parsed as `foo-123` with the alias `a`.
if requires_whitespace {
let token = self.next_token();
if !matches!(token.token, Token::EOF | Token::Whitespace(_)) {
return self
.expected("whitespace following hyphenated identifier", token);
}
}
}
Ok(ident)
}
Token::SingleQuotedString(s) => Ok(Ident::with_quote('\'', s)),
Token::DoubleQuotedString(s) => Ok(Ident::with_quote('\"', s)),
_ => self.expected("identifier", next_token),
}
}
/// Parses a parenthesized, comma-separated list of column definitions within a view.
fn parse_view_columns(&mut self) -> Result<Vec<ViewColumnDef>, ParserError> {
if self.consume_token(&Token::LParen) {
if self.peek_token().token == Token::RParen {
self.next_token();
Ok(vec![])
} else {
let cols = self.parse_comma_separated(Parser::parse_view_column)?;
self.expect_token(&Token::RParen)?;
Ok(cols)
}
} else {
Ok(vec![])
}
}
/// Parses a column definition within a view.
fn parse_view_column(&mut self) -> Result<ViewColumnDef, ParserError> {
let name = self.parse_identifier(false)?;
let options = if dialect_of!(self is BigQueryDialect | GenericDialect)
&& self.parse_keyword(Keyword::OPTIONS)
{
self.prev_token();
Some(self.parse_options(Keyword::OPTIONS)?)
} else {
None
};
let data_type = if dialect_of!(self is ClickHouseDialect) {
Some(self.parse_data_type()?)
} else {
None
};
Ok(ViewColumnDef {
name,
data_type,
options,
})
}
/// Parse a parenthesized comma-separated list of unqualified, possibly quoted identifiers
pub fn parse_parenthesized_column_list(
&mut self,
optional: IsOptional,
allow_empty: bool,
) -> Result<Vec<Ident>, ParserError> {
if self.consume_token(&Token::LParen) {
if allow_empty && self.peek_token().token == Token::RParen {
self.next_token();
Ok(vec![])
} else {
let cols = self.parse_comma_separated(|p| p.parse_identifier(false))?;
self.expect_token(&Token::RParen)?;
Ok(cols)
}
} else if optional == Optional {
Ok(vec![])
} else {
self.expected("a list of columns in parentheses", self.peek_token())
}
}
pub fn parse_precision(&mut self) -> Result<u64, ParserError> {
self.expect_token(&Token::LParen)?;
let n = self.parse_literal_uint()?;
self.expect_token(&Token::RParen)?;
Ok(n)
}
pub fn parse_optional_precision(&mut self) -> Result<Option<u64>, ParserError> {
if self.consume_token(&Token::LParen) {
let n = self.parse_literal_uint()?;
self.expect_token(&Token::RParen)?;
Ok(Some(n))
} else {
Ok(None)
}
}
/// Parse datetime64 [1]
/// Syntax
/// ```sql
/// DateTime64(precision[, timezone])
/// ```
///
/// [1]: https://clickhouse.com/docs/en/sql-reference/data-types/datetime64
pub fn parse_datetime_64(&mut self) -> Result<(u64, Option<String>), ParserError> {
self.expect_keyword(Keyword::DATETIME64)?;
self.expect_token(&Token::LParen)?;
let precision = self.parse_literal_uint()?;
let time_zone = if self.consume_token(&Token::Comma) {
Some(self.parse_literal_string()?)
} else {
None
};
self.expect_token(&Token::RParen)?;
Ok((precision, time_zone))
}
pub fn parse_optional_character_length(
&mut self,
) -> Result<Option<CharacterLength>, ParserError> {
if self.consume_token(&Token::LParen) {
let character_length = self.parse_character_length()?;
self.expect_token(&Token::RParen)?;
Ok(Some(character_length))
} else {
Ok(None)
}
}
pub fn parse_character_length(&mut self) -> Result<CharacterLength, ParserError> {
if self.parse_keyword(Keyword::MAX) {
return Ok(CharacterLength::Max);
}
let length = self.parse_literal_uint()?;
let unit = if self.parse_keyword(Keyword::CHARACTERS) {
Some(CharLengthUnits::Characters)
} else if self.parse_keyword(Keyword::OCTETS) {
Some(CharLengthUnits::Octets)
} else {
None
};
Ok(CharacterLength::IntegerLength { length, unit })
}
pub fn parse_optional_precision_scale(
&mut self,
) -> Result<(Option<u64>, Option<u64>), ParserError> {
if self.consume_token(&Token::LParen) {
let n = self.parse_literal_uint()?;
let scale = if self.consume_token(&Token::Comma) {
Some(self.parse_literal_uint()?)
} else {
None
};
self.expect_token(&Token::RParen)?;
Ok((Some(n), scale))
} else {
Ok((None, None))
}
}
pub fn parse_exact_number_optional_precision_scale(
&mut self,
) -> Result<ExactNumberInfo, ParserError> {
if self.consume_token(&Token::LParen) {
let precision = self.parse_literal_uint()?;
let scale = if self.consume_token(&Token::Comma) {
Some(self.parse_literal_uint()?)
} else {
None
};
self.expect_token(&Token::RParen)?;
match scale {
None => Ok(ExactNumberInfo::Precision(precision)),
Some(scale) => Ok(ExactNumberInfo::PrecisionAndScale(precision, scale)),
}
} else {
Ok(ExactNumberInfo::None)
}
}
pub fn parse_optional_type_modifiers(&mut self) -> Result<Option<Vec<String>>, ParserError> {
if self.consume_token(&Token::LParen) {
let mut modifiers = Vec::new();
loop {
let next_token = self.next_token();
match next_token.token {
Token::Word(w) => modifiers.push(w.to_string()),
Token::Number(n, _) => modifiers.push(n),
Token::SingleQuotedString(s) => modifiers.push(s),
Token::Comma => {
continue;
}
Token::RParen => {
break;
}
_ => self.expected("type modifiers", next_token)?,
}
}
Ok(Some(modifiers))
} else {
Ok(None)
}
}
/// Parse a parenthesized sub data type
fn parse_sub_type<F>(&mut self, parent_type: F) -> Result<DataType, ParserError>
where
F: FnOnce(Box<DataType>) -> DataType,
{
self.expect_token(&Token::LParen)?;
let inside_type = self.parse_data_type()?;
self.expect_token(&Token::RParen)?;
Ok(parent_type(inside_type.into()))
}
pub fn parse_delete(&mut self) -> Result<Statement, ParserError> {
let (tables, with_from_keyword) = if !self.parse_keyword(Keyword::FROM) {
// `FROM` keyword is optional in BigQuery SQL.
// https://cloud.google.com/bigquery/docs/reference/standard-sql/dml-syntax#delete_statement
if dialect_of!(self is BigQueryDialect | GenericDialect) {
(vec![], false)
} else {
let tables = self.parse_comma_separated(|p| p.parse_object_name(false))?;
self.expect_keyword(Keyword::FROM)?;
(tables, true)
}
} else {
(vec![], true)
};
let from = self.parse_comma_separated(Parser::parse_table_and_joins)?;
let using = if self.parse_keyword(Keyword::USING) {
Some(self.parse_comma_separated(Parser::parse_table_and_joins)?)
} else {
None
};
let selection = if self.parse_keyword(Keyword::WHERE) {
Some(self.parse_expr()?)
} else {
None
};
let returning = if self.parse_keyword(Keyword::RETURNING) {
Some(self.parse_comma_separated(Parser::parse_select_item)?)
} else {
None
};
let order_by = if self.parse_keywords(&[Keyword::ORDER, Keyword::BY]) {
self.parse_comma_separated(Parser::parse_order_by_expr)?
} else {
vec![]
};
let limit = if self.parse_keyword(Keyword::LIMIT) {
self.parse_limit()?
} else {
None
};
Ok(Statement::Delete(Delete {
tables,
from: if with_from_keyword {
FromTable::WithFromKeyword(from)
} else {
FromTable::WithoutKeyword(from)
},
using,
selection,
returning,
order_by,
limit,
}))
}
// KILL [CONNECTION | QUERY | MUTATION] processlist_id
pub fn parse_kill(&mut self) -> Result<Statement, ParserError> {
let modifier_keyword =
self.parse_one_of_keywords(&[Keyword::CONNECTION, Keyword::QUERY, Keyword::MUTATION]);
let id = self.parse_literal_uint()?;
let modifier = match modifier_keyword {
Some(Keyword::CONNECTION) => Some(KillType::Connection),
Some(Keyword::QUERY) => Some(KillType::Query),
Some(Keyword::MUTATION) => {
if dialect_of!(self is ClickHouseDialect | GenericDialect) {
Some(KillType::Mutation)
} else {
self.expected(
"Unsupported type for KILL, allowed: CONNECTION | QUERY",
self.peek_token(),
)?
}
}
_ => None,
};
Ok(Statement::Kill { modifier, id })
}
pub fn parse_explain(
&mut self,
describe_alias: DescribeAlias,
) -> Result<Statement, ParserError> {
let analyze = self.parse_keyword(Keyword::ANALYZE);
let verbose = self.parse_keyword(Keyword::VERBOSE);
let mut format = None;
if self.parse_keyword(Keyword::FORMAT) {
format = Some(self.parse_analyze_format()?);
}
match self.maybe_parse(|parser| parser.parse_statement()) {
Some(Statement::Explain { .. }) | Some(Statement::ExplainTable { .. }) => Err(
ParserError::ParserError("Explain must be root of the plan".to_string()),
),
Some(statement) => Ok(Statement::Explain {
describe_alias,
analyze,
verbose,
statement: Box::new(statement),
format,
}),
_ => {
let hive_format =
match self.parse_one_of_keywords(&[Keyword::EXTENDED, Keyword::FORMATTED]) {
Some(Keyword::EXTENDED) => Some(HiveDescribeFormat::Extended),
Some(Keyword::FORMATTED) => Some(HiveDescribeFormat::Formatted),
_ => None,
};
let has_table_keyword = if self.dialect.describe_requires_table_keyword() {
// only allow to use TABLE keyword for DESC|DESCRIBE statement
self.parse_keyword(Keyword::TABLE)
} else {
false
};
let table_name = self.parse_object_name(false)?;
Ok(Statement::ExplainTable {
describe_alias,
hive_format,
has_table_keyword,
table_name,
})
}
}
}
/// Call's [`Self::parse_query`] returning a `Box`'ed result.
///
/// This function can be used to reduce the stack size required in debug
/// builds. Instead of `sizeof(Query)` only a pointer (`Box<Query>`)
/// is used.
pub fn parse_boxed_query(&mut self) -> Result<Box<Query>, ParserError> {
self.parse_query().map(Box::new)
}
/// Parse a query expression, i.e. a `SELECT` statement optionally
/// preceded with some `WITH` CTE declarations and optionally followed
/// by `ORDER BY`. Unlike some other parse_... methods, this one doesn't
/// expect the initial keyword to be already consumed
pub fn parse_query(&mut self) -> Result<Query, ParserError> {
let _guard = self.recursion_counter.try_decrease()?;
let with = if self.parse_keyword(Keyword::WITH) {
Some(With {
recursive: self.parse_keyword(Keyword::RECURSIVE),
cte_tables: self.parse_comma_separated(Parser::parse_cte)?,
})
} else {
None
};
if self.parse_keyword(Keyword::INSERT) {
Ok(Query {
with,
body: self.parse_insert_setexpr_boxed()?,
limit: None,
limit_by: vec![],
order_by: None,
offset: None,
fetch: None,
locks: vec![],
for_clause: None,
settings: None,
format_clause: None,
})
} else if self.parse_keyword(Keyword::UPDATE) {
Ok(Query {
with,
body: self.parse_update_setexpr_boxed()?,
limit: None,
limit_by: vec![],
order_by: None,
offset: None,
fetch: None,
locks: vec![],
for_clause: None,
settings: None,
format_clause: None,
})
} else {
let body = self.parse_boxed_query_body(self.dialect.prec_unknown())?;
let order_by = if self.parse_keywords(&[Keyword::ORDER, Keyword::BY]) {
let order_by_exprs = self.parse_comma_separated(Parser::parse_order_by_expr)?;
let interpolate = if dialect_of!(self is ClickHouseDialect | GenericDialect) {
self.parse_interpolations()?
} else {
None
};
Some(OrderBy {
exprs: order_by_exprs,
interpolate,
})
} else {
None
};
let mut limit = None;
let mut offset = None;
for _x in 0..2 {
if limit.is_none() && self.parse_keyword(Keyword::LIMIT) {
limit = self.parse_limit()?
}
if offset.is_none() && self.parse_keyword(Keyword::OFFSET) {
offset = Some(self.parse_offset()?)
}
if dialect_of!(self is GenericDialect | MySqlDialect | ClickHouseDialect)
&& limit.is_some()
&& offset.is_none()
&& self.consume_token(&Token::Comma)
{
// MySQL style LIMIT x,y => LIMIT y OFFSET x.
// Check <https://dev.mysql.com/doc/refman/8.0/en/select.html> for more details.
offset = Some(Offset {
value: limit.unwrap(),
rows: OffsetRows::None,
});
limit = Some(self.parse_expr()?);
}
}
let limit_by = if dialect_of!(self is ClickHouseDialect | GenericDialect)
&& self.parse_keyword(Keyword::BY)
{
self.parse_comma_separated(Parser::parse_expr)?
} else {
vec![]
};
let settings = self.parse_settings()?;
let fetch = if self.parse_keyword(Keyword::FETCH) {
Some(self.parse_fetch()?)
} else {
None
};
let mut for_clause = None;
let mut locks = Vec::new();
while self.parse_keyword(Keyword::FOR) {
if let Some(parsed_for_clause) = self.parse_for_clause()? {
for_clause = Some(parsed_for_clause);
break;
} else {
locks.push(self.parse_lock()?);
}
}
let format_clause = if dialect_of!(self is ClickHouseDialect | GenericDialect)
&& self.parse_keyword(Keyword::FORMAT)
{
if self.parse_keyword(Keyword::NULL) {
Some(FormatClause::Null)
} else {
let ident = self.parse_identifier(false)?;
Some(FormatClause::Identifier(ident))
}
} else {
None
};
Ok(Query {
with,
body,
order_by,
limit,
limit_by,
offset,
fetch,
locks,
for_clause,
settings,
format_clause,
})
}
}
fn parse_settings(&mut self) -> Result<Option<Vec<Setting>>, ParserError> {
let settings = if dialect_of!(self is ClickHouseDialect|GenericDialect)
&& self.parse_keyword(Keyword::SETTINGS)
{
let key_values = self.parse_comma_separated(|p| {
let key = p.parse_identifier(false)?;
p.expect_token(&Token::Eq)?;
let value = p.parse_value()?;
Ok(Setting { key, value })
})?;
Some(key_values)
} else {
None
};
Ok(settings)
}
/// Parse a mssql `FOR [XML | JSON | BROWSE]` clause
pub fn parse_for_clause(&mut self) -> Result<Option<ForClause>, ParserError> {
if self.parse_keyword(Keyword::XML) {
Ok(Some(self.parse_for_xml()?))
} else if self.parse_keyword(Keyword::JSON) {
Ok(Some(self.parse_for_json()?))
