Value Members

1.  final def !=(arg0: Any): Boolean

   Definition Classes

   AnyRef → Any

2.  final def ##: Int

   Definition Classes

   AnyRef → Any

3.  def +(other: String): String

   Implicit

   This member is added by an implicit conversion from Vec[T] toany2stringadd[Vec[T]] performed by method any2stringadd in scala.Predef.

   Definition Classes

   any2stringadd

4.  final def ++[B >: T](suffix: IterableOnce[B]): IndexedSeq[B]

   Definition Classes

   IterableOps

   Annotations

   @inline()

5.  final def ++:[B >: T](prefix: IterableOnce[B]): IndexedSeq[B]

   Definition Classes

   SeqOps → IterableOps

   Annotations

   @inline()

6.  final def +:[B >: T](elem: B): IndexedSeq[B]

   Definition Classes

   SeqOps

   Annotations

   @inline()

7.  def ->[B](y: B): (Vec[T], B)

   Implicit

   This member is added by an implicit conversion from Vec[T] toArrowAssoc[Vec[T]] performed by method ArrowAssoc in scala.Predef.This conversion will take place only if T is a subclass of Option[Nothing] (T <: Option[Nothing]).

   Definition Classes

   ArrowAssoc

   Annotations

   @inline()

8.  def :#=(producer: Seq[T])(implicit sourceInfo: SourceInfo): Unit

   The "mono-direction connection operator", aka the "coercion operator".

   The "mono-direction connection operator", aka the "coercion operator".

   For consumer :#= producer, all leaf members of consumer (regardless of relative flip) are driven by the corresponding leaf members of producer (regardless of relative flip)

   Identical to calling :<= and :>=, but swapping consumer/producer for :>= (order is irrelevant), e.g.: consumer :<= producer producer :>= consumer

   Symbol reference:

   • ':' is the consumer side
   • '=' is the producer side
   • '#' means to ignore flips, always drive from producer to consumer

   The following restrictions apply:

   • The Chisel type of consumer and producer must be the "same shape" recursively:
     • All ground types are the same (UInt and UInt are same, SInt and UInt are not), but widths can be different (implicit trunction/padding occurs)
     • All vector types are the same length
     • All bundle types have the same member names, but the flips of members can be different between producer and consumer
   • The leaf members that are ultimately assigned to, must be assignable. This means they cannot be module inputs or instance outputs.

   Additional notes: - Connecting two util.DecoupledIO's would connect bits, valid, AND ready from producer to consumer (despite ready being flipped) - Functionally equivalent to chisel3.:=, but different than Chisel.:=

   producer

   the right-hand-side of the connection, all members will be driving, none will be driven-to

   Implicit

   This member is added by an implicit conversion from Vec[T] toConnectableVecDefault[T] performed by method ConnectableVecDefault in chisel3.Data.This conversion will take place only if T is a subclass of Data (T <: Data).

   Definition Classes

   ConnectableVecOperators

9.  final def :#=[S <: Data](producer: connectable.Connectable[S])(implicit evidence: =:=[Vec[T], S], sourceInfo: SourceInfo): Unit

   The "mono-direction connection operator", aka the "coercion operator".

   The "mono-direction connection operator", aka the "coercion operator".

   For consumer :#= producer, all leaf members of consumer (regardless of relative flip) are driven by the corresponding leaf members of producer (regardless of relative flip)

   Identical to calling :<= and :>=, but swapping consumer/producer for :>= (order is irrelevant), e.g.: consumer :<= producer producer :>= consumer

   Symbol reference:

   • ':' is the consumer side
   • '=' is the producer side
   • '#' means to ignore flips, always drive from producer to consumer

   The following restrictions apply:

   • The Chisel type of consumer and producer must be the "same shape" recursively:
     • All ground types are the same (UInt and UInt are same, SInt and UInt are not), but widths can be different (implicit trunction/padding occurs)
     • All vector types are the same length
     • All bundle types have the same member names, but the flips of members can be different between producer and consumer
   • The leaf members that are ultimately assigned to, must be assignable. This means they cannot be module inputs or instance outputs.

   Additional notes: - Connecting two util.DecoupledIO's would connect bits, valid, AND ready from producer to consumer (despite ready being flipped) - Functionally equivalent to chisel3.:=, but different than Chisel.:=

   producer

   the right-hand-side of the connection, all members will be driving, none will be driven-to

   Implicit

   This member is added by an implicit conversion from Vec[T] toConnectableDefault[Vec[T]] performed by method ConnectableDefault in chisel3.Data.

   Definition Classes

   ConnectableOpExtension

10.  final def :#=[S <: Data](lProducer: => S)(implicit evidence: =:=[Vec[T], S], sourceInfo: SourceInfo): Unit

    The "mono-direction connection operator", aka the "coercion operator".

    The "mono-direction connection operator", aka the "coercion operator".

    For consumer :#= producer, all leaf members of consumer (regardless of relative flip) are driven by the corresponding leaf members of producer (regardless of relative flip)

    Identical to calling :<= and :>=, but swapping consumer/producer for :>= (order is irrelevant), e.g.: consumer :<= producer producer :>= consumer

    Symbol reference:

    • ':' is the consumer side
    • '=' is the producer side
    • '#' means to ignore flips, always drive from producer to consumer

    The following restrictions apply:

    • The Chisel type of consumer and producer must be the "same shape" recursively:
      • All ground types are the same (UInt and UInt are same, SInt and UInt are not), but widths can be different (implicit trunction/padding occurs)
      • All vector types are the same length
      • All bundle types have the same member names, but the flips of members can be different between producer and consumer
    • The leaf members that are ultimately assigned to, must be assignable. This means they cannot be module inputs or instance outputs.

    Additional notes: - Connecting two util.DecoupledIO's would connect bits, valid, AND ready from producer to consumer (despite ready being flipped) - Functionally equivalent to chisel3.:=, but different than Chisel.:=

    Implicit

    This member is added by an implicit conversion from Vec[T] toConnectableDefault[Vec[T]] performed by method ConnectableDefault in chisel3.Data.

    Definition Classes

    ConnectableOpExtension

11.  final def :+[B >: T](elem: B): IndexedSeq[B]

    Definition Classes

    SeqOps

    Annotations

    @inline()

12.  final def :++[B >: T](suffix: IterableOnce[B]): IndexedSeq[B]

    Definition Classes

    SeqOps

    Annotations

    @inline()

13.  def :<=(producer: Seq[T])(implicit sourceInfo: SourceInfo): Unit

    The "aligned connection operator" between a producer and consumer.

    The "aligned connection operator" between a producer and consumer.

    For consumer :<= producer, each of consumer's leaf members which are aligned with respect to consumer are driven from the corresponding producer leaf member. Only consumer's leaf/branch alignments influence the connection.

    Symbol reference:

    • ':' is the consumer side
    • '=' is the producer side
    • '<' means to connect from producer to consumer

    The following restrictions apply:

    • The Chisel type of consumer and producer must be the "same shape" recursively:
      • All ground types are the same (UInt and UInt are same, SInt and UInt are not), but widths can be different (implicit trunction/padding occurs)
      • All vector types are the same length
      • All bundle types have the same member names, but the flips of members can be different between producer and consumer
    • The leaf members that are ultimately assigned to, must be assignable. This means they cannot be module inputs or instance outputs.

    Additional notes:

    • Connecting two util.DecoupledIO's would connect bits and valid from producer to consumer, but leave ready unconnected

    producer

    the right-hand-side of the connection; will always drive leaf connections, and never get driven by leaf connections ("aligned connection")

    Implicit

    This member is added by an implicit conversion from Vec[T] toConnectableVecDefault[T] performed by method ConnectableVecDefault in chisel3.Data.This conversion will take place only if T is a subclass of Data (T <: Data).

    Definition Classes

    ConnectableVecOperators

14.  final def :<=(producer: DontCare.type)(implicit sourceInfo: SourceInfo): Unit

    The "aligned connection operator" between a producer and consumer.

    The "aligned connection operator" between a producer and consumer.

    For consumer :<= producer, each of consumer's leaf members which are aligned with respect to consumer are driven from the corresponding producer leaf member. Only consumer's leaf/branch alignments influence the connection.

