596 lines
21 KiB
Plaintext
596 lines
21 KiB
Plaintext
// Copyright (c) 2018-2020 Bluespec, Inc. All Rights Reserved.
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//
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//-
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// RVFI_DII + CHERI modifications:
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// Copyright (c) 2020 Alexandre Joannou
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// Copyright (c) 2020 Peter Rugg
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// Copyright (c) 2020 Jonathan Woodruff
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// All rights reserved.
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//
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// This software was developed by SRI International and the University of
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// Cambridge Computer Laboratory (Department of Computer Science and
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// Technology) under DARPA contract HR0011-18-C-0016 ("ECATS"), as part of the
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// DARPA SSITH research programme.
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//
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// This work was supported by NCSC programme grant 4212611/RFA 15971 ("SafeBet").
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//-
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package CoreW;
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// ================================================================
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// This package is called 'CoreW' for 'Core Wrapper'
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// and corresponds to 'Core' in Piccolo and Flute.
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//
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// Here in Toooba, we use the name 'CoreW' to avoid a name-clash with
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// an inner module called 'Core' in MIT's RISCY-OOO.
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//
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// The specific correspondence with Piccolo/Flute structure is:
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// Piccolo/Flute Toooba
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// mkCore mkCoreW
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// mkProc
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// mkCPU mkCore
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// This package defines:
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// Core_IFC
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// mkCore #(Core_IFC)
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//
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// mkCoreW instantiates:
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// - mkProc (the RISC-V CPU, a version of MIT's RISCY-OOO)
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// - mkPLIC_16_CoreNumX2_7
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// - mkTV_Encode (Tandem-Verification logic, optional: INCLUDE_TANDEM_VERIF)
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// - mkDebug_Module (RISC-V Debug Module, optional: INCLUDE_GDB_CONTROL)
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// and connects them all up.
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// ================================================================
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// BSV library imports
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import Vector :: *;
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import FIFO :: *;
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import FIFOF :: *;
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import GetPut :: *;
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import ClientServer :: *;
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import Connectable :: *;
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import Clocks :: *;
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// ----------------
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// BSV additional libs
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import Cur_Cycle :: *;
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import GetPut_Aux :: *;
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import Routable :: *;
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import AXI4 :: *;
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import AXI4Lite :: *;
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import SourceSink :: *;
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import TagControllerAXI :: *;
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import CacheCore :: *;
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// ================================================================
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// Project imports
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// ----------------
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// From RISCY-ooo
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import ProcTypes :: *;
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`ifdef PERFORMANCE_MONITORING
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import StatCounters::*;
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`endif
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// ----------------
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// From Toooba
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// Main fabric
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import Fabric_Defs :: *; // for Wd_Id, Wd_Addr, Wd_Data...
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import SoC_Map :: *;
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`ifdef INCLUDE_GDB_CONTROL
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import Debug_Module :: *;
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`endif
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import WindCoreInterface :: *;
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import Proc_IFC :: *;
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import Proc :: *;
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import PLIC :: *;
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import PLIC_16_CoreNumX2_7 :: *;
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`ifdef INCLUDE_TANDEM_VERIF
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import TV_Info :: *;
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import Trace_Data2 :: *;
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import TV_Encode :: *;
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import Trace_Data2_to_Trace_Data :: *;
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`endif
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// TV_Taps needed when both GDB_CONTROL and TANDEM_VERIF are present
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`ifdef INCLUDE_GDB_CONTROL
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`ifdef INCLUDE_TANDEM_VERIF
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import TV_Taps :: *;
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`endif
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`endif
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import DM_CPU_Req_Rsp ::*;
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// ================================================================
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// The Core module
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typedef WindCoreMid #( // AXI manager 0 port parameters
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TAdd#(Wd_MId,1), Wd_Addr, Wd_Data, 0, 0, 0, 0, 0
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// AXI manager 1 port parameters
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, TAdd#(Wd_MId,1), Wd_Addr, Wd_Data, 0, 0, 0, 0, 0
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// AXI subordinate 0 port parameters
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, 0, 0, 0, 0, 0, 0, 0, 0
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// Number of interrupt lines
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, t_n_irq) CoreW_IFC #(numeric type t_n_irq);
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//(* synthesize *)
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module mkCoreW (CoreW_IFC #(t_n_irq));
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Clock clk <- exposeCurrentClock;
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Reset rst <- exposeCurrentReset;
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let newRst <- mkReset (0, True, clk, reset_by rst);
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match {.otherRst, .ifc} <- mkCoreResetHelper ( rst
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, reset_by newRst.new_rst);
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rule rl_forward_debug_reset (otherRst);
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newRst.assertReset;
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endrule
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return ifc;
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endmodule
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// The interface to this module is a convenience to avoid exposing the reset
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// hacks to the nicer outer interface, and not have to use a large amount of
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// reset_by to decouple the debug module from the rest...
