// See LICENSE for license details. package chisel3.core import scala.language.experimental.macros import chisel3.internal._ import chisel3.internal.Builder.{pushCommand, pushOp} import chisel3.internal.firrtl._ import chisel3.internal.sourceinfo.{SourceInfo, SourceInfoTransform, UnlocatableSourceInfo, DeprecatedSourceInfo} import chisel3.SourceInfoDoc import chisel3.core.BiConnect.DontCareCantBeSink /** User-specified directions. */ sealed abstract class SpecifiedDirection object SpecifiedDirection { /** Default user direction, also meaning 'not-flipped' */ case object Unspecified extends SpecifiedDirection /** Node and its children are forced as output */ case object Output extends SpecifiedDirection /** Node and its children are forced as inputs */ case object Input extends SpecifiedDirection /** Mainly for containers, children are flipped. */ case object Flip extends SpecifiedDirection def flip(dir: SpecifiedDirection) = dir match { case Unspecified => Flip case Flip => Unspecified case Output => Input case Input => Output } /** Returns the effective SpecifiedDirection of this node given the parent's effective SpecifiedDirection * and the user-specified SpecifiedDirection of this node. */ def fromParent(parentDirection: SpecifiedDirection, thisDirection: SpecifiedDirection) = (parentDirection, thisDirection) match { case (SpecifiedDirection.Output, _) => SpecifiedDirection.Output case (SpecifiedDirection.Input, _) => SpecifiedDirection.Input case (SpecifiedDirection.Unspecified, thisDirection) => thisDirection case (SpecifiedDirection.Flip, thisDirection) => SpecifiedDirection.flip(thisDirection) } } /** Resolved directions for both leaf and container nodes, only visible after * a node is bound (since higher-level specifications like Input and Output * can override directions). */ sealed abstract class ActualDirection object ActualDirection { /** Undirectioned, struct-like */ case object Unspecified extends ActualDirection /** Output element, or container with all outputs (even if forced) */ case object Output extends ActualDirection /** Input element, or container with all inputs (even if forced) */ case object Input extends ActualDirection sealed abstract class BidirectionalDirection case object Default extends BidirectionalDirection case object Flipped extends BidirectionalDirection case class Bidirectional(dir: BidirectionalDirection) extends ActualDirection } object debug { // scalastyle:ignore object.name @chiselRuntimeDeprecated @deprecated("debug doesn't do anything in Chisel3 as no pruning happens in the frontend", "chisel3") def apply (arg: Data): Data = arg } /** Experimental hardware construction reflection API */ object DataMirror { def widthOf(target: Data): Width = target.width def specifiedDirectionOf(target: Data): SpecifiedDirection = target.specifiedDirection def directionOf(target: Data): ActualDirection = { requireIsHardware(target, "node requested directionality on") target.direction } // Returns the top-level module ports // TODO: maybe move to something like Driver or DriverUtils, since this is mainly for interacting // with compiled artifacts (vs. elaboration-time reflection)? def modulePorts(target: BaseModule): Seq[(String, Data)] = target.getChiselPorts // Returns all module ports with underscore-qualified names def fullModulePorts(target: BaseModule): Seq[(String, Data)] = { def getPortNames(name: String, data: Data): Seq[(String, Data)] = Seq(name -> data) ++ (data match { case _: Element => Seq() case r: Record => r.elements.toSeq flatMap { case (eltName, elt) => getPortNames(s"${name}_${eltName}", elt) } case v: Vec[_] => v.zipWithIndex flatMap { case (elt, index) => getPortNames(s"${name}_${index}", elt) } }) modulePorts(target).flatMap { case (name, data) => getPortNames(name, data).toList } } // Internal reflection-style APIs, subject to change and removal whenever. object internal { def isSynthesizable(target: Data) = target.topBindingOpt.isDefined // For those odd cases where you need to care about object reference and uniqueness def chiselTypeClone[T<:Data](target: Data): T = { target.cloneTypeFull.asInstanceOf[T] } } } /** Creates a clone of the super-type of the input elements. Super-type is defined as: * - for Bits type of the same class: the cloned type of the largest width * - Bools are treated as UInts * - For other types of the same class are are the same: clone of any of the elements * - Otherwise: fail */ //scalastyle:off cyclomatic.complexity private[core] object cloneSupertype { def apply[T <: Data](elts: Seq[T], createdType: String)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): T = { require(!elts.isEmpty, s"can't create $createdType with no inputs") val filteredElts = elts.filter(_ != DontCare) require(!filteredElts.isEmpty, s"can't create $createdType with only DontCare inputs") if (filteredElts.head.isInstanceOf[Bits]) { val model: T = filteredElts reduce { (elt1: T, elt2: T) => ((elt1, elt2) match { case (elt1: Bool, elt2: Bool) => elt1 case (elt1: Bool, elt2: UInt) => elt2 // TODO: what happens with zero width UInts? case (elt1: UInt, elt2: Bool) => elt1 // TODO: what happens with zero width UInts? case (elt1: UInt, elt2: UInt) => // TODO: perhaps redefine Widths to allow >= op? if (elt1.width == (elt1.width max elt2.width)) elt1 else elt2 case (elt1: SInt, elt2: SInt) => if (elt1.width == (elt1.width max elt2.width)) elt1 else elt2 case (elt1: FixedPoint, elt2: FixedPoint) => { (elt1.binaryPoint, elt2.binaryPoint, elt1.width, elt2.width) match { case (KnownBinaryPoint(bp1), KnownBinaryPoint(bp2), KnownWidth(w1), KnownWidth(w2)) => val maxBinaryPoint = bp1 max bp2 val maxIntegerWidth = (w1 - bp1) max (w2 - bp2) FixedPoint((maxIntegerWidth + maxBinaryPoint).W, (maxBinaryPoint).BP) case (KnownBinaryPoint(bp1), KnownBinaryPoint(bp2), _, _) => FixedPoint(Width(), (bp1 max bp2).BP) case _ => FixedPoint() } } case (elt1, elt2) => throw new AssertionError( s"can't create $createdType with heterogeneous types ${elt1.getClass} and ${elt2.getClass}") }).asInstanceOf[T] } model.cloneTypeFull } else { for (elt <- filteredElts.tail) { require(elt.getClass == filteredElts.head.getClass, s"can't create $createdType with heterogeneous types ${filteredElts.head.getClass} and ${elt.getClass}") require(elt typeEquivalent filteredElts.head, s"can't create $createdType with non-equivalent types ${filteredElts.head} and ${elt}") } filteredElts.head.cloneTypeFull } } } /** Returns the chisel type of a hardware object, allowing other hardware to be constructed from it. */ object chiselTypeOf { def apply[T <: Data](target: T): T = { requireIsHardware(target) target.cloneTypeFull.asInstanceOf[T] } } /** * Input, Output, and Flipped are used to define the directions of Module IOs. * * Note that they currently clone their source argument, including its bindings. * * Thus, an error will be thrown if these are used on bound Data */ object Input { def apply[T<:Data](source: T)(implicit compileOptions: CompileOptions): T = { if (compileOptions.checkSynthesizable) { requireIsChiselType(source) } val out = source.cloneType.asInstanceOf[T] out.specifiedDirection = SpecifiedDirection.Input out } } object Output { def apply[T<:Data](source: T)(implicit compileOptions: CompileOptions): T = { if (compileOptions.checkSynthesizable) { requireIsChiselType(source) } val out = source.cloneType.asInstanceOf[T] out.specifiedDirection = SpecifiedDirection.Output out } } object Flipped { def apply[T<:Data](source: T)(implicit compileOptions: CompileOptions): T = { if (compileOptions.checkSynthesizable) { requireIsChiselType(source) } val out = source.cloneType.asInstanceOf[T] out.specifiedDirection = SpecifiedDirection.flip(source.specifiedDirection) out } } /** This forms the root of the type system for wire data types. The data value * must be representable as some number (need not be known at Chisel compile * time) of bits, and must have methods to pack / unpack structured data to / * from bits. * * @groupdesc Connect Utilities for connecting hardware components * @define coll data */ abstract class Data extends HasId with NamedComponent with SourceInfoDoc { // This is a bad API that punches through object boundaries. @deprecated("pending removal once all instances replaced", "chisel3") private[chisel3] def flatten: IndexedSeq[Element] = { this match { case elt: Aggregate => elt.getElements.toIndexedSeq flatMap {_.flatten} case elt: Element => IndexedSeq(elt) case elt => throwException(s"Cannot flatten type ${elt.getClass}") } } // User-specified direction, local at this node only. // Note that the actual direction of this