Documentation ¶
Index ¶
- Constants
- Variables
- func AsString(n NodeFormatter) string
- func AsStringWithFlags(n NodeFormatter, f FmtFlags) string
- func ContainsVars(expr Expr) bool
- func ExprDebugString(expr Expr) string
- func FindEqualComparisonFunction(leftType, rightType Type) (func(*EvalContext, Datum, Datum) (Datum, error), bool)
- func FormatNode(buf *bytes.Buffer, f FmtFlags, n NodeFormatter)
- func HasReturningClause(clause ReturningClause) bool
- func IsNumericOne(expr TypedExpr) bool
- func IsNumericZero(expr TypedExpr) bool
- func LimitDecimalWidth(d *apd.Decimal, precision, scale int) error
- func PGDisplayName(typ Type) string
- func PGIOBuiltinPrefix(typ Type) string
- func ReNormalizeName(name string) string
- func Serialize(n NodeFormatter) string
- func SimilarEscape(pattern string) string
- func StmtDebugString(stmt Statement) string
- func ValidateRestartCheckpoint(savepoint string) error
- func WalkExprConst(v Visitor, expr Expr)
- type AggregateFunc
- type AliasClause
- type AliasedTableExpr
- type AllColumnsSelector
- func (expr *AllColumnsSelector) Eval(ctx *EvalContext) (Datum, error)
- func (a *AllColumnsSelector) Format(buf *bytes.Buffer, f FmtFlags)
- func (a *AllColumnsSelector) NormalizeVarName() (VarName, error)
- func (*AllColumnsSelector) ResolvedType() Type
- func (a *AllColumnsSelector) String() string
- func (expr *AllColumnsSelector) TypeCheck(_ *SemaContext, desired Type) (TypedExpr, error)
- func (a *AllColumnsSelector) Variable()
- func (expr *AllColumnsSelector) Walk(_ Visitor) Expr
- type AllTablesSelector
- type AlterTable
- type AlterTableAddColumn
- type AlterTableAddConstraint
- type AlterTableCmd
- type AlterTableCmds
- type AlterTableDropColumn
- type AlterTableDropConstraint
- type AlterTableDropNotNull
- type AlterTableSetDefault
- type AlterTableValidateConstraint
- type AndExpr
- func (expr *AndExpr) Eval(ctx *EvalContext) (Datum, error)
- func (node *AndExpr) Format(buf *bytes.Buffer, f FmtFlags)
- func (ta AndExpr) ResolvedType() Type
- func (node *AndExpr) String() string
- func (expr *AndExpr) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
- func (node *AndExpr) TypedLeft() TypedExpr
- func (node *AndExpr) TypedRight() TypedExpr
- func (expr *AndExpr) Walk(v Visitor) Expr
- type AnnotateTypeExpr
- func (node *AnnotateTypeExpr) Format(buf *bytes.Buffer, f FmtFlags)
- func (node *AnnotateTypeExpr) String() string
- func (expr *AnnotateTypeExpr) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
- func (node *AnnotateTypeExpr) TypedInnerExpr() TypedExpr
- func (expr *AnnotateTypeExpr) Walk(v Visitor) Expr
- type ArgTypes
- type Array
- func (t *Array) Eval(ctx *EvalContext) (Datum, error)
- func (node *Array) Format(buf *bytes.Buffer, f FmtFlags)
- func (ta Array) ResolvedType() Type
- func (node *Array) String() string
- func (expr *Array) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
- func (expr *Array) Walk(v Visitor) Expr
- type ArrayColType
- type ArrayFlatten
- func (t *ArrayFlatten) Eval(ctx *EvalContext) (Datum, error)
- func (node *ArrayFlatten) Format(buf *bytes.Buffer, f FmtFlags)
- func (ta ArrayFlatten) ResolvedType() Type
- func (node *ArrayFlatten) String() string
- func (expr *ArrayFlatten) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
- func (expr *ArrayFlatten) Walk(v Visitor) Expr
- type ArraySubscript
- type ArraySubscripts
- type AsOfClause
- type Backup
- type BeginTransaction
- type BinOp
- type BinaryExpr
- func (expr *BinaryExpr) Eval(ctx *EvalContext) (Datum, error)
- func (node *BinaryExpr) Format(buf *bytes.Buffer, f FmtFlags)
- func (ta BinaryExpr) ResolvedType() Type
- func (node *BinaryExpr) String() string
- func (expr *BinaryExpr) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
- func (node *BinaryExpr) TypedLeft() TypedExpr
- func (node *BinaryExpr) TypedRight() TypedExpr
- func (expr *BinaryExpr) Walk(v Visitor) Expr
- type BinaryOperator
- type BoolColType
- type Builtin
- type BytesColType
- type CaseExpr
- func (expr *CaseExpr) CopyNode() *CaseExpr
- func (expr *CaseExpr) Eval(ctx *EvalContext) (Datum, error)
- func (node *CaseExpr) Format(buf *bytes.Buffer, f FmtFlags)
- func (ta CaseExpr) ResolvedType() Type
- func (node *CaseExpr) String() string
- func (expr *CaseExpr) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
- func (expr *CaseExpr) Walk(v Visitor) Expr
- type CastExpr
- func (expr *CastExpr) Eval(ctx *EvalContext) (Datum, error)
- func (node *CastExpr) Format(buf *bytes.Buffer, f FmtFlags)
- func (ta CastExpr) ResolvedType() Type
- func (node *CastExpr) String() string
- func (expr *CastExpr) TypeCheck(ctx *SemaContext, _ Type) (TypedExpr, error)
- func (expr *CastExpr) Walk(v Visitor) Expr
- type CastTargetType
- type CheckConstraintTableDef
- type CmpOp
- type CoalesceExpr
- func (expr *CoalesceExpr) CopyNode() *CoalesceExpr
- func (expr *CoalesceExpr) Eval(ctx *EvalContext) (Datum, error)
- func (node *CoalesceExpr) Format(buf *bytes.Buffer, f FmtFlags)
- func (ta CoalesceExpr) ResolvedType() Type
- func (node *CoalesceExpr) String() string
- func (expr *CoalesceExpr) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
- func (node *CoalesceExpr) TypedExprAt(idx int) TypedExpr
- func (expr *CoalesceExpr) Walk(v Visitor) Expr
- type CollateExpr
- func (expr *CollateExpr) Eval(ctx *EvalContext) (Datum, error)
- func (node *CollateExpr) Format(buf *bytes.Buffer, f FmtFlags)
- func (ta CollateExpr) ResolvedType() Type
- func (node *CollateExpr) String() string
- func (expr *CollateExpr) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
- func (expr *CollateExpr) Walk(v Visitor) Expr
- type CollatedStringColType
- type CollationEnvironment
- type ColumnCheckConstraint
- type ColumnCollation
- type ColumnDefault
- type ColumnFKConstraint
- type ColumnFamilyConstraint
- type ColumnID
- type ColumnItem
- func (c *ColumnItem) Column() string
- func (expr *ColumnItem) Eval(ctx *EvalContext) (Datum, error)
- func (c *ColumnItem) Format(buf *bytes.Buffer, f FmtFlags)
- func (c *ColumnItem) NormalizeVarName() (VarName, error)
- func (c *ColumnItem) ResolvedType() Type
- func (c *ColumnItem) String() string
- func (expr *ColumnItem) TypeCheck(_ *SemaContext, desired Type) (TypedExpr, error)
- func (c *ColumnItem) Variable()
- func (expr *ColumnItem) Walk(_ Visitor) Expr
- type ColumnMutationCmd
- type ColumnQualification
- type ColumnTableDef
- type ColumnTableDefCheckExpr
- type ColumnType
- type CommitTransaction
- type ComparisonExpr
- func (expr *ComparisonExpr) Eval(ctx *EvalContext) (Datum, error)
- func (node *ComparisonExpr) Format(buf *bytes.Buffer, f FmtFlags)
- func (node *ComparisonExpr) IsMixedTypeComparison() bool
- func (ta ComparisonExpr) ResolvedType() Type
- func (node *ComparisonExpr) String() string
- func (expr *ComparisonExpr) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
- func (node *ComparisonExpr) TypedLeft() TypedExpr
- func (node *ComparisonExpr) TypedRight() TypedExpr
- func (expr *ComparisonExpr) Walk(v Visitor) Expr
- type ComparisonOperator
- type CompositeDatum
- type Constant
- type ConstraintTableDef
- type ContainsWindowVisitor
- type CopyFrom
- type CreateDatabase
- type CreateIndex
- type CreateTable
- type CreateUser
- type CreateView
- type DArray
- func (*DArray) AmbiguousFormat() bool
- func (d *DArray) Append(v Datum) error
- func (d *DArray) Compare(ctx *EvalContext, other Datum) int
- func (t *DArray) Eval(_ *EvalContext) (Datum, error)
- func (d *DArray) Format(buf *bytes.Buffer, f FmtFlags)
- func (d *DArray) IsMax() bool
- func (d *DArray) IsMin() bool
- func (d *DArray) Len() int
- func (d *DArray) Next() (Datum, bool)
- func (d *DArray) Prev() (Datum, bool)
- func (d *DArray) ResolvedType() Type
- func (d *DArray) Size() uintptr
- func (node *DArray) String() string
- func (d *DArray) TypeCheck(_ *SemaContext, _ Type) (TypedExpr, error)
- func (expr *DArray) Walk(_ Visitor) Expr
- type DBool
- func (*DBool) AmbiguousFormat() bool
- func (d *DBool) Compare(ctx *EvalContext, other Datum) int
- func (t *DBool) Eval(_ *EvalContext) (Datum, error)
- func (d *DBool) Format(buf *bytes.Buffer, f FmtFlags)
- func (d *DBool) IsMax() bool
- func (d *DBool) IsMin() bool
- func (*DBool) Next() (Datum, bool)
- func (*DBool) Prev() (Datum, bool)
- func (*DBool) ResolvedType() Type
- func (d *DBool) Size() uintptr
- func (node *DBool) String() string
- func (d *DBool) TypeCheck(_ *SemaContext, _ Type) (TypedExpr, error)
- func (expr *DBool) Walk(_ Visitor) Expr
- type DBytes
- func (*DBytes) AmbiguousFormat() bool
- func (d *DBytes) Compare(ctx *EvalContext, other Datum) int
- func (t *DBytes) Eval(_ *EvalContext) (Datum, error)
- func (d *DBytes) Format(buf *bytes.Buffer, f FmtFlags)
- func (*DBytes) IsMax() bool
- func (d *DBytes) IsMin() bool
- func (d *DBytes) Next() (Datum, bool)
- func (d *DBytes) Prev() (Datum, bool)
- func (*DBytes) ResolvedType() Type
- func (d *DBytes) Size() uintptr
- func (node *DBytes) String() string
- func (d *DBytes) TypeCheck(_ *SemaContext, _ Type) (TypedExpr, error)
- func (expr *DBytes) Walk(_ Visitor) Expr
- type DCollatedString
- func (*DCollatedString) AmbiguousFormat() bool
- func (d *DCollatedString) Compare(ctx *EvalContext, other Datum) int
- func (t *DCollatedString) Eval(_ *EvalContext) (Datum, error)
- func (d *DCollatedString) Format(buf *bytes.Buffer, f FmtFlags)
- func (d *DCollatedString) IsComposite() bool
- func (*DCollatedString) IsMax() bool
- func (d *DCollatedString) IsMin() bool
- func (d *DCollatedString) Next() (Datum, bool)
- func (d *DCollatedString) Prev() (Datum, bool)
- func (d *DCollatedString) ResolvedType() Type
- func (d *DCollatedString) Size() uintptr
- func (node *DCollatedString) String() string
- func (d *DCollatedString) TypeCheck(_ *SemaContext, _ Type) (TypedExpr, error)
- func (expr *DCollatedString) Walk(_ Visitor) Expr
- type DDate
- func (*DDate) AmbiguousFormat() bool
- func (d *DDate) Compare(ctx *EvalContext, other Datum) int
- func (t *DDate) Eval(_ *EvalContext) (Datum, error)
- func (d *DDate) Format(buf *bytes.Buffer, f FmtFlags)
- func (d *DDate) IsMax() bool
- func (d *DDate) IsMin() bool
- func (d *DDate) Next() (Datum, bool)
- func (d *DDate) Prev() (Datum, bool)
- func (*DDate) ResolvedType() Type
- func (d *DDate) Size() uintptr
- func (node *DDate) String() string
- func (d *DDate) TypeCheck(_ *SemaContext, _ Type) (TypedExpr, error)
- func (expr *DDate) Walk(_ Visitor) Expr
- type DDecimal
- func (*DDecimal) AmbiguousFormat() bool
- func (d *DDecimal) Compare(ctx *EvalContext, other Datum) int
- func (t *DDecimal) Eval(_ *EvalContext) (Datum, error)
- func (d *DDecimal) Format(buf *bytes.Buffer, f FmtFlags)
- func (d *DDecimal) IsComposite() bool
- func (*DDecimal) IsMax() bool
- func (*DDecimal) IsMin() bool
- func (d *DDecimal) Next() (Datum, bool)
- func (d *DDecimal) Prev() (Datum, bool)
- func (*DDecimal) ResolvedType() Type
- func (d *DDecimal) SetString(s string) error
- func (d *DDecimal) Size() uintptr
- func (node *DDecimal) String() string
- func (d *DDecimal) TypeCheck(_ *SemaContext, _ Type) (TypedExpr, error)
- func (expr *DDecimal) Walk(_ Visitor) Expr
- type DFloat
- func (*DFloat) AmbiguousFormat() bool
- func (d *DFloat) Compare(ctx *EvalContext, other Datum) int
- func (t *DFloat) Eval(_ *EvalContext) (Datum, error)
- func (d *DFloat) Format(buf *bytes.Buffer, f FmtFlags)
- func (d *DFloat) IsComposite() bool
- func (d *DFloat) IsMax() bool
- func (d *DFloat) IsMin() bool
- func (d *DFloat) Next() (Datum, bool)
- func (d *DFloat) Prev() (Datum, bool)
- func (*DFloat) ResolvedType() Type
- func (d *DFloat) Size() uintptr
- func (node *DFloat) String() string
- func (d *DFloat) TypeCheck(_ *SemaContext, _ Type) (TypedExpr, error)
- func (expr *DFloat) Walk(_ Visitor) Expr
- type DInt
- func (*DInt) AmbiguousFormat() bool
- func (d *DInt) Compare(ctx *EvalContext, other Datum) int
- func (t *DInt) Eval(_ *EvalContext) (Datum, error)
- func (d *DInt) Format(buf *bytes.Buffer, f FmtFlags)
- func (d *DInt) IsMax() bool
- func (d *DInt) IsMin() bool
- func (d *DInt) Next() (Datum, bool)
- func (d *DInt) Prev() (Datum, bool)
- func (*DInt) ResolvedType() Type
- func (d *DInt) Size() uintptr
- func (node *DInt) String() string
- func (d *DInt) TypeCheck(_ *SemaContext, _ Type) (TypedExpr, error)
- func (expr *DInt) Walk(_ Visitor) Expr
- type DInterval
- func (*DInterval) AmbiguousFormat() bool
- func (d *DInterval) Compare(ctx *EvalContext, other Datum) int
- func (t *DInterval) Eval(_ *EvalContext) (Datum, error)
- func (d *DInterval) Format(buf *bytes.Buffer, f FmtFlags)
- func (d *DInterval) IsMax() bool
- func (d *DInterval) IsMin() bool
- func (d *DInterval) Next() (Datum, bool)
- func (d *DInterval) Prev() (Datum, bool)
- func (*DInterval) ResolvedType() Type
- func (d *DInterval) Size() uintptr
- func (node *DInterval) String() string
- func (d *DInterval) TypeCheck(_ *SemaContext, _ Type) (TypedExpr, error)
- func (d *DInterval) ValueAsString() string
- func (expr *DInterval) Walk(_ Visitor) Expr
- type DOid
- func (*DOid) AmbiguousFormat() bool
- func (d *DOid) AsRegProc(name string) *DOid
- func (d *DOid) Compare(ctx *EvalContext, other Datum) int
- func (t *DOid) Eval(_ *EvalContext) (Datum, error)
- func (d *DOid) Format(buf *bytes.Buffer, f FmtFlags)
- func (d *DOid) IsMax() bool
- func (d *DOid) IsMin() bool
- func (d *DOid) Next() (Datum, bool)
- func (d *DOid) Prev() (Datum, bool)
- func (d *DOid) ResolvedType() Type
- func (d *DOid) Size() uintptr
- func (node *DOid) String() string
- func (d *DOid) TypeCheck(_ *SemaContext, _ Type) (TypedExpr, error)
- func (expr *DOid) Walk(_ Visitor) Expr
- type DOidWrapper
- func (d *DOidWrapper) AmbiguousFormat() bool
- func (d *DOidWrapper) Compare(ctx *EvalContext, other Datum) int
- func (t *DOidWrapper) Eval(_ *EvalContext) (Datum, error)
- func (d *DOidWrapper) Format(buf *bytes.Buffer, f FmtFlags)
- func (d *DOidWrapper) IsMax() bool
- func (d *DOidWrapper) IsMin() bool
- func (d *DOidWrapper) Next() (Datum, bool)
- func (d *DOidWrapper) Prev() (Datum, bool)
- func (d *DOidWrapper) ResolvedType() Type
- func (d *DOidWrapper) Size() uintptr
- func (node *DOidWrapper) String() string
- func (d *DOidWrapper) TypeCheck(_ *SemaContext, _ Type) (TypedExpr, error)
- func (expr *DOidWrapper) Walk(_ Visitor) Expr
- type DString
- func (*DString) AmbiguousFormat() bool
- func (d *DString) Compare(ctx *EvalContext, other Datum) int
- func (t *DString) Eval(_ *EvalContext) (Datum, error)
- func (d *DString) Format(buf *bytes.Buffer, f FmtFlags)
- func (*DString) IsMax() bool
- func (d *DString) IsMin() bool
- func (d *DString) Next() (Datum, bool)
- func (d *DString) Prev() (Datum, bool)
- func (*DString) ResolvedType() Type
- func (d *DString) Size() uintptr
- func (node *DString) String() string
- func (d *DString) TypeCheck(_ *SemaContext, _ Type) (TypedExpr, error)
- func (expr *DString) Walk(_ Visitor) Expr
- type DTable
- func (*DTable) AmbiguousFormat() bool
- func (t *DTable) Compare(ctx *EvalContext, other Datum) int
- func (t *DTable) Eval(_ *EvalContext) (Datum, error)
- func (t *DTable) Format(buf *bytes.Buffer, _ FmtFlags)
- func (*DTable) IsMax() bool
- func (*DTable) IsMin() bool
- func (*DTable) Next() (Datum, bool)
- func (*DTable) Prev() (Datum, bool)
- func (t *DTable) ResolvedType() Type
- func (*DTable) Size() uintptr
- func (node *DTable) String() string
- func (d *DTable) TypeCheck(_ *SemaContext, _ Type) (TypedExpr, error)
- func (expr *DTable) Walk(_ Visitor) Expr
- type DTimestamp
- func (*DTimestamp) AmbiguousFormat() bool
- func (d *DTimestamp) Compare(ctx *EvalContext, other Datum) int
- func (t *DTimestamp) Eval(_ *EvalContext) (Datum, error)
- func (d *DTimestamp) Format(buf *bytes.Buffer, f FmtFlags)
- func (d *DTimestamp) IsMax() bool
- func (d *DTimestamp) IsMin() bool
- func (d *DTimestamp) Next() (Datum, bool)
- func (d *DTimestamp) Prev() (Datum, bool)
- func (*DTimestamp) ResolvedType() Type
- func (d *DTimestamp) Size() uintptr
- func (node *DTimestamp) String() string
- func (d *DTimestamp) TypeCheck(_ *SemaContext, _ Type) (TypedExpr, error)
- func (expr *DTimestamp) Walk(_ Visitor) Expr
- type DTimestampTZ
- func (*DTimestampTZ) AmbiguousFormat() bool
- func (d *DTimestampTZ) Compare(ctx *EvalContext, other Datum) int
- func (t *DTimestampTZ) Eval(_ *EvalContext) (Datum, error)
- func (d *DTimestampTZ) Format(buf *bytes.Buffer, f FmtFlags)
- func (d *DTimestampTZ) IsMax() bool
- func (d *DTimestampTZ) IsMin() bool
- func (d *DTimestampTZ) Next() (Datum, bool)
- func (d *DTimestampTZ) Prev() (Datum, bool)
- func (*DTimestampTZ) ResolvedType() Type
- func (d *DTimestampTZ) Size() uintptr
- func (node *DTimestampTZ) String() string
- func (d *DTimestampTZ) TypeCheck(_ *SemaContext, _ Type) (TypedExpr, error)
- func (expr *DTimestampTZ) Walk(_ Visitor) Expr
- type DTuple
- func (*DTuple) AmbiguousFormat() bool
- func (d *DTuple) AssertSorted()
- func (d *DTuple) Compare(ctx *EvalContext, other Datum) int
- func (t *DTuple) Eval(_ *EvalContext) (Datum, error)
- func (d *DTuple) Format(buf *bytes.Buffer, f FmtFlags)
- func (d *DTuple) IsMax() bool
- func (d *DTuple) IsMin() bool
- func (d *DTuple) Next() (Datum, bool)
- func (d *DTuple) Normalize(ctx *EvalContext)
- func (d *DTuple) Prev() (Datum, bool)
- func (d *DTuple) ResolvedType() Type
- func (d *DTuple) SearchSorted(ctx *EvalContext, target Datum) (int, bool)
- func (d *DTuple) SetSorted() *DTuple
- func (d *DTuple) Size() uintptr
- func (d *DTuple) SortedDifference(ctx *EvalContext, other *DTuple) *DTuple
- func (node *DTuple) String() string
- func (d *DTuple) TypeCheck(_ *SemaContext, _ Type) (TypedExpr, error)
- func (expr *DTuple) Walk(_ Visitor) Expr
- type DateColType
- type Datum
- type Datums
- type Deallocate
- type DecimalColType
- type DefaultVal
- func (expr DefaultVal) Eval(ctx *EvalContext) (Datum, error)
- func (node DefaultVal) Format(buf *bytes.Buffer, f FmtFlags)
- func (DefaultVal) ResolvedType() Type
- func (node DefaultVal) String() string
- func (expr DefaultVal) TypeCheck(_ *SemaContext, desired Type) (TypedExpr, error)
- func (expr DefaultVal) Walk(_ Visitor) Expr
- type Delete
- type Direction
- type DropBehavior
- type DropDatabase
- type DropIndex
- type DropTable
- type DropView
- type EvalContext
- func (ctx *EvalContext) GetClusterTimestamp() *DDecimal
- func (ctx *EvalContext) GetClusterTimestampRaw() hlc.Timestamp
- func (ctx *EvalContext) GetLocation() *time.Location
- func (ctx *EvalContext) GetStmtTimestamp() time.Time
- func (ctx *EvalContext) GetTxnTimestamp(precision time.Duration) *DTimestampTZ
- func (ctx *EvalContext) GetTxnTimestampNoZone(precision time.Duration) *DTimestamp
- func (ctx *EvalContext) GetTxnTimestampRaw() time.Time
- func (ctx *EvalContext) NormalizeExpr(typedExpr TypedExpr) (TypedExpr, error)
- func (ctx *EvalContext) SetClusterTimestamp(ts hlc.Timestamp)
- func (ctx *EvalContext) SetStmtTimestamp(ts time.Time)
- func (ctx *EvalContext) SetTxnTimestamp(ts time.Time)
- type EvalPlanner
- type Execute
- type ExistsExpr
- func (t *ExistsExpr) Eval(ctx *EvalContext) (Datum, error)
- func (node *ExistsExpr) Format(buf *bytes.Buffer, f FmtFlags)
- func (ta ExistsExpr) ResolvedType() Type
- func (node *ExistsExpr) String() string
- func (expr *ExistsExpr) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
- func (expr *ExistsExpr) Walk(v Visitor) Expr
- type Explain
- type Expr
- type Exprs
- type FamilyTableDef
- type FloatColType
- type FmtFlags
- func FmtExpr(base FmtFlags, showTypes bool, symbolicVars bool, showTableAliases bool) FmtFlags
- func FmtIndexedVarFormat(base FmtFlags, ...) FmtFlags
- func FmtReformatTableNames(base FmtFlags, fn func(*NormalizableTableName, *bytes.Buffer, FmtFlags)) FmtFlags
- func FmtStarDatumFormat(base FmtFlags, fn func(buf *bytes.Buffer, f FmtFlags)) FmtFlags
- type ForeignKeyConstraintTableDef
- type From
- type FuncExpr
- func (expr *FuncExpr) CopyNode() *FuncExpr
- func (expr *FuncExpr) Eval(ctx *EvalContext) (Datum, error)
- func (node *FuncExpr) Format(buf *bytes.Buffer, f FmtFlags)
- func (node *FuncExpr) GetAggregateConstructor() func(*EvalContext) AggregateFunc
- func (node *FuncExpr) GetWindowConstructor() func(*EvalContext) WindowFunc
- func (node *FuncExpr) IsDistSQLBlacklist() bool
- func (node *FuncExpr) IsImpure() bool
- func (node *FuncExpr) IsWindowFunctionApplication() bool
- func (ta FuncExpr) ResolvedType() Type
- func (node *FuncExpr) String() string
- func (expr *FuncExpr) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
- func (expr *FuncExpr) Walk(v Visitor) Expr
- type FunctionClass
- type FunctionDefinition
- type FunctionReference
- type Grant
- type GroupBy
- type Help
- type HiddenFromStats
- type HomogeneousType
- type ID
- type IfExpr
- func (expr *IfExpr) Eval(ctx *EvalContext) (Datum, error)
- func (node *IfExpr) Format(buf *bytes.Buffer, f FmtFlags)
- func (ta IfExpr) ResolvedType() Type
- func (node *IfExpr) String() string
- func (expr *IfExpr) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
- func (node *IfExpr) TypedCondExpr() TypedExpr
- func (node *IfExpr) TypedElseExpr() TypedExpr
- func (node *IfExpr) TypedTrueExpr() TypedExpr
- func (expr *IfExpr) Walk(v Visitor) Expr
- type IndependentFromParallelizedPriors
- type IndexElem
- type IndexElemList
- type IndexHints
- type IndexID
- type IndexTableDef
- type IndexedRow
- type IndexedVar
- func (v *IndexedVar) Eval(ctx *EvalContext) (Datum, error)
- func (v *IndexedVar) Format(buf *bytes.Buffer, f FmtFlags)
- func (v *IndexedVar) ResolvedType() Type
- func (node *IndexedVar) String() string
- func (v *IndexedVar) TypeCheck(_ *SemaContext, desired Type) (TypedExpr, error)
- func (*IndexedVar) Variable()
- func (v *IndexedVar) Walk(_ Visitor) Expr
- type IndexedVarContainer
- type IndexedVarHelper
- func (h *IndexedVarHelper) AppendSlot() int
- func (h *IndexedVarHelper) AssertSameContainer(ivar *IndexedVar)
- func (h *IndexedVarHelper) BindIfUnbound(ivar *IndexedVar) error
- func (h *IndexedVarHelper) GetIndexedVars() []IndexedVar
- func (h *IndexedVarHelper) IndexedVar(idx int) *IndexedVar
- func (h *IndexedVarHelper) IndexedVarUsed(idx int) bool
- func (h *IndexedVarHelper) NumVars() int
- func (h *IndexedVarHelper) Rebind(expr TypedExpr, alsoReset, normalizeToNonNil bool) TypedExpr
- func (h *IndexedVarHelper) Reset()
- func (*IndexedVarHelper) VisitPost(expr Expr) Expr
- func (h *IndexedVarHelper) VisitPre(expr Expr) (recurse bool, newExpr Expr)
- type IndirectionExpr
- func (expr *IndirectionExpr) CopyNode() *IndirectionExpr
- func (expr *IndirectionExpr) Eval(ctx *EvalContext) (Datum, error)
- func (node *IndirectionExpr) Format(buf *bytes.Buffer, f FmtFlags)
- func (ta IndirectionExpr) ResolvedType() Type
- func (node *IndirectionExpr) String() string
- func (expr *IndirectionExpr) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
- func (expr *IndirectionExpr) Walk(v Visitor) Expr
- type Insert
- func (stmt *Insert) CopyNode() *Insert
- func (node *Insert) DefaultValues() bool
- func (node *Insert) Format(buf *bytes.Buffer, f FmtFlags)
- func (*Insert) StatementTag() string
- func (n *Insert) StatementType() StatementType
- func (n *Insert) String() string
- func (stmt *Insert) WalkStmt(v Visitor) Statement
- type IntColType
- type InterleaveDef
- type IntervalColType
- type IsAggregateVisitor
- type IsOfTypeExpr
- func (expr *IsOfTypeExpr) Eval(ctx *EvalContext) (Datum, error)
- func (node *IsOfTypeExpr) Format(buf *bytes.Buffer, f FmtFlags)
- func (ta IsOfTypeExpr) ResolvedType() Type
- func (node *IsOfTypeExpr) String() string
- func (expr *IsOfTypeExpr) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
- func (expr *IsOfTypeExpr) Walk(v Visitor) Expr
- type IsolationLevel
- type JoinCond
- type JoinTableExpr
- type KVOption
- type KVOptions
- type Limit
- type MaxAggregate
- type MinAggregate
- type MultipleResultsError
- type Name
- type NameColType
- type NameList
- type NamePart
- type NameParts
- type NamedColumnQualification
- type NaturalJoinCond
- type NoReturningClause
- type NodeFormatter
- type NormalizableTableName
- func (nt NormalizableTableName) Format(buf *bytes.Buffer, f FmtFlags)
- func (nt *NormalizableTableName) Normalize() (*TableName, error)
- func (nt *NormalizableTableName) NormalizeWithDatabaseName(database string) (*TableName, error)
- func (nt NormalizableTableName) String() string
- func (nt *NormalizableTableName) TableName() *TableName
- type NotExpr
- func (expr *NotExpr) Eval(ctx *EvalContext) (Datum, error)
- func (node *NotExpr) Format(buf *bytes.Buffer, f FmtFlags)
- func (ta NotExpr) ResolvedType() Type
- func (node *NotExpr) String() string
- func (expr *NotExpr) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
- func (node *NotExpr) TypedInnerExpr() TypedExpr
- func (expr *NotExpr) Walk(v Visitor) Expr
- type NotNullConstraint
- type NullConstraint
- type NullIfExpr
- func (expr *NullIfExpr) Eval(ctx *EvalContext) (Datum, error)
- func (node *NullIfExpr) Format(buf *bytes.Buffer, f FmtFlags)
- func (ta NullIfExpr) ResolvedType() Type
- func (node *NullIfExpr) String() string
- func (expr *NullIfExpr) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
- func (expr *NullIfExpr) Walk(v Visitor) Expr
- type Nullability
- type NumVal
- func (expr *NumVal) AsInt64() (int64, error)
- func (expr *NumVal) AvailableTypes() []Type
- func (expr *NumVal) Format(buf *bytes.Buffer, f FmtFlags)
- func (expr *NumVal) ResolveAsType(ctx *SemaContext, typ Type) (Datum, error)
- func (expr *NumVal) ShouldBeInt64() bool
- func (node *NumVal) String() string
- func (expr *NumVal) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
- func (expr *NumVal) Walk(_ Visitor) Expr
- type OidColType
- type OnConflict
- type OnJoinCond
- type OrExpr
- func (expr *OrExpr) Eval(ctx *EvalContext) (Datum, error)
- func (node *OrExpr) Format(buf *bytes.Buffer, f FmtFlags)
- func (ta OrExpr) ResolvedType() Type
- func (node *OrExpr) String() string
- func (expr *OrExpr) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
- func (node *OrExpr) TypedLeft() TypedExpr
- func (node *OrExpr) TypedRight() TypedExpr
- func (expr *OrExpr) Walk(v Visitor) Expr
- type Order
- type OrderBy
- type ParenExpr
- func (expr *ParenExpr) Eval(ctx *EvalContext) (Datum, error)
- func (node *ParenExpr) Format(buf *bytes.Buffer, f FmtFlags)
- func (ta ParenExpr) ResolvedType() Type
- func (node *ParenExpr) String() string
- func (expr *ParenExpr) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
- func (node *ParenExpr) TypedInnerExpr() TypedExpr
- func (expr *ParenExpr) Walk(v Visitor) Expr
- type ParenSelect
- type ParenTableExpr
- type Parser
- func (p *Parser) AggregateInExpr(expr Expr, searchPath SearchPath) bool
- func (p *Parser) AssertNoAggregationOrWindowing(expr Expr, op string, searchPath SearchPath) error
- func (p *Parser) IsAggregate(n *SelectClause, searchPath SearchPath) bool
- func (p *Parser) NormalizeExpr(ctx *EvalContext, typedExpr TypedExpr) (TypedExpr, error)
- func (p *Parser) Parse(sql string) (stmts StatementList, err error)
- func (p *Parser) WindowFuncInExpr(expr Expr) bool
- func (p *Parser) WindowFuncInExprs(exprs []TypedExpr) bool
- type Placeholder
- func (node *Placeholder) Eval(_ *EvalContext) (Datum, error)
- func (node *Placeholder) Format(buf *bytes.Buffer, f FmtFlags)
- func (node *Placeholder) ResolvedType() Type
- func (node *Placeholder) String() string
- func (expr *Placeholder) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
- func (*Placeholder) Variable()
- func (expr *Placeholder) Walk(_ Visitor) Expr
- type PlaceholderInfo
- func (p *PlaceholderInfo) AssertAllAssigned() error
- func (p *PlaceholderInfo) Assign(src *PlaceholderInfo)
- func (p *PlaceholderInfo) Clear()
- func (p *PlaceholderInfo) FillUnassigned()
- func (p *PlaceholderInfo) IsUnresolvedPlaceholder(expr Expr) bool
- func (p *PlaceholderInfo) SetType(name string, typ Type) error
- func (p *PlaceholderInfo) SetTypes(src PlaceholderTypes)
- func (p *PlaceholderInfo) SetValue(name string, val Datum)
- func (p *PlaceholderInfo) Type(name string) (Type, bool)
- func (p *PlaceholderInfo) Value(name string) (TypedExpr, bool)
- type PlaceholderTypes
- type Prepare
- type PrimaryKeyConstraint
- type QueryArguments
- type RangeCond
- func (expr *RangeCond) Eval(ctx *EvalContext) (Datum, error)
- func (node *RangeCond) Format(buf *bytes.Buffer, f FmtFlags)
- func (ta RangeCond) ResolvedType() Type
- func (node *RangeCond) String() string
- func (expr *RangeCond) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
- func (node *RangeCond) TypedFrom() TypedExpr
- func (node *RangeCond) TypedLeft() TypedExpr
- func (node *RangeCond) TypedTo() TypedExpr
- func (expr *RangeCond) Walk(v Visitor) Expr
- type RegexpCache
- type ReleaseSavepoint
- type Relocate
- type RenameColumn
- type RenameDatabase
- type RenameIndex
- type RenameTable
- type ResolvableFunctionReference
- type Restore
- type ReturningClause
- type ReturningExprs
- type ReturningNothing
- type Revoke
- type RollbackToSavepoint
- type RollbackTransaction
- type Savepoint
- type Scanner
- type Scatter
- type SearchPath
- type Select
- type SelectClause
- func (stmt *SelectClause) CopyNode() *SelectClause
- func (node *SelectClause) Format(buf *bytes.Buffer, f FmtFlags)
- func (*SelectClause) StatementTag() string
- func (*SelectClause) StatementType() StatementType
- func (n *SelectClause) String() string
- func (stmt *SelectClause) WalkStmt(v Visitor) Statement
- type SelectExpr
- type SelectExprs
- type SelectStatement
- type SemaContext
- type Set
- type SetDefaultIsolation
- type SetMode
- type SetTimeZone
- type SetTransaction
- type Show
- type ShowColumns
- type ShowConstraints
- type ShowCreateTable
- type ShowCreateView
- type ShowDatabases
- type ShowGrants
- type ShowIndex
- type ShowRanges
- type ShowTables
- type ShowTransactionStatus
- type ShowUsers
- type SimpleVisitFn
- type Split
- type StarDatum
- func (*StarDatum) Eval(ctx *EvalContext) (Datum, error)
- func (*StarDatum) Format(buf *bytes.Buffer, f FmtFlags)
- func (*StarDatum) ResolvedType() Type
- func (s *StarDatum) String() string
- func (s *StarDatum) TypeCheck(_ *SemaContext, _ Type) (TypedExpr, error)
- func (*StarDatum) Variable()
- func (s *StarDatum) Walk(v Visitor) Expr
- type Statement
- type StatementList
- type StatementType
- type StrVal
- func (expr *StrVal) AvailableTypes() []Type
- func (expr *StrVal) Format(buf *bytes.Buffer, f FmtFlags)
- func (expr *StrVal) ResolveAsType(ctx *SemaContext, typ Type) (Datum, error)
- func (node *StrVal) String() string
- func (expr *StrVal) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
- func (expr *StrVal) Walk(_ Visitor) Expr
- type StringColType
- type Subquery
- type TArray
- type TCollatedString
- func (t TCollatedString) Equivalent(other Type) bool
- func (TCollatedString) FamilyEqual(other Type) bool
- func (t TCollatedString) IsAmbiguous() bool
- func (TCollatedString) Oid() oid.Oid
- func (TCollatedString) SQLName() string
- func (TCollatedString) Size() (uintptr, bool)
- func (t TCollatedString) String() string
- type TPlaceholder
- type TTable
- type TTuple
- type TableDef
- type TableDefs
- type TableExpr
- type TableExprs
- type TableName
- func (t *TableName) Database() string
- func (t *TableName) Format(buf *bytes.Buffer, f FmtFlags)
- func (t *TableName) NormalizeTableName() (*TableName, error)
- func (t *TableName) NormalizeTablePattern() (TablePattern, error)
- func (t *TableName) NormalizedTableName() TableName
- func (t *TableName) QualifyWithDatabase(database string) error
- func (t *TableName) String() string
- func (t *TableName) Table() string
- type TableNameReference
- type TableNameReferences
- type TableNameWithIndex
- type TableNameWithIndexList
- type TableNames
- type TablePattern
- type TablePatterns
- type TableRef
- type TargetList
- type TimestampColType
- type TimestampTZColType
- type Truncate
- type Tuple
- func (t *Tuple) Eval(ctx *EvalContext) (Datum, error)
- func (node *Tuple) Format(buf *bytes.Buffer, f FmtFlags)
- func (node *Tuple) ResolvedType() Type
- func (node *Tuple) String() string
- func (expr *Tuple) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
- func (expr *Tuple) Walk(v Visitor) Expr
- type Type
- type TypedExpr
- type TypedExprs
- type UnaryExpr
- func (expr *UnaryExpr) Eval(ctx *EvalContext) (Datum, error)
- func (node *UnaryExpr) Format(buf *bytes.Buffer, f FmtFlags)
- func (ta UnaryExpr) ResolvedType() Type
- func (node *UnaryExpr) String() string
- func (expr *UnaryExpr) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
- func (node *UnaryExpr) TypedInnerExpr() TypedExpr
- func (expr *UnaryExpr) Walk(v Visitor) Expr
- type UnaryOp
- type UnaryOperator
- type UnionClause
- type UnionType
- type UniqueConstraint
- type UniqueConstraintTableDef
- type UnqualifiedStar
- func (expr UnqualifiedStar) Eval(ctx *EvalContext) (Datum, error)
- func (UnqualifiedStar) Format(buf *bytes.Buffer, _ FmtFlags)
- func (u UnqualifiedStar) NormalizeVarName() (VarName, error)
- func (UnqualifiedStar) ResolvedType() Type
- func (u UnqualifiedStar) String() string
- func (expr UnqualifiedStar) TypeCheck(_ *SemaContext, desired Type) (TypedExpr, error)
- func (UnqualifiedStar) Variable()
- func (expr UnqualifiedStar) Walk(_ Visitor) Expr
- type UnresolvedName
- func (expr UnresolvedName) Eval(ctx *EvalContext) (Datum, error)
- func (u UnresolvedName) Format(buf *bytes.Buffer, f FmtFlags)
- func (n UnresolvedName) NormalizeTableName() (*TableName, error)
- func (n UnresolvedName) NormalizeTablePattern() (TablePattern, error)
- func (n UnresolvedName) NormalizeUnqualifiedColumnItem() (*ColumnItem, error)
- func (n UnresolvedName) NormalizeVarName() (VarName, error)
- func (n UnresolvedName) ResolveFunction(searchPath SearchPath) (*FunctionDefinition, error)
- func (UnresolvedName) ResolvedType() Type
- func (u UnresolvedName) String() string
- func (expr UnresolvedName) TypeCheck(s *SemaContext, desired Type) (TypedExpr, error)
- func (UnresolvedName) Variable()
- func (expr UnresolvedName) Walk(_ Visitor) Expr
- type UnresolvedNames
- type Update
- type UpdateExpr
- type UpdateExprs
- type UserPriority
- type UsingJoinCond
- type ValidationBehavior
- type ValueGenerator
- type ValuesClause
- type VarName
- type VariableExpr
- type VariadicType
- type VectorColType
- type Visitor
- type WalkableStmt
- type When
- type Where
- type Window
- type WindowDef
- type WindowFrame
- type WindowFunc
Constants ¶
const ( TimestampJdbcFormat = timestampFormat + ".999999 -07:00:00" TimestampNodeFormat = timestampFormat + ".999999-07:00" )
time.Time formats.