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module mkCoreResetHelper #(Reset toDbgReset)
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(Tuple2#(PulseWire, CoreW_IFC #(t_n_irq)));
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// ================================================================
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// Notes on 'reset'
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// This module's default reset (Verilog RST_N) is a
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// 'non-debug-module reset', or 'ndm-reset': it resets everything
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// in mkCoreW other than the optional RISC-V Debug Module (DM).
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// DM is reset ONLY by 'toDbgReset' (parameter of this module).
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// This is expected to be performed exactly once, on power-up.
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// Note: DM has an internal functionality that the DM spec calls
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// 'dm_reset'. This is not really an electrical reset, it is just
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// a module initializer wholly within the DM to put it into a
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// known state. To be able to do a dm_reset, the DM has to be
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// working already, at least to the point that it can field DMI
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// requests from the external debugger asking the DM to proform a
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// dm_reset.
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// DM can ask the environment to perform an 'ndm-reset', which the
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// environment does by asserting the default reset (RST_N). At the
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// same time, the environment may also reset part or all of the
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// rest of the SoC.
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// DM can also individually reset each hart in mkCPU.
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// 'hart' = hardware thread = independent PC and fetch-and-execute pipeline.
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// mkCPU (instantiated in this module) has one or more harts.
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// This hart-reset logic is entirely within this module.
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// ================================================================
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// The CPU's (hart's) reset is the ``or'' of the default reset
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// (power-on reset) and the Debug Module's 'hart_reset' control.
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let ndm_reset <- exposeCurrentReset;
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`ifdef INCLUDE_GDB_CONTROL
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let clk <- exposeCurrentClock;
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Bool initial_reset_val = False;
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Integer hart_reset_duration = 10; // NOTE: assuming 10 cycle reset enough for hart
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Vector #(CoreNum, MakeResetIfc) dm_harts_reset_controller <- replicateM(mkReset(hart_reset_duration, initial_reset_val, clk));
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function Reset proj_new_rst (MakeResetIfc x) = x.new_rst;
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let all_harts_reset <- foldlM (mkResetEither, ndm_reset, map (proj_new_rst, dm_harts_reset_controller));
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`else
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let all_harts_reset = ndm_reset;
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`endif
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// ================================================================
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// STATE
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// System address map
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SoC_Map_IFC soc_map <- mkSoC_Map;
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// RISCY-OOO processor
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// TODO: could have separate resets for each core.
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Proc_IFC proc <- mkProc (reset_by all_harts_reset);
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// handle uncached interface
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let proc_uncached = prepend_AXI4_Master_id (0, zero_AXI4_Master_user (proc.master1));
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// Bridge for uncached expernal bus transactions.
