sealed class FixedPoint extends Bits with Num[FixedPoint] with HasBinaryPoint
A sealed class representing a fixed point number that has a bit width and a binary point The width and binary point may be inferred.
IMPORTANT: The API provided here is experimental and may change in the future.
- Annotations
- @deprecated
- Deprecated
(Since version Chisel 3.6) this feature will not be supported as part of the migration to the MLIR-based FIRRTL Compiler (MFC). For more information about this migration, please see the Chisel ROADMAP.md.
- Source
- Bits.scala
- Grouped
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- FixedPoint
- HasBinaryPoint
- Num
- Bits
- ToBoolable
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- SourceInfoDoc
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- HasId
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- by toConnectableDefault
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- by any2stringadd
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- by Ensuring
- by ArrowAssoc
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- Public
- Protected
Value Members
- final macro def !=(that: FixedPoint): Bool
- final def !=(arg0: Any): Boolean
- Definition Classes
- AnyRef → Any
- final macro def ##(that: Bits): UInt
Concatenation operator
Concatenation operator
- that
a hardware component
- returns
this FixedPoint concatenated to the most significant end of
that
- Definition Classes
- Bits
- Note
The width of the returned FixedPoint is
width of this
+width of that
.
- final def ##: Int
- Definition Classes
- AnyRef → Any
- final macro def %(that: FixedPoint): FixedPoint
Modulo operator
Modulo operator
- that
- returns
the remainder of this FixedPoint divided by
that
- Definition Classes
- Num
- Note
This method generates a fully combinational divider which can result in significant cycle time and area costs.
- final macro def &(that: FixedPoint): FixedPoint
Bitwise and operator
Bitwise and operator
- that
a hardware FixedPoint
- returns
the bitwise and of this FixedPoint and
that
- Note
The width of the returned FixedPoint is
max(width of this, width of that)
.
- final macro def *(that: SInt): FixedPoint
Multiplication operator
Multiplication operator
- that
a hardware SInt
- returns
the product of this FixedPoint and
that
- Note
The width of the returned FixedPoint is
,width of this
+width of that
.This method generates a fully combinational multiplier which can result in significant cycle time and area costs.
- final macro def *(that: UInt): FixedPoint
Multiplication operator
Multiplication operator
- that
a hardware UInt
- returns
the product of this FixedPoint and
that
- Note
The width of the returned FixedPoint is
,width of this
+width of that
.This method generates a fully combinational multiplier which can result in significant cycle time and area costs.
- final macro def *(that: FixedPoint): FixedPoint
Multiplication operator
Multiplication operator
- that
- returns
the product of this FixedPoint and
that
- Definition Classes
- Num
- Note
The width of the returned FixedPoint is
,width of this
+width of that
.This method generates a fully combinational multiplier which can result in significant cycle time and area costs.
- final macro def +(that: FixedPoint): FixedPoint
Addition operator
Addition operator
- that
- returns
the sum of this FixedPoint and
that
- Definition Classes
- Num
- Note
The width of the returned FixedPoint is
max(width of this, width of that)
.
- final macro def +%(that: FixedPoint): FixedPoint
Addition operator (constant width)
Addition operator (constant width)
- that
a hardware FixedPoint
- returns
the sum of this FixedPoint and
that
shifted right by one
- Note
The width of the returned FixedPoint is
max(width of this, width of that)
.
- final macro def +&(that: FixedPoint): FixedPoint
Addition operator (expanding width)
Addition operator (expanding width)
- that
a hardware FixedPoint
- returns
the sum of this FixedPoint and
that
- Note
The width of the returned FixedPoint is
max(width of this, width of that) + 1
.
- final macro def -(that: FixedPoint): FixedPoint
Subtraction operator
Subtraction operator
- that
- returns
the difference of this FixedPoint less
that
- Definition Classes
- Num
- Note
The width of the returned FixedPoint is
max(width of this, width of that) + 1
.
- final macro def -%(that: FixedPoint): FixedPoint
Subtraction operator (constant width)
Subtraction operator (constant width)
- that
a hardware FixedPoint
- returns
the difference of this FixedPoint less
that
shifted right by one
- Note
The width of the returned FixedPoint is
max(width of this, width of that)
.
- final macro def -&(that: FixedPoint): FixedPoint
Subtraction operator (increasing width)
Subtraction operator (increasing width)
- that
a hardware FixedPoint
- returns
the difference of this FixedPoint less
that
- Note
The width of the returned FixedPoint is
max(width of this, width of that) + 1
.
- def ->[B](y: B): (FixedPoint, B)
- Implicit
- This member is added by an implicit conversion from FixedPoint toArrowAssoc[FixedPoint] performed by method ArrowAssoc in scala.Predef.
- Definition Classes
- ArrowAssoc
- Annotations
- @inline()
- final macro def /(that: FixedPoint): FixedPoint
Division operator
Division operator
- that
- returns
the quotient of this FixedPoint divided by
that
- Definition Classes
- Num
- To do
full rules
- Note
This method generates a fully combinational divider which can result in significant cycle time and area costs.
- final def :#=(producer: DontCare.type)(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 connectbits
,valid
, ANDready
from producer to consumer (despiteready
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 FixedPoint toConnectableDefault[FixedPoint] performed by method ConnectableDefault in chisel3.Data.