} else if self.parse_keyword(Keyword::BROWSE) {
Ok(Some(ForClause::Browse))
} else {
Ok(None)
}
}
/// Parse a mssql `FOR XML` clause
pub fn parse_for_xml(&mut self) -> Result<ForClause, ParserError> {
let for_xml = if self.parse_keyword(Keyword::RAW) {
let mut element_name = None;
if self.peek_token().token == Token::LParen {
self.expect_token(&Token::LParen)?;
element_name = Some(self.parse_literal_string()?);
self.expect_token(&Token::RParen)?;
}
ForXml::Raw(element_name)
} else if self.parse_keyword(Keyword::AUTO) {
ForXml::Auto
} else if self.parse_keyword(Keyword::EXPLICIT) {
ForXml::Explicit
} else if self.parse_keyword(Keyword::PATH) {
let mut element_name = None;
if self.peek_token().token == Token::LParen {
self.expect_token(&Token::LParen)?;
element_name = Some(self.parse_literal_string()?);
self.expect_token(&Token::RParen)?;
}
ForXml::Path(element_name)
} else {
return Err(ParserError::ParserError(
"Expected FOR XML [RAW | AUTO | EXPLICIT | PATH ]".to_string(),
));
};
let mut elements = false;
let mut binary_base64 = false;
let mut root = None;
let mut r#type = false;
while self.peek_token().token == Token::Comma {
self.next_token();
if self.parse_keyword(Keyword::ELEMENTS) {
elements = true;
} else if self.parse_keyword(Keyword::BINARY) {
self.expect_keyword(Keyword::BASE64)?;
binary_base64 = true;
} else if self.parse_keyword(Keyword::ROOT) {
self.expect_token(&Token::LParen)?;
root = Some(self.parse_literal_string()?);
self.expect_token(&Token::RParen)?;
} else if self.parse_keyword(Keyword::TYPE) {
r#type = true;
}
}
Ok(ForClause::Xml {
for_xml,
elements,
binary_base64,
root,
r#type,
})
}
/// Parse a mssql `FOR JSON` clause
pub fn parse_for_json(&mut self) -> Result<ForClause, ParserError> {
let for_json = if self.parse_keyword(Keyword::AUTO) {
ForJson::Auto
} else if self.parse_keyword(Keyword::PATH) {
ForJson::Path
} else {
return Err(ParserError::ParserError(
"Expected FOR JSON [AUTO | PATH ]".to_string(),
));
};
let mut root = None;
let mut include_null_values = false;
let mut without_array_wrapper = false;
while self.peek_token().token == Token::Comma {
self.next_token();
if self.parse_keyword(Keyword::ROOT) {
self.expect_token(&Token::LParen)?;
root = Some(self.parse_literal_string()?);
self.expect_token(&Token::RParen)?;
} else if self.parse_keyword(Keyword::INCLUDE_NULL_VALUES) {
include_null_values = true;
} else if self.parse_keyword(Keyword::WITHOUT_ARRAY_WRAPPER) {
without_array_wrapper = true;
}
}
Ok(ForClause::Json {
for_json,
root,
include_null_values,
without_array_wrapper,
})
}
/// Parse a CTE (`alias [( col1, col2, ... )] AS (subquery)`)
pub fn parse_cte(&mut self) -> Result<Cte, ParserError> {
let name = self.parse_identifier(false)?;
let mut cte = if self.parse_keyword(Keyword::AS) {
let mut is_materialized = None;
if dialect_of!(self is PostgreSqlDialect) {
if self.parse_keyword(Keyword::MATERIALIZED) {
is_materialized = Some(CteAsMaterialized::Materialized);
} else if self.parse_keywords(&[Keyword::NOT, Keyword::MATERIALIZED]) {
is_materialized = Some(CteAsMaterialized::NotMaterialized);
}
}
self.expect_token(&Token::LParen)?;
let query = self.parse_boxed_query()?;
self.expect_token(&Token::RParen)?;
let alias = TableAlias {
name,
columns: vec![],
};
Cte {
alias,
query,
from: None,
materialized: is_materialized,
}
} else {
let columns = self.parse_parenthesized_column_list(Optional, false)?;
self.expect_keyword(Keyword::AS)?;
let mut is_materialized = None;
if dialect_of!(self is PostgreSqlDialect) {
if self.parse_keyword(Keyword::MATERIALIZED) {
is_materialized = Some(CteAsMaterialized::Materialized);
} else if self.parse_keywords(&[Keyword::NOT, Keyword::MATERIALIZED]) {
is_materialized = Some(CteAsMaterialized::NotMaterialized);
}
}
self.expect_token(&Token::LParen)?;
let query = self.parse_boxed_query()?;
self.expect_token(&Token::RParen)?;
let alias = TableAlias { name, columns };
Cte {
alias,
query,
from: None,
materialized: is_materialized,
}
};
if self.parse_keyword(Keyword::FROM) {
cte.from = Some(self.parse_identifier(false)?);
}
Ok(cte)
}
/// Call's [`Self::parse_query_body`] returning a `Box`'ed result.
///
/// This function can be used to reduce the stack size required in debug
/// builds. Instead of `sizeof(QueryBody)` only a pointer (`Box<QueryBody>`)
/// is used.
fn parse_boxed_query_body(&mut self, precedence: u8) -> Result<Box<SetExpr>, ParserError> {
self.parse_query_body(precedence).map(Box::new)
}
/// Parse a "query body", which is an expression with roughly the
/// following grammar:
/// ```sql
/// query_body ::= restricted_select | '(' subquery ')' | set_operation
/// restricted_select ::= 'SELECT' [expr_list] [ from ] [ where ] [ groupby_having ]
/// subquery ::= query_body [ order_by_limit ]
/// set_operation ::= query_body { 'UNION' | 'EXCEPT' | 'INTERSECT' } [ 'ALL' ] query_body
/// ```
///
/// If you need `Box<SetExpr>` then maybe there is sense to use `parse_boxed_query_body`
/// due to prevent stack overflow in debug building(to reserve less memory on stack).
pub fn parse_query_body(&mut self, precedence: u8) -> Result<SetExpr, ParserError> {
// We parse the expression using a Pratt parser, as in `parse_expr()`.
// Start by parsing a restricted SELECT or a `(subquery)`:
let expr = if self.parse_keyword(Keyword::SELECT) {
SetExpr::Select(self.parse_select().map(Box::new)?)
} else if self.consume_token(&Token::LParen) {
// CTEs are not allowed here, but the parser currently accepts them
let subquery = self.parse_boxed_query()?;
self.expect_token(&Token::RParen)?;
SetExpr::Query(subquery)
} else if self.parse_keyword(Keyword::VALUES) {
let is_mysql = dialect_of!(self is MySqlDialect);
SetExpr::Values(self.parse_values(is_mysql)?)
} else if self.parse_keyword(Keyword::TABLE) {
SetExpr::Table(Box::new(self.parse_as_table()?))
} else {
return self.expected(
"SELECT, VALUES, or a subquery in the query body",
self.peek_token(),
);
};
self.parse_remaining_set_exprs(expr, precedence)
}
/// Parse any extra set expressions that may be present in a query body
///
/// (this is its own function to reduce required stack size in debug builds)
fn parse_remaining_set_exprs(
&mut self,
mut expr: SetExpr,
precedence: u8,
) -> Result<SetExpr, ParserError> {
loop {
// The query can be optionally followed by a set operator:
let op = self.parse_set_operator(&self.peek_token().token);
let next_precedence = match op {
// UNION and EXCEPT have the same binding power and evaluate left-to-right
Some(SetOperator::Union) | Some(SetOperator::Except) => 10,
// INTERSECT has higher precedence than UNION/EXCEPT
Some(SetOperator::Intersect) => 20,
// Unexpected token or EOF => stop parsing the query body
None => break,
};
if precedence >= next_precedence {
break;
}
self.next_token(); // skip past the set operator
let set_quantifier = self.parse_set_quantifier(&op);
expr = SetExpr::SetOperation {
left: Box::new(expr),
op: op.unwrap(),
set_quantifier,
right: self.parse_boxed_query_body(next_precedence)?,
};
}
Ok(expr)
}
pub fn parse_set_operator(&mut self, token: &Token) -> Option<SetOperator> {
match token {
Token::Word(w) if w.keyword == Keyword::UNION => Some(SetOperator::Union),
Token::Word(w) if w.keyword == Keyword::EXCEPT => Some(SetOperator::Except),
Token::Word(w) if w.keyword == Keyword::INTERSECT => Some(SetOperator::Intersect),
_ => None,
}
}
pub fn parse_set_quantifier(&mut self, op: &Option<SetOperator>) -> SetQuantifier {
match op {
Some(SetOperator::Except | SetOperator::Intersect | SetOperator::Union) => {
if self.parse_keywords(&[Keyword::DISTINCT, Keyword::BY, Keyword::NAME]) {
SetQuantifier::DistinctByName
} else if self.parse_keywords(&[Keyword::BY, Keyword::NAME]) {
SetQuantifier::ByName
} else if self.parse_keyword(Keyword::ALL) {
if self.parse_keywords(&[Keyword::BY, Keyword::NAME]) {
SetQuantifier::AllByName
} else {
SetQuantifier::All
}
} else if self.parse_keyword(Keyword::DISTINCT) {
SetQuantifier::Distinct
} else {
SetQuantifier::None
}
}
_ => SetQuantifier::None,
}
}
/// Parse a restricted `SELECT` statement (no CTEs / `UNION` / `ORDER BY`),
/// assuming the initial `SELECT` was already consumed
pub fn parse_select(&mut self) -> Result<Select, ParserError> {
let value_table_mode =
if dialect_of!(self is BigQueryDialect) && self.parse_keyword(Keyword::AS) {
if self.parse_keyword(Keyword::VALUE) {
Some(ValueTableMode::AsValue)
} else if self.parse_keyword(Keyword::STRUCT) {
Some(ValueTableMode::AsStruct)
} else {
self.expected("VALUE or STRUCT", self.peek_token())?
}
} else {
None
};
let distinct = self.parse_all_or_distinct()?;
let top = if self.parse_keyword(Keyword::TOP) {
Some(self.parse_top()?)
} else {
None
};
let projection = self.parse_projection()?;
let into = if self.parse_keyword(Keyword::INTO) {
let temporary = self
.parse_one_of_keywords(&[Keyword::TEMP, Keyword::TEMPORARY])
.is_some();
let unlogged = self.parse_keyword(Keyword::UNLOGGED);
let table = self.parse_keyword(Keyword::TABLE);
let name = self.parse_object_name(false)?;
Some(SelectInto {
temporary,
unlogged,
table,
name,
})
} else {
None
};
// Note that for keywords to be properly handled here, they need to be
// added to `RESERVED_FOR_COLUMN_ALIAS` / `RESERVED_FOR_TABLE_ALIAS`,
// otherwise they may be parsed as an alias as part of the `projection`
// or `from`.
let from = if self.parse_keyword(Keyword::FROM) {
self.parse_comma_separated(Parser::parse_table_and_joins)?
} else {
vec![]
};
let mut lateral_views = vec![];
loop {
if self.parse_keywords(&[Keyword::LATERAL, Keyword::VIEW]) {
let outer = self.parse_keyword(Keyword::OUTER);
let lateral_view = self.parse_expr()?;
let lateral_view_name = self.parse_object_name(false)?;
let lateral_col_alias = self
.parse_comma_separated(|parser| {
parser.parse_optional_alias(&[
Keyword::WHERE,
Keyword::GROUP,
Keyword::CLUSTER,
Keyword::HAVING,
Keyword::LATERAL,
]) // This couldn't possibly be a bad idea
})?
.into_iter()
.flatten()
.collect();
lateral_views.push(LateralView {
lateral_view,
lateral_view_name,
lateral_col_alias,
outer,
});
} else {
break;
}
}
let prewhere = if dialect_of!(self is ClickHouseDialect|GenericDialect)
&& self.parse_keyword(Keyword::PREWHERE)
{
Some(self.parse_expr()?)
} else {
None
};
let selection = if self.parse_keyword(Keyword::WHERE) {
Some(self.parse_expr()?)
} else {
None
};
let group_by = if self.parse_keywords(&[Keyword::GROUP, Keyword::BY]) {
let expressions = if self.parse_keyword(Keyword::ALL) {
None
} else {
Some(self.parse_comma_separated(Parser::parse_group_by_expr)?)
};
let mut modifiers = vec![];
if dialect_of!(self is ClickHouseDialect | GenericDialect) {
loop {
if !self.parse_keyword(Keyword::WITH) {
break;
}
let keyword = self.expect_one_of_keywords(&[
Keyword::ROLLUP,
Keyword::CUBE,
Keyword::TOTALS,
])?;
modifiers.push(match keyword {
Keyword::ROLLUP => GroupByWithModifier::Rollup,
Keyword::CUBE => GroupByWithModifier::Cube,
Keyword::TOTALS => GroupByWithModifier::Totals,
_ => {
return parser_err!(
"BUG: expected to match GroupBy modifier keyword",
self.peek_token().location
)
}
});
}
}
match expressions {
None => GroupByExpr::All(modifiers),
Some(exprs) => GroupByExpr::Expressions(exprs, modifiers),
}
} else {
GroupByExpr::Expressions(vec![], vec![])
};
let cluster_by = if self.parse_keywords(&[Keyword::CLUSTER, Keyword::BY]) {
self.parse_comma_separated(Parser::parse_expr)?
} else {
vec![]
};
let distribute_by = if self.parse_keywords(&[Keyword::DISTRIBUTE, Keyword::BY]) {
self.parse_comma_separated(Parser::parse_expr)?
} else {
vec![]
};
let sort_by = if self.parse_keywords(&[Keyword::SORT, Keyword::BY]) {
self.parse_comma_separated(Parser::parse_expr)?
} else {
vec![]
};
let having = if self.parse_keyword(Keyword::HAVING) {
Some(self.parse_expr()?)
} else {
None
};
// Accept QUALIFY and WINDOW in any order and flag accordingly.
let (named_windows, qualify, window_before_qualify) = if self.parse_keyword(Keyword::WINDOW)
{
let named_windows = self.parse_comma_separated(Parser::parse_named_window)?;
if self.parse_keyword(Keyword::QUALIFY) {
(named_windows, Some(self.parse_expr()?), true)
} else {
(named_windows, None, true)
}
} else if self.parse_keyword(Keyword::QUALIFY) {
let qualify = Some(self.parse_expr()?);
if self.parse_keyword(Keyword::WINDOW) {
(
self.parse_comma_separated(Parser::parse_named_window)?,
qualify,
false,
)
} else {
(Default::default(), qualify, false)
}
} else {
Default::default()
};
let connect_by = if self.dialect.supports_connect_by()
&& self
.parse_one_of_keywords(&[Keyword::START, Keyword::CONNECT])
.is_some()
{
self.prev_token();
Some(self.parse_connect_by()?)
} else {
None
};
Ok(Select {
distinct,
top,
projection,
into,
from,
lateral_views,
prewhere,
selection,
group_by,
cluster_by,
distribute_by,
sort_by,
having,
named_window: named_windows,
window_before_qualify,
qualify,
value_table_mode,
connect_by,
})
}
/// Invoke `f` after first setting the parser's `ParserState` to `state`.
///
/// Upon return, restores the parser's state to what it started at.
fn with_state<T, F>(&mut self, state: ParserState, mut f: F) -> Result<T, ParserError>
where
F: FnMut(&mut Parser) -> Result<T, ParserError>,
{
let current_state = self.state;
self.state = state;
let res = f(self);
self.state = current_state;
res
}
pub fn parse_connect_by(&mut self) -> Result<ConnectBy, ParserError> {
let (condition, relationships) = if self.parse_keywords(&[Keyword::CONNECT, Keyword::BY]) {
let relationships = self.with_state(ParserState::ConnectBy, |parser| {
parser.parse_comma_separated(Parser::parse_expr)
})?;
self.expect_keywords(&[Keyword::START, Keyword::WITH])?;
let condition = self.parse_expr()?;
(condition, relationships)
} else {
self.expect_keywords(&[Keyword::START, Keyword::WITH])?;
let condition = self.parse_expr()?;
self.expect_keywords(&[Keyword::CONNECT, Keyword::BY])?;
let relationships = self.with_state(ParserState::ConnectBy, |parser| {
parser.parse_comma_separated(Parser::parse_expr)
})?;
(condition, relationships)
};
Ok(ConnectBy {
condition,
relationships,
})
}
/// Parse `CREATE TABLE x AS TABLE y`
pub fn parse_as_table(&mut self) -> Result<Table, ParserError> {
let token1 = self.next_token();
let token2 = self.next_token();
let token3 = self.next_token();
let table_name;
let schema_name;
if token2 == Token::Period {
match token1.token {
Token::Word(w) => {
schema_name = w.value;
}
_ => {
return self.expected("Schema name", token1);
}
}
match token3.token {
Token::Word(w) => {
table_name = w.value;
}
_ => {
return self.expected("Table name", token3);
}
}
Ok(Table {
table_name: Some(table_name),
schema_name: Some(schema_name),
})
} else {
match token1.token {
Token::Word(w) => {
table_name = w.value;
}
_ => {
return self.expected("Table name", token1);
}
}
Ok(Table {
table_name: Some(table_name),
schema_name: None,
})
}
}
pub fn parse_set(&mut self) -> Result<Statement, ParserError> {
let modifier =
self.parse_one_of_keywords(&[Keyword::SESSION, Keyword::LOCAL, Keyword::HIVEVAR]);
if let Some(Keyword::HIVEVAR) = modifier {
self.expect_token(&Token::Colon)?;
} else if self.parse_keyword(Keyword::ROLE) {
let context_modifier = match modifier {
Some(Keyword::LOCAL) => ContextModifier::Local,
Some(Keyword::SESSION) => ContextModifier::Session,
_ => ContextModifier::None,
};
let role_name = if self.parse_keyword(Keyword::NONE) {
None
} else {
Some(self.parse_identifier(false)?)
};
return Ok(Statement::SetRole {
context_modifier,
role_name,
});
}
let variables = if self.parse_keywords(&[Keyword::TIME, Keyword::ZONE]) {
OneOrManyWithParens::One(ObjectName(vec!["TIMEZONE".into()]))
} else if self.dialect.supports_parenthesized_set_variables()
&& self.consume_token(&Token::LParen)
{
let variables = OneOrManyWithParens::Many(
self.parse_comma_separated(|parser: &mut Parser<'a>| {
parser.parse_identifier(false)
})?
.into_iter()
.map(|ident| ObjectName(vec![ident]))
.collect(),
);
self.expect_token(&Token::RParen)?;
variables
} else {
OneOrManyWithParens::One(self.parse_object_name(false)?)
};
if matches!(&variables, OneOrManyWithParens::One(variable) if variable.to_string().eq_ignore_ascii_case("NAMES")
&& dialect_of!(self is MySqlDialect | GenericDialect))
{
if self.parse_keyword(Keyword::DEFAULT) {
return Ok(Statement::SetNamesDefault {});
}
let charset_name = self.parse_literal_string()?;
let collation_name = if self.parse_one_of_keywords(&[Keyword::COLLATE]).is_some() {
Some(self.parse_literal_string()?)
} else {
None
};
return Ok(Statement::SetNames {
charset_name,
collation_name,
});
}
let parenthesized_assignment = matches!(&variables, OneOrManyWithParens::Many(_));
if self.consume_token(&Token::Eq) || self.parse_keyword(Keyword::TO) {
if parenthesized_assignment {
self.expect_token(&Token::LParen)?;
}
let mut values = vec![];
loop {
let value = if let Some(expr) = self.try_parse_expr_sub_query()? {
expr
} else if let Ok(expr) = self.parse_expr() {
expr
} else {
self.expected("variable value", self.peek_token())?
