upsilon/gateware/swic.py

369 lines
14 KiB
Python

# Copyright 2023-2024 (C) Peter McGoron
#
# This file is a part of Upsilon, a free and open source software project.
# For license terms, refer to the files in `doc/copying` in the Upsilon
# source distribution.
# XXX: PicoRV32 code only handles word-sized registers correctly. Memory
# regions made up of multiple words are not supported right now.
from migen import *
from litex.soc.interconnect.csr import CSRStorage, CSRStatus
from litex.soc.interconnect.wishbone import Interface, SRAM, Decoder
from litex.gen import LiteXModule
from region import *
class PreemptiveInterface(LiteXModule):
""" A preemptive interface is a manually controlled Wishbone interface
that stands between multiple masters (potentially interconnects) and a
single slave. A master controls which master (or interconnect) has access
to the slave. This is to avoid bus contention by having multiple buses.
To use this module, instantiate it. Then connect the controlling master
to ``self.buses[0]``. Connect the other masters to ``self.buses[1]``, etc.
Since the buses are seperate, origins don't have to be the same, but the
size of the region will be the same as the slave interface.
"""
def __init__(self, masters_len, slave, addressing="word"):
"""
:param masters_len: The amount of buses accessing this slave. This number
must be greater than one.
:param slave: The slave device. This object must have an Interface object
accessable as ``bus``.
:param addressing: Addressing style of the slave. Default is "word". Note
that masters may have to convert when selecting self.buses.
"""
assert masters_len > 1
self.buses = []
self.master_select = CSRStorage(masters_len, name='master_select', description='RW bitstring of which master interconnect to connect to')
self.slave = slave
for i in range(masters_len):
# Add the slave interface each master interconnect sees.
self.buses.append(Interface(data_width=32, address_width=32, addressing=addressing))
"""
Construct a combinatorial case statement. In verilog, the case
statment would look like
always @ (*) case (master_select)
1: begin
// Assign slave to master 1,
// Assign all other masters to dummy ports
end
2: begin
// Assign slave to master 2,
// Assign all other masters to dummy ports
end
// more cases:
default: begin
// assign slave to master 0
// Assign all other masters to dummy ports
end
Case statement is a dictionary, where each key is either the
number to match or "default", which is the default case.
Avoiding latches:
Left hand sign (assignment) is always an input.
"""
def assign_for_case(current_case):
asn = [ ]
for j in range(masters_len):
if current_case == j:
""" Assign all inputs (for example, slave reads addr
from master) to outputs. """
asn += [
self.slave.bus.adr.eq(self.buses[j].adr),
self.slave.bus.dat_w.eq(self.buses[j].dat_w),
self.slave.bus.cyc.eq(self.buses[j].cyc),
self.slave.bus.stb.eq(self.buses[j].stb),
self.slave.bus.we.eq(self.buses[j].we),
self.slave.bus.sel.eq(self.buses[j].sel),
self.buses[j].dat_r.eq(self.slave.bus.dat_r),
self.buses[j].ack.eq(self.slave.bus.ack),
]
else:
""" Master bus will always read 0 when they are not
selected, and writes are ignored. They will still
get a response to avoid timeouts. """
asn += [
self.buses[j].dat_r.eq(0),
self.buses[j].ack.eq(self.buses[j].cyc & self.buses[j].stb),
]
return asn
cases = {"default": assign_for_case(0)}
for i in range(1, masters_len):
cases[i] = assign_for_case(i)
self.comb += Case(self.master_select.storage, cases)
class SpecialRegister:
""" Special registers used for small bits of communiciation. """
def __init__(self, name, direction, width):
"""
:param name: Name of the register, seen in mmio.py.
:param direction: One of "PR" (pico-read main-write) or "PW" (pico-write main-read).
:param width: Width in bits, from 0 exclusive to 32 inclusive.
"""
assert direction in ["PR", "PW"]
assert 0 < width and width <= 32
self.name = name
self.direction = direction
self.width = width
def from_tuples(*tuples):
return [SpecialRegister(*args) for args in tuples]
class RegisterInterface(LiteXModule):
""" Defines "registers" that are either exclusively CPU-write Pico-read
or CPU-read pico-write. These registers are stored as flip-flops. """
def __init__(self, registers):
"""
:param registers: List of instances of SpecialRegister.
