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/* sim.cfg -- Simulator configuration script file

   Copyright (C) 2001-2002, Marko Mlinar, markom@opencores.org

This file is part of OpenRISC 1000 Architectural Simulator.

It contains the default configuration and help about configuring

the simulator.

This program is free software; you can redistribute it and/or modify

it under the terms of the GNU General Public License as published by

the Free Software Foundation; either version 2 of the License, or

(at your option) any later version.

This program is distributed in the hope that it will be useful,

but WITHOUT ANY WARRANTY; without even the implied warranty of

MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the

GNU General Public License for more details.

You should have received a copy of the GNU General Public License

along with this program; if not, write to the Free Software

Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. */

/* INTRODUCTION

   The ork1sim has various parameters, that are set in configuration files

   like this one. The user can switch between configurations at startup by

   specifying the required configuration file with the -f  option.

   If no configuration file is specified or1ksim searches for the default

   configuration file sim.cfg. First it searches for './sim.cfg'. If this

   file is not found, it searches for '~/or1k/sim.cfg'. If this file is

   not found too, it reverts to the built-in default configuration.

   NOTE: Users should not rely on the built-in configuration, since the

         default configuration may differ between version.

         Rather create a configuration file that sets all critical values.

   This file may contain (standard C) comments only - no // support.

   Configure files may be be included, using:

   include "file_name_to_include"

   Like normal configuration files, the included file is divided into

   sections. Each section is described in detail also.

   Some section have subsections. One example of such a subsection is:

   device 

     instance specific parameters...

   enddevice

   which creates a device instance.

*/

/* MEMORY SECTION

   This section specifies how the memory is generated and the blocks

   it consists of.

   type = random/unknown/pattern

      Specifies the initial memory values.

      'random' generates random memory using seed 'random_seed'.

      'pattern' fills memory with 'pattern'.

      'unknown' does not specify how memory should be generated,

      leaving the memory in a undefined state. This is the fastest

      option.

   random_seed = 

      random seed for randomizer, used if type = 'random'.

   pattern = 

      pattern to fill memory, used if type = 'pattern'.

   nmemories = 

      number of memory instances connected

   instance specific:

     baseaddr = 

        memory start address

     size = 

        memory size

     name = ""

        memory block name

     ce = 

        chip enable index of the memory instance

     delayr = 

        cycles, required for read access, -1 if instance does not support reading

     delayw = 

        cycles, required for write access, -1 if instance does not support writing

     log = ""

        filename, where to log memory accesses to, no log, if log command is not specified

*/

section memory

  /*random_seed = 12345

  type = random*/

  pattern = 0x00

  type = unknown /* Fastest */

  nmemories = 3

  device 0

    name = "FLASH"

    ce = 0

    baseaddr = 0xf0000000

    size = 0x00800000

    delayr = 10

    delayw = -1

  enddevice

  device 1

    name = "RAM"

    ce = 1

    baseaddr = 0x00000000

    size = 0x00400000

    delayr = 1

    delayw = 2

  enddevice

  device 2

    name = "SRAM"

    ce = 2

    baseaddr = 0x08000000

    size = 0x00400000

    delayr = 1

    delayw = 2

  enddevice

end

/* IMMU SECTION

    This section configures the Instruction Memory Manangement Unit

    enabled = 0/1

       '0': disabled

       '1': enabled

       (NOTE: UPR bit is set)

    nsets = 

       number of ITLB sets; must be power of two

    nways = 

       number of ITLB ways

    pagesize = 

       instruction page size; must be power of two

    entrysize = 

       instruction entry size in bytes

    ustates = 

       number of ITLB usage states (2, 3, 4 etc., max is 4)

    hitdelay = 

       number of cycles immu hit costs

    missdelay = 

       number of cycles immu miss costs

*/

section immu

  enabled = 1

  nsets = 64

  nways = 1

  pagesize = 8192

  hitdelay = 0

  missdelay = 0

end

/* DMMU SECTION

    This section configures the Data Memory Manangement Unit

    enabled = 0/1

       '0': disabled

       '1': enabled

       (NOTE: UPR bit is set)

    nsets = 

       number of DTLB sets; must be power of two

    nways = 

       number of DTLB ways

    pagesize = 

       data page size; must be power of two

    entrysize = 

       data entry size in bytes

    ustates = 

       number of DTLB usage states (2, 3, 4 etc., max is 4)

