ARM/XScale Intel IQ80321

Overview

RedBoot supports the serial port and the built-in ethernet port for communication and downloads. The default serial port settings are 115200,8,N,1. RedBoot also supports flash management for the onboard 8MB flash.

The following RedBoot configurations are supported:

ConfigurationModeDescriptionFile
ROM[ROM]RedBoot running from the board's flash boot sector.redboot_ROM.ecm
RAM[RAM]RedBoot running from RAM with RedBoot in the flash boot sector.redboot_RAM.ecm

Initial Installation Method

The board manufacturer provides a DOS application which is capable of programming the flash over the PCI bus, and this is required for initial installations of RedBoot. Please see the board manual for information on using this utility. In general, the process involves programming the ROM mode RedBoot image to flash. RedBoot should be programmed to flash address 0x00000000 using the DOS utility.

After booting the initial installation of RedBoot, this warning may be printed:

flash configuration checksum error or invalid key
This is normal, and indicates that the flash must be configured for use by RedBoot. Even if the above message is not printed, it may be a good idea to reinitialize the flash anyway. Do this with the fis command:
RedBoot> fis init
About to initialize [format] FLASH image system - continue (y/n)? y
*** Initialize FLASH Image System
    Warning: device contents not erased, some blocks may not be usable
    ... Unlock from 0xf07e0000-0xf0800000: .
    ... Erase from 0xf07e0000-0xf0800000: .
    ... Program from 0x01ddf000-0x01ddf400 at 0xf07e0000: .
    ... Lock from 0xf07e0000-0xf0800000: .

Switch Settings

The 80321 board is highly configurable through a number of switches and jumpers. RedBoot makes some assumptions about board configuration and attention must be paid to these assumptions for reliable RedBoot operation:

LED Codes

RedBoot uses the two digit LED display to indicate status during board initialization. Possible codes are:

LED     Actions
-------------------------------------------------------------
   Power-On/Reset
88
        Set the CPSR
        Enable coprocessor access
        Drain write and fill buffer
        Setup PBIU chip selects
A1
        Enable the Icache
A2
        Move FLASH chip select from 0x0 to 0xF0000000
        Jump to new FLASH location
A3
        Setup and enable the MMU
A4
        I2C interface initialization
90
        Wait for I2C initialization to complete
91
        Send address (via I2C) to the DIMM
92
        Wait for transmit complete
93
        Read SDRAM PD data from DIMM
94
        Read remainder of EEPROM data.
        An error will result in one of the following
        error codes on the LEDs:
        77 BAD EEPROM checksum
        55 I2C protocol error
        FF bank size error
A5
        Setup DDR memory interface
A6
        Enable branch target buffer
        Drain the write & fill buffers
        Flush Icache, Dcache and BTB
        Flush instuction and data TLBs
        Drain the write & fill buffers
SL
        ECC Scrub Loop
SE
A7
        Clean, drain, flush the main Dcache
A8
        Clean, drain, flush the mini Dcache
        Flush Dcache
        Drain the write & fill buffers
A9
        Enable ECC
AA
        Save SDRAM size
        Move MMU tables into RAM
AB
        Clean, drain, flush the main Dcache
        Clean, drain, flush the mini Dcache
        Drain the write & fill buffers
AC
        Set the TTB register to DRAM mmu_table
AD
        Set mode to IRQ mode
A7
        Move SWI & Undefined "vectors" to RAM (at 0x0)
A6
        Switch to supervisor mode
A5
        Move remaining "vectors" to RAM (at 0x0)
A4
        Copy DATA to RAM
        Initialize interrupt exception environment
        Initialize stack
        Clear BSS section
A3
        Call platform specific hardware initialization
A2
        Run through static constructors
A1
        Start up the eCos kernel or RedBoot

Special RedBoot Commands

A special RedBoot command, diag, is used to access a set of hardware diagnostics. To access the diagnostic menu, enter diag at the RedBoot prompt:

RedBoot> diag
Entering Hardware Diagnostics - Disabling Data Cache!

  IQ80321 Hardware Tests

 1 - Memory Tests
 2 - Repeating Memory Tests
 3 - Repeat-On-Fail Memory Tests
 4 - Rotary Switch S1 Test
 5 - 7 Segment LED Tests
 6 - i82544 Ethernet Configuration
 7 - Baterry Status Test
 8 - Battery Backup SDRAM Memory Test
 9 - Timer Test
10 - PCI Bus test
11 - CPU Cache Loop (No Return)
 0 - quit
Enter the menu item number (0 to quit):
Tests for various hardware subsystems are provided, and some tests require special hardware in order to execute normally. The Ethernet Configuration item may be used to set the board ethernet address.

