| # -*- coding: utf-8 -*- |
| # Copyright (c) 2016 Jason Lowe-Power |
| # All Rights Reserved. |
| # |
| # Redistribution and use in source and binary forms, with or without |
| # modification, are permitted provided that the following conditions are |
| # met: redistributions of source code must retain the above copyright |
| # notice, this list of conditions and the following disclaimer; |
| # redistributions in binary form must reproduce the above copyright |
| # notice, this list of conditions and the following disclaimer in the |
| # documentation and/or other materials provided with the distribution; |
| # neither the name of the copyright holders nor the names of its |
| # contributors may be used to endorse or promote products derived from |
| # this software without specific prior written permission. |
| # |
| # THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS |
| # "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT |
| # LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR |
| # A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT |
| # OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, |
| # SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT |
| # LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, |
| # DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY |
| # THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT |
| # (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE |
| # OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. |
| # |
| # Authors: Jason Lowe-Power |
| |
| import m5 |
| from m5.objects import * |
| from m5.util import convert |
| from .fs_tools import * |
| |
| |
| class MyRubySystem(System): |
| |
| def __init__(self, kernel, disk, mem_sys, num_cpus, TimingCPUModel, no_kvm=False): |
| super(MyRubySystem, self).__init__() |
| self._no_kvm = no_kvm |
| |
| self._host_parallel = True |
| |
| # Set up the clock domain and the voltage domain |
| self.clk_domain = SrcClockDomain() |
| self.clk_domain.clock = '2.3GHz' |
| self.clk_domain.voltage_domain = VoltageDomain() |
| |
| self.mem_ranges = [AddrRange(Addr('3GB')), # All data |
| AddrRange(0xC0000000, size=0x100000), # For I/0 |
| ] |
| |
| self.initFS(num_cpus) |
| |
| # Replace these paths with the path to your disk images. |
| # The first disk is the root disk. The second could be used for swap |
| # or anything else. |
| self.setDiskImages(disk, disk) |
| |
| # Change this path to point to the kernel you want to use |
| self.workload.object_file = kernel |
| # Options specified on the kernel command line |
| boot_options = ['earlyprintk=ttyS0', 'console=ttyS0', 'lpj=7999923', |
| 'root=/dev/hda1'] |
| |
| self.workload.command_line = ' '.join(boot_options) |
| |
| # Create the CPUs for our system. |
| self.createCPU(num_cpus,TimingCPUModel) |
| |
| self.createMemoryControllersDDR4() |
| |
| # Create the cache hierarchy for the system. |
| if mem_sys == 'MI_example': |
| from .MI_example_caches import MIExampleSystem |
| self.caches = MIExampleSystem() |
| elif mem_sys == 'MESI_Two_Level': |
| from .MESI_Two_Level import MESITwoLevelCache |
| self.caches = MESITwoLevelCache() |
| elif mem_sys == 'MOESI_CMP_directory': |
| from .MOESI_CMP_directory import MOESICMPDirCache |
| self.caches = MOESICMPDirCache() |
| self.caches.setup(self, self.cpu, self.mem_cntrls, |
| [self.pc.south_bridge.ide.dma, self.iobus.mem_side_ports], |
| self.iobus) |
| |
| if self._host_parallel: |
| # To get the KVM CPUs to run on different host CPUs |
| # Specify a different event queue for each CPU |
| for i,cpu in enumerate(self.cpu): |
| for obj in cpu.descendants(): |
| obj.eventq_index = 0 |
| cpu.eventq_index = i + 1 |
| |
| def getHostParallel(self): |
| return self._host_parallel |
| |
| def totalInsts(self): |
| return sum([cpu.totalInsts() for cpu in self.cpu]) |
| |
| def createCPUThreads(self, cpu): |
| for c in cpu: |
| c.createThreads() |
| |
| def createCPU(self, num_cpus, TimingCPUModel): |
| if self._no_kvm: |
| self.cpu = [AtomicSimpleCPU(cpu_id = i, switched_out = False) |
| for i in range(num_cpus)] |
| self.createCPUThreads(self.cpu) |
| self.mem_mode = 'timing' |
| |
| else: |
| # Note KVM needs a VM and atomic_noncaching |