- Definition Classes
- ConnectableOpExtension
- final def :#=[S <: Data](producer: connectable.Connectable[S])(implicit evidence: =:=[FixedPoint, 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 connectbits
,valid
, ANDready
from producer to consumer (despiteready
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 FixedPoint toConnectableDefault[FixedPoint] performed by method ConnectableDefault in chisel3.Data.
- Definition Classes
- ConnectableOpExtension
- final def :#=[S <: Data](lProducer: => S)(implicit evidence: =:=[FixedPoint, 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 connectbits
,valid
, ANDready
from producer to consumer (despiteready
being flipped) - Functionally equivalent to chisel3.:=, but different than Chisel.:=- Implicit
- This member is added by an implicit conversion from FixedPoint toConnectableDefault[FixedPoint] performed by method ConnectableDefault in chisel3.Data.
- Definition Classes
- ConnectableOpExtension
- 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 ofconsumer
's leaf members which are aligned with respect toconsumer
are driven from the correspondingproducer
leaf member. Onlyconsumer
'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 connectbits
andvalid
from producer to consumer, but leaveready
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 FixedPoint toConnectableDefault[FixedPoint] performed by method ConnectableDefault in chisel3.Data.
- Definition Classes
- ConnectableOpExtension
- final def :<=[S <: Data](producer: connectable.Connectable[S])(implicit evidence: =:=[FixedPoint, 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 ofconsumer
's leaf members which are aligned with respect toconsumer
are driven from the correspondingproducer
leaf member. Onlyconsumer
'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 connectbits
andvalid
from producer to consumer, but leaveready
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 FixedPoint toConnectableDefault[FixedPoint] performed by method ConnectableDefault in chisel3.Data.
- Definition Classes
- ConnectableOpExtension
- final def :<=[S <: Data](lProducer: => S)(implicit evidence: =:=[FixedPoint, 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 ofconsumer
's leaf members which are aligned with respect toconsumer
are driven from the correspondingproducer
leaf member. Onlyconsumer
'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 connectbits
andvalid
from producer to consumer, but leaveready
unconnected
- Implicit
- This member is added by an implicit conversion from FixedPoint toConnectableDefault[FixedPoint] performed by method ConnectableDefault in chisel3.Data.
- Definition Classes
- ConnectableOpExtension
- 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. Theconsumer
's members aligned w.r.t.consumer
will be driven by corresponding members ofproducer
; theproducer
's members flipped w.r.t.producer
will be driven by corresponding members ofconsumer
Identical to calling
:<=
and:>=
in sequence (order is irrelevant), e.g.consumer :<= producer
thenconsumer :>= 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
andproducer
must match exactly.
Additional notes:
- Connecting two wires of
util.DecoupledIO
chisel type would connectbits
andvalid
from producer to consumer, andready
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 FixedPoint toConnectableDefault[FixedPoint] performed by method ConnectableDefault in chisel3.Data.
- Definition Classes
- ConnectableOpExtension
- final def :<>=[S <: Data](producer: connectable.Connectable[S])(implicit evidence: =:=[FixedPoint, 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. Theconsumer
's members aligned w.r.t.consumer
will be driven by corresponding members ofproducer
; theproducer
's members flipped w.r.t.producer
will be driven by corresponding members ofconsumer
Identical to calling
:<=
and:>=
in sequence (order is irrelevant), e.g.consumer :<= producer
thenconsumer :>= 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
andproducer
must match exactly.
Additional notes:
- Connecting two wires of
util.DecoupledIO
chisel type would connectbits
andvalid
from producer to consumer, andready
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 FixedPoint toConnectableDefault[FixedPoint] performed by method ConnectableDefault in chisel3.Data.
- Definition Classes
- ConnectableOpExtension
- final def :<>=[S <: Data](lProducer: => S)(implicit evidence: =:=[FixedPoint, 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. Theconsumer
's members aligned w.r.t.consumer
will be driven by corresponding members ofproducer
; theproducer
's members flipped w.r.t.producer
will be driven by corresponding members ofconsumer
Identical to calling
:<=
and:>=
in sequence (order is irrelevant), e.g.consumer :<= producer
thenconsumer :>= 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
andproducer
must match exactly.
Additional notes:
- Connecting two wires of
util.DecoupledIO
chisel type would connectbits
andvalid
from producer to consumer, andready
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 FixedPoint toConnectableDefault[FixedPoint] performed by method ConnectableDefault in chisel3.Data.
- Definition Classes
- ConnectableOpExtension
- 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 ofthat
.- 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
- Equivalent to
- 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 ofproducer
's leaf members which are flipped with respect toproducer
are driven from the corresponding consumer leaf member Onlyproducer
'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 connectready
from consumer to producer, but leavebits
andvalid
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 FixedPoint toConnectableDefault[FixedPoint] performed by method ConnectableDefault in chisel3.Data.
- Definition Classes
- ConnectableOpExtension
- final def :>=[S <: Data](producer: connectable.Connectable[S])(implicit evidence: =:=[FixedPoint, 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 ofproducer
's leaf members which are flipped with respect toproducer
are driven from the corresponding consumer leaf member Onlyproducer
'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 connectready
from consumer to producer, but leavebits
andvalid
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 FixedPoint toConnectableDefault[FixedPoint] performed by method ConnectableDefault in chisel3.Data.