const ( DistinctFuncType funcType AllFuncType )
FuncExpr.Type
const ACTION = 57362
const ADD = 57363
const ALL = 57364
const ALTER = 57365
const ANALYSE = 57366
const ANALYZE = 57367
const AND = 57368
const ANNOTATE_TYPE = 57370
const ANY = 57369
const ARRAY = 57371
const AS = 57372
const ASC = 57373
const ASYMMETRIC = 57374
const AS_LA = 57651
const AT = 57375
const BACKUP = 57376
const BCONST = 57348
const BEGIN = 57377
const BETWEEN = 57378
const BIGINT = 57379
const BIGSERIAL = 57380
const BIT = 57381
const BLOB = 57382
const BOOL = 57383
const BOOLEAN = 57384
const BOTH = 57385
const BY = 57386
const BYTEA = 57387
const BYTES = 57388
const CASCADE = 57389
const CASE = 57390
const CAST = 57391
const CHAR = 57392
const CHARACTER = 57393
const CHARACTERISTICS = 57394
const CHECK = 57395
const CLUSTER = 57396
const COALESCE = 57397
const COLLATE = 57398
const COLLATION = 57399
const COLUMN = 57400
const COLUMNS = 57401
const COMMIT = 57402
const COMMITTED = 57403
const CONCAT = 57404
const CONFLICT = 57405
const CONSTRAINT = 57406
const CONSTRAINTS = 57407
const COPY = 57408
const COVERING = 57409
const CREATE = 57410
const CROSS = 57411
const CUBE = 57412
const CURRENT = 57413
const CURRENT_CATALOG = 57414
const CURRENT_DATE = 57415
const CURRENT_ROLE = 57416
const CURRENT_TIME = 57417
const CURRENT_TIMESTAMP = 57418
const CURRENT_USER = 57419
const CYCLE = 57420
const DATA = 57421
const DATABASE = 57422
const DATABASES = 57423
const DATE = 57424
const DAY = 57425
const DEALLOCATE = 57429
const DEC = 57426
const DECIMAL = 57427
const DEFAULT = 57428
const DEFERRABLE = 57430
const DELETE = 57431
const DESC = 57432
const DISTINCT = 57433
const DO = 57434
const DOT_DOT = 57354
const DOUBLE = 57435
const DROP = 57436
const ELSE = 57437
const ENCODING = 57438
const END = 57439
const ERROR = 57361
const ESCAPE = 57440
const EXCEPT = 57441
const EXECUTE = 57443
const EXISTS = 57442
const EXPLAIN = 57444
const EXTRACT = 57445
const EXTRACT_DURATION = 57446
const FALSE = 57447
const FAMILY = 57448
const FCONST = 57350
const FETCH = 57449
const FILTER = 57450
const FIRST = 57451
const FLOAT = 57452
const FLOORDIV = 57453
const FOLLOWING = 57454
const FOR = 57455
const FORCE_INDEX = 57456
const FOREIGN = 57457
const FROM = 57458
const FULL = 57459
const GRANT = 57460
const GRANTS = 57461
const GREATER_EQUALS = 57356
const GREATEST = 57462
const GROUP = 57463
const GROUPING = 57464
const HAVING = 57465
const HELP = 57466
const HIGH = 57467
const HOUR = 57468
const ICONST = 57349
const IDENT = 57346
const IF = 57470
const IFNULL = 57471
const ILIKE = 57472
const IN = 57473
const INCREMENTAL = 57469
const INDEX = 57475
const INDEXES = 57476
const INITIALLY = 57477
const INNER = 57478
const INSERT = 57479
const INT = 57480
const INT2VECTOR = 57481
const INT64 = 57483
const INT8 = 57482
const INTEGER = 57484
const INTERLEAVE = 57474
const INTERSECT = 57485
const INTERVAL = 57486
const INTO = 57487
const IS = 57488
const ISOLATION = 57489
const InvalidColIdx = -1
InvalidColIdx is the index value of a non-initialized IndexedVar.
const JOIN = 57490
const KEY = 57491
const KEYS = 57492
const LATERAL = 57493
const LC_COLLATE = 57495
const LC_CTYPE = 57494
const LEADING = 57496
const LEAST = 57497
const LEFT = 57498
const LESS_EQUALS = 57355
const LEVEL = 57499
const LIKE = 57500
const LIMIT = 57501
const LOCAL = 57502
const LOCALTIME = 57503
const LOCALTIMESTAMP = 57504
const LOW = 57505
const LSHIFT = 57506
const MATCH = 57507
const MINUTE = 57508
const MONTH = 57509
const MaxInt = int(MaxUint >> 1)
MaxInt is the maximum value of an int.
const MaxUint = ^uint(0)
MaxUint is the maximum value of an uint.
const NAME = 57511
const NAMES = 57512
const NAN = 57510
const NATURAL = 57513
const NEXT = 57514
const NO = 57515
const NORMAL = 57517
const NOT = 57518
const NOTHING = 57519
const NOT_EQUALS = 57357
const NOT_LA = 57649
const NOT_REGIMATCH = 57360
const NOT_REGMATCH = 57358
const NO_INDEX_JOIN = 57516
const NULL = 57520
const NULLIF = 57521
const NULLS = 57522
const NUMERIC = 57523
const OF = 57524
const OFF = 57525
const OFFSET = 57526
const OID = 57527
const ON = 57528
const ONLY = 57529
const OPTIONS = 57530
const OR = 57531
const ORDER = 57532
const ORDINALITY = 57533
const OUT = 57534
const OUTER = 57535
const OVER = 57536
const OVERLAPS = 57537
const OVERLAY = 57538
const PARENT = 57539
const PARTIAL = 57540
const PARTITION = 57541
const PASSWORD = 57542
const PLACEHOLDER = 57351
const PLACING = 57543
const POSITION = 57544
const POSTFIXOP = 57652
const PRECEDING = 57545
const PRECISION = 57546
const PREPARE = 57547
const PRIMARY = 57548
const PRIORITY = 57549
const RANGE = 57550
const READ = 57551
const REAL = 57552
const RECURSIVE = 57553
const REF = 57554
const REFERENCES = 57555
const REGCLASS = 57556
const REGIMATCH = 57359
const REGNAMESPACE = 57559
const REGPROC = 57557
const REGPROCEDURE = 57558
const REGTYPE = 57560
const RELEASE = 57563
const RENAME = 57561
const REPEATABLE = 57562
const RESET = 57564
const RESTORE = 57565
const RESTRICT = 57566
const RETURNING = 57567
const REVOKE = 57568
const RIGHT = 57569
const ROLLBACK = 57570
const ROLLUP = 57571
const ROW = 57572
const ROWS = 57573
const RSHIFT = 57574
const RestartSavepointName string = "COCKROACH_RESTART"
RestartSavepointName is the only savepoint name that we accept, modulo capitalization.
const SAVEPOINT = 57575
const SCATTER = 57576
const SCONST = 57347
const SEARCH = 57577
const SECOND = 57578
const SELECT = 57579
const SERIAL = 57580
const SERIALIZABLE = 57581
const SESSION = 57582
const SESSION_USER = 57583
const SET = 57584
const SETTING = 57585
const SETTINGS = 57586
const SHOW = 57587
const SIMILAR = 57588
const SIMPLE = 57589
const SMALLINT = 57590
const SMALLSERIAL = 57591
const SNAPSHOT = 57592
const SOME = 57593
const SPLIT = 57594
const SQL = 57595
const START = 57596
const STATUS = 57597
const STDIN = 57598
const STORING = 57601
const STRICT = 57599
const STRING = 57600
const SUBSTRING = 57602
const SYMMETRIC = 57603
const SYSTEM = 57604
const TABLE = 57605
const TABLES = 57606
const TEMPLATE = 57607
const TESTING_RANGES = 57608
const TESTING_RELOCATE = 57609
const TEXT = 57610
const THEN = 57611
const TIME = 57612
const TIMESTAMP = 57613
const TIMESTAMPTZ = 57614
const TO = 57615
const TRAILING = 57616
const TRANSACTION = 57617
const TREAT = 57618
const TRIM = 57619
const TRUE = 57620
const TRUNCATE = 57621
const TYPE = 57622
const TYPEANNOTATE = 57353
const TYPECAST = 57352
const UMINUS = 57653
const UNBOUNDED = 57623
const UNCOMMITTED = 57624
const UNION = 57625
const UNIQUE = 57626
const UNKNOWN = 57627
const UPDATE = 57628
const UPSERT = 57629
const USER = 57630
const USERS = 57631
const USING = 57632
const VALID = 57633
const VALIDATE = 57634
const VALUE = 57635
const VALUES = 57636
const VARCHAR = 57637
const VARIADIC = 57638
const VARYING = 57640
const VIEW = 57639
const WHEN = 57641
const WHERE = 57642
const WINDOW = 57643
const WITH = 57644
const WITHIN = 57645
const WITHOUT = 57646
const WITH_LA = 57650
const YEAR = 57647
const ZONE = 57648
Variables ¶
var ( // DBoolTrue is a pointer to the DBool(true) value and can be used in // comparisons against Datum types. DBoolTrue = &constDBoolTrue // DBoolFalse is a pointer to the DBool(false) value and can be used in // comparisons against Datum types. DBoolFalse = &constDBoolFalse // DNull is the NULL Datum. DNull Datum = dNull{} // DZero is the zero-valued integer Datum. DZero = NewDInt(0) )
var ( // DecimalCtx is the default context for decimal operations. Any change // in the exponent limits must still guarantee a safe conversion to the // postegrs binary decimal format in the wire protocol, which uses an // int16. See pgwire/types.go. DecimalCtx = &apd.Context{ Precision: 20, Rounding: apd.RoundHalfUp, MaxExponent: 2000, MinExponent: -2000, Traps: apd.DefaultTraps, } // ExactCtx is a decimal context with exact precision. ExactCtx = DecimalCtx.WithPrecision(0) // HighPrecisionCtx is a decimal context with high precision. HighPrecisionCtx = DecimalCtx.WithPrecision(2000) // RoundCtx is a decimal context with high precision and RoundHalfEven // rounding. RoundCtx = func() *apd.Context { ctx := *HighPrecisionCtx ctx.Rounding = apd.RoundHalfEven return &ctx }() )
var ( // TypeNull is the type of a DNull. Can be compared with ==. TypeNull Type = tNull{} // TypeBool is the type of a DBool. Can be compared with ==. TypeBool Type = tBool{} // TypeInt is the type of a DInt. Can be compared with ==. TypeInt Type = tInt{} // TypeFloat is the type of a DFloat. Can be compared with ==. TypeFloat Type = tFloat{} // TypeDecimal is the type of a DDecimal. Can be compared with ==. TypeDecimal Type = tDecimal{} // TypeString is the type of a DString. Can be compared with ==. TypeString Type = tString{} // TypeCollatedString is the type family of a DString. CANNOT be compared with // ==. TypeCollatedString Type = TCollatedString{} // TypeBytes is the type of a DBytes. Can be compared with ==. TypeBytes Type = tBytes{} // TypeDate is the type of a DDate. Can be compared with ==. TypeDate Type = tDate{} // TypeTimestamp is the type of a DTimestamp. Can be compared with ==. TypeTimestamp Type = tTimestamp{} // TypeTimestampTZ is the type of a DTimestampTZ. Can be compared with ==. TypeTimestampTZ Type = tTimestampTZ{} // TypeInterval is the type of a DInterval. Can be compared with ==. TypeInterval Type = tInterval{} // TypeTuple is the type family of a DTuple. CANNOT be compared with ==. TypeTuple Type = TTuple(nil) // TypeTable is the type family of a DTable. CANNOT be compared with ==. TypeTable Type = TTable{} // TypePlaceholder is the type family of a placeholder. CANNOT be compared // with ==. TypePlaceholder Type = TPlaceholder{} // TypeStringArray is the type family of a DArray containing strings. Can be // compared with ==. TypeStringArray Type = TArray{TypeString} // TypeIntArray is the type family of a DArray containing ints. Can be // compared with ==. TypeIntArray Type = TArray{TypeInt} // TypeAnyArray is the type of a DArray with a wildcard parameterized type. // Can be compared with ==. TypeAnyArray Type = TArray{TypeAny} // TypeAny can be any type. Can be compared with ==. TypeAny Type = tAny{} // TypeOid is the type of an OID. Can be compared with ==. TypeOid = tOid{oid.T_oid} // TypeRegClass is the type of an regclass OID variant. Can be compared with ==. TypeRegClass = tOid{oid.T_regclass} // TypeRegNamespace is the type of an regnamespace OID variant. Can be compared with ==. TypeRegNamespace = tOid{oid.T_regnamespace} // TypeRegProc is the type of an regproc OID variant. Can be compared with ==. TypeRegProc = tOid{oid.T_regproc} // TypeRegProcedure is the type of an regprocedure OID variant. Can be compared with ==. TypeRegProcedure = tOid{oid.T_regprocedure} // TypeRegType is the type of an regtype OID variant. Can be compared with ==. TypeRegType = tOid{oid.T_regtype} // TypeName is a type-alias for TypeString with a different OID. Can be // compared with ==. TypeName = wrapTypeWithOid(TypeString, oid.T_name) // TypeIntVector is a type-alias for a TypeIntArray with a different OID. Can // be compared with ==. TypeIntVector = wrapTypeWithOid(TypeIntArray, oid.T_int2vector) // TypeNameArray is the type family of a DArray containing the Name alias type. // Can be compared with ==. TypeNameArray Type = TArray{TypeName} // TypesAnyNonArray contains all non-array types. TypesAnyNonArray = []Type{ TypeBool, TypeInt, TypeFloat, TypeDecimal, TypeString, TypeBytes, TypeDate, TypeTimestamp, TypeTimestampTZ, TypeInterval, TypeOid, } )
var AbsentReturningClause = &NoReturningClause{}
AbsentReturningClause is a ReturningClause variant representing the absence of a RETURNING clause.
var Aggregates = map[string][]Builtin{ "array_agg": { makeAggBuiltinWithReturnType( TypeAny, func(args []TypedExpr) Type { if len(args) == 0 { return unknownReturnType } return TArray{args[0].ResolvedType()} }, newArrayAggregate, "Aggregates the selected values into an array.", ), }, "avg": { makeAggBuiltin(TypeInt, TypeDecimal, newIntAvgAggregate, "Calculates the average of the selected values."), makeAggBuiltin(TypeFloat, TypeFloat, newFloatAvgAggregate, "Calculates the average of the selected values."), makeAggBuiltin(TypeDecimal, TypeDecimal, newDecimalAvgAggregate, "Calculates the average of the selected values."), }, "bool_and": { makeAggBuiltin(TypeBool, TypeBool, newBoolAndAggregate, "Calculates the boolean value of `AND`ing all selected values."), }, "bool_or": { makeAggBuiltin(TypeBool, TypeBool, newBoolOrAggregate, "Calculates the boolean value of `OR`ing all selected values."), }, "concat_agg": { makeAggBuiltin(TypeString, TypeString, newStringConcatAggregate, "Concatenates all selected values."), makeAggBuiltin(TypeBytes, TypeBytes, newBytesConcatAggregate, "Concatenates all selected values."), }, "count": { makeAggBuiltin(TypeAny, TypeInt, newCountAggregate, "Calculates the number of selected elements."), }, "max": collectBuiltins(func(t Type) Builtin { return makeAggBuiltin(t, t, newMaxAggregate, "Identifies the maximum selected value.") }, TypesAnyNonArray...), "min": collectBuiltins(func(t Type) Builtin { return makeAggBuiltin(t, t, newMinAggregate, "Identifies the minimum selected value.") }, TypesAnyNonArray...), "sum_int": { makeAggBuiltin(TypeInt, TypeInt, newSmallIntSumAggregate, "Calculates the sum of the selected values."), }, "sum": { makeAggBuiltin(TypeInt, TypeDecimal, newIntSumAggregate, "Calculates the sum of the selected values."), makeAggBuiltin(TypeFloat, TypeFloat, newFloatSumAggregate, "Calculates the sum of the selected values."), makeAggBuiltin(TypeDecimal, TypeDecimal, newDecimalSumAggregate, "Calculates the sum of the selected values."), makeAggBuiltin(TypeInterval, TypeInterval, newIntervalSumAggregate, "Calculates the sum of the selected values."), }, "variance": { makeAggBuiltin(TypeInt, TypeDecimal, newIntVarianceAggregate, "Calculates the variance of the selected values."), makeAggBuiltin(TypeDecimal, TypeDecimal, newDecimalVarianceAggregate, "Calculates the variance of the selected values."), makeAggBuiltin(TypeFloat, TypeFloat, newFloatVarianceAggregate, "Calculates the variance of the selected values."), }, "stddev": { makeAggBuiltin(TypeInt, TypeDecimal, newIntStdDevAggregate, "Calculates the standard deviation of the selected values."), makeAggBuiltin(TypeDecimal, TypeDecimal, newDecimalStdDevAggregate, "Calculates the standard deviation of the selected values."), makeAggBuiltin(TypeFloat, TypeFloat, newFloatStdDevAggregate, "Calculates the standard deviation of the selected values."), }, "xor_agg": { makeAggBuiltin(TypeBytes, TypeBytes, newBytesXorAggregate, "Calculates the bitwise XOR of the selected values."), makeAggBuiltin(TypeInt, TypeInt, newIntXorAggregate, "Calculates the bitwise XOR of the selected values."), }, }
Aggregates are a special class of builtin functions that are wrapped at execution in a bucketing layer to combine (aggregate) the result of the function being run over many rows. See `aggregateFuncHolder` in the sql package. In particular they must not be simplified during normalization (and thus must be marked as impure), even when they are given a constant argument (e.g. SUM(1)). This is because aggregate functions must return NULL when they are no rows in the source table, so their evaluation must always be delayed until query execution. Exported for use in documentation.
var BinOps = map[BinaryOperator]binOpOverload{ Bitand: { BinOp{ LeftType: TypeInt, RightType: TypeInt, ReturnType: TypeInt, // contains filtered or unexported fields }, }, Bitor: { BinOp{ LeftType: TypeInt, RightType: TypeInt, ReturnType: TypeInt, // contains filtered or unexported fields }, }, Bitxor: { BinOp{ LeftType: TypeInt, RightType: TypeInt, ReturnType: TypeInt, // contains filtered or unexported fields }, }, Plus: { BinOp{ LeftType: TypeInt, RightType: TypeInt, ReturnType: TypeInt, // contains filtered or unexported fields }, BinOp{ LeftType: TypeFloat, RightType: TypeFloat, ReturnType: TypeFloat, // contains filtered or unexported fields }, BinOp{ LeftType: TypeDecimal, RightType: TypeDecimal, ReturnType: TypeDecimal, // contains filtered or unexported fields }, BinOp{ LeftType: TypeDecimal, RightType: TypeInt, ReturnType: TypeDecimal, // contains filtered or unexported fields }, BinOp{ LeftType: TypeInt, RightType: TypeDecimal, ReturnType: TypeDecimal, // contains filtered or unexported fields }, BinOp{ LeftType: TypeDate, RightType: TypeInt, ReturnType: TypeDate, // contains filtered or unexported fields }, BinOp{ LeftType: TypeInt, RightType: TypeDate, ReturnType: TypeDate, // contains filtered or unexported fields }, BinOp{ LeftType: TypeTimestamp, RightType: TypeInterval, ReturnType: TypeTimestamp, // contains filtered or unexported fields }, BinOp{ LeftType: TypeInterval, RightType: TypeTimestamp, ReturnType: TypeTimestamp, // contains filtered or unexported fields }, BinOp{ LeftType: TypeTimestampTZ, RightType: TypeInterval, ReturnType: TypeTimestampTZ, // contains filtered or unexported fields }, BinOp{ LeftType: TypeInterval, RightType: TypeTimestampTZ, ReturnType: TypeTimestampTZ, // contains filtered or unexported fields }, BinOp{ LeftType: TypeInterval, RightType: TypeInterval, ReturnType: TypeInterval, // contains filtered or unexported fields }, BinOp{ LeftType: TypeDate, RightType: TypeInterval, ReturnType: TypeTimestampTZ, // contains filtered or unexported fields }, BinOp{ LeftType: TypeInterval, RightType: TypeDate, ReturnType: TypeTimestampTZ, // contains filtered or unexported fields }, }, Minus: { BinOp{ LeftType: TypeInt, RightType: TypeInt, ReturnType: TypeInt, // contains filtered or unexported fields }, BinOp{ LeftType: TypeFloat, RightType: TypeFloat, ReturnType: TypeFloat, // contains filtered or unexported fields }, BinOp{ LeftType: TypeDecimal, RightType: TypeDecimal, ReturnType: TypeDecimal, // contains filtered or unexported fields }, BinOp{ LeftType: TypeDecimal, RightType: TypeInt, ReturnType: TypeDecimal, // contains filtered or unexported fields }, BinOp{ LeftType: TypeInt, RightType: TypeDecimal, ReturnType: TypeDecimal, // contains filtered or unexported fields }, BinOp{ LeftType: TypeDate, RightType: TypeInt, ReturnType: TypeDate, // contains filtered or unexported fields }, BinOp{ LeftType: TypeDate, RightType: TypeDate, ReturnType: TypeInt, // contains filtered or unexported fields }, BinOp{ LeftType: TypeTimestamp, RightType: TypeTimestamp, ReturnType: TypeInterval, // contains filtered or unexported fields }, BinOp{ LeftType: TypeTimestampTZ, RightType: TypeTimestampTZ, ReturnType: TypeInterval, // contains filtered or unexported fields }, BinOp{ LeftType: TypeTimestamp, RightType: TypeTimestampTZ, ReturnType: TypeInterval, // contains filtered or unexported fields }, BinOp{ LeftType: TypeTimestampTZ, RightType: TypeTimestamp, ReturnType: TypeInterval, // contains filtered or unexported fields }, BinOp{ LeftType: TypeTimestamp, RightType: TypeInterval, ReturnType: TypeTimestamp, // contains filtered or unexported fields }, BinOp{ LeftType: TypeTimestampTZ, RightType: TypeInterval, ReturnType: TypeTimestampTZ, // contains filtered or unexported fields }, BinOp{ LeftType: TypeDate, RightType: TypeInterval, ReturnType: TypeTimestampTZ, // contains filtered or unexported fields }, BinOp{ LeftType: TypeInterval, RightType: TypeInterval, ReturnType: TypeInterval, // contains filtered or unexported fields }, }, Mult: { BinOp{ LeftType: TypeInt, RightType: TypeInt, ReturnType: TypeInt, // contains filtered or unexported fields }, BinOp{ LeftType: TypeFloat, RightType: TypeFloat, ReturnType: TypeFloat, // contains filtered or unexported fields }, BinOp{ LeftType: TypeDecimal, RightType: TypeDecimal, ReturnType: TypeDecimal, // contains filtered or unexported fields }, BinOp{ LeftType: TypeDecimal, RightType: TypeInt, ReturnType: TypeDecimal, // contains filtered or unexported fields }, BinOp{ LeftType: TypeInt, RightType: TypeDecimal, ReturnType: TypeDecimal, // contains filtered or unexported fields }, BinOp{ LeftType: TypeInt, RightType: TypeInterval, ReturnType: TypeInterval, // contains filtered or unexported fields }, BinOp{ LeftType: TypeInterval, RightType: TypeInt, ReturnType: TypeInterval, // contains filtered or unexported fields }, BinOp{ LeftType: TypeInterval, RightType: TypeFloat, ReturnType: TypeInterval, // contains filtered or unexported fields }, }, Div: { BinOp{ LeftType: TypeInt, RightType: TypeInt, ReturnType: TypeDecimal, // contains filtered or unexported fields }, BinOp{ LeftType: TypeFloat, RightType: TypeFloat, ReturnType: TypeFloat, // contains filtered or unexported fields }, BinOp{ LeftType: TypeDecimal, RightType: TypeDecimal, ReturnType: TypeDecimal, // contains filtered or unexported fields }, BinOp{ LeftType: TypeDecimal, RightType: TypeInt, ReturnType: TypeDecimal, // contains filtered or unexported fields }, BinOp{ LeftType: TypeInt, RightType: TypeDecimal, ReturnType: TypeDecimal, // contains filtered or unexported fields }, BinOp{ LeftType: TypeInterval, RightType: TypeInt, ReturnType: TypeInterval, // contains filtered or unexported fields }, BinOp{ LeftType: TypeInterval, RightType: TypeFloat, ReturnType: TypeInterval, // contains filtered or unexported fields }, }, FloorDiv: { BinOp{ LeftType: TypeInt, RightType: TypeInt, ReturnType: TypeInt, // contains filtered or unexported fields }, BinOp{ LeftType: TypeFloat, RightType: TypeFloat, ReturnType: TypeFloat, // contains filtered or unexported fields }, BinOp{ LeftType: TypeDecimal, RightType: TypeDecimal, ReturnType: TypeDecimal, // contains filtered or unexported fields }, BinOp{ LeftType: TypeDecimal, RightType: TypeInt, ReturnType: TypeDecimal, // contains filtered or unexported fields }, BinOp{ LeftType: TypeInt, RightType: TypeDecimal, ReturnType: TypeDecimal, // contains filtered or unexported fields }, }, Mod: { BinOp{ LeftType: TypeInt, RightType: TypeInt, ReturnType: TypeInt, // contains filtered or unexported fields }, BinOp{ LeftType: TypeFloat, RightType: TypeFloat, ReturnType: TypeFloat, // contains filtered or unexported fields }, BinOp{ LeftType: TypeDecimal, RightType: TypeDecimal, ReturnType: TypeDecimal, // contains filtered or unexported fields }, BinOp{ LeftType: TypeDecimal, RightType: TypeInt, ReturnType: TypeDecimal, // contains filtered or unexported fields }, BinOp{ LeftType: TypeInt, RightType: TypeDecimal, ReturnType: TypeDecimal, // contains filtered or unexported fields }, }, Concat: { BinOp{ LeftType: TypeString, RightType: TypeString, ReturnType: TypeString, // contains filtered or unexported fields }, BinOp{ LeftType: TypeBytes, RightType: TypeBytes, ReturnType: TypeBytes, // contains filtered or unexported fields }, }, LShift: { BinOp{ LeftType: TypeInt, RightType: TypeInt, ReturnType: TypeInt, // contains filtered or unexported fields }, }, RShift: { BinOp{ LeftType: TypeInt, RightType: TypeInt, ReturnType: TypeInt, // contains filtered or unexported fields }, }, Pow: { BinOp{ LeftType: TypeInt, RightType: TypeInt, ReturnType: TypeInt, // contains filtered or unexported fields }, BinOp{ LeftType: TypeFloat, RightType: TypeFloat, ReturnType: TypeFloat, // contains filtered or unexported fields }, BinOp{ LeftType: TypeDecimal, RightType: TypeDecimal, ReturnType: TypeDecimal, // contains filtered or unexported fields }, BinOp{ LeftType: TypeDecimal, RightType: TypeInt, ReturnType: TypeDecimal, // contains filtered or unexported fields }, BinOp{ LeftType: TypeInt, RightType: TypeDecimal, ReturnType: TypeDecimal, // contains filtered or unexported fields }, }, }
BinOps contains the binary operations indexed by operation type.