"""
self.picobus = Interface(data_width = 32, address_width = 32, addressing="byte")
self.mainbus = Interface(data_width = 32, address_width = 32, addressing="byte")
pico_case = {"default": self.picobus.dat_r.eq(0xFACADE)}
main_case = {"default": self.picobus.dat_r.eq(0xEDACAF)}
# Tuple list of (SpecialRegister, offset)
self.registers = []
for num, reg in enumerate(registers):
self.registers.append((reg, num*0x4))
# Round up the width of the stored signal to a multiple of 8.
wid = round_up_to_word(reg.width)
sig = Signal(wid)
def make_write_case(target_bus):
""" Function to handle write selection for ``target_bus``. """
writes = []
if wid >= 8:
writes.append(If(target_bus.sel[0],
sig[0:8].eq(target_bus.dat_w[0:8])))
if wid >= 16:
writes.append(If(target_bus.sel[1],
sig[8:16].eq(target_bus.dat_w[8:16])))
if wid >= 32:
writes.append(If(target_bus.sel[2],
sig[16:24].eq(target_bus.dat_w[16:24])))
writes.append(If(target_bus.sel[3],
sig[24:32].eq(target_bus.dat_w[24:32])))
return writes
if reg.direction == "PR":
pico_case[num*4] = self.picobus.dat_r.eq(sig)
main_case[num*4] = If(self.mainbus.we,
*make_write_case(self.mainbus)).Else(
self.mainbus.dat_r.eq(sig))
else:
main_case[num*4] = self.mainbus.dat_r.eq(sig)
pico_case[num*4] = If(self.picobus.we,
*make_write_case(self.picobus)).Else(
self.picobus.dat_r.eq(sig))
self.width = round_up_to_pow_2(len(registers)*0x4)
# Since array indices are exclusive in python (unlike in Verilog),
# use the bit length of the power of 2, not the bit length of the
# maximum addressable value.
bitlen = self.width.bit_length()
def bus_logic(bus, cases):
self.sync += If(bus.cyc & bus.stb & ~bus.ack,
Case(bus.adr[0:bitlen], cases),
bus.ack.eq(1)
).Elif(~bus.cyc,
bus.ack.eq(0))
bus_logic(self.mainbus, main_case)
bus_logic(self.picobus, pico_case)
# Generate addresses
self.public_registers = {}
for reg, off in self.public_registers:
self.addresses[reg.name] = {
"width" : reg.width,
"direction" : reg.direction,
"offset": off
}
class RegisterRead(LiteXModule):
pico_registers = {
"ra", "sp", "gp", "tp", "t0", "t1", "t2", "s0", "t1", "t2",
"s0/fp", "s1", "a0", "a1", "a2", "a3", "a4", "a5", "a6", "a7", "s2",
"s3", "s4", "s5", "s6", "s7", "t3", "t4", "t5", "t6",
}
public_registers = {name: {"origin" : num * 4, "width" : 4, "rw": False} for num, name in enumerate(pico_registers)}
""" Inspect PicoRV32 registers via Wishbone bus. """
def __init__(self):
self.regs = [Signal(32) for i in range(1,32)]
self.bus = Interface(data_width = 32, address_width = 32, addressing="byte")
self.width = 0x100
cases = {"default": self.bus.dat_r.eq(0xdeaddead)}
for i, reg in enumerate(self.regs):
cases[i*0x4] = self.bus.dat_r.eq(reg)
# CYC -> transfer in progress
# STB -> data is valid on the input lines
self.sync += [
If(self.bus.cyc & self.bus.stb & ~self.bus.ack,
Case(self.bus.adr[0:7], cases),
self.bus.ack.eq(1),
).Elif(self.bus.cyc != 1,
self.bus.ack.eq(0)
)
]
def gen_pico_header(pico_name):
""" Generate PicoRV32 C header for this CPU from JSON file. """
import json
with open(pico_name + "_mmio.h", "wt") as out:
print('#pragma once', file=out)
with open(pico_name + ".json") as f:
js = json.load(f)
for region in js:
if js[region]["registers"] is None:
continue
origin = js[region]["origin"]
for reg in js[region]["registers"]:
macname = f"{region}_{reg}".upper()
loc = origin + js[region]["registers"][reg]["origin"]
print(f"#define {macname} (volatile uint32_t *)({loc})", file=out)
# Parts of this class come from LiteX.
#
# Copyright (c) 2016-2019 Florent Kermarrec <florent@enjoy-digital.fr>
# Copyright (c) 2018 Sergiusz Bazanski <q3k@q3k.org>
# Copyright (c) 2019 Antmicro <www.antmicro.com>
# Copyright (c) 2019 Tim 'mithro' Ansell <me@mith.ro>
# Copyright (c) 2018 William D. Jones <thor0505@comcast.net>
# SPDX-License-Identifier: BSD-2-Clause
class PicoRV32(LiteXModule):
def add_cl_params(self, origin, dumpname):
""" Add parameter region for control loop variables. Dumps the
region information to a JSON file `dumpname`.