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let uncached_mem_shim <- mkAXI4ShimFF(reset_by all_harts_reset);
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// handle cached interface
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// AXI4 tagController
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TagControllerAXI#(Wd_MId, Wd_Addr, Wd_Data) tagController <- mkTagControllerAXI(reset_by all_harts_reset); // TODO double check if reseting like this is good enough
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mkConnection(proc.master0, tagController.slave, reset_by all_harts_reset);
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`ifdef PERFORMANCE_MONITORING
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rule report_tagController_events;
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EventsCacheCore cache_core_evts = tagController.events;
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EventsTGC evts = unpack(0);
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evts.evt_WRITE = zeroExtend(pack(cache_core_evts.evt_WRITE));
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evts.evt_WRITE_MISS = zeroExtend(pack(cache_core_evts.evt_WRITE_MISS));
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evts.evt_READ = zeroExtend(pack(cache_core_evts.evt_READ));
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evts.evt_READ_MISS = zeroExtend(pack(cache_core_evts.evt_READ_MISS));
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evts.evt_EVICT = zeroExtend(pack(cache_core_evts.evt_EVICT));
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`ifdef USECAP
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evts.evt_SET_TAG_WRITE = zeroExtend(pack(cache_core_evts.evt_SET_TAG_WRITE));
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evts.evt_SET_TAG_READ = zeroExtend(pack(cache_core_evts.evt_SET_TAG_READ));
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`endif
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proc.events_tgc(evts);
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endrule
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`endif
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// PLIC (Platform-Level Interrupt Controller)
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PLIC_IFC_16_CoreNumX2_7 plic <- mkPLIC_16_CoreNumX2_7;
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`ifdef INCLUDE_GDB_CONTROL
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// Debug Module
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Debug_Module_IFC debug_module <- mkDebug_Module (reset_by toDbgReset);
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`endif
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`ifdef INCLUDE_TANDEM_VERIF
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// The following are a superscalar-wide set of transformers from RISCY-OOO output Trace_Data2
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// to Trace_Data which is input to the TV encoder
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Vector #(SupSize, Trace_Data2_to_Trace_Data_IFC) v_td2_to_td <- replicateM (mkTrace_Data2_to_Trace_Data);
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// The TV encoder transforms Trace_Data structures from the CPU and DM
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// into encoded byte vectors for transmission to the Tandem Verifier
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TV_Encode_IFC tv_encode <- mkTV_Encode;
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`endif
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// ================================================================
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// Hart-reset from DM
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`ifdef INCLUDE_GDB_CONTROL
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Reg #(Bit #(8)) rg_harts_reset_delay <- mkReg (0);
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Reg #(Bit #(64)) rg_tohost_addr <- mkReg (0);
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Reg #(Bit #(64)) rg_fromhost_addr <- mkReg (0);
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for (Integer core = 0; core < valueOf(CoreNum); core = core + 1)
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rule rl_dm_harts_reset (rg_harts_reset_delay == 0);
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let x <- debug_module.harts_reset_client[core].request.get;
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dm_harts_reset_controller[core].assertReset;
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rg_harts_reset_delay <= fromInteger (hart_reset_duration + 200); // NOTE: heuristic
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$display ("%0d: %m.rl_dm_harts_reset: asserting harts reset for %0d cycles",
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cur_cycle, hart_reset_duration);
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endrule
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rule rl_dm_harts_reset_wait (rg_harts_reset_delay != 0);
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if (rg_harts_reset_delay == 1) begin
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let pc = soc_map_struct.pc_reset_value;
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Bool is_running = True;
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proc.start (is_running, pc, rg_tohost_addr, rg_fromhost_addr);
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// We reset all the harts, so we indicate this to the DM, even though it's possible only one hart was requested to reset
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for (Integer core = 0; core < valueOf(CoreNum); core = core + 1)
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debug_module.harts_reset_client[core].response.put (is_running);
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$display ("%0d: %m.rl_dm_harts_reset_wait: proc.start (pc %0h, tohostAddr %0h, fromhostAddr %0h",
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cur_cycle, pc, rg_tohost_addr, rg_fromhost_addr);
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end
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rg_harts_reset_delay <= rg_harts_reset_delay - 1;
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endrule
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`endif
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`ifdef INCLUDE_GDB_CONTROL
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// ================================================================
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// Direct DM-to-CPU connections for run-control and other misc requests
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mkConnection (debug_module.harts_client_run_halt, proc.harts_run_halt_server);
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mkConnection (debug_module.harts_get_other_req, proc.harts_put_other_req);
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`endif
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`ifdef INCLUDE_TANDEM_VERIF
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// ================================================================
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// Direct CPU-to-TV connections for TV trace data
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for (Integer j = 0; j < valueOf (SupSize); j = j + 1) begin
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// CPU Trace_Data2 output streams to Trace_Data2_to_Trace_Data converters
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mkConnection (proc.v_to_TV [j], v_td2_to_td [j].in);
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// Trace_Data2_to_Trace_Data converters to TV encoder
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mkConnection (v_td2_to_td [j].out, tv_encode.v_cpu_in [j]);
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end
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`endif
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`ifdef INCLUDE_GDB_CONTROL
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`ifdef INCLUDE_TANDEM_VERIF
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// ================================================================
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// BEGIN SECTION: DM and TV both present
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// We instantiate 'taps' into connections where DM writes CPU GPRs,
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// FPRs, CSRs, and main memory. The tap outputs go the TV encoder,
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// to keep the tandem verifier in sync with DM updates to the CPU.