var Builtins = map[string][]Builtin{ "length": { stringBuiltin1(func(s string) (Datum, error) { return NewDInt(DInt(utf8.RuneCountInString(s))), nil }, TypeInt, "Calculates the number of characters in `val`."), bytesBuiltin1(func(s string) (Datum, error) { return NewDInt(DInt(len(s))), nil }, TypeInt, "Calculates the number of bytes in `val`."), }, "octet_length": { stringBuiltin1(func(s string) (Datum, error) { return NewDInt(DInt(len(s))), nil }, TypeInt, "Calculates the number of bytes used to represent `val`."), bytesBuiltin1(func(s string) (Datum, error) { return NewDInt(DInt(len(s))), nil }, TypeInt, "Calculates the number of bytes in `val`."), }, "lower": {stringBuiltin1(func(s string) (Datum, error) { return NewDString(strings.ToLower(s)), nil }, TypeString, "Converts all characters in `val`to their lower-case equivalents.")}, "upper": {stringBuiltin1(func(s string) (Datum, error) { return NewDString(strings.ToUpper(s)), nil }, TypeString, "Converts all characters in `val`to their to their upper-case equivalents.")}, "substr": substringImpls, "substring": substringImpls, "concat": { Builtin{ Types: VariadicType{TypeString}, ReturnType: fixedReturnType(TypeString), Info: "Concatenates a comma-separated list of strings.", // contains filtered or unexported fields }, }, "concat_ws": { Builtin{ Types: VariadicType{TypeString}, ReturnType: fixedReturnType(TypeString), Info: "Uses the first argument as a separator between the concatenation of the " + "subsequent arguments. <br/><br/>For example `concat_ws('!','wow','great')` " + "returns `wow!great`.", // contains filtered or unexported fields }, }, "to_uuid": { Builtin{ Types: ArgTypes{{"val", TypeString}}, ReturnType: fixedReturnType(TypeBytes), Info: "Converts the character string representation of a UUID to its byte string " + "representation.", // contains filtered or unexported fields }, }, "from_uuid": { Builtin{ Types: ArgTypes{{"val", TypeBytes}}, ReturnType: fixedReturnType(TypeString), Info: "Converts the byte string representation of a UUID to its character string " + "representation.", // contains filtered or unexported fields }, }, "from_ip": { Builtin{ Types: ArgTypes{{"val", TypeBytes}}, ReturnType: fixedReturnType(TypeString), Info: "Converts the byte string representation of an IP to its character string " + "representation.", // contains filtered or unexported fields }, }, "to_ip": { Builtin{ Types: ArgTypes{{"val", TypeString}}, ReturnType: fixedReturnType(TypeBytes), Info: "Converts the character string representation of an IP to its byte string " + "representation.", // contains filtered or unexported fields }, }, "split_part": { Builtin{ Types: ArgTypes{ {"input", TypeString}, {"delimiter", TypeString}, {"return_index_pos", TypeInt}, }, ReturnType: fixedReturnType(TypeString), Info: "Splits `input` on `delimiter` and return the value in the `return_index_pos` " + "position (starting at 1). <br/><br/>For example, `split_part('123.456.789.0','.',3)`" + "returns `789`.", // contains filtered or unexported fields }, }, "repeat": { Builtin{ Types: ArgTypes{{"input", TypeString}, {"repeat_counter", TypeInt}}, ReturnType: fixedReturnType(TypeString), Info: "Concatenates `input` `repeat_counter` number of times.<br/><br/>For example, " + "`repeat('dog', 2)` returns `dogdog`.", // contains filtered or unexported fields }, }, "ascii": {stringBuiltin1(func(s string) (Datum, error) { for _, ch := range s { return NewDInt(DInt(ch)), nil } return nil, errEmptyInputString }, TypeInt, "Calculates the ASCII value for the first character in `val`.")}, "md5": hashBuiltin( func() hash.Hash { return md5.New() }, "Calculates the MD5 hash value of a set of values.", ), "sha1": hashBuiltin( func() hash.Hash { return sha1.New() }, "Calculates the SHA1 hash value of a set of values.", ), "sha256": hashBuiltin( func() hash.Hash { return sha256.New() }, "Calculates the SHA256 hash value of a set of values.", ), "sha512": hashBuiltin( func() hash.Hash { return sha512.New() }, "Calculates the SHA512 hash value of a set of values.", ), "fnv32": hash32Builtin( func() hash.Hash32 { return fnv.New32() }, "Calculates the 32-bit FNV-1 hash value of a set of values.", ), "fnv32a": hash32Builtin( func() hash.Hash32 { return fnv.New32a() }, "Calculates the 32-bit FNV-1a hash value of a set of values.", ), "fnv64": hash64Builtin( func() hash.Hash64 { return fnv.New64() }, "Calculates the 64-bit FNV-1 hash value of a set of values.", ), "fnv64a": hash64Builtin( func() hash.Hash64 { return fnv.New64a() }, "Calculates the 64-bit FNV-1a hash value of a set of values.", ), "crc32ieee": hash32Builtin( func() hash.Hash32 { return crc32.New(crc32.IEEETable) }, "Calculates the CRC-32 hash using the IEEE polynomial.", ), "crc32c": hash32Builtin( func() hash.Hash32 { return crc32.New(crc32.MakeTable(crc32.Castagnoli)) }, "Calculates the CRC-32 hash using the Castagnoli polynomial.", ), "to_hex": { Builtin{ Types: ArgTypes{{"val", TypeInt}}, ReturnType: fixedReturnType(TypeString), Info: "Converts `val` to its hexadecimal representation.", // contains filtered or unexported fields }, Builtin{ Types: ArgTypes{{"val", TypeBytes}}, ReturnType: fixedReturnType(TypeString), Info: "Converts `val` to its hexadecimal representation.", // contains filtered or unexported fields }, }, "strpos": {stringBuiltin2("input", "find", func(s, substring string) (Datum, error) { index := strings.Index(s, substring) if index < 0 { return DZero, nil } return NewDInt(DInt(utf8.RuneCountInString(s[:index]) + 1)), nil }, TypeInt, "Calculates the position where the string `find` begins in `input`. <br/><br/>For"+ " example, `strpos('doggie', 'gie')` returns `4`.")}, "overlay": { Builtin{ Types: ArgTypes{ {"input", TypeString}, {"overlay_val", TypeString}, {"start_pos", TypeInt}, }, ReturnType: fixedReturnType(TypeString), Info: "Replaces characters in `input` with `overlay_val` starting at `start_pos` " + "(begins at 1). <br/><br/>For example, `overlay('doggie', 'CAT', 2)` returns " + "`dCATie`.", // contains filtered or unexported fields }, Builtin{ Types: ArgTypes{ {"input", TypeString}, {"overlay_val", TypeString}, {"start_pos", TypeInt}, {"end_pos", TypeInt}, }, ReturnType: fixedReturnType(TypeString), Info: "Deletes the characters in `input` between `start_pos` and `end_pos` (count " + "starts at 1), and then insert `overlay_val` at `start_pos`.", // contains filtered or unexported fields }, }, "btrim": { stringBuiltin2("input", "trim_chars", func(s, chars string) (Datum, error) { return NewDString(strings.Trim(s, chars)), nil }, TypeString, "Removes any characters included in `trim_chars` from the beginning or end"+ " of `input` (applies recursively). <br/><br/>For example, `btrim('doggie', 'eod')` "+ "returns `ggi`."), stringBuiltin1(func(s string) (Datum, error) { return NewDString(strings.TrimSpace(s)), nil }, TypeString, "Removes all spaces from the beginning and end of `val`."), }, "ltrim": { stringBuiltin2("input", "trim_chars", func(s, chars string) (Datum, error) { return NewDString(strings.TrimLeft(s, chars)), nil }, TypeString, "Removes any characters included in `trim_chars` from the beginning "+ "(left-hand side) of `input` (applies recursively). <br/><br/>For example, "+ "`ltrim('doggie', 'od')` returns `ggie`."), stringBuiltin1(func(s string) (Datum, error) { return NewDString(strings.TrimLeftFunc(s, unicode.IsSpace)), nil }, TypeString, "Removes all spaces from the beginning (left-hand side) of `val`."), }, "rtrim": { stringBuiltin2("input", "trim_chars", func(s, chars string) (Datum, error) { return NewDString(strings.TrimRight(s, chars)), nil }, TypeString, "Removes any characters included in `trim_chars` from the end (right-hand "+ "side) of `input` (applies recursively). <br/><br/>For example, `rtrim('doggie', 'ei')` "+ "returns `dogg`."), stringBuiltin1(func(s string) (Datum, error) { return NewDString(strings.TrimRightFunc(s, unicode.IsSpace)), nil }, TypeString, "Removes all spaces from the end (right-hand side) of `val`."), }, "reverse": {stringBuiltin1(func(s string) (Datum, error) { runes := []rune(s) for i, j := 0, len(runes)-1; i < j; i, j = i+1, j-1 { runes[i], runes[j] = runes[j], runes[i] } return NewDString(string(runes)), nil }, TypeString, "Reverses the order of the string's characters.")}, "replace": {stringBuiltin3( "input", "find", "replace", func(input, from, to string) (Datum, error) { return NewDString(strings.Replace(input, from, to, -1)), nil }, TypeString, "Replaces all occurrences of `find` with `replace` in `input`", )}, "translate": {stringBuiltin3( "input", "find", "replace", func(s, from, to string) (Datum, error) { const deletionRune = utf8.MaxRune + 1 translation := make(map[rune]rune, len(from)) for _, fromRune := range from { toRune, size := utf8.DecodeRuneInString(to) if toRune == utf8.RuneError { toRune = deletionRune } else { to = to[size:] } translation[fromRune] = toRune } runes := make([]rune, 0, len(s)) for _, c := range s { if t, ok := translation[c]; ok { if t != deletionRune { runes = append(runes, t) } } else { runes = append(runes, c) } } return NewDString(string(runes)), nil }, TypeString, "In `input`, replaces the first character from `find` with the first "+ "character in `replace`; repeat for each character in `find`. <br/><br/>For example, "+ "`translate('doggie', 'dog', '123');` returns `1233ie`.")}, "regexp_extract": { Builtin{ Types: ArgTypes{{"input", TypeString}, {"regex", TypeString}}, ReturnType: fixedReturnType(TypeString), Info: "Returns the first match for the Regular Expression `regex` in `input`.", // contains filtered or unexported fields }, }, "regexp_replace": { Builtin{ Types: ArgTypes{ {"input", TypeString}, {"regex", TypeString}, {"replace", TypeString}, }, ReturnType: fixedReturnType(TypeString), Info: "Replaces matches for the Regular Expression `regex` in `input` with the " + "Regular Expression `replace`.", // contains filtered or unexported fields }, Builtin{ Types: ArgTypes{ {"input", TypeString}, {"regex", TypeString}, {"replace", TypeString}, {"flags", TypeString}, }, ReturnType: fixedReturnType(TypeString), Info: "Replaces matches for the Regular Expression `regex` in `input` with the Regular " + "Expression `replace` using `flags`.<br/><br/>CockroachDB supports the following " + "flags:<br/><br/>• **c**: Case-sensitive matching<br/><br/>• **g**: " + "Global matching (match each substring instead of only the first).<br/><br/>• " + "**i**: Case-insensitive matching<br/><br/>• **m** or **n**: Newline-sensitive " + "`.` and negated brackets (`[^...]`) do not match newline characters (preventing " + "matching: matches from crossing newlines unless explicitly defined to); `^` and " + "`$` match the space before and after newline characters respectively (so characters " + "between newline characters are treated as if they're on a separate line).<br/>" + "<br/>• **p**: Partial newline-sensitive matching: `.` and negated brackets " + "(`[^...]`) do not match newline characters (preventing matches from crossing " + "newlines unless explicitly defined to), but `^` and `$` still only match the " + "beginning and end of `val`.<br/><br/>• **s**: Newline-insensitive " + "matching *(default)*.<br/><br/>• **w**: Inverse partial newline-sensitive " + "matching:`.` and negated brackets (`[^...]`) *do* match newline characters, but `^` " + "and `$` match the space before and after newline characters respectively (so " + "characters between newline characters are treated as if they're on a separate line).", // contains filtered or unexported fields }, }, "initcap": {stringBuiltin1(func(s string) (Datum, error) { return NewDString(strings.Title(strings.ToLower(s))), nil }, TypeString, "Capitalizes the first letter of `val`.")}, "left": { Builtin{ Types: ArgTypes{{"input", TypeBytes}, {"return_set", TypeInt}}, ReturnType: fixedReturnType(TypeBytes), Info: "Returns the first `return_set` bytes from `input`.", // contains filtered or unexported fields }, Builtin{ Types: ArgTypes{{"input", TypeString}, {"return_set", TypeInt}}, ReturnType: fixedReturnType(TypeString), Info: "Returns the first `return_set` characters from `input`.", // contains filtered or unexported fields }, }, "right": { Builtin{ Types: ArgTypes{{"input", TypeBytes}, {"return_set", TypeInt}}, ReturnType: fixedReturnType(TypeBytes), Info: "Returns the last `return_set` bytes from `input`.", // contains filtered or unexported fields }, Builtin{ Types: ArgTypes{{"input", TypeString}, {"return_set", TypeInt}}, ReturnType: fixedReturnType(TypeString), Info: "Returns the last `return_set` characters from `input`.", // contains filtered or unexported fields }, }, "random": { Builtin{ Types: ArgTypes{}, ReturnType: fixedReturnType(TypeFloat), Info: "Returns a random float between 0 and 1.", // contains filtered or unexported fields }, }, "unique_rowid": { Builtin{ Types: ArgTypes{}, ReturnType: fixedReturnType(TypeInt), Info: "Returns a unique ID used by CockroachDB to generate unique row IDs if a " + "Primary Key isn't defined for the table. The value is a combination of the " + " insert timestamp and the ID of the node executing the statement, which " + " guarantees this combination is globally unique.", // contains filtered or unexported fields }, }, "experimental_uuid_v4": {uuidV4Impl}, "uuid_v4": {uuidV4Impl}, "greatest": { Builtin{ Types: HomogeneousType{}, ReturnType: identityReturnType(0), Info: "Returns the element with the greatest value.", // contains filtered or unexported fields }, }, "least": { Builtin{ Types: HomogeneousType{}, ReturnType: identityReturnType(0), Info: "Returns the element with the lowest value.", // contains filtered or unexported fields }, }, "experimental_strftime": { Builtin{ Types: ArgTypes{{"input", TypeTimestamp}, {"extract_format", TypeString}}, ReturnType: fixedReturnType(TypeString), Info: "From `input`, extracts and formats the time as identified in `extract_format` " + "using standard `strftime` notation (though not all formatting is supported).", // contains filtered or unexported fields }, Builtin{ Types: ArgTypes{{"input", TypeDate}, {"extract_format", TypeString}}, ReturnType: fixedReturnType(TypeString), Info: "From `input`, extracts and formats the time as identified in `extract_format` " + "using standard `strftime` notation (though not all formatting is supported).", // contains filtered or unexported fields }, Builtin{ Types: ArgTypes{{"input", TypeTimestampTZ}, {"extract_format", TypeString}}, ReturnType: fixedReturnType(TypeString), Info: "From `input`, extracts and formats the time as identified in `extract_format` " + "using standard `strftime` notation (though not all formatting is supported).", // contains filtered or unexported fields }, }, "experimental_strptime": { Builtin{ Types: ArgTypes{{"input", TypeString}, {"format", TypeString}}, ReturnType: fixedReturnType(TypeTimestampTZ), Info: "Returns `input` as a timestamptz using `format` (which uses standard " + "`strptime` formatting).", // contains filtered or unexported fields }, }, "age": { Builtin{ Types: ArgTypes{{"val", TypeTimestampTZ}}, ReturnType: fixedReturnType(TypeInterval), Info: "Calculates the interval between `val` and the current time.", // contains filtered or unexported fields }, Builtin{ Types: ArgTypes{{"begin", TypeTimestampTZ}, {"end", TypeTimestampTZ}}, ReturnType: fixedReturnType(TypeInterval), Info: "Calculates the interval between `begin` and `end`.", // contains filtered or unexported fields }, }, "current_date": { Builtin{ Types: ArgTypes{}, ReturnType: fixedReturnType(TypeDate), Info: "Returns the current date.", // contains filtered or unexported fields }, }, "now": txnTSImpl, "current_timestamp": txnTSImpl, "transaction_timestamp": txnTSImpl, "statement_timestamp": { Builtin{ Types: ArgTypes{}, ReturnType: fixedReturnType(TypeTimestampTZ), Info: "Returns the current statement's timestamp.", // contains filtered or unexported fields }, Builtin{ Types: ArgTypes{}, ReturnType: fixedReturnType(TypeTimestamp), Info: "Returns the current statement's timestamp.", // contains filtered or unexported fields }, }, "cluster_logical_timestamp": { Builtin{ Types: ArgTypes{}, ReturnType: fixedReturnType(TypeDecimal), Info: "This function is used only by CockroachDB's developers for testing purposes.", // contains filtered or unexported fields }, }, "clock_timestamp": { Builtin{ Types: ArgTypes{}, ReturnType: fixedReturnType(TypeTimestampTZ), Info: "Returns the current wallclock time.", // contains filtered or unexported fields }, Builtin{ Types: ArgTypes{}, ReturnType: fixedReturnType(TypeTimestamp), Info: "Returns the current wallclock time.", // contains filtered or unexported fields }, }, "extract": { Builtin{ Types: ArgTypes{{"element", TypeString}, {"input", TypeTimestamp}}, ReturnType: fixedReturnType(TypeInt), Info: "Extracts `element` from `input`. Compatible `elements` are: <br/>• " + "year<br/>• quarter<br/>• month<br/>• week<br/>• " + "dayofweek<br/>• dayofyear<br/>• hour<br/>• minute<br/>• " + "second<br/>• millisecond<br/>• microsecond<br/>• epoch", // contains filtered or unexported fields }, Builtin{ Types: ArgTypes{{"element", TypeString}, {"input", TypeDate}}, ReturnType: fixedReturnType(TypeInt), Info: "Extracts `element` from `input`. Compatible `elements` are: <br/>• " + "year<br/>• quarter<br/>• month<br/>• week<br/>• " + "dayofweek<br/>• dayofyear<br/>• hour<br/>• minute<br/>• " + "second<br/>• millisecond<br/>• microsecond<br/>• epoch", // contains filtered or unexported fields }, }, "extract_duration": { Builtin{ Types: ArgTypes{{"element", TypeString}, {"input", TypeInterval}}, ReturnType: fixedReturnType(TypeInt), Info: "Extracts `element` from `input`. Compatible `elements` are: <br/>• hour" + "<br/>• minute<br/>• second<br/>• millisecond<br/>• " + "microsecond", // contains filtered or unexported fields }, }, "abs": { floatBuiltin1(func(x float64) (Datum, error) { return NewDFloat(DFloat(math.Abs(x))), nil }, "Calculates the absolute value of `val`."), decimalBuiltin1(func(x *apd.Decimal) (Datum, error) { dd := &DDecimal{} dd.Abs(x) return dd, nil }, "Calculates the absolute value of `val`."), Builtin{ Types: ArgTypes{{"val", TypeInt}}, ReturnType: fixedReturnType(TypeInt), Info: "Calculates the absolute value of `val`.", // contains filtered or unexported fields }, }, "acos": { floatBuiltin1(func(x float64) (Datum, error) { return NewDFloat(DFloat(math.Acos(x))), nil }, "Calculates the inverse cosine of `val`."), }, "asin": { floatBuiltin1(func(x float64) (Datum, error) { return NewDFloat(DFloat(math.Asin(x))), nil }, "Calculates the inverse sine of `val`."), }, "atan": { floatBuiltin1(func(x float64) (Datum, error) { return NewDFloat(DFloat(math.Atan(x))), nil }, "Calculates the inverse tangent of `val`."), }, "atan2": { floatBuiltin2("x", "y", func(x, y float64) (Datum, error) { return NewDFloat(DFloat(math.Atan2(x, y))), nil }, "Calculates the inverse tangent of `x`/`y`."), }, "cbrt": { floatBuiltin1(func(x float64) (Datum, error) { return NewDFloat(DFloat(math.Cbrt(x))), nil }, "Calculates the cube root (∛) of `val`."), decimalBuiltin1(func(x *apd.Decimal) (Datum, error) { dd := &DDecimal{} _, err := DecimalCtx.Cbrt(&dd.Decimal, x) return dd, err }, "Calculates the cube root (∛) of `val`."), }, "ceil": ceilImpl, "ceiling": ceilImpl, "cos": { floatBuiltin1(func(x float64) (Datum, error) { return NewDFloat(DFloat(math.Cos(x))), nil }, "Calculates the cosine of `val`."), }, "cot": { floatBuiltin1(func(x float64) (Datum, error) { return NewDFloat(DFloat(1 / math.Tan(x))), nil }, "Calculates the cotangent of `val`."), }, "degrees": { floatBuiltin1(func(x float64) (Datum, error) { return NewDFloat(DFloat(180.0 * x / math.Pi)), nil }, "Converts `val` as a radian value to a degree value."), }, "div": { floatBuiltin2("x", "y", func(x, y float64) (Datum, error) { return NewDFloat(DFloat(math.Trunc(x / y))), nil }, "Calculates the integer quotient of `x`/`y`."), decimalBuiltin2("x", "y", func(x, y *apd.Decimal) (Datum, error) { if y.Sign() == 0 { return nil, errDivByZero } dd := &DDecimal{} _, err := HighPrecisionCtx.QuoInteger(&dd.Decimal, x, y) return dd, err }, "Calculates the integer quotient of `x`/`y`."), { Types: ArgTypes{{"x", TypeInt}, {"y", TypeInt}}, ReturnType: fixedReturnType(TypeInt), Info: "Calculates the integer quotient of `x`/`y`.", // contains filtered or unexported fields }, }, "exp": { floatBuiltin1(func(x float64) (Datum, error) { return NewDFloat(DFloat(math.Exp(x))), nil }, "Calculates *e* ^ `val`."), decimalBuiltin1(func(x *apd.Decimal) (Datum, error) { dd := &DDecimal{} _, err := DecimalCtx.Exp(&dd.Decimal, x) return dd, err }, "Calculates *e* ^ `val`."), }, "floor": { floatBuiltin1(func(x float64) (Datum, error) { return NewDFloat(DFloat(math.Floor(x))), nil }, "Calculates the largest integer not greater than `val`."), decimalBuiltin1(func(x *apd.Decimal) (Datum, error) { dd := &DDecimal{} _, err := ExactCtx.Floor(&dd.Decimal, x) return dd, err }, "Calculates the largest integer not greater than `val`."), }, "isnan": { Builtin{ Types: ArgTypes{{"val", TypeFloat}}, ReturnType: fixedReturnType(TypeBool), Info: "Returns true if `val` is NaN, false otherwise.", // contains filtered or unexported fields }, Builtin{ Types: ArgTypes{{"val", TypeDecimal}}, ReturnType: fixedReturnType(TypeBool), Info: "Returns true if `val` is NaN, false otherwise.", // contains filtered or unexported fields }, }, "ln": { floatBuiltin1(func(x float64) (Datum, error) { return NewDFloat(DFloat(math.Log(x))), nil }, "Calculates the natural log of `val`."), decimalLogFn(DecimalCtx.Ln, "Calculates the natural log of `val`."), }, "log": { floatBuiltin1(func(x float64) (Datum, error) { return NewDFloat(DFloat(math.Log10(x))), nil }, "Calculates the base 10 log of `val`."), decimalLogFn(DecimalCtx.Log10, "Calculates the base 10 log of `val`."), }, "mod": { floatBuiltin2("x", "y", func(x, y float64) (Datum, error) { return NewDFloat(DFloat(math.Mod(x, y))), nil }, "Calculates `x`%`y`."), decimalBuiltin2("x", "y", func(x, y *apd.Decimal) (Datum, error) { if y.Sign() == 0 { return nil, errZeroModulus } dd := &DDecimal{} _, err := HighPrecisionCtx.Rem(&dd.Decimal, x, y) return dd, err }, "Calculates `x`%`y`."), Builtin{ Types: ArgTypes{{"x", TypeInt}, {"y", TypeInt}}, ReturnType: fixedReturnType(TypeInt), Info: "Calculates `x`%`y`.", // contains filtered or unexported fields }, }, "pi": { Builtin{ Types: ArgTypes{}, ReturnType: fixedReturnType(TypeFloat), Info: "Returns the value for pi (3.141592653589793).", // contains filtered or unexported fields }, }, "pow": powImpls, "power": powImpls, "radians": { floatBuiltin1(func(x float64) (Datum, error) { return NewDFloat(DFloat(x * math.Pi / 180.0)), nil }, "Converts `val` as a degree value to a radians value."), }, "round": { floatBuiltin1(func(x float64) (Datum, error) { return NewDFloat(DFloat(round(x))), nil }, "Rounds `val` to the nearest integer using half to even (banker's) rounding."), decimalBuiltin1(func(x *apd.Decimal) (Datum, error) { return roundDecimal(x, 0) }, "Rounds `val` to the nearest integer, half away from zero: "+ "ROUND(+/-2.4) = +/-2, ROUND(+/-2.5) = +/-3."), Builtin{ Types: ArgTypes{{"input", TypeFloat}, {"decimal_accuracy", TypeInt}}, ReturnType: fixedReturnType(TypeFloat), Info: "Keeps `decimal_accuracy` number of figures to the right of the zero position " + " in `input` using half to even (banker's) rounding.", // contains filtered or unexported fields }, Builtin{ Types: ArgTypes{{"input", TypeDecimal}, {"decimal_accuracy", TypeInt}}, ReturnType: fixedReturnType(TypeDecimal), Info: "Keeps `decimal_accuracy` number of figures to the right of the zero position " + " in `input using half away from zero rounding. If `decimal_accuracy` " + "is not in the range -2^31...(2^31-1), the results are undefined.", // contains filtered or unexported fields }, }, "sin": { floatBuiltin1(func(x float64) (Datum, error) { return NewDFloat(DFloat(math.Sin(x))), nil }, "Calculates the sine of `val`."), }, "sign": { floatBuiltin1(func(x float64) (Datum, error) { switch { case x < 0: return NewDFloat(-1), nil case x == 0: return NewDFloat(0), nil } return NewDFloat(1), nil }, "Determines the sign of `val`: **1** for positive; **0** for 0 values; **-1** for "+ "negative."), decimalBuiltin1(func(x *apd.Decimal) (Datum, error) { d := &DDecimal{} d.Decimal.SetCoefficient(int64(x.Sign())) return d, nil }, "Determines the sign of `val`: **1** for positive; **0** for 0 values; **-1** for "+ "negative."), Builtin{ Types: ArgTypes{{"val", TypeInt}}, ReturnType: fixedReturnType(TypeInt), Info: "Determines the sign of `val`: **1** for positive; **0** for 0 values; **-1** " + "for negative.", // contains filtered or unexported fields }, }, "sqrt": { floatBuiltin1(func(x float64) (Datum, error) { if x < 0 { return nil, errSqrtOfNegNumber } return NewDFloat(DFloat(math.Sqrt(x))), nil }, "Calculates the square root of `val`."), decimalBuiltin1(func(x *apd.Decimal) (Datum, error) { if x.Sign() < 0 { return nil, errSqrtOfNegNumber } dd := &DDecimal{} _, err := DecimalCtx.Sqrt(&dd.Decimal, x) return dd, err }, "Calculates the square root of `val`."), }, "tan": { floatBuiltin1(func(x float64) (Datum, error) { return NewDFloat(DFloat(math.Tan(x))), nil }, "Calculates the tangent of `val`."), }, "trunc": { floatBuiltin1(func(x float64) (Datum, error) { return NewDFloat(DFloat(math.Trunc(x))), nil }, "Truncates the decimal values of `val`."), decimalBuiltin1(func(x *apd.Decimal) (Datum, error) { dd := &DDecimal{} frac := new(apd.Decimal) x.Modf(&dd.Decimal, frac) return dd, nil }, "Truncates the decimal values of `val`."), }, "to_english": { Builtin{ Types: ArgTypes{{"val", TypeInt}}, ReturnType: fixedReturnType(TypeString), Info: "This function enunciates the value of its argument using English cardinals.", // contains filtered or unexported fields }, }, "array_length": { Builtin{ Types: ArgTypes{{"input", TypeAnyArray}, {"array_dimension", TypeInt}}, ReturnType: fixedReturnType(TypeInt), Info: "Calculates the length of `input` on the provided `array_dimension`. However, " + "because CockroachDB doesn't yet support multi-dimensional arrays, the only supported" + " `array_dimension` is **1**.", // contains filtered or unexported fields }, }, "array_lower": { Builtin{ Types: ArgTypes{{"input", TypeAnyArray}, {"array_dimension", TypeInt}}, ReturnType: fixedReturnType(TypeInt), Info: "Calculates the minimum value of `input` on the provided `array_dimension`. " + "However, because CockroachDB doesn't yet support multi-dimensional arrays, the only " + "supported `array_dimension` is **1**.", // contains filtered or unexported fields }, }, "array_upper": { Builtin{ Types: ArgTypes{{"input", TypeAnyArray}, {"array_dimension", TypeInt}}, ReturnType: fixedReturnType(TypeInt), Info: "Calculates the maximum value of `input` on the provided `array_dimension`. " + "However, because CockroachDB doesn't yet support multi-dimensional arrays, the only " + "supported `array_dimension` is **1**.", // contains filtered or unexported fields }, }, "version": { Builtin{ Types: ArgTypes{}, ReturnType: fixedReturnType(TypeString), Info: "Returns the node's version of CockroachDB.", // contains filtered or unexported fields }, }, "current_database": { Builtin{ Types: ArgTypes{}, ReturnType: fixedReturnType(TypeString), Info: "Returns the current database.", // contains filtered or unexported fields }, }, "current_schema": { Builtin{ Types: ArgTypes{}, ReturnType: fixedReturnType(TypeString), Info: "Returns the current schema. This function is provided for " + "compatibility with PostgreSQL. For a new CockroachDB application, " + "consider using current_database() instead.", // contains filtered or unexported fields }, }, "current_schemas": { Builtin{ Types: ArgTypes{{"include_pg_catalog", TypeBool}}, ReturnType: fixedReturnType(TypeStringArray), Info: "Returns the current search path for unqualified names.", // contains filtered or unexported fields }, }, "crdb_internal.force_internal_error": { Builtin{ Types: ArgTypes{{"msg", TypeString}}, ReturnType: fixedReturnType(TypeInt), Info: "This function is used only by CockroachDB's developers for testing purposes.", // contains filtered or unexported fields }, }, "crdb_internal.force_panic": { Builtin{ Types: ArgTypes{{"msg", TypeString}}, ReturnType: fixedReturnType(TypeInt), Info: "This function is used only by CockroachDB's developers for testing purposes.", // contains filtered or unexported fields }, }, "crdb_internal.force_log_fatal": { Builtin{ Types: ArgTypes{{"msg", TypeString}}, ReturnType: fixedReturnType(TypeInt), Info: "This function is used only by CockroachDB's developers for testing purposes.", // contains filtered or unexported fields }, }, "crdb_internal.force_retry": { Builtin{ Types: ArgTypes{{"val", TypeInterval}}, ReturnType: fixedReturnType(TypeInt), Info: "This function is used only by CockroachDB's developers for testing purposes.", // contains filtered or unexported fields }, Builtin{ Types: ArgTypes{ {"val", TypeInterval}, {"txnID", TypeString}}, ReturnType: fixedReturnType(TypeInt), Info: "This function is used only by CockroachDB's developers for testing purposes.", // contains filtered or unexported fields }, }, }
Builtins contains the built-in functions indexed by name.