};
values.push(value);
if self.consume_token(&Token::Comma) {
continue;
}
if parenthesized_assignment {
self.expect_token(&Token::RParen)?;
}
return Ok(Statement::SetVariable {
local: modifier == Some(Keyword::LOCAL),
hivevar: Some(Keyword::HIVEVAR) == modifier,
variables,
value: values,
});
}
}
let OneOrManyWithParens::One(variable) = variables else {
return self.expected("set variable", self.peek_token());
};
if variable.to_string().eq_ignore_ascii_case("TIMEZONE") {
// for some db (e.g. postgresql), SET TIME ZONE <value> is an alias for SET TIMEZONE [TO|=] <value>
match self.parse_expr() {
Ok(expr) => Ok(Statement::SetTimeZone {
local: modifier == Some(Keyword::LOCAL),
value: expr,
}),
_ => self.expected("timezone value", self.peek_token())?,
}
} else if variable.to_string() == "CHARACTERISTICS" {
self.expect_keywords(&[Keyword::AS, Keyword::TRANSACTION])?;
Ok(Statement::SetTransaction {
modes: self.parse_transaction_modes()?,
snapshot: None,
session: true,
})
} else if variable.to_string() == "TRANSACTION" && modifier.is_none() {
if self.parse_keyword(Keyword::SNAPSHOT) {
let snapshot_id = self.parse_value()?;
return Ok(Statement::SetTransaction {
modes: vec![],
snapshot: Some(snapshot_id),
session: false,
});
}
Ok(Statement::SetTransaction {
modes: self.parse_transaction_modes()?,
snapshot: None,
session: false,
})
} else {
self.expected("equals sign or TO", self.peek_token())
}
}
pub fn parse_show(&mut self) -> Result<Statement, ParserError> {
let extended = self.parse_keyword(Keyword::EXTENDED);
let full = self.parse_keyword(Keyword::FULL);
let session = self.parse_keyword(Keyword::SESSION);
let global = self.parse_keyword(Keyword::GLOBAL);
if self
.parse_one_of_keywords(&[Keyword::COLUMNS, Keyword::FIELDS])
.is_some()
{
Ok(self.parse_show_columns(extended, full)?)
} else if self.parse_keyword(Keyword::TABLES) {
Ok(self.parse_show_tables(extended, full)?)
} else if self.parse_keyword(Keyword::FUNCTIONS) {
Ok(self.parse_show_functions()?)
} else if extended || full {
Err(ParserError::ParserError(
"EXTENDED/FULL are not supported with this type of SHOW query".to_string(),
))
} else if self.parse_one_of_keywords(&[Keyword::CREATE]).is_some() {
Ok(self.parse_show_create()?)
} else if self.parse_keyword(Keyword::COLLATION) {
Ok(self.parse_show_collation()?)
} else if self.parse_keyword(Keyword::VARIABLES)
&& dialect_of!(self is MySqlDialect | GenericDialect)
{
Ok(Statement::ShowVariables {
filter: self.parse_show_statement_filter()?,
session,
global,
})
} else if self.parse_keyword(Keyword::STATUS)
&& dialect_of!(self is MySqlDialect | GenericDialect)
{
Ok(Statement::ShowStatus {
filter: self.parse_show_statement_filter()?,
session,
global,
})
} else {
Ok(Statement::ShowVariable {
variable: self.parse_identifiers()?,
})
}
}
pub fn parse_show_create(&mut self) -> Result<Statement, ParserError> {
let obj_type = match self.expect_one_of_keywords(&[
Keyword::TABLE,
Keyword::TRIGGER,
Keyword::FUNCTION,
Keyword::PROCEDURE,
Keyword::EVENT,
Keyword::VIEW,
])? {
Keyword::TABLE => Ok(ShowCreateObject::Table),
Keyword::TRIGGER => Ok(ShowCreateObject::Trigger),
Keyword::FUNCTION => Ok(ShowCreateObject::Function),
Keyword::PROCEDURE => Ok(ShowCreateObject::Procedure),
Keyword::EVENT => Ok(ShowCreateObject::Event),
Keyword::VIEW => Ok(ShowCreateObject::View),
keyword => Err(ParserError::ParserError(format!(
"Unable to map keyword to ShowCreateObject: {keyword:?}"
))),
}?;
let obj_name = self.parse_object_name(false)?;
Ok(Statement::ShowCreate { obj_type, obj_name })
}
pub fn parse_show_columns(
&mut self,
extended: bool,
full: bool,
) -> Result<Statement, ParserError> {
self.expect_one_of_keywords(&[Keyword::FROM, Keyword::IN])?;
let object_name = self.parse_object_name(false)?;
let table_name = match self.parse_one_of_keywords(&[Keyword::FROM, Keyword::IN]) {
Some(_) => {
let db_name = vec![self.parse_identifier(false)?];
let ObjectName(table_name) = object_name;
let object_name = db_name.into_iter().chain(table_name).collect();
ObjectName(object_name)
}
None => object_name,
};
let filter = self.parse_show_statement_filter()?;
Ok(Statement::ShowColumns {
extended,
full,
table_name,
filter,
})
}
pub fn parse_show_tables(
&mut self,
extended: bool,
full: bool,
) -> Result<Statement, ParserError> {
let db_name = match self.parse_one_of_keywords(&[Keyword::FROM, Keyword::IN]) {
Some(_) => Some(self.parse_identifier(false)?),
None => None,
};
let filter = self.parse_show_statement_filter()?;
Ok(Statement::ShowTables {
extended,
full,
db_name,
filter,
})
}
pub fn parse_show_functions(&mut self) -> Result<Statement, ParserError> {
let filter = self.parse_show_statement_filter()?;
Ok(Statement::ShowFunctions { filter })
}
pub fn parse_show_collation(&mut self) -> Result<Statement, ParserError> {
let filter = self.parse_show_statement_filter()?;
Ok(Statement::ShowCollation { filter })
}
pub fn parse_show_statement_filter(
&mut self,
) -> Result<Option<ShowStatementFilter>, ParserError> {
if self.parse_keyword(Keyword::LIKE) {
Ok(Some(ShowStatementFilter::Like(
self.parse_literal_string()?,
)))
} else if self.parse_keyword(Keyword::ILIKE) {
Ok(Some(ShowStatementFilter::ILike(
self.parse_literal_string()?,
)))
} else if self.parse_keyword(Keyword::WHERE) {
Ok(Some(ShowStatementFilter::Where(self.parse_expr()?)))
} else {
Ok(None)
}
}
pub fn parse_use(&mut self) -> Result<Statement, ParserError> {
let db_name = self.parse_identifier(false)?;
Ok(Statement::Use { db_name })
}
pub fn parse_table_and_joins(&mut self) -> Result<TableWithJoins, ParserError> {
let relation = self.parse_table_factor()?;
// Note that for keywords to be properly handled here, they need to be
// added to `RESERVED_FOR_TABLE_ALIAS`, otherwise they may be parsed as
// a table alias.
let mut joins = vec![];
loop {
let global = self.parse_keyword(Keyword::GLOBAL);
let join = if self.parse_keyword(Keyword::CROSS) {
let join_operator = if self.parse_keyword(Keyword::JOIN) {
JoinOperator::CrossJoin
} else if self.parse_keyword(Keyword::APPLY) {
// MSSQL extension, similar to CROSS JOIN LATERAL
JoinOperator::CrossApply
} else {
return self.expected("JOIN or APPLY after CROSS", self.peek_token());
};
Join {
relation: self.parse_table_factor()?,
global,
join_operator,
}
} else if self.parse_keyword(Keyword::OUTER) {
// MSSQL extension, similar to LEFT JOIN LATERAL .. ON 1=1
self.expect_keyword(Keyword::APPLY)?;
Join {
relation: self.parse_table_factor()?,
global,
join_operator: JoinOperator::OuterApply,
}
} else if self.parse_keyword(Keyword::ASOF) {
self.expect_keyword(Keyword::JOIN)?;
let relation = self.parse_table_factor()?;
self.expect_keyword(Keyword::MATCH_CONDITION)?;
let match_condition = self.parse_parenthesized(Self::parse_expr)?;
Join {
relation,
global,
join_operator: JoinOperator::AsOf {
match_condition,
constraint: self.parse_join_constraint(false)?,
},
}
} else {
let natural = self.parse_keyword(Keyword::NATURAL);
let peek_keyword = if let Token::Word(w) = self.peek_token().token {
w.keyword
} else {
Keyword::NoKeyword
};
let join_operator_type = match peek_keyword {
Keyword::INNER | Keyword::JOIN => {
let _ = self.parse_keyword(Keyword::INNER); // [ INNER ]
self.expect_keyword(Keyword::JOIN)?;
JoinOperator::Inner
}
kw @ Keyword::LEFT | kw @ Keyword::RIGHT => {
let _ = self.next_token(); // consume LEFT/RIGHT
let is_left = kw == Keyword::LEFT;
let join_type = self.parse_one_of_keywords(&[
Keyword::OUTER,
Keyword::SEMI,
Keyword::ANTI,
Keyword::JOIN,
]);
match join_type {
Some(Keyword::OUTER) => {
self.expect_keyword(Keyword::JOIN)?;
if is_left {
JoinOperator::LeftOuter
} else {
JoinOperator::RightOuter
}
}
Some(Keyword::SEMI) => {
self.expect_keyword(Keyword::JOIN)?;
if is_left {
JoinOperator::LeftSemi
} else {
JoinOperator::RightSemi
}
}
Some(Keyword::ANTI) => {
self.expect_keyword(Keyword::JOIN)?;
if is_left {
JoinOperator::LeftAnti
} else {
JoinOperator::RightAnti
}
}
Some(Keyword::JOIN) => {
if is_left {
JoinOperator::LeftOuter
} else {
JoinOperator::RightOuter
}
}
_ => {
return Err(ParserError::ParserError(format!(
"expected OUTER, SEMI, ANTI or JOIN after {kw:?}"
)))
}
}
}
Keyword::FULL => {
let _ = self.next_token(); // consume FULL
let _ = self.parse_keyword(Keyword::OUTER); // [ OUTER ]
self.expect_keyword(Keyword::JOIN)?;
JoinOperator::FullOuter
}
Keyword::OUTER => {
return self.expected("LEFT, RIGHT, or FULL", self.peek_token());
}
_ if natural => {
return self.expected("a join type after NATURAL", self.peek_token());
}
_ => break,
};
let relation = self.parse_table_factor()?;
let join_constraint = self.parse_join_constraint(natural)?;
Join {
relation,
global,
join_operator: join_operator_type(join_constraint),
}
};
joins.push(join);
}
Ok(TableWithJoins { relation, joins })
}
/// A table name or a parenthesized subquery, followed by optional `[AS] alias`
pub fn parse_table_factor(&mut self) -> Result<TableFactor, ParserError> {
if self.parse_keyword(Keyword::LATERAL) {
// LATERAL must always be followed by a subquery or table function.
if self.consume_token(&Token::LParen) {
self.parse_derived_table_factor(Lateral)
} else {
let name = self.parse_object_name(false)?;
self.expect_token(&Token::LParen)?;
let args = self.parse_optional_args()?;
let alias = self.parse_optional_table_alias(keywords::RESERVED_FOR_TABLE_ALIAS)?;
Ok(TableFactor::Function {
lateral: true,
name,
args,
alias,
})
}
} else if self.parse_keyword(Keyword::TABLE) {
// parse table function (SELECT * FROM TABLE (<expr>) [ AS <alias> ])
self.expect_token(&Token::LParen)?;
let expr = self.parse_expr()?;
self.expect_token(&Token::RParen)?;
let alias = self.parse_optional_table_alias(keywords::RESERVED_FOR_TABLE_ALIAS)?;
Ok(TableFactor::TableFunction { expr, alias })
} else if self.consume_token(&Token::LParen) {
// A left paren introduces either a derived table (i.e., a subquery)
// or a nested join. It's nearly impossible to determine ahead of
// time which it is... so we just try to parse both.
//
// Here's an example that demonstrates the complexity:
// /-------------------------------------------------------\
// | /-----------------------------------\ |
// SELECT * FROM ( ( ( (SELECT 1) UNION (SELECT 2) ) AS t1 NATURAL JOIN t2 ) )
// ^ ^ ^ ^
// | | | |
// | | | |
// | | | (4) belongs to a SetExpr::Query inside the subquery
// | | (3) starts a derived table (subquery)
// | (2) starts a nested join
// (1) an additional set of parens around a nested join
//
// If the recently consumed '(' starts a derived table, the call to
// `parse_derived_table_factor` below will return success after parsing the
// subquery, followed by the closing ')', and the alias of the derived table.
// In the example above this is case (3).
if let Some(mut table) =
self.maybe_parse(|parser| parser.parse_derived_table_factor(NotLateral))
{
while let Some(kw) = self.parse_one_of_keywords(&[Keyword::PIVOT, Keyword::UNPIVOT])
{
table = match kw {
Keyword::PIVOT => self.parse_pivot_table_factor(table)?,
Keyword::UNPIVOT => self.parse_unpivot_table_factor(table)?,
_ => unreachable!(),
}
}
return Ok(table);
}
// A parsing error from `parse_derived_table_factor` indicates that the '(' we've
// recently consumed does not start a derived table (cases 1, 2, or 4).
// `maybe_parse` will ignore such an error and rewind to be after the opening '('.
// Inside the parentheses we expect to find an (A) table factor
// followed by some joins or (B) another level of nesting.
let mut table_and_joins = self.parse_table_and_joins()?;
#[allow(clippy::if_same_then_else)]
if !table_and_joins.joins.is_empty() {
self.expect_token(&Token::RParen)?;
let alias = self.parse_optional_table_alias(keywords::RESERVED_FOR_TABLE_ALIAS)?;
Ok(TableFactor::NestedJoin {
table_with_joins: Box::new(table_and_joins),
alias,
}) // (A)
} else if let TableFactor::NestedJoin {
table_with_joins: _,
alias: _,
} = &table_and_joins.relation
{
// (B): `table_and_joins` (what we found inside the parentheses)
// is a nested join `(foo JOIN bar)`, not followed by other joins.
self.expect_token(&Token::RParen)?;
let alias = self.parse_optional_table_alias(keywords::RESERVED_FOR_TABLE_ALIAS)?;
Ok(TableFactor::NestedJoin {
table_with_joins: Box::new(table_and_joins),
alias,
})
} else if dialect_of!(self is SnowflakeDialect | GenericDialect) {
// Dialect-specific behavior: Snowflake diverges from the
// standard and from most of the other implementations by
// allowing extra parentheses not only around a join (B), but
// around lone table names (e.g. `FROM (mytable [AS alias])`)
// and around derived tables (e.g. `FROM ((SELECT ...)
// [AS alias])`) as well.
self.expect_token(&Token::RParen)?;
if let Some(outer_alias) =
self.parse_optional_table_alias(keywords::RESERVED_FOR_TABLE_ALIAS)?
{
// Snowflake also allows specifying an alias *after* parens
// e.g. `FROM (mytable) AS alias`
match &mut table_and_joins.relation {
TableFactor::Derived { alias, .. }
| TableFactor::Table { alias, .. }
| TableFactor::Function { alias, .. }
| TableFactor::UNNEST { alias, .. }
| TableFactor::JsonTable { alias, .. }
| TableFactor::TableFunction { alias, .. }
| TableFactor::Pivot { alias, .. }
| TableFactor::Unpivot { alias, .. }
| TableFactor::MatchRecognize { alias, .. }
| TableFactor::NestedJoin { alias, .. } => {
// but not `FROM (mytable AS alias1) AS alias2`.
if let Some(inner_alias) = alias {
return Err(ParserError::ParserError(format!(
"duplicate alias {inner_alias}"
)));
}
// Act as if the alias was specified normally next
// to the table name: `(mytable) AS alias` ->
// `(mytable AS alias)`
alias.replace(outer_alias);
}
};
}
// Do not store the extra set of parens in the AST
Ok(table_and_joins.relation)
} else {
// The SQL spec prohibits derived tables and bare tables from
// appearing alone in parentheses (e.g. `FROM (mytable)`)
self.expected("joined table", self.peek_token())
}
} else if dialect_of!(self is SnowflakeDialect | DatabricksDialect | GenericDialect)
&& matches!(
self.peek_tokens(),
[
Token::Word(Word {
keyword: Keyword::VALUES,
..
