sqlglot.transforms
1from __future__ import annotations 2 3import typing as t 4 5from sqlglot import expressions as exp 6from sqlglot.errors import UnsupportedError 7from sqlglot.helper import find_new_name, name_sequence, seq_get 8 9 10if t.TYPE_CHECKING: 11 from sqlglot._typing import E 12 from sqlglot.generator import Generator 13 14 15def preprocess( 16 transforms: list[t.Callable[[exp.Expr], exp.Expr]], 17 generator: t.Callable[[Generator, exp.Expr], str] | None = None, 18) -> t.Callable[[Generator, exp.Expr], str]: 19 """ 20 Creates a new transform by chaining a sequence of transformations and converts the resulting 21 expression to SQL, using either the "_sql" method corresponding to the resulting expression, 22 or the appropriate `Generator.TRANSFORMS` function (when applicable -- see below). 23 24 Args: 25 transforms: sequence of transform functions. These will be called in order. 26 27 Returns: 28 Function that can be used as a generator transform. 29 """ 30 31 def _to_sql(self, expression: exp.Expr) -> str: 32 expression_type = type(expression) 33 34 try: 35 expression = transforms[0](expression) 36 for transform in transforms[1:]: 37 expression = transform(expression) 38 except UnsupportedError as unsupported_error: 39 self.unsupported(str(unsupported_error)) 40 41 if generator: 42 return generator(self, expression) 43 44 _sql_handler = getattr(self, expression.key + "_sql", None) 45 if _sql_handler: 46 return _sql_handler(expression) 47 48 transforms_handler = self.TRANSFORMS.get(type(expression)) 49 if transforms_handler: 50 if expression_type is type(expression): 51 if isinstance(expression, exp.Func): 52 return self.function_fallback_sql(expression) 53 54 # Ensures we don't enter an infinite loop. This can happen when the original expression 55 # has the same type as the final expression and there's no _sql method available for it, 56 # because then it'd re-enter _to_sql. 57 raise ValueError( 58 f"Expr type {expression.__class__.__name__} requires a _sql method in order to be transformed." 59 ) 60 61 return transforms_handler(self, expression) 62 63 raise ValueError(f"Unsupported expression type {expression.__class__.__name__}.") 64 65 return _to_sql 66 67 68def unnest_generate_date_array_using_recursive_cte(expression: exp.Expr) -> exp.Expr: 69 if isinstance(expression, exp.Select): 70 count = 0 71 recursive_ctes = [] 72 73 for unnest in expression.find_all(exp.Unnest): 74 if ( 75 not isinstance(unnest.parent, (exp.From, exp.Join)) 76 or len(unnest.expressions) != 1 77 or not isinstance(unnest.expressions[0], exp.GenerateDateArray) 78 ): 79 continue 80 81 generate_date_array = unnest.expressions[0] 82 start = generate_date_array.args.get("start") 83 end = generate_date_array.args.get("end") 84 step = generate_date_array.args.get("step") 85 86 if not start or not end or not isinstance(step, exp.Interval): 87 continue 88 89 alias = unnest.args.get("alias") 90 column_name = alias.columns[0] if isinstance(alias, exp.TableAlias) else "date_value" 91 92 start = exp.cast(start, "date") 93 date_add = exp.func( 94 "date_add", column_name, exp.Literal.number(step.name), step.args.get("unit") 95 ) 96 cast_date_add = exp.cast(date_add, "date") 97 98 cte_name = "_generated_dates" + (f"_{count}" if count else "") 99 100 base_query = exp.select(start.as_(column_name)) 101 recursive_query = ( 102 exp.select(cast_date_add) 103 .from_(cte_name) 104 .where(cast_date_add <= exp.cast(end, "date")) 105 ) 106 cte_query = base_query.union(recursive_query, distinct=False) 107 108 generate_dates_query = exp.select(column_name).from_(cte_name) 109 unnest.replace(generate_dates_query.subquery(cte_name)) 110 111 recursive_ctes.append( 112 exp.alias_(exp.CTE(this=cte_query), cte_name, table=[column_name]) 113 ) 114 count += 1 115 116 if recursive_ctes: 117 with_expression = expression.args.get("with_") or exp.With() 118 with_expression.set("recursive", True) 119 with_expression.set("expressions", [*recursive_ctes, *with_expression.expressions]) 120 expression.set("with_", with_expression) 121 122 return expression 123 124 125def unnest_generate_series(expression: exp.Expr) -> exp.Expr: 126 """Unnests GENERATE_SERIES or SEQUENCE table references.""" 127 this = expression.this 128 if isinstance(expression, exp.Table) and isinstance(this, exp.GenerateSeries): 129 unnest = exp.Unnest(expressions=[this]) 130 if expression.alias: 131 return exp.alias_(unnest, alias="_u", table=[expression.alias], copy=False) 132 133 return unnest 134 135 return expression 136 137 138def eliminate_distinct_on(expression: exp.Expr) -> exp.Expr: 139 """ 140 Convert SELECT DISTINCT ON statements to a subquery with a window function. 141 142 This is useful for dialects that don't support SELECT DISTINCT ON but support window functions. 143 144 Args: 145 expression: the expression that will be transformed. 146 147 Returns: 148 The transformed expression. 149 """ 150 if ( 151 isinstance(expression, exp.Select) 152 and expression.args.get("distinct") 153 and isinstance(expression.args["distinct"].args.get("on"), exp.Tuple) 154 ): 155 row_number_window_alias = find_new_name(expression.named_selects, "_row_number") 156 157 distinct_cols = expression.args["distinct"].pop().args["on"].expressions 158 window = exp.Window(this=exp.RowNumber(), partition_by=distinct_cols) 159 160 order = expression.args.get("order") 161 if order: 162 window.set("order", order.pop()) 163 else: 164 window.set("order", exp.Order(expressions=[c.copy() for c in distinct_cols])) 165 166 expression.select(exp.alias_(window, row_number_window_alias), copy=False) 167 168 # We add aliases to the projections so that we can safely reference them in the outer query 169 new_selects = [] 170 taken_names = {row_number_window_alias} 171 for select in expression.selects[:-1]: 172 if select.is_star: 173 new_selects = [exp.Star()] 174 break 175 176 if not isinstance(select, exp.Alias): 177 alias = find_new_name(taken_names, select.output_name or "_col") 178 quoted = select.this.args.get("quoted") if isinstance(select, exp.Column) else None 179 select = select.replace(exp.alias_(select, alias, quoted=quoted)) 180 181 taken_names.add(select.output_name) 182 new_selects.append(select.args["alias"]) 183 184 return ( 185 exp.select(*new_selects, copy=False) 186 .from_(expression.subquery("_t", copy=False), copy=False) 187 .where(exp.column(row_number_window_alias).eq(1), copy=False) 188 ) 189 190 return expression 191 192 193def eliminate_qualify(expression: exp.Expr) -> exp.Expr: 194 """ 195 Convert SELECT statements that contain the QUALIFY clause into subqueries, filtered equivalently. 196 197 The idea behind this transformation can be seen in Snowflake's documentation for QUALIFY: 198 https://docs.snowflake.com/en/sql-reference/constructs/qualify 199 200 Some dialects don't support window functions in the WHERE clause, so we need to include them as 201 projections in the subquery, in order to refer to them in the outer filter using aliases. Also, 202 if a column is referenced in the QUALIFY clause but is not selected, we need to include it too, 203 otherwise we won't be able to refer to it in the outer query's WHERE clause. Finally, if a 204 newly aliased projection is referenced in the QUALIFY clause, it will be replaced by the 205 corresponding expression to avoid creating invalid column references. 206 """ 207 if isinstance(expression, exp.Select) and expression.args.get("qualify"): 208 taken = set(expression.named_selects) 209 for select in expression.selects: 210 if not select.alias_or_name: 211 alias = find_new_name(taken, "_c") 212 select.replace(exp.alias_(select, alias)) 213 taken.add(alias) 214 215 def _select_alias_or_name(select: exp.Expr) -> str | exp.Column: 216 alias_or_name = select.alias_or_name 217 identifier = select.args.get("alias") or select.this 218 if isinstance(identifier, exp.Identifier): 219 return exp.column(alias_or_name, quoted=identifier.args.get("quoted")) 220 return alias_or_name 221 222 outer_selects = exp.select(*list(map(_select_alias_or_name, expression.selects))) 223 qualify_filters = expression.args["qualify"].pop().this 224 expression_by_alias = { 225 select.alias: select.this 226 for select in expression.selects 227 if isinstance(select, exp.Alias) 228 } 229 230 select_candidates = exp.Window if expression.is_star else (exp.Window, exp.Column) 231 for select_candidate in list(qualify_filters.find_all(select_candidates)): 232 if isinstance(select_candidate, exp.Window): 233 if expression_by_alias: 234 for column in select_candidate.find_all(exp.Column): 235 expr = expression_by_alias.get(column.name) 236 if expr: 237 column.replace(expr) 238 239 alias = find_new_name(expression.named_selects, "_w") 240 expression.select(exp.alias_(select_candidate, alias), copy=False) 241 column = exp.column(alias) 242 243 if isinstance(select_candidate.parent, exp.Qualify): 244 qualify_filters = column 245 else: 246 select_candidate.replace(column) 247 elif select_candidate.name not in expression.named_selects: 248 expression.select(select_candidate.copy(), copy=False) 249 250 return outer_selects.from_(expression.subquery(alias="_t", copy=False), copy=False).where( 251 qualify_filters, copy=False 252 ) 253 254 return expression 255 256 257def remove_precision_parameterized_types(expression: exp.Expr) -> exp.Expr: 258 """ 259 Some dialects only allow the precision for parameterized types to be defined in the DDL and not in 260 other expressions. This transforms removes the precision from parameterized types in expressions. 