node can differ from child and parent specifiedDirection. private var _specifiedDirection: SpecifiedDirection = SpecifiedDirection.Unspecified private[chisel3] def specifiedDirection: SpecifiedDirection = _specifiedDirection private[core] def specifiedDirection_=(direction: SpecifiedDirection) = { if (_specifiedDirection != SpecifiedDirection.Unspecified) { this match { // Anything flies in compatibility mode case t: Record if !t.compileOptions.dontAssumeDirectionality => case _ => throw Binding.RebindingException(s"Attempted reassignment of user-specified direction to $this") } } _specifiedDirection = direction } /** This overwrites a relative SpecifiedDirection with an explicit one, and is used to implement * the compatibility layer where, at the elements, Flip is Input and unspecified is Output. * DO NOT USE OUTSIDE THIS PURPOSE. THIS OPERATION IS DANGEROUS! */ private[core] def _assignCompatibilityExplicitDirection: Unit = { (this, _specifiedDirection) match { case (_: Analog, _) => // nothing to do case (_, SpecifiedDirection.Unspecified) => _specifiedDirection = SpecifiedDirection.Output case (_, SpecifiedDirection.Flip) => _specifiedDirection = SpecifiedDirection.Input case (_, SpecifiedDirection.Input | SpecifiedDirection.Output) => // nothing to do } } // Binding stores information about this node's position in the hardware graph. // This information is supplemental (more than is necessary to generate FIRRTL) and is used to // perform checks in Chisel, where more informative error messages are possible. private var _binding: Option[Binding] = None // Only valid after node is bound (synthesizable), crashes otherwise protected def binding: Option[Binding] = _binding protected def binding_=(target: Binding) { if (_binding.isDefined) { throw Binding.RebindingException(s"Attempted reassignment of binding to $this") } _binding = Some(target) } private[core] def topBindingOpt: Option[TopBinding] = _binding.map { case ChildBinding(parent) => parent.topBinding case bindingVal: TopBinding => bindingVal } private[core] def topBinding: TopBinding = topBindingOpt.get /** Binds this node to the hardware graph. * parentDirection is the direction of the parent node, or Unspecified (default) if the target * node is the top-level. * binding and direction are valid after this call completes. */ private[chisel3] def bind(target: Binding, parentDirection: SpecifiedDirection = SpecifiedDirection.Unspecified) // Variant of bind that can be called from subclasses, used for bundle literals protected def selfBind(target: Binding) = bind(target) // Both _direction and _resolvedUserDirection are saved versions of computed variables (for // efficiency, avoid expensive recomputation of frequent operations). // Both are only valid after binding is set. // Direction of this node, accounting for parents (force Input / Output) and children. private var _direction: Option[ActualDirection] = None private[chisel3] def direction: ActualDirection = _direction.get private[core] def direction_=(actualDirection: ActualDirection) { if (_direction.isDefined) { throw Binding.RebindingException(s"Attempted reassignment of resolved direction to $this") } _direction = Some(actualDirection) } // User-friendly representation of the binding as a helper function for toString. // Provides a unhelpful fallback for literals, which should have custom rendering per // Data-subtype. protected def bindingToString: String = topBindingOpt match { case None => "" case Some(OpBinding(enclosure)) => s"(OpResult in ${enclosure.desiredName})" case Some(MemoryPortBinding(enclosure)) => s"(MemPort in ${enclosure.desiredName})" case Some(PortBinding(enclosure)) if !enclosure.isClosed => s"(IO in unelaborated ${enclosure.desiredName})" case Some(PortBinding(enclosure)) if enclosure.isClosed => DataMirror.fullModulePorts(enclosure).find(_._2 == this) match { case Some((name, _)) => s"(IO $name in ${enclosure.desiredName})" case None => s"(IO (unknown) in ${enclosure.desiredName})" } case Some(RegBinding(enclosure)) => s"(Reg in ${enclosure.desiredName})" case Some(WireBinding(enclosure)) => s"(Wire in ${enclosure.desiredName})" case Some(DontCareBinding()) => s"(DontCare)" case Some(ElementLitBinding(litArg)) => s"(unhandled literal)" case Some(BundleLitBinding(litMap)) => s"(unhandled