}),
Token::LParen
]
)
{
self.expect_keyword(Keyword::VALUES)?;
// Snowflake and Databricks allow syntax like below:
// SELECT * FROM VALUES (1, 'a'), (2, 'b') AS t (col1, col2)
// where there are no parentheses around the VALUES clause.
let values = SetExpr::Values(self.parse_values(false)?);
let alias = self.parse_optional_table_alias(keywords::RESERVED_FOR_TABLE_ALIAS)?;
Ok(TableFactor::Derived {
lateral: false,
subquery: Box::new(Query {
with: None,
body: Box::new(values),
order_by: None,
limit: None,
limit_by: vec![],
offset: None,
fetch: None,
locks: vec![],
for_clause: None,
settings: None,
format_clause: None,
}),
alias,
})
} else if dialect_of!(self is BigQueryDialect | PostgreSqlDialect | GenericDialect)
&& self.parse_keyword(Keyword::UNNEST)
{
self.expect_token(&Token::LParen)?;
let array_exprs = self.parse_comma_separated(Parser::parse_expr)?;
self.expect_token(&Token::RParen)?;
let with_ordinality = self.parse_keywords(&[Keyword::WITH, Keyword::ORDINALITY]);
let alias = match self.parse_optional_table_alias(keywords::RESERVED_FOR_TABLE_ALIAS) {
Ok(Some(alias)) => Some(alias),
Ok(None) => None,
Err(e) => return Err(e),
};
let with_offset = match self.expect_keywords(&[Keyword::WITH, Keyword::OFFSET]) {
Ok(()) => true,
Err(_) => false,
};
let with_offset_alias = if with_offset {
match self.parse_optional_alias(keywords::RESERVED_FOR_COLUMN_ALIAS) {
Ok(Some(alias)) => Some(alias),
Ok(None) => None,
Err(e) => return Err(e),
}
} else {
None
};
Ok(TableFactor::UNNEST {
alias,
array_exprs,
with_offset,
with_offset_alias,
with_ordinality,
})
} else if self.parse_keyword_with_tokens(Keyword::JSON_TABLE, &[Token::LParen]) {
let json_expr = self.parse_expr()?;
self.expect_token(&Token::Comma)?;
let json_path = self.parse_value()?;
self.expect_keyword(Keyword::COLUMNS)?;
self.expect_token(&Token::LParen)?;
let columns = self.parse_comma_separated(Parser::parse_json_table_column_def)?;
self.expect_token(&Token::RParen)?;
self.expect_token(&Token::RParen)?;
let alias = self.parse_optional_table_alias(keywords::RESERVED_FOR_TABLE_ALIAS)?;
Ok(TableFactor::JsonTable {
json_expr,
json_path,
columns,
alias,
})
} else {
let name = self.parse_object_name(true)?;
let partitions: Vec<Ident> = if dialect_of!(self is MySqlDialect | GenericDialect)
&& self.parse_keyword(Keyword::PARTITION)
{
self.parse_parenthesized_identifiers()?
} else {
vec![]
};
// Parse potential version qualifier
let version = self.parse_table_version()?;
// Postgres, MSSQL, ClickHouse: table-valued functions:
let args = if self.consume_token(&Token::LParen) {
Some(self.parse_table_function_args()?)
} else {
None
};
let with_ordinality = self.parse_keywords(&[Keyword::WITH, Keyword::ORDINALITY]);
let alias = self.parse_optional_table_alias(keywords::RESERVED_FOR_TABLE_ALIAS)?;
// MSSQL-specific table hints:
let mut with_hints = vec![];
if self.parse_keyword(Keyword::WITH) {
if self.consume_token(&Token::LParen) {
with_hints = self.parse_comma_separated(Parser::parse_expr)?;
self.expect_token(&Token::RParen)?;
} else {
// rewind, as WITH may belong to the next statement's CTE
self.prev_token();
}
};
let mut table = TableFactor::Table {
name,
alias,
args,
with_hints,
version,
partitions,
with_ordinality,
};
while let Some(kw) = self.parse_one_of_keywords(&[Keyword::PIVOT, Keyword::UNPIVOT]) {
table = match kw {
Keyword::PIVOT => self.parse_pivot_table_factor(table)?,
Keyword::UNPIVOT => self.parse_unpivot_table_factor(table)?,
_ => unreachable!(),
}
}
if self.dialect.supports_match_recognize()
&& self.parse_keyword(Keyword::MATCH_RECOGNIZE)
{
table = self.parse_match_recognize(table)?;
}
Ok(table)
}
}
fn parse_match_recognize(&mut self, table: TableFactor) -> Result<TableFactor, ParserError> {
self.expect_token(&Token::LParen)?;
let partition_by = if self.parse_keywords(&[Keyword::PARTITION, Keyword::BY]) {
self.parse_comma_separated(Parser::parse_expr)?
} else {
vec![]
};
let order_by = if self.parse_keywords(&[Keyword::ORDER, Keyword::BY]) {
self.parse_comma_separated(Parser::parse_order_by_expr)?
} else {
vec![]
};
let measures = if self.parse_keyword(Keyword::MEASURES) {
self.parse_comma_separated(|p| {
let expr = p.parse_expr()?;
let _ = p.parse_keyword(Keyword::AS);
let alias = p.parse_identifier(false)?;
Ok(Measure { expr, alias })
})?
} else {
vec![]
};
let rows_per_match =
if self.parse_keywords(&[Keyword::ONE, Keyword::ROW, Keyword::PER, Keyword::MATCH]) {
Some(RowsPerMatch::OneRow)
} else if self.parse_keywords(&[
Keyword::ALL,
Keyword::ROWS,
Keyword::PER,
Keyword::MATCH,
]) {
Some(RowsPerMatch::AllRows(
if self.parse_keywords(&[Keyword::SHOW, Keyword::EMPTY, Keyword::MATCHES]) {
Some(EmptyMatchesMode::Show)
} else if self.parse_keywords(&[
Keyword::OMIT,
Keyword::EMPTY,
Keyword::MATCHES,
]) {
Some(EmptyMatchesMode::Omit)
} else if self.parse_keywords(&[
Keyword::WITH,
Keyword::UNMATCHED,
Keyword::ROWS,
]) {
Some(EmptyMatchesMode::WithUnmatched)
} else {
None
},
))
} else {
None
};
let after_match_skip =
if self.parse_keywords(&[Keyword::AFTER, Keyword::MATCH, Keyword::SKIP]) {
if self.parse_keywords(&[Keyword::PAST, Keyword::LAST, Keyword::ROW]) {
Some(AfterMatchSkip::PastLastRow)
} else if self.parse_keywords(&[Keyword::TO, Keyword::NEXT, Keyword::ROW]) {
Some(AfterMatchSkip::ToNextRow)
} else if self.parse_keywords(&[Keyword::TO, Keyword::FIRST]) {
Some(AfterMatchSkip::ToFirst(self.parse_identifier(false)?))
} else if self.parse_keywords(&[Keyword::TO, Keyword::LAST]) {
Some(AfterMatchSkip::ToLast(self.parse_identifier(false)?))
} else {
let found = self.next_token();
return self.expected("after match skip option", found);
}
} else {
None
};
self.expect_keyword(Keyword::PATTERN)?;
let pattern = self.parse_parenthesized(Self::parse_pattern)?;
self.expect_keyword(Keyword::DEFINE)?;
let symbols = self.parse_comma_separated(|p| {
let symbol = p.parse_identifier(false)?;
p.expect_keyword(Keyword::AS)?;
let definition = p.parse_expr()?;
Ok(SymbolDefinition { symbol, definition })
})?;
self.expect_token(&Token::RParen)?;
let alias = self.parse_optional_table_alias(keywords::RESERVED_FOR_TABLE_ALIAS)?;
Ok(TableFactor::MatchRecognize {
table: Box::new(table),
partition_by,
order_by,
measures,
rows_per_match,
after_match_skip,
pattern,
symbols,
alias,
})
}
fn parse_base_pattern(&mut self) -> Result<MatchRecognizePattern, ParserError> {
match self.next_token().token {
Token::Caret => Ok(MatchRecognizePattern::Symbol(MatchRecognizeSymbol::Start)),
Token::Placeholder(s) if s == "$" => {
Ok(MatchRecognizePattern::Symbol(MatchRecognizeSymbol::End))
}
Token::LBrace => {
self.expect_token(&Token::Minus)?;
let symbol = self
.parse_identifier(false)
.map(MatchRecognizeSymbol::Named)?;
self.expect_token(&Token::Minus)?;
self.expect_token(&Token::RBrace)?;
Ok(MatchRecognizePattern::Exclude(symbol))
}
Token::Word(Word {
value,
quote_style: None,
..
}) if value == "PERMUTE" => {
self.expect_token(&Token::LParen)?;
let symbols = self.parse_comma_separated(|p| {
p.parse_identifier(false).map(MatchRecognizeSymbol::Named)
})?;
self.expect_token(&Token::RParen)?;
Ok(MatchRecognizePattern::Permute(symbols))
}
Token::LParen => {
let pattern = self.parse_pattern()?;
self.expect_token(&Token::RParen)?;
Ok(MatchRecognizePattern::Group(Box::new(pattern)))
}
_ => {
self.prev_token();
self.parse_identifier(false)
.map(MatchRecognizeSymbol::Named)
.map(MatchRecognizePattern::Symbol)
}
}
}
fn parse_repetition_pattern(&mut self) -> Result<MatchRecognizePattern, ParserError> {
let mut pattern = self.parse_base_pattern()?;
loop {
let token = self.next_token();
let quantifier = match token.token {
Token::Mul => RepetitionQuantifier::ZeroOrMore,
Token::Plus => RepetitionQuantifier::OneOrMore,
Token::Placeholder(s) if s == "?" => RepetitionQuantifier::AtMostOne,
Token::LBrace => {
// quantifier is a range like {n} or {n,} or {,m} or {n,m}
let token = self.next_token();
match token.token {
Token::Comma => {
let next_token = self.next_token();
let Token::Number(n, _) = next_token.token else {
return self.expected("literal number", next_token);
};
self.expect_token(&Token::RBrace)?;
RepetitionQuantifier::AtMost(Self::parse(n, token.location)?)
}
Token::Number(n, _) if self.consume_token(&Token::Comma) => {
let next_token = self.next_token();
match next_token.token {
Token::Number(m, _) => {
self.expect_token(&Token::RBrace)?;
RepetitionQuantifier::Range(
Self::parse(n, token.location)?,
Self::parse(m, token.location)?,
)
}
Token::RBrace => {
RepetitionQuantifier::AtLeast(Self::parse(n, token.location)?)
}
_ => {
return self.expected("} or upper bound", next_token);
}
}
}
Token::Number(n, _) => {
self.expect_token(&Token::RBrace)?;
RepetitionQuantifier::Exactly(Self::parse(n, token.location)?)
}
_ => return self.expected("quantifier range", token),
}
}
_ => {
self.prev_token();
break;
}
};
pattern = MatchRecognizePattern::Repetition(Box::new(pattern), quantifier);
}
Ok(pattern)
}
fn parse_concat_pattern(&mut self) -> Result<MatchRecognizePattern, ParserError> {
let mut patterns = vec![self.parse_repetition_pattern()?];
while !matches!(self.peek_token().token, Token::RParen | Token::Pipe) {
patterns.push(self.parse_repetition_pattern()?);
}
match <[MatchRecognizePattern; 1]>::try_from(patterns) {
Ok([pattern]) => Ok(pattern),
Err(patterns) => Ok(MatchRecognizePattern::Concat(patterns)),
}
}
fn parse_pattern(&mut self) -> Result<MatchRecognizePattern, ParserError> {
let pattern = self.parse_concat_pattern()?;
if self.consume_token(&Token::Pipe) {
match self.parse_pattern()? {
// flatten nested alternations
MatchRecognizePattern::Alternation(mut patterns) => {
patterns.insert(0, pattern);
Ok(MatchRecognizePattern::Alternation(patterns))
}
next => Ok(MatchRecognizePattern::Alternation(vec![pattern, next])),
}
} else {
Ok(pattern)
}
}
/// Parse a given table version specifier.
///
/// For now it only supports timestamp versioning for BigQuery and MSSQL dialects.
pub fn parse_table_version(&mut self) -> Result<Option<TableVersion>, ParserError> {
if dialect_of!(self is BigQueryDialect | MsSqlDialect)
&& self.parse_keywords(&[Keyword::FOR, Keyword::SYSTEM_TIME, Keyword::AS, Keyword::OF])
{
let expr = self.parse_expr()?;
Ok(Some(TableVersion::ForSystemTimeAsOf(expr)))
} else {
Ok(None)
}
}
/// Parses MySQL's JSON_TABLE column definition.
/// For example: `id INT EXISTS PATH '$' DEFAULT '0' ON EMPTY ERROR ON ERROR`
pub fn parse_json_table_column_def(&mut self) -> Result<JsonTableColumn, ParserError> {
let name = self.parse_identifier(false)?;
let r#type = self.parse_data_type()?;
let exists = self.parse_keyword(Keyword::EXISTS);
self.expect_keyword(Keyword::PATH)?;
let path = self.parse_value()?;
let mut on_empty = None;
let mut on_error = None;
while let Some(error_handling) = self.parse_json_table_column_error_handling()? {
if self.parse_keyword(Keyword::EMPTY) {
on_empty = Some(error_handling);
} else {
self.expect_keyword(Keyword::ERROR)?;
on_error = Some(error_handling);
}
}
Ok(JsonTableColumn {
name,
r#type,
path,
exists,
on_empty,
on_error,
})
}
fn parse_json_table_column_error_handling(
&mut self,
) -> Result<Option<JsonTableColumnErrorHandling>, ParserError> {
let res = if self.parse_keyword(Keyword::NULL) {
JsonTableColumnErrorHandling::Null
} else if self.parse_keyword(Keyword::ERROR) {
JsonTableColumnErrorHandling::Error
} else if self.parse_keyword(Keyword::DEFAULT) {
JsonTableColumnErrorHandling::Default(self.parse_value()?)
} else {
return Ok(None);
};
self.expect_keyword(Keyword::ON)?;
Ok(Some(res))
}
pub fn parse_derived_table_factor(
&mut self,
lateral: IsLateral,
) -> Result<TableFactor, ParserError> {
let subquery = self.parse_boxed_query()?;
self.expect_token(&Token::RParen)?;
let alias = self.parse_optional_table_alias(keywords::RESERVED_FOR_TABLE_ALIAS)?;
Ok(TableFactor::Derived {
lateral: match lateral {
Lateral => true,
NotLateral => false,
},
subquery,
alias,
})
}
fn parse_aliased_function_call(&mut self) -> Result<ExprWithAlias, ParserError> {
let function_name = match self.next_token().token {
Token::Word(w) => Ok(w.value),
_ => self.expected("a function identifier", self.peek_token()),
}?;
let expr = self.parse_function(ObjectName(vec![Ident::new(function_name)]))?;
let alias = if self.parse_keyword(Keyword::AS) {
Some(self.parse_identifier(false)?)
} else {
None
};
Ok(ExprWithAlias { expr, alias })
}
fn parse_expr_with_alias(&mut self) -> Result<ExprWithAlias, ParserError> {
let expr = self.parse_expr()?;
let alias = if self.parse_keyword(Keyword::AS) {
Some(self.parse_identifier(false)?)
} else {
None
};
Ok(ExprWithAlias { expr, alias })
}
pub fn parse_pivot_table_factor(
&mut self,
table: TableFactor,
) -> Result<TableFactor, ParserError> {
self.expect_token(&Token::LParen)?;
let aggregate_functions = self.parse_comma_separated(Self::parse_aliased_function_call)?;
self.expect_keyword(Keyword::FOR)?;
let value_column = self.parse_object_name(false)?.0;
self.expect_keyword(Keyword::IN)?;
self.expect_token(&Token::LParen)?;
let value_source = if self.parse_keyword(Keyword::ANY) {
let order_by = if self.parse_keywords(&[Keyword::ORDER, Keyword::BY]) {
self.parse_comma_separated(Parser::parse_order_by_expr)?
} else {
vec![]
};
PivotValueSource::Any(order_by)
} else if self
.parse_one_of_keywords(&[Keyword::SELECT, Keyword::WITH])
.is_some()
{
self.prev_token();
PivotValueSource::Subquery(self.parse_query()?)
} else {
PivotValueSource::List(self.parse_comma_separated(Self::parse_expr_with_alias)?)
};
self.expect_token(&Token::RParen)?;
let default_on_null =
if self.parse_keywords(&[Keyword::DEFAULT, Keyword::ON, Keyword::NULL]) {
self.expect_token(&Token::LParen)?;
let expr = self.parse_expr()?;
self.expect_token(&Token::RParen)?;
Some(expr)
} else {
None
};
self.expect_token(&Token::RParen)?;
let alias = self.parse_optional_table_alias(keywords::RESERVED_FOR_TABLE_ALIAS)?;
Ok(TableFactor::Pivot {
table: Box::new(table),
aggregate_functions,
value_column,
value_source,
default_on_null,
alias,
})
}
pub fn parse_unpivot_table_factor(
&mut self,
table: TableFactor,
) -> Result<TableFactor, ParserError> {
self.expect_token(&Token::LParen)?;
let value = self.parse_identifier(false)?;
self.expect_keyword(Keyword::FOR)?;
let name = self.parse_identifier(false)?;
self.expect_keyword(Keyword::IN)?;
let columns = self.parse_parenthesized_column_list(Mandatory, false)?;
self.expect_token(&Token::RParen)?;
let alias = self.parse_optional_table_alias(keywords::RESERVED_FOR_TABLE_ALIAS)?;
Ok(TableFactor::Unpivot {
table: Box::new(table),
value,
name,
columns,
alias,
})
}
pub fn parse_join_constraint(&mut self, natural: bool) -> Result<JoinConstraint, ParserError> {
if natural {
Ok(JoinConstraint::Natural)
} else if self.parse_keyword(Keyword::ON) {
let constraint = self.parse_expr()?;
Ok(JoinConstraint::On(constraint))
} else if self.parse_keyword(Keyword::USING) {
let columns = self.parse_parenthesized_column_list(Mandatory, false)?;
Ok(JoinConstraint::Using(columns))
} else {
Ok(JoinConstraint::None)
//self.expected("ON, or USING after JOIN", self.peek_token())
}
}
/// Parse a GRANT statement.
pub fn parse_grant(&mut self) -> Result<Statement, ParserError> {
let (privileges, objects) = self.parse_grant_revoke_privileges_objects()?;
self.expect_keyword(Keyword::TO)?;
let grantees = self.parse_comma_separated(|p| p.parse_identifier(false))?;
let with_grant_option =
self.parse_keywords(&[Keyword::WITH, Keyword::GRANT, Keyword::OPTION]);
let granted_by = self
.parse_keywords(&[Keyword::GRANTED, Keyword::BY])
.then(|| self.parse_identifier(false).unwrap());
Ok(Statement::Grant {
privileges,
objects,
grantees,
with_grant_option,
granted_by,
})
}
pub fn parse_grant_revoke_privileges_objects(
&mut self,
) -> Result<(Privileges, GrantObjects), ParserError> {
let privileges = if self.parse_keyword(Keyword::ALL) {
Privileges::All {
with_privileges_keyword: self.parse_keyword(Keyword::PRIVILEGES),
}
} else {
let (actions, err): (Vec<_>, Vec<_>) = self
.parse_actions_list()?