| self.cpu = [X86KvmCPU(cpu_id = i) |
| for i in range(num_cpus)] |
| self.createCPUThreads(self.cpu) |
| self.kvm_vm = KvmVM() |
| self.mem_mode = 'atomic_noncaching' |
| |
| self.atomicCpu = [AtomicSimpleCPU(cpu_id = i, |
| switched_out = True) |
| for i in range(num_cpus)] |
| self.createCPUThreads(self.atomicCpu) |
| |
| self.detailed_cpu = [TimingCPUModel(cpu_id = i, |
| switched_out = True) |
| for i in range(num_cpus)] |
| |
| self.createCPUThreads(self.detailed_cpu) |
| |
| def switchCpus(self, old, new): |
| assert(new[0].switchedOut()) |
| m5.switchCpus(self, list(zip(old, new))) |
| |
| def setDiskImages(self, img_path_1, img_path_2): |
| disk0 = CowDisk(img_path_1) |
| disk2 = CowDisk(img_path_2) |
| self.pc.south_bridge.ide.disks = [disk0, disk2] |
| |
| def createMemoryControllersDDR4(self): |
| self._createMemoryControllers(1, DDR4_2400_16x4) |
| |
| def _createMemoryControllers(self, num, cls): |
| self.mem_cntrls = [ |
| MemCtrl(dram = cls(range = self.mem_ranges[0])) |
| for i in range(num) |
| ] |
| |
| def _createKernelMemoryController(self, cls): |
| return cls(range = self.mem_ranges[0], |
| port = self.membus.mem_side_ports) |
| |
| def initFS(self, cpus): |
| self.pc = Pc() |
| |
| self.workload = X86FsLinux() |
| |
| # North Bridge |
| self.iobus = IOXBar() |
| |
| # connect the io bus |
| # Note: pass in a reference to where Ruby will connect to in the future |
| # so the port isn't connected twice. |
| self.pc.attachIO(self.iobus, [self.pc.south_bridge.ide.dma]) |
| |
| self.intrctrl = IntrControl() |
| |
| ############################################### |
| |
| # Add in a Bios information structure. |
| self.workload.smbios_table.structures = [X86SMBiosBiosInformation()] |
| |
| # Set up the Intel MP table |
| base_entries = [] |
| ext_entries = [] |
| for i in range(cpus): |
| bp = X86IntelMPProcessor( |
| local_apic_id = i, |
| local_apic_version = 0x14, |
| enable = True, |
| bootstrap = (i ==0)) |
| base_entries.append(bp) |
| io_apic = X86IntelMPIOAPIC( |
| id = cpus, |
| version = 0x11, |
| enable = True, |
| address = 0xfec00000) |
| self.pc.south_bridge.io_apic.apic_id = io_apic.id |
| base_entries.append(io_apic) |
| pci_bus = X86IntelMPBus(bus_id = 0, bus_type='PCI ') |
| base_entries.append(pci_bus) |
| isa_bus = X86IntelMPBus(bus_id = 1, bus_type='ISA ') |
| base_entries.append(isa_bus) |
| connect_busses = X86IntelMPBusHierarchy(bus_id=1, |
| subtractive_decode=True, parent_bus=0) |
| ext_entries.append(connect_busses) |
| pci_dev4_inta = X86IntelMPIOIntAssignment( |
| interrupt_type = 'INT', |
| polarity = 'ConformPolarity', |
| trigger = 'ConformTrigger', |
| source_bus_id = 0, |
| source_bus_irq = 0 + (4 << 2), |
| dest_io_apic_id = io_apic.id, |
| dest_io_apic_intin = 16) |
| base_entries.append(pci_dev4_inta) |
| def assignISAInt(irq, apicPin): |
| assign_8259_to_apic = X86IntelMPIOIntAssignment( |
| interrupt_type = 'ExtInt', |
| polarity = 'ConformPolarity', |
| trigger = 'ConformTrigger', |
| source_bus_id = 1, |
| source_bus_irq = irq, |
| dest_io_apic_id = io_apic.id, |
| dest_io_apic_intin = 0) |
| base_entries.append(assign_8259_to_apic) |
| assign_to_apic = X86IntelMPIOIntAssignment( |
| interrupt_type = 'INT', |
| polarity = 'ConformPolarity', |
| trigger = 'ConformTrigger', |
| source_bus_id = 1, |
| source_bus_irq = irq, |
| dest_io_apic_id = io_apic.id, |
| dest_io_apic_intin = apicPin) |
| base_entries.append(assign_to_apic) |
| assignISAInt(0, 2) |
| assignISAInt(1, 1) |
| for i in range(3, 15): |
| assignISAInt(i, i) |
| self.workload.intel_mp_table.base_entries = base_entries |
| self.workload.intel_mp_table.ext_entries = ext_entries |
| |
| entries = \ |
| [ |
| # Mark the first megabyte of memory as reserved |
| X86E820Entry(addr = 0, size = '639kB', range_type = 1), |
| X86E820Entry(addr = 0x9fc00, size = '385kB', range_type = 2), |
| # Mark the rest of physical memory as available |
| X86E820Entry(addr = 0x100000, |
| size = '%dB' % (self.mem_ranges[0].size() - 0x100000), |
| range_type = 1), |
| ] |
| |
| # Reserve the last 16kB of the 32-bit address space for m5ops |
| entries.append(X86E820Entry(addr = 0xFFFF0000, size = '64kB', |
| range_type=2)) |
| |
| self.workload.e820_table.entries = entries |