    Symbol reference:

    • ':' is the consumer side
    • '=' is the producer side
    • '<' means to connect from producer to consumer

    The following restrictions apply:

    • The Chisel type of consumer and producer must be the "same shape" recursively:
      • All ground types are the same (UInt and UInt are same, SInt and UInt are not), but widths can be different (implicit trunction/padding occurs)
      • All vector types are the same length
      • All bundle types have the same member names, but the flips of members can be different between producer and consumer
    • The leaf members that are ultimately assigned to, must be assignable. This means they cannot be module inputs or instance outputs.

    Additional notes:

    • Connecting two util.DecoupledIO's would connect bits and valid from producer to consumer, but leave ready unconnected

    producer

    the right-hand-side of the connection; will always drive leaf connections, and never get driven by leaf connections ("aligned connection")

    Implicit

    This member is added by an implicit conversion from Vec[T] toConnectableDefault[Vec[T]] performed by method ConnectableDefault in chisel3.Data.

    Definition Classes

    ConnectableOpExtension

15.  final def :<=[S <: Data](producer: connectable.Connectable[S])(implicit evidence: =:=[Vec[T], S], sourceInfo: SourceInfo): Unit

    The "aligned connection operator" between a producer and consumer.

    The "aligned connection operator" between a producer and consumer.

    For consumer :<= producer, each of consumer's leaf members which are aligned with respect to consumer are driven from the corresponding producer leaf member. Only consumer's leaf/branch alignments influence the connection.

    Symbol reference:

    • ':' is the consumer side
    • '=' is the producer side
    • '<' means to connect from producer to consumer

    The following restrictions apply:

    • The Chisel type of consumer and producer must be the "same shape" recursively:
      • All ground types are the same (UInt and UInt are same, SInt and UInt are not), but widths can be different (implicit trunction/padding occurs)
      • All vector types are the same length
      • All bundle types have the same member names, but the flips of members can be different between producer and consumer
    • The leaf members that are ultimately assigned to, must be assignable. This means they cannot be module inputs or instance outputs.

    Additional notes:

    • Connecting two util.DecoupledIO's would connect bits and valid from producer to consumer, but leave ready unconnected

    producer

    the right-hand-side of the connection; will always drive leaf connections, and never get driven by leaf connections ("aligned connection")

    Implicit

    This member is added by an implicit conversion from Vec[T] toConnectableDefault[Vec[T]] performed by method ConnectableDefault in chisel3.Data.

    Definition Classes

    ConnectableOpExtension

16.  final def :<=[S <: Data](lProducer: => S)(implicit evidence: =:=[Vec[T], S], sourceInfo: SourceInfo): Unit

    The "aligned connection operator" between a producer and consumer.

    The "aligned connection operator" between a producer and consumer.

    For consumer :<= producer, each of consumer's leaf members which are aligned with respect to consumer are driven from the corresponding producer leaf member. Only consumer's leaf/branch alignments influence the connection.

    Symbol reference:

    • ':' is the consumer side
    • '=' is the producer side
    • '<' means to connect from producer to consumer

    The following restrictions apply:

    • The Chisel type of consumer and producer must be the "same shape" recursively:
      • All ground types are the same (UInt and UInt are same, SInt and UInt are not), but widths can be different (implicit trunction/padding occurs)
      • All vector types are the same length
      • All bundle types have the same member names, but the flips of members can be different between producer and consumer
    • The leaf members that are ultimately assigned to, must be assignable. This means they cannot be module inputs or instance outputs.

    Additional notes:

    • Connecting two util.DecoupledIO's would connect bits and valid from producer to consumer, but leave ready unconnected

    Implicit

    This member is added by an implicit conversion from Vec[T] toConnectableDefault[Vec[T]] performed by method ConnectableDefault in chisel3.Data.

    Definition Classes

    ConnectableOpExtension

17.  def :<>=(producer: Seq[T])(implicit sourceInfo: SourceInfo): Unit

    The "bi-direction connection operator", aka the "tur-duck-en operator"

    The "bi-direction connection operator", aka the "tur-duck-en operator"

    For consumer :<>= producer, both producer and consumer leafs could be driving or be driven-to. The consumer's members aligned w.r.t. consumer will be driven by corresponding members of producer; the producer's members flipped w.r.t. producer will be driven by corresponding members of consumer

    Identical to calling :<= and :>= in sequence (order is irrelevant), e.g. consumer :<= producer then consumer :>= producer

    Symbol reference:

    • ':' is the consumer side
    • '=' is the producer side
    • '<' means to connect from producer to consumer
    • '>' means to connect from consumer to producer

    The following restrictions apply:

    • The Chisel type of consumer and producer must be the "same shape" recursively:
      • All ground types are the same (UInt and UInt are same, SInt and UInt are not), but widths can be different (implicit trunction/padding occurs)
      • All vector types are the same length
      • All bundle types have the same member names, but the flips of members can be different between producer and consumer
    • The leaf members that are ultimately assigned to, must be assignable. This means they cannot be module inputs or instance outputs. - An additional type restriction is that all relative orientations of consumer and producer must match exactly.

    Additional notes:

    • Connecting two wires of util.DecoupledIO chisel type would connect bits and valid from producer to consumer, and ready from consumer to producer.
    • If the types of consumer and producer also have identical relative flips, then we can emit FIRRTL.<= as it is a stricter version of chisel3.:<>=
    • "turk-duck-en" is a dish where a turkey is stuffed with a duck, which is stuffed with a chicken; :<>= is a := stuffed with a <>

    producer

    the right-hand-side of the connection

    Implicit

    This member is added by an implicit conversion from Vec[T] toConnectableVecDefault[T] performed by method ConnectableVecDefault in chisel3.Data.This conversion will take place only if T is a subclass of Data (T <: Data).

    Definition Classes

    ConnectableVecOperators

18.  final def :<>=(producer: DontCare.type)(implicit sourceInfo: SourceInfo): Unit

    The "bi-direction connection operator", aka the "tur-duck-en operator"

    The "bi-direction connection operator", aka the "tur-duck-en operator"

    For consumer :<>= producer, both producer and consumer leafs could be driving or be driven-to. The consumer's members aligned w.r.t. consumer will be driven by corresponding members of producer; the producer's members flipped w.r.t. producer will be driven by corresponding members of consumer

    Identical to calling :<= and :>= in sequence (order is irrelevant), e.g. consumer :<= producer then consumer :>= producer

    Symbol reference:

    • ':' is the consumer side
    • '=' is the producer side
    • '<' means to connect from producer to consumer
    • '>' means to connect from consumer to producer

    The following restrictions apply:

    • The Chisel type of consumer and producer must be the "same shape" recursively:
      • All ground types are the same (UInt and UInt are same, SInt and UInt are not), but widths can be different (implicit trunction/padding occurs)
      • All vector types are the same length
      • All bundle types have the same member names, but the flips of members can be different between producer and consumer
    • The leaf members that are ultimately assigned to, must be assignable. This means they cannot be module inputs or instance outputs. - An additional type restriction is that all relative orientations of consumer and producer must match exactly.

    Additional notes:

    • Connecting two wires of util.DecoupledIO chisel type would connect bits and valid from producer to consumer, and ready from consumer to producer.
    • If the types of consumer and producer also have identical relative flips, then we can emit FIRRTL.<= as it is a stricter version of chisel3.:<>=
    • "turk-duck-en" is a dish where a turkey is stuffed with a duck, which is stuffed with a chicken; :<>= is a := stuffed with a <>

    producer

    the right-hand-side of the connection

    Implicit

    This member is added by an implicit conversion from Vec[T] toConnectableDefault[Vec[T]] performed by method ConnectableDefault in chisel3.Data.

    Definition Classes

    ConnectableOpExtension

19.  final def :<>=[S <: Data](producer: connectable.Connectable[S])(implicit evidence: =:=[Vec[T], S], sourceInfo: SourceInfo): Unit

    The "bi-direction connection operator", aka the "tur-duck-en operator"

    The "bi-direction connection operator", aka the "tur-duck-en operator"

    For consumer :<>= producer, both producer and consumer leafs could be driving or be driven-to. The consumer's members aligned w.r.t. consumer will be driven by corresponding members of producer; the producer's members flipped w.r.t. producer will be driven by corresponding members of consumer

    Identical to calling :<= and :>= in sequence (order is irrelevant), e.g. consumer :<= producer then consumer :>= producer

    Symbol reference:

    • ':' is the consumer side
    • '=' is the producer side
    • '<' means to connect from producer to consumer
    • '>' means to connect from consumer to producer

    The following restrictions apply:

    • The Chisel type of consumer and producer must be the "same shape" recursively:
      • All ground types are the same (UInt and UInt are same, SInt and UInt are not), but widths can be different (implicit trunction/padding occurs)
      • All vector types are the same length
      • All bundle types have the same member names, but the flips of members can be different between producer and consumer
    • The leaf members that are ultimately assigned to, must be assignable. This means they cannot be module inputs or instance outputs. - An additional type restriction is that all relative orientations of consumer and producer must match exactly.