.into_iter()
.map(|(kw, columns)| match kw {
Keyword::DELETE => Ok(Action::Delete),
Keyword::INSERT => Ok(Action::Insert { columns }),
Keyword::REFERENCES => Ok(Action::References { columns }),
Keyword::SELECT => Ok(Action::Select { columns }),
Keyword::TRIGGER => Ok(Action::Trigger),
Keyword::TRUNCATE => Ok(Action::Truncate),
Keyword::UPDATE => Ok(Action::Update { columns }),
Keyword::USAGE => Ok(Action::Usage),
Keyword::CONNECT => Ok(Action::Connect),
Keyword::CREATE => Ok(Action::Create),
Keyword::EXECUTE => Ok(Action::Execute),
Keyword::TEMPORARY => Ok(Action::Temporary),
// This will cover all future added keywords to
// parse_grant_permission and unhandled in this
// match
_ => Err(kw),
})
.partition(Result::is_ok);
if !err.is_empty() {
let errors: Vec<Keyword> = err.into_iter().filter_map(|x| x.err()).collect();
return Err(ParserError::ParserError(format!(
"INTERNAL ERROR: GRANT/REVOKE unexpected keyword(s) - {errors:?}"
)));
}
let act = actions.into_iter().filter_map(|x| x.ok()).collect();
Privileges::Actions(act)
};
self.expect_keyword(Keyword::ON)?;
let objects = if self.parse_keywords(&[
Keyword::ALL,
Keyword::TABLES,
Keyword::IN,
Keyword::SCHEMA,
]) {
GrantObjects::AllTablesInSchema {
schemas: self.parse_comma_separated(|p| p.parse_object_name(false))?,
}
} else if self.parse_keywords(&[
Keyword::ALL,
Keyword::SEQUENCES,
Keyword::IN,
Keyword::SCHEMA,
]) {
GrantObjects::AllSequencesInSchema {
schemas: self.parse_comma_separated(|p| p.parse_object_name(false))?,
}
} else {
let object_type =
self.parse_one_of_keywords(&[Keyword::SEQUENCE, Keyword::SCHEMA, Keyword::TABLE]);
let objects = self.parse_comma_separated(|p| p.parse_object_name(false));
match object_type {
Some(Keyword::SCHEMA) => GrantObjects::Schemas(objects?),
Some(Keyword::SEQUENCE) => GrantObjects::Sequences(objects?),
Some(Keyword::TABLE) | None => GrantObjects::Tables(objects?),
_ => unreachable!(),
}
};
Ok((privileges, objects))
}
pub fn parse_grant_permission(&mut self) -> Result<ParsedAction, ParserError> {
if let Some(kw) = self.parse_one_of_keywords(&[
Keyword::CONNECT,
Keyword::CREATE,
Keyword::DELETE,
Keyword::EXECUTE,
Keyword::INSERT,
Keyword::REFERENCES,
Keyword::SELECT,
Keyword::TEMPORARY,
Keyword::TRIGGER,
Keyword::TRUNCATE,
Keyword::UPDATE,
Keyword::USAGE,
]) {
let columns = match kw {
Keyword::INSERT | Keyword::REFERENCES | Keyword::SELECT | Keyword::UPDATE => {
let columns = self.parse_parenthesized_column_list(Optional, false)?;
if columns.is_empty() {
None
} else {
Some(columns)
}
}
_ => None,
};
Ok((kw, columns))
} else {
self.expected("a privilege keyword", self.peek_token())?
}
}
/// Parse a REVOKE statement
pub fn parse_revoke(&mut self) -> Result<Statement, ParserError> {
let (privileges, objects) = self.parse_grant_revoke_privileges_objects()?;
self.expect_keyword(Keyword::FROM)?;
let grantees = self.parse_comma_separated(|p| p.parse_identifier(false))?;
let granted_by = self
.parse_keywords(&[Keyword::GRANTED, Keyword::BY])
.then(|| self.parse_identifier(false).unwrap());
let loc = self.peek_token().location;
let cascade = self.parse_keyword(Keyword::CASCADE);
let restrict = self.parse_keyword(Keyword::RESTRICT);
if cascade && restrict {
return parser_err!("Cannot specify both CASCADE and RESTRICT in REVOKE", loc);
}
Ok(Statement::Revoke {
privileges,
objects,
grantees,
granted_by,
cascade,
})
}
/// Parse an REPLACE statement
pub fn parse_replace(&mut self) -> Result<Statement, ParserError> {
if !dialect_of!(self is MySqlDialect | GenericDialect) {
return parser_err!("Unsupported statement REPLACE", self.peek_token().location);
}
let insert = &mut self.parse_insert()?;
if let Statement::Insert(Insert { replace_into, .. }) = insert {
*replace_into = true;
}
Ok(insert.clone())
}
/// Parse an INSERT statement, returning a `Box`ed SetExpr
///
/// This is used to reduce the size of the stack frames in debug builds
fn parse_insert_setexpr_boxed(&mut self) -> Result<Box<SetExpr>, ParserError> {
Ok(Box::new(SetExpr::Insert(self.parse_insert()?)))
}
/// Parse an INSERT statement
pub fn parse_insert(&mut self) -> Result<Statement, ParserError> {
let or = if !dialect_of!(self is SQLiteDialect) {
None
} else if self.parse_keywords(&[Keyword::OR, Keyword::REPLACE]) {
Some(SqliteOnConflict::Replace)
} else if self.parse_keywords(&[Keyword::OR, Keyword::ROLLBACK]) {
Some(SqliteOnConflict::Rollback)
} else if self.parse_keywords(&[Keyword::OR, Keyword::ABORT]) {
Some(SqliteOnConflict::Abort)
} else if self.parse_keywords(&[Keyword::OR, Keyword::FAIL]) {
Some(SqliteOnConflict::Fail)
} else if self.parse_keywords(&[Keyword::OR, Keyword::IGNORE]) {
Some(SqliteOnConflict::Ignore)
} else if self.parse_keyword(Keyword::REPLACE) {
Some(SqliteOnConflict::Replace)
} else {
None
};
let priority = if !dialect_of!(self is MySqlDialect | GenericDialect) {
None
} else if self.parse_keyword(Keyword::LOW_PRIORITY) {
Some(MysqlInsertPriority::LowPriority)
} else if self.parse_keyword(Keyword::DELAYED) {
Some(MysqlInsertPriority::Delayed)
} else if self.parse_keyword(Keyword::HIGH_PRIORITY) {
Some(MysqlInsertPriority::HighPriority)
} else {
None
};
let ignore = dialect_of!(self is MySqlDialect | GenericDialect)
&& self.parse_keyword(Keyword::IGNORE);
let replace_into = false;
let action = self.parse_one_of_keywords(&[Keyword::INTO, Keyword::OVERWRITE]);
let into = action == Some(Keyword::INTO);
let overwrite = action == Some(Keyword::OVERWRITE);
let local = self.parse_keyword(Keyword::LOCAL);
if self.parse_keyword(Keyword::DIRECTORY) {
let path = self.parse_literal_string()?;
let file_format = if self.parse_keywords(&[Keyword::STORED, Keyword::AS]) {
Some(self.parse_file_format()?)
} else {
None
};
let source = self.parse_boxed_query()?;
Ok(Statement::Directory {
local,
path,
overwrite,
file_format,
source,
})
} else {
// Hive lets you put table here regardless
let table = self.parse_keyword(Keyword::TABLE);
let table_name = self.parse_object_name(false)?;
let table_alias =
if dialect_of!(self is PostgreSqlDialect) && self.parse_keyword(Keyword::AS) {
Some(self.parse_identifier(false)?)
} else {
None
};
let is_mysql = dialect_of!(self is MySqlDialect);
let (columns, partitioned, after_columns, source) =
if self.parse_keywords(&[Keyword::DEFAULT, Keyword::VALUES]) {
(vec![], None, vec![], None)
} else {
let columns = self.parse_parenthesized_column_list(Optional, is_mysql)?;
let partitioned = self.parse_insert_partition()?;
// Hive allows you to specify columns after partitions as well if you want.
let after_columns = if dialect_of!(self is HiveDialect) {
self.parse_parenthesized_column_list(Optional, false)?
} else {
vec![]
};
let source = Some(self.parse_boxed_query()?);
(columns, partitioned, after_columns, source)
};
let insert_alias = if dialect_of!(self is MySqlDialect | GenericDialect)
&& self.parse_keyword(Keyword::AS)
{
let row_alias = self.parse_object_name(false)?;
let col_aliases = Some(self.parse_parenthesized_column_list(Optional, false)?);
Some(InsertAliases {
row_alias,
col_aliases,
})
} else {
None
};
let on = if self.parse_keyword(Keyword::ON) {
if self.parse_keyword(Keyword::CONFLICT) {
let conflict_target =
if self.parse_keywords(&[Keyword::ON, Keyword::CONSTRAINT]) {
Some(ConflictTarget::OnConstraint(self.parse_object_name(false)?))
} else if self.peek_token() == Token::LParen {
Some(ConflictTarget::Columns(
self.parse_parenthesized_column_list(IsOptional::Mandatory, false)?,
))
} else {
None
};
self.expect_keyword(Keyword::DO)?;
let action = if self.parse_keyword(Keyword::NOTHING) {
OnConflictAction::DoNothing
} else {
self.expect_keyword(Keyword::UPDATE)?;
self.expect_keyword(Keyword::SET)?;
let assignments = self.parse_comma_separated(Parser::parse_assignment)?;
let selection = if self.parse_keyword(Keyword::WHERE) {
Some(self.parse_expr()?)
} else {
None
};
OnConflictAction::DoUpdate(DoUpdate {
assignments,
selection,
})
};
Some(OnInsert::OnConflict(OnConflict {
conflict_target,
action,
}))
} else {
self.expect_keyword(Keyword::DUPLICATE)?;
self.expect_keyword(Keyword::KEY)?;
self.expect_keyword(Keyword::UPDATE)?;
let l = self.parse_comma_separated(Parser::parse_assignment)?;
Some(OnInsert::DuplicateKeyUpdate(l))
}
} else {
None
};
let returning = if self.parse_keyword(Keyword::RETURNING) {
Some(self.parse_comma_separated(Parser::parse_select_item)?)
} else {
None
};
Ok(Statement::Insert(Insert {
or,
table_name,
table_alias,
ignore,
into,
overwrite,
partitioned,
columns,
after_columns,
source,
table,
on,
returning,
replace_into,
priority,
insert_alias,
}))
}
}
pub fn parse_insert_partition(&mut self) -> Result<Option<Vec<Expr>>, ParserError> {
if self.parse_keyword(Keyword::PARTITION) {
self.expect_token(&Token::LParen)?;
let partition_cols = Some(self.parse_comma_separated(Parser::parse_expr)?);
self.expect_token(&Token::RParen)?;
Ok(partition_cols)
} else {
Ok(None)
}
}
/// Parse an UPDATE statement, returning a `Box`ed SetExpr
///
/// This is used to reduce the size of the stack frames in debug builds
fn parse_update_setexpr_boxed(&mut self) -> Result<Box<SetExpr>, ParserError> {
Ok(Box::new(SetExpr::Update(self.parse_update()?)))
}
pub fn parse_update(&mut self) -> Result<Statement, ParserError> {
let table = self.parse_table_and_joins()?;
self.expect_keyword(Keyword::SET)?;
let assignments = self.parse_comma_separated(Parser::parse_assignment)?;
let from = if self.parse_keyword(Keyword::FROM)
&& dialect_of!(self is GenericDialect | PostgreSqlDialect | DuckDbDialect | BigQueryDialect | SnowflakeDialect | RedshiftSqlDialect | MsSqlDialect | SQLiteDialect )
{
Some(self.parse_table_and_joins()?)
} else {
None
};
let selection = if self.parse_keyword(Keyword::WHERE) {
Some(self.parse_expr()?)
} else {
None
};
let returning = if self.parse_keyword(Keyword::RETURNING) {
Some(self.parse_comma_separated(Parser::parse_select_item)?)
} else {
None
};
Ok(Statement::Update {
table,
assignments,
from,
selection,
returning,
})
}
/// Parse a `var = expr` assignment, used in an UPDATE statement
pub fn parse_assignment(&mut self) -> Result<Assignment, ParserError> {
let target = self.parse_assignment_target()?;
self.expect_token(&Token::Eq)?;
let value = self.parse_expr()?;
Ok(Assignment { target, value })
}
/// Parse the left-hand side of an assignment, used in an UPDATE statement
pub fn parse_assignment_target(&mut self) -> Result<AssignmentTarget, ParserError> {
if self.consume_token(&Token::LParen) {
let columns = self.parse_comma_separated(|p| p.parse_object_name(false))?;
self.expect_token(&Token::RParen)?;
Ok(AssignmentTarget::Tuple(columns))
} else {
let column = self.parse_object_name(false)?;
Ok(AssignmentTarget::ColumnName(column))
}
}
pub fn parse_function_args(&mut self) -> Result<FunctionArg, ParserError> {
if self.peek_nth_token(1) == Token::RArrow {
let name = self.parse_identifier(false)?;
self.expect_token(&Token::RArrow)?;
let arg = self.parse_wildcard_expr()?.into();
Ok(FunctionArg::Named {
name,
arg,
operator: FunctionArgOperator::RightArrow,
})
} else if self.dialect.supports_named_fn_args_with_eq_operator()
&& self.peek_nth_token(1) == Token::Eq
{
let name = self.parse_identifier(false)?;
self.expect_token(&Token::Eq)?;
let arg = self.parse_wildcard_expr()?.into();
Ok(FunctionArg::Named {
name,
arg,
operator: FunctionArgOperator::Equals,
})
} else if dialect_of!(self is DuckDbDialect | GenericDialect)
&& self.peek_nth_token(1) == Token::Assignment
{
let name = self.parse_identifier(false)?;
self.expect_token(&Token::Assignment)?;
let arg = self.parse_expr()?.into();
Ok(FunctionArg::Named {
name,
arg,
operator: FunctionArgOperator::Assignment,
})
} else {
Ok(FunctionArg::Unnamed(self.parse_wildcard_expr()?.into()))
}
}
pub fn parse_optional_args(&mut self) -> Result<Vec<FunctionArg>, ParserError> {
if self.consume_token(&Token::RParen) {
Ok(vec![])
} else {
let args = self.parse_comma_separated(Parser::parse_function_args)?;
self.expect_token(&Token::RParen)?;
Ok(args)
}
}
fn parse_table_function_args(&mut self) -> Result<TableFunctionArgs, ParserError> {
if self.consume_token(&Token::RParen) {
return Ok(TableFunctionArgs {
args: vec![],
settings: None,
});
}
let mut args = vec![];
let settings = loop {
if let Some(settings) = self.parse_settings()? {
break Some(settings);
}
args.push(self.parse_function_args()?);
if self.is_parse_comma_separated_end() {
break None;
}
};
self.expect_token(&Token::RParen)?;
Ok(TableFunctionArgs { args, settings })
}
/// Parses a potentially empty list of arguments to a window function
/// (including the closing parenthesis).