261 """ 262 for node in expression.find_all(exp.DataType): 263 node.set( 264 "expressions", [e for e in node.expressions if not isinstance(e, exp.DataTypeParam)] 265 ) 266 267 return expression 268 269 270def unqualify_unnest(expression: exp.Expr) -> exp.Expr: 271 """Remove references to unnest table aliases, added by the optimizer's qualify_columns step.""" 272 from sqlglot.optimizer.scope import find_all_in_scope 273 274 if isinstance(expression, exp.Select): 275 unnest_aliases = { 276 unnest.alias 277 for unnest in find_all_in_scope(expression, exp.Unnest) 278 if isinstance(unnest.parent, (exp.From, exp.Join)) 279 } 280 if unnest_aliases: 281 for column in expression.find_all(exp.Column): 282 leftmost_part = column.parts[0] 283 if leftmost_part.arg_key != "this" and leftmost_part.this in unnest_aliases: 284 leftmost_part.pop() 285 286 return expression 287 288 289def unnest_to_explode( 290 expression: exp.Expr, 291 unnest_using_arrays_zip: bool = True, 292) -> exp.Expr: 293 """Convert cross join unnest into lateral view explode.""" 294 295 def _unnest_zip_exprs( 296 u: exp.Unnest, unnest_exprs: list[exp.Expr], has_multi_expr: bool 297 ) -> list[exp.Expr]: 298 if has_multi_expr: 299 if not unnest_using_arrays_zip: 300 raise UnsupportedError("Cannot transpile UNNEST with multiple input arrays") 301 302 # Use INLINE(ARRAYS_ZIP(...)) for multiple expressions 303 zip_exprs: list[exp.Expr] = [exp.Anonymous(this="ARRAYS_ZIP", expressions=unnest_exprs)] 304 u.set("expressions", zip_exprs) 305 return zip_exprs 306 return unnest_exprs 307 308 def _udtf_type(u: exp.Unnest, has_multi_expr: bool) -> type[exp.Func]: 309 if u.args.get("offset"): 310 return exp.Posexplode 311 return exp.Inline if has_multi_expr else exp.Explode 312 313 if isinstance(expression, exp.Select): 314 from_ = expression.args.get("from_") 315 316 if from_ and isinstance(from_.this, exp.Unnest): 317 unnest = from_.this 318 alias = unnest.args.get("alias") 319 exprs = unnest.expressions 320 has_multi_expr = len(exprs) > 1 321 this, *_ = _unnest_zip_exprs(unnest, exprs, has_multi_expr) 322 323 columns = alias.columns if alias else [] 324 offset = unnest.args.get("offset") 325 if offset: 326 columns.insert( 327 0, offset if isinstance(offset, exp.Identifier) else exp.to_identifier("pos") 328 ) 329 330 unnest.replace( 331 exp.Table( 332 this=_udtf_type(unnest, has_multi_expr)(this=this), 333 alias=exp.TableAlias(this=alias.this, columns=columns) if alias else None, 334 ) 335 ) 336 337 joins = expression.args.get("joins") or [] 338 for join in list(joins): 339 join_expr = join.this 340 341 is_lateral = isinstance(join_expr, exp.Lateral) 342 343 unnest = join_expr.this if is_lateral else join_expr 344 345 if isinstance(unnest, exp.Unnest): 346 if is_lateral: 347 alias = join_expr.args.get("alias") 348 else: 349 alias = unnest.args.get("alias") 350 exprs = unnest.expressions 351 # The number of unnest.expressions will be changed by _unnest_zip_exprs, we need to record it here 352 has_multi_expr = len(exprs) > 1 353 exprs = _unnest_zip_exprs(unnest, exprs, has_multi_expr) 354 355 joins.remove(join) 356 357 alias_cols = alias.columns if alias else [] 358 359 # # Handle UNNEST to LATERAL VIEW EXPLODE: Exception is raised when there are 0 or > 2 aliases 360 # Spark LATERAL VIEW EXPLODE requires single alias for array/struct and two for Map type column unlike unnest in trino/presto which can take an arbitrary amount. 361 # Refs: https://spark.apache.org/docs/latest/sql-ref-syntax-qry-select-lateral-view.html 362 363 if not has_multi_expr and len(alias_cols) not in (1, 2): 364 raise UnsupportedError( 365 "CROSS JOIN UNNEST to LATERAL VIEW EXPLODE transformation requires explicit column aliases" 366 ) 367 368 offset = unnest.args.get("offset") 369 if offset: 370 alias_cols.insert( 371 0, 372 offset if isinstance(offset, exp.Identifier) else exp.to_identifier("pos"), 373 ) 374 375 for e, column in zip(exprs, alias_cols): 376 expression.append( 377 "laterals", 378 exp.Lateral( 379 this=_udtf_type(unnest, has_multi_expr)(this=e), 380 view=True, 381 alias=exp.TableAlias( 382 this=alias.this, # type: ignore 383 columns=alias_cols, 384 ), 385 ), 386 ) 387 388 return expression 389 390 391def explode_projection_to_unnest( 392 index_offset: int = 0, 393) -> t.Callable[[exp.Expr], exp.Expr]: 394 """Convert explode/posexplode projections into unnests.""" 395 396 def _explode_projection_to_unnest(expression: exp.Expr) -> exp.Expr: 397 if isinstance(expression, exp.Select): 398 from sqlglot.optimizer.scope import Scope 399 400 taken_select_names = set(expression.named_selects) 401 taken_source_names = {name for name, _ in Scope(expression).references} 402 403 def new_name(names: set[str], name: str) -> str: 404 name = find_new_name(names, name) 405 names.add(name) 406 return name 407 408 arrays: list[exp.Condition] = [] 409 series_alias = new_name(taken_select_names, "pos") 410 series = exp.alias_( 411 exp.Unnest( 412 expressions=[exp.GenerateSeries(start=exp.Literal.number(index_offset))] 413 ), 414 new_name(taken_source_names, "_u"), 415 table=[series_alias], 416 ) 417 418 # we use list here because expression.selects is mutated inside the loop 419 for select in list(expression.selects): 420 explode = select.find(exp.Explode) 421 422 if explode: 423 pos_alias: t.Any = "" 424 explode_alias: t.Any = "" 425 426 if isinstance(select, exp.Alias): 427 explode_alias = select.args["alias"] 428 alias: exp.Expr = select 429 elif isinstance(select, exp.Aliases): 430 pos_alias = select.aliases[0] 431 explode_alias = select.aliases[1] 432 alias = select.replace(exp.alias_(select.this, "", copy=False)) 433 else: 434 alias = select.replace(exp.alias_(select, "")) 435 explode = alias.find(exp.Explode) 436 assert explode 437 438 is_posexplode = isinstance(explode, exp.Posexplode) 439 explode_arg = explode.this 440 441 if isinstance(explode, exp.ExplodeOuter): 442 bracket = explode_arg[0] 443 bracket.set("safe", True) 444 bracket.set("offset", True) 445 explode_arg = exp.func( 446 "IF", 447 exp.func( 448 "ARRAY_SIZE", exp.func("COALESCE", explode_arg, exp.Array()) 449 ).eq(0), 450 exp.array(bracket, copy=False), 451 explode_arg, 452 ) 453 454 # This ensures that we won't use [POS]EXPLODE's argument as a new selection 455 if isinstance(explode_arg, exp.Column): 456 taken_select_names.add(explode_arg.output_name) 457 458 unnest_source_alias = new_name(taken_source_names, "_u") 459 460 if not explode_alias: 461 explode_alias = new_name(taken_select_names, "col") 462 463 if is_posexplode: 464 pos_alias = new_name(taken_select_names, "pos") 465 466 if not pos_alias: 467 pos_alias = new_name(taken_select_names, "pos") 468 469 alias.set("alias", exp.to_identifier(explode_alias)) 470 471 series_table_alias = series.args["alias"].this 472 column = exp.If( 473 this=exp.column(series_alias, table=series_table_alias).eq( 474 exp.column(pos_alias, table=unnest_source_alias) 475 ), 476 true=exp.column(explode_alias, table=unnest_source_alias), 477 ) 478 479 explode.replace(column) 480 481 if is_posexplode: 482 expressions = expression.expressions 483 expressions.insert( 484 expressions.index(alias) + 1, 485 exp.If( 486 this=exp.column(series_alias, table=series_table_alias).eq( 487 exp.column(pos_alias, table=unnest_source_alias) 488 ), 489 true=exp.column(pos_alias, table=unnest_source_alias), 490 ).as_(pos_alias), 491 ) 492 expression.set("expressions", expressions) 493 494 if not arrays: 495 if expression.args.get("from_"): 496 expression.join(series, copy=False, join_type="CROSS") 497 else: 498 expression.from_(series, copy=False) 499 500 size: exp.Condition = exp.ArraySize(this=explode_arg.copy()) 501 arrays.append(size) 502 503 # trino doesn't support left join unnest with on conditions 504 # if it did, this would be much simpler 505 expression.join( 506 exp.alias_( 507 exp.Unnest( 508 expressions=[explode_arg.copy()], 509 offset=exp.to_identifier(pos_alias), 510 ), 511 unnest_source_alias, 512 table=[explode_alias], 513 ), 514 join_type="CROSS", 515 copy=False, 516 ) 517 518 if index_offset != 1: 519 size = size - 1 520 521 expression.where( 522 exp.column(series_alias, table=series_table_alias) 523 .eq(exp.column(pos_alias, table=unnest_source_alias)) 524 .or_( 525 (exp.column(series_alias, table=series_table_alias) > size).and_( 526 exp.column(pos_alias, table=unnest_source_alias).eq(size) 527 ) 528 ), 529 copy=False, 530 ) 531 532 if arrays: 533 end: exp.Condition = exp.Greatest(this=arrays[0], expressions=arrays[1:]) 534 535 if index_offset != 1: 536 end = end - (1 - index_offset) 537 series.expressions[0].set("end", end) 538 539 return expression 540 541 return _explode_projection_to_unnest 542 543 544def add_within_group_for_percentiles(expression: exp.Expr) -> exp.Expr: 545 """Transforms percentiles by adding a WITHIN GROUP clause to them.""" 546 if ( 547 isinstance(expression, exp.PERCENTILES) 548 and not isinstance(expression.parent, exp.WithinGroup) 549 and expression.expression 550 ): 551 column = expression.this.pop() 552 expression.set("this", expression.expression.pop()) 553 order = exp.Order(expressions=[exp.Ordered(this=column)]) 554 expression = exp.WithinGroup(this=expression, expression=order) 555 556 return expression 557 558 559def remove_within_group_for_percentiles(expression: exp.Expr) -> exp.Expr: 560 """Transforms percentiles by getting rid of their corresponding WITHIN GROUP clause.""" 561 if ( 562 isinstance(expression, exp.WithinGroup) 563 and isinstance(expression.this, exp.PERCENTILES) 564 and isinstance(expression.expression, exp.Order) 565 ): 566 quantile = expression.this.this 567 input_value = t.cast(exp.Ordered, expression.find(exp.Ordered)).this 568 return expression.replace(exp.ApproxQuantile(this=input_value, quantile=quantile)) 569 570 return expression 571 572 573def add_recursive_cte_column_names(expression: exp.Expr) -> exp.Expr: 574 """Uses projection output names in recursive CTE definitions to define the CTEs' columns.""" 