var CmpOps = map[ComparisonOperator]cmpOpOverload{ EQ: { CmpOp{ LeftType: TypeString, RightType: TypeString, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeCollatedString, RightType: TypeCollatedString, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeBytes, RightType: TypeBytes, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeBool, RightType: TypeBool, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeInt, RightType: TypeInt, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeFloat, RightType: TypeFloat, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeDecimal, RightType: TypeDecimal, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeFloat, RightType: TypeInt, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeInt, RightType: TypeFloat, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeDecimal, RightType: TypeInt, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeInt, RightType: TypeDecimal, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeDecimal, RightType: TypeFloat, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeFloat, RightType: TypeDecimal, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeDate, RightType: TypeDate, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeTimestamp, RightType: TypeTimestamp, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeTimestampTZ, RightType: TypeTimestampTZ, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeTimestamp, RightType: TypeTimestampTZ, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeTimestampTZ, RightType: TypeTimestamp, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeDate, RightType: TypeTimestampTZ, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeDate, RightType: TypeTimestamp, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeTimestampTZ, RightType: TypeDate, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeTimestamp, RightType: TypeDate, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeInterval, RightType: TypeInterval, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeOid, RightType: TypeOid, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeTuple, RightType: TypeTuple, // contains filtered or unexported fields }, }, LT: { CmpOp{ LeftType: TypeString, RightType: TypeString, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeCollatedString, RightType: TypeCollatedString, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeBytes, RightType: TypeBytes, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeBool, RightType: TypeBool, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeInt, RightType: TypeInt, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeFloat, RightType: TypeFloat, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeDecimal, RightType: TypeDecimal, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeFloat, RightType: TypeInt, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeInt, RightType: TypeFloat, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeDecimal, RightType: TypeInt, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeInt, RightType: TypeDecimal, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeDecimal, RightType: TypeFloat, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeFloat, RightType: TypeDecimal, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeDate, RightType: TypeDate, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeTimestamp, RightType: TypeTimestamp, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeTimestampTZ, RightType: TypeTimestampTZ, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeTimestamp, RightType: TypeTimestampTZ, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeTimestampTZ, RightType: TypeTimestamp, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeDate, RightType: TypeTimestampTZ, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeDate, RightType: TypeTimestamp, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeTimestampTZ, RightType: TypeDate, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeTimestamp, RightType: TypeDate, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeInterval, RightType: TypeInterval, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeTuple, RightType: TypeTuple, // contains filtered or unexported fields }, }, LE: { CmpOp{ LeftType: TypeString, RightType: TypeString, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeCollatedString, RightType: TypeCollatedString, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeBytes, RightType: TypeBytes, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeBool, RightType: TypeBool, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeInt, RightType: TypeInt, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeFloat, RightType: TypeFloat, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeDecimal, RightType: TypeDecimal, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeFloat, RightType: TypeInt, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeInt, RightType: TypeFloat, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeDecimal, RightType: TypeInt, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeInt, RightType: TypeDecimal, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeDecimal, RightType: TypeFloat, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeFloat, RightType: TypeDecimal, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeDate, RightType: TypeDate, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeTimestamp, RightType: TypeTimestamp, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeTimestampTZ, RightType: TypeTimestampTZ, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeTimestampTZ, RightType: TypeTimestamp, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeTimestamp, RightType: TypeTimestampTZ, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeDate, RightType: TypeTimestampTZ, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeDate, RightType: TypeTimestamp, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeTimestampTZ, RightType: TypeDate, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeTimestamp, RightType: TypeDate, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeInterval, RightType: TypeInterval, // contains filtered or unexported fields }, CmpOp{ LeftType: TypeTuple, RightType: TypeTuple, // contains filtered or unexported fields }, }, In: { makeEvalTupleIn(TypeBool), makeEvalTupleIn(TypeInt), makeEvalTupleIn(TypeFloat), makeEvalTupleIn(TypeDecimal), makeEvalTupleIn(TypeString), makeEvalTupleIn(TypeCollatedString), makeEvalTupleIn(TypeBytes), makeEvalTupleIn(TypeDate), makeEvalTupleIn(TypeTimestamp), makeEvalTupleIn(TypeTimestampTZ), makeEvalTupleIn(TypeInterval), makeEvalTupleIn(TypeTuple), }, Like: { CmpOp{ LeftType: TypeString, RightType: TypeString, // contains filtered or unexported fields }, }, ILike: { CmpOp{ LeftType: TypeString, RightType: TypeString, // contains filtered or unexported fields }, }, SimilarTo: { CmpOp{ LeftType: TypeString, RightType: TypeString, // contains filtered or unexported fields }, }, RegMatch: { CmpOp{ LeftType: TypeString, RightType: TypeString, // contains filtered or unexported fields }, }, RegIMatch: { CmpOp{ LeftType: TypeString, RightType: TypeString, // contains filtered or unexported fields }, }, }
CmpOps contains the comparison operations indexed by operation type.
var Generators = map[string][]Builtin{ "generate_series": { makeGeneratorBuiltin( ArgTypes{{"start", TypeInt}, {"end", TypeInt}}, TTuple{TypeInt}, makeSeriesGenerator, "Produces a virtual table containing the integer values from `start` to `end`, inclusive.", ), makeGeneratorBuiltin( ArgTypes{{"start", TypeInt}, {"end", TypeInt}, {"step", TypeInt}}, TTuple{TypeInt}, makeSeriesGenerator, "Produces a virtual table containing the integer values from `start` to `end`, inclusive, by increment of `step`.", ), }, "unnest": { makeGeneratorBuiltinWithReturnType( ArgTypes{{"input", TypeAnyArray}}, func(args []TypedExpr) Type { if len(args) == 0 { return unknownReturnType } return TTable{Cols: TTuple{args[0].ResolvedType().(TArray).Typ}} }, makeArrayGenerator, "Returns the input array as a set of rows", ), }, }
Generators is a map from name to slice of Builtins for all built-in generators.
var OidToType = map[oid.Oid]Type{ oid.T_anyelement: TypeAny, oid.T_bool: TypeBool, oid.T_bytea: TypeBytes, oid.T_date: TypeDate, oid.T_float4: typeFloat4, oid.T_float8: TypeFloat, oid.T_int2: typeInt2, oid.T_int4: typeInt4, oid.T_int8: TypeInt, oid.T_int2vector: TypeIntVector, oid.T_interval: TypeInterval, oid.T_name: TypeName, oid.T_numeric: TypeDecimal, oid.T_oid: TypeOid, oid.T_regclass: TypeRegClass, oid.T_regnamespace: TypeRegNamespace, oid.T_regproc: TypeRegProc, oid.T_regprocedure: TypeRegProcedure, oid.T_regtype: TypeRegType, oid.T__text: TypeStringArray, oid.T__int2: typeInt2Array, oid.T__int4: typeInt4Array, oid.T__int8: TypeIntArray, oid.T_record: TypeTuple, oid.T_text: TypeString, oid.T_timestamp: TypeTimestamp, oid.T_timestamptz: TypeTimestampTZ, oid.T_varchar: typeVarChar, }
OidToType maps Postgres object IDs to CockroachDB types.
var StarDatumInstance = &StarDatum{}
StarDatumInstance can be used as common instance for all uses of StarDatum.
var UnaryOps = map[UnaryOperator]unaryOpOverload{ UnaryPlus: { UnaryOp{ Typ: TypeInt, ReturnType: TypeInt, // contains filtered or unexported fields }, UnaryOp{ Typ: TypeFloat, ReturnType: TypeFloat, // contains filtered or unexported fields }, UnaryOp{ Typ: TypeDecimal, ReturnType: TypeDecimal, // contains filtered or unexported fields }, }, UnaryMinus: { UnaryOp{ Typ: TypeInt, ReturnType: TypeInt, // contains filtered or unexported fields }, UnaryOp{ Typ: TypeFloat, ReturnType: TypeFloat, // contains filtered or unexported fields }, UnaryOp{ Typ: TypeDecimal, ReturnType: TypeDecimal, // contains filtered or unexported fields }, UnaryOp{ Typ: TypeInterval, ReturnType: TypeInterval, // contains filtered or unexported fields }, }, UnaryComplement: { UnaryOp{ Typ: TypeInt, ReturnType: TypeInt, // contains filtered or unexported fields }, }, }
UnaryOps contains the unary operations indexed by operation type.
Functions ¶
func AsStringWithFlags ¶
func AsStringWithFlags(n NodeFormatter, f FmtFlags) string
AsStringWithFlags pretty prints a node to a string given specific flags.
func ContainsVars ¶
ContainsVars returns true if the expression contains any variables. (variables = sub-expressions, placeholders, indexed vars, etc.)
func ExprDebugString ¶
ExprDebugString generates a multi-line debug string with one node per line in Go format.
func FindEqualComparisonFunction ¶
func FindEqualComparisonFunction( leftType, rightType Type, ) (func(*EvalContext, Datum, Datum) (Datum, error), bool)
FindEqualComparisonFunction looks up an overload of the "=" operator for a given pair of input operand types.
func FormatNode ¶
func FormatNode(buf *bytes.Buffer, f FmtFlags, n NodeFormatter)
FormatNode recurses into a node for pretty-printing. Flag-driven special cases can hook into this.
func HasReturningClause ¶
func HasReturningClause(clause ReturningClause) bool
HasReturningClause determines if a ReturningClause is present, given a variant of the ReturningClause interface.
func IsNumericOne ¶
IsNumericOne returns true if the datum is a number and equal to one.
func IsNumericZero ¶
IsNumericZero returns true if the datum is a number and equal to zero.
func LimitDecimalWidth ¶
LimitDecimalWidth limits d's precision (total number of digits) and scale (number of digits after the decimal point).
func PGDisplayName ¶
PGDisplayName returns the Postgres display name for a given type.
func PGIOBuiltinPrefix ¶
PGIOBuiltinPrefix returns the string prefix to a type's IO functions. This is either the type's postgres display name or the type's postgres display name plus an underscore, depending on the type.
func ReNormalizeName ¶
ReNormalizeName performs the same work as NormalizeName but when the string originates from the database. We define a different function so as to be able to track usage of this function (cf. #8200).
func Serialize ¶
func Serialize(n NodeFormatter) string
Serialize pretty prints a node to a string using FmtParsable; it is appropriate when we store expressions into strings that are later parsed back into expressions.
func SimilarEscape ¶
SimilarEscape converts a SQL:2008 regexp pattern to POSIX style, so it can be used by our regexp engine.
func StmtDebugString ¶
StmtDebugString generates multi-line debug strings in Go format for the expressions that are part of the given statement.
func ValidateRestartCheckpoint ¶
ValidateRestartCheckpoint checks that a checkpoint name is our magic restart value. We accept everything with the desired prefix because at least the C++ libpqxx appends sequence numbers to the savepoint name specified by the user.
func WalkExprConst ¶
WalkExprConst is a variant of WalkExpr for visitors that do not modify the expression.
Types ¶
type AggregateFunc ¶
type AggregateFunc interface { // Add accumulates the passed datum into the AggregateFunc. Add(context.Context, Datum) error // Result returns the current value of the accumulation. This value // will be a deep copy of any AggregateFunc internal state, so that // it will not be mutated by additional calls to Add. Result() (Datum, error) // Close closes out the AggregateFunc and allows it to release any memory it // requested during aggregation, and must be called upon completion of the // aggregation. Close(context.Context) }
AggregateFunc accumulates the result of a function of a Datum.
func NewIdentAggregate ¶
func NewIdentAggregate(*EvalContext) AggregateFunc
NewIdentAggregate returns an identAggregate (see comment on struct).
type AliasClause ¶
AliasClause represents an alias, optionally with a column list: "AS name" or "AS name(col1, col2)".
type AliasedTableExpr ¶
type AliasedTableExpr struct { Expr TableExpr Hints *IndexHints Ordinality bool As AliasClause }
AliasedTableExpr represents a table expression coupled with an optional alias.
func (*AliasedTableExpr) Format ¶
func (node *AliasedTableExpr) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*AliasedTableExpr) String ¶
func (node *AliasedTableExpr) String() string
type AllColumnsSelector ¶
type AllColumnsSelector struct {
TableName
}
AllColumnsSelector corresponds to a selection of all columns in a table when used in a SELECT clause. (e.g. `table.*`)
func (*AllColumnsSelector) Eval ¶
func (expr *AllColumnsSelector) Eval(ctx *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (*AllColumnsSelector) Format ¶
func (a *AllColumnsSelector) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*AllColumnsSelector) NormalizeVarName ¶
func (a *AllColumnsSelector) NormalizeVarName() (VarName, error)
NormalizeVarName is a no-op for AllColumnsSelector (already normalized)
func (*AllColumnsSelector) ResolvedType ¶
func (*AllColumnsSelector) ResolvedType() Type
ResolvedType implements the TypedExpr interface.
func (*AllColumnsSelector) String ¶
func (a *AllColumnsSelector) String() string
func (*AllColumnsSelector) TypeCheck ¶
func (expr *AllColumnsSelector) TypeCheck(_ *SemaContext, desired Type) (TypedExpr, error)
TypeCheck implements the Expr interface.
func (*AllColumnsSelector) Variable ¶
func (a *AllColumnsSelector) Variable()
Variable implements the VariableExpr interface. Although, the AllColumnsSelector ought to be replaced to an IndexedVar before the points the VariableExpr interface is used.
func (*AllColumnsSelector) Walk ¶
func (expr *AllColumnsSelector) Walk(_ Visitor) Expr
Walk implements the Expr interface.
type AllTablesSelector ¶
type AllTablesSelector struct {
Database Name
}
AllTablesSelector corresponds to a selection of all tables in a database, e.g. when used with GRANT.
func (*AllTablesSelector) Format ¶
func (at *AllTablesSelector) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*AllTablesSelector) NormalizeTablePattern ¶
func (at *AllTablesSelector) NormalizeTablePattern() (TablePattern, error)
NormalizeTablePattern implements the TablePattern interface.
func (*AllTablesSelector) QualifyWithDatabase ¶
func (at *AllTablesSelector) QualifyWithDatabase(database string) error
QualifyWithDatabase adds an indirection for the database, if it's missing. It transforms: * -> database.*
func (*AllTablesSelector) String ¶
func (at *AllTablesSelector) String() string
type AlterTable ¶
type AlterTable struct { IfExists bool Table NormalizableTableName Cmds AlterTableCmds }
AlterTable represents an ALTER TABLE statement.
func (*AlterTable) Format ¶
func (node *AlterTable) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*AlterTable) StatementTag ¶
func (*AlterTable) StatementTag() string
StatementTag returns a short string identifying the type of statement.
func (*AlterTable) StatementType ¶
func (*AlterTable) StatementType() StatementType
StatementType implements the Statement interface.
func (*AlterTable) String ¶
func (n *AlterTable) String() string
type AlterTableAddColumn ¶
type AlterTableAddColumn struct { IfNotExists bool ColumnDef *ColumnTableDef // contains filtered or unexported fields }
AlterTableAddColumn represents an ADD COLUMN command.
func (*AlterTableAddColumn) Format ¶
func (node *AlterTableAddColumn) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*AlterTableAddColumn) String ¶
func (n *AlterTableAddColumn) String() string
type AlterTableAddConstraint ¶
type AlterTableAddConstraint struct { ConstraintDef ConstraintTableDef ValidationBehavior ValidationBehavior }
AlterTableAddConstraint represents an ADD CONSTRAINT command.
func (*AlterTableAddConstraint) Format ¶
func (node *AlterTableAddConstraint) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*AlterTableAddConstraint) String ¶
func (n *AlterTableAddConstraint) String() string
type AlterTableCmd ¶
type AlterTableCmd interface { NodeFormatter // contains filtered or unexported methods }
AlterTableCmd represents a table modification operation.
type AlterTableCmds ¶
type AlterTableCmds []AlterTableCmd
AlterTableCmds represents a list of table alterations.
func (AlterTableCmds) Format ¶
func (node AlterTableCmds) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (AlterTableCmds) String ¶
func (n AlterTableCmds) String() string
type AlterTableDropColumn ¶
type AlterTableDropColumn struct { IfExists bool Column Name DropBehavior DropBehavior // contains filtered or unexported fields }
AlterTableDropColumn represents a DROP COLUMN command.
func (*AlterTableDropColumn) Format ¶
func (node *AlterTableDropColumn) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*AlterTableDropColumn) String ¶
func (n *AlterTableDropColumn) String() string
type AlterTableDropConstraint ¶
type AlterTableDropConstraint struct { IfExists bool Constraint Name DropBehavior DropBehavior }
AlterTableDropConstraint represents a DROP CONSTRAINT command.
func (*AlterTableDropConstraint) Format ¶
func (node *AlterTableDropConstraint) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*AlterTableDropConstraint) String ¶
func (n *AlterTableDropConstraint) String() string
type AlterTableDropNotNull ¶
type AlterTableDropNotNull struct { Column Name // contains filtered or unexported fields }
AlterTableDropNotNull represents an ALTER COLUMN DROP NOT NULL command.
func (*AlterTableDropNotNull) Format ¶
func (node *AlterTableDropNotNull) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*AlterTableDropNotNull) GetColumn ¶
func (node *AlterTableDropNotNull) GetColumn() Name
GetColumn implements the ColumnMutationCmd interface.
func (*AlterTableDropNotNull) String ¶
func (n *AlterTableDropNotNull) String() string
type AlterTableSetDefault ¶
type AlterTableSetDefault struct { Column Name Default Expr // contains filtered or unexported fields }
AlterTableSetDefault represents an ALTER COLUMN SET DEFAULT or DROP DEFAULT command.
func (*AlterTableSetDefault) Format ¶
func (node *AlterTableSetDefault) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*AlterTableSetDefault) GetColumn ¶
func (node *AlterTableSetDefault) GetColumn() Name
GetColumn implements the ColumnMutationCmd interface.
func (*AlterTableSetDefault) String ¶
func (n *AlterTableSetDefault) String() string
type AlterTableValidateConstraint ¶
type AlterTableValidateConstraint struct {
Constraint Name
}
AlterTableValidateConstraint represents a VALIDATE CONSTRAINT command.
type AndExpr ¶
type AndExpr struct {
Left, Right Expr
// contains filtered or unexported fields
}
AndExpr represents an AND expression.
func NewTypedAndExpr ¶
NewTypedAndExpr returns a new AndExpr that is verified to be well-typed.
func (*AndExpr) Eval ¶
func (expr *AndExpr) Eval(ctx *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (AndExpr) ResolvedType ¶
func (ta AndExpr) ResolvedType() Type
func (*AndExpr) TypeCheck ¶
func (expr *AndExpr) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
TypeCheck implements the Expr interface.
func (*AndExpr) TypedRight ¶
TypedRight returns the AndExpr's right expression as a TypedExpr.
type AnnotateTypeExpr ¶
type AnnotateTypeExpr struct { Expr Expr Type CastTargetType // contains filtered or unexported fields }
AnnotateTypeExpr represents a ANNOTATE_TYPE(expr, type) expression.
func (*AnnotateTypeExpr) Format ¶
func (node *AnnotateTypeExpr) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*AnnotateTypeExpr) String ¶
func (node *AnnotateTypeExpr) String() string
func (*AnnotateTypeExpr) TypeCheck ¶
func (expr *AnnotateTypeExpr) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
TypeCheck implements the Expr interface.
func (*AnnotateTypeExpr) TypedInnerExpr ¶
func (node *AnnotateTypeExpr) TypedInnerExpr() TypedExpr
TypedInnerExpr returns the AnnotateTypeExpr's inner expression as a TypedExpr.
func (*AnnotateTypeExpr) Walk ¶
func (expr *AnnotateTypeExpr) Walk(v Visitor) Expr
Walk implements the Expr interface.
type ArgTypes ¶
ArgTypes is very similar to ArgTypes except it allows keeping a string name for each argument as well and using those when printing the human-readable signature.
type Array ¶
type Array struct { Exprs Exprs // contains filtered or unexported fields }
Array represents an array constructor.
func (*Array) Eval ¶
func (t *Array) Eval(ctx *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (Array) ResolvedType ¶
func (ta Array) ResolvedType() Type
type ArrayColType ¶
type ArrayColType struct { Name string // ParamTyp is the type of the elements in this array. ParamType ColumnType BoundsExprs Exprs }
ArrayColType represents an ARRAY column type.
func (*ArrayColType) Format ¶
func (node *ArrayColType) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*ArrayColType) String ¶
func (node *ArrayColType) String() string
type ArrayFlatten ¶
type ArrayFlatten struct { Subquery Expr // contains filtered or unexported fields }
ArrayFlatten represents a subquery array constructor.
func (*ArrayFlatten) Eval ¶
func (t *ArrayFlatten) Eval(ctx *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (*ArrayFlatten) Format ¶
func (node *ArrayFlatten) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (ArrayFlatten) ResolvedType ¶
func (ta ArrayFlatten) ResolvedType() Type
func (*ArrayFlatten) String ¶
func (node *ArrayFlatten) String() string
func (*ArrayFlatten) TypeCheck ¶
func (expr *ArrayFlatten) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
TypeCheck implements the Expr interface.
func (*ArrayFlatten) Walk ¶
func (expr *ArrayFlatten) Walk(v Visitor) Expr
Walk implements the Expr interface.
type ArraySubscript ¶
ArraySubscript corresponds to the syntax `<name>[ ... ]`.
type ArraySubscripts ¶
type ArraySubscripts []*ArraySubscript
ArraySubscripts represents a sequence of one or more array subscripts.
type Backup ¶
type Backup struct { Targets TargetList To Expr IncrementalFrom Exprs AsOf AsOfClause Options KVOptions }
Backup represents a BACKUP statement.
func (*Backup) StatementTag ¶
StatementTag returns a short string identifying the type of statement.
func (*Backup) StatementType ¶
func (*Backup) StatementType() StatementType
StatementType implements the Statement interface.
type BeginTransaction ¶
type BeginTransaction struct { Isolation IsolationLevel UserPriority UserPriority }
BeginTransaction represents a BEGIN statement
func (*BeginTransaction) Format ¶
func (node *BeginTransaction) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*BeginTransaction) StatementTag ¶
func (*BeginTransaction) StatementTag() string
StatementTag returns a short string identifying the type of statement.
func (*BeginTransaction) StatementType ¶
func (*BeginTransaction) StatementType() StatementType
StatementType implements the Statement interface.
func (*BeginTransaction) String ¶
func (n *BeginTransaction) String() string
type BinOp ¶
type BinOp struct { LeftType Type RightType Type ReturnType Type // contains filtered or unexported fields }
BinOp is a binary operator.
type BinaryExpr ¶
type BinaryExpr struct { Operator BinaryOperator Left, Right Expr // contains filtered or unexported fields }
BinaryExpr represents a binary value expression.
func (*BinaryExpr) Eval ¶
func (expr *BinaryExpr) Eval(ctx *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (*BinaryExpr) Format ¶
func (node *BinaryExpr) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (BinaryExpr) ResolvedType ¶
func (ta BinaryExpr) ResolvedType() Type
func (*BinaryExpr) String ¶
func (node *BinaryExpr) String() string
func (*BinaryExpr) TypeCheck ¶
func (expr *BinaryExpr) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
TypeCheck implements the Expr interface.
func (*BinaryExpr) TypedLeft ¶
func (node *BinaryExpr) TypedLeft() TypedExpr
TypedLeft returns the BinaryExpr's left expression as a TypedExpr.
func (*BinaryExpr) TypedRight ¶
func (node *BinaryExpr) TypedRight() TypedExpr
TypedRight returns the BinaryExpr's right expression as a TypedExpr.
func (*BinaryExpr) Walk ¶
func (expr *BinaryExpr) Walk(v Visitor) Expr
Walk implements the Expr interface.
type BinaryOperator ¶
type BinaryOperator int
BinaryOperator represents a binary operator.
const ( Bitand BinaryOperator = iota Bitor Bitxor Plus Minus Mult Div FloorDiv Mod Pow Concat LShift RShift )
BinaryExpr.Operator
func (BinaryOperator) String ¶
func (i BinaryOperator) String() string
type BoolColType ¶
type BoolColType struct {
Name string
}
BoolColType represents a BOOLEAN type.
func (*BoolColType) Format ¶
func (node *BoolColType) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*BoolColType) String ¶
func (node *BoolColType) String() string
type Builtin ¶
type Builtin struct { Types typeList ReturnType returnTyper // Info is a description of the function, which is surfaced on the CockroachDB // docs site on the "Functions and Operators" page. Descriptions typically use // third-person with the function as an implicit subject (e.g. "Calculates // infinity"), but should focus more on ease of understanding so other structures // might be more appropriate. Info string AggregateFunc func([]Type, *EvalContext) AggregateFunc WindowFunc func([]Type, *EvalContext) WindowFunc // contains filtered or unexported fields }
Builtin is a built-in function.
func (Builtin) Class ¶
func (b Builtin) Class() FunctionClass
Class returns the FunctionClass of this builtin.
func (Builtin) DistSQLBlacklist ¶
DistSQLBlacklist returns true if the builtin is not supported by DistSQL. See distsqlBlacklist.
func (Builtin) FixedReturnType ¶
FixedReturnType returns a fixed type that the function returns, returning Any if the return type is based on the function's arguments.
type BytesColType ¶
type BytesColType struct {
Name string
}
BytesColType represents a BYTES or BLOB type.
func (*BytesColType) Format ¶
func (node *BytesColType) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*BytesColType) String ¶
func (node *BytesColType) String() string
type CaseExpr ¶
type CaseExpr struct { Expr Expr Whens []*When Else Expr // contains filtered or unexported fields }
CaseExpr represents a CASE expression.
func (*CaseExpr) CopyNode ¶
CopyNode makes a copy of this Expr without recursing in any child Exprs.
func (*CaseExpr) Eval ¶
func (expr *CaseExpr) Eval(ctx *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (CaseExpr) ResolvedType ¶
func (ta CaseExpr) ResolvedType() Type
type CastExpr ¶
type CastExpr struct { Expr Expr Type CastTargetType // contains filtered or unexported fields }
CastExpr represents a CAST(expr AS type) expression.
func (*CastExpr) Eval ¶
func (expr *CastExpr) Eval(ctx *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (CastExpr) ResolvedType ¶
func (ta CastExpr) ResolvedType() Type
type CastTargetType ¶
type CastTargetType interface { fmt.Stringer NodeFormatter // contains filtered or unexported methods }
CastTargetType represents a type that is a valid cast target.
type CheckConstraintTableDef ¶
CheckConstraintTableDef represents a check constraint within a CREATE TABLE statement.
type CoalesceExpr ¶
CoalesceExpr represents a COALESCE or IFNULL expression.
func (*CoalesceExpr) CopyNode ¶
func (expr *CoalesceExpr) CopyNode() *CoalesceExpr
CopyNode makes a copy of this Expr without recursing in any child Exprs.
func (*CoalesceExpr) Eval ¶
func (expr *CoalesceExpr) Eval(ctx *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (*CoalesceExpr) Format ¶
func (node *CoalesceExpr) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (CoalesceExpr) ResolvedType ¶
func (ta CoalesceExpr) ResolvedType() Type
func (*CoalesceExpr) String ¶
func (node *CoalesceExpr) String() string
func (*CoalesceExpr) TypeCheck ¶
func (expr *CoalesceExpr) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
TypeCheck implements the Expr interface.
func (*CoalesceExpr) TypedExprAt ¶
func (node *CoalesceExpr) TypedExprAt(idx int) TypedExpr
TypedExprAt returns the expression at the specified index as a TypedExpr.
func (*CoalesceExpr) Walk ¶
func (expr *CoalesceExpr) Walk(v Visitor) Expr
Walk implements the Expr interface.
type CollateExpr ¶
CollateExpr represents an (expr COLLATE locale) expression.
func (*CollateExpr) Eval ¶
func (expr *CollateExpr) Eval(ctx *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (*CollateExpr) Format ¶
func (node *CollateExpr) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (CollateExpr) ResolvedType ¶
func (ta CollateExpr) ResolvedType() Type
func (*CollateExpr) String ¶
func (node *CollateExpr) String() string
func (*CollateExpr) TypeCheck ¶
func (expr *CollateExpr) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
TypeCheck implements the Expr interface.
func (*CollateExpr) Walk ¶
func (expr *CollateExpr) Walk(v Visitor) Expr
Walk implements the Expr interface.
type CollatedStringColType ¶
CollatedStringColType represents a STRING, CHAR or VARCHAR type with a collation locale.
func (*CollatedStringColType) Format ¶
func (node *CollatedStringColType) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*CollatedStringColType) String ¶
func (node *CollatedStringColType) String() string
type CollationEnvironment ¶
type CollationEnvironment struct {
// contains filtered or unexported fields
}
CollationEnvironment stores the state needed by NewDCollatedString to construct collation keys efficiently.
type ColumnCheckConstraint ¶
type ColumnCheckConstraint struct {
Expr Expr
}
ColumnCheckConstraint represents either a check on a column.
type ColumnCollation ¶
type ColumnCollation string
ColumnCollation represents a COLLATE clause for a column.
type ColumnDefault ¶
type ColumnDefault struct {
Expr Expr
}
ColumnDefault represents a DEFAULT clause for a column.
type ColumnFKConstraint ¶
type ColumnFKConstraint struct { Table NormalizableTableName Col Name // empty-string means use PK }
ColumnFKConstraint represents a FK-constaint on a column.
type ColumnFamilyConstraint ¶
ColumnFamilyConstraint represents FAMILY on a column.
type ColumnItem ¶
type ColumnItem struct { // TableName holds the table prefix, if the name refers to a column. TableName TableName // ColumnName names the designated column. ColumnName Name // Selector defines which sub-part of the variable is being // accessed. Selector NameParts }
ColumnItem corresponds to the name of a column or sub-item of a column in an expression.
func (*ColumnItem) Column ¶
func (c *ColumnItem) Column() string
Column retrieves the unqualified column name.