    Additional notes:

    • Connecting two wires of util.DecoupledIO chisel type would connect bits and valid from producer to consumer, and ready from consumer to producer.
    • If the types of consumer and producer also have identical relative flips, then we can emit FIRRTL.<= as it is a stricter version of chisel3.:<>=
    • "turk-duck-en" is a dish where a turkey is stuffed with a duck, which is stuffed with a chicken; :<>= is a := stuffed with a <>

    producer

    the right-hand-side of the connection

    Implicit

    This member is added by an implicit conversion from Vec[T] toConnectableDefault[Vec[T]] performed by method ConnectableDefault in chisel3.Data.

    Definition Classes

    ConnectableOpExtension

20.  final def :<>=[S <: Data](lProducer: => S)(implicit evidence: =:=[Vec[T], S], sourceInfo: SourceInfo): Unit

    The "bi-direction connection operator", aka the "tur-duck-en operator"

    The "bi-direction connection operator", aka the "tur-duck-en operator"

    For consumer :<>= producer, both producer and consumer leafs could be driving or be driven-to. The consumer's members aligned w.r.t. consumer will be driven by corresponding members of producer; the producer's members flipped w.r.t. producer will be driven by corresponding members of consumer

    Identical to calling :<= and :>= in sequence (order is irrelevant), e.g. consumer :<= producer then consumer :>= producer

    Symbol reference:

    • ':' is the consumer side
    • '=' is the producer side
    • '<' means to connect from producer to consumer
    • '>' means to connect from consumer to producer

    The following restrictions apply:

    • The Chisel type of consumer and producer must be the "same shape" recursively:
      • All ground types are the same (UInt and UInt are same, SInt and UInt are not), but widths can be different (implicit trunction/padding occurs)
      • All vector types are the same length
      • All bundle types have the same member names, but the flips of members can be different between producer and consumer
    • The leaf members that are ultimately assigned to, must be assignable. This means they cannot be module inputs or instance outputs. - An additional type restriction is that all relative orientations of consumer and producer must match exactly.

    Additional notes:

    • Connecting two wires of util.DecoupledIO chisel type would connect bits and valid from producer to consumer, and ready from consumer to producer.
    • If the types of consumer and producer also have identical relative flips, then we can emit FIRRTL.<= as it is a stricter version of chisel3.:<>=
    • "turk-duck-en" is a dish where a turkey is stuffed with a duck, which is stuffed with a chicken; :<>= is a := stuffed with a <>

    Implicit

    This member is added by an implicit conversion from Vec[T] toConnectableDefault[Vec[T]] performed by method ConnectableDefault in chisel3.Data.

    Definition Classes

    ConnectableOpExtension

21.  def :=(that: Vec[T])(implicit sourceInfo: SourceInfo, moduleCompileOptions: CompileOptions): Unit

    "The strong connect operator", assigning elements in this Vec from elements in a Vec.

    "The strong connect operator", assigning elements in this Vec from elements in a Vec.

    For chisel3._, this operator is mono-directioned; all sub-elements of this will be driven by sub-elements of that.

    • Equivalent to this :#= that

    For Chisel._, this operator connections bi-directionally via emitting the FIRRTL.<=

    • Equivalent to this :<>= that, with the additional restriction that the relative bundle field flips must match

    Note

    This is necessary in Aggregate, rather than relying on Data.:=, due to supporting the Seq

    ,

    the length of this Vec must match the length of the input Vec

22.  def :=(that: Seq[T])(implicit sourceInfo: SourceInfo, moduleCompileOptions: CompileOptions): Unit

    "The strong connect operator", assigning elements in this Vec from elements in a Seq.

    "The strong connect operator", assigning elements in this Vec from elements in a Seq.

    For chisel3._, this operator is mono-directioned; all sub-elements of this will be driven by sub-elements of that.

    • Equivalent to this :#= that

    For Chisel._, this operator connections bi-directionally via emitting the FIRRTL.<=

    • Equivalent to this :<>= that

    Note

    the length of this Vec must match the length of the input Seq

23.  final def :=(that: => Data)(implicit sourceInfo: SourceInfo, connectionCompileOptions: CompileOptions): Unit

    The "strong connect" operator.

    The "strong connect" operator.

    For chisel3._, this operator is mono-directioned; all sub-elements of this will be driven by sub-elements of that.

    • Equivalent to this :#= that

    For Chisel._, this operator connections bi-directionally via emitting the FIRRTL.<=

    • Equivalent to this :<>= that

    that

    the Data to connect from

    Definition Classes

    Data

24.  def :>=(producer: Seq[T])(implicit sourceInfo: SourceInfo): Unit

    The "flipped connection operator", or the "backpressure connection operator" between a producer and consumer.

    The "flipped connection operator", or the "backpressure connection operator" between a producer and consumer.

    For consumer :>= producer, each of producer's leaf members which are flipped with respect to producer are driven from the corresponding consumer leaf member Only producer's leaf/branch alignments influence the connection.

    Symbol reference:

    • ':' is the consumer side
    • '=' is the producer side
    • '>' means to connect from consumer to producer

    The following restrictions apply:

    • The Chisel type of consumer and producer must be the "same shape" recursively:
      • All ground types are the same (UInt and UInt are same, SInt and UInt are not), but widths can be different (implicit trunction/padding occurs)
      • All vector types are the same length
      • All bundle types have the same member names, but the flips of members can be different between producer and consumer
    • The leaf members that are ultimately assigned to, must be assignable. This means they cannot be module inputs or instance outputs.

    Additional notes:

    • Connecting two util.DecoupledIO's would connect ready from consumer to producer, but leave bits and valid unconnected

    producer

    the right-hand-side of the connection; will always be driven by leaf connections, and never drive leaf connections ("flipped connection")

    Implicit

    This member is added by an implicit conversion from Vec[T] toConnectableVecDefault[T] performed by method ConnectableVecDefault in chisel3.Data.This conversion will take place only if T is a subclass of Data (T <: Data).

    Definition Classes

    ConnectableVecOperators

25.  final def :>=(producer: DontCare.type)(implicit sourceInfo: SourceInfo): Unit

    The "flipped connection operator", or the "backpressure connection operator" between a producer and consumer.

    The "flipped connection operator", or the "backpressure connection operator" between a producer and consumer.

    For consumer :>= producer, each of producer's leaf members which are flipped with respect to producer are driven from the corresponding consumer leaf member Only producer's leaf/branch alignments influence the connection.

    Symbol reference:

    • ':' is the consumer side
    • '=' is the producer side
    • '>' means to connect from consumer to producer

    The following restrictions apply:

    • The Chisel type of consumer and producer must be the "same shape" recursively:
      • All ground types are the same (UInt and UInt are same, SInt and UInt are not), but widths can be different (implicit trunction/padding occurs)
      • All vector types are the same length
      • All bundle types have the same member names, but the flips of members can be different between producer and consumer
    • The leaf members that are ultimately assigned to, must be assignable. This means they cannot be module inputs or instance outputs.

    Additional notes:

    • Connecting two util.DecoupledIO's would connect ready from consumer to producer, but leave bits and valid unconnected

    producer

    the right-hand-side of the connection; will always be driven by leaf connections, and never drive leaf connections ("flipped connection")

    Implicit

    This member is added by an implicit conversion from Vec[T] toConnectableDefault[Vec[T]] performed by method ConnectableDefault in chisel3.Data.

    Definition Classes

    ConnectableOpExtension

26.  final def :>=[S <: Data](producer: connectable.Connectable[S])(implicit evidence: =:=[Vec[T], S], sourceInfo: SourceInfo): Unit

    The "flipped connection operator", or the "backpressure connection operator" between a producer and consumer.

    The "flipped connection operator", or the "backpressure connection operator" between a producer and consumer.

    For consumer :>= producer, each of producer's leaf members which are flipped with respect to producer are driven from the corresponding consumer leaf member Only producer's leaf/branch alignments influence the connection.