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// Create a tap for DM's memory-writes to the bus, and merge-in the trace data.
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DM_Mem_Tap_IFC dm_mem_tap <- mkDM_Mem_Tap;
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mkConnection (debug_module.master, dm_mem_tap.slave);
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let dm_master_local = dm_mem_tap.master;
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rule rl_merge_dm_mem_trace_data;
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let tmp <- dm_mem_tap.trace_data_out.get;
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tv_encode.dm_in.put (tmp);
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endrule
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// Create a tap for DM's GPR writes to the CPU, and merge-in the trace data.
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DM_GPR_Tap_IFC dm_gpr_tap_ifc <- mkDM_GPR_Tap;
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mkConnection (debug_module.hart0_gpr_mem_client, dm_gpr_tap_ifc.server);
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mkConnection (dm_gpr_tap_ifc.client, proc.hart0_gpr_mem_server);
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rule rl_merge_dm_gpr_trace_data;
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let tmp <- dm_gpr_tap_ifc.trace_data_out.get;
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tv_encode.dm_in.put (tmp);
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endrule
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`ifdef ISA_F_OR_D
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// Create a tap for DM's FPR writes to the CPU, and merge-in the trace data.
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DM_FPR_Tap_IFC dm_fpr_tap_ifc <- mkDM_FPR_Tap;
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mkConnection (debug_module.hart0_fpr_mem_client, dm_fpr_tap_ifc.server);
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mkConnection (dm_fpr_tap_ifc.client, proc.hart0_fpr_mem_server);
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rule rl_merge_dm_fpr_trace_data;
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let tmp <- dm_fpr_tap_ifc.trace_data_out.get;
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tv_encode.dm_in.put (tmp);
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endrule
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`endif
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// for ifdef ISA_F_OR_D
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// Create a tap for DM's CSR writes, and merge-in the trace data.
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DM_CSR_Tap_IFC dm_csr_tap <- mkDM_CSR_Tap;
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mkConnection(debug_module.hart0_csr_mem_client, dm_csr_tap.server);
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mkConnection(dm_csr_tap.client, proc.hart0_csr_mem_server);
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rule rl_merge_dm_csr_trace_data;
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let tmp <- dm_csr_tap.trace_data_out.get;
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tv_encode.dm_in.put(tmp);
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endrule
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`ifdef ISA_F_OR_D
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(* descending_urgency = "rl_merge_dm_fpr_trace_data, rl_merge_dm_gpr_trace_data" *)
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`endif
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(* descending_urgency = "rl_merge_dm_gpr_trace_data, rl_merge_dm_csr_trace_data" *)
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(* descending_urgency = "rl_merge_dm_csr_trace_data, rl_merge_dm_mem_trace_data" *)
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rule rl_bogus_for_sched_attributes;
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endrule
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// END SECTION: DM and TV
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// ================================================================
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`else // of ifdef INCLUDE_TANDEM_VERIF
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// ================================================================
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// BEGIN SECTION: DM, no TV
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// Connect DM's GPR interface directly to CPU
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mkConnection (debug_module.harts_gpr_mem_client, proc.harts_gpr_mem_server);
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`ifdef ISA_F_OR_D
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// Connect DM's FPR interface directly to CPU
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mkConnection (debug_module.harts_fpr_mem_client, proc.harts_fpr_mem_server);
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`endif
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// Connect DM's CSR interface directly to CPU
