linux/Documentation/fujitsu/frv/features.txt

311 lines
11 KiB
Plaintext

===========================
FUJITSU FR-V LINUX FEATURES
===========================
This kernel port has a number of features of which the user should be aware:
(*) Linux and uClinux
The FR-V architecture port supports both normal MMU linux and uClinux out
of the same sources.
(*) CPU support
Support for the FR401, FR403, FR405, FR451 and FR555 CPUs should work with
the same uClinux kernel configuration.
In normal (MMU) Linux mode, only the FR451 CPU will work as that is the
only one with a suitably featured CPU.
The kernel is written and compiled with the assumption that only the
bottom 32 GR registers and no FR registers will be used by the kernel
itself, however all extra userspace registers will be saved on context
switch. Note that since most CPUs can't support lazy switching, no attempt
is made to do lazy register saving where that would be possible (FR555
only currently).
(*) Board support
The board on which the kernel will run can be configured on the "Processor
type and features" configuration tab.
Set the System to "MB93093-PDK" to boot from the MB93093 (FR403) PDK.
Set the System to "MB93091-VDK" to boot from the CB11, CB30, CB41, CB60,
CB70 or CB451 VDK boards. Set the Motherboard setting to "MB93090-MB00" to
boot with the standard ATA90590B VDK motherboard, and set it to "None" to
boot without any motherboard.
(*) Binary Formats
The only userspace binary format supported is FDPIC ELF. Normal ELF, FLAT
and AOUT binaries are not supported for this architecture.
FDPIC ELF supports shared library and program interpreter facilities.
(*) Scheduler Speed
The kernel scheduler runs at 100Hz irrespective of the clock speed on this
architecture. This value is set in asm/param.h (see the HZ macro defined
there).
(*) Normal (MMU) Linux Memory Layout.
See mmu-layout.txt in this directory for a description of the normal linux
memory layout
See include/asm-frv/mem-layout.h for constants pertaining to the memory
layout.
See include/asm-frv/mb-regs.h for the constants pertaining to the I/O bus
controller configuration.
(*) uClinux Memory Layout
The memory layout used by the uClinux kernel is as follows:
0x00000000 - 0x00000FFF Null pointer catch page
0x20000000 - 0x200FFFFF CS2# [PDK] FPGA
0xC0000000 - 0xCFFFFFFF SDRAM
0xC0000000 Base of Linux kernel image
0xE0000000 - 0xEFFFFFFF CS2# [VDK] SLBUS/PCI window
0xF0000000 - 0xF0FFFFFF CS5# MB93493 CSC area (DAV daughter board)
0xF1000000 - 0xF1FFFFFF CS7# [CB70/CB451] CPU-card PCMCIA port space
0xFC000000 - 0xFC0FFFFF CS1# [VDK] MB86943 config space
0xFC100000 - 0xFC1FFFFF CS6# [CB70/CB451] CPU-card DM9000 NIC space
0xFC100000 - 0xFC1FFFFF CS6# [PDK] AX88796 NIC space
0xFC200000 - 0xFC2FFFFF CS3# MB93493 CSR area (DAV daughter board)
0xFD000000 - 0xFDFFFFFF CS4# [CB70/CB451] CPU-card extra flash space
0xFE000000 - 0xFEFFFFFF Internal CPU peripherals
0xFF000000 - 0xFF1FFFFF CS0# Flash 1
0xFF200000 - 0xFF3FFFFF CS0# Flash 2
0xFFC00000 - 0xFFC0001F CS0# [VDK] FPGA
The kernel reads the size of the SDRAM from the memory bus controller
registers by default.
The kernel initialisation code (1) adjusts the SDRAM base addresses to
move the SDRAM to desired address, (2) moves the kernel image down to the
bottom of SDRAM, (3) adjusts the bus controller registers to move I/O
windows, and (4) rearranges the protection registers to protect all of
this.
The reasons for doing this are: (1) the page at address 0 should be
inaccessible so that NULL pointer errors can be caught; and (2) the bottom
three quarters are left unoccupied so that an FR-V CPU with an MMU can use
it for virtual userspace mappings.
See include/asm-frv/mem-layout.h for constants pertaining to the memory
layout.
See include/asm-frv/mb-regs.h for the constants pertaining to the I/O bus
controller configuration.
(*) uClinux Memory Protection
A DAMPR register is used to cover the entire region used for I/O
(0xE0000000 - 0xFFFFFFFF). This permits the kernel to make uncached
accesses to this region. Userspace is not permitted to access it.
The DAMPR/IAMPR protection registers not in use for any other purpose are
tiled over the top of the SDRAM such that:
(1) The core kernel image is covered by as small a tile as possible
granting only the kernel access to the underlying data, whilst
making sure no SDRAM is actually made unavailable by this approach.
(2) All other tiles are arranged to permit userspace access to the rest
of the SDRAM.
Barring point (1), there is nothing to protect kernel data against
userspace damage - but this is uClinux.
(*) Exceptions and Fixups
Since the FR40x and FR55x CPUs that do not have full MMUs generate
imprecise data error exceptions, there are currently no automatic fixup
services available in uClinux. This includes misaligned memory access
fixups.