    Symbol reference:

    • ':' is the consumer side
    • '=' is the producer side
    • '>' means to connect from consumer to producer

    The following restrictions apply:

    • The Chisel type of consumer and producer must be the "same shape" recursively:
      • All ground types are the same (UInt and UInt are same, SInt and UInt are not), but widths can be different (implicit trunction/padding occurs)
      • All vector types are the same length
      • All bundle types have the same member names, but the flips of members can be different between producer and consumer
    • The leaf members that are ultimately assigned to, must be assignable. This means they cannot be module inputs or instance outputs.

    Additional notes:

    • Connecting two util.DecoupledIO's would connect ready from consumer to producer, but leave bits and valid unconnected

    producer

    the right-hand-side of the connection; will always be driven by leaf connections, and never drive leaf connections ("flipped connection")

    Implicit

    This member is added by an implicit conversion from Vec[T] toConnectableDefault[Vec[T]] performed by method ConnectableDefault in chisel3.Data.

    Definition Classes

    ConnectableOpExtension

27.  final def :>=[S <: Data](lProducer: => S)(implicit evidence: =:=[Vec[T], S], sourceInfo: SourceInfo): Unit

    The "flipped connection operator", or the "backpressure connection operator" between a producer and consumer.

    The "flipped connection operator", or the "backpressure connection operator" between a producer and consumer.

    For consumer :>= producer, each of producer's leaf members which are flipped with respect to producer are driven from the corresponding consumer leaf member Only producer's leaf/branch alignments influence the connection.

    Symbol reference:

    • ':' is the consumer side
    • '=' is the producer side
    • '>' means to connect from consumer to producer

    The following restrictions apply:

    • The Chisel type of consumer and producer must be the "same shape" recursively:
      • All ground types are the same (UInt and UInt are same, SInt and UInt are not), but widths can be different (implicit trunction/padding occurs)
      • All vector types are the same length
      • All bundle types have the same member names, but the flips of members can be different between producer and consumer
    • The leaf members that are ultimately assigned to, must be assignable. This means they cannot be module inputs or instance outputs.

    Additional notes:

    • Connecting two util.DecoupledIO's would connect ready from consumer to producer, but leave bits and valid unconnected

    Implicit

    This member is added by an implicit conversion from Vec[T] toConnectableDefault[Vec[T]] performed by method ConnectableDefault in chisel3.Data.

    Definition Classes

    ConnectableOpExtension

28.  def <>(that: Vec[T])(implicit sourceInfo: SourceInfo, moduleCompileOptions: CompileOptions): Unit

    The "bulk connect operator", assigning elements in this Vec from elements in a Vec.

    The "bulk connect operator", assigning elements in this Vec from elements in a Vec.

    For chisel3._, uses the chisel3.internal.BiConnect algorithm; sub-elements of that may end up driving sub-elements of this

    • See docs/src/explanations/connection-operators.md for details

    For Chisel._, emits the FIRRTL.<- operator

    • Equivalent to this :<>= that without the restrictions that bundle field names and vector sizes must match

    that

    the Vec to connect from

    Note

    This is necessary in Aggregate, rather than relying on Data.<>, due to supporting the Seq

    ,

    the length of this Vec and that Vec must match

29.  def <>(that: Seq[T])(implicit sourceInfo: SourceInfo, moduleCompileOptions: CompileOptions): Unit

    The "bulk connect operator", assigning elements in this Vec from elements in a Seq.

    The "bulk connect operator", assigning elements in this Vec from elements in a Seq.

    For chisel3._, uses the chisel3.internal.BiConnect algorithm; sub-elements of that may end up driving sub-elements of this

    • Complicated semantics, will likely be deprecated in the future

    For Chisel._, emits the FIRRTL.<- operator

    • Equivalent to this :<>= that but bundle field names and vector sizes do not have to match

    that

    the Seq to connect from

    Note

    the length of this Vec and that Seq must match

30.  final def <>(that: => Data)(implicit sourceInfo: SourceInfo, connectionCompileOptions: CompileOptions): Unit

    The "bulk connect operator", assigning elements in this Vec from elements in a Vec.

    The "bulk connect operator", assigning elements in this Vec from elements in a Vec.

    For chisel3._, uses the chisel3.internal.BiConnect algorithm; sub-elements of that may end up driving sub-elements of this

    • Complicated semantics, hard to write quickly, will likely be deprecated in the future

    For Chisel._, emits the FIRRTL.<- operator

    • Equivalent to this :<>= that without the restrictions that bundle field names and vector sizes must match

    that

    the Data to connect from

    Definition Classes

    Data

31.  final def ==(arg0: Any): Boolean

    Definition Classes

    AnyRef → Any

32.  def ===(rhs: Vec[T]): Bool

    Dynamic recursive equality operator for generic Data

    Dynamic recursive equality operator for generic Data

    rhs

    a hardware Data to compare lhs to

    returns

    a hardware Bool asserted if lhs is equal to rhs

    Implicit

    This member is added by an implicit conversion from Vec[T] toDataEquality[Vec[T]] performed by method DataEquality in chisel3.Data.

    Definition Classes

    DataEquality

    Exceptions thrown

    ChiselException when lhs and rhs are different types during elaboration time

33.  final def addString(b: StringBuilder): b.type

    Definition Classes

    IterableOnceOps

    Annotations

    @inline()

34.  final def addString(b: StringBuilder, sep: String): b.type

    Definition Classes

    IterableOnceOps

    Annotations

    @inline()

35.  def addString(b: StringBuilder, start: String, sep: String, end: String): b.type

    Definition Classes

    IterableOnceOps

36.  def andThen[C](k: PartialFunction[T, C]): PartialFunction[Int, C]

    Definition Classes

    PartialFunction

37.  def andThen[C](k: (T) => C): PartialFunction[Int, C]

    Definition Classes

    PartialFunction → Function1

38.  def appended[B >: T](elem: B): IndexedSeq[B]

    Definition Classes

    SeqOps

39.  def appendedAll[B >: T](suffix: IterableOnce[B]): IndexedSeq[B]

    Definition Classes

    SeqOps

40.  def apply(idx: Int): T

    Creates a statically indexed read or write accessor into the array.

    Creates a statically indexed read or write accessor into the array.

    Definition Classes

    Vec → SeqOps → Function1

41.  macro def apply(p: UInt): T

    Creates a dynamically indexed read or write accessor into the array.

    Creates a dynamically indexed read or write accessor into the array.

    Definition Classes

    Vec → VecLike

42.  def applyOrElse[A1 <: Int, B1 >: T](x: A1, default: (A1) => B1): B1

    Definition Classes

    PartialFunction

43.  def applyPreferredMaxLength: Int

    Attributes

    protected

    Definition Classes

    IndexedSeq

44.  final def asInstanceOf[T0]: T0

    Definition Classes

    Any

45.  macro def asTypeOf[T <: Data](that: T): T

    Does a reinterpret cast of the bits in this node into the format that provides.

    Does a reinterpret cast of the bits in this node into the format that provides. Returns a new Wire of that type. Does not modify existing nodes.

    x.asTypeOf(that) performs the inverse operation of x := that.toBits.

    Definition Classes

    Data

    Note

    bit widths are NOT checked, may pad or drop bits from input

    ,

    that should have known widths

46.  final macro def asUInt: UInt

    Reinterpret cast to UInt.

    Reinterpret cast to UInt.

    Definition Classes

    Data

    Note

    value not guaranteed to be preserved: for example, a SInt of width 3 and value -1 (0b111) would become an UInt with value 7

    ,

    Aggregates are recursively packed with the first element appearing in the least-significant bits of the result.

47.  def autoSeed(name: String): Vec.this.type

    Takes the last seed suggested.

    Takes the last seed suggested. Multiple calls to this function will take the last given seed, unless this HasId is a module port (see overridden method in Data.scala).

    If the final computed name conflicts with the final name of another signal, the final name may get uniquified by appending a digit at the end of the name.

    Is a lower priority than suggestName, in that regardless of whether autoSeed was called, suggestName will always take precedence if it was called.

    returns

    this object

    Definition Classes

    Data → HasId

48.  val base: Vec[T]

    Implicit

    This member is added by an implicit conversion from Vec[T] toConnectable[Vec[T]] performed by method toConnectableDefault in chisel3.Data.