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mkConnection (debug_module.harts_csr_mem_client, proc.harts_csr_mem_server);
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// DM's bus master is directly the bus master
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let dm_master_local = debug_module.master;
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// END SECTION: DM, no TV
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// ================================================================
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`endif // for ifdef INCLUDE_TANDEM_VERIF
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// ================================================================
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`else // for ifdef INCLUDE_GDB_CONTROL
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// ================================================================
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// BEGIN SECTION: no DM
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// No DM, so 'DM bus master' is AXI4 dummy
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let dm_master_local = culDeSac;
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`ifdef INCLUDE_TANDEM_VERIF
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// TV, no DM: stub out the dm input to TV
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Get #(Trace_Data) gs = getstub;
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mkConnection (tv_encode.dm_in, gs);
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`endif
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`endif // for ifdef INCLUDE_GDB_CONTROL
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// ================================================================
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// Connect the local 2x3 fabric
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// Masters on the local 2x3 fabric
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Vector#(Num_Masters_2x3, AXI4_Master #(Wd_MId_2x3, Wd_Addr, Wd_Data,
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Wd_AW_User, Wd_W_User, Wd_B_User,
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Wd_AR_User, Wd_R_User))
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master_vector = newVector;
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//let master_vector = newVector;
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master_vector[cpu_uncached_master_num] = proc_uncached;
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master_vector[debug_module_sba_master_num] = dm_master_local;
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// Slaves on the local 2x3 fabric
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// default slave is forwarded out directly to the Core interface
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Vector#(Num_Slaves_2x3, AXI4_Slave #(Wd_SId_2x3, Wd_Addr, Wd_Data,
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Wd_AW_User, Wd_W_User, Wd_B_User,
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Wd_AR_User, Wd_R_User))
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slave_vector = newVector;
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//let slave_vector = newVector;
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slave_vector[default_slave_num] = uncached_mem_shim.slave;
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slave_vector[llc_slave_num] = proc.debug_module_mem_server;
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slave_vector[plic_slave_num] = zero_AXI4_Slave_user (plic.axi4_slave);
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function Vector#(Num_Slaves_2x3, Bool) route_2x3 (Bit#(Wd_Addr) addr);
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Vector#(Num_Slaves_2x3, Bool) res = replicate(False);
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if (inRange(soc_map.m_mem0_controller_addr_range, addr))
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res[llc_slave_num] = True;
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else if (inRange(soc_map.m_plic_addr_range, addr))
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res[plic_slave_num] = True;
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else
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res[default_slave_num] = True;
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//Bit #(24) topBits = truncateLSB(addr); //XXX TODO Tag controller masks to 40 bits
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//if (topBits != 0) res = replicate(False);
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return res;
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endfunction
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mkAXI4Bus (route_2x3, master_vector, slave_vector);
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// ================================================================
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// Connect external interrupt lines from PLIC to CPU
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rule rl_relay_external_interrupts; // from PLIC
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Vector #(CoreNum, Bool) meips;