///
/// Examples:
/// ```sql
/// FIRST_VALUE(x ORDER BY 1,2,3);
/// FIRST_VALUE(x IGNORE NULL);
/// ```
fn parse_function_argument_list(&mut self) -> Result<FunctionArgumentList, ParserError> {
if self.consume_token(&Token::RParen) {
return Ok(FunctionArgumentList {
duplicate_treatment: None,
args: vec![],
clauses: vec![],
});
}
let duplicate_treatment = self.parse_duplicate_treatment()?;
let args = self.parse_comma_separated(Parser::parse_function_args)?;
let mut clauses = vec![];
if self.dialect.supports_window_function_null_treatment_arg() {
if let Some(null_treatment) = self.parse_null_treatment()? {
clauses.push(FunctionArgumentClause::IgnoreOrRespectNulls(null_treatment));
}
}
if self.parse_keywords(&[Keyword::ORDER, Keyword::BY]) {
clauses.push(FunctionArgumentClause::OrderBy(
self.parse_comma_separated(Parser::parse_order_by_expr)?,
));
}
if self.parse_keyword(Keyword::LIMIT) {
clauses.push(FunctionArgumentClause::Limit(self.parse_expr()?));
}
if dialect_of!(self is GenericDialect | BigQueryDialect)
&& self.parse_keyword(Keyword::HAVING)
{
let kind = match self.expect_one_of_keywords(&[Keyword::MIN, Keyword::MAX])? {
Keyword::MIN => HavingBoundKind::Min,
Keyword::MAX => HavingBoundKind::Max,
_ => unreachable!(),
};
clauses.push(FunctionArgumentClause::Having(HavingBound(
kind,
self.parse_expr()?,
)))
}
if dialect_of!(self is GenericDialect | MySqlDialect)
&& self.parse_keyword(Keyword::SEPARATOR)
{
clauses.push(FunctionArgumentClause::Separator(self.parse_value()?));
}
if let Some(on_overflow) = self.parse_listagg_on_overflow()? {
clauses.push(FunctionArgumentClause::OnOverflow(on_overflow));
}
self.expect_token(&Token::RParen)?;
Ok(FunctionArgumentList {
duplicate_treatment,
args,
clauses,
})
}
fn parse_duplicate_treatment(&mut self) -> Result<Option<DuplicateTreatment>, ParserError> {
let loc = self.peek_token().location;
match (
self.parse_keyword(Keyword::ALL),
self.parse_keyword(Keyword::DISTINCT),
) {
(true, false) => Ok(Some(DuplicateTreatment::All)),
(false, true) => Ok(Some(DuplicateTreatment::Distinct)),
(false, false) => Ok(None),
(true, true) => parser_err!("Cannot specify both ALL and DISTINCT".to_string(), loc),
}
}
/// Parse a comma-delimited list of projections after SELECT
pub fn parse_select_item(&mut self) -> Result<SelectItem, ParserError> {
match self.parse_wildcard_expr()? {
Expr::QualifiedWildcard(prefix) => Ok(SelectItem::QualifiedWildcard(
prefix,
self.parse_wildcard_additional_options()?,
)),
Expr::Wildcard => Ok(SelectItem::Wildcard(
self.parse_wildcard_additional_options()?,
)),
Expr::Identifier(v) if v.value.to_lowercase() == "from" && v.quote_style.is_none() => {
parser_err!(
format!("Expected an expression, found: {}", v),
self.peek_token().location
)
}
expr => self
.parse_optional_alias(keywords::RESERVED_FOR_COLUMN_ALIAS)
.map(|alias| match alias {
Some(alias) => SelectItem::ExprWithAlias { expr, alias },
None => SelectItem::UnnamedExpr(expr),
}),
}
}
/// Parse an [`WildcardAdditionalOptions`] information for wildcard select items.
///
/// If it is not possible to parse it, will return an option.
pub fn parse_wildcard_additional_options(
&mut self,
) -> Result<WildcardAdditionalOptions, ParserError> {
let opt_ilike = if dialect_of!(self is GenericDialect | SnowflakeDialect) {
self.parse_optional_select_item_ilike()?
} else {
None
};
let opt_exclude = if opt_ilike.is_none()
&& dialect_of!(self is GenericDialect | DuckDbDialect | SnowflakeDialect)
{
self.parse_optional_select_item_exclude()?
} else {
None
};
let opt_except = if self.dialect.supports_select_wildcard_except() {
self.parse_optional_select_item_except()?
} else {
None
};
let opt_replace = if dialect_of!(self is GenericDialect | BigQueryDialect | ClickHouseDialect | DuckDbDialect | SnowflakeDialect)
{
self.parse_optional_select_item_replace()?
} else {
None
};
let opt_rename = if dialect_of!(self is GenericDialect | SnowflakeDialect) {
self.parse_optional_select_item_rename()?
} else {
None
};
Ok(WildcardAdditionalOptions {
opt_ilike,
opt_exclude,
opt_except,
opt_rename,
opt_replace,
})
}
/// Parse an [`Ilike`](IlikeSelectItem) information for wildcard select items.
///
/// If it is not possible to parse it, will return an option.
pub fn parse_optional_select_item_ilike(
&mut self,
) -> Result<Option<IlikeSelectItem>, ParserError> {
let opt_ilike = if self.parse_keyword(Keyword::ILIKE) {
let next_token = self.next_token();
let pattern = match next_token.token {
Token::SingleQuotedString(s) => s,
_ => return self.expected("ilike pattern", next_token),
};
Some(IlikeSelectItem { pattern })
} else {
None
};
Ok(opt_ilike)
}
/// Parse an [`Exclude`](ExcludeSelectItem) information for wildcard select items.
///
/// If it is not possible to parse it, will return an option.
pub fn parse_optional_select_item_exclude(
&mut self,
) -> Result<Option<ExcludeSelectItem>, ParserError> {
let opt_exclude = if self.parse_keyword(Keyword::EXCLUDE) {
if self.consume_token(&Token::LParen) {
let columns =
self.parse_comma_separated(|parser| parser.parse_identifier(false))?;
self.expect_token(&Token::RParen)?;
Some(ExcludeSelectItem::Multiple(columns))
} else {
let column = self.parse_identifier(false)?;
Some(ExcludeSelectItem::Single(column))
}
} else {
None
};
Ok(opt_exclude)
}
/// Parse an [`Except`](ExceptSelectItem) information for wildcard select items.
///
/// If it is not possible to parse it, will return an option.
pub fn parse_optional_select_item_except(
&mut self,
) -> Result<Option<ExceptSelectItem>, ParserError> {
let opt_except = if self.parse_keyword(Keyword::EXCEPT) {
if self.peek_token().token == Token::LParen {
let idents = self.parse_parenthesized_column_list(Mandatory, false)?;
match &idents[..] {
[] => {
return self.expected(
"at least one column should be parsed by the expect clause",
self.peek_token(),
)?;
}
[first, idents @ ..] => Some(ExceptSelectItem {
first_element: first.clone(),
additional_elements: idents.to_vec(),
}),
}
} else {
// Clickhouse allows EXCEPT column_name
let ident = self.parse_identifier(false)?;
Some(ExceptSelectItem {
first_element: ident,
additional_elements: vec![],
})
}
} else {
None
};
Ok(opt_except)
}
/// Parse a [`Rename`](RenameSelectItem) information for wildcard select items.
pub fn parse_optional_select_item_rename(
&mut self,
) -> Result<Option<RenameSelectItem>, ParserError> {
let opt_rename = if self.parse_keyword(Keyword::RENAME) {
if self.consume_token(&Token::LParen) {
let idents =
self.parse_comma_separated(|parser| parser.parse_identifier_with_alias())?;
self.expect_token(&Token::RParen)?;
Some(RenameSelectItem::Multiple(idents))
} else {
let ident = self.parse_identifier_with_alias()?;
Some(RenameSelectItem::Single(ident))
}
} else {
None
};
Ok(opt_rename)
}
/// Parse a [`Replace`](ReplaceSelectItem) information for wildcard select items.
pub fn parse_optional_select_item_replace(
&mut self,
) -> Result<Option<ReplaceSelectItem>, ParserError> {
let opt_replace = if self.parse_keyword(Keyword::REPLACE) {
if self.consume_token(&Token::LParen) {
let items = self.parse_comma_separated(|parser| {
Ok(Box::new(parser.parse_replace_elements()?))
})?;
self.expect_token(&Token::RParen)?;
Some(ReplaceSelectItem { items })
} else {
let tok = self.next_token();
return self.expected("( after REPLACE but", tok);
}
} else {
None
};
Ok(opt_replace)
}
pub fn parse_replace_elements(&mut self) -> Result<ReplaceSelectElement, ParserError> {
let expr = self.parse_expr()?;
let as_keyword = self.parse_keyword(Keyword::AS);
let ident = self.parse_identifier(false)?;
Ok(ReplaceSelectElement {
expr,
column_name: ident,
as_keyword,
})
}
/// Parse an expression, optionally followed by ASC or DESC (used in ORDER BY)
pub fn parse_order_by_expr(&mut self) -> Result<OrderByExpr, ParserError> {
let expr = self.parse_expr()?;
let asc = if self.parse_keyword(Keyword::ASC) {
Some(true)
} else if self.parse_keyword(Keyword::DESC) {
Some(false)
} else {
None
};
let nulls_first = if self.parse_keywords(&[Keyword::NULLS, Keyword::FIRST]) {
Some(true)
} else if self.parse_keywords(&[Keyword::NULLS, Keyword::LAST]) {
Some(false)
} else {
None
};
let with_fill = if dialect_of!(self is ClickHouseDialect | GenericDialect)
&& self.parse_keywords(&[Keyword::WITH, Keyword::FILL])
{
Some(self.parse_with_fill()?)
} else {
None
};
Ok(OrderByExpr {
expr,
asc,
nulls_first,
with_fill,
})
}
// Parse a WITH FILL clause (ClickHouse dialect)
// that follow the WITH FILL keywords in a ORDER BY clause
pub fn parse_with_fill(&mut self) -> Result<WithFill, ParserError> {
let from = if self.parse_keyword(Keyword::FROM) {
Some(self.parse_expr()?)
} else {
None
};
let to = if self.parse_keyword(Keyword::TO) {
Some(self.parse_expr()?)
} else {
None
};
let step = if self.parse_keyword(Keyword::STEP) {
Some(self.parse_expr()?)
} else {
None
};
Ok(WithFill { from, to, step })
}
// Parse a set of comma seperated INTERPOLATE expressions (ClickHouse dialect)
// that follow the INTERPOLATE keyword in an ORDER BY clause with the WITH FILL modifier
pub fn parse_interpolations(&mut self) -> Result<Option<Interpolate>, ParserError> {
if !self.parse_keyword(Keyword::INTERPOLATE) {
return Ok(None);
}
if self.consume_token(&Token::LParen) {
let interpolations =
self.parse_comma_separated0(|p| p.parse_interpolation(), Token::RParen)?;
self.expect_token(&Token::RParen)?;
// INTERPOLATE () and INTERPOLATE ( ... ) variants
return Ok(Some(Interpolate {
exprs: Some(interpolations),
}));
}
// INTERPOLATE
Ok(Some(Interpolate { exprs: None }))
}
// Parse a INTERPOLATE expression (ClickHouse dialect)
pub fn parse_interpolation(&mut self) -> Result<InterpolateExpr, ParserError> {
let column = self.parse_identifier(false)?;
let expr = if self.parse_keyword(Keyword::AS) {
Some(self.parse_expr()?)
} else {
None
};
Ok(InterpolateExpr { column, expr })
}
/// Parse a TOP clause, MSSQL equivalent of LIMIT,
/// that follows after `SELECT [DISTINCT]`.
pub fn parse_top(&mut self) -> Result<Top, ParserError> {
let quantity = if self.consume_token(&Token::LParen) {
let quantity = self.parse_expr()?;
self.expect_token(&Token::RParen)?;
Some(TopQuantity::Expr(quantity))
} else {
let next_token = self.next_token();
let quantity = match next_token.token {
Token::Number(s, _) => Self::parse::<u64>(s, next_token.location)?,
_ => self.expected("literal int", next_token)?,
};
Some(TopQuantity::Constant(quantity))
};
let percent = self.parse_keyword(Keyword::PERCENT);
let with_ties = self.parse_keywords(&[Keyword::WITH, Keyword::TIES]);
Ok(Top {
with_ties,
percent,
quantity,
})
}
/// Parse a LIMIT clause
pub fn parse_limit(&mut self) -> Result<Option<Expr>, ParserError> {
if self.parse_keyword(Keyword::ALL) {
Ok(None)
} else {
Ok(Some(self.parse_expr()?))
}
}
/// Parse an OFFSET clause
pub fn parse_offset(&mut self) -> Result<Offset, ParserError> {
let value = self.parse_expr()?;
let rows = if self.parse_keyword(Keyword::ROW) {
OffsetRows::Row
} else if self.parse_keyword(Keyword::ROWS) {
OffsetRows::Rows
} else {
OffsetRows::None
};
Ok(Offset { value, rows })
}
/// Parse a FETCH clause
pub fn parse_fetch(&mut self) -> Result<Fetch, ParserError> {
self.expect_one_of_keywords(&[Keyword::FIRST, Keyword::NEXT])?;
let (quantity, percent) = if self
.parse_one_of_keywords(&[Keyword::ROW, Keyword::ROWS])
.is_some()
{
(None, false)
} else {
let quantity = Expr::Value(self.parse_value()?);
let percent = self.parse_keyword(Keyword::PERCENT);
self.expect_one_of_keywords(&[Keyword::ROW, Keyword::ROWS])?;
(Some(quantity), percent)
};
let with_ties = if self.parse_keyword(Keyword::ONLY) {
false
} else if self.parse_keywords(&[Keyword::WITH, Keyword::TIES]) {
true
} else {
return self.expected("one of ONLY or WITH TIES", self.peek_token());
};
Ok(Fetch {
with_ties,
percent,
quantity,
})
}
/// Parse a FOR UPDATE/FOR SHARE clause
pub fn parse_lock(&mut self) -> Result<LockClause, ParserError> {
let lock_type = match self.expect_one_of_keywords(&[Keyword::UPDATE, Keyword::SHARE])? {
Keyword::UPDATE => LockType::Update,
Keyword::SHARE => LockType::Share,
_ => unreachable!(),
};
let of = if self.parse_keyword(Keyword::OF) {
Some(self.parse_object_name(false)?)
} else {
None
};
let nonblock = if self.parse_keyword(Keyword::NOWAIT) {
Some(NonBlock::Nowait)
} else if self.parse_keywords(&[Keyword::SKIP, Keyword::LOCKED]) {
Some(NonBlock::SkipLocked)
} else {
None
};
Ok(LockClause {
lock_type,
of,
nonblock,
})
}
pub fn parse_values(&mut self, allow_empty: bool) -> Result<Values, ParserError> {
let mut explicit_row = false;
let rows = self.parse_comma_separated(|parser| {
if parser.parse_keyword(Keyword::ROW) {
explicit_row = true;
}
parser.expect_token(&Token::LParen)?;
if allow_empty && parser.peek_token().token == Token::RParen {
parser.next_token();
Ok(vec![])
} else {
let exprs = parser.parse_comma_separated(Parser::parse_expr)?;
parser.expect_token(&Token::RParen)?;
Ok(exprs)
}
})?;
Ok(Values { explicit_row, rows })
}
pub fn parse_start_transaction(&mut self) -> Result<Statement, ParserError> {
self.expect_keyword(Keyword::TRANSACTION)?;
Ok(Statement::StartTransaction {
modes: self.parse_transaction_modes()?,
begin: false,
modifier: None,
})
}
pub fn parse_begin(&mut self) -> Result<Statement, ParserError> {
let modifier = if !self.dialect.supports_start_transaction_modifier() {
None
} else if self.parse_keyword(Keyword::DEFERRED) {
Some(TransactionModifier::Deferred)
} else if self.parse_keyword(Keyword::IMMEDIATE) {
Some(TransactionModifier::Immediate)
} else if self.parse_keyword(Keyword::EXCLUSIVE) {
Some(TransactionModifier::Exclusive)
} else {
None
};
let _ = self.parse_one_of_keywords(&[Keyword::TRANSACTION, Keyword::WORK]);
Ok(Statement::StartTransaction {
modes: self.parse_transaction_modes()?,
begin: true,
modifier,
})
}
pub fn parse_end(&mut self) -> Result<Statement, ParserError> {
Ok(Statement::Commit {
chain: self.parse_commit_rollback_chain()?,
})
}
pub fn parse_transaction_modes(&mut self) -> Result<Vec<TransactionMode>, ParserError> {
let mut modes = vec![];
let mut required = false;
loop {
let mode = if self.parse_keywords(&[Keyword::ISOLATION, Keyword::LEVEL]) {
let iso_level = if self.parse_keywords(&[Keyword::READ, Keyword::UNCOMMITTED]) {
TransactionIsolationLevel::ReadUncommitted
} else if self.parse_keywords(&[Keyword::READ, Keyword::COMMITTED]) {
TransactionIsolationLevel::ReadCommitted
} else if self.parse_keywords(&[Keyword::REPEATABLE, Keyword::READ]) {
TransactionIsolationLevel::RepeatableRead
} else if self.parse_keyword(Keyword::SERIALIZABLE) {
TransactionIsolationLevel::Serializable
} else {
self.expected("isolation level", self.peek_token())?
};
TransactionMode::IsolationLevel(iso_level)
} else if self.parse_keywords(&[Keyword::READ, Keyword::ONLY]) {
TransactionMode::AccessMode(TransactionAccessMode::ReadOnly)
} else if self.parse_keywords(&[Keyword::READ, Keyword::WRITE]) {
TransactionMode::AccessMode(TransactionAccessMode::ReadWrite)
} else if required {
self.expected("transaction mode", self.peek_token())?