- Definition Classes
- ConnectableOpExtension
- final def :>=[S <: Data](lProducer: => S)(implicit evidence: =:=[FixedPoint, 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 ofproducer
's leaf members which are flipped with respect toproducer
are driven from the corresponding consumer leaf member Onlyproducer
'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 connectready
from consumer to producer, but leavebits
andvalid
unconnected
- Implicit
- This member is added by an implicit conversion from FixedPoint toConnectableDefault[FixedPoint] performed by method ConnectableDefault in chisel3.Data.
- Definition Classes
- ConnectableOpExtension
- final macro def <(that: FixedPoint): Bool
Less than operator
Less than operator
- that
- returns
a hardware Bool asserted if this FixedPoint is less than
that
- Definition Classes
- Num
- final macro def <<(that: UInt): Bits
Dynamic left shift operator
Dynamic left shift operator
- that
a hardware component
- returns
this FixedPoint dynamically shifted left by
that
many places, shifting in zeros from the right
- Definition Classes
- Bits
- Note
The width of the returned FixedPoint is
width of this + pow(2, width of that) - 1
.
- final macro def <<(that: Int): Bits
Static left shift operator
Static left shift operator
- that
an amount to shift by
- returns
this FixedPoint with
that
many zeros concatenated to its least significant end
- Definition Classes
- Bits
- Note
The width of the returned FixedPoint is
width of this
+that
.
- final macro def <<(that: BigInt): Bits
Static left shift operator
Static left shift operator
- that
an amount to shift by
- returns
this FixedPoint with
that
many zeros concatenated to its least significant end
- Definition Classes
- Bits
- Note
The width of the returned FixedPoint is
width of this
+that
.
- final macro def <=(that: FixedPoint): Bool
Less than or equal to operator
Less than or equal to operator
- that
- returns
a hardware Bool asserted if this FixedPoint is less than or equal to
that
- Definition Classes
- Num
- 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 thatmay 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
- final macro def =/=(that: FixedPoint): Bool
Dynamic not equals operator
Dynamic not equals operator
- that
a hardware FixedPoint
- returns
a hardware Bool asserted if this FixedPoint is not equal to
that
- final def ==(arg0: Any): Boolean
- Definition Classes
- AnyRef → Any
- final macro def ===(that: FixedPoint): Bool
Dynamic equals operator
Dynamic equals operator
- that
a hardware FixedPoint
- returns
a hardware Bool asserted if this FixedPoint is equal to
that
- final macro def >(that: FixedPoint): Bool
Greater than operator
Greater than operator
- that
a hardware component
- returns
a hardware Bool asserted if this FixedPoint is greater than
that
- Definition Classes
- Num
- final macro def >=(that: FixedPoint): Bool
Greater than or equal to operator
Greater than or equal to operator
- that
a hardware component
- returns
a hardware Bool asserted if this FixedPoint is greather than or equal to
that
- Definition Classes
- Num
- final macro def >>(that: UInt): Bits
Dynamic right shift operator
Dynamic right shift operator
- that
a hardware component
- returns
this FixedPoint dynamically shifted right by the value of
that
component, inserting zeros into the most significant bits.
- Definition Classes
- Bits
- Note
The width of the returned FixedPoint is unchanged, i.e., the
width of this
.
- final macro def >>(that: Int): Bits
Static right shift operator
Static right shift operator
- that
an amount to shift by
- returns
this FixedPoint with
that
many least significant bits truncated
- Definition Classes
- Bits
- Note
The width of the returned FixedPoint is unchanged, i.e., the
width of this
.
- final macro def >>(that: BigInt): Bits
Static right shift operator
Static right shift operator
- that
an amount to shift by
- returns
this FixedPoint with
that
many least significant bits truncated
- Definition Classes
- Bits
- Note
The width of the returned FixedPoint is unchanged, i.e., the
width of this
.
- final macro def ^(that: FixedPoint): FixedPoint
Bitwise exclusive or (xor) operator
Bitwise exclusive or (xor) operator
- that
a hardware FixedPoint
- returns
the bitwise xor of this FixedPoint and
that
- Note
The width of the returned FixedPoint is
max(width of this, width of that)
.
- final macro def abs: FixedPoint
Absolute value operator
Absolute value operator
- returns
a FixedPoint with a value equal to the absolute value of this FixedPoint
- Definition Classes
- Num
- Note
The width of the returned FixedPoint is unchanged, i.e., the
width of this
.
- final macro def apply(x: BigInt, y: BigInt): UInt
Returns a subset of bits on this FixedPoint from
hi
tolo
(inclusive), statically addressed.Returns a subset of bits on this FixedPoint from
hi
tolo
(inclusive), statically addressed.- x
the high bit
- y
the low bit
- returns
a hardware component contain the requested bits
- Definition Classes
- Bits
myBits = 0x5 = 0b101 myBits(1,0) => 0b01 // extracts the two least significant bits
Example: - final macro def apply(x: Int, y: Int): UInt
Returns a subset of bits on this FixedPoint from
hi
tolo
(inclusive), statically addressed.Returns a subset of bits on this FixedPoint from
hi
tolo
(inclusive), statically addressed.- x
the high bit
- y
the low bit
- returns
a hardware component contain the requested bits
- Definition Classes
- Bits
myBits = 0x5 = 0b101 myBits(1,0) => 0b01 // extracts the two least significant bits
Example: - final macro def apply(x: UInt): Bool
Returns the specified bit on this wire as a Bool, dynamically addressed.