func (*ColumnItem) Eval ¶
func (expr *ColumnItem) Eval(ctx *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (*ColumnItem) Format ¶
func (c *ColumnItem) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*ColumnItem) NormalizeVarName ¶
func (c *ColumnItem) NormalizeVarName() (VarName, error)
NormalizeVarName is a no-op for ColumnItem (already normalized)
func (*ColumnItem) ResolvedType ¶
func (c *ColumnItem) ResolvedType() Type
ResolvedType implements the TypedExpr interface.
func (*ColumnItem) String ¶
func (c *ColumnItem) String() string
func (*ColumnItem) TypeCheck ¶
func (expr *ColumnItem) TypeCheck(_ *SemaContext, desired Type) (TypedExpr, error)
TypeCheck implements the Expr interface. This function has a valid implementation only for testing within this package. During query execution, ColumnItems are replaced to IndexedVars prior to type checking.
func (*ColumnItem) Variable ¶
func (c *ColumnItem) Variable()
Variable implements the VariableExpr interface. Although, the ColumnItem ought to be replaced to an IndexedVar before the points the VariableExpr interface is used.
func (*ColumnItem) Walk ¶
func (expr *ColumnItem) Walk(_ Visitor) Expr
Walk implements the Expr interface.
type ColumnMutationCmd ¶
type ColumnMutationCmd interface { AlterTableCmd GetColumn() Name }
ColumnMutationCmd is the subset of AlterTableCmds that modify an existing column.
type ColumnQualification ¶
type ColumnQualification interface {
// contains filtered or unexported methods
}
ColumnQualification represents a constraint on a column.
type ColumnTableDef ¶
type ColumnTableDef struct { Name Name Type ColumnType Nullable struct { Nullability Nullability ConstraintName Name } PrimaryKey bool Unique bool UniqueConstraintName Name DefaultExpr struct { Expr Expr ConstraintName Name } CheckExprs []ColumnTableDefCheckExpr References struct { Table NormalizableTableName Col Name ConstraintName Name } Family struct { Name Name Create bool IfNotExists bool } }
ColumnTableDef represents a column definition within a CREATE TABLE statement.
func (*ColumnTableDef) Format ¶
func (node *ColumnTableDef) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*ColumnTableDef) HasColumnFamily ¶
func (node *ColumnTableDef) HasColumnFamily() bool
HasColumnFamily returns if the ColumnTableDef has a column family.
func (*ColumnTableDef) HasDefaultExpr ¶
func (node *ColumnTableDef) HasDefaultExpr() bool
HasDefaultExpr returns if the ColumnTableDef has a default expression.
func (*ColumnTableDef) HasFKConstraint ¶
func (node *ColumnTableDef) HasFKConstraint() bool
HasFKConstraint returns if the ColumnTableDef has a foreign key constraint.
type ColumnTableDefCheckExpr ¶
ColumnTableDefCheckExpr represents a check constraint on a column definition within a CREATE TABLE statement.
type ColumnType ¶
type ColumnType interface { CastTargetType // contains filtered or unexported methods }
ColumnType represents a type in a column definition.
func DatumTypeToColumnType ¶
func DatumTypeToColumnType(t Type) (ColumnType, error)
DatumTypeToColumnType produces a SQL column type equivalent to the given Datum type. Used to generate CastExpr nodes during normalization.
type CommitTransaction ¶
type CommitTransaction struct{}
CommitTransaction represents a COMMIT statement.
func (*CommitTransaction) Format ¶
func (node *CommitTransaction) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*CommitTransaction) StatementTag ¶
func (*CommitTransaction) StatementTag() string
StatementTag returns a short string identifying the type of statement.
func (*CommitTransaction) StatementType ¶
func (*CommitTransaction) StatementType() StatementType
StatementType implements the Statement interface.
func (*CommitTransaction) String ¶
func (n *CommitTransaction) String() string
type ComparisonExpr ¶
type ComparisonExpr struct { Operator ComparisonOperator SubOperator ComparisonOperator // used for array operators (when Operator is Any, Some, or All) Left, Right Expr // contains filtered or unexported fields }
ComparisonExpr represents a two-value comparison expression.
func NewTypedComparisonExpr ¶
func NewTypedComparisonExpr(op ComparisonOperator, left, right TypedExpr) *ComparisonExpr
NewTypedComparisonExpr returns a new ComparisonExpr that is verified to be well-typed.
func (*ComparisonExpr) Eval ¶
func (expr *ComparisonExpr) Eval(ctx *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (*ComparisonExpr) Format ¶
func (node *ComparisonExpr) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*ComparisonExpr) IsMixedTypeComparison ¶
func (node *ComparisonExpr) IsMixedTypeComparison() bool
IsMixedTypeComparison returns true when the two sides of a comparison operator have different types.
func (ComparisonExpr) ResolvedType ¶
func (ta ComparisonExpr) ResolvedType() Type
func (*ComparisonExpr) String ¶
func (node *ComparisonExpr) String() string
func (*ComparisonExpr) TypeCheck ¶
func (expr *ComparisonExpr) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
TypeCheck implements the Expr interface.
func (*ComparisonExpr) TypedLeft ¶
func (node *ComparisonExpr) TypedLeft() TypedExpr
TypedLeft returns the ComparisonExpr's left expression as a TypedExpr.
func (*ComparisonExpr) TypedRight ¶
func (node *ComparisonExpr) TypedRight() TypedExpr
TypedRight returns the ComparisonExpr's right expression as a TypedExpr.
func (*ComparisonExpr) Walk ¶
func (expr *ComparisonExpr) Walk(v Visitor) Expr
Walk implements the Expr interface.
type ComparisonOperator ¶
type ComparisonOperator int
ComparisonOperator represents a binary operator.
const ( EQ ComparisonOperator = iota LT GT LE GE NE In NotIn Like NotLike ILike NotILike SimilarTo NotSimilarTo RegMatch NotRegMatch RegIMatch NotRegIMatch IsDistinctFrom IsNotDistinctFrom Is IsNot // The following operators will always be used with an associated SubOperator. // If Go had algebraic data types they would be defined in a self-contained // manner like: // // Any(ComparisonOperator) // Some(ComparisonOperator) // ... // // where the internal ComparisonOperator qualifies the behavior of the primary // operator. Instead, a secondary ComparisonOperator is optionally included in // ComparisonExpr for the cases where these operators are the primary op. // // ComparisonOperator.hasSubOperator returns true for ops in this group. Any Some All )
ComparisonExpr.Operator
func (ComparisonOperator) String ¶
func (i ComparisonOperator) String() string
type CompositeDatum ¶
type CompositeDatum interface { Datum // IsComposite returns true if this datum is not round-tripable in a key // encoding. IsComposite() bool }
CompositeDatum is a Datum that may require composite encoding in indexes. Any Datum implementing this interface must also add itself to sqlbase/HasCompositeKeyEncoding.
type Constant ¶
type Constant interface { Expr // AvailableTypes returns the ordered set of types that the Constant is able to // be resolved into. The order of the type slice provides a notion of precedence, // with the first element in the ordering being the Constant's "natural type". AvailableTypes() []Type // ResolveAsType resolves the Constant as the Datum type specified, or returns an // error if the Constant could not be resolved as that type. The method should only // be passed a type returned from AvailableTypes and should never be called more than // once for a given Constant. ResolveAsType(*SemaContext, Type) (Datum, error) }
Constant is an constant literal expression which may be resolved to more than one type.
type ConstraintTableDef ¶
type ConstraintTableDef interface { TableDef // contains filtered or unexported methods }
ConstraintTableDef represents a constraint definition within a CREATE TABLE statement.
type ContainsWindowVisitor ¶
type ContainsWindowVisitor struct {
// contains filtered or unexported fields
}
ContainsWindowVisitor checks if walked expressions contain window functions.
func (*ContainsWindowVisitor) ContainsWindowFunc ¶
func (v *ContainsWindowVisitor) ContainsWindowFunc(expr Expr) bool
ContainsWindowFunc determines if an Expr contains a window function.
func (*ContainsWindowVisitor) VisitPost ¶
func (*ContainsWindowVisitor) VisitPost(expr Expr) Expr
VisitPost satisfies the Visitor interface.
type CopyFrom ¶
type CopyFrom struct { Table NormalizableTableName Columns UnresolvedNames Stdin bool }
CopyFrom represents a COPY FROM statement.
func (*CopyFrom) StatementTag ¶
StatementTag returns a short string identifying the type of statement.
func (*CopyFrom) StatementType ¶
func (*CopyFrom) StatementType() StatementType
StatementType implements the Statement interface.
type CreateDatabase ¶
type CreateDatabase struct { IfNotExists bool Name Name Template string Encoding string Collate string CType string }
CreateDatabase represents a CREATE DATABASE statement.
func (*CreateDatabase) Format ¶
func (node *CreateDatabase) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*CreateDatabase) StatementTag ¶
func (*CreateDatabase) StatementTag() string
StatementTag returns a short string identifying the type of statement.
func (*CreateDatabase) StatementType ¶
func (*CreateDatabase) StatementType() StatementType
StatementType implements the Statement interface.
func (*CreateDatabase) String ¶
func (n *CreateDatabase) String() string
type CreateIndex ¶
type CreateIndex struct { Name Name Table NormalizableTableName Unique bool IfNotExists bool Columns IndexElemList // Extra columns to be stored together with the indexed ones as an optimization // for improved reading performance. Storing NameList Interleave *InterleaveDef }
CreateIndex represents a CREATE INDEX statement.
func (*CreateIndex) Format ¶
func (node *CreateIndex) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*CreateIndex) StatementTag ¶
func (*CreateIndex) StatementTag() string
StatementTag returns a short string identifying the type of statement.
func (*CreateIndex) StatementType ¶
func (*CreateIndex) StatementType() StatementType
StatementType implements the Statement interface.
func (*CreateIndex) String ¶
func (n *CreateIndex) String() string
type CreateTable ¶
type CreateTable struct { IfNotExists bool Table NormalizableTableName Interleave *InterleaveDef Defs TableDefs AsSource *Select AsColumnNames NameList // Only to be used in conjunction with AsSource }
CreateTable represents a CREATE TABLE statement.
func (*CreateTable) As ¶
func (node *CreateTable) As() bool
As returns true if this table represents a CREATE TABLE ... AS statement, false otherwise.
func (*CreateTable) Format ¶
func (node *CreateTable) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*CreateTable) StatementTag ¶
func (n *CreateTable) StatementTag() string
StatementTag returns a short string identifying the type of statement.
func (*CreateTable) StatementType ¶
func (*CreateTable) StatementType() StatementType
StatementType implements the Statement interface.
func (*CreateTable) String ¶
func (n *CreateTable) String() string
type CreateUser ¶
type CreateUser struct { Name Name Password *string // pointer so that empty and nil can be differentiated }
CreateUser represents a CREATE USER statement.
func (*CreateUser) Format ¶
func (node *CreateUser) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*CreateUser) HasPassword ¶
func (node *CreateUser) HasPassword() bool
HasPassword returns if the CreateUser has a password.
func (*CreateUser) StatementTag ¶
func (*CreateUser) StatementTag() string
StatementTag returns a short string identifying the type of statement.
func (*CreateUser) StatementType ¶
func (*CreateUser) StatementType() StatementType
StatementType implements the Statement interface.
func (*CreateUser) String ¶
func (n *CreateUser) String() string
type CreateView ¶
type CreateView struct { Name NormalizableTableName ColumnNames NameList AsSource *Select }
CreateView represents a CREATE VIEW statement.
func (*CreateView) Format ¶
func (node *CreateView) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*CreateView) StatementTag ¶
func (*CreateView) StatementTag() string
StatementTag returns a short string identifying the type of statement.
func (*CreateView) StatementType ¶
func (*CreateView) StatementType() StatementType
StatementType implements the Statement interface.
func (*CreateView) String ¶
func (n *CreateView) String() string
type DArray ¶
type DArray struct { ParamTyp Type Array Datums // HasNulls is set to true if any of the datums within the array are null. // This is used in the binary array serialization format. HasNulls bool }
DArray is the array Datum. Any Datum inserted into a DArray are treated as text during serialization.
func AsDArray ¶
AsDArray attempts to retrieve a *DArray from an Expr, returning a *DArray and a flag signifying whether the assertion was successful. The function should be used instead of direct type assertions wherever a *DArray wrapped by a *DOidWrapper is possible.
func MustBeDArray ¶
MustBeDArray attempts to retrieve a *DArray from an Expr, panicking if the assertion fails.
func (*DArray) AmbiguousFormat ¶
AmbiguousFormat implements the Datum interface.
func (*DArray) Append ¶
Append appends a Datum to the array, whose parameterized type must be consistent with the type of the Datum.
func (*DArray) Compare ¶
func (d *DArray) Compare(ctx *EvalContext, other Datum) int
Compare implements the Datum interface.
func (*DArray) Eval ¶
func (t *DArray) Eval(_ *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (*DArray) ResolvedType ¶
ResolvedType implements the TypedExpr interface.
type DBool ¶
type DBool bool
DBool is the boolean Datum.
func MakeDBool ¶
MakeDBool converts its argument to a *DBool, returning either DBoolTrue or DBoolFalse.
func ParseDBool ¶
ParseDBool parses and returns the *DBool Datum value represented by the provided string, or an error if parsing is unsuccessful.
func (*DBool) AmbiguousFormat ¶
AmbiguousFormat implements the Datum interface.
func (*DBool) Compare ¶
func (d *DBool) Compare(ctx *EvalContext, other Datum) int
Compare implements the Datum interface.
func (*DBool) Eval ¶
func (t *DBool) Eval(_ *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (*DBool) ResolvedType ¶
ResolvedType implements the TypedExpr interface.
type DBytes ¶
type DBytes string
DBytes is the bytes Datum. The underlying type is a string because we want the immutability, but this may contain arbitrary bytes.
func (*DBytes) AmbiguousFormat ¶
AmbiguousFormat implements the Datum interface.
func (*DBytes) Compare ¶
func (d *DBytes) Compare(ctx *EvalContext, other Datum) int
Compare implements the Datum interface.
func (*DBytes) Eval ¶
func (t *DBytes) Eval(_ *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (*DBytes) ResolvedType ¶
ResolvedType implements the TypedExpr interface.
type DCollatedString ¶
type DCollatedString struct { Contents string Locale string // Key is the collation key. Key []byte }
DCollatedString is the Datum for strings with a locale. The struct members are intended to be immutable.
func NewDCollatedString ¶
func NewDCollatedString( contents string, locale string, env *CollationEnvironment, ) *DCollatedString
NewDCollatedString is a helper routine to create a *DCollatedString. Panics if locale is invalid. Not safe for concurrent use.
func (*DCollatedString) AmbiguousFormat ¶
func (*DCollatedString) AmbiguousFormat() bool
AmbiguousFormat implements the Datum interface.
func (*DCollatedString) Compare ¶
func (d *DCollatedString) Compare(ctx *EvalContext, other Datum) int
Compare implements the Datum interface.
func (*DCollatedString) Eval ¶
func (t *DCollatedString) Eval(_ *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (*DCollatedString) Format ¶
func (d *DCollatedString) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*DCollatedString) IsComposite ¶
func (d *DCollatedString) IsComposite() bool
IsComposite implements the CompositeDatum interface.
func (*DCollatedString) IsMax ¶
func (*DCollatedString) IsMax() bool
IsMax implements the Datum interface.
func (*DCollatedString) IsMin ¶
func (d *DCollatedString) IsMin() bool
IsMin implements the Datum interface.
func (*DCollatedString) Next ¶
func (d *DCollatedString) Next() (Datum, bool)
Next implements the Datum interface.
func (*DCollatedString) Prev ¶
func (d *DCollatedString) Prev() (Datum, bool)
Prev implements the Datum interface.
func (*DCollatedString) ResolvedType ¶
func (d *DCollatedString) ResolvedType() Type
ResolvedType implements the TypedExpr interface.
func (*DCollatedString) Size ¶
func (d *DCollatedString) Size() uintptr
Size implements the Datum interface.
func (*DCollatedString) String ¶
func (node *DCollatedString) String() string
func (*DCollatedString) TypeCheck ¶
func (d *DCollatedString) TypeCheck(_ *SemaContext, _ Type) (TypedExpr, error)
TypeCheck implements the Expr interface. It is implemented as an idempotent identity function for Datum.
func (*DCollatedString) Walk ¶
func (expr *DCollatedString) Walk(_ Visitor) Expr
Walk implements the Expr interface.
type DDate ¶
type DDate int64
DDate is the date Datum represented as the number of days after the Unix epoch.
func NewDDateFromTime ¶
NewDDateFromTime constructs a *DDate from a time.Time in the provided time zone.
func ParseDDate ¶
ParseDDate parses and returns the *DDate Datum value represented by the provided string in the provided location, or an error if parsing is unsuccessful.
func (*DDate) AmbiguousFormat ¶
AmbiguousFormat implements the Datum interface.
func (*DDate) Compare ¶
func (d *DDate) Compare(ctx *EvalContext, other Datum) int
Compare implements the Datum interface.
func (*DDate) Eval ¶
func (t *DDate) Eval(_ *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (*DDate) ResolvedType ¶
ResolvedType implements the TypedExpr interface.
type DDecimal ¶
DDecimal is the decimal Datum.
var DecimalOne DDecimal
DecimalOne represents the constant 1 as DECIMAL.
func ParseDDecimal ¶
ParseDDecimal parses and returns the *DDecimal Datum value represented by the provided string, or an error if parsing is unsuccessful.
func TimestampToDecimal ¶
TimestampToDecimal converts the logical timestamp into a decimal value with the number of nanoseconds in the integer part and the logical counter in the decimal part.
func (*DDecimal) AmbiguousFormat ¶
AmbiguousFormat implements the Datum interface.
func (*DDecimal) Compare ¶
func (d *DDecimal) Compare(ctx *EvalContext, other Datum) int
Compare implements the Datum interface.
func (*DDecimal) Eval ¶
func (t *DDecimal) Eval(_ *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (*DDecimal) IsComposite ¶
IsComposite implements the CompositeDatum interface.
func (*DDecimal) ResolvedType ¶
ResolvedType implements the TypedExpr interface.
func (*DDecimal) SetString ¶
SetString sets d to s. Any non-standard NaN values are converted to a normal NaN.
type DFloat ¶
type DFloat float64
DFloat is the float Datum.
func ParseDFloat ¶
ParseDFloat parses and returns the *DFloat Datum value represented by the provided string, or an error if parsing is unsuccessful.
func (*DFloat) AmbiguousFormat ¶
AmbiguousFormat implements the Datum interface.
func (*DFloat) Compare ¶
func (d *DFloat) Compare(ctx *EvalContext, other Datum) int
Compare implements the Datum interface.
func (*DFloat) Eval ¶
func (t *DFloat) Eval(_ *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (*DFloat) IsComposite ¶
IsComposite implements the CompositeDatum interface.
func (*DFloat) ResolvedType ¶
ResolvedType implements the TypedExpr interface.
type DInt ¶
type DInt int64
DInt is the int Datum.
func AsDInt ¶
AsDInt attempts to retrieve a DInt from an Expr, returning a DInt and a flag signifying whether the assertion was successful. The function should be used instead of direct type assertions wherever a *DInt wrapped by a *DOidWrapper is possible.
func GenerateUniqueInt ¶
GenerateUniqueInt creates a unique int composed of the current time at a 10-microsecond granularity and the node-id. The node-id is stored in the lower 15 bits of the returned value and the timestamp is stored in the upper 48 bits. The top-bit is left empty so that negative values are not returned. The 48-bit timestamp field provides for 89 years of timestamps. We use a custom epoch (Jan 1, 2015) in order to utilize the entire timestamp range.
Note that GenerateUniqueInt() imposes a limit on node IDs while generateUniqueBytes() does not.
TODO(pmattis): Do we have to worry about persisting the milliseconds value periodically to avoid the clock ever going backwards (e.g. due to NTP adjustment)?
func MustBeDInt ¶
MustBeDInt attempts to retrieve a DInt from an Expr, panicking if the assertion fails.
func ParseDInt ¶
ParseDInt parses and returns the *DInt Datum value represented by the provided string, or an error if parsing is unsuccessful.
func (*DInt) AmbiguousFormat ¶
AmbiguousFormat implements the Datum interface.
func (*DInt) Compare ¶
func (d *DInt) Compare(ctx *EvalContext, other Datum) int
Compare implements the Datum interface.
func (*DInt) Eval ¶
func (t *DInt) Eval(_ *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (*DInt) ResolvedType ¶
ResolvedType implements the TypedExpr interface.
type DInterval ¶
DInterval is the interval Datum.
func ParseDInterval ¶
ParseDInterval parses and returns the *DInterval Datum value represented by the provided string, or an error if parsing is unsuccessful.
func ParseDIntervalWithField ¶
ParseDIntervalWithField is like ParseDInterval, but it also takes a DurationField that both specifies the units for unitless, numeric intervals and also specifies the precision of the interval. Any precision in the input interval that's higher than the DurationField value will be truncated downward.
func (*DInterval) AmbiguousFormat ¶
AmbiguousFormat implements the Datum interface.
func (*DInterval) Compare ¶
func (d *DInterval) Compare(ctx *EvalContext, other Datum) int
Compare implements the Datum interface.
func (*DInterval) Eval ¶
func (t *DInterval) Eval(_ *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (*DInterval) ResolvedType ¶
ResolvedType implements the TypedExpr interface.
func (*DInterval) TypeCheck ¶
func (d *DInterval) TypeCheck(_ *SemaContext, _ Type) (TypedExpr, error)
TypeCheck implements the Expr interface. It is implemented as an idempotent identity function for Datum.
func (*DInterval) ValueAsString ¶
ValueAsString returns the interval as a string (e.g. "1h2m").
type DOid ¶
type DOid struct { // A DOid embeds a DInt, the underlying integer OID for this OID datum. DInt // contains filtered or unexported fields }
DOid is the Postgres OID datum. It can represent either an OID type or any of the reg* types, such as regproc or regclass.
func (*DOid) AmbiguousFormat ¶
AmbiguousFormat implements the Datum interface.
func (*DOid) AsRegProc ¶
AsRegProc changes the input DOid into a regproc with the given name and returns it.
func (*DOid) Compare ¶
func (d *DOid) Compare(ctx *EvalContext, other Datum) int
Compare implements the Datum interface.
func (*DOid) Eval ¶
func (t *DOid) Eval(_ *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (*DOid) ResolvedType ¶
ResolvedType implements the Datum interface.
type DOidWrapper ¶
DOidWrapper is a Datum implementation which is a wrapper around a Datum, allowing custom Oid values to be attached to the Datum and its Type (see tOidWrapper). The reason the Datum type was introduced was to permit the introduction of Datum types with new Object IDs while maintaining identical behavior to current Datum types. Specifically, it obviates the need to: - define a new parser.Datum type. - define a new parser.Type type. - support operations and functions for the new Type. - support mixed-type operations between the new Type and the old Type.
Instead, DOidWrapper allows a standard Datum to be wrapped with a new Oid. This approach provides two major advantages:
- performance of the existing Datum types are not affected because they do not need to have custom oid.Oids added to their structure.
- the introduction of new Datum aliases is straightforward and does not require additions to typing rules or type-dependent evaluation behavior.
Types that currently benefit from DOidWrapper are: - DName => DOidWrapper(*DString, oid.T_name)
func (*DOidWrapper) AmbiguousFormat ¶
func (d *DOidWrapper) AmbiguousFormat() bool
AmbiguousFormat implements the Datum interface.
func (*DOidWrapper) Compare ¶
func (d *DOidWrapper) Compare(ctx *EvalContext, other Datum) int
Compare implements the Datum interface.
func (*DOidWrapper) Eval ¶
func (t *DOidWrapper) Eval(_ *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (*DOidWrapper) Format ¶
func (d *DOidWrapper) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*DOidWrapper) IsMax ¶
func (d *DOidWrapper) IsMax() bool
IsMax implements the Datum interface.
func (*DOidWrapper) IsMin ¶
func (d *DOidWrapper) IsMin() bool
IsMin implements the Datum interface.
func (*DOidWrapper) Next ¶
func (d *DOidWrapper) Next() (Datum, bool)
Next implements the Datum interface.
func (*DOidWrapper) Prev ¶
func (d *DOidWrapper) Prev() (Datum, bool)
Prev implements the Datum interface.
func (*DOidWrapper) ResolvedType ¶
func (d *DOidWrapper) ResolvedType() Type
ResolvedType implements the TypedExpr interface.
func (*DOidWrapper) Size ¶
func (d *DOidWrapper) Size() uintptr
Size implements the Datum interface.
func (*DOidWrapper) String ¶
func (node *DOidWrapper) String() string
func (*DOidWrapper) TypeCheck ¶
func (d *DOidWrapper) TypeCheck(_ *SemaContext, _ Type) (TypedExpr, error)
TypeCheck implements the Expr interface. It is implemented as an idempotent identity function for Datum.
func (*DOidWrapper) Walk ¶
func (expr *DOidWrapper) Walk(_ Visitor) Expr
Walk implements the Expr interface.
type DString ¶
type DString string
DString is the string Datum.
func AsDString ¶
AsDString attempts to retrieve a DString from an Expr, returning a DString and a flag signifying whether the assertion was successful. The function should be used instead of direct type assertions wherever a *DString wrapped by a *DOidWrapper is possible.
func MustBeDString ¶
MustBeDString attempts to retrieve a DString from an Expr, panicking if the assertion fails.
func NewDString ¶
NewDString is a helper routine to create a *DString initialized from its argument.
func (*DString) AmbiguousFormat ¶
AmbiguousFormat implements the Datum interface.
func (*DString) Compare ¶
func (d *DString) Compare(ctx *EvalContext, other Datum) int
Compare implements the Datum interface.
func (*DString) Eval ¶
func (t *DString) Eval(_ *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (*DString) ResolvedType ¶
ResolvedType implements the TypedExpr interface.
type DTable ¶
type DTable struct {
ValueGenerator
}
DTable is the table Datum. It is used for datums that hold an entire table generator. See the comments in generator_builtins.go for details.
func (*DTable) AmbiguousFormat ¶
AmbiguousFormat implements the Datum interface.
func (*DTable) Compare ¶
func (t *DTable) Compare(ctx *EvalContext, other Datum) int
Compare implements the Datum interface.
func (*DTable) Eval ¶
func (t *DTable) Eval(_ *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (*DTable) ResolvedType ¶
ResolvedType implements the TypedExpr interface.
type DTimestamp ¶
DTimestamp is the timestamp Datum.
func MakeDTimestamp ¶
func MakeDTimestamp(t time.Time, precision time.Duration) *DTimestamp
MakeDTimestamp creates a DTimestamp with specified precision.
func ParseDTimestamp ¶
func ParseDTimestamp(s string, precision time.Duration) (*DTimestamp, error)
ParseDTimestamp parses and returns the *DTimestamp Datum value represented by the provided string in UTC, or an error if parsing is unsuccessful.
func (*DTimestamp) AmbiguousFormat ¶
func (*DTimestamp) AmbiguousFormat() bool
AmbiguousFormat implements the Datum interface.
func (*DTimestamp) Compare ¶
func (d *DTimestamp) Compare(ctx *EvalContext, other Datum) int
Compare implements the Datum interface.
func (*DTimestamp) Eval ¶
func (t *DTimestamp) Eval(_ *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (*DTimestamp) Format ¶
func (d *DTimestamp) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*DTimestamp) Next ¶
func (d *DTimestamp) Next() (Datum, bool)
Next implements the Datum interface.
func (*DTimestamp) Prev ¶
func (d *DTimestamp) Prev() (Datum, bool)
Prev implements the Datum interface.
func (*DTimestamp) ResolvedType ¶
func (*DTimestamp) ResolvedType() Type
ResolvedType implements the TypedExpr interface.
func (*DTimestamp) String ¶
func (node *DTimestamp) String() string
func (*DTimestamp) TypeCheck ¶
func (d *DTimestamp) TypeCheck(_ *SemaContext, _ Type) (TypedExpr, error)
TypeCheck implements the Expr interface. It is implemented as an idempotent identity function for Datum.
func (*DTimestamp) Walk ¶
func (expr *DTimestamp) Walk(_ Visitor) Expr
Walk implements the Expr interface.
type DTimestampTZ ¶
DTimestampTZ is the timestamp Datum that is rendered with session offset.
func MakeDTimestampTZ ¶
func MakeDTimestampTZ(t time.Time, precision time.Duration) *DTimestampTZ
MakeDTimestampTZ creates a DTimestampTZ with specified precision.
func MakeDTimestampTZFromDate ¶
func MakeDTimestampTZFromDate(loc *time.Location, d *DDate) *DTimestampTZ
MakeDTimestampTZFromDate creates a DTimestampTZ from a DDate.
func ParseDTimestampTZ ¶
func ParseDTimestampTZ( s string, loc *time.Location, precision time.Duration, ) (*DTimestampTZ, error)
ParseDTimestampTZ parses and returns the *DTimestampTZ Datum value represented by the provided string in the provided location, or an error if parsing is unsuccessful.
func (*DTimestampTZ) AmbiguousFormat ¶
func (*DTimestampTZ) AmbiguousFormat() bool
AmbiguousFormat implements the Datum interface.
func (*DTimestampTZ) Compare ¶
func (d *DTimestampTZ) Compare(ctx *EvalContext, other Datum) int
Compare implements the Datum interface.
func (*DTimestampTZ) Eval ¶
func (t *DTimestampTZ) Eval(_ *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (*DTimestampTZ) Format ¶
func (d *DTimestampTZ) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*DTimestampTZ) IsMax ¶
func (d *DTimestampTZ) IsMax() bool
IsMax implements the Datum interface.
func (*DTimestampTZ) IsMin ¶
func (d *DTimestampTZ) IsMin() bool
IsMin implements the Datum interface.
func (*DTimestampTZ) Next ¶
func (d *DTimestampTZ) Next() (Datum, bool)
Next implements the Datum interface.
func (*DTimestampTZ) Prev ¶
func (d *DTimestampTZ) Prev() (Datum, bool)
Prev implements the Datum interface.
func (*DTimestampTZ) ResolvedType ¶
func (*DTimestampTZ) ResolvedType() Type
ResolvedType implements the TypedExpr interface.
func (*DTimestampTZ) Size ¶
func (d *DTimestampTZ) Size() uintptr
Size implements the Datum interface.
func (*DTimestampTZ) String ¶
func (node *DTimestampTZ) String() string
func (*DTimestampTZ) TypeCheck ¶
func (d *DTimestampTZ) TypeCheck(_ *SemaContext, _ Type) (TypedExpr, error)
TypeCheck implements the Expr interface. It is implemented as an idempotent identity function for Datum.
func (*DTimestampTZ) Walk ¶
func (expr *DTimestampTZ) Walk(_ Visitor) Expr
Walk implements the Expr interface.
type DTuple ¶
DTuple is the tuple Datum.
func NewDTuple ¶
NewDTuple creates a *DTuple with the provided datums. When creating a new DTuple with Datums that are known to be sorted in ascending order, chain this call with DTuple.SetSorted.
func NewDTupleWithCap ¶
NewDTupleWithCap creates a *DTuple with the provided capacity.
func NewDTupleWithLen ¶
NewDTupleWithLen creates a *DTuple with the provided length.
func (*DTuple) AmbiguousFormat ¶
AmbiguousFormat implements the Datum interface.
func (*DTuple) AssertSorted ¶
func (d *DTuple) AssertSorted()
AssertSorted asserts that the DTuple is sorted.
func (*DTuple) Compare ¶
func (d *DTuple) Compare(ctx *EvalContext, other Datum) int
Compare implements the Datum interface.
func (*DTuple) Eval ¶
func (t *DTuple) Eval(_ *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (*DTuple) Normalize ¶
func (d *DTuple) Normalize(ctx *EvalContext)
Normalize sorts and uniques the datum tuple.
func (*DTuple) ResolvedType ¶
ResolvedType implements the TypedExpr interface.
func (*DTuple) SearchSorted ¶
func (d *DTuple) SearchSorted(ctx *EvalContext, target Datum) (int, bool)
SearchSorted searches the tuple for the target Datum, returning an int with the same contract as sort.Search and a boolean flag signifying whether the datum was found. It assumes that the DTuple is sorted and panics if it is not.
func (*DTuple) SetSorted ¶
SetSorted sets the sorted flag on the DTuple. This should be used when a DTuple is known to be sorted based on the datums added to it.
func (*DTuple) SortedDifference ¶
func (d *DTuple) SortedDifference(ctx *EvalContext, other *DTuple) *DTuple
SortedDifference finds the elements of d which are not in other, assuming that d and other are already sorted.
type DateColType ¶
type DateColType struct { }
DateColType represents a DATE type.