    hitdelay = 

       number of cycles dmmu hit costs

    missdelay = 

       number of cycles dmmu miss costs

*/

section dmmu

  enabled = 1

  nsets = 64

  nways = 1

  pagesize = 8192

  hitdelay = 0

  missdelay = 0

end

/* IC SECTION

   This section configures the Instruction Cache

   enabled = 0/1

       '0': disabled

       '1': enabled

      (NOTE: UPR bit is set)

   nsets = 

      number of IC sets; must be power of two

   nways = 

      number of IC ways

   blocksize = 

      IC block size in bytes; must be power of two

   ustates = 

      number of IC usage states (2, 3, 4 etc., max is 4)

   hitdelay = 

      number of cycles ic hit costs

    missdelay = 

      number of cycles ic miss costs

*/

section ic

  enabled = 1

  nsets = 256

  nways = 1

  blocksize = 16

  hitdelay = 0

  missdelay = 0

end

/* DC SECTION

   This section configures the Data Cache

   enabled = 0/1

       '0': disabled

       '1': enabled

      (NOTE: UPR bit is set)

   nsets = 

      number of DC sets; must be power of two

   nways = 

      number of DC ways

   blocksize = 

      DC block size in bytes; must be power of two

   ustates = 

      number of DC usage states (2, 3, 4 etc., max is 4)

   load_hitdelay = 

      number of cycles dc load hit costs

   load_missdelay = 

      number of cycles dc load miss costs

   store_hitdelay = 

      number of cycles dc load hit costs

   store_missdelay = 

      number of cycles dc load miss costs

*/

section dc

  enabled = 1

  nsets = 256

  nways = 1

  blocksize = 16

  load_hitdelay = 0

  load_missdelay = 0

  store_hitdelay = 0

  store_missdelay = 0

end

/* SIM SECTION

  This section specifies how or1ksim should behave.

  verbose = 0/1

       '0': don't print extra messages

       '1': print extra messages

  debug = 0-9

      1-9: debug message level.

           higher numbers produce more messages

  profile = 0/1

      '0': don't generate profiling file 'sim.profile'

      '1': don't generate profiling file 'sim.profile'

  prof_fn = ""

      optional filename for the profiling file.

      valid only if 'profile' is set

  mprofile = 0/1

      '0': don't generate memory profiling file 'sim.mprofile'

      '1': generate memory profiling file 'sim.mprofile'

  mprof_fn = ""

      optional filename for the memory profiling file.

      valid only if 'mprofile' is set

  history = 0/1

      '0': don't track execution flow

      '1': track execution flow

      Execution flow can be tracked for the simulator's

      'hist' command. Useful for back-trace debugging.

  iprompt = 0/1

     '0': start in  (so what do we start in ???)

     '1': start in interactive prompt.

  exe_log = 0/1

      '0': don't generate execution log.

      '1': generate execution log.

  exe_log = default/hardware/simple/software

      type of execution log, default is used when not specified

  exe_log_start = 

      index of first instruction to start logging, default = 0

  exe_log_end = 

      index of last instruction to end logging; not limited, if omitted

  exe_log_marker = 

       specifies number of instructions before horizontal marker is

      printed; if zero, markers are disabled (default)

  exe_log_fn = ""

      filename for the exection log file.

      valid only if 'exe_log' is set

  spr_log = 0/1

      '0': log reads/writes to/from sprs

      '1': don't log reads/write to/from sprs

  spr_log_fn = ""

      filename for the sprs log file.

      valid only if 'spr_log' is set

  clkcycle = [ps|ns|us|ms]

      specifies time measurement for one cycle

*/

section sim

  /* verbose = 1 */

  debug = 0

  profile = 0

  prof_fn = "sim.profile"

  history = 1

  /* iprompt = 0 */

  exe_log = 0

  exe_log_type = software

  exe_log_start = 0

/*  exe_log_end = 20000000*/

  exe_log_marker = 10000

  exe_log_fn = "executed.log"

  spr_log = 0

  spr_log_fn = "spr.log"

  clkcycle = 100ns

end

/* SECTION VAPI

    This section configures the Verification API, used for Advanced

    Core Verification.