575 if isinstance(expression, exp.With) and expression.recursive: 576 next_name = name_sequence("_c_") 577 578 for cte in expression.expressions: 579 if not cte.args["alias"].columns: 580 query = cte.this 581 if isinstance(query, exp.SetOperation): 582 query = query.this 583 584 cte.args["alias"].set( 585 "columns", 586 [exp.to_identifier(s.alias_or_name or next_name()) for s in query.selects], 587 ) 588 589 return expression 590 591 592def epoch_cast_to_ts(expression: exp.Expr) -> exp.Expr: 593 """Replace 'epoch' in casts by the equivalent date literal.""" 594 if ( 595 isinstance(expression, (exp.Cast, exp.TryCast)) 596 and expression.name.lower() == "epoch" 597 and expression.to.this in exp.DataType.TEMPORAL_TYPES 598 ): 599 expression.this.replace(exp.Literal.string("1970-01-01 00:00:00")) 600 601 return expression 602 603 604def eliminate_semi_and_anti_joins(expression: exp.Expr) -> exp.Expr: 605 """Convert SEMI and ANTI joins into equivalent forms that use EXIST instead.""" 606 if isinstance(expression, exp.Select): 607 for join in list(expression.args.get("joins") or []): 608 on = join.args.get("on") 609 if on and join.kind in ("SEMI", "ANTI"): 610 subquery = exp.select("1").from_(join.this).where(on) 611 exists: exp.Exists | exp.Not = exp.Exists(this=subquery) 612 if join.kind == "ANTI": 613 exists = exists.not_(copy=False) 614 615 join.pop() 616 expression.where(exists, copy=False) 617 618 return expression 619 620 621def eliminate_full_outer_join(expression: exp.Expr) -> exp.Expr: 622 """ 623 Converts a query with a FULL OUTER join to a union of identical queries that 624 use LEFT/RIGHT OUTER joins instead. This transformation currently only works 625 for queries that have a single FULL OUTER join. 626 """ 627 if isinstance(expression, exp.Select): 628 full_outer_joins = [ 629 (index, join) 630 for index, join in enumerate(expression.args.get("joins") or []) 631 if join.side == "FULL" 632 ] 633 634 if len(full_outer_joins) == 1: 635 expression_copy = expression.copy() 636 expression.set("limit", None) 637 index, full_outer_join = full_outer_joins[0] 638 639 tables = (expression.args["from_"].alias_or_name, full_outer_join.alias_or_name) 640 join_conditions = full_outer_join.args.get("on") or exp.and_( 641 *[ 642 exp.column(col, tables[0]).eq(exp.column(col, tables[1])) 643 for col in full_outer_join.args.get("using") 644 ] 645 ) 646 647 full_outer_join.set("side", "left") 648 anti_join_clause = ( 649 exp.select("1").from_(expression.args["from_"]).where(join_conditions) 650 ) 651 expression_copy.args["joins"][index].set("side", "right") 652 expression_copy = expression_copy.where(exp.Exists(this=anti_join_clause).not_()) 653 expression_copy.set("with_", None) # remove CTEs from RIGHT side 654 expression.set("order", None) # remove order by from LEFT side 655 656 return exp.union(expression, expression_copy, copy=False, distinct=False) 657 658 return expression 659 660 661def move_ctes_to_top_level(expression: E) -> E: 662 """ 663 Some dialects (e.g. Hive, T-SQL, Spark prior to version 3) only allow CTEs to be 664 defined at the top-level, so for example queries like: 665 666 SELECT * FROM (WITH t(c) AS (SELECT 1) SELECT * FROM t) AS subq 667 668 are invalid in those dialects. This transformation can be used to ensure all CTEs are 669 moved to the top level so that the final SQL code is valid from a syntax standpoint. 670 671 TODO: handle name clashes whilst moving CTEs (it can get quite tricky & costly). 672 """ 673 top_level_with = expression.args.get("with_") 674 for inner_with in expression.find_all(exp.With): 675 if inner_with.parent is expression: 676 continue 677 678 if not top_level_with: 679 top_level_with = inner_with.pop() 680 expression.set("with_", top_level_with) 681 else: 682 if inner_with.recursive: 683 top_level_with.set("recursive", True) 684 685 parent_cte = inner_with.find_ancestor(exp.CTE) 686 inner_with.pop() 687 688 if parent_cte: 689 i = top_level_with.expressions.index(parent_cte) 690 top_level_with.expressions[i:i] = inner_with.expressions 691 top_level_with.set("expressions", top_level_with.expressions) 692 else: 693 top_level_with.set( 694 "expressions", top_level_with.expressions + inner_with.expressions 695 ) 696 697 return expression 698 699 700def ensure_bools(expression: exp.Expr) -> exp.Expr: 701 """Converts numeric values used in conditions into explicit boolean expressions.""" 702 from sqlglot.optimizer.canonicalize import ensure_bools 703 704 def _ensure_bool(node: exp.Expr) -> None: 705 if ( 706 node.is_number 707 or ( 708 not isinstance(node, exp.SubqueryPredicate) 709 and node.is_type(exp.DType.UNKNOWN, *exp.DataType.NUMERIC_TYPES) 710 ) 711 or (isinstance(node, exp.Column) and not node.type) 712 ): 713 node.replace(node.neq(0)) 714 715 for node in expression.walk(): 716 ensure_bools(node, _ensure_bool) 717 718 return expression 719 720 721def unqualify_columns(expression: exp.Expr) -> exp.Expr: 722 for column in expression.find_all(exp.Column): 723 # We only wanna pop off the table, db, catalog args 724 for part in column.parts[:-1]: 725 part.pop() 726 727 return expression 728 729 730def remove_unique_constraints(expression: exp.Expr) -> exp.Expr: 731 assert isinstance(expression, exp.Create) 732 for constraint in expression.find_all(exp.UniqueColumnConstraint): 733 if constraint.parent: 734 constraint.parent.pop() 735 736 return expression 737 738 739def ctas_with_tmp_tables_to_create_tmp_view( 740 expression: exp.Expr, 741 tmp_storage_provider: t.Callable[[exp.Expr], exp.Expr] = lambda e: e, 742) -> exp.Expr: 743 assert isinstance(expression, exp.Create) 744 properties = expression.args.get("properties") 745 temporary = any( 746 isinstance(prop, exp.TemporaryProperty) 747 for prop in (properties.expressions if properties else []) 748 ) 749 750 # CTAS with temp tables map to CREATE TEMPORARY VIEW 751 if expression.kind == "TABLE" and temporary: 752 if expression.expression: 753 return exp.Create( 754 kind="TEMPORARY VIEW", 755 this=expression.this, 756 expression=expression.expression, 757 ) 758 return tmp_storage_provider(expression) 759 760 return expression 761 762 763def move_schema_columns_to_partitioned_by(expression: exp.Expr) -> exp.Expr: 764 """ 765 In Hive, the PARTITIONED BY property acts as an extension of a table's schema. When the 766 PARTITIONED BY value is an array of column names, they are transformed into a schema. 767 The corresponding columns are removed from the create statement. 768 """ 769 assert isinstance(expression, exp.Create) 770 has_schema = isinstance(expression.this, exp.Schema) 771 is_partitionable = expression.kind in {"TABLE", "VIEW"} 772 773 if has_schema and is_partitionable: 774 prop = expression.find(exp.PartitionedByProperty) 775 if prop and prop.this and not isinstance(prop.this, exp.Schema): 776 schema = expression.this 777 columns = {v.name.upper() for v in prop.this.expressions} 778 partitions = [col for col in schema.expressions if col.name.upper() in columns] 779 schema.set("expressions", [e for e in schema.expressions if e not in partitions]) 780 prop.replace(exp.PartitionedByProperty(this=exp.Schema(expressions=partitions))) 781 expression.set("this", schema) 782 783 return expression 784 785 786def move_partitioned_by_to_schema_columns(expression: exp.Expr) -> exp.Expr: 787 """ 788 Spark 3 supports both "HIVEFORMAT" and "DATASOURCE" formats for CREATE TABLE. 789 790 Currently, SQLGlot uses the DATASOURCE format for Spark 3. 791 """ 792 assert isinstance(expression, exp.Create) 793 prop = expression.find(exp.PartitionedByProperty) 794 if ( 795 prop 796 and prop.this 797 and isinstance(prop.this, exp.Schema) 798 and all(isinstance(e, exp.ColumnDef) and e.kind for e in prop.this.expressions) 799 ): 800 prop_this = exp.Tuple( 801 expressions=[exp.to_identifier(e.this) for e in prop.this.expressions] 802 ) 803 schema = expression.this 804 for e in prop.this.expressions: 805 schema.append("expressions", e) 806 prop.set("this", prop_this) 807 808 return expression 809 810 811def struct_kv_to_alias(expression: exp.Expr) -> exp.Expr: 812 """Converts struct arguments to aliases, e.g. STRUCT(1 AS y).""" 813 if isinstance(expression, exp.Struct): 814 expression.set( 815 "expressions", 816 [ 817 exp.alias_(e.expression, e.this) if isinstance(e, exp.PropertyEQ) else e 818 for e in expression.expressions 819 ], 820 ) 821 822 return expression 823 824 825def eliminate_join_marks(expression: exp.Expr) -> exp.Expr: 826 """https://docs.oracle.com/cd/B19306_01/server.102/b14200/queries006.htm#sthref3178 827 828 1. You cannot specify the (+) operator in a query block that also contains FROM clause join syntax. 829 830 2. The (+) operator can appear only in the WHERE clause or, in the context of left-correlation (that is, when specifying the TABLE clause) in the FROM clause, and can be applied only to a column of a table or view. 831 832 The (+) operator does not produce an outer join if you specify one table in the outer query and the other table in an inner query. 833 834 You cannot use the (+) operator to outer-join a table to itself, although self joins are valid. 835 836 The (+) operator can be applied only to a column, not to an arbitrary expression. However, an arbitrary expression can contain one or more columns marked with the (+) operator. 837 838 A WHERE condition containing the (+) operator cannot be combined with another condition using the OR logical operator. 839 840 A WHERE condition cannot use the IN comparison condition to compare a column marked with the (+) operator with an expression. 841 842 A WHERE condition cannot compare any column marked with the (+) operator with a subquery. 