func (*DateColType) Format ¶
func (node *DateColType) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*DateColType) String ¶
func (node *DateColType) String() string
type Datum ¶
type Datum interface { TypedExpr // AmbiguousFormat indicates whether the result of formatting this Datum can // be interpreted into more than one type. Used with // fmtFlags.disambiguateDatumTypes. AmbiguousFormat() bool // Compare returns -1 if the receiver is less than other, 0 if receiver is // equal to other and +1 if receiver is greater than other. Compare(ctx *EvalContext, other Datum) int // Prev returns the previous datum and true, if one exists, or nil and false. // The previous datum satisfies the following definition: if the receiver is // "b" and the returned datum is "a", then for every compatible datum "x", it // holds that "x < b" is true if and only if "x <= a" is true. // // The return value is undefined if IsMin() returns true. // // TODO(#12022): for DTuple, the contract is actually that "x < b" (SQL order, // where NULL < x is unknown for all x) is true only if "x <= a" // (.Compare/encoding order, where NULL <= x is true for all x) is true. This // is okay for now: the returned datum is used only to construct a span, which // uses .Compare/encoding order and is guaranteed to be large enough by this // weaker contract. The original filter expression is left in place to catch // false positives. Prev() (Datum, bool) // IsMin returns true if the datum is equal to the minimum value the datum // type can hold. IsMin() bool // Next returns the next datum and true, if one exists, or nil and false // otherwise. The next datum satisfies the following definition: if the // receiver is "a" and the returned datum is "b", then for every compatible // datum "x", it holds that "x > a" is true if and only if "x >= b" is true. // // The return value is undefined if IsMax() returns true. // // TODO(#12022): for DTuple, the contract is actually that "x > a" (SQL order, // where x > NULL is unknown for all x) is true only if "x >= b" // (.Compare/encoding order, where x >= NULL is true for all x) is true. This // is okay for now: the returned datum is used only to construct a span, which // uses .Compare/encoding order and is guaranteed to be large enough by this // weaker contract. The original filter expression is left in place to catch // false positives. Next() (Datum, bool) // IsMax returns true if the datum is equal to the maximum value the datum // type can hold. IsMax() bool // Size returns a lower bound on the total size of the receiver in bytes, // including memory that is pointed at (even if shared between Datum // instances) but excluding allocation overhead. // // It holds for every Datum d that d.Size() >= d.ResolvedType().Size(). Size() uintptr // contains filtered or unexported methods }
Datum represents a SQL value.
func NewDIntVectorFromDArray ¶
NewDIntVectorFromDArray is a helper routine to create a *DIntVector (implemented as a *DOidWrapper) initialized from an existing *DArray.
func NewDName ¶
NewDName is a helper routine to create a *DName (implemented as a *DOidWrapper) initialized from a string.
func NewDNameFromDString ¶
NewDNameFromDString is a helper routine to create a *DName (implemented as a *DOidWrapper) initialized from an existing *DString.
func UnwrapDatum ¶
UnwrapDatum returns the base Datum type for a provided datum, stripping an *DOidWrapper if present. This is useful for cases like type switches, where type aliases should be ignored.
type Datums ¶
type Datums []Datum
Datums is a slice of Datum values.
type Deallocate ¶
type Deallocate struct {
Name Name // empty for ALL
}
Deallocate represents a DEALLOCATE statement.
func (*Deallocate) Format ¶
func (node *Deallocate) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*Deallocate) StatementTag ¶
func (n *Deallocate) StatementTag() string
StatementTag returns a short string identifying the type of statement.
func (*Deallocate) StatementType ¶
func (*Deallocate) StatementType() StatementType
StatementType implements the Statement interface.
func (*Deallocate) String ¶
func (n *Deallocate) String() string
type DecimalColType ¶
DecimalColType represents a DECIMAL or NUMERIC type.
func (*DecimalColType) Format ¶
func (node *DecimalColType) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*DecimalColType) String ¶
func (node *DecimalColType) String() string
type DefaultVal ¶
type DefaultVal struct{}
DefaultVal represents the DEFAULT expression.
func (DefaultVal) Eval ¶
func (expr DefaultVal) Eval(ctx *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (DefaultVal) Format ¶
func (node DefaultVal) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (DefaultVal) ResolvedType ¶
func (DefaultVal) ResolvedType() Type
ResolvedType implements the TypedExpr interface.
func (DefaultVal) String ¶
func (node DefaultVal) String() string
func (DefaultVal) TypeCheck ¶
func (expr DefaultVal) TypeCheck(_ *SemaContext, desired Type) (TypedExpr, error)
TypeCheck implements the Expr interface.
func (DefaultVal) Walk ¶
func (expr DefaultVal) Walk(_ Visitor) Expr
Walk implements the Expr interface.
type Delete ¶
type Delete struct { Table TableExpr Where *Where Returning ReturningClause }
Delete represents a DELETE statement.
func (*Delete) CopyNode ¶
CopyNode makes a copy of this Statement without recursing in any child Statements.
func (*Delete) StatementTag ¶
StatementTag returns a short string identifying the type of statement.
func (*Delete) StatementType ¶
func (n *Delete) StatementType() StatementType
StatementType implements the Statement interface.
type DropBehavior ¶
type DropBehavior int
DropBehavior represents options for dropping schema elements.
const ( DropDefault DropBehavior = iota DropRestrict DropCascade )
DropBehavior values.
func (DropBehavior) String ¶
func (d DropBehavior) String() string
type DropDatabase ¶
DropDatabase represents a DROP DATABASE statement.
func (*DropDatabase) Format ¶
func (node *DropDatabase) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*DropDatabase) StatementTag ¶
func (*DropDatabase) StatementTag() string
StatementTag returns a short string identifying the type of statement.
func (*DropDatabase) StatementType ¶
func (*DropDatabase) StatementType() StatementType
StatementType implements the Statement interface.
func (*DropDatabase) String ¶
func (n *DropDatabase) String() string
type DropIndex ¶
type DropIndex struct { IndexList TableNameWithIndexList IfExists bool DropBehavior DropBehavior }
DropIndex represents a DROP INDEX statement.
func (*DropIndex) StatementTag ¶
StatementTag returns a short string identifying the type of statement.
func (*DropIndex) StatementType ¶
func (*DropIndex) StatementType() StatementType
StatementType implements the Statement interface.
type DropTable ¶
type DropTable struct { Names TableNameReferences IfExists bool DropBehavior DropBehavior }
DropTable represents a DROP TABLE statement.
func (*DropTable) StatementTag ¶
StatementTag returns a short string identifying the type of statement.
func (*DropTable) StatementType ¶
func (*DropTable) StatementType() StatementType
StatementType implements the Statement interface.
type DropView ¶
type DropView struct { Names TableNameReferences IfExists bool DropBehavior DropBehavior }
DropView represents a DROP VIEW statement.
func (*DropView) StatementTag ¶
StatementTag returns a short string identifying the type of statement.
func (*DropView) StatementType ¶
func (*DropView) StatementType() StatementType
StatementType implements the Statement interface.
type EvalContext ¶
type EvalContext struct { NodeID roachpb.NodeID // Location references the *Location on the current Session. Location **time.Location // Database is the database in the current Session. Database string // SearchPath is the search path for databases used when encountering an // unqualified table name. Names in the search path are normalized already. // This must not be modified (this is shared from the session). SearchPath SearchPath // Ctx represents the context in which the expression is evaluated. This will // point to the Session's context container. // NOTE: seems a bit lazy to hold a pointer to the session's context here, // instead of making sure the right context is explicitly set before the // EvalContext is used. But there's already precedent with the Location field, // and also at the time of writing, EvalContexts are initialized with the // planner and not mutated. Ctx contextHolder Planner EvalPlanner ReCache *RegexpCache // TODO(mjibson): remove prepareOnly in favor of a 2-step prepare-exec solution // that is also able to save the plan to skip work during the exec step. PrepareOnly bool // SkipNormalize indicates whether expressions should be normalized // (false) or not (true). It is set to true conditionally by // EXPLAIN(TYPES[, NORMALIZE]). SkipNormalize bool Mon *mon.MemoryMonitor // contains filtered or unexported fields }
EvalContext defines the context in which to evaluate an expression, allowing the retrieval of state such as the node ID or statement start time.
ATTENTION: Fields from this struct are also represented in distsqlrun.EvalContext. Make sure to keep the two in sync. TODO(andrei): remove or limit the duplication.
func MakeTestingEvalContext ¶
func MakeTestingEvalContext() EvalContext
MakeTestingEvalContext returns an EvalContext that includes a MemoryMonitor.
func (*EvalContext) GetClusterTimestamp ¶
func (ctx *EvalContext) GetClusterTimestamp() *DDecimal
GetClusterTimestamp retrieves the current cluster timestamp as per the evaluation context. The timestamp is guaranteed to be nonzero.
func (*EvalContext) GetClusterTimestampRaw ¶
func (ctx *EvalContext) GetClusterTimestampRaw() hlc.Timestamp
GetClusterTimestampRaw exposes the clusterTimestamp field. Also see GetClusterTimestamp().
func (*EvalContext) GetLocation ¶
func (ctx *EvalContext) GetLocation() *time.Location
GetLocation returns the session timezone.
func (*EvalContext) GetStmtTimestamp ¶
func (ctx *EvalContext) GetStmtTimestamp() time.Time
GetStmtTimestamp retrieves the current statement timestamp as per the evaluation context. The timestamp is guaranteed to be nonzero.
func (*EvalContext) GetTxnTimestamp ¶
func (ctx *EvalContext) GetTxnTimestamp(precision time.Duration) *DTimestampTZ
GetTxnTimestamp retrieves the current transaction timestamp as per the evaluation context. The timestamp is guaranteed to be nonzero.
func (*EvalContext) GetTxnTimestampNoZone ¶
func (ctx *EvalContext) GetTxnTimestampNoZone(precision time.Duration) *DTimestamp
GetTxnTimestampNoZone retrieves the current transaction timestamp as per the evaluation context. The timestamp is guaranteed to be nonzero.
func (*EvalContext) GetTxnTimestampRaw ¶
func (ctx *EvalContext) GetTxnTimestampRaw() time.Time
GetTxnTimestampRaw exposes the txnTimestamp field. Also see GetTxnTimestamp() and GetTxnTimestampNoZone().
func (*EvalContext) NormalizeExpr ¶
func (ctx *EvalContext) NormalizeExpr(typedExpr TypedExpr) (TypedExpr, error)
NormalizeExpr normalizes a typed expression, simplifying where possible, but guaranteeing that the result of evaluating the expression is unchanged and that resulting expression tree is still well-typed. Example normalizations:
(a) -> a a = 1 + 1 -> a = 2 a + 1 = 2 -> a = 1 a BETWEEN b AND c -> (a >= b) AND (a <= c) a NOT BETWEEN b AND c -> (a < b) OR (a > c)
func (*EvalContext) SetClusterTimestamp ¶
func (ctx *EvalContext) SetClusterTimestamp(ts hlc.Timestamp)
SetClusterTimestamp sets the corresponding timestamp in the EvalContext.
func (*EvalContext) SetStmtTimestamp ¶
func (ctx *EvalContext) SetStmtTimestamp(ts time.Time)
SetStmtTimestamp sets the corresponding timestamp in the EvalContext.
func (*EvalContext) SetTxnTimestamp ¶
func (ctx *EvalContext) SetTxnTimestamp(ts time.Time)
SetTxnTimestamp sets the corresponding timestamp in the EvalContext.
type EvalPlanner ¶
type EvalPlanner interface { // QueryRow executes a SQL query string where exactly 1 result row is // expected and returns that row. QueryRow(ctx context.Context, sql string, args ...interface{}) (Datums, error) // QualifyWithDatabase resolves a possibly unqualified table name into a // table name that is qualified by database. QualifyWithDatabase(ctx context.Context, t *NormalizableTableName) (*TableName, error) }
EvalPlanner is a limited planner that can be used from EvalContext.
type Execute ¶
Execute represents an EXECUTE statement.
func (*Execute) StatementTag ¶
StatementTag returns a short string identifying the type of statement.
func (*Execute) StatementType ¶
func (*Execute) StatementType() StatementType
StatementType implements the Statement interface.
type ExistsExpr ¶
type ExistsExpr struct { Subquery Expr // contains filtered or unexported fields }
ExistsExpr represents an EXISTS expression.
func (*ExistsExpr) Eval ¶
func (t *ExistsExpr) Eval(ctx *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (*ExistsExpr) Format ¶
func (node *ExistsExpr) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (ExistsExpr) ResolvedType ¶
func (ta ExistsExpr) ResolvedType() Type
func (*ExistsExpr) String ¶
func (node *ExistsExpr) String() string
func (*ExistsExpr) TypeCheck ¶
func (expr *ExistsExpr) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
TypeCheck implements the Expr interface.
func (*ExistsExpr) Walk ¶
func (expr *ExistsExpr) Walk(v Visitor) Expr
Walk implements the Expr interface.
type Explain ¶
type Explain struct { // Options defines how EXPLAIN should operate (VERBOSE, METADATA, // etc.) Which options are valid depends on the explain mode. See // sql/explain.go for details. Options []string // Statement is the statement being EXPLAINed. Statement Statement // Enclosed is set to true if the EXPLAIN syntax was used as a data // source, and thus enclosed in square brackets. Enclosed bool }
Explain represents an EXPLAIN statement.
func (*Explain) CopyNode ¶
CopyNode makes a copy of this Statement without recursing in any child Statements.
func (*Explain) StatementTag ¶
StatementTag returns a short string identifying the type of statement.
func (*Explain) StatementType ¶
func (*Explain) StatementType() StatementType
StatementType implements the Statement interface.
type Expr ¶
type Expr interface { fmt.Stringer NodeFormatter // Walk recursively walks all children using WalkExpr. If any children are changed, it returns a // copy of this node updated to point to the new children. Otherwise the receiver is returned. // For childless (leaf) Exprs, its implementation is empty. Walk(Visitor) Expr // TypeCheck transforms the Expr into a well-typed TypedExpr, which further permits // evaluation and type introspection, or an error if the expression cannot be well-typed. // When type checking is complete, if no error was reported, the expression and all // sub-expressions will be guaranteed to be well-typed, meaning that the method effectively // maps the Expr tree into a TypedExpr tree. // // The ctx parameter defines the context in which to perform type checking. // The desired parameter hints the desired type that the method's caller wants from // the resulting TypedExpr. It is not valid to call TypeCheck with a nil desired // type. Instead, call it with wildcard type TypeAny if no specific type is // desired. This restriction is also true of most methods and functions related // to type checking. TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error) }
Expr represents an expression.
func SimpleVisit ¶
func SimpleVisit(expr Expr, preFn SimpleVisitFn) (Expr, error)
SimpleVisit is a convenience wrapper for visitors that only have VisitPre code and don't return any results except an error. The given function is called in VisitPre for every node. The visitor stops as soon as an error is returned.
func StripParens ¶
StripParens strips any parentheses surrounding an expression and returns the inner expression. For instance:
1 -> 1 (1) -> 1
((1)) -> 1
type Exprs ¶
type Exprs []Expr
Exprs represents a list of value expressions. It's not a valid expression because it's not parenthesized.
func ParseExprs ¶
ParseExprs is a short-hand for parseExprs(sql)
type FamilyTableDef ¶
FamilyTableDef represents a family definition within a CREATE TABLE statement.
type FloatColType ¶
type FloatColType struct { Name string Prec int PrecSpecified bool // true if the value of Prec is not the default }
FloatColType represents a REAL, DOUBLE or FLOAT type.
func NewFloatColType ¶
func NewFloatColType(prec int, precSpecified bool) *FloatColType
NewFloatColType creates a type representing a FLOAT, optionally with a precision.
func (*FloatColType) Format ¶
func (node *FloatColType) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*FloatColType) String ¶
func (node *FloatColType) String() string
type FmtFlags ¶
type FmtFlags *fmtFlags
FmtFlags enables conditional formatting in the pretty-printer.
FmtAnonymize instructs the pretty-printer to remove any name but function names. TODO(knz): temporary until a better solution is found for #13968
FmtBareStrings instructs the pretty-printer to print strings without wrapping quotes, if possible.
FmtCheckEquivalence instructs the pretty-printer to produce a representation that can be used to check equivalence of expressions. Specifically:
- IndexedVars are formatted using symbolic notation (to disambiguate columns).
- datum types are disambiguated with casts. This is necessary because datums of different types can otherwise be formatted to the same string: (for example the DDecimal 1 and the DInt 1).
FmtHideConstants instructs the pretty-printer to produce a representation that does not disclose query-specific data.
FmtParsable instructs the pretty-printer to produce a representation that can be parsed into an equivalent expression (useful for serialization of expressions).
FmtShowTypes instructs the pretty-printer to annotate expressions with their resolved types.
var FmtSimple FmtFlags = &fmtFlags{}
FmtSimple instructs the pretty-printer to produce a straightforward representation.
FmtSimpleWithPasswords instructs the pretty-printer to produce a straightforward representation that does not suppress passwords.
func FmtExpr ¶
FmtExpr returns FmtFlags that indicate how the pretty-printer should format expressions.
func FmtIndexedVarFormat ¶
func FmtIndexedVarFormat( base FmtFlags, fn func(buf *bytes.Buffer, f FmtFlags, c IndexedVarContainer, idx int), ) FmtFlags
FmtIndexedVarFormat returns FmtFlags that customizes the printing of IndexedVars using the provided function.
func FmtReformatTableNames ¶
func FmtReformatTableNames( base FmtFlags, fn func(*NormalizableTableName, *bytes.Buffer, FmtFlags), ) FmtFlags
FmtReformatTableNames returns FmtFlags that instructs the pretty-printer to substitute the printing of table names using the provided function.
type ForeignKeyConstraintTableDef ¶
type ForeignKeyConstraintTableDef struct { Name Name Table NormalizableTableName FromCols NameList ToCols NameList }
ForeignKeyConstraintTableDef represents a FOREIGN KEY constraint in the AST.
type FuncExpr ¶
type FuncExpr struct { Func ResolvableFunctionReference Type funcType Exprs Exprs // Filter is used for filters on aggregates: SUM(k) FILTER (WHERE k > 0) Filter Expr WindowDef *WindowDef // contains filtered or unexported fields }
FuncExpr represents a function call.
func (*FuncExpr) CopyNode ¶
CopyNode makes a copy of this Expr without recursing in any child Exprs.
func (*FuncExpr) Eval ¶
func (expr *FuncExpr) Eval(ctx *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (*FuncExpr) GetAggregateConstructor ¶
func (node *FuncExpr) GetAggregateConstructor() func(*EvalContext) AggregateFunc
GetAggregateConstructor exposes the AggregateFunc field for use by the group node in package sql.
func (*FuncExpr) GetWindowConstructor ¶
func (node *FuncExpr) GetWindowConstructor() func(*EvalContext) WindowFunc
GetWindowConstructor returns a window function constructor if the FuncExpr is a built-in window function.
func (*FuncExpr) IsDistSQLBlacklist ¶
IsDistSQLBlacklist returns whether the function is not supported by DistSQL.
func (*FuncExpr) IsImpure ¶
IsImpure returns whether the function application is impure, meaning that it potentially returns a different value when called in the same statement with the same parameters.
func (*FuncExpr) IsWindowFunctionApplication ¶
IsWindowFunctionApplication returns if the function is being applied as a window function.
func (FuncExpr) ResolvedType ¶
func (ta FuncExpr) ResolvedType() Type
type FunctionClass ¶
type FunctionClass int
FunctionClass specifies the class of the builtin function.
const ( // NormalClass is a standard builtin function. NormalClass FunctionClass = iota // AggregateClass is a builtin aggregate function. AggregateClass // WindowClass is a builtin window function. WindowClass // GeneratorClass is a builtin generator function. GeneratorClass )
type FunctionDefinition ¶
type FunctionDefinition struct { // Name is the short name of the function. Name string // HasOverloadsNeedingRepeatedEvaluation is true if one or more of // the overload definitions has needsRepeatedEvaluation set. // Set e.g. for aggregate functions. HasOverloadsNeedingRepeatedEvaluation bool // Definition is the set of overloads for this function name. Definition []Builtin }
FunctionDefinition implements a reference to the (possibly several) overloads for a built-in function.
func (*FunctionDefinition) Format ¶
func (fd *FunctionDefinition) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*FunctionDefinition) String ¶
func (fd *FunctionDefinition) String() string
type FunctionReference ¶
type FunctionReference interface { fmt.Stringer NodeFormatter // contains filtered or unexported methods }
FunctionReference is the common interface to UnresolvedName and QualifiedFunctionName.
type Grant ¶
type Grant struct { Privileges privilege.List Targets TargetList Grantees NameList }
Grant represents a GRANT statement.
func (*Grant) StatementTag ¶
StatementTag returns a short string identifying the type of statement.
func (*Grant) StatementType ¶
func (*Grant) StatementType() StatementType
StatementType implements the Statement interface.
type Help ¶
type Help struct {
Name Name
}
Help represents a HELP statement.
func (*Help) StatementTag ¶
StatementTag returns a short string identifying the type of statement.
func (*Help) StatementType ¶
func (*Help) StatementType() StatementType
StatementType implements the Statement interface.
type HiddenFromStats ¶
type HiddenFromStats interface {
// contains filtered or unexported methods
}
HiddenFromStats is a pseudo-interface to be implemented by statements that should not show up in per-app statistics.
type HomogeneousType ¶
type HomogeneousType struct{}
HomogeneousType is a typeList implementation that accepts any arguments, as long as all are the same type or NULL. The homogeneous constraint is enforced in typeCheckOverloadedExprs.
func (HomogeneousType) Length ¶
func (HomogeneousType) Length() int
Length implements the typeList interface.
func (HomogeneousType) String ¶
func (HomogeneousType) String() string
func (HomogeneousType) Types ¶
func (HomogeneousType) Types() []Type
Types implements the typeList interface.
type IfExpr ¶
IfExpr represents an IF expression.
func (*IfExpr) Eval ¶
func (expr *IfExpr) Eval(ctx *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (IfExpr) ResolvedType ¶
func (ta IfExpr) ResolvedType() Type
func (*IfExpr) TypeCheck ¶
func (expr *IfExpr) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
TypeCheck implements the Expr interface.
func (*IfExpr) TypedCondExpr ¶
TypedCondExpr returns the IfExpr's Cond expression as a TypedExpr.
func (*IfExpr) TypedElseExpr ¶
TypedElseExpr returns the IfExpr's Else expression as a TypedExpr.
func (*IfExpr) TypedTrueExpr ¶
TypedTrueExpr returns the IfExpr's True expression as a TypedExpr.
type IndependentFromParallelizedPriors ¶
type IndependentFromParallelizedPriors interface {
// contains filtered or unexported methods
}
IndependentFromParallelizedPriors is a pseudo-interface to be implemented by statements which do not force parallel statement execution synchronization when they run.
type IndexHints ¶
IndexHints represents "@<index_name>" or "@{param[,param]}" where param is one of:
- FORCE_INDEX=<index_name>
- NO_INDEX_JOIN
It is used optionally after a table name in SELECT statements.
type IndexTableDef ¶
type IndexTableDef struct { Name Name Columns IndexElemList Storing NameList Interleave *InterleaveDef }
IndexTableDef represents an index definition within a CREATE TABLE statement.
type IndexedRow ¶
IndexedRow is a row with a corresponding index.
type IndexedVar ¶
type IndexedVar struct { Idx int // contains filtered or unexported fields }
IndexedVar is a VariableExpr that can be used as a leaf in expressions; it represents a dynamic value. It defers calls to TypeCheck, Eval, String to an IndexedVarContainer.
func NewOrdinalReference ¶
func NewOrdinalReference(r int) *IndexedVar
NewOrdinalReference is a helper routine to create a standalone IndexedVar with the given index value. This needs to undergo BindIfUnbound() below before it can be fully used.
func (*IndexedVar) Eval ¶
func (v *IndexedVar) Eval(ctx *EvalContext) (Datum, error)
Eval is part of the TypedExpr interface.
func (*IndexedVar) Format ¶
func (v *IndexedVar) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*IndexedVar) ResolvedType ¶
func (v *IndexedVar) ResolvedType() Type
ResolvedType is part of the TypedExpr interface.
func (*IndexedVar) String ¶
func (node *IndexedVar) String() string
func (*IndexedVar) TypeCheck ¶
func (v *IndexedVar) TypeCheck(_ *SemaContext, desired Type) (TypedExpr, error)
TypeCheck is part of the Expr interface.
func (*IndexedVar) Variable ¶
func (*IndexedVar) Variable()
Variable is a dummy function part of the VariableExpr interface.
func (*IndexedVar) Walk ¶
func (v *IndexedVar) Walk(_ Visitor) Expr
Walk is part of the Expr interface.
type IndexedVarContainer ¶
type IndexedVarContainer interface { IndexedVarEval(idx int, ctx *EvalContext) (Datum, error) IndexedVarResolvedType(idx int) Type IndexedVarFormat(buf *bytes.Buffer, f FmtFlags, idx int) }
IndexedVarContainer provides the implementation of TypeCheck, Eval, and String for IndexedVars. If an object that wishes to implement this interface has lost the textual name that an IndexedVar originates from, it can use the ordinal column reference syntax: fmt.Fprintf(buf, "@%d", idx)
type IndexedVarHelper ¶
type IndexedVarHelper struct {
// contains filtered or unexported fields
}
IndexedVarHelper wraps an IndexedVarContainer (an interface) and creates IndexedVars bound to that container.
It also keeps track of which indexes from the container are used by expressions.
func MakeIndexedVarHelper ¶
func MakeIndexedVarHelper(container IndexedVarContainer, numVars int) IndexedVarHelper
MakeIndexedVarHelper initializes an IndexedVarHelper structure.
func (*IndexedVarHelper) AppendSlot ¶
func (h *IndexedVarHelper) AppendSlot() int
AppendSlot expands the capacity of this IndexedVarHelper by one and returns the index of the new slot.
func (*IndexedVarHelper) AssertSameContainer ¶
func (h *IndexedVarHelper) AssertSameContainer(ivar *IndexedVar)
AssertSameContainer checks that the indexed var refers to the same container.
func (*IndexedVarHelper) BindIfUnbound ¶
func (h *IndexedVarHelper) BindIfUnbound(ivar *IndexedVar) error
BindIfUnbound attaches an IndexedVar to an existing container. This is needed for standalone column ordinals created during parsing.
func (*IndexedVarHelper) GetIndexedVars ¶
func (h *IndexedVarHelper) GetIndexedVars() []IndexedVar
GetIndexedVars transfers ownership of the array of initialized IndexedVars to the caller; unused vars are guaranteed to have an invalid index. The helper cannot be used any more after the ownership has been transferred.
func (*IndexedVarHelper) IndexedVar ¶
func (h *IndexedVarHelper) IndexedVar(idx int) *IndexedVar
IndexedVar returns an IndexedVar for the given index. The index must be valid.
func (*IndexedVarHelper) IndexedVarUsed ¶
func (h *IndexedVarHelper) IndexedVarUsed(idx int) bool
IndexedVarUsed returns true if IndexedVar() was called for the given index. The index must be valid.
func (*IndexedVarHelper) NumVars ¶
func (h *IndexedVarHelper) NumVars() int
NumVars returns the number of variables the IndexedVarHelper was initialized for.
func (*IndexedVarHelper) Rebind ¶
func (h *IndexedVarHelper) Rebind(expr TypedExpr, alsoReset, normalizeToNonNil bool) TypedExpr
Rebind collects all the IndexedVars in the given expression and re-binds them to this helper.
func (*IndexedVarHelper) Reset ¶
func (h *IndexedVarHelper) Reset()
Reset re-initializes an IndexedVarHelper structure with the same number of slots. After a helper has been reset, all the expressions that were linked to the helper before it was reset must be re-bound, e.g. using Rebind(). Resetting is useful to ensure that the helper's knowledge of which IndexedVars are actually used by linked expressions is up to date, especially after optimizations/transforms which eliminate sub-expressions. The optimizations performed by setNeededColumns() work then best.