    Definition Classes

    Connectable

49.  def binding: Option[Binding]

    Attributes

    protected[chisel3]

    Definition Classes

    Data

50.  def binding_=(target: Binding): Unit

    Attributes

    protected

    Definition Classes

    Data

51.  def canEqual(that: Any): Boolean

    Definition Classes

    IndexedSeq → Seq → Equals

52.  def circuitName: String

    Attributes

    protected

    Definition Classes

    HasId

53.  def className: String

    Attributes

    protected[this]

    Definition Classes

    Iterable

54.  def clone(): AnyRef

    Attributes

    protected[lang]

    Definition Classes

    AnyRef

    Annotations

    @throws(classOf[java.lang.CloneNotSupportedException]) @native() @HotSpotIntrinsicCandidate()

55.  def cloneType: Vec.this.type

    Internal API; Chisel users should look at chisel3.chiselTypeOf(...).

    Internal API; Chisel users should look at chisel3.chiselTypeOf(...).

    cloneType must be defined for any Chisel object extending Data. It is responsible for constructing a basic copy of the object being cloned.

    returns

    a copy of the object.

    Definition Classes

    Vec → Data

56.  final def coll: Vec.this.type

    Attributes

    protected

    Definition Classes

    Iterable → IterableOps

57.  def collect[B](pf: PartialFunction[T, B]): IndexedSeq[B]

    Definition Classes

    IterableOps → IterableOnceOps

58.  def collectFirst[B](pf: PartialFunction[T, B]): Option[B]

    Definition Classes

    IterableOnceOps

59.  def combinations(n: Int): Iterator[IndexedSeq[T]]

    Definition Classes

    SeqOps

60.  def compose[R](k: PartialFunction[R, Int]): PartialFunction[R, T]

    Definition Classes

    PartialFunction

61.  def compose[A](g: (A) => Int): (A) => T

    Definition Classes

    Function1

    Annotations

    @unspecialized()

62.  final def concat[B >: T](suffix: IterableOnce[B]): IndexedSeq[B]

    Definition Classes

    SeqOps → IterableOps

    Annotations

    @inline()

63.  macro def contains(x: T)(implicit ev: <:<[T, UInt]): Bool

    Outputs true if the vector contains at least one element equal to x (using the === operator).

    Outputs true if the vector contains at least one element equal to x (using the === operator).

    Definition Classes

    VecLike

64.  def contains[A1 >: T](elem: A1): Boolean

    Definition Classes

    SeqOps

65.  def containsSlice[B >: T](that: Seq[B]): Boolean

    Definition Classes

    SeqOps

66.  def copyToArray[B >: T](xs: Array[B], start: Int, len: Int): Int

    Definition Classes

    IterableOnceOps

67.  def copyToArray[B >: T](xs: Array[B], start: Int): Int

    Definition Classes

    IterableOnceOps

    Annotations

    @deprecatedOverriding()

68.  def copyToArray[B >: T](xs: Array[B]): Int

    Definition Classes

    IterableOnceOps

    Annotations

    @deprecatedOverriding()

69.  def corresponds[B](that: Seq[B])(p: (T, B) => Boolean): Boolean

    Definition Classes

    SeqOps

70.  def corresponds[B](that: IterableOnce[B])(p: (T, B) => Boolean): Boolean

    Definition Classes

    IterableOnceOps

71.  macro def count(p: (T) => Bool): UInt

    Outputs the number of elements for which p is true.

    Outputs the number of elements for which p is true.

    Definition Classes

    VecLike

72.  def count(p: (T) => Boolean): Int

    Definition Classes

    IterableOnceOps

73.  def diff[B >: T](that: Seq[B]): IndexedSeq[T]

    Definition Classes

    SeqOps

74.  def distinct: IndexedSeq[T]

    Definition Classes

    SeqOps

75.  def distinctBy[B](f: (T) => B): IndexedSeq[T]

    Definition Classes

    SeqOps

76.  def do_apply(p: UInt)(implicit compileOptions: CompileOptions): T
    Definition Classes

    Vec → VecLike

77.  def do_asTypeOf[T <: Data](that: T)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): T
    Definition Classes

    Data

78.  def do_asUInt(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): UInt
    Definition Classes

    Aggregate → Data

79.  def do_contains(x: T)(implicit sourceInfo: SourceInfo, ev: <:<[T, UInt], compileOptions: CompileOptions): Bool
    Definition Classes

    VecLike

80.  def do_count(p: (T) => Bool)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): UInt
    Definition Classes

    VecLike

81.  def do_exists(p: (T) => Bool)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): Bool
    Definition Classes

    VecLike

82.  def do_forall(p: (T) => Bool)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): Bool
    Definition Classes

    VecLike

83.  def do_indexWhere(p: (T) => Bool)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): UInt
    Definition Classes

    VecLike

84.  def do_lastIndexWhere(p: (T) => Bool)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): UInt
    Definition Classes

    VecLike

85.  def do_onlyIndexWhere(p: (T) => Bool)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): UInt
    Definition Classes

    VecLike

86.  def do_reduceTree(redOp: (T, T) => T, layerOp: (T) => T = (x: T) => x)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): T
87.  def drop(n: Int): IndexedSeq[T]

    Definition Classes

    IndexedSeqOps → IterableOps → IterableOnceOps

88.  def dropRight(n: Int): IndexedSeq[T]

    Definition Classes

    IndexedSeqOps → IterableOps

89.  def dropWhile(p: (T) => Boolean): IndexedSeq[T]

    Definition Classes

    IterableOps → IterableOnceOps

90.  def elementWise: ElementWiseExtractor[Int, T]

    Definition Classes

    PartialFunction

91.  def empty: IndexedSeq[T]

    Definition Classes

    IterableFactoryDefaults → IterableOps

92.  def endsWith[B >: T](that: Iterable[B]): Boolean

    Definition Classes

    SeqOps

93.  def ensuring(cond: (Vec[T]) => Boolean, msg: => Any): Vec[T]

    Implicit

    This member is added by an implicit conversion from Vec[T] toEnsuring[Vec[T]] performed by method Ensuring in scala.Predef.

    Definition Classes

    Ensuring

94.  def ensuring(cond: (Vec[T]) => Boolean): Vec[T]

    Implicit

    This member is added by an implicit conversion from Vec[T] toEnsuring[Vec[T]] performed by method Ensuring in scala.Predef.

    Definition Classes

    Ensuring

95.  def ensuring(cond: Boolean, msg: => Any): Vec[T]

    Implicit

    This member is added by an implicit conversion from Vec[T] toEnsuring[Vec[T]] performed by method Ensuring in scala.Predef.

    Definition Classes

    Ensuring

96.  def ensuring(cond: Boolean): Vec[T]

    Implicit

    This member is added by an implicit conversion from Vec[T] toEnsuring[Vec[T]] performed by method Ensuring in scala.Predef.

    Definition Classes

    Ensuring

97.  final def eq(arg0: AnyRef): Boolean

    Definition Classes

    AnyRef

98.  def equals(that: Any): Boolean

    Definition Classes

    VecLike → HasId → Seq → Equals → AnyRef → Any

99.  macro def exists(p: (T) => Bool): Bool

    Outputs true if p outputs true for at least one element.

    Outputs true if p outputs true for at least one element.

    Definition Classes

    VecLike

100.  def exists(p: (T) => Boolean): Boolean

     Definition Classes

     IterableOnceOps

101.  def filter(pred: (T) => Boolean): IndexedSeq[T]

     Definition Classes

     IterableOps → IterableOnceOps

102.  def filterNot(pred: (T) => Boolean): IndexedSeq[T]

     Definition Classes

     IterableOps → IterableOnceOps

103.  def find(p: (T) => Boolean): Option[T]

     Definition Classes

     IterableOnceOps

104.  def findLast(p: (T) => Boolean): Option[T]

     Definition Classes

     SeqOps

105.  def flatMap[B](f: (T) => IterableOnce[B]): IndexedSeq[B]

     Definition Classes

     IterableOps → IterableOnceOps

106.  def flatten[B](implicit asIterable: (T) => IterableOnce[B]): IndexedSeq[B]

     Definition Classes

     IterableOps → IterableOnceOps

107.  def fold[A1 >: T](z: A1)(op: (A1, A1) => A1): A1

     Definition Classes

     IterableOnceOps

108.  def foldLeft[B](z: B)(op: (B, T) => B): B

     Definition Classes

     IterableOnceOps

109.  def foldRight[B](z: B)(op: (T, B) => B): B

     Definition Classes

     IndexedSeqOps → IterableOnceOps

110.  macro def forall(p: (T) => Bool): Bool

     Outputs true if p outputs true for every element.

     Outputs true if p outputs true for every element.