bundle literal)" } // Return ALL elements at root of this type. // Contasts with flatten, which returns just Bits // TODO: refactor away this, this is outside the scope of Data private[chisel3] def allElements: Seq[Element] private[core] def badConnect(that: Data)(implicit sourceInfo: SourceInfo): Unit = throwException(s"cannot connect ${this} and ${that}") private[chisel3] def connect(that: Data)(implicit sourceInfo: SourceInfo, connectCompileOptions: CompileOptions): Unit = { if (connectCompileOptions.checkSynthesizable) { requireIsHardware(this, "data to be connected") requireIsHardware(that, "data to be connected") this.topBinding match { case _: ReadOnlyBinding => throwException(s"Cannot reassign to read-only $this") case _ => // fine } try { MonoConnect.connect(sourceInfo, connectCompileOptions, this, that, Builder.forcedUserModule) } catch { case MonoConnect.MonoConnectException(message) => throwException( s"Connection between sink ($this) and source ($that) failed @$message" ) } } else { this legacyConnect that } } private[chisel3] def bulkConnect(that: Data)(implicit sourceInfo: SourceInfo, connectCompileOptions: CompileOptions): Unit = { if (connectCompileOptions.checkSynthesizable) { requireIsHardware(this, s"data to be bulk-connected") requireIsHardware(that, s"data to be bulk-connected") (this.topBinding, that.topBinding) match { case (_: ReadOnlyBinding, _: ReadOnlyBinding) => throwException(s"Both $this and $that are read-only") // DontCare cannot be a sink (LHS) case (_: DontCareBinding, _) => throw DontCareCantBeSink case _ => // fine } try { BiConnect.connect(sourceInfo, connectCompileOptions, this, that, Builder.forcedUserModule) } catch { case BiConnect.BiConnectException(message) => throwException( s"Connection between left ($this) and source ($that) failed @$message" ) } } else { this legacyConnect that } } /** Whether this Data has the same model ("data type") as that Data. * Data subtypes should overload this with checks against their own type. */ private[core] def typeEquivalent(that: Data): Boolean // Internal API: returns a ref that can be assigned to, if consistent with the binding private[chisel3] def lref: Node = { requireIsHardware(this) topBindingOpt match { case Some(binding: ReadOnlyBinding) => throwException(s"internal error: attempted to generate LHS ref to ReadOnlyBinding $binding") case Some(binding: TopBinding) => Node(this) case opt => throwException(s"internal error: unknown binding $opt in generating LHS ref") } } // Internal API: returns a ref, if bound. Literals should override this as needed. private[chisel3] def ref: Arg = { requireIsHardware(this) topBindingOpt match { case Some(binding: LitBinding) => throwException(s"internal error: can't handle literal binding $binding") case Some(binding: TopBinding) => Node(this) case opt => throwException(s"internal error: unknown binding $opt in generating LHS ref") } } private[chisel3] def width: Width private[core] def legacyConnect(that: Data)(implicit sourceInfo: SourceInfo): Unit /** 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. * * @return a copy of the object. */ def cloneType: this.type /** Internal API; Chisel users should look at chisel3.chiselTypeOf(...). * * Returns a copy of this data type, with hardware bindings (if any) removed. * Directionality data is still preserved. */ private[chisel3] def cloneTypeFull: this.type = { val clone = this.cloneType.asInstanceOf[this.type] // get a fresh object, without bindings // Only the top-level direction needs to be fixed up, cloneType should do the rest clone.specifiedDirection = specifiedDirection clone } /** Connect this $coll to that $coll mono-directionally and element-wise. * * This uses the [[MonoConnect]] algorithm. * * @param that the $coll to connect to * @group Connect */ final def := (that: Data)(implicit sourceInfo: SourceInfo, connectionCompileOptions: CompileOptions): Unit = this.connect(that)(sourceInfo, connectionCompileOptions) /** Connect this $coll to that $coll bi-directionally and element-wise. * * This uses the [[BiConnect]] algorithm. * * @param that the $coll to connect to * @group Connect */ final def <> (that: Data)(implicit sourceInfo: SourceInfo, connectionCompileOptions: CompileOptions): Unit = this.bulkConnect(that)(sourceInfo, connectionCompileOptions) @chiselRuntimeDeprecated @deprecated("litArg is deprecated, use litOption or litTo*Option", "chisel3.2") def litArg(): Option[LitArg] = topBindingOpt match { case Some(ElementLitBinding(litArg)) => Some(litArg) case Some(BundleLitBinding(litMap)) => None // this API does not support Bundle literals case _ => None } @chiselRuntimeDeprecated @deprecated("isLit is deprecated, use litOption.isDefined", "chisel3.2") def isLit(): Boolean = litArg.isDefined /** * If this is a literal that is representable as bits, returns the value as a BigInt. * If not a literal, or not representable as bits (for example, is or contains Analog), returns None. */ def litOption(): Option[BigInt] /** * Returns the literal value if this is a literal that is representable as bits, otherwise crashes. */ def litValue(): BigInt = litOption.get /** Returns the width, in bits, if currently known. */ final def getWidth: Int = if (isWidthKnown) width.get else throwException(s"Width of $this is unknown!") /** Returns whether the width is currently known. */ final def isWidthKnown: Boolean = width.known /** Returns Some(width) if the width is known, else None. */ final def widthOption: Option[Int] = if (isWidthKnown) Some(getWidth) else None /** Packs the value of this object as plain Bits. * * This performs the inverse operation of fromBits(Bits). */ @chiselRuntimeDeprecated @deprecated("Best alternative, .asUInt()", "chisel3") def toBits(implicit compileOptions: CompileOptions): UInt = do_asUInt(DeprecatedSourceInfo, compileOptions) /** 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. * * @note bit widths are NOT checked, may pad or drop bits from input * @note that should have known widths */ def asTypeOf[T <: Data](that: T): T = macro SourceInfoTransform.thatArg /** @group SourceInfoTransformMacro */ def do_asTypeOf[T <: Data](that: T)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): T = { val thatCloned = Wire(that.cloneTypeFull) thatCloned.connectFromBits(this.asUInt()) thatCloned } /** Assigns this node from Bits type. Internal implementation for asTypeOf. */ private[core] def connectFromBits(that: Bits)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): Unit /** Reinterpret cast to UInt. * * @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 * @note Aggregates are recursively packed with the first element appearing * in the least-significant bits of the result. */ final def asUInt(): UInt = macro SourceInfoTransform.noArg /** @group SourceInfoTransformMacro */ def do_asUInt(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): UInt /** Default pretty printing */ def toPrintable: Printable } trait WireFactory { /** @usecase def apply[T <: Data](t: T): T * Construct a [[Wire]] from a type template * @param t The template from which to construct this wire */ def apply[T <: Data](t: T)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): T = { if (compileOptions.declaredTypeMustBeUnbound) { requireIsChiselType(t, "wire type") } val x = t.cloneTypeFull // Bind each element of x to being a Wire x.bind(WireBinding(Builder.forcedUserModule)) pushCommand(DefWire(sourceInfo, x)) if (!compileOptions.explicitInvalidate) { pushCommand(DefInvalid(sourceInfo, x.ref)) } x } } /** Utility for constructing hardware wires * * The width of a `Wire` (inferred or not) is copied from the type template * {{{ * val w0 = Wire(UInt()) // width is inferred * val w1 = Wire(UInt(8.W)) // width is set to 8 * * val w2 = Wire(Vec(4, UInt())) // width is inferred * val w3 = Wire(Vec(4, UInt(8.W))) // width of each element is set to 8 * * class MyBundle { * val unknown = UInt() * val known = UInt(8.W) * } * val w4 = Wire(new MyBundle) * // Width of w4.unknown is inferred * // Width of w4.known is set to 8 * }}} * */ object Wire extends WireFactory /** Utility for constructing hardware wires with a default connection * * The two forms of `WireDefault` differ in how the type and width of the resulting [[Wire]] are * specified. * * ==Single Argument== * The single argument form uses the argument to specify both the type and default connection. For * non-literal [[Bits]], the width of the [[Wire]] will be inferred. For literal [[Bits]] and all * non-Bits arguments, the type will be copied from the argument. See the following examples for * more details: * * 