import os, struct from operator import itemgetter from math import ceil from migen.fhdl.std import * from migen.bank import csrgen from migen.bus import wishbone, csr, wishbone2csr from misoclib.com.uart.phy import UARTPHY from misoclib.com import uart from misoclib.cpu import CPU, lm32, mor1kx from misoclib.cpu.peripherals import identifier, timer def mem_decoder(address, start=26, end=29): return lambda a: a[start:end] == ((address >> (start+2)) & (2**(end-start))-1) class SoC(Module): csr_map = { "crg": 0, # user "uart_phy": 1, # provided by default (optional) "uart": 2, # provided by default (optional) "identifier": 3, # provided by default (optional) "timer0": 4, # provided by default (optional) "buttons": 5, # user "leds": 6, # user } interrupt_map = { "uart": 0, "timer0": 1, } mem_map = { "rom": 0x00000000, # (shadow @0x80000000) "sram": 0x10000000, # (shadow @0x90000000) "sdram": 0x40000000, # (shadow @0xc0000000) "csr": 0x60000000, # (shadow @0xe0000000) } def __init__(self, platform, clk_freq, cpu_or_bridge=None, with_cpu=True, cpu_type="lm32", cpu_reset_address=0x00000000, cpu_boot_file="software/bios/bios.bin", with_rom=False, rom_size=0x8000, with_sram=True, sram_size=4096, with_sdram=False, sdram_size=64*1024, with_csr=True, csr_data_width=8, csr_address_width=14, with_uart=True, uart_baudrate=115200, with_identifier=True, with_timer=True): self.platform = platform self.clk_freq = clk_freq self.cpu_or_bridge = cpu_or_bridge self.with_cpu = with_cpu self.cpu_type = cpu_type if with_rom: self.cpu_reset_address = 0 else: self.cpu_reset_address = cpu_reset_address self.cpu_boot_file = cpu_boot_file self.with_rom = with_rom self.rom_size = rom_size self.with_sram = with_sram self.sram_size = sram_size self.with_sdram = with_sdram self.sdram_size = sdram_size self.with_uart = with_uart self.uart_baudrate = uart_baudrate self.with_identifier = with_identifier self.with_csr = with_csr self.csr_data_width = csr_data_width self.csr_address_width = csr_address_width self.memory_regions = [] self.csr_regions = [] # list of (name, origin, busword, csr_list/Memory) self._wb_masters = [] self._wb_slaves = [] if with_cpu: if cpu_type == "lm32": self.submodules.cpu = lm32.LM32(platform, self.cpu_reset_address) elif cpu_type == "or1k": self.submodules.cpu = mor1kx.MOR1KX(platform, self.cpu_reset_address) else: raise ValueError("Unsupported CPU type: "+cpu_type) self.cpu_or_bridge = self.cpu self._wb_masters += [self.cpu.ibus, self.cpu.dbus] if with_rom: self.submodules.rom = wishbone.SRAM(rom_size, read_only=True) self.register_rom(self.rom.bus, rom_size) if with_sram: self.submodules.sram = wishbone.SRAM(sram_size) self.register_mem("sram", self.mem_map["sram"], self.sram.bus, sram_size) if with_sdram: self.submodules.sdram = wishbone.SRAM(sdram_size) self.register_mem("sdram", self.mem_map["sdram"], self.sdram.bus, sdram_size) elif cpu_or_bridge is not None and not isinstance(cpu_or_bridge, CPU): self._wb_masters += [cpu_or_bridge.wishbone] if with_csr: self.submodules.wishbone2csr = wishbone2csr.WB2CSR(bus_csr=csr.Interface(csr_data_width, csr_address_width)) self.register_mem("csr", self.mem_map["csr"], self.wishbone2csr.wishbone) if with_uart: self.submodules.uart_phy = UARTPHY(platform.request("serial"), clk_freq, uart_baudrate) self.submodules.uart = uart.UART(self.uart_phy) if with_identifier: platform_id = 0x554E if not hasattr(platform, "identifier") else platform.identifier self.submodules.identifier = identifier.Identifier(platform_id, int(clk_freq)) if with_timer: self.submodules.timer0 = timer.Timer() def init_rom(self, data): self.rom.mem.init = data def add_wb_master(self, wbm): if self.finalized: raise FinalizeError self._wb_masters.append(wbm) def add_wb_slave(self, address_decoder, interface): if self.finalized: raise FinalizeError self._wb_slaves.append((address_decoder, interface)) def check_memory_region(self, name, origin): for n, o, l in self.memory_regions: if n == name or o == origin: raise ValueError("Memory region conflict between {} and {}".format(n, name)) def add_memory_region(self, name, origin, length): self.check_memory_region(name, origin) self.memory_regions.append((name, origin, length)) def register_mem(self, name, address, interface, size=None): self.add_wb_slave(mem_decoder(address), interface) if size is not None: self.add_memory_region(name, address, size) def register_rom(self, interface, rom_size=0xa000): self.add_wb_slave(mem_decoder(self.mem_map["rom"]), interface) self.add_memory_region("rom", self.cpu_reset_address, rom_size) def check_csr_region(self, name, origin): for n, o, l, obj in self.csr_regions: if n == name or o == origin: raise ValueError("CSR region conflict between {} and {}".format(n, name)) def add_csr_region(self, name, origin, busword, obj): self.check_csr_region(name, origin) self.csr_regions.append((name, origin, busword, obj)) def do_finalize(self): registered_mems = [regions[0] for regions in self.memory_regions] if isinstance(self.cpu_or_bridge, CPU): for mem in ["rom", "sram"]: if mem not in registered_mems: raise FinalizeError("CPU needs a {} to be registered with SoC.register_mem()".format(mem)) # Wishbone self.submodules.wishbonecon = wishbone.InterconnectShared(self._wb_masters, self._wb_slaves, register=True) # CSR if self.with_csr: self.submodules.csrbankarray = csrgen.BankArray(self, lambda name, memory: self.csr_map[name if memory is None else name + "_" + memory.name_override], data_width=self.csr_data_width, address_width=self.csr_address_width) self.submodules.csrcon = csr.Interconnect(self.wishbone2csr.csr, self.csrbankarray.get_buses()) for name, csrs, mapaddr, rmap in self.csrbankarray.banks: self.add_csr_region(name, self.mem_map["csr"]+0x80000000+0x800*mapaddr, flen(rmap.bus.dat_w), csrs) for name, memory, mapaddr, mmap in self.csrbankarray.srams: self.add_csr_region(name, self.mem_map["csr"]+0x80000000+0x800*mapaddr, flen(rmap.bus.dat_w), memory) # Interrupts if hasattr(self.cpu_or_bridge, "interrupt"): for k, v in sorted(self.interrupt_map.items(), key=itemgetter(1)): if hasattr(self, k): self.comb += self.cpu_or_bridge.interrupt[v].eq(getattr(self, k).ev.irq) def ns(self, t, margin=True): clk_period_ns = 1000000000/self.clk_freq if margin: t += clk_period_ns/2 return ceil(t/clk_period_ns) def do_exit(self, vns): pass