- final macro def apply(x: Int): Bool
Returns the specified bit on this FixedPoint as a Bool, statically addressed.
Returns the specified bit on this FixedPoint as a Bool, statically addressed.
- x
an index
- returns
the specified bit
- Definition Classes
- Bits
- final macro def apply(x: BigInt): Bool
Returns the specified bit on this FixedPoint as a Bool, statically addressed.
Returns the specified bit on this FixedPoint as a Bool, statically addressed.
- x
an index
- returns
the specified bit
- Definition Classes
- Bits
- final macro def asBool: Bool
Casts this FixedPoint to a Bool
Casts this FixedPoint to a Bool
- Definition Classes
- ToBoolable
- Note
The width must be known and equal to 1
- final macro def asBools: Seq[Bool]
Returns the contents of this wire as a scala.collection.Seq of Bool.
Returns the contents of this wire as a scala.collection.Seq of Bool.
- Definition Classes
- Bits
- final def asInstanceOf[T0]: T0
- Definition Classes
- Any
- final macro def asSInt: SInt
Reinterpret this FixedPoint as an SInt
Reinterpret this FixedPoint as an SInt
- 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
- 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.
- def autoSeed(name: String): FixedPoint.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
- val base: FixedPoint
- Implicit
- This member is added by an implicit conversion from FixedPoint toConnectable[FixedPoint] performed by method toConnectableDefault in chisel3.Data.
- Definition Classes
- Connectable
- val binaryPoint: BinaryPoint
- Definition Classes
- FixedPoint → HasBinaryPoint
- def binding: Option[Binding]
- def binding_=(target: Binding): Unit
- Attributes
- protected
- Definition Classes
- Data
- def circuitName: String
- Attributes
- protected
- Definition Classes
- HasId
- def clone(): AnyRef
- Attributes
- protected[lang]
- Definition Classes
- AnyRef
- Annotations
- @throws(classOf[java.lang.CloneNotSupportedException]) @native() @HotSpotIntrinsicCandidate()
- def cloneType: FixedPoint.this.type
Internal API; Chisel users should look at chisel3.chiselTypeOf(...).
- def connect(that: Data)(implicit sourceInfo: SourceInfo, connectCompileOptions: CompileOptions): Unit
- Definition Classes
- FixedPoint → Data
- def do_!=(that: FixedPoint)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): Bool
- def do_##(that: Bits)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): UInt
- Definition Classes
- Bits
- def do_%(that: FixedPoint)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): FixedPoint
- Definition Classes
- FixedPoint → Num
- def do_&(that: FixedPoint)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): FixedPoint
- def do_*(that: SInt)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): FixedPoint
- def do_*(that: UInt)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): FixedPoint
- def do_*(that: FixedPoint)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): FixedPoint
- Definition Classes
- FixedPoint → Num
- def do_+(that: FixedPoint)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): FixedPoint
add (default - no growth) operator
add (default - no growth) operator
- Definition Classes
- FixedPoint → Num
- def do_+%(that: FixedPoint)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): FixedPoint
- def do_+&(that: FixedPoint)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): FixedPoint
- def do_-(that: FixedPoint)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): FixedPoint
subtract (default - no growth) operator
subtract (default - no growth) operator
- Definition Classes
- FixedPoint → Num
- def do_-%(that: FixedPoint)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): FixedPoint
- def do_-&(that: FixedPoint)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): FixedPoint
- def do_/(that: FixedPoint)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): FixedPoint
- Definition Classes
- FixedPoint → Num
- def do_<(that: FixedPoint)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): Bool
- Definition Classes
- FixedPoint → Num
- def do_<<(that: UInt)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): FixedPoint
- Definition Classes
- FixedPoint → Bits
- def do_<<(that: BigInt)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): FixedPoint
- Definition Classes
- FixedPoint → Bits
- def do_<<(that: Int)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): FixedPoint
- Definition Classes
- FixedPoint → Bits
- def do_<=(that: FixedPoint)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): Bool
- Definition Classes
- FixedPoint → Num
- def do_=/=(that: FixedPoint)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): Bool
- def do_===(that: FixedPoint)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): Bool
- def do_>(that: FixedPoint)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): Bool
- Definition Classes
- FixedPoint → Num
- def do_>=(that: FixedPoint)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): Bool
- Definition Classes
- FixedPoint → Num
- def do_>>(that: UInt)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): FixedPoint
- Definition Classes
- FixedPoint → Bits
- def do_>>(that: BigInt)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): FixedPoint
- Definition Classes
- FixedPoint → Bits
- def do_>>(that: Int)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): FixedPoint
- Definition Classes
- FixedPoint → Bits
- def do_^(that: FixedPoint)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): FixedPoint
- def do_abs(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): FixedPoint
- Definition Classes
- FixedPoint → Num
- final def do_apply(x: BigInt, y: BigInt)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): UInt
- Definition Classes
- Bits
- final def do_apply(x: Int, y: Int)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): UInt