Userspace EFAULT errors can be trapped by issuing a MEMBAR instruction and
forcing the fault to happen there.
On the FR451, however, data exceptions are mostly precise, and so
exception fixup handling is implemented as normal.
(*) Userspace Breakpoints
The ptrace() system call supports the following userspace debugging
features:
(1) Hardware assisted single step.
(2) Breakpoint via the FR-V "BREAK" instruction.
(3) Breakpoint via the FR-V "TIRA GR0, #1" instruction.
(4) Syscall entry/exit trap.
Each of the above generates a SIGTRAP.
(*) On-Chip Serial Ports
The FR-V on-chip serial ports are made available as ttyS0 and ttyS1. Note
that if the GDB stub is compiled in, ttyS1 will not actually be available
as it will be being used for the GDB stub.
These ports can be made by:
mknod /dev/ttyS0 c 4 64
mknod /dev/ttyS1 c 4 65
(*) Maskable Interrupts
Level 15 (Non-maskable) interrupts are dealt with by the GDB stub if
present, and cause a panic if not. If the GDB stub is present, ttyS1's
interrupts are rated at level 15.
All other interrupts are distributed over the set of available priorities
so that no IRQs are shared where possible. The arch interrupt handling
routines attempt to disentangle the various sources available through the
CPU's own multiplexor, and those on off-CPU peripherals.
(*) Accessing PCI Devices
Where PCI is available, care must be taken when dealing with drivers that
access PCI devices. PCI devices present their data in little-endian form,
but the CPU sees it in big-endian form. The macros in asm/io.h try to get
this right, but may not under all circumstances...
(*) Ax88796 Ethernet Driver
The MB93093 PDK board has an Ax88796 ethernet chipset (an NE2000 clone). A
driver has been written to deal specifically with this. The driver
provides MII services for the card.
The driver can be configured by running make xconfig, and going to:
(*) Network device support
- turn on "Network device support"
(*) Ethernet (10 or 100Mbit)
- turn on "Ethernet (10 or 100Mbit)"
- turn on "AX88796 NE2000 compatible chipset"
The driver can be found in:
drivers/net/ax88796.c
include/asm/ax88796.h
(*) WorkRAM Driver
This driver provides a character device that permits access to the WorkRAM
that can be found on the FR451 CPU. Each page is accessible through a
separate minor number, thereby permitting each page to have its own
filesystem permissions set on the device file.
The device files should be:
mknod /dev/frv/workram0 c 240 0
mknod /dev/frv/workram1 c 240 1
mknod /dev/frv/workram2 c 240 2
...
The driver will not permit the opening of any device file that does not
correspond to at least a partial page of WorkRAM. So the first device file
is the only one available on the FR451. If any other CPU is detected, none
of the devices will be openable.
The devices can be accessed with read, write and llseek, and can also be
mmapped. If they're mmapped, they will only map at the appropriate
0x7e8nnnnn address on linux and at the 0xfe8nnnnn address on uClinux. If
MAP_FIXED is not specified, the appropriate address will be chosen anyway.
The mappings must be MAP_SHARED not MAP_PRIVATE, and must not be
PROT_EXEC. They must also start at file offset 0, and must not be longer
than one page in size.
This driver can be configured by running make xconfig, and going to:
(*) Character devices
- turn on "Fujitsu FR-V CPU WorkRAM support"
(*) Dynamic data cache write mode changing
It is possible to view and to change the data cache's write mode through
the /proc/sys/frv/cache-mode file while the kernel is running. There are
two modes available:
NAME MEANING
===== ==========================================
wthru Data cache is in Write-Through mode
wback Data cache is in Write-Back/Copy-Back mode
To read the cache mode:
# cat /proc/sys/frv/cache-mode
wthru
To change the cache mode:
# echo wback >/proc/sys/frv/cache-mode
# cat /proc/sys/frv/cache-mode
wback
(*) MMU Context IDs and Pinning
On MMU Linux the CPU supports the concept of a context ID in its MMU to
make it more efficient (TLB entries are labelled with a context ID to link
them to specific tasks).
Normally once a context ID is allocated, it will remain affixed to a task
or CLONE_VM'd group of tasks for as long as it exists. However, since the
kernel is capable of supporting more tasks than there are possible ID
numbers, the kernel will pass context IDs from one task to another if
there are insufficient available.
The context ID currently in use by a task can be viewed in /proc:
# grep CXNR /proc/1/status
CXNR: 1
Note that kernel threads do not have a userspace context, and so will not
show a CXNR entry in that file.
Under some circumstances, however, it is desirable to pin a context ID on
a process such that the kernel won't pass it on. This can be done by
writing the process ID of the target process to a special file:
# echo 17 >/proc/sys/frv/pin-cxnr
Reading from the file will then show the context ID pinned.
# cat /proc/sys/frv/pin-cxnr
4
The context ID will remain pinned as long as any process is using that
context, i.e.: when the all the subscribing processes have exited or
exec'd; or when an unpinning request happens:
# echo 0 >/proc/sys/frv/pin-cxnr
When there isn't a pinned context, the file shows -1:
# cat /proc/sys/frv/pin-cxnr
-1