843 844 -- example with WHERE 845 SELECT d.department_name, sum(e.salary) as total_salary 846 FROM departments d, employees e 847 WHERE e.department_id(+) = d.department_id 848 group by department_name 849 850 -- example of left correlation in select 851 SELECT d.department_name, ( 852 SELECT SUM(e.salary) 853 FROM employees e 854 WHERE e.department_id(+) = d.department_id) AS total_salary 855 FROM departments d; 856 857 -- example of left correlation in from 858 SELECT d.department_name, t.total_salary 859 FROM departments d, ( 860 SELECT SUM(e.salary) AS total_salary 861 FROM employees e 862 WHERE e.department_id(+) = d.department_id 863 ) t 864 """ 865 866 from sqlglot.optimizer.scope import traverse_scope 867 from sqlglot.optimizer.normalize import normalize, normalized 868 from collections import defaultdict 869 870 # we go in reverse to check the main query for left correlation 871 for scope in reversed(traverse_scope(expression)): 872 query = scope.expression 873 874 where = query.args.get("where") 875 joins = query.args.get("joins", []) 876 877 if not where or not any(c.args.get("join_mark") for c in where.find_all(exp.Column)): 878 continue 879 880 # knockout: we do not support left correlation (see point 2) 881 assert not scope.is_correlated_subquery, "Correlated queries are not supported" 882 883 # make sure we have AND of ORs to have clear join terms 884 where = normalize(where.this) 885 assert normalized(where), "Cannot normalize JOIN predicates" 886 887 joins_ons = defaultdict(list) # dict of {name: list of join AND conditions} 888 for cond in [where] if not isinstance(where, exp.And) else where.flatten(): 889 join_cols = [col for col in cond.find_all(exp.Column) if col.args.get("join_mark")] 890 891 left_join_table = set(col.table for col in join_cols) 892 if not left_join_table: 893 continue 894 895 assert not (len(left_join_table) > 1), ( 896 "Cannot combine JOIN predicates from different tables" 897 ) 898 899 for col in join_cols: 900 col.set("join_mark", False) 901 902 joins_ons[left_join_table.pop()].append(cond) 903 904 old_joins = {join.alias_or_name: join for join in joins} 905 new_joins = {} 906 query_from = query.args["from_"] 907 908 for table, predicates in joins_ons.items(): 909 join_what = old_joins.get(table, query_from).this.copy() 910 new_joins[join_what.alias_or_name] = exp.Join( 911 this=join_what, on=exp.and_(*predicates), kind="LEFT" 912 ) 913 914 for p in predicates: 915 while isinstance(p.parent, exp.Paren): 916 p.parent.replace(p) 917 918 parent = p.parent 919 p.pop() 920 if isinstance(parent, exp.Binary): 921 left = parent.args.get("this") 922 parent.replace(parent.right if left is None else left) 923 elif isinstance(parent, exp.Where): 924 parent.pop() 925 926 if query_from.alias_or_name in new_joins: 927 only_old_joins = old_joins.keys() - new_joins.keys() 928 assert len(only_old_joins) >= 1, ( 929 "Cannot determine which table to use in the new FROM clause" 930 ) 931 932 new_from_name = list(only_old_joins)[0] 933 query.set("from_", exp.From(this=old_joins[new_from_name].this)) 934 935 if new_joins: 936 for n, j in old_joins.items(): # preserve any other joins 937 if n not in new_joins and n != query.args["from_"].name: 938 if not j.kind: 939 j.set("kind", "CROSS") 940 new_joins[n] = j 941 query.set("joins", list(new_joins.values())) 942 943 return expression 944 945 946def any_to_exists(expression: exp.Expr) -> exp.Expr: 947 """ 948 Transform ANY operator to Spark's EXISTS 949 950 For example, 951 - Postgres: SELECT * FROM tbl WHERE 5 > ANY(tbl.col) 952 - Spark: SELECT * FROM tbl WHERE EXISTS(tbl.col, x -> x < 5) 953 954 Both ANY and EXISTS accept queries but currently only array expressions are supported for this 955 transformation 956 """ 957 if isinstance(expression, exp.Select): 958 for any_expr in expression.find_all(exp.Any): 959 this = any_expr.this 960 if isinstance(this, exp.Query) or isinstance(any_expr.parent, (exp.Like, exp.ILike)): 961 continue 962 963 binop = any_expr.parent 964 if isinstance(binop, exp.Binary): 965 lambda_arg = exp.to_identifier("x") 966 any_expr.replace(lambda_arg) 967 lambda_expr = exp.Lambda(this=binop.copy(), expressions=[lambda_arg]) 968 binop.replace(exp.Exists(this=this.unnest(), expression=lambda_expr)) 969 970 return expression 971 972 973def eliminate_window_clause(expression: exp.Expr) -> exp.Expr: 974 """Eliminates the `WINDOW` query clause by inling each named window.""" 975 if isinstance(expression, exp.Select) and expression.args.get("windows"): 976 from sqlglot.optimizer.scope import find_all_in_scope 977 978 windows = expression.args["windows"] 979 expression.set("windows", None) 980 981 window_expression: dict[str, exp.Expr] = {} 982 983 def _inline_inherited_window(window: exp.Expr) -> None: 984 inherited_window = window_expression.get(window.alias.lower()) 985 if not inherited_window: 986 return 987 988 window.set("alias", None) 989 for key in ("partition_by", "order", "spec"): 990 arg = inherited_window.args.get(key) 991 if arg: 992 window.set(key, arg.copy()) 993 994 for window in windows: 995 _inline_inherited_window(window) 996 window_expression[window.name.lower()] = window 997 998 for window in find_all_in_scope(expression, exp.Window): 999 _inline_inherited_window(window) 1000 1001 return expression 1002 1003 1004def inherit_struct_field_names(expression: exp.Expr) -> exp.Expr: 1005 """ 1006 Inherit field names from the first struct in an array. 1007 1008 BigQuery supports implicitly inheriting names from the first STRUCT in an array: 1009 1010 Example: 1011 ARRAY[ 1012 STRUCT('Alice' AS name, 85 AS score), -- defines names 1013 STRUCT('Bob', 92), -- inherits names 1014 STRUCT('Diana', 95) -- inherits names 1015 ] 1016 1017 This transformation makes the field names explicit on all structs by adding 1018 PropertyEQ nodes, in order to facilitate transpilation to other dialects. 1019 1020 Args: 1021 expression: The expression tree to transform 1022 1023 Returns: 1024 The modified expression with field names inherited in all structs 1025 """ 1026 if ( 1027 isinstance(expression, exp.Array) 1028 and expression.args.get("struct_name_inheritance") 1029 and isinstance(first_item := seq_get(expression.expressions, 0), exp.Struct) 1030 and all(isinstance(fld, exp.PropertyEQ) for fld in first_item.expressions) 1031 ): 1032 field_names = [fld.this for fld in first_item.expressions] 1033 1034 # Apply field names to subsequent structs that don't have them 1035 for struct in expression.expressions[1:]: 1036 if not isinstance(struct, exp.Struct) or len(struct.expressions) != len(field_names): 1037 continue 1038 1039 # Convert unnamed expressions to PropertyEQ with inherited names 1040 new_expressions = [] 1041 for i, expr in enumerate(struct.expressions): 1042 if not isinstance(expr, exp.PropertyEQ): 1043 # Create PropertyEQ: field_name := value, preserving the type from the inner expression 1044 property_eq = exp.PropertyEQ( 1045 this=field_names[i].copy(), 1046 expression=expr, 1047 ) 1048 property_eq.type = expr.type 1049 new_expressions.append(property_eq) 1050 else: 1051 new_expressions.append(expr) 1052 1053 struct.set("expressions", new_expressions) 1054 1055 return expression
def
preprocess( transforms: list[typing.Callable[[sqlglot.expressions.core.Expr], sqlglot.expressions.core.Expr]], generator: Optional[Callable[[sqlglot.generator.Generator, sqlglot.expressions.core.Expr], str]] = None) -> Callable[[sqlglot.generator.Generator, sqlglot.expressions.core.Expr], str]:
16def preprocess( 17 transforms: list[t.Callable[[exp.Expr], exp.Expr]], 18 generator: t.Callable[[Generator, exp.Expr], str] | None = None, 19) -> t.Callable[[Generator, exp.Expr], str]: 20 """ 21 Creates a new transform by chaining a sequence of transformations and converts the resulting 22 expression to SQL, using either the "_sql" method corresponding to the resulting expression, 23 or the appropriate `Generator.TRANSFORMS` function (when applicable -- see below). 24 25 Args: 26 transforms: sequence of transform functions. These will be called in order. 27 28 Returns: 29 Function that can be used as a generator transform. 30 """ 31 32 def _to_sql(self, expression: exp.Expr) -> str: 33 expression_type = type(expression) 34 35 try: 36 expression = transforms[0](expression) 37 for transform in transforms[1:]: 38 expression = transform(expression) 39 except UnsupportedError as unsupported_error: 40 self.unsupported(str(unsupported_error)) 41 42 if generator: 43 return generator(self, expression) 44 45 _sql_handler = getattr(self, expression.key + "_sql", None) 46 if _sql_handler: 47 return _sql_handler(expression) 48 49 transforms_handler = self.TRANSFORMS.get(type(expression)) 50 if transforms_handler: 51 if expression_type is type(expression): 52 if isinstance(expression, exp.Func): 53 return self.function_fallback_sql(expression) 54 55 # Ensures we don't enter an infinite loop. This can happen when the original expression 56 # has the same type as the final expression and there's no _sql method available for it, 57 # because then it'd re-enter _to_sql. 58 raise ValueError( 59 f"Expr type {expression.__class__.__name__} requires a _sql method in order to be transformed." 60 ) 61 62 return transforms_handler(self, expression) 63 64 raise ValueError(f"Unsupported expression type {expression.__class__.__name__}.") 65 66 return _to_sql
Creates a new transform by chaining a sequence of transformations and converts the resulting
expression to SQL, using either the "_sql" method corresponding to the resulting expression,
or the appropriate Generator.TRANSFORMS function (when applicable -- see below).
Arguments:
- transforms: sequence of transform functions. These will be called in order.