- Definition Classes
- Bits
- final def do_apply(x: UInt)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): Bool
- Definition Classes
- Bits
- final def do_apply(x: Int)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): Bool
- Definition Classes
- Bits
- final def do_apply(x: BigInt)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): Bool
- Definition Classes
- Bits
- final def do_asBool(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): Bool
- Definition Classes
- Bits → ToBoolable
- def do_asBools(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): Seq[Bool]
- Definition Classes
- Bits
- def do_asFixedPoint(binaryPoint: BinaryPoint)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): FixedPoint
- Definition Classes
- FixedPoint → Bits
- def do_asInterval(range: IntervalRange = IntervalRange.Unknown)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): Interval
- Definition Classes
- FixedPoint → Bits
- def do_asInterval(binaryPoint: BinaryPoint)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): Interval
- def do_asSInt(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): SInt
- Definition Classes
- FixedPoint → Bits
- def do_asTypeOf[T <: Data](that: T)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): T
- Definition Classes
- Data
- def do_asUInt(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): UInt
- Definition Classes
- FixedPoint → Data
- final def do_extract(x: UInt)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): Bool
- Definition Classes
- Bits
- final def do_extract(x: BigInt)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): Bool
- Definition Classes
- Bits
- def do_head(n: Int)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): UInt
- Definition Classes
- Bits
- def do_max(that: FixedPoint)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): FixedPoint
- Definition Classes
- Num
- def do_min(that: FixedPoint)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): FixedPoint
- Definition Classes
- Num
- def do_pad(that: Int)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): FixedPoint.this.type
- Definition Classes
- Bits
- def do_setBinaryPoint(that: Int)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): FixedPoint
- def do_tail(n: Int)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): UInt
- Definition Classes
- Bits
- def do_unary_-(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): FixedPoint
- def do_unary_-%(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): FixedPoint
- def do_unary_~(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): FixedPoint
- Definition Classes
- FixedPoint → Bits
- def do_|(that: FixedPoint)(implicit sourceInfo: SourceInfo, compileOptions: CompileOptions): FixedPoint
- def ensuring(cond: (FixedPoint) => Boolean, msg: => Any): FixedPoint
- Implicit
- This member is added by an implicit conversion from FixedPoint toEnsuring[FixedPoint] performed by method Ensuring in scala.Predef.
- Definition Classes
- Ensuring
- def ensuring(cond: (FixedPoint) => Boolean): FixedPoint
- Implicit
- This member is added by an implicit conversion from FixedPoint toEnsuring[FixedPoint] performed by method Ensuring in scala.Predef.
- Definition Classes
- Ensuring
- def ensuring(cond: Boolean, msg: => Any): FixedPoint
- Implicit
- This member is added by an implicit conversion from FixedPoint toEnsuring[FixedPoint] performed by method Ensuring in scala.Predef.
- Definition Classes
- Ensuring
- def ensuring(cond: Boolean): FixedPoint
- Implicit
- This member is added by an implicit conversion from FixedPoint toEnsuring[FixedPoint] performed by method Ensuring in scala.Predef.
- Definition Classes
- Ensuring
- final def eq(arg0: AnyRef): Boolean
- Definition Classes
- AnyRef
- def equals(that: Any): Boolean
- Definition Classes
- HasId → AnyRef → Any
- def exclude(members: (FixedPoint) => Data*): connectable.Connectable[FixedPoint]
Select members of base to exclude
Select members of base to exclude
- members
functions given the base return a member to exclude
- Implicit
- This member is added by an implicit conversion from FixedPoint toConnectable[FixedPoint] performed by method toConnectableDefault in chisel3.Data.
- Definition Classes
- Connectable
- def exclude: connectable.Connectable[FixedPoint]
Adds base to excludes
Adds base to excludes
- Implicit
- This member is added by an implicit conversion from FixedPoint toConnectable[FixedPoint] performed by method toConnectableDefault in chisel3.Data.
- Definition Classes
- Connectable
- def excludeAs[S <: Data](members: (FixedPoint) => Data*)(implicit ev: <:<[FixedPoint, S]): connectable.Connectable[S]
Select members of base to exclude and static cast to a new type
Select members of base to exclude and static cast to a new type
- members
functions given the base return a member to exclude
- Implicit
- This member is added by an implicit conversion from FixedPoint toConnectable[FixedPoint] performed by method toConnectableDefault in chisel3.Data.
- Definition Classes
- Connectable
- def excludeEach[S <: Data](pf: PartialFunction[Data, Seq[Data]])(implicit ev: <:<[FixedPoint, S]): connectable.Connectable[S]
Programmatically select members of base to exclude and static cast to a new type
Programmatically select members of base to exclude and static cast to a new type
- Implicit
- This member is added by an implicit conversion from FixedPoint toConnectable[FixedPoint] performed by method toConnectableDefault in chisel3.Data.
- Definition Classes
- Connectable
- final macro def extract(x: UInt): Bool
Returns the specified bit on this wire as a Bool, dynamically addressed.
- final macro def extract(x: BigInt): Bool
Returns the specified bit on this FixedPoint as a Bool, statically addressed.
Returns the specified bit on this FixedPoint as a Bool, statically addressed.
