// See LICENSE for license details. package uncore.tilelink2 import Chisel._ class TLRegisterNode(address: AddressSet, concurrency: Option[Int] = None, beatBytes: Int = 4) extends TLManagerNode(beatBytes, TLManagerParameters( address = Seq(address), supportsGet = TransferSizes(1, beatBytes), supportsPutPartial = TransferSizes(1, beatBytes), supportsPutFull = TransferSizes(1, beatBytes), fifoId = Some(0))) // requests are handled in order { require (!address.strided) // Calling this method causes the matching TL2 bundle to be // configured to route all requests to the listed RegFields. def regmap(mapping: RegField.Map*) = { val a = bundleIn(0).a val d = bundleIn(0).d val edge = edgesIn(0) // Please forgive me ... val baseEnd = 0 val (sizeEnd, sizeOff) = (edge.bundle.sizeBits + baseEnd, baseEnd) val (sourceEnd, sourceOff) = (edge.bundle.sourceBits + sizeEnd, sizeEnd) val (addrLoEnd, addrLoOff) = (log2Ceil(beatBytes) + sourceEnd, sourceEnd) val params = RegMapperParams(log2Up(address.mask+1), beatBytes, addrLoEnd) val in = Wire(Decoupled(new RegMapperInput(params))) in.bits.read := a.bits.opcode === TLMessages.Get in.bits.index := a.bits.addr_hi in.bits.data := a.bits.data in.bits.mask := a.bits.mask in.bits.extra := Cat(edge.addr_lo(a.bits), a.bits.source, a.bits.size) // Invoke the register map builder val (endIndex, out) = RegMapper(beatBytes, concurrency, in, mapping:_*) // All registers must fit inside the device address space require (address.mask >= (endIndex-1)*beatBytes) // No flow control needed in.valid := a.valid a.ready := in.ready d.valid := out.valid out.ready := d.ready // We must restore the size and addr_lo to enable width adapters to work d.bits := edge.AccessAck( fromAddress = out.bits.extra(addrLoEnd-1, addrLoOff), fromSink = UInt(0), // our unique sink id toSource = out.bits.extra(sourceEnd-1, sourceOff), lgSize = out.bits.extra(sizeEnd-1, sizeOff)) // avoid a Mux on the data bus by manually overriding two fields d.bits.data := out.bits.data d.bits.opcode := Mux(out.bits.read, TLMessages.AccessAckData, TLMessages.AccessAck) // Tie off unused channels bundleIn(0).b.valid := Bool(false) bundleIn(0).c.ready := Bool(true) bundleIn(0).e.ready := Bool(true) } } object TLRegisterNode { def apply(address: AddressSet, concurrency: Option[Int] = None, beatBytes: Int = 4) = new TLRegisterNode(address, concurrency, beatBytes) } // These convenience methods below combine to make it possible to create a TL2 // register mapped device from a totally abstract register mapped device. // See GPIO.scala in this directory for an example abstract class TLRegisterRouterBase(address: AddressSet, interrupts: Int, concurrency: Option[Int], beatBytes: Int) extends LazyModule { val node = TLRegisterNode(address, concurrency, beatBytes) val intnode = IntSourceNode(name + s" @ ${address.base}", interrupts) } case class TLRegBundleArg(interrupts: Vec[Vec[Bool]], in: Vec[TLBundle]) class TLRegBundleBase(arg: TLRegBundleArg) extends Bundle { val interrupts = arg.interrupts val in = arg.in } class TLRegBundle[P](val params: P, arg: TLRegBundleArg) extends TLRegBundleBase(arg) class TLRegModule[P, B <: TLRegBundleBase](val params: P, bundleBuilder: => B, router: TLRegisterRouterBase) extends LazyModuleImp(router) with HasRegMap { val io = bundleBuilder val interrupts = if (io.interrupts.isEmpty) Vec(0, Bool()) else io.interrupts(0) def regmap(mapping: RegField.Map*) = router.node.regmap(mapping:_*) } class TLRegisterRouter[B <: TLRegBundleBase, M <: LazyModuleImp] (base: BigInt, interrupts: Int = 0, size: BigInt = 4096, concurrency: Option[Int] = None, beatBytes: Int = 4) (bundleBuilder: TLRegBundleArg => B) (moduleBuilder: (=> B, TLRegisterRouterBase) => M) extends TLRegisterRouterBase(AddressSet(base, size-1), interrupts, concurrency, beatBytes) { require (size % 4096 == 0) // devices should be 4K aligned require (isPow2(size)) require (size >= 4096) lazy val module = moduleBuilder(bundleBuilder(TLRegBundleArg(intnode.bundleOut, node.bundleIn)), this) }