    enabled = 0/1

        '0': disbable VAPI server

        '1': enable/start VAPI server

    server_port = 

        TCP/IP port to start VAPI server on

    log_enabled = 0/1

       '0': disable VAPI requests logging

       '1': enable VAPI requests logging

    hide_device_id = 0/1

       '0': don't log device id (for compatability with old version)

       '1': log device id

    vapi_fn = 

       filename for the log file.

       valid only if log_enabled is set

*/

section VAPI

  enabled = 0

  server_port = 9998

  log_enabled = 0

  vapi_log_fn = "vapi.log"

end

/* CPU SECTION

   This section specifies various CPU parameters.

   ver = 

   rev = 

      specifies version and revision of the CPU used

   upr = 

      changes the upr register

   sr = 

      sets the initial Supervision Register value

   superscalar = 0/1

      '0': CPU is scalar

      '1': CPU is superscalar

      (modify cpu/or32/execute.c to tune superscalar model)

   hazards = 0/1

      '0': don't track data hazards in superscalar CPU

      '1': track data hazards in superscalar CPU

      If tracked, data hazards can be displayed using the

      simulator's 'r' command.

   dependstats = 0/1

      '0': don't calculate inter-instruction dependencies.

      '1': calculate inter-instruction dependencies.

      If calculated, inter-instruction dependencies can be

      displayed using the simulator's 'stat' command.

   sbuf_len = 

      length of store buffer (<= 256), 0 = disabled

*/

section cpu

  ver = 0x1200

  rev = 0x0001

  /* upr = */

  superscalar = 0

  hazards = 0

  dependstats = 0

  sbuf_len = 0

end

/* PM SECTION

   This section specifies Power Management parameters

   enabled = 0/1

      '0': disable power management

      '1': enable power management

*/

section pm

  enabled = 0

end

/* BPB SECTION

   This section specifies how branch prediction should behave.

   enabled = 0/1

     '0': disable branch prediction

     '1': enable branch prediction

   btic = 0/1

     '0': disable branch target instruction cache model

     '1': enable branch target instruction cache model

   sbp_bf_fwd = 0/1

     Static branch prediction for 'l.bf'

     '0': don't use forward prediction

     '1': use forward prediction

   sbp_bnf_fwd = 0/1

     Static branch prediction for 'l.bnf'

     '0': don't use forward prediction

     '1': use forward prediction

   hitdelay = 

       number of cycles bpb hit costs

   missdelay = 

       number of cycles bpb miss costs

*/

section bpb

  enabled = 0

  btic = 0

  sbp_bf_fwd = 0

  sbp_bnf_fwd = 0

  hitdelay = 0

  missdelay = 0

end

/* DEBUG SECTION

   This sections specifies how the debug unit should behave.

   enabled = 0/1

      '0': disable debug unit

      '1': enable debug unit

   gdb_enabled = 0/1

      '0': don't start gdb server

      '1': start gdb server at port 'server_port'

   server_port = 

      TCP/IP port to start gdb server on

      valid only if gdb_enabled is set

   vapi_id = 

      Used to create "fake" vapi log file containing the JTAG proxy messages.

*/

section debug

  enabled = 0

  gdb_enabled = 0

  server_port = 9999

end

/* MC SECTION

   This section configures the memory controller

   enabled = 0/1

     '0': disable memory controller

     '1': enable memory controller

   baseaddr = 

      address of first MC register

   POC = 

      Power On Configuration register

*/

section mc

  enabled = 1

  baseaddr = 0x93000000

  POC = 0x00000008                 /* Power on configuration register */

end

/* UART SECTION

   This section configures the UARTs

   nuarts = 

      make specified number of instances, configure each

      instance within device - enddevice construct.

   instance specific:

     baseaddr = 

        address of first UART register for this device

     channel = :

        The channel parameter indicates the source of received UART characters

        and the sink for transmitted UART characters.

        The  can be either "file", "xterm", "tcp", "fd", or "tty"

        (without quotes).