- x
an index
- returns
the specified bit
- Definition Classes
- Bits
- final def getClass(): Class[_ <: AnyRef]
- Definition Classes
- AnyRef → Any
- Annotations
- @native() @HotSpotIntrinsicCandidate()
- final def getWidth: Int
Returns the width, in bits, if currently known.
Returns the width, in bits, if currently known.
- Definition Classes
- Data
- def hasSeed: Boolean
- returns
Whether either autoName or suggestName has been called
- Definition Classes
- HasId
- def hashCode(): Int
- Definition Classes
- HasId → AnyRef → Any
- final macro def head(n: Int): UInt
Head operator
Head operator
- n
the number of bits to take
- returns
The
n
most significant bits of this FixedPoint
- Definition Classes
- Bits
- def instanceName: String
- Definition Classes
- HasId → InstanceId
- final def isInstanceOf[T0]: Boolean
- Definition Classes
- Any
- def isLit: Boolean
- Definition Classes
- Data
- final def isWidthKnown: Boolean
Returns whether the width is currently known.
Returns whether the width is currently known.
- Definition Classes
- Data
- def litOption: Option[BigInt]
If this is a literal that is representable as bits, returns the value as a BigInt.
- 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
- final macro def max(that: FixedPoint): FixedPoint
Maximum operator
Maximum operator
- that
- returns
a FixedPoint with a value equal to the minimum value of this FixedPoint and
that
- Definition Classes
- Num
- Note
The width of the returned FixedPoint is
max(width of this, width of that)
.
- final macro def min(that: FixedPoint): FixedPoint
Minimum operator
Minimum operator
- that
a hardware FixedPoint
- returns
a FixedPoint with a value equal to the minimum value of this FixedPoint and
that
- Definition Classes
- Num
- Note
The width of the returned FixedPoint is
max(width of this, width of that)
.
- def name: String
- Definition Classes
- Element
- final def ne(arg0: AnyRef): Boolean
- Definition Classes
- AnyRef
- def notWaivedOrSqueezedOrExcluded: Boolean
True if no members are waived or squeezed or excluded
True if no members are waived or squeezed or excluded
- Implicit
- This member is added by an implicit conversion from FixedPoint toConnectable[FixedPoint] performed by method toConnectableDefault in chisel3.Data.
- Definition Classes
- Connectable
- final def notify(): Unit
- Definition Classes
- AnyRef
- Annotations
- @native() @HotSpotIntrinsicCandidate()
- final def notifyAll(): Unit
- Definition Classes
- AnyRef
- Annotations
- @native() @HotSpotIntrinsicCandidate()
- final macro def pad(that: Int): FixedPoint.this.type
Pad operator
- def parentModName: String
- Definition Classes
- HasId → InstanceId
- def parentPathName: String
- Definition Classes
- HasId → InstanceId
- def pathName: String
- Definition Classes
- HasId → InstanceId
- final macro def setBinaryPoint(that: Int): FixedPoint
- def squeeze(members: (FixedPoint) => Data*): connectable.Connectable[FixedPoint]
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 FixedPoint toConnectable[FixedPoint] performed by method toConnectableDefault in chisel3.Data.
- Definition Classes
- Connectable
- def squeeze: connectable.Connectable[FixedPoint]
Adds base to squeezes
Adds base to squeezes
- Implicit
- This member is added by an implicit conversion from FixedPoint toConnectable[FixedPoint] performed by method toConnectableDefault in chisel3.Data.
- Definition Classes
- Connectable
- def squeezeAll: connectable.Connectable[FixedPoint]
Squeeze all members of base
Squeeze all members of base
- Implicit
- This member is added by an implicit conversion from FixedPoint toConnectable[FixedPoint] performed by method toConnectableDefault in chisel3.Data.
- Definition Classes
- Connectable
- def squeezeEach[S <: Data](pf: PartialFunction[Data, Seq[Data]]): connectable.Connectable[FixedPoint]
Programmatically select members of base to squeeze
Programmatically select members of base to squeeze
- Implicit
- This member is added by an implicit conversion from FixedPoint toConnectable[FixedPoint] performed by method toConnectableDefault in chisel3.Data.
- Definition Classes
- Connectable
- def suggestName(seed: => String): FixedPoint.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 whetherautoSeed
was called, suggestName will always take precedence.- seed
The seed for the name of this component
- returns
this object
- Definition Classes
- HasId
- final def synchronized[T0](arg0: => T0): T0
- Definition Classes
- AnyRef
- final macro def tail(n: Int): UInt
Tail operator
Tail operator
- n
the number of bits to remove
- returns
This FixedPoint with the
n
most significant bits removed.
- Definition Classes
- Bits
- 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
- 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
- final def toPrintable: Printable
Default print as Decimal
- def toString(): String
- Definition Classes
- FixedPoint → AnyRef → Any
- 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
- final macro def unary_-: FixedPoint
Unary negation (expanding width)
Unary negation (expanding width)
- returns
a hardware FixedPoint equal to zero minus this FixedPoint
- Note
The width of the returned FixedPoint is
width of this
+1
.
- final macro def unary_-%: FixedPoint
Unary negation (constant width)
Unary negation (constant width)
- returns
a hardware FixedPoint equal to zero minus
this
shifted right by one
- Note
The width of the returned FixedPoint is unchanged, i.e.,
width of this
.