     Definition Classes

     VecLike

111.  def forall(p: (T) => Boolean): Boolean

     Definition Classes

     IterableOnceOps

112.  def foreach[U](f: (T) => U): Unit

     Definition Classes

     IterableOnceOps

113.  def fromSpecific(coll: IterableOnce[T]): IndexedSeq[T]

     Attributes

     protected

     Definition Classes

     IterableFactoryDefaults → IterableOps

114.  final def getClass(): Class[_ <: AnyRef]

     Definition Classes

     AnyRef → Any

     Annotations

     @native() @HotSpotIntrinsicCandidate()

115.  def getElements: Seq[Data]

     Returns a Seq of the immediate contents of this Aggregate, in order.

     Returns a Seq of the immediate contents of this Aggregate, in order.

     Definition Classes

     Vec → Aggregate

116.  final def getWidth: Int

     Returns the width, in bits, if currently known.

     Returns the width, in bits, if currently known.

     Definition Classes

     Data

117.  def groupBy[K](f: (T) => K): Map[K, IndexedSeq[T]]

     Definition Classes

     IterableOps

118.  def groupMap[K, B](key: (T) => K)(f: (T) => B): Map[K, IndexedSeq[B]]

     Definition Classes

     IterableOps

119.  def groupMapReduce[K, B](key: (T) => K)(f: (T) => B)(reduce: (B, B) => B): Map[K, B]

     Definition Classes

     IterableOps

120.  def grouped(size: Int): Iterator[IndexedSeq[T]]

     Definition Classes

     IterableOps

121.  def hasSeed: Boolean
     returns

     Whether either autoName or suggestName has been called

     Definition Classes

     HasId

122.  def hashCode(): Int

     Definition Classes

     VecLike → HasId → Seq → AnyRef → Any

123.  def head: T

     Definition Classes

     IndexedSeqOps → IterableOps

124.  def headOption: Option[T]

     Definition Classes

     IndexedSeqOps → IterableOps

125.  def indexOf[B >: T](elem: B): Int

     Definition Classes

     SeqOps

     Annotations

     @deprecatedOverriding()

126.  def indexOf[B >: T](elem: B, from: Int): Int

     Definition Classes

     SeqOps

127.  def indexOfSlice[B >: T](that: Seq[B]): Int

     Definition Classes

     SeqOps

     Annotations

     @deprecatedOverriding()

128.  def indexOfSlice[B >: T](that: Seq[B], from: Int): Int

     Definition Classes

     SeqOps

129.  macro def indexWhere(p: (T) => Bool): UInt

     Outputs the index of the first element for which p outputs true.

     Outputs the index of the first element for which p outputs true.

     Definition Classes

     VecLike

130.  def indexWhere(p: (T) => Boolean): Int

     Definition Classes

     SeqOps

     Annotations

     @deprecatedOverriding()

131.  def indexWhere(p: (T) => Boolean, from: Int): Int

     Definition Classes

     SeqOps

132.  def indices: Range

     Definition Classes

     SeqOps

133.  def init: IndexedSeq[T]

     Definition Classes

     IterableOps

134.  def inits: Iterator[IndexedSeq[T]]

     Definition Classes

     IterableOps

135.  def instanceName: String

     Definition Classes

     HasId → InstanceId

136.  def intersect[B >: T](that: Seq[B]): IndexedSeq[T]

     Definition Classes

     SeqOps

137.  def isDefinedAt(idx: Int): Boolean

     Definition Classes

     SeqOps

138.  def isEmpty: Boolean

     Definition Classes

     SeqOps → IterableOnceOps

139.  final def isInstanceOf[T0]: Boolean

     Definition Classes

     Any

140.  def isLit: Boolean

     Definition Classes

     Data

141.  def isTraversableAgain: Boolean

     Definition Classes

     IterableOps → IterableOnceOps

142.  final def isWidthKnown: Boolean

     Returns whether the width is currently known.

     Returns whether the width is currently known.

     Definition Classes

     Data

143.  def iterableFactory: SeqFactory[IndexedSeq]

     Definition Classes

     IndexedSeq → IndexedSeq → Seq → Seq → Iterable → Iterable → IterableOps

144.  def iterator: Iterator[T]

     Definition Classes

     IndexedSeqOps → IterableOnce

145.  def knownSize: Int

     Definition Classes

     IndexedSeqOps → IterableOnce

146.  def last: T

     Definition Classes

     IndexedSeqOps → IterableOps

147.  def lastIndexOf[B >: T](elem: B, end: Int): Int

     Definition Classes

     SeqOps

148.  def lastIndexOfSlice[B >: T](that: Seq[B]): Int

     Definition Classes

     SeqOps

     Annotations

     @deprecatedOverriding()

149.  def lastIndexOfSlice[B >: T](that: Seq[B], end: Int): Int

     Definition Classes

     SeqOps

150.  macro def lastIndexWhere(p: (T) => Bool): UInt

     Outputs the index of the last element for which p outputs true.

     Outputs the index of the last element for which p outputs true.

     Definition Classes

     VecLike

151.  def lastIndexWhere(p: (T) => Boolean): Int

     Definition Classes

     SeqOps

     Annotations

     @deprecatedOverriding()

152.  def lastIndexWhere(p: (T) => Boolean, end: Int): Int

     Definition Classes

     SeqOps

153.  def lastOption: Option[T]

     Definition Classes

     IterableOps

154.  def lazyZip[B](that: Iterable[B]): LazyZip2[T, B, Vec.this.type]

     Definition Classes

     Iterable

155.  val length: Int

     Definition Classes

     Vec → SeqOps

156.  final def lengthCompare(that: Iterable[_]): Int

     Definition Classes

     IndexedSeqOps → SeqOps

157.  final def lengthCompare(len: Int): Int

     Definition Classes

     IndexedSeqOps → SeqOps

158.  final def lengthIs: SizeCompareOps

     Definition Classes

     SeqOps

     Annotations

     @inline()

159.  def lift: (Int) => Option[T]

     Definition Classes

     PartialFunction

160.  def litOption: Option[BigInt]

     Return an Aggregate's literal value if it is a literal, None otherwise.

     Return an Aggregate's literal value if it is a literal, None otherwise. If any element of the aggregate is not a literal with a defined width, the result isn't a literal.

     returns

     an Aggregate's literal value if it is a literal.

     Definition Classes

     Aggregate → Data

161.  def litValue: BigInt

     Returns the literal value if this is a literal that is representable as bits, otherwise crashes.

     Returns the literal value if this is a literal that is representable as bits, otherwise crashes.

     Definition Classes

     Data

162.  def map[B](f: (T) => B): IndexedSeq[B]

     Definition Classes

     IndexedSeqOps → IterableOps → IterableOnceOps

163.  def max[B >: T](implicit ord: Ordering[B]): T

     Definition Classes

     IterableOnceOps

164.  def maxBy[B](f: (T) => B)(implicit cmp: Ordering[B]): T

     Definition Classes

     IterableOnceOps

165.  def maxByOption[B](f: (T) => B)(implicit cmp: Ordering[B]): Option[T]

     Definition Classes

     IterableOnceOps

166.  def maxOption[B >: T](implicit ord: Ordering[B]): Option[T]

     Definition Classes

     IterableOnceOps

167.  def min[B >: T](implicit ord: Ordering[B]): T

     Definition Classes

     IterableOnceOps

168.  def minBy[B](f: (T) => B)(implicit cmp: Ordering[B]): T

     Definition Classes

     IterableOnceOps

169.  def minByOption[B](f: (T) => B)(implicit cmp: Ordering[B]): Option[T]

     Definition Classes

     IterableOnceOps

170.  def minOption[B >: T](implicit ord: Ordering[B]): Option[T]

     Definition Classes

     IterableOnceOps

171.  final def mkString: String

     Definition Classes

     IterableOnceOps

     Annotations

     @inline()

172.  final def mkString(sep: String): String

     Definition Classes

     IterableOnceOps

     Annotations

     @inline()

173.  final def mkString(start: String, sep: String, end: String): String

     Definition Classes

     IterableOnceOps

174.  final def ne(arg0: AnyRef): Boolean

     Definition Classes

     AnyRef

175.  def newSpecificBuilder: Builder[T, IndexedSeq[T]]

     Attributes

     protected

     Definition Classes

     IterableFactoryDefaults → IterableOps

176.  def nonEmpty: Boolean

     Definition Classes

     IterableOnceOps

     Annotations

     @deprecatedOverriding()

177.  def notSpecial: Boolean

     True if no members are waived or squeezed

     True if no members are waived or squeezed

     Implicit

     This member is added by an implicit conversion from Vec[T] toConnectable[Vec[T]] performed by method toConnectableDefault in chisel3.Data.