Returns:
Function that can be used as a generator transform.
def
unnest_generate_date_array_using_recursive_cte( expression: sqlglot.expressions.core.Expr) -> sqlglot.expressions.core.Expr:
69def unnest_generate_date_array_using_recursive_cte(expression: exp.Expr) -> exp.Expr: 70 if isinstance(expression, exp.Select): 71 count = 0 72 recursive_ctes = [] 73 74 for unnest in expression.find_all(exp.Unnest): 75 if ( 76 not isinstance(unnest.parent, (exp.From, exp.Join)) 77 or len(unnest.expressions) != 1 78 or not isinstance(unnest.expressions[0], exp.GenerateDateArray) 79 ): 80 continue 81 82 generate_date_array = unnest.expressions[0] 83 start = generate_date_array.args.get("start") 84 end = generate_date_array.args.get("end") 85 step = generate_date_array.args.get("step") 86 87 if not start or not end or not isinstance(step, exp.Interval): 88 continue 89 90 alias = unnest.args.get("alias") 91 column_name = alias.columns[0] if isinstance(alias, exp.TableAlias) else "date_value" 92 93 start = exp.cast(start, "date") 94 date_add = exp.func( 95 "date_add", column_name, exp.Literal.number(step.name), step.args.get("unit") 96 ) 97 cast_date_add = exp.cast(date_add, "date") 98 99 cte_name = "_generated_dates" + (f"_{count}" if count else "") 100 101 base_query = exp.select(start.as_(column_name)) 102 recursive_query = ( 103 exp.select(cast_date_add) 104 .from_(cte_name) 105 .where(cast_date_add <= exp.cast(end, "date")) 106 ) 107 cte_query = base_query.union(recursive_query, distinct=False) 108 109 generate_dates_query = exp.select(column_name).from_(cte_name) 110 unnest.replace(generate_dates_query.subquery(cte_name)) 111 112 recursive_ctes.append( 113 exp.alias_(exp.CTE(this=cte_query), cte_name, table=[column_name]) 114 ) 115 count += 1 116 117 if recursive_ctes: 118 with_expression = expression.args.get("with_") or exp.With() 119 with_expression.set("recursive", True) 120 with_expression.set("expressions", [*recursive_ctes, *with_expression.expressions]) 121 expression.set("with_", with_expression) 122 123 return expression
def
unnest_generate_series( expression: sqlglot.expressions.core.Expr) -> sqlglot.expressions.core.Expr:
126def unnest_generate_series(expression: exp.Expr) -> exp.Expr: 127 """Unnests GENERATE_SERIES or SEQUENCE table references.""" 128 this = expression.this 129 if isinstance(expression, exp.Table) and isinstance(this, exp.GenerateSeries): 130 unnest = exp.Unnest(expressions=[this]) 131 if expression.alias: 132 return exp.alias_(unnest, alias="_u", table=[expression.alias], copy=False) 133 134 return unnest 135 136 return expression
Unnests GENERATE_SERIES or SEQUENCE table references.
def
eliminate_distinct_on( expression: sqlglot.expressions.core.Expr) -> sqlglot.expressions.core.Expr:
139def eliminate_distinct_on(expression: exp.Expr) -> exp.Expr: 140 """ 141 Convert SELECT DISTINCT ON statements to a subquery with a window function. 142 143 This is useful for dialects that don't support SELECT DISTINCT ON but support window functions. 144 145 Args: 146 expression: the expression that will be transformed. 147 148 Returns: 149 The transformed expression. 150 """ 151 if ( 152 isinstance(expression, exp.Select) 153 and expression.args.get("distinct") 154 and isinstance(expression.args["distinct"].args.get("on"), exp.Tuple) 155 ): 156 row_number_window_alias = find_new_name(expression.named_selects, "_row_number") 157 158 distinct_cols = expression.args["distinct"].pop().args["on"].expressions 159 window = exp.Window(this=exp.RowNumber(), partition_by=distinct_cols) 160 161 order = expression.args.get("order") 162 if order: 163 window.set("order", order.pop()) 164 else: 165 window.set("order", exp.Order(expressions=[c.copy() for c in distinct_cols])) 166 167 expression.select(exp.alias_(window, row_number_window_alias), copy=False) 168 169 # We add aliases to the projections so that we can safely reference them in the outer query 170 new_selects = [] 171 taken_names = {row_number_window_alias} 172 for select in expression.selects[:-1]: 173 if select.is_star: 174 new_selects = [exp.Star()] 175 break 176 177 if not isinstance(select, exp.Alias): 178 alias = find_new_name(taken_names, select.output_name or "_col") 179 quoted = select.this.args.get("quoted") if isinstance(select, exp.Column) else None 180 select = select.replace(exp.alias_(select, alias, quoted=quoted)) 181 182 taken_names.add(select.output_name) 183 new_selects.append(select.args["alias"]) 184 185 return ( 186 exp.select(*new_selects, copy=False) 187 .from_(expression.subquery("_t", copy=False), copy=False) 188 .where(exp.column(row_number_window_alias).eq(1), copy=False) 189 ) 190 191 return expression
Convert SELECT DISTINCT ON statements to a subquery with a window function.
This is useful for dialects that don't support SELECT DISTINCT ON but support window functions.
Arguments:
- expression: the expression that will be transformed.
Returns:
The transformed expression.
194def eliminate_qualify(expression: exp.Expr) -> exp.Expr: 195 """ 196 Convert SELECT statements that contain the QUALIFY clause into subqueries, filtered equivalently. 197 198 The idea behind this transformation can be seen in Snowflake's documentation for QUALIFY: 199 https://docs.snowflake.com/en/sql-reference/constructs/qualify 200 201 Some dialects don't support window functions in the WHERE clause, so we need to include them as 202 projections in the subquery, in order to refer to them in the outer filter using aliases. Also, 203 if a column is referenced in the QUALIFY clause but is not selected, we need to include it too, 204 otherwise we won't be able to refer to it in the outer query's WHERE clause. Finally, if a 205 newly aliased projection is referenced in the QUALIFY clause, it will be replaced by the 206 corresponding expression to avoid creating invalid column references. 207 """ 208 if isinstance(expression, exp.Select) and expression.args.get("qualify"): 209 taken = set(expression.named_selects) 210 for select in expression.selects: 211 if not select.alias_or_name: 212 alias = find_new_name(taken, "_c") 213 select.replace(exp.alias_(select, alias)) 214 taken.add(alias) 215 216 def _select_alias_or_name(select: exp.Expr) -> str | exp.Column: 217 alias_or_name = select.alias_or_name 218 identifier = select.args.get("alias") or select.this 219 if isinstance(identifier, exp.Identifier): 220 return exp.column(alias_or_name, quoted=identifier.args.get("quoted")) 221 return alias_or_name 222 223 outer_selects = exp.select(*list(map(_select_alias_or_name, expression.selects))) 224 qualify_filters = expression.args["qualify"].pop().this 225 expression_by_alias = { 226 select.alias: select.this 227 for select in expression.selects 228 if isinstance(select, exp.Alias) 229 } 230 231 select_candidates = exp.Window if expression.is_star else (exp.Window, exp.Column) 232 for select_candidate in list(qualify_filters.find_all(select_candidates)): 233 if isinstance(select_candidate, exp.Window): 234 if expression_by_alias: 235 for column in select_candidate.find_all(exp.Column): 236 expr = expression_by_alias.get(column.name) 237 if expr: 238 column.replace(expr) 239 240 alias = find_new_name(expression.named_selects, "_w") 241 expression.select(exp.alias_(select_candidate, alias), copy=False) 242 column = exp.column(alias) 243 244 if isinstance(select_candidate.parent, exp.Qualify): 245 qualify_filters = column 246 else: 247 select_candidate.replace(column) 248 elif select_candidate.name not in expression.named_selects: 249 expression.select(select_candidate.copy(), copy=False) 250 251 return outer_selects.from_(expression.subquery(alias="_t", copy=False), copy=False).where( 252 qualify_filters, copy=False 253 ) 254 255 return expression
Convert SELECT statements that contain the QUALIFY clause into subqueries, filtered equivalently.
The idea behind this transformation can be seen in Snowflake's documentation for QUALIFY: https://docs.snowflake.com/en/sql-reference/constructs/qualify
Some dialects don't support window functions in the WHERE clause, so we need to include them as projections in the subquery, in order to refer to them in the outer filter using aliases. Also, if a column is referenced in the QUALIFY clause but is not selected, we need to include it too, otherwise we won't be able to refer to it in the outer query's WHERE clause. Finally, if a newly aliased projection is referenced in the QUALIFY clause, it will be replaced by the corresponding expression to avoid creating invalid column references.
def
remove_precision_parameterized_types( expression: sqlglot.expressions.core.Expr) -> sqlglot.expressions.core.Expr:
258def remove_precision_parameterized_types(expression: exp.Expr) -> exp.Expr: 259 """ 260 Some dialects only allow the precision for parameterized types to be defined in the DDL and not in 261 other expressions. This transforms removes the precision from parameterized types in expressions. 262 """ 263 for node in expression.find_all(exp.DataType): 264 node.set( 265 "expressions", [e for e in node.expressions if not isinstance(e, exp.DataTypeParam)] 266 ) 267 268 return expression
Some dialects only allow the precision for parameterized types to be defined in the DDL and not in other expressions. This transforms removes the precision from parameterized types in expressions.
271def unqualify_unnest(expression: exp.Expr) -> exp.Expr: 272 """Remove references to unnest table aliases, added by the optimizer's qualify_columns step.""" 273 from sqlglot.optimizer.scope import find_all_in_scope 274 275 if isinstance(expression, exp.Select): 276 unnest_aliases = { 277 unnest.alias 278 for unnest in find_all_in_scope(expression, exp.Unnest) 279 if isinstance(unnest.parent, (exp.From, exp.Join)) 280 } 281 if unnest_aliases: 282 for column in expression.find_all(exp.Column): 283 leftmost_part = column.parts[0] 284 if leftmost_part.arg_key != "this" and leftmost_part.this in unnest_aliases: 285 leftmost_part.pop() 286 287 return expression
Remove references to unnest table aliases, added by the optimizer's qualify_columns step.