- final macro def unary_~: Bits
Bitwise inversion operator
- final def validateShiftAmount(x: Int)(implicit sourceInfo: SourceInfo): Int
- Attributes
- protected
- Definition Classes
- Bits
- final def wait(arg0: Long, arg1: Int): Unit
- Definition Classes
- AnyRef
- Annotations
- @throws(classOf[java.lang.InterruptedException])
- final def wait(arg0: Long): Unit
- Definition Classes
- AnyRef
- Annotations
- @throws(classOf[java.lang.InterruptedException]) @native()
- final def wait(): Unit
- Definition Classes
- AnyRef
- Annotations
- @throws(classOf[java.lang.InterruptedException])
- def waive(members: (FixedPoint) => Data*): connectable.Connectable[FixedPoint]
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 FixedPoint toConnectable[FixedPoint] performed by method toConnectableDefault in chisel3.Data.
- Definition Classes
- Connectable
- def waiveAll: connectable.Connectable[FixedPoint]
Waive all members of base
Waive all members of base
- Implicit
- This member is added by an implicit conversion from FixedPoint toConnectable[FixedPoint] performed by method toConnectableDefault in chisel3.Data.
- Definition Classes
- Connectable
- def waiveAllAs[S <: Data](implicit ev: <:<[FixedPoint, 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 FixedPoint toConnectable[FixedPoint] performed by method toConnectableDefault in chisel3.Data.
- Definition Classes
- Connectable
- def waiveAs[S <: Data](members: (FixedPoint) => Data*)(implicit ev: <:<[FixedPoint, 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 FixedPoint toConnectable[FixedPoint] performed by method toConnectableDefault in chisel3.Data.
- Definition Classes
- Connectable
- def waiveEach[S <: Data](pf: PartialFunction[Data, Seq[Data]])(implicit ev: <:<[FixedPoint, 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 FixedPoint toConnectable[FixedPoint] performed by method toConnectableDefault in chisel3.Data.
- Definition Classes
- Connectable
- def widthKnown: Boolean
- Definition Classes
- Element
- 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
- final macro def |(that: FixedPoint): FixedPoint
Bitwise or operator
Bitwise or operator
- that
a hardware FixedPoint
- returns
the bitwise or of this FixedPoint and
that
- Note
The width of the returned FixedPoint is
max(width of this, width of that)
.
Shadowed Implicit Value Members
- def +(other: String): String
- Implicit
- This member is added by an implicit conversion from FixedPoint toany2stringadd[FixedPoint] performed by method any2stringadd in scala.Predef.
- Shadowing
- This implicitly inherited member is shadowed by one or more members in this class.
To access this member you can use a type ascription:(fixedPoint: any2stringadd[FixedPoint]).+(other)
- Definition Classes
- any2stringadd
- def ===(rhs: FixedPoint): Bool
Dynamic recursive equality operator for generic Data
Dynamic recursive equality operator for generic Data
- Implicit
- This member is added by an implicit conversion from FixedPoint toDataEquality[FixedPoint] performed by method DataEquality in chisel3.Data.
- Shadowing
- This implicitly inherited member is shadowed by one or more members in this class.
To access this member you can use a type ascription:(fixedPoint: DataEquality[FixedPoint]).===(rhs)
- Definition Classes
- DataEquality
- Exceptions thrown
ChiselException
whenlhs
andrhs
are different types during elaboration time
Deprecated Value Members
- final macro def asFixedPoint(that: BinaryPoint): FixedPoint
Reinterpret this FixedPoint as a
FixedPoint
.Reinterpret this FixedPoint as a
FixedPoint
.- Definition Classes
- Bits
- Annotations
- @deprecated
- Deprecated
(Since version Chisel 3.6) this feature will not be supported as part of the migration to the MLIR-based FIRRTL Compiler (MFC). For more information about this migration, please see the Chisel ROADMAP.md.
- Note
The value is not guaranteed to be preserved. For example, a UInt of width 3 and value 7 (0b111) would become a
FixedPoint
with value -1. The interpretation of the number is also affected by the specified binary point. Caution is advised!
- final macro def asInterval(that: IntervalRange): Interval
Reinterpret cast as a Interval.
Reinterpret cast as a Interval.
- Definition Classes
- Bits
- Annotations
- @deprecated
- Deprecated
(Since version Chisel 3.6) this feature will not be supported as part of the migration to the MLIR-based FIRRTL Compiler (MFC). For more information about this migration, please see the Chisel ROADMAP.md.
- Note
value not guaranteed to be preserved: for example, an UInt of width 3 and value 7 (0b111) would become a FixedInt with value -1, the interpretation of the number is also affected by the specified binary point. Caution advised
- def finalize(): Unit
- Attributes
- protected[lang]
- Definition Classes
- AnyRef
- Annotations
- @throws(classOf[java.lang.Throwable]) @Deprecated
- Deprecated
- def formatted(fmtstr: String): String
- Implicit
- This member is added by an implicit conversion from FixedPoint toStringFormat[FixedPoint] performed by method StringFormat in scala.Predef.
- Definition Classes
- StringFormat
- Annotations
- @deprecated @inline()
- Deprecated
(Since version 2.12.16) Use
formatString.format(value)
instead ofvalue.formatted(formatString)
, or use thef""
string interpolator. In Java 15 and later,formatted
resolves to the new method in String which has reversed parameters.