     Definition Classes

     Connectable

178.  final def notify(): Unit

     Definition Classes

     AnyRef

     Annotations

     @native() @HotSpotIntrinsicCandidate()

179.  final def notifyAll(): Unit

     Definition Classes

     AnyRef

     Annotations

     @native() @HotSpotIntrinsicCandidate()

180.  def occCounts[B](sq: Seq[B]): Map[B, Int]

     Attributes

     protected[collection]

     Definition Classes

     SeqOps

181.  macro def onlyIndexWhere(p: (T) => Bool): UInt

     Outputs the index of the element for which p outputs true, assuming that the there is exactly one such element.

     Outputs the index of the element for which p outputs true, assuming that the there is exactly one such element.

     The implementation may be more efficient than a priority mux, but incorrect results are possible if there is not exactly one true element.

     Definition Classes

     VecLike

     Note

     the assumption that there is only one element for which p outputs true is NOT checked (useful in cases where the condition doesn't always hold, but the results are not used in those cases)

182.  def orElse[A1 <: Int, B1 >: T](that: PartialFunction[A1, B1]): PartialFunction[A1, B1]

     Definition Classes

     PartialFunction

183.  def padTo[B >: T](len: Int, elem: B): IndexedSeq[B]

     Definition Classes

     SeqOps

184.  def parentModName: String

     Definition Classes

     HasId → InstanceId

185.  def parentPathName: String

     Definition Classes

     HasId → InstanceId

186.  def partition(p: (T) => Boolean): (IndexedSeq[T], IndexedSeq[T])

     Definition Classes

     IterableOps

187.  def partitionMap[A1, A2](f: (T) => Either[A1, A2]): (IndexedSeq[A1], IndexedSeq[A2])

     Definition Classes

     IterableOps

188.  def patch[B >: T](from: Int, other: IterableOnce[B], replaced: Int): IndexedSeq[B]

     Definition Classes

     SeqOps

189.  def pathName: String

     Definition Classes

     HasId → InstanceId

190.  def permutations: Iterator[IndexedSeq[T]]

     Definition Classes

     SeqOps

191.  def prepended[B >: T](elem: B): IndexedSeq[B]

     Definition Classes

     IndexedSeqOps → SeqOps

192.  def prependedAll[B >: T](prefix: IterableOnce[B]): IndexedSeq[B]

     Definition Classes

     SeqOps

193.  def product[B >: T](implicit num: Numeric[B]): B

     Definition Classes

     IterableOnceOps

194.  def reduce[B >: T](op: (B, B) => B): B

     Definition Classes

     IterableOnceOps

195.  def reduceLeft[B >: T](op: (B, T) => B): B

     Definition Classes

     IterableOnceOps

196.  def reduceLeftOption[B >: T](op: (B, T) => B): Option[B]

     Definition Classes

     IterableOnceOps

197.  def reduceOption[B >: T](op: (B, B) => B): Option[B]

     Definition Classes

     IterableOnceOps

198.  def reduceRight[B >: T](op: (T, B) => B): B

     Definition Classes

     IterableOnceOps

199.  def reduceRightOption[B >: T](op: (T, B) => B): Option[B]

     Definition Classes

     IterableOnceOps

200.  macro def reduceTree(redOp: (T, T) => T, layerOp: (T) => T): T

     A reduce operation in a tree like structure instead of sequentially

     A reduce operation in a tree like structure instead of sequentially

     Example:

     1. A pipelined adder tree

        val sumOut = inputNums.reduceTree(
          (a: T, b: T) => RegNext(a + b),
          (a: T) => RegNext(a)
        )

201.  macro def reduceTree(redOp: (T, T) => T): T

     A reduce operation in a tree like structure instead of sequentially

     A reduce operation in a tree like structure instead of sequentially

     Example:

     1. An adder tree

        val sumOut = inputNums.reduceTree((a: T, b: T) => (a + b))

202.  def reverse: IndexedSeq[T]

     Definition Classes

     IndexedSeqOps → SeqOps

203.  def reverseIterator: Iterator[T]

     Definition Classes

     IndexedSeqOps → SeqOps

204.  def reversed: Iterable[T]

     Attributes

     protected

     Definition Classes

     IndexedSeqOps → IterableOnceOps

205.  def runWith[U](action: (T) => U): (Int) => Boolean

     Definition Classes

     PartialFunction

206.  def sameElements[B >: T](o: IterableOnce[B]): Boolean

     Definition Classes

     IndexedSeq → SeqOps

207.  def scan[B >: T](z: B)(op: (B, B) => B): IndexedSeq[B]

     Definition Classes

     IterableOps

208.  def scanLeft[B](z: B)(op: (B, T) => B): IndexedSeq[B]

     Definition Classes

     IterableOps → IterableOnceOps

209.  def scanRight[B](z: B)(op: (T, B) => B): IndexedSeq[B]

     Definition Classes

     IterableOps

210.  def search[B >: T](elem: B, from: Int, to: Int)(implicit ord: Ordering[B]): SearchResult

     Definition Classes

     IndexedSeqOps → SeqOps

211.  def search[B >: T](elem: B)(implicit ord: Ordering[B]): SearchResult

     Definition Classes

     IndexedSeqOps → SeqOps

212.  def segmentLength(p: (T) => Boolean, from: Int): Int

     Definition Classes

     SeqOps

213.  final def segmentLength(p: (T) => Boolean): Int

     Definition Classes

     SeqOps

214.  final def size: Int

     Definition Classes

     SeqOps → IterableOnceOps

215.  final def sizeCompare(that: Iterable[_]): Int

     Definition Classes

     SeqOps → IterableOps

216.  final def sizeCompare(otherSize: Int): Int

     Definition Classes

     SeqOps → IterableOps

217.  final def sizeIs: SizeCompareOps

     Definition Classes

     IterableOps

     Annotations

     @inline()

218.  def slice(from: Int, until: Int): IndexedSeq[T]

     Definition Classes

     IndexedSeqOps → IndexedSeqOps → IterableOps → IterableOnceOps

219.  def sliding(size: Int, step: Int): Iterator[IndexedSeq[T]]

     Definition Classes

     IterableOps

220.  def sliding(size: Int): Iterator[IndexedSeq[T]]

     Definition Classes

     IterableOps

221.  def sortBy[B](f: (T) => B)(implicit ord: Ordering[B]): IndexedSeq[T]

     Definition Classes

     SeqOps

222.  def sortWith(lt: (T, T) => Boolean): IndexedSeq[T]

     Definition Classes

     SeqOps

223.  def sorted[B >: T](implicit ord: Ordering[B]): IndexedSeq[T]

     Definition Classes

     SeqOps

224.  def span(p: (T) => Boolean): (IndexedSeq[T], IndexedSeq[T])

     Definition Classes

     IterableOps → IterableOnceOps

225.  def splitAt(n: Int): (IndexedSeq[T], IndexedSeq[T])

     Definition Classes

     IterableOps → IterableOnceOps

226.  def squeeze(members: (Vec[T]) => Data*): connectable.Connectable[Vec[T]]

     Select members of base to squeeze

     Select members of base to squeeze

     members

     functions given the base return a member to squeeze

     Implicit

     This member is added by an implicit conversion from Vec[T] toConnectable[Vec[T]] performed by method toConnectableDefault in chisel3.Data.

     Definition Classes

     Connectable

227.  def squeeze: connectable.Connectable[Vec[T]]

     Adds base to squeezes

     Adds base to squeezes

     Implicit

     This member is added by an implicit conversion from Vec[T] toConnectable[Vec[T]] performed by method toConnectableDefault in chisel3.Data.

     Definition Classes

     Connectable

228.  def squeezeAll: connectable.Connectable[Vec[T]]

     Squeeze all members of base

     Squeeze all members of base

     Implicit

     This member is added by an implicit conversion from Vec[T] toConnectable[Vec[T]] performed by method toConnectableDefault in chisel3.Data.

     Definition Classes

     Connectable

229.  def squeezeEach[S <: Data](pf: PartialFunction[Data, Seq[Data]]): connectable.Connectable[Vec[T]]

     Programmatically select members of base to squeeze

     Programmatically select members of base to squeeze

     Implicit

     This member is added by an implicit conversion from Vec[T] toConnectable[Vec[T]] performed by method toConnectableDefault in chisel3.Data.