def
unnest_to_explode( expression: sqlglot.expressions.core.Expr, unnest_using_arrays_zip: bool = True) -> sqlglot.expressions.core.Expr:
290def unnest_to_explode( 291 expression: exp.Expr, 292 unnest_using_arrays_zip: bool = True, 293) -> exp.Expr: 294 """Convert cross join unnest into lateral view explode.""" 295 296 def _unnest_zip_exprs( 297 u: exp.Unnest, unnest_exprs: list[exp.Expr], has_multi_expr: bool 298 ) -> list[exp.Expr]: 299 if has_multi_expr: 300 if not unnest_using_arrays_zip: 301 raise UnsupportedError("Cannot transpile UNNEST with multiple input arrays") 302 303 # Use INLINE(ARRAYS_ZIP(...)) for multiple expressions 304 zip_exprs: list[exp.Expr] = [exp.Anonymous(this="ARRAYS_ZIP", expressions=unnest_exprs)] 305 u.set("expressions", zip_exprs) 306 return zip_exprs 307 return unnest_exprs 308 309 def _udtf_type(u: exp.Unnest, has_multi_expr: bool) -> type[exp.Func]: 310 if u.args.get("offset"): 311 return exp.Posexplode 312 return exp.Inline if has_multi_expr else exp.Explode 313 314 if isinstance(expression, exp.Select): 315 from_ = expression.args.get("from_") 316 317 if from_ and isinstance(from_.this, exp.Unnest): 318 unnest = from_.this 319 alias = unnest.args.get("alias") 320 exprs = unnest.expressions 321 has_multi_expr = len(exprs) > 1 322 this, *_ = _unnest_zip_exprs(unnest, exprs, has_multi_expr) 323 324 columns = alias.columns if alias else [] 325 offset = unnest.args.get("offset") 326 if offset: 327 columns.insert( 328 0, offset if isinstance(offset, exp.Identifier) else exp.to_identifier("pos") 329 ) 330 331 unnest.replace( 332 exp.Table( 333 this=_udtf_type(unnest, has_multi_expr)(this=this), 334 alias=exp.TableAlias(this=alias.this, columns=columns) if alias else None, 335 ) 336 ) 337 338 joins = expression.args.get("joins") or [] 339 for join in list(joins): 340 join_expr = join.this 341 342 is_lateral = isinstance(join_expr, exp.Lateral) 343 344 unnest = join_expr.this if is_lateral else join_expr 345 346 if isinstance(unnest, exp.Unnest): 347 if is_lateral: 348 alias = join_expr.args.get("alias") 349 else: 350 alias = unnest.args.get("alias") 351 exprs = unnest.expressions 352 # The number of unnest.expressions will be changed by _unnest_zip_exprs, we need to record it here 353 has_multi_expr = len(exprs) > 1 354 exprs = _unnest_zip_exprs(unnest, exprs, has_multi_expr) 355 356 joins.remove(join) 357 358 alias_cols = alias.columns if alias else [] 359 360 # # Handle UNNEST to LATERAL VIEW EXPLODE: Exception is raised when there are 0 or > 2 aliases 361 # Spark LATERAL VIEW EXPLODE requires single alias for array/struct and two for Map type column unlike unnest in trino/presto which can take an arbitrary amount. 362 # Refs: https://spark.apache.org/docs/latest/sql-ref-syntax-qry-select-lateral-view.html 363 364 if not has_multi_expr and len(alias_cols) not in (1, 2): 365 raise UnsupportedError( 366 "CROSS JOIN UNNEST to LATERAL VIEW EXPLODE transformation requires explicit column aliases" 367 ) 368 369 offset = unnest.args.get("offset") 370 if offset: 371 alias_cols.insert( 372 0, 373 offset if isinstance(offset, exp.Identifier) else exp.to_identifier("pos"), 374 ) 375 376 for e, column in zip(exprs, alias_cols): 377 expression.append( 378 "laterals", 379 exp.Lateral( 380 this=_udtf_type(unnest, has_multi_expr)(this=e), 381 view=True, 382 alias=exp.TableAlias( 383 this=alias.this, # type: ignore 384 columns=alias_cols, 385 ), 386 ), 387 ) 388 389 return expression
Convert cross join unnest into lateral view explode.
def
explode_projection_to_unnest( index_offset: int = 0) -> Callable[[sqlglot.expressions.core.Expr], sqlglot.expressions.core.Expr]:
392def explode_projection_to_unnest( 393 index_offset: int = 0, 394) -> t.Callable[[exp.Expr], exp.Expr]: 395 """Convert explode/posexplode projections into unnests.""" 396 397 def _explode_projection_to_unnest(expression: exp.Expr) -> exp.Expr: 398 if isinstance(expression, exp.Select): 399 from sqlglot.optimizer.scope import Scope 400 401 taken_select_names = set(expression.named_selects) 402 taken_source_names = {name for name, _ in Scope(expression).references} 403 404 def new_name(names: set[str], name: str) -> str: 405 name = find_new_name(names, name) 406 names.add(name) 407 return name 408 409 arrays: list[exp.Condition] = [] 410 series_alias = new_name(taken_select_names, "pos") 411 series = exp.alias_( 412 exp.Unnest( 413 expressions=[exp.GenerateSeries(start=exp.Literal.number(index_offset))] 414 ), 415 new_name(taken_source_names, "_u"), 416 table=[series_alias], 417 ) 418 419 # we use list here because expression.selects is mutated inside the loop 420 for select in list(expression.selects): 421 explode = select.find(exp.Explode) 422 423 if explode: 424 pos_alias: t.Any = "" 425 explode_alias: t.Any = "" 426 427 if isinstance(select, exp.Alias): 428 explode_alias = select.args["alias"] 429 alias: exp.Expr = select 430 elif isinstance(select, exp.Aliases): 431 pos_alias = select.aliases[0] 432 explode_alias = select.aliases[1] 433 alias = select.replace(exp.alias_(select.this, "", copy=False)) 434 else: 435 alias = select.replace(exp.alias_(select, "")) 436 explode = alias.find(exp.Explode) 437 assert explode 438 439 is_posexplode = isinstance(explode, exp.Posexplode) 440 explode_arg = explode.this 441 442 if isinstance(explode, exp.ExplodeOuter): 443 bracket = explode_arg[0] 444 bracket.set("safe", True) 445 bracket.set("offset", True) 446 explode_arg = exp.func( 447 "IF", 448 exp.func( 449 "ARRAY_SIZE", exp.func("COALESCE", explode_arg, exp.Array()) 450 ).eq(0), 451 exp.array(bracket, copy=False), 452 explode_arg, 453 ) 454 455 # This ensures that we won't use [POS]EXPLODE's argument as a new selection 456 if isinstance(explode_arg, exp.Column): 457 taken_select_names.add(explode_arg.output_name) 458 459 unnest_source_alias = new_name(taken_source_names, "_u") 460 461 if not explode_alias: 462 explode_alias = new_name(taken_select_names, "col") 463 464 if is_posexplode: 465 pos_alias = new_name(taken_select_names, "pos") 466 467 if not pos_alias: 468 pos_alias = new_name(taken_select_names, "pos") 469 470 alias.set("alias", exp.to_identifier(explode_alias)) 471 472 series_table_alias = series.args["alias"].this 473 column = exp.If( 474 this=exp.column(series_alias, table=series_table_alias).eq( 475 exp.column(pos_alias, table=unnest_source_alias) 476 ), 477 true=exp.column(explode_alias, table=unnest_source_alias), 478 ) 479 480 explode.replace(column) 481 482 if is_posexplode: 483 expressions = expression.expressions 484 expressions.insert( 485 expressions.index(alias) + 1, 486 exp.If( 487 this=exp.column(series_alias, table=series_table_alias).eq( 488 exp.column(pos_alias, table=unnest_source_alias) 489 ), 490 true=exp.column(pos_alias, table=unnest_source_alias), 491 ).as_(pos_alias), 492 ) 493 expression.set("expressions", expressions) 494 495 if not arrays: 496 if expression.args.get("from_"): 497 expression.join(series, copy=False, join_type="CROSS") 498 else: 499 expression.from_(series, copy=False) 500 501 size: exp.Condition = exp.ArraySize(this=explode_arg.copy()) 502 arrays.append(size) 503 504 # trino doesn't support left join unnest with on conditions 505 # if it did, this would be much simpler 506 expression.join( 507 exp.alias_( 508 exp.Unnest( 509 expressions=[explode_arg.copy()], 510 offset=exp.to_identifier(pos_alias), 511 ), 512 unnest_source_alias, 513 table=[explode_alias], 514 ), 515 join_type="CROSS", 516 copy=False, 517 ) 518 519 if index_offset != 1: 520 size = size - 1 521 522 expression.where( 523 exp.column(series_alias, table=series_table_alias) 524 .eq(exp.column(pos_alias, table=unnest_source_alias)) 525 .or_( 526 (exp.column(series_alias, table=series_table_alias) > size).and_( 527 exp.column(pos_alias, table=unnest_source_alias).eq(size) 528 ) 529 ), 530 copy=False, 531 ) 532 533 if arrays: 534 end: exp.Condition = exp.Greatest(this=arrays[0], expressions=arrays[1:]) 535 536 if index_offset != 1: 537 end = end - (1 - index_offset) 538 series.expressions[0].set("end", end) 539 540 return expression 541 542 return _explode_projection_to_unnest
Convert explode/posexplode projections into unnests.
def
add_within_group_for_percentiles( expression: sqlglot.expressions.core.Expr) -> sqlglot.expressions.core.Expr:
545def add_within_group_for_percentiles(expression: exp.Expr) -> exp.Expr: 546 """Transforms percentiles by adding a WITHIN GROUP clause to them.""" 547 if ( 548 isinstance(expression, exp.PERCENTILES) 549 and not isinstance(expression.parent, exp.WithinGroup) 550 and expression.expression 551 ): 552 column = expression.this.pop() 553 expression.set("this", expression.expression.pop()) 554 order = exp.Order(expressions=[exp.Ordered(this=column)]) 555 expression = exp.WithinGroup(this=expression, expression=order) 556 557 return expression
Transforms percentiles by adding a WITHIN GROUP clause to them.
def
remove_within_group_for_percentiles( expression: sqlglot.expressions.core.Expr) -> sqlglot.expressions.core.Expr:
560def remove_within_group_for_percentiles(expression: exp.Expr) -> exp.Expr: 561 """Transforms percentiles by getting rid of their corresponding WITHIN GROUP clause.""" 562 if ( 563 isinstance(expression, exp.WithinGroup) 564 and isinstance(expression.this, exp.PERCENTILES) 565 and isinstance(expression.expression, exp.Order) 566 ): 567 quantile = expression.this.this 568 input_value = t.cast(exp.Ordered, expression.find(exp.Ordered)).this 569 return expression.replace(exp.ApproxQuantile(this=input_value, quantile=quantile)) 570 571 return expression
Transforms percentiles by getting rid of their corresponding WITHIN GROUP clause.
def
add_recursive_cte_column_names( expression: sqlglot.expressions.core.Expr) -> sqlglot.expressions.core.Expr:
574def add_recursive_cte_column_names(expression: exp.Expr) -> exp.Expr: 575 """Uses projection output names in recursive CTE definitions to define the CTEs' columns.""" 576 if isinstance(expression, exp.With) and expression.recursive: 577 next_name = name_sequence("_c_") 578 579 for cte in expression.expressions: 580 if not cte.args["alias"].columns: 581 query = cte.this 582 if isinstance(query, exp.SetOperation): 583 query = query.this 584 585 cte.args["alias"].set( 586 "columns", 587 [exp.to_identifier(s.alias_or_name or next_name()) for s in query.selects], 588 ) 589 590 return expression
Uses projection output names in recursive CTE definitions to define the CTEs' columns.