- def litToBigDecimal: BigDecimal
Return the scala.math.BigDecimal value of this instance assuming it is a literal (convenience method)
Return the scala.math.BigDecimal value of this instance assuming it is a literal (convenience method)
- Definition Classes
- HasBinaryPoint
- Annotations
- @deprecated
- Deprecated
(Since version Chisel 3.6) this feature will not be supported as part of the migration to the MLIR-based FIRRTL Compiler (MFC). For more information about this migration, please see the Chisel ROADMAP.md.
- def litToBigDecimalOption: Option[BigDecimal]
Return the scala.math.BigDecimal value of this instance if it is a Literal
Return the scala.math.BigDecimal value of this instance if it is a Literal
- Definition Classes
- HasBinaryPoint
- Annotations
- @deprecated
- Deprecated
(Since version Chisel 3.6) this feature will not be supported as part of the migration to the MLIR-based FIRRTL Compiler (MFC). For more information about this migration, please see the Chisel ROADMAP.md.
- Note
this method may throw an exception if the literal value won't fit in a BigDecimal
- def litToDouble: Double
Return the double value of this instance assuming it is a literal (convenience method)
Return the double value of this instance assuming it is a literal (convenience method)
- Definition Classes
- HasBinaryPoint
- Annotations
- @deprecated
- Deprecated
(Since version Chisel 3.6) this feature will not be supported as part of the migration to the MLIR-based FIRRTL Compiler (MFC). For more information about this migration, please see the Chisel ROADMAP.md.
- def litToDoubleOption: Option[Double]
Return the
Double
value of this instance if it is a LiteralReturn the
Double
value of this instance if it is a Literal- Definition Classes
- HasBinaryPoint
- Annotations
- @deprecated
- Deprecated
(Since version Chisel 3.6) this feature will not be supported as part of the migration to the MLIR-based FIRRTL Compiler (MFC). For more information about this migration, please see the Chisel ROADMAP.md.
- Note
this method may throw an exception if the literal value won't fit in a Double
- def →[B](y: B): (FixedPoint, B)
- Implicit
- This member is added by an implicit conversion from FixedPoint toArrowAssoc[FixedPoint] performed by method ArrowAssoc in scala.Predef.
- Definition Classes
- ArrowAssoc
- Annotations
- @deprecated
- Deprecated
(Since version 2.13.0) Use
->
instead. If you still wish to display it as one character, consider using a font with programming ligatures such as Fira Code.
Inherited from HasBinaryPoint
Inherited from Num[FixedPoint]
Inherited from Bits
Inherited from ToBoolable
Inherited from Element
Inherited from Data
Inherited from SourceInfoDoc
Inherited from NamedComponent
Inherited from HasId
Inherited from InstanceId
Inherited from AnyRef
Inherited from Any
Inherited by implicit conversion DataEquality fromFixedPoint to DataEquality[FixedPoint]
Inherited by implicit conversion toConnectableDefault fromFixedPoint to Connectable[FixedPoint]
Inherited by implicit conversion ConnectableDefault fromFixedPoint to ConnectableDefault[FixedPoint]
Inherited by implicit conversion any2stringadd fromFixedPoint to any2stringadd[FixedPoint]
Inherited by implicit conversion StringFormat fromFixedPoint to StringFormat[FixedPoint]
Inherited by implicit conversion Ensuring fromFixedPoint to Ensuring[FixedPoint]
Inherited by implicit conversion ArrowAssoc fromFixedPoint to ArrowAssoc[FixedPoint]
Arithmetic
Arithmetic hardware operators
Bitwise
Bitwise hardware operators
Comparison
Comparison hardware operators
connection
Ungrouped
SourceInfoTransformMacro
These internal methods are not part of the public-facing API!
The equivalent public-facing methods do not have the do_
prefix or have the same name. Use and look at the
documentation for those. If you want left shift, use <<
, not do_<<
. If you want conversion to a
Seq of Bools look at the asBools
above, not the one below. Users can safely ignore
every method in this group!
🐉🐉🐉 Here be dragons... 🐉🐉🐉
These do_X
methods are used to enable both implicit passing of SourceInfo and chisel3.CompileOptions
while also supporting chained apply methods. In effect all "normal" methods that you, as a user, will use in your
designs, are converted to their "hidden", do_*
, via macro transformations. Without using macros here, only one
of the above wanted behaviors is allowed (implicit passing and chained applies)---the compiler interprets a
chained apply as an explicit 'implicit' argument and will throw type errors.
The "normal", public-facing methods then take no SourceInfo. However, a macro transforms this public-facing method
into a call to an internal, hidden do_*
that takes an explicit SourceInfo by inserting an
implicitly[SourceInfo]
as the explicit argument.
This is the documentation for Chisel.
Package structure
The chisel3 package presents the public API of Chisel. It contains the concrete core types
UInt
,SInt
,Bool
,FixedPoint
,Clock
, andReg
, the abstract typesBits
,Aggregate
, andData
, and the aggregate typesBundle
andVec
.The Chisel package is a compatibility layer that attempts to provide chisel2 compatibility in chisel3.
Utility objects and methods are found in the
util
package.The
testers
package defines the basic interface for chisel testers.