} else {
break;
};
modes.push(mode);
// ANSI requires a comma after each transaction mode, but
// PostgreSQL, for historical reasons, does not. We follow
// PostgreSQL in making the comma optional, since that is strictly
// more general.
required = self.consume_token(&Token::Comma);
}
Ok(modes)
}
pub fn parse_commit(&mut self) -> Result<Statement, ParserError> {
Ok(Statement::Commit {
chain: self.parse_commit_rollback_chain()?,
})
}
pub fn parse_rollback(&mut self) -> Result<Statement, ParserError> {
let chain = self.parse_commit_rollback_chain()?;
let savepoint = self.parse_rollback_savepoint()?;
Ok(Statement::Rollback { chain, savepoint })
}
pub fn parse_commit_rollback_chain(&mut self) -> Result<bool, ParserError> {
let _ = self.parse_one_of_keywords(&[Keyword::TRANSACTION, Keyword::WORK]);
if self.parse_keyword(Keyword::AND) {
let chain = !self.parse_keyword(Keyword::NO);
self.expect_keyword(Keyword::CHAIN)?;
Ok(chain)
} else {
Ok(false)
}
}
pub fn parse_rollback_savepoint(&mut self) -> Result<Option<Ident>, ParserError> {
if self.parse_keyword(Keyword::TO) {
let _ = self.parse_keyword(Keyword::SAVEPOINT);
let savepoint = self.parse_identifier(false)?;
Ok(Some(savepoint))
} else {
Ok(None)
}
}
pub fn parse_deallocate(&mut self) -> Result<Statement, ParserError> {
let prepare = self.parse_keyword(Keyword::PREPARE);
let name = self.parse_identifier(false)?;
Ok(Statement::Deallocate { name, prepare })
}
pub fn parse_execute(&mut self) -> Result<Statement, ParserError> {
let name = self.parse_identifier(false)?;
let mut parameters = vec![];
if self.consume_token(&Token::LParen) {
parameters = self.parse_comma_separated(Parser::parse_expr)?;
self.expect_token(&Token::RParen)?;
}
let mut using = vec![];
if self.parse_keyword(Keyword::USING) {
using.push(self.parse_expr()?);
while self.consume_token(&Token::Comma) {
using.push(self.parse_expr()?);
}
};
Ok(Statement::Execute {
name,
parameters,
using,
})
}
pub fn parse_prepare(&mut self) -> Result<Statement, ParserError> {
let name = self.parse_identifier(false)?;
let mut data_types = vec![];
if self.consume_token(&Token::LParen) {
data_types = self.parse_comma_separated(Parser::parse_data_type)?;
self.expect_token(&Token::RParen)?;
}
self.expect_keyword(Keyword::AS)?;
let statement = Box::new(self.parse_statement()?);
Ok(Statement::Prepare {
name,
data_types,
statement,
})
}
pub fn parse_unload(&mut self) -> Result<Statement, ParserError> {
self.expect_token(&Token::LParen)?;
let query = self.parse_boxed_query()?;
self.expect_token(&Token::RParen)?;
self.expect_keyword(Keyword::TO)?;
let to = self.parse_identifier(false)?;
let with_options = self.parse_options(Keyword::WITH)?;
Ok(Statement::Unload {
query,
to,
with: with_options,
})
}
pub fn parse_merge_clauses(&mut self) -> Result<Vec<MergeClause>, ParserError> {
let mut clauses = vec![];
loop {
if self.peek_token() == Token::EOF || self.peek_token() == Token::SemiColon {
break;
}
self.expect_keyword(Keyword::WHEN)?;
let mut clause_kind = MergeClauseKind::Matched;
if self.parse_keyword(Keyword::NOT) {
clause_kind = MergeClauseKind::NotMatched;
}
self.expect_keyword(Keyword::MATCHED)?;
if matches!(clause_kind, MergeClauseKind::NotMatched)
&& self.parse_keywords(&[Keyword::BY, Keyword::SOURCE])
{
clause_kind = MergeClauseKind::NotMatchedBySource;
} else if matches!(clause_kind, MergeClauseKind::NotMatched)
&& self.parse_keywords(&[Keyword::BY, Keyword::TARGET])
{
clause_kind = MergeClauseKind::NotMatchedByTarget;
}
let predicate = if self.parse_keyword(Keyword::AND) {
Some(self.parse_expr()?)
} else {
None
};
self.expect_keyword(Keyword::THEN)?;
let merge_clause = match self.parse_one_of_keywords(&[
Keyword::UPDATE,
Keyword::INSERT,
Keyword::DELETE,
]) {
Some(Keyword::UPDATE) => {
if matches!(
clause_kind,
MergeClauseKind::NotMatched | MergeClauseKind::NotMatchedByTarget
) {
return Err(ParserError::ParserError(format!(
"UPDATE is not allowed in a {clause_kind} merge clause"
)));
}
self.expect_keyword(Keyword::SET)?;
MergeAction::Update {
assignments: self.parse_comma_separated(Parser::parse_assignment)?,
}
}
Some(Keyword::DELETE) => {
if matches!(
clause_kind,
MergeClauseKind::NotMatched | MergeClauseKind::NotMatchedByTarget
) {
return Err(ParserError::ParserError(format!(
"DELETE is not allowed in a {clause_kind} merge clause"
)));
}
MergeAction::Delete
}
Some(Keyword::INSERT) => {
if !matches!(
clause_kind,
MergeClauseKind::NotMatched | MergeClauseKind::NotMatchedByTarget
) {
return Err(ParserError::ParserError(format!(
"INSERT is not allowed in a {clause_kind} merge clause"
)));
}
let is_mysql = dialect_of!(self is MySqlDialect);
let columns = self.parse_parenthesized_column_list(Optional, is_mysql)?;
let kind = if dialect_of!(self is BigQueryDialect | GenericDialect)
&& self.parse_keyword(Keyword::ROW)
{
MergeInsertKind::Row
} else {
self.expect_keyword(Keyword::VALUES)?;
let values = self.parse_values(is_mysql)?;
MergeInsertKind::Values(values)
};
MergeAction::Insert(MergeInsertExpr { columns, kind })
}
_ => {
return Err(ParserError::ParserError(
"expected UPDATE, DELETE or INSERT in merge clause".to_string(),
));
}
};
clauses.push(MergeClause {
clause_kind,
predicate,
action: merge_clause,
});
}
Ok(clauses)
}
pub fn parse_merge(&mut self) -> Result<Statement, ParserError> {
let into = self.parse_keyword(Keyword::INTO);
let table = self.parse_table_factor()?;
self.expect_keyword(Keyword::USING)?;
let source = self.parse_table_factor()?;
self.expect_keyword(Keyword::ON)?;
let on = self.parse_expr()?;
let clauses = self.parse_merge_clauses()?;
Ok(Statement::Merge {
into,
table,
source,
on: Box::new(on),
clauses,
})
}
fn parse_pragma_value(&mut self) -> Result<Value, ParserError> {
match self.parse_value()? {
v @ Value::SingleQuotedString(_) => Ok(v),
v @ Value::DoubleQuotedString(_) => Ok(v),
v @ Value::Number(_, _) => Ok(v),
v @ Value::Placeholder(_) => Ok(v),
_ => {
self.prev_token();
self.expected("number or string or ? placeholder", self.peek_token())
}
}
}
// PRAGMA [schema-name '.'] pragma-name [('=' pragma-value) | '(' pragma-value ')']
pub fn parse_pragma(&mut self) -> Result<Statement, ParserError> {
let name = self.parse_object_name(false)?;
if self.consume_token(&Token::LParen) {
let value = self.parse_pragma_value()?;
self.expect_token(&Token::RParen)?;
Ok(Statement::Pragma {
name,
value: Some(value),
is_eq: false,
})
} else if self.consume_token(&Token::Eq) {
Ok(Statement::Pragma {
name,
value: Some(self.parse_pragma_value()?),
is_eq: true,
})
} else {
Ok(Statement::Pragma {
name,
value: None,
is_eq: false,
})
}
}
/// `INSTALL [extension_name]`
pub fn parse_install(&mut self) -> Result<Statement, ParserError> {
let extension_name = self.parse_identifier(false)?;
Ok(Statement::Install { extension_name })
}
/// `LOAD [extension_name]`
pub fn parse_load(&mut self) -> Result<Statement, ParserError> {
let extension_name = self.parse_identifier(false)?;
Ok(Statement::Load { extension_name })
}
/// ```sql
/// OPTIMIZE TABLE [db.]name [ON CLUSTER cluster] [PARTITION partition | PARTITION ID 'partition_id'] [FINAL] [DEDUPLICATE [BY expression]]
/// ```
/// [ClickHouse](https://clickhouse.com/docs/en/sql-reference/statements/optimize)
pub fn parse_optimize_table(&mut self) -> Result<Statement, ParserError> {
self.expect_keyword(Keyword::TABLE)?;
let name = self.parse_object_name(false)?;
let on_cluster = self.parse_optional_on_cluster()?;
let partition = if self.parse_keyword(Keyword::PARTITION) {
if self.parse_keyword(Keyword::ID) {
Some(Partition::Identifier(self.parse_identifier(false)?))
} else {
Some(Partition::Expr(self.parse_expr()?))
}
} else {
None
};
let include_final = self.parse_keyword(Keyword::FINAL);
let deduplicate = if self.parse_keyword(Keyword::DEDUPLICATE) {
if self.parse_keyword(Keyword::BY) {
Some(Deduplicate::ByExpression(self.parse_expr()?))
} else {
Some(Deduplicate::All)
}
} else {
None
};
Ok(Statement::OptimizeTable {
name,
on_cluster,
partition,
include_final,
deduplicate,
})
}
/// ```sql
/// CREATE [ { TEMPORARY | TEMP } ] SEQUENCE [ IF NOT EXISTS ] <sequence_name>
/// ```
///
/// See [Postgres docs](https://www.postgresql.org/docs/current/sql-createsequence.html) for more details.
pub fn parse_create_sequence(&mut self, temporary: bool) -> Result<Statement, ParserError> {
//[ IF NOT EXISTS ]
let if_not_exists = self.parse_keywords(&[Keyword::IF, Keyword::NOT, Keyword::EXISTS]);
//name
let name = self.parse_object_name(false)?;
//[ AS data_type ]
let mut data_type: Option<DataType> = None;
if self.parse_keywords(&[Keyword::AS]) {
data_type = Some(self.parse_data_type()?)
}
let sequence_options = self.parse_create_sequence_options()?;
// [ OWNED BY { table_name.column_name | NONE } ]
let owned_by = if self.parse_keywords(&[Keyword::OWNED, Keyword::BY]) {
if self.parse_keywords(&[Keyword::NONE]) {
Some(ObjectName(vec![Ident::new("NONE")]))
} else {
Some(self.parse_object_name(false)?)
}
} else {
None
};
Ok(Statement::CreateSequence {
temporary,
if_not_exists,
name,
data_type,
sequence_options,
owned_by,
})
}
fn parse_create_sequence_options(&mut self) -> Result<Vec<SequenceOptions>, ParserError> {
let mut sequence_options = vec![];
//[ INCREMENT [ BY ] increment ]
if self.parse_keywords(&[Keyword::INCREMENT]) {
if self.parse_keywords(&[Keyword::BY]) {
sequence_options.push(SequenceOptions::IncrementBy(
Expr::Value(self.parse_number_value()?),
true,
));
} else {
sequence_options.push(SequenceOptions::IncrementBy(
Expr::Value(self.parse_number_value()?),
false,
));
}
}
//[ MINVALUE minvalue | NO MINVALUE ]
if self.parse_keyword(Keyword::MINVALUE) {
sequence_options.push(SequenceOptions::MinValue(Some(Expr::Value(
self.parse_number_value()?,
))));
} else if self.parse_keywords(&[Keyword::NO, Keyword::MINVALUE]) {
sequence_options.push(SequenceOptions::MinValue(None));
}
//[ MAXVALUE maxvalue | NO MAXVALUE ]
if self.parse_keywords(&[Keyword::MAXVALUE]) {
sequence_options.push(SequenceOptions::MaxValue(Some(Expr::Value(
self.parse_number_value()?,
))));
} else if self.parse_keywords(&[Keyword::NO, Keyword::MAXVALUE]) {
sequence_options.push(SequenceOptions::MaxValue(None));
}
//[ START [ WITH ] start ]
if self.parse_keywords(&[Keyword::START]) {
if self.parse_keywords(&[Keyword::WITH]) {
sequence_options.push(SequenceOptions::StartWith(
Expr::Value(self.parse_number_value()?),
true,
));
} else {
sequence_options.push(SequenceOptions::StartWith(
Expr::Value(self.parse_number_value()?),
false,
));
}
}
//[ CACHE cache ]
if self.parse_keywords(&[Keyword::CACHE]) {
sequence_options.push(SequenceOptions::Cache(Expr::Value(
self.parse_number_value()?,
)));
}
// [ [ NO ] CYCLE ]
if self.parse_keywords(&[Keyword::NO, Keyword::CYCLE]) {
sequence_options.push(SequenceOptions::Cycle(true));
} else if self.parse_keywords(&[Keyword::CYCLE]) {
sequence_options.push(SequenceOptions::Cycle(false));
}
Ok(sequence_options)
}
/// The index of the first unprocessed token.
pub fn index(&self) -> usize {
self.index
}
pub fn parse_named_window(&mut self) -> Result<NamedWindowDefinition, ParserError> {
let ident = self.parse_identifier(false)?;
self.expect_keyword(Keyword::AS)?;
let window_expr = if self.consume_token(&Token::LParen) {
NamedWindowExpr::WindowSpec(self.parse_window_spec()?)
} else if self.dialect.supports_window_clause_named_window_reference() {
NamedWindowExpr::NamedWindow(self.parse_identifier(false)?)
} else {
return self.expected("(", self.peek_token());
};
Ok(NamedWindowDefinition(ident, window_expr))
}
pub fn parse_create_procedure(&mut self, or_alter: bool) -> Result<Statement, ParserError> {
let name = self.parse_object_name(false)?;
let params = self.parse_optional_procedure_parameters()?;
self.expect_keyword(Keyword::AS)?;
self.expect_keyword(Keyword::BEGIN)?;
let statements = self.parse_statements()?;
self.expect_keyword(Keyword::END)?;
Ok(Statement::CreateProcedure {
name,
or_alter,
params,
body: statements,
})
}
pub fn parse_window_spec(&mut self) -> Result<WindowSpec, ParserError> {
let window_name = match self.peek_token().token {
Token::Word(word) if word.keyword == Keyword::NoKeyword => self.parse_optional_indent(),
_ => None,
};
let partition_by = if self.parse_keywords(&[Keyword::PARTITION, Keyword::BY]) {
self.parse_comma_separated(Parser::parse_expr)?
} else {
vec![]
};
let order_by = if self.parse_keywords(&[Keyword::ORDER, Keyword::BY]) {
self.parse_comma_separated(Parser::parse_order_by_expr)?
} else {
vec![]
};
let window_frame = if !self.consume_token(&Token::RParen) {
let window_frame = self.parse_window_frame()?;
self.expect_token(&Token::RParen)?;
Some(window_frame)
} else {
None
};
Ok(WindowSpec {
window_name,
partition_by,
order_by,
window_frame,
})
}
pub fn parse_create_type(&mut self) -> Result<Statement, ParserError> {
let name = self.parse_object_name(false)?;
self.expect_keyword(Keyword::AS)?;
let mut attributes = vec![];
if !self.consume_token(&Token::LParen) || self.consume_token(&Token::RParen) {
return Ok(Statement::CreateType {
name,
representation: UserDefinedTypeRepresentation::Composite { attributes },
});
}
loop {
let attr_name = self.parse_identifier(false)?;
let attr_data_type = self.parse_data_type()?;
let attr_collation = if self.parse_keyword(Keyword::COLLATE) {
Some(self.parse_object_name(false)?)
} else {
None
};
attributes.push(UserDefinedTypeCompositeAttributeDef {
name: attr_name,
data_type: attr_data_type,
collation: attr_collation,
});
let comma = self.consume_token(&Token::Comma);
if self.consume_token(&Token::RParen) {
// allow a trailing comma
break;
} else if !comma {
return self.expected("',' or ')' after attribute definition", self.peek_token());
}
}
Ok(Statement::CreateType {
name,
representation: UserDefinedTypeRepresentation::Composite { attributes },
})
}
fn parse_parenthesized_identifiers(&mut self) -> Result<Vec<Ident>, ParserError> {
self.expect_token(&Token::LParen)?;
let partitions = self.parse_comma_separated(|p| p.parse_identifier(false))?;
self.expect_token(&Token::RParen)?;
Ok(partitions)
}
fn parse_column_position(&mut self) -> Result<Option<MySQLColumnPosition>, ParserError> {
if dialect_of!(self is MySqlDialect | GenericDialect) {
if self.parse_keyword(Keyword::FIRST) {
Ok(Some(MySQLColumnPosition::First))
} else if self.parse_keyword(Keyword::AFTER) {
let ident = self.parse_identifier(false)?;
Ok(Some(MySQLColumnPosition::After(ident)))
} else {
Ok(None)
}
} else {
Ok(None)
}
}
/// Consume the parser and return its underlying token buffer
pub fn into_tokens(self) -> Vec<TokenWithLocation> {
self.tokens
}
}
impl Word {
pub fn to_ident(&self) -> Ident {
Ident {
value: self.value.clone(),
quote_style: self.quote_style,
}
}
}
#[cfg(test)]
mod tests {
use crate::test_utils::{all_dialects, TestedDialects};
use super::*;
#[test]
fn test_prev_index() {
let sql = "SELECT version";
all_dialects().run_parser_method(sql, |parser| {
assert_eq!(parser.peek_token(), Token::make_keyword("SELECT"));
assert_eq!(parser.next_token(), Token::make_keyword("SELECT"));
parser.prev_token();
assert_eq!(parser.next_token(), Token::make_keyword("SELECT"));
assert_eq!(parser.next_token(), Token::make_word("version", None));
parser.prev_token();
assert_eq!(parser.peek_token(), Token::make_word("version", None));
assert_eq!(parser.next_token(), Token::make_word("version", None));
assert_eq!(parser.peek_token(), Token::EOF);
parser.prev_token();
assert_eq!(parser.next_token(), Token::make_word("version", None));
assert_eq!(parser.next_token(), Token::EOF);
assert_eq!(parser.next_token(), Token::EOF);
parser.prev_token();
});
}
#[test]
fn test_peek_tokens() {
all_dialects().run_parser_method("SELECT foo AS bar FROM baz", |parser| {
assert!(matches!(
parser.peek_tokens(),
[Token::Word(Word {
keyword: Keyword::SELECT,
..
})]
));
assert!(matches!(
parser.peek_tokens(),
[
Token::Word(Word {
keyword: Keyword::SELECT,
..
}),
Token::Word(_),
Token::Word(Word {
keyword: Keyword::AS,
..
