fhdl/memory: First Cleanup/Re-organization pass.

- Reorganize a bit (move Memory initialization to Memory declaration block).
- Use f-strings.
- Add separators.
- Add comments.
This commit is contained in:
Florent Kermarrec 2021-10-28 09:48:58 +02:00
parent 70c5be6fb8
commit 71f8fc7cb5
1 changed files with 88 additions and 50 deletions

View File

@ -1,3 +1,10 @@
#
# This file is part of LiteX (Adapted from Migen for LiteX usage).
#
# This file is Copyright (c) 2013-2014 Sebastien Bourdeauducq <sb@m-labs.hk>
# This file is Copyright (c) 2021 Florent Kermarrec <florent@enjoy-digital.fr>
# SPDX-License-Identifier: BSD-2-Clause
from migen.fhdl.structure import *
from migen.fhdl.module import *
from migen.fhdl.bitcontainer import bits_for
@ -6,21 +13,22 @@ from migen.fhdl.verilog import _printexpr as verilog_printexpr
from migen.fhdl.specials import *
def memory_emit_verilog(memory, ns, add_data_file):
r = ""
# Helpers.
# --------
def gn(e):
if isinstance(e, Memory):
return ns.get_name(e)
else:
return verilog_printexpr(ns, e)[0]
# Parameters.
# -----------
adrbits = bits_for(memory.depth-1)
r += "reg [" + str(memory.width-1) + ":0] " \
+ gn(memory) \
+ "[0:" + str(memory.depth-1) + "];\n"
adr_regs = {}
data_regs = {}
# Ports Transformations.
# ----------------------
# https://github.com/enjoy-digital/litex/issues/1003
# FIXME: Verify behaviour with the different FPGA toolchains.
clocks = [port.clock for port in memory.ports]
@ -28,69 +36,99 @@ def memory_emit_verilog(memory, ns, add_data_file):
for port in memory.ports:
port.mode = READ_FIRST
# Memory Declaration/Initialization.
# ----------------------------------
r = f"reg [{memory.width-1}:0] {gn(memory)}[0:{memory.depth-1}];\n"
if memory.init is not None:
content = ""
formatter = f"{{:0{int(memory.width/4)}x}}\n"
for d in memory.init:
content += formatter.format(d)
memory_filename = add_data_file(f"{gn(memory)}.init", content)
r += "initial begin\n"
r += f"\t$readmemh(\"{memory_filename}\", {gn(memory)});\n"
r += "end\n\n"
# Port Intermediate Signals.
# --------------------------
for port in memory.ports:
if not port.async_read:
if port.mode == WRITE_FIRST:
# No Intermediate Signal for Async Read.
if port.async_read:
continue
# Create Address Register in Write-First mode.
if port.mode in [WRITE_FIRST]:
adr_reg = Signal(name_override="memadr")
r += "reg [" + str(adrbits-1) + ":0] " \
+ gn(adr_reg) + ";\n"
r += f"reg [{adrbits-1}:0] {gn(adr_reg)};\n"
adr_regs[id(port)] = adr_reg
else:
# Create Data Register in Read-First/No Change mode.
if port.mode in [READ_FIRST, NO_CHANGE]:
data_reg = Signal(name_override="memdat")
r += "reg [" + str(memory.width-1) + ":0] " \
+ gn(data_reg) + ";\n"
r += f"reg [{memory.width-1}:0] {gn(data_reg)};\n"
data_regs[id(port)] = data_reg
# Ports Write/Read Logic.
# -----------------------
for port in memory.ports:
r += "always @(posedge " + gn(port.clock) + ") begin\n"
r += f"always @(posedge {gn(port.clock)}) begin\n"