TODO(knz): groupNode and windowNode hold on to IndexedVar's after a Reset().
func (*IndexedVarHelper) VisitPost ¶
func (*IndexedVarHelper) VisitPost(expr Expr) Expr
VisitPost implements the Visitor interface.
type IndirectionExpr ¶
type IndirectionExpr struct { Expr Expr Indirection ArraySubscripts // contains filtered or unexported fields }
IndirectionExpr represents a subscript expression.
func (*IndirectionExpr) CopyNode ¶
func (expr *IndirectionExpr) CopyNode() *IndirectionExpr
CopyNode makes a copy of this Expr without recursing in any child Exprs.
func (*IndirectionExpr) Eval ¶
func (expr *IndirectionExpr) Eval(ctx *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (*IndirectionExpr) Format ¶
func (node *IndirectionExpr) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (IndirectionExpr) ResolvedType ¶
func (ta IndirectionExpr) ResolvedType() Type
func (*IndirectionExpr) String ¶
func (node *IndirectionExpr) String() string
func (*IndirectionExpr) TypeCheck ¶
func (expr *IndirectionExpr) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
TypeCheck implements the Expr interface.
func (*IndirectionExpr) Walk ¶
func (expr *IndirectionExpr) Walk(v Visitor) Expr
Walk implements the Expr interface.
type Insert ¶
type Insert struct { Table TableExpr Columns UnresolvedNames Rows *Select OnConflict *OnConflict Returning ReturningClause }
Insert represents an INSERT statement.
func (*Insert) CopyNode ¶
CopyNode makes a copy of this Statement without recursing in any child Statements.
func (*Insert) DefaultValues ¶
DefaultValues returns true iff only default values are being inserted.
func (*Insert) StatementTag ¶
StatementTag returns a short string identifying the type of statement.
func (*Insert) StatementType ¶
func (n *Insert) StatementType() StatementType
StatementType implements the Statement interface.
type IntColType ¶
IntColType represents an INT, INTEGER, SMALLINT or BIGINT type.
func (*IntColType) Format ¶
func (node *IntColType) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*IntColType) IsSerial ¶
func (node *IntColType) IsSerial() bool
IsSerial returns true when this column should be given a DEFAULT of a unique, incrementing function.
func (*IntColType) String ¶
func (node *IntColType) String() string
type InterleaveDef ¶
type InterleaveDef struct { Parent NormalizableTableName Fields NameList DropBehavior DropBehavior }
InterleaveDef represents an interleave definition within a CREATE TABLE or CREATE INDEX statement.
type IntervalColType ¶
type IntervalColType struct { }
IntervalColType represents an INTERVAL type
func (*IntervalColType) Format ¶
func (node *IntervalColType) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*IntervalColType) String ¶
func (node *IntervalColType) String() string
type IsAggregateVisitor ¶
type IsAggregateVisitor struct { Aggregated bool // contains filtered or unexported fields }
IsAggregateVisitor checks if walked expressions contain aggregate functions.
func (*IsAggregateVisitor) Reset ¶
func (v *IsAggregateVisitor) Reset()
Reset clear the IsAggregateVisitor's internal state.
func (*IsAggregateVisitor) VisitPost ¶
func (*IsAggregateVisitor) VisitPost(expr Expr) Expr
VisitPost satisfies the Visitor interface.
type IsOfTypeExpr ¶
type IsOfTypeExpr struct { Not bool Expr Expr Types []ColumnType // contains filtered or unexported fields }
IsOfTypeExpr represents an IS {,NOT} OF (type_list) expression.
func (*IsOfTypeExpr) Eval ¶
func (expr *IsOfTypeExpr) Eval(ctx *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (*IsOfTypeExpr) Format ¶
func (node *IsOfTypeExpr) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (IsOfTypeExpr) ResolvedType ¶
func (ta IsOfTypeExpr) ResolvedType() Type
func (*IsOfTypeExpr) String ¶
func (node *IsOfTypeExpr) String() string
func (*IsOfTypeExpr) TypeCheck ¶
func (expr *IsOfTypeExpr) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
TypeCheck implements the Expr interface.
func (*IsOfTypeExpr) Walk ¶
func (expr *IsOfTypeExpr) Walk(v Visitor) Expr
Walk implements the Expr interface.
type IsolationLevel ¶
type IsolationLevel int
IsolationLevel holds the isolation level for a transaction.
const ( UnspecifiedIsolation IsolationLevel = iota SnapshotIsolation SerializableIsolation )
IsolationLevel values
func (IsolationLevel) String ¶
func (i IsolationLevel) String() string
type JoinCond ¶
type JoinCond interface { NodeFormatter // contains filtered or unexported methods }
JoinCond represents a join condition.
type JoinTableExpr ¶
JoinTableExpr represents a TableExpr that's a JOIN operation.
func (*JoinTableExpr) Format ¶
func (node *JoinTableExpr) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*JoinTableExpr) String ¶
func (node *JoinTableExpr) String() string
type KVOptions ¶
type KVOptions []KVOption
KVOptions is a list of KVOptions.
type MaxAggregate ¶
type MaxAggregate struct {
// contains filtered or unexported fields
}
MaxAggregate keeps track of the largest value passed to Add.
func (*MaxAggregate) Add ¶
func (a *MaxAggregate) Add(_ context.Context, datum Datum) error
Add sets the max to the larger of the current max or the passed datum.
func (*MaxAggregate) Close ¶
func (a *MaxAggregate) Close(context.Context)
Close is part of the AggregateFunc interface.
func (*MaxAggregate) Result ¶
func (a *MaxAggregate) Result() (Datum, error)
Result returns the largest value passed to Add.
type MinAggregate ¶
type MinAggregate struct {
// contains filtered or unexported fields
}
MinAggregate keeps track of the smallest value passed to Add.
func (*MinAggregate) Add ¶
func (a *MinAggregate) Add(_ context.Context, datum Datum) error
Add sets the min to the smaller of the current min or the passed datum.
func (*MinAggregate) Close ¶
func (a *MinAggregate) Close(context.Context)
Close is part of the AggregateFunc interface.
func (*MinAggregate) Result ¶
func (a *MinAggregate) Result() (Datum, error)
Result returns the smallest value passed to Add.
type MultipleResultsError ¶
type MultipleResultsError struct {
SQL string // the query that produced this error
}
MultipleResultsError is returned by QueryRow when more than one result is encountered.
func (*MultipleResultsError) Error ¶
func (e *MultipleResultsError) Error() string
type Name ¶
type Name string
A Name is an SQL identifier.
type NameColType ¶
type NameColType struct{}
NameColType represents a a NAME type.
func (*NameColType) Format ¶
func (node *NameColType) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*NameColType) String ¶
func (node *NameColType) String() string
type NameList ¶
type NameList []Name
A NameList is a list of identifiers.
type NamePart ¶
type NamePart interface { NodeFormatter // contains filtered or unexported methods }
NamePart is the interface for the sub-parts of an UnresolvedName or the Selector/Context members of ColumnItem and FunctionName.
type NameParts ¶
type NameParts []NamePart
NameParts represents a combination of names with array and sub-field subscripts.
type NamedColumnQualification ¶
type NamedColumnQualification struct { Name Name Qualification ColumnQualification }
NamedColumnQualification wraps a NamedColumnQualification with a name.
type NaturalJoinCond ¶
type NaturalJoinCond struct{}
NaturalJoinCond represents a NATURAL join condition
type NoReturningClause ¶
type NoReturningClause struct{}
NoReturningClause represents the absence of a RETURNING clause.
type NodeFormatter ¶
type NodeFormatter interface { // Format performs pretty-printing towards a bytes buffer. The flags argument // influences the results. Most callers should use FormatNode instead. Format(buf *bytes.Buffer, flags FmtFlags) }
NodeFormatter is implemented by nodes that can be pretty-printed.
type NormalizableTableName ¶
type NormalizableTableName struct {
TableNameReference
}
NormalizableTableName implements an editable table name.
func (NormalizableTableName) Format ¶
func (nt NormalizableTableName) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*NormalizableTableName) Normalize ¶
func (nt *NormalizableTableName) Normalize() (*TableName, error)
Normalize checks if the table name is already normalized and normalizes it as necessary.
func (*NormalizableTableName) NormalizeWithDatabaseName ¶
func (nt *NormalizableTableName) NormalizeWithDatabaseName(database string) (*TableName, error)
NormalizeWithDatabaseName combines Normalize and QualifyWithDatabase.
func (NormalizableTableName) String ¶
func (nt NormalizableTableName) String() string
func (*NormalizableTableName) TableName ¶
func (nt *NormalizableTableName) TableName() *TableName
TableName asserts that the table name has been previously normalized.
type NotExpr ¶
type NotExpr struct { Expr Expr // contains filtered or unexported fields }
NotExpr represents a NOT expression.
func NewTypedNotExpr ¶
NewTypedNotExpr returns a new NotExpr that is verified to be well-typed.
func (*NotExpr) Eval ¶
func (expr *NotExpr) Eval(ctx *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (NotExpr) ResolvedType ¶
func (ta NotExpr) ResolvedType() Type
func (*NotExpr) TypeCheck ¶
func (expr *NotExpr) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
TypeCheck implements the Expr interface.
func (*NotExpr) TypedInnerExpr ¶
TypedInnerExpr returns the NotExpr's inner expression as a TypedExpr.
type NotNullConstraint ¶
type NotNullConstraint struct{}
NotNullConstraint represents NOT NULL on a column.
type NullIfExpr ¶
NullIfExpr represents a NULLIF expression.
func (*NullIfExpr) Eval ¶
func (expr *NullIfExpr) Eval(ctx *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (*NullIfExpr) Format ¶
func (node *NullIfExpr) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (NullIfExpr) ResolvedType ¶
func (ta NullIfExpr) ResolvedType() Type
func (*NullIfExpr) String ¶
func (node *NullIfExpr) String() string
func (*NullIfExpr) TypeCheck ¶
func (expr *NullIfExpr) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
TypeCheck implements the Expr interface.
func (*NullIfExpr) Walk ¶
func (expr *NullIfExpr) Walk(v Visitor) Expr
Walk implements the Expr interface.
type Nullability ¶
type Nullability int
Nullability represents either NULL, NOT NULL or an unspecified value (silent NULL).
const ( NotNull Nullability = iota Null SilentNull )
The values for NullType.
type NumVal ¶
type NumVal struct { constant.Value // We preserve the "original" string representation (before folding). OrigString string // contains filtered or unexported fields }
NumVal represents a constant numeric value.
func (*NumVal) AsInt64 ¶
AsInt64 returns the value as a 64-bit integer if possible, or returns an error if not possible. The method will set expr.resInt to the value of this int64 if it is successful, avoiding the need to call the method again.
func (*NumVal) AvailableTypes ¶
AvailableTypes implements the Constant interface.
func (*NumVal) ResolveAsType ¶
func (expr *NumVal) ResolveAsType(ctx *SemaContext, typ Type) (Datum, error)
ResolveAsType implements the Constant interface.
func (*NumVal) ShouldBeInt64 ¶
ShouldBeInt64 checks if the value naturally is an int64:
1 = yes 1.0 = no 1.1 = no 123...overflow...456 = no
Currently unused so commented out, but useful even just for its documentation value.
type OidColType ¶
type OidColType struct {
Name string
}
OidColType represents an OID type, which is the type of system object identifiers. There are several different OID types: the raw OID type, which can be any integer, and the reg* types, each of which corresponds to the particular system table that contains the system object identified by the OID itself.
See https://www.postgresql.org/docs/9.6/static/datatype-oid.html.
func (*OidColType) Format ¶
func (node *OidColType) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*OidColType) String ¶
func (node *OidColType) String() string
type OnConflict ¶
type OnConflict struct { Columns NameList Exprs UpdateExprs Where *Where DoNothing bool }
OnConflict represents an `ON CONFLICT (columns) DO UPDATE SET exprs WHERE where` clause.
The zero value for OnConflict is used to signal the UPSERT short form, which uses the primary key for as the conflict index and the values being inserted for Exprs.
func (*OnConflict) IsUpsertAlias ¶
func (oc *OnConflict) IsUpsertAlias() bool
IsUpsertAlias returns true if the UPSERT syntactic sugar was used.
type OrExpr ¶
type OrExpr struct {
Left, Right Expr
// contains filtered or unexported fields
}
OrExpr represents an OR expression.
func NewTypedOrExpr ¶
NewTypedOrExpr returns a new OrExpr that is verified to be well-typed.
func (*OrExpr) Eval ¶
func (expr *OrExpr) Eval(ctx *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (OrExpr) ResolvedType ¶
func (ta OrExpr) ResolvedType() Type
func (*OrExpr) TypeCheck ¶
func (expr *OrExpr) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
TypeCheck implements the Expr interface.
func (*OrExpr) TypedRight ¶
TypedRight returns the OrExpr's right expression as a TypedExpr.
type ParenExpr ¶
type ParenExpr struct { Expr Expr // contains filtered or unexported fields }
ParenExpr represents a parenthesized expression.
func (*ParenExpr) Eval ¶
func (expr *ParenExpr) Eval(ctx *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (ParenExpr) ResolvedType ¶
func (ta ParenExpr) ResolvedType() Type
func (*ParenExpr) TypeCheck ¶
func (expr *ParenExpr) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
TypeCheck implements the Expr interface.
func (*ParenExpr) TypedInnerExpr ¶
TypedInnerExpr returns the ParenExpr's inner expression as a TypedExpr.
type ParenSelect ¶
type ParenSelect struct {
Select *Select
}
ParenSelect represents a parenthesized SELECT/UNION/VALUES statement.
func (*ParenSelect) Format ¶
func (node *ParenSelect) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*ParenSelect) StatementTag ¶
func (*ParenSelect) StatementTag() string
StatementTag returns a short string identifying the type of statement.
func (*ParenSelect) StatementType ¶
func (*ParenSelect) StatementType() StatementType
StatementType implements the Statement interface.
func (*ParenSelect) String ¶
func (n *ParenSelect) String() string
func (*ParenSelect) WalkStmt ¶
func (stmt *ParenSelect) WalkStmt(v Visitor) Statement
WalkStmt is part of the WalkableStmt interface.
type ParenTableExpr ¶
type ParenTableExpr struct {
Expr TableExpr
}
ParenTableExpr represents a parenthesized TableExpr.
func (*ParenTableExpr) Format ¶
func (node *ParenTableExpr) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*ParenTableExpr) String ¶
func (node *ParenTableExpr) String() string
type Parser ¶
type Parser struct {
// contains filtered or unexported fields
}
Parser wraps a scanner, parser and other utilities present in the parser package.
func (*Parser) AggregateInExpr ¶
func (p *Parser) AggregateInExpr(expr Expr, searchPath SearchPath) bool
AggregateInExpr determines if an Expr contains an aggregate function.
func (*Parser) AssertNoAggregationOrWindowing ¶
func (p *Parser) AssertNoAggregationOrWindowing(expr Expr, op string, searchPath SearchPath) error
AssertNoAggregationOrWindowing checks if the provided expression contains either aggregate functions or window functions, returning an error in either case.
func (*Parser) IsAggregate ¶
func (p *Parser) IsAggregate(n *SelectClause, searchPath SearchPath) bool
IsAggregate determines if SelectClause contains an aggregate function.
func (*Parser) NormalizeExpr ¶
func (p *Parser) NormalizeExpr(ctx *EvalContext, typedExpr TypedExpr) (TypedExpr, error)
NormalizeExpr is wrapper around ctx.NormalizeExpr which avoids allocation of a normalizeVisitor.
func (*Parser) Parse ¶
func (p *Parser) Parse(sql string) (stmts StatementList, err error)
Parse parses the sql and returns a list of statements.
func (*Parser) WindowFuncInExpr ¶
WindowFuncInExpr determines if an Expr contains a window function, using the Parser's embedded visitor.
func (*Parser) WindowFuncInExprs ¶
WindowFuncInExprs determines if any of the provided TypedExpr contains a window function, using the Parser's embedded visitor.
type Placeholder ¶
type Placeholder struct { Name string // contains filtered or unexported fields }
Placeholder represents a named placeholder.
func NewPlaceholder ¶
func NewPlaceholder(name string) *Placeholder
NewPlaceholder allocates a Placeholder.
func (*Placeholder) Eval ¶
func (node *Placeholder) Eval(_ *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (*Placeholder) Format ¶
func (node *Placeholder) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*Placeholder) ResolvedType ¶
func (node *Placeholder) ResolvedType() Type
ResolvedType implements the TypedExpr interface.
func (*Placeholder) String ¶
func (node *Placeholder) String() string
func (*Placeholder) TypeCheck ¶
func (expr *Placeholder) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
TypeCheck implements the Expr interface.
func (*Placeholder) Variable ¶
func (*Placeholder) Variable()
Variable implements the VariableExpr interface.
func (*Placeholder) Walk ¶
func (expr *Placeholder) Walk(_ Visitor) Expr
Walk implements the Expr interface.
type PlaceholderInfo ¶
type PlaceholderInfo struct { Values QueryArguments Types PlaceholderTypes }
PlaceholderInfo defines the interface to SQL placeholders.
func MakePlaceholderInfo ¶
func MakePlaceholderInfo() PlaceholderInfo
MakePlaceholderInfo constructs an empty PlaceholderInfo.
func (*PlaceholderInfo) AssertAllAssigned ¶
func (p *PlaceholderInfo) AssertAllAssigned() error
AssertAllAssigned ensures that all placeholders that are used also have a value assigned.
func (*PlaceholderInfo) Assign ¶
func (p *PlaceholderInfo) Assign(src *PlaceholderInfo)
Assign resets the PlaceholderInfo to the contents of src. If src is nil, the map is cleared.
func (*PlaceholderInfo) Clear ¶
func (p *PlaceholderInfo) Clear()
Clear resets the placeholder info map.
func (*PlaceholderInfo) FillUnassigned ¶
func (p *PlaceholderInfo) FillUnassigned()
FillUnassigned sets all unsassigned placeholders to NULL.
func (*PlaceholderInfo) IsUnresolvedPlaceholder ¶
func (p *PlaceholderInfo) IsUnresolvedPlaceholder(expr Expr) bool
IsUnresolvedPlaceholder returns whether expr is an unresolved placeholder. In other words, it returns whether the provided expression is a placeholder expression or a placeholder expression within nested parentheses, and if so, whether the placeholder's type remains unset in the PlaceholderInfo.
func (*PlaceholderInfo) SetType ¶
func (p *PlaceholderInfo) SetType(name string, typ Type) error
SetType assignes a known type to a placeholder. Reports an error if another type was previously assigned.
func (*PlaceholderInfo) SetTypes ¶
func (p *PlaceholderInfo) SetTypes(src PlaceholderTypes)
SetTypes resets the type and values in the map and replaces the types map by an alias to src. If src is nil, the map is cleared. The types map is aliased because the invoking code from pgwire/v3.go for sql.Prepare needs to receive the updated type assignments after Prepare completes.
func (*PlaceholderInfo) SetValue ¶
func (p *PlaceholderInfo) SetValue(name string, val Datum)
SetValue assigns a known value to a placeholder. If no type is known yet, it is inferred from the assigned value.
type PlaceholderTypes ¶
PlaceholderTypes relates placeholder names to their resolved type.
func (PlaceholderTypes) ProcessPlaceholderAnnotations ¶
func (p PlaceholderTypes) ProcessPlaceholderAnnotations(stmt Statement) error
ProcessPlaceholderAnnotations performs an order-independent global traversal of the provided Statement, annotating all placeholders with a type in either of the following situations.
- the placeholder is the subject of an explicit type annotation in at least one of its occurrences. If it is subject to multiple explicit type annotations where the types are not all in agreement, or if the placeholder already has an inferred type in the placeholder map which conflicts with the explicit type annotation type, an error will be thrown.
- the placeholder is the subject to an implicit type annotation, meaning that it is not subject to an explicit type annotation, and that in all occurrences of the placeholder, it is subject to a cast to the same type. If it is subject to casts of multiple types, no error will be thrown, but the placeholder type will not be inferred. If a type has already been assigned for the placeholder in the placeholder map, no error will be thrown, and the placeholder will keep it's previously inferred type.
TODO(nvanbenschoten): Can this visitor and map be preallocated (like normalizeVisitor)?
type Prepare ¶
type Prepare struct { Name Name Types []ColumnType Statement Statement }
Prepare represents a PREPARE statement.
func (*Prepare) StatementTag ¶
StatementTag returns a short string identifying the type of statement.
func (*Prepare) StatementType ¶
func (*Prepare) StatementType() StatementType
StatementType implements the Statement interface.
type PrimaryKeyConstraint ¶
type PrimaryKeyConstraint struct{}
PrimaryKeyConstraint represents NULL on a column.
type QueryArguments ¶
QueryArguments relates placeholder names to their provided query argument.
type RangeCond ¶
type RangeCond struct { Not bool Left Expr From, To Expr // contains filtered or unexported fields }
RangeCond represents a BETWEEN or a NOT BETWEEN expression.
func (*RangeCond) Eval ¶
func (expr *RangeCond) Eval(ctx *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (RangeCond) ResolvedType ¶
func (ta RangeCond) ResolvedType() Type
func (*RangeCond) TypeCheck ¶
func (expr *RangeCond) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
TypeCheck implements the Expr interface.
type RegexpCache ¶
type RegexpCache struct {
// contains filtered or unexported fields
}
A RegexpCache is a cache used to store compiled regular expressions. The cache is safe for concurrent use by multiple goroutines. It is also safe to use the cache through a nil reference, where it will act like a valid cache with no capacity.
func NewRegexpCache ¶
func NewRegexpCache(size int) *RegexpCache
NewRegexpCache creates a new RegexpCache of the given size. The underlying cache internally uses a hash map, so lookups are cheap.
func (*RegexpCache) GetRegexp ¶
func (rc *RegexpCache) GetRegexp(key regexpCacheKey) (*regexp.Regexp, error)
GetRegexp consults the cache for the regular expressions stored for the given key, compiling the key's pattern if it is not already in the cache.
func (*RegexpCache) Len ¶
func (rc *RegexpCache) Len() int
Len returns the number of compiled regular expressions in the cache.
type ReleaseSavepoint ¶
type ReleaseSavepoint struct {
Savepoint string
}
ReleaseSavepoint represents a RELEASE SAVEPOINT <name> statement.
func (*ReleaseSavepoint) Format ¶
func (node *ReleaseSavepoint) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*ReleaseSavepoint) StatementTag ¶
func (*ReleaseSavepoint) StatementTag() string
StatementTag returns a short string identifying the type of statement.
func (*ReleaseSavepoint) StatementType ¶
func (*ReleaseSavepoint) StatementType() StatementType
StatementType implements the Statement interface.
func (*ReleaseSavepoint) String ¶
func (n *ReleaseSavepoint) String() string
type Relocate ¶
type Relocate struct { // Only one of Table and Index can be set. Table *NormalizableTableName Index *TableNameWithIndex // Each row contains an array with store ids and values for the columns in the // PK or index (or a prefix of the columns). // See docs/RFCS/sql_split_syntax.md. Rows *Select }
Relocate represents an `ALTER TABLE/INDEX .. TESTING_RELOCATE ..` statement.
func (*Relocate) StatementTag ¶
StatementTag returns a short string identifying the type of statement.
func (*Relocate) StatementType ¶
func (*Relocate) StatementType() StatementType
StatementType implements the Statement interface.
type RenameColumn ¶
type RenameColumn struct { Table NormalizableTableName Name Name NewName Name // IfExists refers to the table, not the column. IfExists bool }
RenameColumn represents a RENAME COLUMN statement.
func (*RenameColumn) Format ¶
func (node *RenameColumn) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*RenameColumn) StatementTag ¶
func (*RenameColumn) StatementTag() string
StatementTag returns a short string identifying the type of statement.
func (*RenameColumn) StatementType ¶
func (*RenameColumn) StatementType() StatementType
StatementType implements the Statement interface.
func (*RenameColumn) String ¶
func (n *RenameColumn) String() string
type RenameDatabase ¶
RenameDatabase represents a RENAME DATABASE statement.
func (*RenameDatabase) Format ¶
func (node *RenameDatabase) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*RenameDatabase) StatementTag ¶
func (*RenameDatabase) StatementTag() string
StatementTag returns a short string identifying the type of statement.
func (*RenameDatabase) StatementType ¶
func (*RenameDatabase) StatementType() StatementType
StatementType implements the Statement interface.
func (*RenameDatabase) String ¶
func (n *RenameDatabase) String() string
type RenameIndex ¶
type RenameIndex struct { Index *TableNameWithIndex NewName Name IfExists bool }
RenameIndex represents a RENAME INDEX statement.
func (*RenameIndex) Format ¶
func (node *RenameIndex) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*RenameIndex) StatementTag ¶
func (*RenameIndex) StatementTag() string
StatementTag returns a short string identifying the type of statement.
func (*RenameIndex) StatementType ¶
func (*RenameIndex) StatementType() StatementType
StatementType implements the Statement interface.
func (*RenameIndex) String ¶
func (n *RenameIndex) String() string
type RenameTable ¶
type RenameTable struct { Name NormalizableTableName NewName NormalizableTableName IfExists bool IsView bool }
RenameTable represents a RENAME TABLE or RENAME VIEW statement. Whether the user has asked to rename a table or view is indicated by the IsView field.
func (*RenameTable) Format ¶
func (node *RenameTable) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*RenameTable) StatementTag ¶
func (n *RenameTable) StatementTag() string
StatementTag returns a short string identifying the type of statement.
func (*RenameTable) StatementType ¶
func (*RenameTable) StatementType() StatementType
StatementType implements the Statement interface.
func (*RenameTable) String ¶
func (n *RenameTable) String() string
type ResolvableFunctionReference ¶
type ResolvableFunctionReference struct {
FunctionReference
}
ResolvableFunctionReference implements the editable reference cell of a FuncExpr. The FunctionRerence is updated by the Normalize() method.
func (ResolvableFunctionReference) Format ¶
func (fn ResolvableFunctionReference) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*ResolvableFunctionReference) Resolve ¶
func (fn *ResolvableFunctionReference) Resolve(searchPath SearchPath) (*FunctionDefinition, error)
Resolve checks if the function name is already resolved and resolves it as necessary.
func (ResolvableFunctionReference) String ¶
func (fn ResolvableFunctionReference) String() string
type Restore ¶
type Restore struct { Targets TargetList From Exprs AsOf AsOfClause Options KVOptions }
Restore represents a RESTORE statement.
func (*Restore) StatementTag ¶
StatementTag returns a short string identifying the type of statement.
func (*Restore) StatementType ¶
func (*Restore) StatementType() StatementType
StatementType implements the Statement interface.
type ReturningClause ¶
type ReturningClause interface { NodeFormatter // contains filtered or unexported methods }
ReturningClause represents the returning clause on a statement.
type ReturningExprs ¶
type ReturningExprs SelectExprs
ReturningExprs represents RETURNING expressions.
func (*ReturningExprs) CopyNode ¶
func (stmt *ReturningExprs) CopyNode() *ReturningExprs
CopyNode makes a copy of this Statement without recursing in any child Statements.
type ReturningNothing ¶
type ReturningNothing struct{}
ReturningNothing represents RETURNING NOTHING.
type Revoke ¶
type Revoke struct { Privileges privilege.List Targets TargetList Grantees NameList }
Revoke represents a REVOKE statements. PrivilegeList and TargetList are defined in grant.go
func (*Revoke) StatementTag ¶
StatementTag returns a short string identifying the type of statement.
func (*Revoke) StatementType ¶
func (*Revoke) StatementType() StatementType
StatementType implements the Statement interface.
type RollbackToSavepoint ¶
type RollbackToSavepoint struct {
Savepoint string
}
RollbackToSavepoint represents a ROLLBACK TO SAVEPOINT <name> statement.
func (*RollbackToSavepoint) Format ¶
func (node *RollbackToSavepoint) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*RollbackToSavepoint) StatementTag ¶
func (*RollbackToSavepoint) StatementTag() string
StatementTag returns a short string identifying the type of statement.
func (*RollbackToSavepoint) StatementType ¶
func (*RollbackToSavepoint) StatementType() StatementType
StatementType implements the Statement interface.
func (*RollbackToSavepoint) String ¶
func (n *RollbackToSavepoint) String() string
type RollbackTransaction ¶
type RollbackTransaction struct{}
RollbackTransaction represents a ROLLBACK statement.
func (*RollbackTransaction) Format ¶
func (node *RollbackTransaction) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*RollbackTransaction) StatementTag ¶
func (*RollbackTransaction) StatementTag() string
StatementTag returns a short string identifying the type of statement.
func (*RollbackTransaction) StatementType ¶
func (*RollbackTransaction) StatementType() StatementType
StatementType implements the Statement interface.
func (*RollbackTransaction) String ¶
func (n *RollbackTransaction) String() string
type Savepoint ¶
type Savepoint struct {
Name string
}
Savepoint represents a SAVEPOINT <name> statement.
func (*Savepoint) StatementTag ¶
StatementTag returns a short string identifying the type of statement.
func (*Savepoint) StatementType ¶
func (*Savepoint) StatementType() StatementType
StatementType implements the Statement interface.
type Scanner ¶
type Scanner struct {
// contains filtered or unexported fields
}
Scanner lexes SQL statements.
type Scatter ¶
type Scatter struct { // Only one of Table and Index can be set. Table *NormalizableTableName Index *TableNameWithIndex // Optional from and to values for the columns in the PK or index (or a prefix // of the columns). // See docs/RFCS/sql_split_syntax.md. From, To Exprs }
Scatter represents an `ALTER TABLE/INDEX .. SCATTER ..` statement.
func (*Scatter) StatementTag ¶
StatementTag returns a short string identifying the type of statement.
func (*Scatter) StatementType ¶
func (*Scatter) StatementType() StatementType
StatementType implements the Statement interface.
type SearchPath ¶
type SearchPath []string
SearchPath represents a list of namespaces to search builtins in. The names must be normalized (as per Name.Normalize) already.
type Select ¶
type Select struct { Select SelectStatement OrderBy OrderBy Limit *Limit }
Select represents a SelectStatement with an ORDER and/or LIMIT.
func (*Select) CopyNode ¶
CopyNode makes a copy of this Statement without recursing in any child Statements.
func (*Select) StatementTag ¶
StatementTag returns a short string identifying the type of statement.
func (*Select) StatementType ¶
func (*Select) StatementType() StatementType
StatementType implements the Statement interface.
type SelectClause ¶
type SelectClause struct { Distinct bool Exprs SelectExprs From *From Where *Where GroupBy GroupBy Having *Where Window Window // contains filtered or unexported fields }
SelectClause represents a SELECT statement.
func (*SelectClause) CopyNode ¶
func (stmt *SelectClause) CopyNode() *SelectClause
CopyNode makes a copy of this Statement without recursing in any child Statements.
func (*SelectClause) Format ¶
func (node *SelectClause) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*SelectClause) StatementTag ¶
func (*SelectClause) StatementTag() string
StatementTag returns a short string identifying the type of statement.
func (*SelectClause) StatementType ¶
func (*SelectClause) StatementType() StatementType
StatementType implements the Statement interface.
func (*SelectClause) String ¶
func (n *SelectClause) String() string
func (*SelectClause) WalkStmt ¶
func (stmt *SelectClause) WalkStmt(v Visitor) Statement
WalkStmt is part of the WalkableStmt interface.
type SelectExpr ¶
SelectExpr represents a SELECT expression.
func (SelectExpr) Format ¶
func (node SelectExpr) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*SelectExpr) NormalizeTopLevelVarName ¶
func (node *SelectExpr) NormalizeTopLevelVarName() error
NormalizeTopLevelVarName preemptively expands any UnresolvedName at the top level of the expression into a VarName. This is meant to catch stars so that sql.checkRenderStar() can see it prior to other expression transformations.
type SelectStatement ¶
type SelectStatement interface { Statement // contains filtered or unexported methods }
SelectStatement represents any SELECT statement.
type SemaContext ¶
type SemaContext struct { // Placeholders relates placeholder names to their type and, later, value. Placeholders PlaceholderInfo // Location references the *Location on the current Session. Location **time.Location // SearchPath indicates where to search for unqualified function // names. The path elements must be normalized via Name.Normalize() // already. SearchPath []string // contains filtered or unexported fields }
SemaContext defines the context in which to perform semantic analysis on an expression syntax tree.
func MakeSemaContext ¶
func MakeSemaContext(privileged bool) SemaContext
MakeSemaContext initializes a simple SemaContext suitable for "lightweight" type checking such as the one performed for default expressions.
type Set ¶
Set represents a SET or RESET statement.
func (*Set) CopyNode ¶
CopyNode makes a copy of this Statement without recursing in any child Statements.
func (*Set) StatementTag ¶
StatementTag returns a short string identifying the type of statement.
func (*Set) StatementType ¶
func (*Set) StatementType() StatementType
StatementType implements the Statement interface.
type SetDefaultIsolation ¶
type SetDefaultIsolation struct {
Isolation IsolationLevel
}
SetDefaultIsolation represents a SET SESSION CHARACTERISTICS AS TRANSACTION statement.
func (*SetDefaultIsolation) Format ¶
func (node *SetDefaultIsolation) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*SetDefaultIsolation) StatementTag ¶
func (*SetDefaultIsolation) StatementTag() string
StatementTag returns a short string identifying the type of statement.
func (*SetDefaultIsolation) StatementType ¶
func (*SetDefaultIsolation) StatementType() StatementType
StatementType implements the Statement interface.
func (*SetDefaultIsolation) String ¶
func (n *SetDefaultIsolation) String() string
type SetTimeZone ¶
type SetTimeZone struct {
Value Expr
}
SetTimeZone represents a SET TIME ZONE statement.
func (*SetTimeZone) Format ¶
func (node *SetTimeZone) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*SetTimeZone) StatementTag ¶
func (*SetTimeZone) StatementTag() string
StatementTag returns a short string identifying the type of statement.
func (*SetTimeZone) StatementType ¶
func (*SetTimeZone) StatementType() StatementType
StatementType implements the Statement interface.
func (*SetTimeZone) String ¶
func (n *SetTimeZone) String() string
type SetTransaction ¶
type SetTransaction struct { Isolation IsolationLevel UserPriority UserPriority }
SetTransaction represents a SET TRANSACTION statement.
func (*SetTransaction) Format ¶
func (node *SetTransaction) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*SetTransaction) StatementTag ¶
func (*SetTransaction) StatementTag() string
StatementTag returns a short string identifying the type of statement.
func (*SetTransaction) StatementType ¶
func (*SetTransaction) StatementType() StatementType
StatementType implements the Statement interface.
func (*SetTransaction) String ¶
func (n *SetTransaction) String() string
type Show ¶
Show represents a SHOW statement.
func (*Show) StatementTag ¶
StatementTag returns a short string identifying the type of statement.
func (*Show) StatementType ¶
func (*Show) StatementType() StatementType
StatementType implements the Statement interface.
type ShowColumns ¶
type ShowColumns struct {
Table NormalizableTableName
}
ShowColumns represents a SHOW COLUMNS statement.
func (*ShowColumns) Format ¶
func (node *ShowColumns) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*ShowColumns) StatementTag ¶
func (*ShowColumns) StatementTag() string
StatementTag returns a short string identifying the type of statement.
func (*ShowColumns) StatementType ¶
func (*ShowColumns) StatementType() StatementType
StatementType implements the Statement interface.
func (*ShowColumns) String ¶
func (n *ShowColumns) String() string
type ShowConstraints ¶
type ShowConstraints struct {
Table NormalizableTableName
}
ShowConstraints represents a SHOW CONSTRAINTS statement.
func (*ShowConstraints) Format ¶
func (node *ShowConstraints) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*ShowConstraints) StatementTag ¶
func (*ShowConstraints) StatementTag() string
StatementTag returns a short string identifying the type of statement.
func (*ShowConstraints) StatementType ¶
func (*ShowConstraints) StatementType() StatementType
StatementType implements the Statement interface.
func (*ShowConstraints) String ¶
func (n *ShowConstraints) String() string
type ShowCreateTable ¶
type ShowCreateTable struct {
Table NormalizableTableName
}
ShowCreateTable represents a SHOW CREATE TABLE statement.
func (*ShowCreateTable) Format ¶
func (node *ShowCreateTable) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*ShowCreateTable) StatementTag ¶
func (*ShowCreateTable) StatementTag() string
StatementTag returns a short string identifying the type of statement.
func (*ShowCreateTable) StatementType ¶
func (*ShowCreateTable) StatementType() StatementType
StatementType implements the Statement interface.
func (*ShowCreateTable) String ¶
func (n *ShowCreateTable) String() string
type ShowCreateView ¶
type ShowCreateView struct {
View NormalizableTableName
}
ShowCreateView represents a SHOW CREATE VIEW statement.
func (*ShowCreateView) Format ¶
func (node *ShowCreateView) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*ShowCreateView) StatementTag ¶
func (*ShowCreateView) StatementTag() string
StatementTag returns a short string identifying the type of statement.
func (*ShowCreateView) StatementType ¶
func (*ShowCreateView) StatementType() StatementType
StatementType implements the Statement interface.
func (*ShowCreateView) String ¶
func (n *ShowCreateView) String() string
type ShowDatabases ¶
type ShowDatabases struct { }
ShowDatabases represents a SHOW DATABASES statement.
func (*ShowDatabases) Format ¶
func (node *ShowDatabases) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*ShowDatabases) StatementTag ¶
func (*ShowDatabases) StatementTag() string
StatementTag returns a short string identifying the type of statement.
func (*ShowDatabases) StatementType ¶
func (*ShowDatabases) StatementType() StatementType
StatementType implements the Statement interface.
func (*ShowDatabases) String ¶
func (n *ShowDatabases) String() string
type ShowGrants ¶
type ShowGrants struct { Targets *TargetList Grantees NameList }
ShowGrants represents a SHOW GRANTS statement. TargetList is defined in grant.go.
func (*ShowGrants) Format ¶
func (node *ShowGrants) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*ShowGrants) StatementTag ¶
func (*ShowGrants) StatementTag() string
StatementTag returns a short string identifying the type of statement.
func (*ShowGrants) StatementType ¶
func (*ShowGrants) StatementType() StatementType
StatementType implements the Statement interface.
func (*ShowGrants) String ¶
func (n *ShowGrants) String() string
type ShowIndex ¶
type ShowIndex struct {
Table NormalizableTableName
}
ShowIndex represents a SHOW INDEX statement.
func (*ShowIndex) StatementTag ¶
StatementTag returns a short string identifying the type of statement.
func (*ShowIndex) StatementType ¶
func (*ShowIndex) StatementType() StatementType
StatementType implements the Statement interface.
type ShowRanges ¶
type ShowRanges struct { Table *NormalizableTableName Index *TableNameWithIndex }
ShowRanges represents a SHOW TESTING_RANGES statement. Only one of Table and Index can be set.
func (*ShowRanges) Format ¶
func (node *ShowRanges) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*ShowRanges) StatementTag ¶
func (*ShowRanges) StatementTag() string
StatementTag returns a short string identifying the type of statement.
func (*ShowRanges) StatementType ¶
func (*ShowRanges) StatementType() StatementType
StatementType implements the Statement interface.
func (*ShowRanges) String ¶
func (n *ShowRanges) String() string
type ShowTables ¶
type ShowTables struct {
Database Name
}
ShowTables represents a SHOW TABLES statement.
func (*ShowTables) Format ¶
func (node *ShowTables) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*ShowTables) StatementTag ¶
func (*ShowTables) StatementTag() string
StatementTag returns a short string identifying the type of statement.
func (*ShowTables) StatementType ¶
func (*ShowTables) StatementType() StatementType
StatementType implements the Statement interface.
func (*ShowTables) String ¶
func (n *ShowTables) String() string
type ShowTransactionStatus ¶
type ShowTransactionStatus struct { }
ShowTransactionStatus represents a SHOW TRANSACTION STATUS statement.
func (*ShowTransactionStatus) Format ¶
func (node *ShowTransactionStatus) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*ShowTransactionStatus) StatementTag ¶
func (*ShowTransactionStatus) StatementTag() string
StatementTag returns a short string identifying the type of statement.
func (*ShowTransactionStatus) StatementType ¶
func (*ShowTransactionStatus) StatementType() StatementType
StatementType implements the Statement interface.
func (*ShowTransactionStatus) String ¶
func (n *ShowTransactionStatus) String() string
type ShowUsers ¶
type ShowUsers struct { }
ShowUsers represents a SHOW USERS statement.
func (*ShowUsers) StatementTag ¶
StatementTag returns a short string identifying the type of statement.
func (*ShowUsers) StatementType ¶
func (*ShowUsers) StatementType() StatementType
StatementType implements the Statement interface.
type SimpleVisitFn ¶
SimpleVisitFn is a function that is run for every node in the VisitPre stage; see SimpleVisit.
type Split ¶
type Split struct { // Only one of Table and Index can be set. Table *NormalizableTableName Index *TableNameWithIndex // Each row contains values for the columns in the PK or index (or a prefix // of the columns). Rows *Select }
Split represents an `ALTER TABLE/INDEX .. SPLIT AT ..` statement.
func (*Split) StatementTag ¶
StatementTag returns a short string identifying the type of statement.
func (*Split) StatementType ¶
func (*Split) StatementType() StatementType
StatementType implements the Statement interface.
type StarDatum ¶
type StarDatum struct{}
StarDatum is a VariableExpr implementation used as a dummy argument for the special case COUNT(*). This ends up being processed correctly by the count aggregator since it is not DNull. Other instances of '*' as render expressions are handled by expandStar().