}),
]
));
for _ in 0..4 {
parser.next_token();
}
assert!(matches!(
parser.peek_tokens(),
[
Token::Word(Word {
keyword: Keyword::FROM,
..
}),
Token::Word(_),
Token::EOF,
Token::EOF,
]
))
})
}
#[cfg(test)]
mod test_parse_data_type {
use crate::ast::{
CharLengthUnits, CharacterLength, DataType, ExactNumberInfo, ObjectName, TimezoneInfo,
};
use crate::dialect::{AnsiDialect, GenericDialect};
use crate::test_utils::TestedDialects;
macro_rules! test_parse_data_type {
($dialect:expr, $input:expr, $expected_type:expr $(,)?) => {{
$dialect.run_parser_method(&*$input, |parser| {
let data_type = parser.parse_data_type().unwrap();
assert_eq!($expected_type, data_type);
assert_eq!($input.to_string(), data_type.to_string());
});
}};
}
#[test]
fn test_ansii_character_string_types() {
// Character string types: <https://jakewheat.github.io/sql-overview/sql-2016-foundation-grammar.html#character-string-type>
let dialect = TestedDialects {
dialects: vec![Box::new(GenericDialect {}), Box::new(AnsiDialect {})],
options: None,
};
test_parse_data_type!(dialect, "CHARACTER", DataType::Character(None));
test_parse_data_type!(
dialect,
"CHARACTER(20)",
DataType::Character(Some(CharacterLength::IntegerLength {
length: 20,
unit: None
}))
);
test_parse_data_type!(
dialect,
"CHARACTER(20 CHARACTERS)",
DataType::Character(Some(CharacterLength::IntegerLength {
length: 20,
unit: Some(CharLengthUnits::Characters)
}))
);
test_parse_data_type!(
dialect,
"CHARACTER(20 OCTETS)",
DataType::Character(Some(CharacterLength::IntegerLength {
length: 20,
unit: Some(CharLengthUnits::Octets)
}))
);
test_parse_data_type!(dialect, "CHAR", DataType::Char(None));
test_parse_data_type!(
dialect,
"CHAR(20)",
DataType::Char(Some(CharacterLength::IntegerLength {
length: 20,
unit: None
}))
);
test_parse_data_type!(
dialect,
"CHAR(20 CHARACTERS)",
DataType::Char(Some(CharacterLength::IntegerLength {
length: 20,
unit: Some(CharLengthUnits::Characters)
}))
);
test_parse_data_type!(
dialect,
"CHAR(20 OCTETS)",
DataType::Char(Some(CharacterLength::IntegerLength {
length: 20,
unit: Some(CharLengthUnits::Octets)
}))
);
test_parse_data_type!(
dialect,
"CHARACTER VARYING(20)",
DataType::CharacterVarying(Some(CharacterLength::IntegerLength {
length: 20,
unit: None
}))
);
test_parse_data_type!(
dialect,
"CHARACTER VARYING(20 CHARACTERS)",
DataType::CharacterVarying(Some(CharacterLength::IntegerLength {
length: 20,
unit: Some(CharLengthUnits::Characters)
}))
);
test_parse_data_type!(
dialect,
"CHARACTER VARYING(20 OCTETS)",
DataType::CharacterVarying(Some(CharacterLength::IntegerLength {
length: 20,
unit: Some(CharLengthUnits::Octets)
}))
);
test_parse_data_type!(
dialect,
"CHAR VARYING(20)",
DataType::CharVarying(Some(CharacterLength::IntegerLength {
length: 20,
unit: None
}))
);
test_parse_data_type!(
dialect,
"CHAR VARYING(20 CHARACTERS)",
DataType::CharVarying(Some(CharacterLength::IntegerLength {
length: 20,
unit: Some(CharLengthUnits::Characters)
}))
);
test_parse_data_type!(
dialect,
"CHAR VARYING(20 OCTETS)",
DataType::CharVarying(Some(CharacterLength::IntegerLength {
length: 20,
unit: Some(CharLengthUnits::Octets)
}))
);
test_parse_data_type!(
dialect,
"VARCHAR(20)",
DataType::Varchar(Some(CharacterLength::IntegerLength {
length: 20,
unit: None
}))
);
}
#[test]
fn test_ansii_character_large_object_types() {
// Character large object types: <https://jakewheat.github.io/sql-overview/sql-2016-foundation-grammar.html#character-large-object-length>
let dialect = TestedDialects {
dialects: vec![Box::new(GenericDialect {}), Box::new(AnsiDialect {})],
options: None,
};
test_parse_data_type!(
dialect,
"CHARACTER LARGE OBJECT",
DataType::CharacterLargeObject(None)
);
test_parse_data_type!(
dialect,
"CHARACTER LARGE OBJECT(20)",
DataType::CharacterLargeObject(Some(20))
);
test_parse_data_type!(
dialect,
"CHAR LARGE OBJECT",
DataType::CharLargeObject(None)
);
test_parse_data_type!(
dialect,
"CHAR LARGE OBJECT(20)",
DataType::CharLargeObject(Some(20))
);
test_parse_data_type!(dialect, "CLOB", DataType::Clob(None));
test_parse_data_type!(dialect, "CLOB(20)", DataType::Clob(Some(20)));
}
#[test]
fn test_parse_custom_types() {
let dialect = TestedDialects {
dialects: vec![Box::new(GenericDialect {}), Box::new(AnsiDialect {})],
options: None,
};
test_parse_data_type!(
dialect,
"GEOMETRY",
DataType::Custom(ObjectName(vec!["GEOMETRY".into()]), vec![])
);
test_parse_data_type!(
dialect,
"GEOMETRY(POINT)",
DataType::Custom(
ObjectName(vec!["GEOMETRY".into()]),
vec!["POINT".to_string()]
)
);
test_parse_data_type!(
dialect,
"GEOMETRY(POINT, 4326)",
DataType::Custom(
ObjectName(vec!["GEOMETRY".into()]),
vec!["POINT".to_string(), "4326".to_string()]
)
);
}
#[test]
fn test_ansii_exact_numeric_types() {
// Exact numeric types: <https://jakewheat.github.io/sql-overview/sql-2016-foundation-grammar.html#exact-numeric-type>
let dialect = TestedDialects {
dialects: vec![Box::new(GenericDialect {}), Box::new(AnsiDialect {})],
options: None,
};
test_parse_data_type!(dialect, "NUMERIC", DataType::Numeric(ExactNumberInfo::None));
test_parse_data_type!(
dialect,
"NUMERIC(2)",
DataType::Numeric(ExactNumberInfo::Precision(2))
);
test_parse_data_type!(
dialect,
"NUMERIC(2,10)",
DataType::Numeric(ExactNumberInfo::PrecisionAndScale(2, 10))
);
test_parse_data_type!(dialect, "DECIMAL", DataType::Decimal(ExactNumberInfo::None));
test_parse_data_type!(
dialect,
"DECIMAL(2)",
DataType::Decimal(ExactNumberInfo::Precision(2))
);
test_parse_data_type!(
dialect,
"DECIMAL(2,10)",
DataType::Decimal(ExactNumberInfo::PrecisionAndScale(2, 10))
);
test_parse_data_type!(dialect, "DEC", DataType::Dec(ExactNumberInfo::None));
test_parse_data_type!(
dialect,
"DEC(2)",
DataType::Dec(ExactNumberInfo::Precision(2))
);
test_parse_data_type!(
dialect,
"DEC(2,10)",
DataType::Dec(ExactNumberInfo::PrecisionAndScale(2, 10))
);
}
#[test]
fn test_ansii_date_type() {
// Datetime types: <https://jakewheat.github.io/sql-overview/sql-2016-foundation-grammar.html#datetime-type>
let dialect = TestedDialects {
dialects: vec![Box::new(GenericDialect {}), Box::new(AnsiDialect {})],
options: None,
};
test_parse_data_type!(dialect, "DATE", DataType::Date);
test_parse_data_type!(dialect, "TIME", DataType::Time(None, TimezoneInfo::None));
test_parse_data_type!(
dialect,
"TIME(6)",
DataType::Time(Some(6), TimezoneInfo::None)
);
test_parse_data_type!(
dialect,
"TIME WITH TIME ZONE",
DataType::Time(None, TimezoneInfo::WithTimeZone)
);
test_parse_data_type!(
dialect,
"TIME(6) WITH TIME ZONE",
DataType::Time(Some(6), TimezoneInfo::WithTimeZone)
);
test_parse_data_type!(
dialect,
"TIME WITHOUT TIME ZONE",
DataType::Time(None, TimezoneInfo::WithoutTimeZone)
);
test_parse_data_type!(
dialect,
"TIME(6) WITHOUT TIME ZONE",
DataType::Time(Some(6), TimezoneInfo::WithoutTimeZone)
);
test_parse_data_type!(
dialect,
"TIMESTAMP",
DataType::Timestamp(None, TimezoneInfo::None)
);
test_parse_data_type!(
dialect,
"TIMESTAMP(22)",
DataType::Timestamp(Some(22), TimezoneInfo::None)
);
test_parse_data_type!(
dialect,
"TIMESTAMP(22) WITH TIME ZONE",
DataType::Timestamp(Some(22), TimezoneInfo::WithTimeZone)
);
test_parse_data_type!(
dialect,
"TIMESTAMP(33) WITHOUT TIME ZONE",
DataType::Timestamp(Some(33), TimezoneInfo::WithoutTimeZone)
);
}
}
#[test]
fn test_parse_schema_name() {
// The expected name should be identical as the input name, that's why I don't receive both
macro_rules! test_parse_schema_name {
($input:expr, $expected_name:expr $(,)?) => {{
all_dialects().run_parser_method(&*$input, |parser| {
let schema_name = parser.parse_schema_name().unwrap();
// Validate that the structure is the same as expected
assert_eq!(schema_name, $expected_name);
// Validate that the input and the expected structure serialization are the same
assert_eq!(schema_name.to_string(), $input.to_string());
});
}};
}
let dummy_name = ObjectName(vec![Ident::new("dummy_name")]);
let dummy_authorization = Ident::new("dummy_authorization");
test_parse_schema_name!(
format!("{dummy_name}"),
SchemaName::Simple(dummy_name.clone())
);
test_parse_schema_name!(
format!("AUTHORIZATION {dummy_authorization}"),
SchemaName::UnnamedAuthorization(dummy_authorization.clone()),
);
test_parse_schema_name!(
format!("{dummy_name} AUTHORIZATION {dummy_authorization}"),
SchemaName::NamedAuthorization(dummy_name.clone(), dummy_authorization.clone()),
);
}
#[test]
fn mysql_parse_index_table_constraint() {
macro_rules! test_parse_table_constraint {
($dialect:expr, $input:expr, $expected:expr $(,)?) => {{
$dialect.run_parser_method(&*$input, |parser| {
let constraint = parser.parse_optional_table_constraint().unwrap().unwrap();
// Validate that the structure is the same as expected
assert_eq!(constraint, $expected);
// Validate that the input and the expected structure serialization are the same
assert_eq!(constraint.to_string(), $input.to_string());
});
}};
}
let dialect = TestedDialects {
dialects: vec![Box::new(GenericDialect {}), Box::new(MySqlDialect {})],
options: None,
};
test_parse_table_constraint!(
dialect,
"INDEX (c1)",
TableConstraint::Index {
display_as_key: false,
name: None,
index_type: None,
columns: vec![Ident::new("c1")],
}
);
test_parse_table_constraint!(
dialect,
"KEY (c1)",
TableConstraint::Index {
display_as_key: true,
name: None,
index_type: None,
columns: vec![Ident::new("c1")],
}
);
test_parse_table_constraint!(
dialect,
"INDEX 'index' (c1, c2)",
TableConstraint::Index {
display_as_key: false,
name: Some(Ident::with_quote('\'', "index")),
index_type: None,
columns: vec![Ident::new("c1"), Ident::new("c2")],
}
);
test_parse_table_constraint!(
dialect,
"INDEX USING BTREE (c1)",
TableConstraint::Index {
display_as_key: false,
name: None,
index_type: Some(IndexType::BTree),
columns: vec![Ident::new("c1")],
}
);
test_parse_table_constraint!(
dialect,
"INDEX USING HASH (c1)",
TableConstraint::Index {
display_as_key: false,
name: None,
index_type: Some(IndexType::Hash),
columns: vec![Ident::new("c1")],
}
);
test_parse_table_constraint!(
dialect,
"INDEX idx_name USING BTREE (c1)",
TableConstraint::Index {
display_as_key: false,
name: Some(Ident::new("idx_name")),
index_type: Some(IndexType::BTree),
columns: vec![Ident::new("c1")],
}
);
test_parse_table_constraint!(
dialect,
"INDEX idx_name USING HASH (c1)",
TableConstraint::Index {
display_as_key: false,
name: Some(Ident::new("idx_name")),
index_type: Some(IndexType::Hash),
columns: vec![Ident::new("c1")],
}
);
}
#[test]
fn test_tokenizer_error_loc() {
let sql = "foo '";
let ast = Parser::parse_sql(&GenericDialect, sql);
assert_eq!(
ast,
Err(ParserError::TokenizerError(
"Unterminated string literal at Line: 1, Column: 5".to_string()
))
);
}
#[test]
fn test_parser_error_loc() {
let sql = "SELECT this is a syntax error";
let ast = Parser::parse_sql(&GenericDialect, sql);
assert_eq!(
ast,
Err(ParserError::ParserError(
"Expected: [NOT] NULL or TRUE|FALSE or [NOT] DISTINCT FROM after IS, found: a at Line: 1, Column: 16"
.to_string()
))
);
}
#[test]
fn test_nested_explain_error() {
let sql = "EXPLAIN EXPLAIN SELECT 1";
let ast = Parser::parse_sql(&GenericDialect, sql);
assert_eq!(
ast,
Err(ParserError::ParserError(
"Explain must be root of the plan".to_string()
))
);
}
#[test]
fn test_parse_multipart_identifier_positive() {
let dialect = TestedDialects {
dialects: vec![Box::new(GenericDialect {})],
options: None,
};
// parse multipart with quotes
let expected = vec![
Ident {
value: "CATALOG".to_string(),
quote_style: None,
},
Ident {
value: "F(o)o. \"bar".to_string(),
quote_style: Some('"'),
},
Ident {
value: "table".to_string(),
quote_style: None,
},
];
dialect.run_parser_method(r#"CATALOG."F(o)o. ""bar".table"#, |parser| {
let actual = parser.parse_multipart_identifier().unwrap();
assert_eq!(expected, actual);
});
// allow whitespace between ident parts
let expected = vec![
Ident {
value: "CATALOG".to_string(),
quote_style: None,
},
Ident {
value: "table".to_string(),
quote_style: None,
},
];
dialect.run_parser_method("CATALOG . table", |parser| {
let actual = parser.parse_multipart_identifier().unwrap();
assert_eq!(expected, actual);
});
}
#[test]
fn test_parse_multipart_identifier_negative() {
macro_rules! test_parse_multipart_identifier_error {
($input:expr, $expected_err:expr $(,)?) => {{
all_dialects().run_parser_method(&*$input, |parser| {
let actual_err = parser.parse_multipart_identifier().unwrap_err();
assert_eq!(actual_err.to_string(), $expected_err);
});
}};
}
test_parse_multipart_identifier_error!(
"",
"sql parser error: Empty input when parsing identifier",
);
test_parse_multipart_identifier_error!(
"*schema.table",
"sql parser error: Unexpected token in identifier: *",
);
test_parse_multipart_identifier_error!(
"schema.table*",
"sql parser error: Unexpected token in identifier: *",
);
test_parse_multipart_identifier_error!(
"schema.table.",
"sql parser error: Trailing period in identifier",
);
test_parse_multipart_identifier_error!(
"schema.*",
"sql parser error: Unexpected token following period in identifier: *",
);
}
#[test]
fn test_mysql_partition_selection() {
let sql = "SELECT * FROM employees PARTITION (p0, p2)";
let expected = vec!["p0", "p2"];
let ast: Vec<Statement> = Parser::parse_sql(&MySqlDialect {}, sql).unwrap();
assert_eq!(ast.len(), 1);
if let Statement::Query(v) = &ast[0] {
if let SetExpr::Select(select) = &*v.body {
assert_eq!(select.from.len(), 1);
let from: &TableWithJoins = &select.from[0];
let table_factor = &from.relation;
if let TableFactor::Table { partitions, .. } = table_factor {
let actual: Vec<&str> = partitions
.iter()
.map(|ident| ident.value.as_str())
.collect();
assert_eq!(expected, actual);
}
}
} else {
panic!("fail to parse mysql partition selection");
}
}
#[test]
fn test_replace_into_placeholders() {
let sql = "REPLACE INTO t (a) VALUES (&a)";
assert!(Parser::parse_sql(&GenericDialect {}, sql).is_err());
}
#[test]
fn test_replace_into_set() {
// NOTE: This is actually valid MySQL syntax, REPLACE and INSERT,
// but the parser does not yet support it.
// https://dev.mysql.com/doc/refman/8.3/en/insert.html
let sql = "REPLACE INTO t SET a='1'";
assert!(Parser::parse_sql(&MySqlDialect {}, sql).is_err());
}
#[test]
fn test_replace_into_set_placeholder() {
let sql = "REPLACE INTO t SET ?";
assert!(Parser::parse_sql(&GenericDialect {}, sql).is_err());
}
#[test]
fn test_replace_incomplete() {
let sql = r#"REPLACE"#;
assert!(Parser::parse_sql(&MySqlDialect {}, sql).is_err());
}
}
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