593def epoch_cast_to_ts(expression: exp.Expr) -> exp.Expr: 594 """Replace 'epoch' in casts by the equivalent date literal.""" 595 if ( 596 isinstance(expression, (exp.Cast, exp.TryCast)) 597 and expression.name.lower() == "epoch" 598 and expression.to.this in exp.DataType.TEMPORAL_TYPES 599 ): 600 expression.this.replace(exp.Literal.string("1970-01-01 00:00:00")) 601 602 return expression
Replace 'epoch' in casts by the equivalent date literal.
def
eliminate_semi_and_anti_joins( expression: sqlglot.expressions.core.Expr) -> sqlglot.expressions.core.Expr:
605def eliminate_semi_and_anti_joins(expression: exp.Expr) -> exp.Expr: 606 """Convert SEMI and ANTI joins into equivalent forms that use EXIST instead.""" 607 if isinstance(expression, exp.Select): 608 for join in list(expression.args.get("joins") or []): 609 on = join.args.get("on") 610 if on and join.kind in ("SEMI", "ANTI"): 611 subquery = exp.select("1").from_(join.this).where(on) 612 exists: exp.Exists | exp.Not = exp.Exists(this=subquery) 613 if join.kind == "ANTI": 614 exists = exists.not_(copy=False) 615 616 join.pop() 617 expression.where(exists, copy=False) 618 619 return expression
Convert SEMI and ANTI joins into equivalent forms that use EXIST instead.
def
eliminate_full_outer_join( expression: sqlglot.expressions.core.Expr) -> sqlglot.expressions.core.Expr:
622def eliminate_full_outer_join(expression: exp.Expr) -> exp.Expr: 623 """ 624 Converts a query with a FULL OUTER join to a union of identical queries that 625 use LEFT/RIGHT OUTER joins instead. This transformation currently only works 626 for queries that have a single FULL OUTER join. 627 """ 628 if isinstance(expression, exp.Select): 629 full_outer_joins = [ 630 (index, join) 631 for index, join in enumerate(expression.args.get("joins") or []) 632 if join.side == "FULL" 633 ] 634 635 if len(full_outer_joins) == 1: 636 expression_copy = expression.copy() 637 expression.set("limit", None) 638 index, full_outer_join = full_outer_joins[0] 639 640 tables = (expression.args["from_"].alias_or_name, full_outer_join.alias_or_name) 641 join_conditions = full_outer_join.args.get("on") or exp.and_( 642 *[ 643 exp.column(col, tables[0]).eq(exp.column(col, tables[1])) 644 for col in full_outer_join.args.get("using") 645 ] 646 ) 647 648 full_outer_join.set("side", "left") 649 anti_join_clause = ( 650 exp.select("1").from_(expression.args["from_"]).where(join_conditions) 651 ) 652 expression_copy.args["joins"][index].set("side", "right") 653 expression_copy = expression_copy.where(exp.Exists(this=anti_join_clause).not_()) 654 expression_copy.set("with_", None) # remove CTEs from RIGHT side 655 expression.set("order", None) # remove order by from LEFT side 656 657 return exp.union(expression, expression_copy, copy=False, distinct=False) 658 659 return expression
Converts a query with a FULL OUTER join to a union of identical queries that use LEFT/RIGHT OUTER joins instead. This transformation currently only works for queries that have a single FULL OUTER join.
def
move_ctes_to_top_level(expression: ~E) -> ~E:
662def move_ctes_to_top_level(expression: E) -> E: 663 """ 664 Some dialects (e.g. Hive, T-SQL, Spark prior to version 3) only allow CTEs to be 665 defined at the top-level, so for example queries like: 666 667 SELECT * FROM (WITH t(c) AS (SELECT 1) SELECT * FROM t) AS subq 668 669 are invalid in those dialects. This transformation can be used to ensure all CTEs are 670 moved to the top level so that the final SQL code is valid from a syntax standpoint. 671 672 TODO: handle name clashes whilst moving CTEs (it can get quite tricky & costly). 673 """ 674 top_level_with = expression.args.get("with_") 675 for inner_with in expression.find_all(exp.With): 676 if inner_with.parent is expression: 677 continue 678 679 if not top_level_with: 680 top_level_with = inner_with.pop() 681 expression.set("with_", top_level_with) 682 else: 683 if inner_with.recursive: 684 top_level_with.set("recursive", True) 685 686 parent_cte = inner_with.find_ancestor(exp.CTE) 687 inner_with.pop() 688 689 if parent_cte: 690 i = top_level_with.expressions.index(parent_cte) 691 top_level_with.expressions[i:i] = inner_with.expressions 692 top_level_with.set("expressions", top_level_with.expressions) 693 else: 694 top_level_with.set( 695 "expressions", top_level_with.expressions + inner_with.expressions 696 ) 697 698 return expression
Some dialects (e.g. Hive, T-SQL, Spark prior to version 3) only allow CTEs to be defined at the top-level, so for example queries like:
SELECT * FROM (WITH t(c) AS (SELECT 1) SELECT * FROM t) AS subq
are invalid in those dialects. This transformation can be used to ensure all CTEs are moved to the top level so that the final SQL code is valid from a syntax standpoint.
TODO: handle name clashes whilst moving CTEs (it can get quite tricky & costly).
701def ensure_bools(expression: exp.Expr) -> exp.Expr: 702 """Converts numeric values used in conditions into explicit boolean expressions.""" 703 from sqlglot.optimizer.canonicalize import ensure_bools 704 705 def _ensure_bool(node: exp.Expr) -> None: 706 if ( 707 node.is_number 708 or ( 709 not isinstance(node, exp.SubqueryPredicate) 710 and node.is_type(exp.DType.UNKNOWN, *exp.DataType.NUMERIC_TYPES) 711 ) 712 or (isinstance(node, exp.Column) and not node.type) 713 ): 714 node.replace(node.neq(0)) 715 716 for node in expression.walk(): 717 ensure_bools(node, _ensure_bool) 718 719 return expression
Converts numeric values used in conditions into explicit boolean expressions.
def
remove_unique_constraints( expression: sqlglot.expressions.core.Expr) -> sqlglot.expressions.core.Expr:
def
ctas_with_tmp_tables_to_create_tmp_view( expression: sqlglot.expressions.core.Expr, tmp_storage_provider: Callable[[sqlglot.expressions.core.Expr], sqlglot.expressions.core.Expr] = <function <lambda>>) -> sqlglot.expressions.core.Expr:
740def ctas_with_tmp_tables_to_create_tmp_view( 741 expression: exp.Expr, 742 tmp_storage_provider: t.Callable[[exp.Expr], exp.Expr] = lambda e: e, 743) -> exp.Expr: 744 assert isinstance(expression, exp.Create) 745 properties = expression.args.get("properties") 746 temporary = any( 747 isinstance(prop, exp.TemporaryProperty) 748 for prop in (properties.expressions if properties else []) 749 ) 750 751 # CTAS with temp tables map to CREATE TEMPORARY VIEW 752 if expression.kind == "TABLE" and temporary: 753 if expression.expression: 754 return exp.Create( 755 kind="TEMPORARY VIEW", 756 this=expression.this, 757 expression=expression.expression, 758 ) 759 return tmp_storage_provider(expression) 760 761 return expression
def
move_schema_columns_to_partitioned_by( expression: sqlglot.expressions.core.Expr) -> sqlglot.expressions.core.Expr:
764def move_schema_columns_to_partitioned_by(expression: exp.Expr) -> exp.Expr: 765 """ 766 In Hive, the PARTITIONED BY property acts as an extension of a table's schema. When the 767 PARTITIONED BY value is an array of column names, they are transformed into a schema. 768 The corresponding columns are removed from the create statement. 769 """ 770 assert isinstance(expression, exp.Create) 771 has_schema = isinstance(expression.this, exp.Schema) 772 is_partitionable = expression.kind in {"TABLE", "VIEW"} 773 774 if has_schema and is_partitionable: 775 prop = expression.find(exp.PartitionedByProperty) 776 if prop and prop.this and not isinstance(prop.this, exp.Schema): 777 schema = expression.this 778 columns = {v.name.upper() for v in prop.this.expressions} 779 partitions = [col for col in schema.expressions if col.name.upper() in columns] 780 schema.set("expressions", [e for e in schema.expressions if e not in partitions]) 781 prop.replace(exp.PartitionedByProperty(this=exp.Schema(expressions=partitions))) 782 expression.set("this", schema) 783 784 return expression
In Hive, the PARTITIONED BY property acts as an extension of a table's schema. When the PARTITIONED BY value is an array of column names, they are transformed into a schema. The corresponding columns are removed from the create statement.
def
move_partitioned_by_to_schema_columns( expression: sqlglot.expressions.core.Expr) -> sqlglot.expressions.core.Expr:
787def move_partitioned_by_to_schema_columns(expression: exp.Expr) -> exp.Expr: 788 """ 789 Spark 3 supports both "HIVEFORMAT" and "DATASOURCE" formats for CREATE TABLE. 790 791 Currently, SQLGlot uses the DATASOURCE format for Spark 3. 792 """ 793 assert isinstance(expression, exp.Create) 794 prop = expression.find(exp.PartitionedByProperty) 795 if ( 796 prop 797 and prop.this 798 and isinstance(prop.this, exp.Schema) 799 and all(isinstance(e, exp.ColumnDef) and e.kind for e in prop.this.expressions) 800 ): 801 prop_this = exp.Tuple( 802 expressions=[exp.to_identifier(e.this) for e in prop.this.expressions] 803 ) 804 schema = expression.this 805 for e in prop.this.expressions: 806 schema.append("expressions", e) 807 prop.set("this", prop_this) 808 809 return expression
Spark 3 supports both "HIVEFORMAT" and "DATASOURCE" formats for CREATE TABLE.