We need to implement enough functionality to satisfy the type checker and to allow the intermediate rendering of the value (before the group aggregation).
func (*StarDatum) Eval ¶
func (*StarDatum) Eval(ctx *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (*StarDatum) ResolvedType ¶
ResolvedType implements the TypedExpr interface.
func (*StarDatum) TypeCheck ¶
func (s *StarDatum) TypeCheck(_ *SemaContext, _ Type) (TypedExpr, error)
TypeCheck implements the Expr interface.
type Statement ¶
type Statement interface { fmt.Stringer NodeFormatter StatementType() StatementType // StatementTag is a short string identifying the type of statement // (usually a single verb). This is different than the Stringer output, // which is the actual statement (including args). // TODO(dt): Currently tags are always pg-compatible in the future it // might make sense to pass a tag format specifier. StatementTag() string }
Statement represents a statement.
func ParseOne ¶
ParseOne parses a sql statement string, ensuring that it contains only a single statement, and returns that Statement.
func WalkStmt ¶
WalkStmt walks the entire parsed stmt calling WalkExpr on each expression, and replacing each expression with the one returned by WalkExpr.
NOTE: Beware that WalkStmt does not necessarily traverse all parts of a statement by itself. For example, it will not walk into Subquery nodes within a FROM clause or into a JoinCond. Walk's logic is pretty interdependent with the logic for constructing a query plan.
type StatementList ¶
type StatementList []Statement
StatementList is a list of statements.
func Parse ¶
func Parse(sql string) (StatementList, error)
Parse parses a sql statement string and returns a list of Statements.
func (StatementList) Format ¶
func (l StatementList) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (StatementList) String ¶
func (l StatementList) String() string
type StatementType ¶
type StatementType int
StatementType is the enumerated type for Statement return styles on the wire.
const ( // Ack indicates that the statement does not have a meaningful // return. Examples include SET, BEGIN, COMMIT. Ack StatementType = iota // DDL indicates that the statement mutates the database schema. DDL // RowsAffected indicates that the statement returns the count of // affected rows. RowsAffected // Rows indicates that the statement returns the affected rows after // the statement was applied. Rows // CopyIn indicates a COPY FROM statement. CopyIn // Unknown indicates that the statement does not have a known // return style at the time of parsing. This is not first in the // enumeration because it is more convenient to have Ack as a zero // value, and because the use of Unknown should be an explicit choice. // The primary example of this statement type is EXECUTE, where the // statement type depends on the statement type of the prepared statement // being executed. Unknown )
type StrVal ¶
type StrVal struct {
// contains filtered or unexported fields
}
StrVal represents a constant string value.
func (*StrVal) AvailableTypes ¶
AvailableTypes implements the Constant interface.
To fully take advantage of literal type inference, this method would determine exactly which types are available for a given string. This would entail attempting to parse the literal string as a date, a timestamp, an interval, etc. and having more fine-grained results than strValAvailAllParsable. However, this is not feasible in practice because of the associated parsing overhead.
Conservative approaches like checking the string's length have been investigated to reduce ambiguity and improve type inference in some cases. When doing so, the length of the string literal was compared against all valid date and timestamp formats to quickly gain limited insight into whether parsing the string as the respective datum types could succeed. The hope was to eliminate impossibilities and constrain the returned type sets as much as possible. Unfortunately, two issues were found with this approach:
- date and timestamp formats do not always imply a fixed-length valid input. For instance, timestamp formats that take fractional seconds can successfully parse inputs of varied length.
- the set of date and timestamp formats are not disjoint, which means that ambiguity can not be eliminated when inferring the type of string literals that use these shared formats.
While these limitations still permitted improved type inference in many cases, they resulted in behavior that was ultimately incomplete, resulted in unpredictable levels of inference, and occasionally failed to eliminate ambiguity. Further heuristics could have been applied to improve the accuracy of the inference, like checking that all or some characters were digits, but it would not have circumvented the fundamental issues here. Fully parsing the literal into each type would be the only way to concretely avoid the issue of unpredictable inference behavior.
func (*StrVal) ResolveAsType ¶
func (expr *StrVal) ResolveAsType(ctx *SemaContext, typ Type) (Datum, error)
ResolveAsType implements the Constant interface.
type StringColType ¶
StringColType represents a STRING, CHAR or VARCHAR type.
func (*StringColType) Format ¶
func (node *StringColType) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*StringColType) String ¶
func (node *StringColType) String() string
type Subquery ¶
type Subquery struct {
Select SelectStatement
}
Subquery represents a subquery.
func (*Subquery) TypeCheck ¶
func (expr *Subquery) TypeCheck(_ *SemaContext, desired Type) (TypedExpr, error)
TypeCheck implements the Expr interface.
type TArray ¶
type TArray struct{ Typ Type }
TArray is the type of a DArray.
func (TArray) Equivalent ¶
Equivalent implements the Type interface.
func (TArray) FamilyEqual ¶
FamilyEqual implements the Type interface.
func (TArray) IsAmbiguous ¶
IsAmbiguous implements the Type interface.
type TCollatedString ¶
type TCollatedString struct {
Locale string
}
TCollatedString is the type of strings with a locale.
func (TCollatedString) Equivalent ¶
func (t TCollatedString) Equivalent(other Type) bool
Equivalent implements the Type interface.
func (TCollatedString) FamilyEqual ¶
func (TCollatedString) FamilyEqual(other Type) bool
FamilyEqual implements the Type interface.
func (TCollatedString) IsAmbiguous ¶
func (t TCollatedString) IsAmbiguous() bool
IsAmbiguous implements the Type interface.
func (TCollatedString) Oid ¶
func (TCollatedString) Oid() oid.Oid
Oid implements the Type interface.
func (TCollatedString) SQLName ¶
func (TCollatedString) SQLName() string
SQLName implements the Type interface.
func (TCollatedString) Size ¶
func (TCollatedString) Size() (uintptr, bool)
Size implements the Type interface.
func (TCollatedString) String ¶
func (t TCollatedString) String() string
String implements the fmt.Stringer interface.
type TPlaceholder ¶
type TPlaceholder struct {
Name string
}
TPlaceholder is the type of a placeholder.
func (TPlaceholder) Equivalent ¶
func (t TPlaceholder) Equivalent(other Type) bool
Equivalent implements the Type interface.
func (TPlaceholder) FamilyEqual ¶
func (TPlaceholder) FamilyEqual(other Type) bool
FamilyEqual implements the Type interface.
func (TPlaceholder) IsAmbiguous ¶
func (TPlaceholder) IsAmbiguous() bool
IsAmbiguous implements the Type interface.
func (TPlaceholder) SQLName ¶
func (TPlaceholder) SQLName() string
SQLName implements the Type interface.
func (TPlaceholder) Size ¶
func (TPlaceholder) Size() (uintptr, bool)
Size implements the Type interface.
func (TPlaceholder) String ¶
func (t TPlaceholder) String() string
String implements the fmt.Stringer interface.
type TTable ¶
type TTable struct{ Cols TTuple }
TTable is the type of a DTable. See the comments at the start of generator_builtins.go for details.
func (TTable) Equivalent ¶
Equivalent implements the Type interface.
func (TTable) FamilyEqual ¶
FamilyEqual implements the Type interface.
func (TTable) IsAmbiguous ¶
IsAmbiguous implements the Type interface.
type TTuple ¶
type TTuple []Type
TTuple is the type of a DTuple.
func (TTuple) Equivalent ¶
Equivalent implements the Type interface.
func (TTuple) FamilyEqual ¶
FamilyEqual implements the Type interface.
func (TTuple) IsAmbiguous ¶
IsAmbiguous implements the Type interface.
type TableDef ¶
type TableDef interface { NodeFormatter // contains filtered or unexported methods }
TableDef represents a column, index or constraint definition within a CREATE TABLE statement.
type TableExpr ¶
type TableExpr interface { NodeFormatter // contains filtered or unexported methods }
TableExpr represents a table expression.
type TableName ¶
type TableName struct { DatabaseName Name TableName Name // DBNameOriginallyOmitted, when set to true, causes the // String()/Format() methods to omit the database name even if one // is set. This is used to ensure that pretty-printing // a TableName normalized from a parser input yields back // the original syntax. DBNameOriginallyOmitted bool }
TableName corresponds to the name of a table in a FROM clause, INSERT or UPDATE statement (and possibly other places).
func ParseTableName ¶
ParseTableName parses a table name.
func (*TableName) NormalizeTableName ¶
NormalizeTableName implements the TableNameReference interface.
func (*TableName) NormalizeTablePattern ¶
func (t *TableName) NormalizeTablePattern() (TablePattern, error)
NormalizeTablePattern implements the TablePattern interface.
func (*TableName) NormalizedTableName ¶
NormalizedTableName normalize DatabaseName and TableName to lowercase and performs Unicode Normalization.
func (*TableName) QualifyWithDatabase ¶
QualifyWithDatabase adds an indirection for the database, if it's missing. It transforms: table -> database.table table@index -> database.table@index
type TableNameReference ¶
type TableNameReference interface { fmt.Stringer NodeFormatter NormalizeTableName() (*TableName, error) }
TableNameReference implements the editable cell of a TableExpr that refers to a single table.
type TableNameReferences ¶
type TableNameReferences []TableNameReference
TableNameReferences corresponds to a comma-delimited list of table name references.
type TableNameWithIndex ¶
type TableNameWithIndex struct { Table NormalizableTableName Index Name // SearchTable indicates that we have just an index (no table name); we will // need to search for a table that has an index with the given name. // // To allow schema-qualified index names in this case, the index is actually // specified in Table as the table name, and Index is empty. SearchTable bool }
TableNameWithIndex represents a "table@index", used in statements that specifically refer to an index.
type TableNameWithIndexList ¶
type TableNameWithIndexList []*TableNameWithIndex
TableNameWithIndexList is a list of indexes.
type TableNames ¶
type TableNames []TableName
TableNames represents a comma separated list (see the Format method) of table names.
func (TableNames) Format ¶
func (ts TableNames) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (TableNames) String ¶
func (ts TableNames) String() string
type TablePattern ¶
type TablePattern interface { fmt.Stringer NodeFormatter NormalizeTablePattern() (TablePattern, error) }
TablePattern is the common interface to UnresolvedName, TableName and AllTablesSelector.
type TablePatterns ¶
type TablePatterns []TablePattern
TablePatterns implement a comma-separated list of table patterns. Used by e.g. the GRANT statement.
type TableRef ¶
type TableRef struct { // TableID is the descriptor ID of the requested table. TableID int64 // ColumnIDs is the list of column IDs requested in the table. // Note that a nil array here means "unspecified" (all columns) // whereas an array of length 0 means "zero columns". Columns []ColumnID }
TableRef represents a numeric table reference. (Syntax !NNN in SQL.)
type TargetList ¶
type TargetList struct { Databases NameList Tables TablePatterns }
TargetList represents a list of targets. Only one field may be non-nil.
type TimestampColType ¶
type TimestampColType struct { }
TimestampColType represents a TIMESTAMP type.
func (*TimestampColType) Format ¶
func (node *TimestampColType) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*TimestampColType) String ¶
func (node *TimestampColType) String() string
type TimestampTZColType ¶
type TimestampTZColType struct { }
TimestampTZColType represents a TIMESTAMP type.
func (*TimestampTZColType) Format ¶
func (node *TimestampTZColType) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*TimestampTZColType) String ¶
func (node *TimestampTZColType) String() string
type Truncate ¶
type Truncate struct { Tables TableNameReferences DropBehavior DropBehavior }
Truncate represents a TRUNCATE statement.
func (*Truncate) StatementTag ¶
StatementTag returns a short string identifying the type of statement.
func (*Truncate) StatementType ¶
func (*Truncate) StatementType() StatementType
StatementType implements the Statement interface.
type Tuple ¶
type Tuple struct { Exprs Exprs // contains filtered or unexported fields }
Tuple represents a parenthesized list of expressions.
func (*Tuple) Eval ¶
func (t *Tuple) Eval(ctx *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (*Tuple) ResolvedType ¶
ResolvedType implements the TypedExpr interface.
type Type ¶
type Type interface { fmt.Stringer // Equivalent returns whether the receiver and the other type are equivalent. // We say that two type patterns are "equivalent" when they are structurally // equivalent given that a wildcard is equivalent to any type. When neither // Type is ambiguous (see IsAmbiguous), equivalency is the same as type equality. Equivalent(other Type) bool // FamilyEqual returns whether the receiver and the other type have the same // constructor. FamilyEqual(other Type) bool // Oid returns the type's Postgres object ID. Oid() oid.Oid // SQLName returns the type's SQL standard name. This can be looked up for a // type `t` in postgres by running `SELECT format_type(t::regtype, NULL)`. SQLName() string // Size returns a lower bound on the total size of a Datum whose type is the // receiver in bytes, including memory that is pointed at (even if shared // between Datum instances) but excluding allocation overhead. // // The second argument indicates whether data of this type have different // sizes. // // It holds for every Datum d that d.Size() >= d.ResolvedType().Size(). Size() (uintptr, bool) // IsAmbiguous returns whether the type is ambiguous or fully defined. This // is important for parameterized types to determine whether they are fully // concrete type specification or not. IsAmbiguous() bool }
Type represents a SQL type.
func CastTargetToDatumType ¶
func CastTargetToDatumType(t CastTargetType) Type
CastTargetToDatumType produces a Type equivalent to the given SQL cast target type.
func UnwrapType ¶
UnwrapType returns the base Type type for a provided type, stripping a *TOidWrapper if present. This is useful for cases like type switches, where type aliases should be ignored.
type TypedExpr ¶
type TypedExpr interface { Expr // Eval evaluates an SQL expression. Expression evaluation is a // mostly straightforward walk over the parse tree. The only // significant complexity is the handling of types and implicit // conversions. See binOps and cmpOps for more details. Note that // expression evaluation returns an error if certain node types are // encountered: Placeholder, VarName (and related UnqualifiedStar, // UnresolvedName and AllColumnsSelector) or Subquery. These nodes // should be replaced prior to expression evaluation by an // appropriate WalkExpr. For example, Placeholder should be replace // by the argument passed from the client. Eval(*EvalContext) (Datum, error) // ResolvedType provides the type of the TypedExpr, which is the type of Datum // that the TypedExpr will return when evaluated. ResolvedType() Type }
TypedExpr represents a well-typed expression.
func ReType ¶
ReType ensures that the given numeric expression evaluates to the requested type, inserting a cast if necessary.
func TypeCheck ¶
func TypeCheck(expr Expr, ctx *SemaContext, desired Type) (TypedExpr, error)
TypeCheck performs type checking on the provided expression tree, returning the new typed expression tree, which additionally permits evaluation and type introspection globally and on each sub-tree.
While doing so, it will fold numeric constants and bind placeholder names to their inferred types in the provided context. The optional desired parameter can be used to hint the desired type for the root of the resulting typed expression tree. Like with Expr.TypeCheck, it is not valid to provide a nil desired type. Instead, call it with the wildcard type TypeAny if no specific type is desired.
func TypeCheckAndRequire ¶
TypeCheckAndRequire performs type checking on the provided expression tree in an identical manner to TypeCheck. It then asserts that the resulting TypedExpr has the provided return type, returning both the typed expression and an error if it does not.
type TypedExprs ¶
type TypedExprs []TypedExpr
TypedExprs represents a list of well-typed value expressions. It's not a valid expression because it's not parenthesized.
func (TypedExprs) String ¶
func (node TypedExprs) String() string
type UnaryExpr ¶
type UnaryExpr struct { Operator UnaryOperator Expr Expr // contains filtered or unexported fields }
UnaryExpr represents a unary value expression.
func (*UnaryExpr) Eval ¶
func (expr *UnaryExpr) Eval(ctx *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (UnaryExpr) ResolvedType ¶
func (ta UnaryExpr) ResolvedType() Type
func (*UnaryExpr) TypeCheck ¶
func (expr *UnaryExpr) TypeCheck(ctx *SemaContext, desired Type) (TypedExpr, error)
TypeCheck implements the Expr interface.
func (*UnaryExpr) TypedInnerExpr ¶
TypedInnerExpr returns the UnaryExpr's inner expression as a TypedExpr.
type UnaryOperator ¶
type UnaryOperator int
UnaryOperator represents a unary operator.
const ( UnaryPlus UnaryOperator = iota UnaryMinus UnaryComplement )
UnaryExpr.Operator
func (UnaryOperator) String ¶
func (i UnaryOperator) String() string
type UnionClause ¶
UnionClause represents a UNION statement.
func (*UnionClause) Format ¶
func (node *UnionClause) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (*UnionClause) StatementTag ¶
func (*UnionClause) StatementTag() string
StatementTag returns a short string identifying the type of statement.
func (*UnionClause) StatementType ¶
func (*UnionClause) StatementType() StatementType
StatementType implements the Statement interface.
func (*UnionClause) String ¶
func (n *UnionClause) String() string
type UniqueConstraint ¶
type UniqueConstraint struct{}
UniqueConstraint represents UNIQUE on a column.
type UniqueConstraintTableDef ¶
type UniqueConstraintTableDef struct { IndexTableDef PrimaryKey bool }
UniqueConstraintTableDef represents a unique constraint within a CREATE TABLE statement.
type UnqualifiedStar ¶
type UnqualifiedStar struct{}
UnqualifiedStar corresponds to a standalone '*' in an expression or a '*' as name part of an UnresolvedName.
func (UnqualifiedStar) Eval ¶
func (expr UnqualifiedStar) Eval(ctx *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (UnqualifiedStar) Format ¶
func (UnqualifiedStar) Format(buf *bytes.Buffer, _ FmtFlags)
Format implements the NodeFormatter interface.
func (UnqualifiedStar) NormalizeVarName ¶
func (u UnqualifiedStar) NormalizeVarName() (VarName, error)
NormalizeVarName is a no-op for UnqualifiedStar (already normalized)
func (UnqualifiedStar) ResolvedType ¶
func (UnqualifiedStar) ResolvedType() Type
ResolvedType implements the TypedExpr interface.
func (UnqualifiedStar) String ¶
func (u UnqualifiedStar) String() string
func (UnqualifiedStar) TypeCheck ¶
func (expr UnqualifiedStar) TypeCheck(_ *SemaContext, desired Type) (TypedExpr, error)
TypeCheck implements the Expr interface.
func (UnqualifiedStar) Variable ¶
func (UnqualifiedStar) Variable()
Variable implements the VariableExpr interface.
func (UnqualifiedStar) Walk ¶
func (expr UnqualifiedStar) Walk(_ Visitor) Expr
Walk implements the Expr interface.
type UnresolvedName ¶
type UnresolvedName NameParts
UnresolvedName holds the initial syntax of a name as determined during parsing.
func (UnresolvedName) Eval ¶
func (expr UnresolvedName) Eval(ctx *EvalContext) (Datum, error)
Eval implements the TypedExpr interface.
func (UnresolvedName) Format ¶
func (u UnresolvedName) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (UnresolvedName) NormalizeTableName ¶
func (n UnresolvedName) NormalizeTableName() (*TableName, error)
NormalizeTableName implements the TableNameReference interface.
func (UnresolvedName) NormalizeTablePattern ¶
func (n UnresolvedName) NormalizeTablePattern() (TablePattern, error)
NormalizeTablePattern resolves an UnresolvedName to either a TableName or AllTablesSelector.
func (UnresolvedName) NormalizeUnqualifiedColumnItem ¶
func (n UnresolvedName) NormalizeUnqualifiedColumnItem() (*ColumnItem, error)
NormalizeUnqualifiedColumnItem normalizes a UnresolvedName for all the forms it can have inside a context that requires an unqualified column item (e.g. UPDATE LHS, INSERT, etc.).
func (UnresolvedName) NormalizeVarName ¶
func (n UnresolvedName) NormalizeVarName() (VarName, error)
NormalizeVarName normalizes a UnresolvedName for all the forms it can have inside an expression context.
func (UnresolvedName) ResolveFunction ¶
func (n UnresolvedName) ResolveFunction(searchPath SearchPath) (*FunctionDefinition, error)
ResolveFunction transforms an UnresolvedName to a FunctionDefinition.
func (UnresolvedName) ResolvedType ¶
func (UnresolvedName) ResolvedType() Type
ResolvedType implements the TypedExpr interface.
func (UnresolvedName) String ¶
func (u UnresolvedName) String() string
func (UnresolvedName) TypeCheck ¶
func (expr UnresolvedName) TypeCheck(s *SemaContext, desired Type) (TypedExpr, error)
TypeCheck implements the Expr interface.
func (UnresolvedName) Variable ¶
func (UnresolvedName) Variable()
Variable implements the VariableExpr interface. Although, the UnresolvedName ought to be replaced to an IndexedVar before the points the VariableExpr interface is used.
func (UnresolvedName) Walk ¶
func (expr UnresolvedName) Walk(_ Visitor) Expr
Walk implements the Expr interface.
type UnresolvedNames ¶
type UnresolvedNames []UnresolvedName
UnresolvedNames corresponds to a comma-separate list of unresolved names. Note: this should be treated as immutable when embedded in an Expr context, otherwise the Walk code must be updated to duplicate the array an Expr node is duplicated.
type Update ¶
type Update struct { Table TableExpr Exprs UpdateExprs Where *Where Returning ReturningClause }
Update represents an UPDATE statement.
func (*Update) CopyNode ¶
CopyNode makes a copy of this Statement without recursing in any child Statements.
func (*Update) StatementTag ¶
StatementTag returns a short string identifying the type of statement.
func (*Update) StatementType ¶
func (n *Update) StatementType() StatementType
StatementType implements the Statement interface.
type UpdateExpr ¶
type UpdateExpr struct { Tuple bool Names UnresolvedNames Expr Expr }
UpdateExpr represents an update expression.
type UpdateExprs ¶
type UpdateExprs []*UpdateExpr
UpdateExprs represents a list of update expressions.
type UserPriority ¶
type UserPriority int
UserPriority holds the user priority for a transaction.
const ( UnspecifiedUserPriority UserPriority = iota Low Normal High )
UserPriority values
func (UserPriority) String ¶
func (up UserPriority) String() string
type UsingJoinCond ¶
type UsingJoinCond struct {
Cols NameList
}
UsingJoinCond represents a USING join condition.
type ValidationBehavior ¶
type ValidationBehavior int
ValidationBehavior specifies whether or not a constraint is validated.
const ( // ValidationDefault is the default validation behavior (immediate). ValidationDefault ValidationBehavior = iota // ValidationSkip skips validation of any existing data. ValidationSkip )
type ValueGenerator ¶
type ValueGenerator interface { // ColumnTypes returns the type signature of this value generator. // Used by DTable.ResolvedType(). ColumnTypes() TTuple // Start initializes the generator. Must be called once before // Next() and Values(). Start() error // Next determines whether there is a row of data available. Next() (bool, error) // Values retrieves the current row of data. Values() Datums // Close must be called after Start() before disposing of the // ValueGenerator. It does not need to be called if Start() has not // been called yet. Close() }
ValueGenerator is the interface provided by the object held by a DTable; objects that implement this interface are able to produce rows of values in a streaming fashion (like Go iterators or generators in Python).
type ValuesClause ¶
type ValuesClause struct {
Tuples []*Tuple
}
ValuesClause represents a VALUES clause.
func (*ValuesClause) Format ¶
func (node *ValuesClause) Format(buf *bytes.Buffer, f FmtFlags)
Format implements the NodeFormatter interface.
func (ValuesClause) StatementTag ¶
func (ValuesClause) StatementTag() string
StatementTag returns a short string identifying the type of statement.
func (ValuesClause) StatementType ¶
func (ValuesClause) StatementType() StatementType
StatementType implements the Statement interface.
func (*ValuesClause) String ¶
func (n *ValuesClause) String() string
func (*ValuesClause) WalkStmt ¶
func (stmt *ValuesClause) WalkStmt(v Visitor) Statement
WalkStmt is part of the WalkableStmt interface.
type VarName ¶
VarName is the common interface to UnresolvedName, ColumnItem and AllColumnsSelector for use in expression contexts.
type VariableExpr ¶
type VariableExpr interface { Expr Variable() }
VariableExpr is an Expr that may change per row. It is used to signal the evaluation/simplification machinery that the underlying Expr is not constant.
type VariadicType ¶
type VariadicType struct {
Typ Type
}
VariadicType is a typeList implementation which accepts any number of arguments and matches when each argument is either NULL or of the type typ.
func (VariadicType) Length ¶
func (v VariadicType) Length() int
Length implements the typeList interface.
func (VariadicType) String ¶
func (v VariadicType) String() string
func (VariadicType) Types ¶
func (v VariadicType) Types() []Type
Types implements the typeList interface.
type VectorColType ¶
type VectorColType struct { Name string ParamType ColumnType }
VectorColType is the base for VECTOR column types, which are Postgres's older, limited version of ARRAYs. These are not meant to be persisted, because ARRAYs are a strict superset.
func (*VectorColType) Format ¶
func (node *VectorColType) Format(buf *bytes.Buffer, _ FmtFlags)
Format implements the NodeFormatter interface.
func (*VectorColType) String ¶
func (node *VectorColType) String() string
type Visitor ¶
type Visitor interface { // VisitPre is called for each node before recursing into that subtree. Upon return, if recurse // is false, the visit will not recurse into the subtree (and VisitPost will not be called for // this node). // // The returned Expr replaces the visited expression and can be used for rewriting expressions. // The function should NOT modify nodes in-place; it should make copies of nodes. The Walk // infrastructure will automatically make copies of parents as needed. VisitPre(expr Expr) (recurse bool, newExpr Expr) // VisitPost is called for each node after recursing into the subtree. The returned Expr // replaces the visited expression and can be used for rewriting expressions. // // The returned Expr replaces the visited expression and can be used for rewriting expressions. // The function should NOT modify nodes in-place; it should make and return copies of nodes. The // Walk infrastructure will automatically make copies of parents as needed. VisitPost(expr Expr) (newNode Expr) }
Visitor defines methods that are called for nodes during an expression or statement walk.
type WalkableStmt ¶
WalkableStmt is implemented by statements that can appear inside an expression (selects) or we want to start a walk from (using WalkStmt).
type WindowFrame ¶
type WindowFrame struct { // constant for all calls to WindowFunc.Add Rows []IndexedRow ArgIdxStart int // the index which arguments to the window function begin ArgCount int // the number of window function arguments // changes for each row (each call to WindowFunc.Add) RowIdx int // the current row index // changes for each peer group FirstPeerIdx int // the first index in the current peer group PeerRowCount int // the number of rows in the current peer group }
WindowFrame is a view into a subset of data over which calculations are made.
type WindowFunc ¶
type WindowFunc interface { // Compute computes the window function for the provided window frame, given the // current state of WindowFunc. The method should be called sequentially for every // row in a partition in turn with the desired ordering of the WindowFunc. This is // because there is an implicit carried dependency between each row and all those // that have come before it (like in an AggregateFunc). As such, this approach does // not present any exploitable associativity/commutativity for optimization. Compute(context.Context, *EvalContext, WindowFrame) (Datum, error) // Close allows the window function to free any memory it requested during execution, // such as during the execution of an aggregation like CONCAT_AGG or ARRAY_AGG. Close(context.Context, *EvalContext) }
WindowFunc performs a computation on each row using data from a provided WindowFrame.
Source Files ¶
- aggregate_builtins.go
- alter_table.go
- backup.go
- builtins.go
- col_types.go
- constant.go
- copy.go
- create.go
- datum.go
- decimal.go
- delete.go
- drop.go
- encode.go
- eval.go
- explain.go
- expr.go
- format.go
- function_definition.go
- function_name.go
- generator_builtins.go
- grant.go
- hide_constants.go
- indexed_vars.go
- insert.go
- interval.go
- keywords.go
- name_part.go
- normalize.go
- overload.go
- parse.go
- pg_builtins.go
- placeholders.go
- prepare.go
- regexp_cache.go
- rename.go
- reserved_keywords.go
- returning.go
- revoke.go
- scan.go
- select.go
- set.go
- show.go
- split.go
- sql.y
- star_datum.go
- stmt.go
- table_name.go
- table_pattern.go
- table_ref.go
- truncate.go
- txn.go
- type.go
- type_check.go
- union.go
- update.go
- values.go
- var_name.go
- walk.go
- window_builtins.go