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Vector #(CoreNum, Bool) seips;
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for (Integer i = 0; i < valueof(CoreNum); i = i + 1) begin
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meips [i] = plic.v_targets [2 * i].m_eip;
|
|
seips [i] = plic.v_targets [2 * i + 1].m_eip;
|
|
end
|
|
|
|
proc.m_external_interrupt_req (meips);
|
|
proc.s_external_interrupt_req (seips);
|
|
endrule
|
|
|
|
// ================================================================
|
|
// Connect external debug module interface
|
|
|
|
let dbgShim <- mkAXI4LiteShim (reset_by toDbgReset);
|
|
|
|
rule rl_debug_module_read_req;
|
|
let arFlit <- get (dbgShim.master.ar);
|
|
debug_module.dmi.read_addr (truncate (arFlit.araddr >> 2));
|
|
endrule
|
|
rule rl_debug_module_read_rsp;
|
|
let x <- debug_module.dmi.read_data;
|
|
dbgShim.master.r.put(AXI4Lite_RFlit { rdata: x, rresp: OKAY, ruser: ?});
|
|
endrule
|
|
rule rl_debug_module_write_req;
|
|
let awFlit <- get (dbgShim.master.aw);
|
|
let wFlit <- get (dbgShim.master.w);
|
|
dbgShim.master.b.put(defaultValue);
|
|
debug_module.dmi.write (truncate (awFlit.awaddr >> 2), wFlit.wdata);
|
|
endrule
|
|
|
|
let fromDbgReset <- mkPulseWire (reset_by toDbgReset);
|
|
rule rl_debug_module_send_reset;
|
|
let _ <- debug_module.ndm_reset_client.request.get;
|
|
fromDbgReset.send;
|
|
endrule
|
|
|
|
// ================================================================
|
|
// Connect external interrupts to the PLIC and Proc
|
|
|
|
Vector #(t_n_irq, Reg #(Bool)) irq_reg
|
|
<- replicateM (mkReg (False));
|
|
Vector #(t_n_irq, Put #(Bool)) irq_ifc;
|
|
for (Integer i = 0; i < valueof (t_n_irq); i = i + 1) begin
|
|
irq_ifc [i] = interface Put;
|
|
method put = writeReg (irq_reg[i]);
|
|
endinterface;
|
|
rule rl_connect_irq;
|
|
plic.v_sources[i].m_interrupt_req (irq_reg[i]);
|
|
endrule
|
|
end
|
|
|
|
let nmirq_reg <- mkReg (False);
|
|
let nmirq_ifc = interface Put;
|
|
method put = writeReg (nmirq_reg);
|
|
endinterface;
|
|
rule rl_connect_nmirq;
|
|
// TODO: fixup; passing const False for now
|
|
//proc.non_maskable_interrupt_req (False);
|
|
proc.non_maskable_interrupt_req (nmirq_reg);
|
|
endrule
|
|
|
|
// ================================================================
|
|
// Connect other control and status signals
|
|
|
|
let f_ctrl_reqs <- mkFIFO1;
|
|
let f_ctrl_rsps <- mkFIFO1;
|
|
|
|
function do_release = action
|
|
plic.set_addr_map (zeroExtend (soc_map.m_plic_addr_range.base),
|
|
zeroExtend (rangeTop(soc_map.m_plic_addr_range)));
|
|
proc.start (True, soc_map_struct.pc_reset_value, 0, 0);
|
|
//proc.set_verbosity (verbosity);
|
|
endaction;
|
|
|
|
rule rl_ctrl_req;
|
|
case (f_ctrl_reqs.first) matches
|
|
tagged ReleaseReq: do_release;
|
|
tagged StatusReq: $display ("StatusReq not supported in Toooba");
|
|
endcase
|
|
f_ctrl_reqs.deq;
|
|
endrule
|
|
|
|
rule rl_ctrl_rsp;
|
|
f_ctrl_rsps.enq (StatusRsp(?));
|
|
endrule
|
|
|
|
// ================================================================
|
|
// INTERFACE
|
|
|
|
let ifc = interface CoreW_IFC;
|
|
// debug related signals
|
|
// ---------------------
|
|
interface debug_subordinate = dbgShim.slave;
|
|
|
|
// interrupt related signals
|
|
// -------------------------
|
|
interface irq = irq_ifc;
|
|
interface nmirq = nmirq_ifc;
|
|
|
|
// other control and status signals
|
|
// --------------------------------
|
|
interface controlStatusServer = toGPServer (f_ctrl_reqs, f_ctrl_rsps);
|
|
|
|
// memory interfaces
|
|
// -----------------
|
|
// Cached master to Fabric master interface
|
|
interface manager_0 = tagController.master;
|
|
// Uncached master to Fabric master interface
|
|
interface manager_1 =
|
|
extendIDFields (zeroMasterUserFields (uncached_mem_shim.master), 0);
|
|
// TODO:
|
|
interface subordinate_0 = culDeSac;
|
|
endinterface;
|
|
|
|
/*
|
|
`ifdef RVFI_DII
|
|
interface Toooba_RVFI_DII_Server rvfi_dii_server = proc.rvfi_dii_server;
|
|
`endif
|
|
|
|
`ifdef INCLUDE_TANDEM_VERIF
|
|
// ----------------------------------------------------------------
|
|
// Optional TV interface
|
|
|
|
interface Get tv_verifier_info_get;
|
|
method ActionValue #(Info_CPU_to_Verifier) get();
|
|
match { .n, .v } <- tv_encode.out.get;
|
|
return (Info_CPU_to_Verifier { num_bytes: n, vec_bytes: v });
|
|
endmethod
|
|
endinterface
|
|
`endif
|
|
*/
|
|
|
|
return tuple2 (fromDbgReset, ifc);
|
|
endmodule: mkCoreResetHelper
|
|
|
|
// ================================================================
|
|
// 2x3 Fabric for this Core
|
|
// Masters: CPU DMem, Debug Module System Bus Access, External access
|
|
|
|
// ----------------
|
|
// Fabric port numbers for masters
|
|
|
|
Master_Num_2x3 cpu_uncached_master_num = 0;
|
|
Master_Num_2x3 debug_module_sba_master_num = 1;
|
|
|
|
// ----------------
|
|
// Fabric port numbers for slaves
|
|
|
|
Slave_Num_2x3 default_slave_num = 0; // for I/O, uncached memory, etc.
|
|
Slave_Num_2x3 plic_slave_num = 1; // PLIC mem-mapped registers
|
|
Slave_Num_2x3 llc_slave_num = 2; // Normal cached memory (connects to coherent Last-Level Cache)
|
|
|
|
// ================================================================
|
|
|
|
endpackage
|