Currently, SQLGlot uses the DATASOURCE format for Spark 3.
def
struct_kv_to_alias( expression: sqlglot.expressions.core.Expr) -> sqlglot.expressions.core.Expr:
812def struct_kv_to_alias(expression: exp.Expr) -> exp.Expr: 813 """Converts struct arguments to aliases, e.g. STRUCT(1 AS y).""" 814 if isinstance(expression, exp.Struct): 815 expression.set( 816 "expressions", 817 [ 818 exp.alias_(e.expression, e.this) if isinstance(e, exp.PropertyEQ) else e 819 for e in expression.expressions 820 ], 821 ) 822 823 return expression
Converts struct arguments to aliases, e.g. STRUCT(1 AS y).
def
eliminate_join_marks( expression: sqlglot.expressions.core.Expr) -> sqlglot.expressions.core.Expr:
826def eliminate_join_marks(expression: exp.Expr) -> exp.Expr: 827 """https://docs.oracle.com/cd/B19306_01/server.102/b14200/queries006.htm#sthref3178 828 829 1. You cannot specify the (+) operator in a query block that also contains FROM clause join syntax. 830 831 2. The (+) operator can appear only in the WHERE clause or, in the context of left-correlation (that is, when specifying the TABLE clause) in the FROM clause, and can be applied only to a column of a table or view. 832 833 The (+) operator does not produce an outer join if you specify one table in the outer query and the other table in an inner query. 834 835 You cannot use the (+) operator to outer-join a table to itself, although self joins are valid. 836 837 The (+) operator can be applied only to a column, not to an arbitrary expression. However, an arbitrary expression can contain one or more columns marked with the (+) operator. 838 839 A WHERE condition containing the (+) operator cannot be combined with another condition using the OR logical operator. 840 841 A WHERE condition cannot use the IN comparison condition to compare a column marked with the (+) operator with an expression. 842 843 A WHERE condition cannot compare any column marked with the (+) operator with a subquery. 844 845 -- example with WHERE 846 SELECT d.department_name, sum(e.salary) as total_salary 847 FROM departments d, employees e 848 WHERE e.department_id(+) = d.department_id 849 group by department_name 850 851 -- example of left correlation in select 852 SELECT d.department_name, ( 853 SELECT SUM(e.salary) 854 FROM employees e 855 WHERE e.department_id(+) = d.department_id) AS total_salary 856 FROM departments d; 857 858 -- example of left correlation in from 859 SELECT d.department_name, t.total_salary 860 FROM departments d, ( 861 SELECT SUM(e.salary) AS total_salary 862 FROM employees e 863 WHERE e.department_id(+) = d.department_id 864 ) t 865 """ 866 867 from sqlglot.optimizer.scope import traverse_scope 868 from sqlglot.optimizer.normalize import normalize, normalized 869 from collections import defaultdict 870 871 # we go in reverse to check the main query for left correlation 872 for scope in reversed(traverse_scope(expression)): 873 query = scope.expression 874 875 where = query.args.get("where") 876 joins = query.args.get("joins", []) 877 878 if not where or not any(c.args.get("join_mark") for c in where.find_all(exp.Column)): 879 continue 880 881 # knockout: we do not support left correlation (see point 2) 882 assert not scope.is_correlated_subquery, "Correlated queries are not supported" 883 884 # make sure we have AND of ORs to have clear join terms 885 where = normalize(where.this) 886 assert normalized(where), "Cannot normalize JOIN predicates" 887 888 joins_ons = defaultdict(list) # dict of {name: list of join AND conditions} 889 for cond in [where] if not isinstance(where, exp.And) else where.flatten(): 890 join_cols = [col for col in cond.find_all(exp.Column) if col.args.get("join_mark")] 891 892 left_join_table = set(col.table for col in join_cols) 893 if not left_join_table: 894 continue 895 896 assert not (len(left_join_table) > 1), ( 897 "Cannot combine JOIN predicates from different tables" 898 ) 899 900 for col in join_cols: 901 col.set("join_mark", False) 902 903 joins_ons[left_join_table.pop()].append(cond) 904 905 old_joins = {join.alias_or_name: join for join in joins} 906 new_joins = {} 907 query_from = query.args["from_"] 908 909 for table, predicates in joins_ons.items(): 910 join_what = old_joins.get(table, query_from).this.copy() 911 new_joins[join_what.alias_or_name] = exp.Join( 912 this=join_what, on=exp.and_(*predicates), kind="LEFT" 913 ) 914 915 for p in predicates: 916 while isinstance(p.parent, exp.Paren): 917 p.parent.replace(p) 918 919 parent = p.parent 920 p.pop() 921 if isinstance(parent, exp.Binary): 922 left = parent.args.get("this") 923 parent.replace(parent.right if left is None else left) 924 elif isinstance(parent, exp.Where): 925 parent.pop() 926 927 if query_from.alias_or_name in new_joins: 928 only_old_joins = old_joins.keys() - new_joins.keys() 929 assert len(only_old_joins) >= 1, ( 930 "Cannot determine which table to use in the new FROM clause" 931 ) 932 933 new_from_name = list(only_old_joins)[0] 934 query.set("from_", exp.From(this=old_joins[new_from_name].this)) 935 936 if new_joins: 937 for n, j in old_joins.items(): # preserve any other joins 938 if n not in new_joins and n != query.args["from_"].name: 939 if not j.kind: 940 j.set("kind", "CROSS") 941 new_joins[n] = j 942 query.set("joins", list(new_joins.values())) 943 944 return expression
https://docs.oracle.com/cd/B19306_01/server.102/b14200/queries006.htm#sthref3178
You cannot specify the (+) operator in a query block that also contains FROM clause join syntax.
The (+) operator can appear only in the WHERE clause or, in the context of left-correlation (that is, when specifying the TABLE clause) in the FROM clause, and can be applied only to a column of a table or view.
The (+) operator does not produce an outer join if you specify one table in the outer query and the other table in an inner query.
You cannot use the (+) operator to outer-join a table to itself, although self joins are valid.
The (+) operator can be applied only to a column, not to an arbitrary expression. However, an arbitrary expression can contain one or more columns marked with the (+) operator.
A WHERE condition containing the (+) operator cannot be combined with another condition using the OR logical operator.
A WHERE condition cannot use the IN comparison condition to compare a column marked with the (+) operator with an expression.
A WHERE condition cannot compare any column marked with the (+) operator with a subquery.
-- example with WHERE SELECT d.department_name, sum(e.salary) as total_salary FROM departments d, employees e WHERE e.department_id(+) = d.department_id group by department_name
-- example of left correlation in select SELECT d.department_name, ( SELECT SUM(e.salary) FROM employees e WHERE e.department_id(+) = d.department_id) AS total_salary FROM departments d;
-- example of left correlation in from SELECT d.department_name, t.total_salary FROM departments d, ( SELECT SUM(e.salary) AS total_salary FROM employees e WHERE e.department_id(+) = d.department_id ) t
947def any_to_exists(expression: exp.Expr) -> exp.Expr: 948 """ 949 Transform ANY operator to Spark's EXISTS 950 951 For example, 952 - Postgres: SELECT * FROM tbl WHERE 5 > ANY(tbl.col) 953 - Spark: SELECT * FROM tbl WHERE EXISTS(tbl.col, x -> x < 5) 954 955 Both ANY and EXISTS accept queries but currently only array expressions are supported for this 956 transformation 957 """ 958 if isinstance(expression, exp.Select): 959 for any_expr in expression.find_all(exp.Any): 960 this = any_expr.this 961 if isinstance(this, exp.Query) or isinstance(any_expr.parent, (exp.Like, exp.ILike)): 962 continue 963 964 binop = any_expr.parent 965 if isinstance(binop, exp.Binary): 966 lambda_arg = exp.to_identifier("x") 967 any_expr.replace(lambda_arg) 968 lambda_expr = exp.Lambda(this=binop.copy(), expressions=[lambda_arg]) 969 binop.replace(exp.Exists(this=this.unnest(), expression=lambda_expr)) 970 971 return expression
Transform ANY operator to Spark's EXISTS
For example, - Postgres: SELECT * FROM tbl WHERE 5 > ANY(tbl.col) - Spark: SELECT * FROM tbl WHERE EXISTS(tbl.col, x -> x < 5)
Both ANY and EXISTS accept queries but currently only array expressions are supported for this transformation
def
eliminate_window_clause( expression: sqlglot.expressions.core.Expr) -> sqlglot.expressions.core.Expr:
974def eliminate_window_clause(expression: exp.Expr) -> exp.Expr: 975 """Eliminates the `WINDOW` query clause by inling each named window.""" 976 if isinstance(expression, exp.Select) and expression.args.get("windows"): 977 from sqlglot.optimizer.scope import find_all_in_scope 978 979 windows = expression.args["windows"] 980 expression.set("windows", None) 981 982 window_expression: dict[str, exp.Expr] = {} 983 984 def _inline_inherited_window(window: exp.Expr) -> None: 985 inherited_window = window_expression.get(window.alias.lower()) 986 if not inherited_window: 987 return 988 989 window.set("alias", None) 990 for key in ("partition_by", "order", "spec"): 991 arg = inherited_window.args.get(key) 992 if arg: 993 window.set(key, arg.copy()) 994 995 for window in windows: 996 _inline_inherited_window(window) 997 window_expression[window.name.lower()] = window 998 999 for window in find_all_in_scope(expression, exp.Window): 1000 _inline_inherited_window(window) 1001 1002 return expression
Eliminates the WINDOW query clause by inling each named window.
def
inherit_struct_field_names( expression: sqlglot.expressions.core.Expr) -> sqlglot.expressions.core.Expr:
1005def inherit_struct_field_names(expression: exp.Expr) -> exp.Expr: 1006 """ 1007 Inherit field names from the first struct in an array. 1008 1009 BigQuery supports implicitly inheriting names from the first STRUCT in an array: 1010 1011 Example: 1012 ARRAY[ 1013 STRUCT('Alice' AS name, 85 AS score), -- defines names 1014 STRUCT('Bob', 92), -- inherits names 1015 STRUCT('Diana', 95) -- inherits names 1016 ] 1017 1018 This transformation makes the field names explicit on all structs by adding 1019 PropertyEQ nodes, in order to facilitate transpilation to other dialects. 1020 1021 Args: 1022 expression: The expression tree to transform 1023 1024 Returns: 1025 The modified expression with field names inherited in all structs 1026 """ 1027 if ( 1028 isinstance(expression, exp.Array) 1029 and expression.args.get("struct_name_inheritance") 1030 and isinstance(first_item := seq_get(expression.expressions, 0), exp.Struct) 1031 and all(isinstance(fld, exp.PropertyEQ) for fld in first_item.expressions) 1032 ): 1033 field_names = [fld.this for fld in first_item.expressions] 1034 1035 # Apply field names to subsequent structs that don't have them 1036 for struct in expression.expressions[1:]: 1037 if not isinstance(struct, exp.Struct) or len(struct.expressions) != len(field_names): 1038 continue 1039 1040 # Convert unnamed expressions to PropertyEQ with inherited names 1041 new_expressions = [] 1042 for i, expr in enumerate(struct.expressions): 1043 if not isinstance(expr, exp.PropertyEQ): 1044 # Create PropertyEQ: field_name := value, preserving the type from the inner expression 1045 property_eq = exp.PropertyEQ( 1046 this=field_names[i].copy(), 1047 expression=expr, 1048 ) 1049 property_eq.type = expr.type 1050 new_expressions.append(property_eq) 1051 else: 1052 new_expressions.append(expr) 1053 1054 struct.set("expressions", new_expressions) 1055 1056 return expression
Inherit field names from the first struct in an array.
BigQuery supports implicitly inheriting names from the first STRUCT in an array:
Example:
ARRAY[ STRUCT('Alice' AS name, 85 AS score), -- defines names STRUCT('Bob', 92), -- inherits names STRUCT('Diana', 95) -- inherits names ]
This transformation makes the field names explicit on all structs by adding PropertyEQ nodes, in order to facilitate transpilation to other dialects.
Arguments:
- expression: The expression tree to transform
Returns:
The modified expression with field names inherited in all structs