:param origin: Origin of the region for the PicoRV32.
:param dumpname: File to dump offsets within the region (common to
both Pico and Main CPU).
:return: Parameter module (used for accessing metadata).
"""
params = RegisterInterface(
SpecialRegister.from_tuples(
("cl_I", "PR", 32),
("cl_P", "PR", 32),
("deltaT", "PR", 32),
("setpt", "PR", 32),
("zset", "PW", 32),
("zpos", "PW", 32),
))
self.add_module("cl_params", params)
self.mmap.add_region("cl_params", BasicRegion(origin, params.width, params.picobus, params.public_registers))
return params
def __init__(self, name, start_addr=0x10000, irq_addr=0x10010, stackaddr=0x100FF):
self.name = name
self.masterbus = Interface(data_width=32, address_width=32, addressing="byte")
self.mmap = MemoryMap(self.masterbus)
self.resetpin = CSRStorage(1, name="enable", description="PicoRV32 enable")
self.trap = CSRStatus(8, name="trap", description="Trap condition")
self.d_adr = CSRStatus(32)
self.d_dat_w = CSRStatus(32)
self.dbg_insn_addr = CSRStatus(32)
self.dbg_insn_opcode = CSRStatus(32)
self.debug_reg_read = RegisterRead()
reg_args = {}
for i in range(1,32):
reg_args[f"o_dbg_reg_x{i}"] = self.debug_reg_read.regs[i-1]
mem_valid = Signal()
mem_instr = Signal()
mem_ready = Signal()
mem_addr = Signal(32)
mem_wdata = Signal(32)
mem_wstrb = Signal(4)
mem_rdata = Signal(32)
self.comb += [
self.masterbus.adr.eq(mem_addr),
self.masterbus.dat_w.eq(mem_wdata),
self.masterbus.we.eq(mem_wstrb != 0),
self.masterbus.sel.eq(mem_wstrb),
self.masterbus.cyc.eq(mem_valid),
self.masterbus.stb.eq(mem_valid),
self.masterbus.cti.eq(0),
self.masterbus.bte.eq(0),
mem_ready.eq(self.masterbus.ack),
mem_rdata.eq(self.masterbus.dat_r),
]
self.comb += [
self.d_adr.status.eq(mem_addr),
self.d_dat_w.status.eq(mem_wdata),
]
self.specials += Instance("picorv32",
p_COMPRESSED_ISA = 1,
p_ENABLE_MUL = 1,
p_REGS_INIT_ZERO = 1,
p_PROGADDR_RESET=start_addr,
p_PROGADDR_IRQ =irq_addr,
p_STACKADDR = stackaddr,
o_trap = self.trap.status,
o_mem_valid = mem_valid,
o_mem_instr = mem_instr,
i_mem_ready = mem_ready,
o_mem_addr = mem_addr,
o_mem_wdata = mem_wdata,
o_mem_wstrb = mem_wstrb,
i_mem_rdata = mem_rdata,
i_clk = ClockSignal(),
i_resetn = self.resetpin.storage,
o_mem_la_read = Signal(),
o_mem_la_write = Signal(),
o_mem_la_addr = Signal(32),
o_mem_la_wdata = Signal(32),
o_mem_la_wstrb = Signal(4),
o_pcpi_valid = Signal(),
o_pcpi_insn = Signal(32),
o_pcpi_rs1 = Signal(32),
o_pcpi_rs2 = Signal(32),
i_pcpi_wr = 0,
i_pcpi_wait = 0,
i_pcpi_rd = 0,
i_pcpi_ready = 0,
i_irq = 0,
o_eoi = Signal(32),
o_trace_valid = Signal(),
o_trace_data = Signal(36),
o_dbg_insn_addr = self.dbg_insn_addr.status,
o_dbg_insn_opcode = self.dbg_insn_opcode.status,
**reg_args
)
def do_finalize(self):
self.mmap.dump_mmap(self.name + ".json")
gen_pico_header(self.name)
self.mmap.finalize()