# Write Logic.
if port.we is not None:
# Split Write Logic when Granularity.
if port.we_granularity:
n = memory.width//port.we_granularity
for i in range(n):
m = i*port.we_granularity
M = (i+1)*port.we_granularity-1
sl = "[" + str(M) + ":" + str(m) + "]"
r += "\tif (" + gn(port.we) + "[" + str(i) + "])\n"
r += "\t\t" + gn(memory) + "[" + gn(port.adr) + "]" + sl + " <= " + gn(port.dat_w) + sl + ";\n"
sl = f"[{M}:{m}]"
r += f"\tif ({gn(port.we)}[{i}])\n"
r += f"\t\t{gn(memory)}[{gn(port.adr)}]{sl} <= {gn(port.dat_w)}{sl};\n"
# Else use common Write Logic.
else:
r += "\tif (" + gn(port.we) + ")\n"
r += "\t\t" + gn(memory) + "[" + gn(port.adr) + "] <= " + gn(port.dat_w) + ";\n"
r += f"\tif ({gn(port.we)})\n"
r += f"\t\t{gn(memory)}[{gn(port.adr)}] <= {gn(port.dat_w)};\n"
# Read Logic.
if not port.async_read:
if port.mode == WRITE_FIRST:
rd = "\t" + gn(adr_regs[id(port)]) + " <= " + gn(port.adr) + ";\n"
else:
bassign = gn(data_regs[id(port)]) + " <= " + gn(memory) + "[" + gn(port.adr) + "];\n"
# In Write-First mode, Read from Address Register.
if port.mode in [WRITE_FIRST]:
rd = f"\t{gn(adr_regs[id(port)])} <= {gn(port.adr)};\n"
# In Write-First/No Change mode:
if port.mode in [READ_FIRST, NO_CHANGE]:
bassign = f"{gn(data_regs[id(port)])} <= {gn(memory)} [{gn(port.adr)}];\n"
# Always Read in Read-First mode.
if port.mode == READ_FIRST:
rd = "\t" + bassign
rd = f"\t{bassign}"
# Only Read in No-Change mode when no Write.
elif port.mode == NO_CHANGE:
rd = "\tif (!" + gn(port.we) + ")\n" \
+ "\t\t" + bassign
rd = f"\tif (!{gn(port.we)})\n\t\t{bassign}"
# Add Read-Enable Logic.
if port.re is None:
r += rd
else:
r += "\tif (" + gn(port.re) + ")\n"
r += f"\tif ({gn(port.re)})\n"
r += "\t" + rd.replace("\n\t", "\n\t\t")
r += "end\n\n"
# Ports Read Mapping.
# -------------------
for port in memory.ports:
# Direct (Asynchronous) Read on Async-Read mode.
if port.async_read:
r += "assign " + gn(port.dat_r) + " = " + gn(memory) + "[" + gn(port.adr) + "];\n"
else:
if port.mode == WRITE_FIRST:
r += "assign " + gn(port.dat_r) + " = " + gn(memory) + "[" + gn(adr_regs[id(port)]) + "];\n"
else:
r += "assign " + gn(port.dat_r) + " = " + gn(data_regs[id(port)]) + ";\n"
r += f"assign {gn(port.dat_r)} = {gn(memory)}[{gn(port.adr)}];\n"
continue
# Write-First mode: Do Read through Address Register.
if port.mode in [WRITE_FIRST]:
r += f"assign {gn(port.dat_r)} = {gn(memory)}[{gn(adr_regs[id(port)])}];\n"
# Read-First/No-Change mode: Data already Read on Data Register.
if port.mode in [READ_FIRST, NO_CHANGE]:
r += f"assign {gn(port.dat_r)} = {gn(data_regs[id(port)])};\n"
r += "\n"
if memory.init is not None:
content = ""
formatter = "{:0" + str(int(memory.width / 4)) + "X}\n"
for d in memory.init:
content += formatter.format(d)
memory_filename = add_data_file(gn(memory) + ".init", content)
r += "initial begin\n"
r += "\t$readmemh(\"" + memory_filename + "\", " + gn(memory) + ");\n"
r += "end\n\n"
return r