          A) To send/receive characters from a pair of files, use a file

             channel:

               channel=file:,

          B) To create an interactive terminal window, use an xterm channel:

               channel=xterm:[]*

          C) To create a bidirectional tcp socket which one could, for example,

             access via telnet, use a tcp channel:

               channel=tcp:

          D) To cause the UART to read/write from existing numeric file

             descriptors, use an fd channel:

               channel=fd:,

          E) To connect the UART to a physical serial port, create a tty

             channel:

               channel=tty:device=/dev/ttyS0,baud=9600

     irq = 

        irq number for this device

     16550 = 0/1

        '0': this device is a UART16450

        '1': this device is a UART16550

     jitter = 

        in msecs... time to block, -1 to disable it

     vapi_id = 

        VAPI id of this instance

*/

section uart

  nuarts = 1

  device 0

    baseaddr = 0x90000000

    irq = 2

    channel = "file:uart0.rx,uart0.tx"

    jitter = -1                     /* async behaviour */

    16550 = 1

  enddevice

end

/* DMA SECTION

   This section configures the DMAs

   ndmas = 

      make specified number of instances, configure each

      instance within device - enddevice construct.

   instance specific:

     baseaddr = 

        address of first DMA register for this device

     irq = 

        irq number for this device

     vapi_id = 

        VAPI id of this instance

*/

section dma

  ndmas = 0

  /*

  device 0

    baseaddr = 0x9a000000

    irq = 11

  enddevice

  */

end

/* ETHERNET SECTION

   This section configures the ETHERNETs

   nethernets = 

      make specified number of instances, configure each

      instance within device - enddevice construct.

   instance specific:

     baseaddr = 

        address of first ethernet register for this device

     dma = 

        which controller is this ethernet "connected" to

     irq = 

        ethernet mac IRQ level

     rtx_type = 

        use 0 - file interface, 1 - socket interface

     rx_channel = 

        DMA channel used for RX

     tx_channel = 

        DMA channel used for TX

     rxfile = ""

        filename, where to read data from

     txfile = ""

        filename, where to write data to

     sockif = ""

        interface name of ethernet socket

     vapi_id = 

        VAPI id of this instance

*/

section ethernet

  nethernets = 1

  device 0

    baseaddr = 0x92000000

    dma = 0

    irq = 4

    rtx_type = 1

    tx_channel = 0

    rx_channel = 1

    rxfile = "eth0.rx"

    txfile = "eth0.tx"

    sockif = "eth0"

  enddevice

end

/* GPIO SECTION

   This section configures the GPIOs

   ngpios = 

      make specified number of instances, configure each

      instance within device - enddevice construct.

   instance specific:

     baseaddr = 

        address of first GPIO register for this device

     irq = 

        irq number for this device

     base_vapi_id = 

        first VAPI id of this instance

        GPIO uses 8 consecutive VAPI IDs

*/

section gpio

  ngpios = 1

  device 0

    baseaddr = 0x91000000

    irq = 3

    base_vapi_id = 0x0200

  enddevice

end

/* VGA SECTION

    This section configures the VGA/LCD controller

    nvgas = 

       number of VGA devices connected

    instance specific:

      baseaddr = 

        address of first VGA register

      irq = 

        irq number for this device

      refresh_rate = 

        number of cycles between screen dumps

      filename = ""

        template name for generated names (e.g. "primary" produces "primary0023.bmp")

*/

section vga

  nvgas = 1

  device 0

    baseaddr = 0x97100000

    irq = 8

    refresh_rate = 100000

    filename = "primary"

  enddevice

end

/* TICK TIMER SECTION

    This section configures tick timer

    enabled = 0/1

      whether tick timer is enabled

    irq = 

      irq number

*/

/*

section tick

  enabled = 1

  irq = 0

end

*/

/* FB SECTION

    This section configures the frame buffer

    enabled = 0/1

      whether frame buffer is enabled

    baseaddr = 

      base address of frame buffer

    paladdr = 

      base address of first palette entry

    refresh_rate = 

      number of cycles between screen dumps

    filename = ""

      template name for generated names (e.g. "primary" produces "primary0023.bmp")

*/

section fb

  enabled = 1

  baseaddr = 0x97000000

  refresh_rate = 1000000

  filename = "primary"

end

/* KBD SECTION

    This section configures the PS/2 compatible keyboard

    enabled = 0/1

      whether keyboard is enabled

    baseaddr = 

      base address of the keyboard device

    rxfile = ""

      filename, where to read data from

*/