     Definition Classes

     Connectable

230.  def startsWith[B >: T](that: IterableOnce[B], offset: Int): Boolean

     Definition Classes

     SeqOps

231.  def stepper[S <: Stepper[_]](implicit shape: StepperShape[T, S]): S with EfficientSplit

     Definition Classes

     IndexedSeqOps → IterableOnce

232.  def stringPrefix: String

     Attributes

     protected[this]

     Definition Classes

     IndexedSeq → Seq → Iterable

233.  def suggestName(seed: => String): Vec.this.type

     Takes the first seed suggested.

     Takes the first seed suggested. Multiple calls to this function will be ignored. If the final computed name conflicts with another name, it may get uniquified by appending a digit at the end.

     Is a higher priority than autoSeed, in that regardless of whether autoSeed was called, suggestName will always take precedence.

     seed

     The seed for the name of this component

     returns

     this object

     Definition Classes

     HasId

234.  def sum[B >: T](implicit num: Numeric[B]): B

     Definition Classes

     IterableOnceOps

235.  final def synchronized[T0](arg0: => T0): T0

     Definition Classes

     AnyRef

236.  def tail: IndexedSeq[T]

     Definition Classes

     IterableOps

237.  def tails: Iterator[IndexedSeq[T]]

     Definition Classes

     IterableOps

238.  def take(n: Int): IndexedSeq[T]

     Definition Classes

     IndexedSeqOps → IterableOps → IterableOnceOps

239.  def takeRight(n: Int): IndexedSeq[T]

     Definition Classes

     IndexedSeqOps → IterableOps

240.  def takeWhile(p: (T) => Boolean): IndexedSeq[T]

     Definition Classes

     IterableOps → IterableOnceOps

241.  def tapEach[U](f: (T) => U): IndexedSeq[T]

     Definition Classes

     IterableOps → IterableOnceOps

242.  def to[C1](factory: Factory[T, C1]): C1

     Definition Classes

     IterableOnceOps

243.  final def toAbsoluteTarget: ReferenceTarget

     Returns a FIRRTL IsMember that refers to the absolute path to this object in the elaborated hardware graph

     Returns a FIRRTL IsMember that refers to the absolute path to this object in the elaborated hardware graph

     Definition Classes

     NamedComponent → InstanceId

244.  def toArray[B >: T](implicit arg0: ClassTag[B]): Array[B]

     Definition Classes

     IterableOnceOps

245.  final def toBuffer[B >: T]: Buffer[B]

     Definition Classes

     IterableOnceOps

     Annotations

     @inline()

246.  final def toIndexedSeq: IndexedSeq[T]

     Definition Classes

     IndexedSeq → IterableOnceOps

247.  def toList: List[T]

     Definition Classes

     IterableOnceOps

248.  def toMap[K, V](implicit ev: <:<[T, (K, V)]): Map[K, V]

     Definition Classes

     IterableOnceOps

249.  final def toNamed: ComponentName

     Returns a FIRRTL ComponentName that references this object

     Returns a FIRRTL ComponentName that references this object

     Definition Classes

     NamedComponent → InstanceId

     Note

     Should not be called until circuit elaboration is complete

250.  def toPrintable: Printable

     Default "pretty-print" implementation Analogous to printing a Seq Results in "Vec(elt0, elt1, ...)"

     Default "pretty-print" implementation Analogous to printing a Seq Results in "Vec(elt0, elt1, ...)"

     Definition Classes

     Vec → Data

251.  final def toSeq: Vec.this.type

     Definition Classes

     Seq → IterableOnceOps

252.  def toSet[B >: T]: Set[B]

     Definition Classes

     IterableOnceOps

253.  def toString(): String

     Definition Classes

     Vec → Seq → Function1 → Iterable → AnyRef → Any

254.  final def toTarget: ReferenceTarget

     Returns a FIRRTL ReferenceTarget that references this object

     Returns a FIRRTL ReferenceTarget that references this object

     Definition Classes

     NamedComponent → InstanceId

     Note

     Should not be called until circuit elaboration is complete

255.  def toVector: Vector[T]

     Definition Classes

     IterableOnceOps

256.  def transpose[B](implicit asIterable: (T) => Iterable[B]): IndexedSeq[IndexedSeq[B]]

     Definition Classes

     IterableOps

257.  def unapply(a: Int): Option[T]

     Definition Classes

     PartialFunction

258.  def unlift: PartialFunction[Int, B]

     Implicit

     This member is added by an implicit conversion from Vec[T] toUnliftOps[Int, B] performed by method UnliftOps in scala.Function1.This conversion will take place only if T is a subclass of Option[B] (T <: Option[B]).

     Definition Classes

     UnliftOps

259.  def unzip[A1, A2](implicit asPair: (T) => (A1, A2)): (IndexedSeq[A1], IndexedSeq[A2])

     Definition Classes

     IterableOps

260.  def unzip3[A1, A2, A3](implicit asTriple: (T) => (A1, A2, A3)): (IndexedSeq[A1], IndexedSeq[A2], IndexedSeq[A3])

     Definition Classes

     IterableOps

261.  def updated[B >: T](index: Int, elem: B): IndexedSeq[B]

     Definition Classes

     SeqOps

262.  def view: IndexedSeqView[T]

     Definition Classes

     IndexedSeqOps → SeqOps → IterableOps

263.  final def wait(arg0: Long, arg1: Int): Unit

     Definition Classes

     AnyRef

     Annotations

     @throws(classOf[java.lang.InterruptedException])

264.  final def wait(arg0: Long): Unit

     Definition Classes

     AnyRef

     Annotations

     @throws(classOf[java.lang.InterruptedException]) @native()

265.  final def wait(): Unit

     Definition Classes

     AnyRef

     Annotations

     @throws(classOf[java.lang.InterruptedException])

266.  def waive(members: (Vec[T]) => Data*): connectable.Connectable[Vec[T]]

     Select members of base to waive

     Select members of base to waive

     members

     functions given the base return a member to waive

     Implicit

     This member is added by an implicit conversion from Vec[T] toConnectable[Vec[T]] performed by method toConnectableDefault in chisel3.Data.

     Definition Classes

     Connectable

267.  def waiveAll: connectable.Connectable[Vec[T]]

     Waive all members of base

     Waive all members of base

     Implicit

     This member is added by an implicit conversion from Vec[T] toConnectable[Vec[T]] performed by method toConnectableDefault in chisel3.Data.

     Definition Classes

     Connectable

268.  def waiveAllAs[S <: Data](implicit ev: <:<[Vec[T], S]): connectable.Connectable[S]

     Waive all members of base and static cast to a new type

     Waive all members of base and static cast to a new type

     Implicit

     This member is added by an implicit conversion from Vec[T] toConnectable[Vec[T]] performed by method toConnectableDefault in chisel3.Data.

     Definition Classes

     Connectable

269.  def waiveAs[S <: Data](members: (Vec[T]) => Data*)(implicit ev: <:<[Vec[T], S]): connectable.Connectable[S]

     Select members of base to waive and static cast to a new type

     Select members of base to waive and static cast to a new type

     members

     functions given the base return a member to waive

     Implicit

     This member is added by an implicit conversion from Vec[T] toConnectable[Vec[T]] performed by method toConnectableDefault in chisel3.Data.

     Definition Classes

     Connectable

270.  def waiveEach[S <: Data](pf: PartialFunction[Data, Seq[Data]])(implicit ev: <:<[Vec[T], S]): connectable.Connectable[S]

     Programmatically select members of base to waive and static cast to a new type

     Programmatically select members of base to waive and static cast to a new type

     Implicit

     This member is added by an implicit conversion from Vec[T] toConnectable[Vec[T]] performed by method toConnectableDefault in chisel3.Data.

     Definition Classes

     Connectable

271.  final def widthOption: Option[Int]

     Returns Some(width) if the width is known, else None.

     Returns Some(width) if the width is known, else None.

     Definition Classes

     Data

272.  def withFilter(p: (T) => Boolean): WithFilter[T, [_]IndexedSeq[_]]

     Definition Classes

     IterableOps

273.  def zip[B](that: IterableOnce[B]): IndexedSeq[(T, B)]

     Definition Classes

     IterableOps

274.  def zipAll[A1 >: T, B](that: Iterable[B], thisElem: A1, thatElem: B): IndexedSeq[(A1, B)]

     Definition Classes

     IterableOps

275.  def zipWithIndex: IndexedSeq[(T, Int)]

     Definition Classes

     IterableOps → IterableOnceOps