1. Literal [[Bits]] initializer: width will be set to match * {{{ * val w1 = WireDefault(1.U) // width will be inferred to be 1 * val w2 = WireDefault(1.U(8.W)) // width is set to 8 * }}} * * 2. Non-Literal [[Element]] initializer - width will be inferred * {{{ * val x = Wire(UInt()) * val y = Wire(UInt(8.W)) * val w1 = WireDefault(x) // width will be inferred * val w2 = WireDefault(y) // width will be inferred * }}} * * 3. [[Aggregate]] initializer - width will be set to match the aggregate * * {{{ * class MyBundle { * val unknown = UInt() * val known = UInt(8.W) * } * val w1 = Wire(new MyBundle) * val w2 = WireDefault(w1) * // Width of w2.unknown is inferred * // Width of w2.known is set to 8 * }}} * * ==Double Argument== * The double argument form allows the type of the [[Wire]] and the default connection to be * specified independently. * * The width inference semantics for `WireDefault` with two arguments match those of [[Wire]]. The * first argument to `WireDefault` is the type template which defines the width of the `Wire` in * exactly the same way as the only argument to [[Wire]]. * * More explicitly, you can reason about `WireDefault` with multiple arguments as if it were defined * as: * {{{ * def WireDefault[T <: Data](t: T, init: T): T = { * val x = Wire(t) * x := init * x * } * }}} * * @note The `Default` in `WireDefault` refers to a `default` connection. This is in contrast to * [[RegInit]] where the `Init` refers to a value on reset. */ object WireDefault { private def applyImpl[T <: Data](t: T, init: Data)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): T = { implicit val noSourceInfo = UnlocatableSourceInfo val x = Wire(t) requireIsHardware(init, "wire initializer") x := init x } /** @usecase def apply[T <: Data](t: T, init: DontCare.type): T * Construct a [[Wire]] with a type template and a [[DontCare]] default * @param t The type template used to construct this [[Wire]] * @param init The default connection to this [[Wire]], can only be [[DontCare]] * @note This is really just a specialized form of `apply[T <: Data](t: T, init: T): T` with [[DontCare]] * as `init` */ def apply[T <: Data](t: T, init: DontCare.type)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): T = { applyImpl(t, init) } /** @usecase def apply[T <: Data](t: T, init: T): T * Construct a [[Wire]] with a type template and a default connection * @param t The type template used to construct this [[Wire]] * @param init The hardware value that will serve as the default value */ def apply[T <: Data](t: T, init: T)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): T = { applyImpl(t, init) } /** @usecase def apply[T <: Data](init: T): T * Construct a [[Wire]] with a default connection * @param init The hardware value that will serve as a type template and default value */ def apply[T <: Data](init: T)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): T = { val model = (init match { // If init is a literal without forced width OR any non-literal, let width be inferred case init: Bits if !init.litIsForcedWidth.getOrElse(false) => init.cloneTypeWidth(Width()) case _ => init.cloneTypeFull }).asInstanceOf[T] apply(model, init) } } /** RHS (source) for Invalidate API. * Causes connection logic to emit a DefInvalid when connected to an output port (or wire). */ object DontCare extends Element { // This object should be initialized before we execute any user code that refers to it, // otherwise this "Chisel" object will end up on the UserModule's id list. private[chisel3] override val width: Width = UnknownWidth() bind(DontCareBinding(), SpecifiedDirection.Output) override def cloneType = DontCare override def toString: String = "DontCare()" override def litOption = None def toPrintable: Printable = PString("DONTCARE") private[core] def connectFromBits(that: chisel3.core.Bits)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): Unit = { Builder.error("connectFromBits: DontCare cannot be a connection sink (LHS)") } def do_asUInt(implicit sourceInfo: chisel3.internal.sourceinfo.SourceInfo, compileOptions: CompileOptions): chisel3.core.UInt = { Builder.error("DontCare does not have a UInt representation") 0.U } // DontCare's only match themselves. private[core] def typeEquivalent(that: chisel3.core.Data): Boolean = that == DontCare }