Memory Tests

This test is used to test installed DDR SDRAM memory. Five different tests are run over the given address ranges. If errors are encountered, the test is aborted and information about the failure is printed. When selected, the user will be prompted to enter the base address of the test range and its size. The numbers must be in hex with no leading “0x”

Enter the menu item number (0 to quit): 1

Base address of memory to test (in hex): 100000

Size of memory to test (in hex): 200000

Testing memory from 0x00100000 to 0x002fffff.

Walking 1's test: 
0000000100000002000000040000000800000010000000200000004000000080
0000010000000200000004000000080000001000000020000000400000008000
0001000000020000000400000008000000100000002000000040000000800000
0100000002000000040000000800000010000000200000004000000080000000
passed
32-bit address test: passed
32-bit address bar test: passed
8-bit address test: passed
Byte address bar test: passed
Memory test done.

Repeating Memory Tests

The repeating memory tests are exactly the same as the above memory tests, except that the tests are automatically rerun after completion. The only way out of this test is to reset the board.

Repeat-On-Fail Memory Tests

This is similar to the repeating memory tests except that when an error is found, the failing test continuously retries on the failing address.

Rotary Switch S1 Test

This tests the operation of the sixteen position rotary switch. When run, this test will display the current position of the rotary switch on the LED display. Slowly dial through each position and confirm reading on LED.

7 Segment LED Tests

This tests the operation of the seven segment displays. When run, each LED cycles through 0 through F and a decimal point.

i82544 Ethernet Configuration

This test initializes the ethernet controller’s serial EEPROM if the current contents are invalid. In any case, this test will also allow the user to enter a six byte ethernet MAC address into the serial EEPROM.

Enter the menu item number (0 to quit): 6


Current MAC address: 00:80:4d:46:00:02
Enter desired MAC address: 00:80:4d:46:00:01
Writing to the Serial EEPROM... Done

******** Reset The Board To Have Changes Take Effect ********

Battery Status Test

This tests the current status of the battery. First, the test checks to see if the battery is installed and reports that finding. If the battery is installed, the test further determines whether the battery status is one or more of the following:

  • Battery is charging.

  • Battery is fully discharged.

  • Battery voltage measures within normal operating range.

Battery Backup SDRAM Memory Test

This tests the battery backup of SDRAM memory. This test is a three step process:

  1. Select Battery backup test from main diag menu, then write data to SDRAM.

  2. Turn off power for 60 seconds, then repower the board.

  3. Select Battery backup test from main diag menu, then check data that was written in step 1.

Timer Test

This tests the internal timer by printing a number of dots at one second intervals.

PCI Bus Test

This tests the secondary PCI-X bus and socket. This test requires that an IQ80310 board be plugged into the secondary slot of the IOP80321 board. The test assumes at least 32MB of installed memory on the IQ80310. That memory is mapped into the IOP80321 address space and the memory tests are run on that memory.

CPU Cache Loop

This test puts the CPU into a tight loop run entirely from the ICache. This should prevent all external bus accesses.

Rebuilding RedBoot

These shell variables provide the platform-specific information needed for building RedBoot according to the procedure described in Chapter 3:

export TARGET=iq80321
export ARCH_DIR=arm
export PLATFORM_DIR=xscale/iq80321

The names of configuration files are listed above with the description of the associated modes.

Interrupts

RedBoot uses an interrupt vector table which is located at address 0x8004. Entries in this table are pointers to functions with this protoype::

int irq_handler( unsigned vector, unsigned data )
On an IQ80321 board, the vector argument is one of 32 interrupts defined in hal/arm/xscale/verde/current/include/hal_var_ints.h::
// *** 80200 CPU ***
#define CYGNUM_HAL_INTERRUPT_DMA0_EOT      0
#define CYGNUM_HAL_INTERRUPT_DMA0_EOC      1
#define CYGNUM_HAL_INTERRUPT_DMA1_EOT      2
#define CYGNUM_HAL_INTERRUPT_DMA1_EOC      3
#define CYGNUM_HAL_INTERRUPT_RSVD_4        4
#define CYGNUM_HAL_INTERRUPT_RSVD_5        5
#define CYGNUM_HAL_INTERRUPT_AA_EOT        6
#define CYGNUM_HAL_INTERRUPT_AA_EOC        7
#define CYGNUM_HAL_INTERRUPT_CORE_PMON     8
#define CYGNUM_HAL_INTERRUPT_TIMER0        9
#define CYGNUM_HAL_INTERRUPT_TIMER1        10
#define CYGNUM_HAL_INTERRUPT_I2C_0         11
#define CYGNUM_HAL_INTERRUPT_I2C_1         12
#define CYGNUM_HAL_INTERRUPT_MESSAGING     13
#define CYGNUM_HAL_INTERRUPT_ATU_BIST      14
#define CYGNUM_HAL_INTERRUPT_PERFMON       15
#define CYGNUM_HAL_INTERRUPT_CORE_PMU      16
#define CYGNUM_HAL_INTERRUPT_BIU_ERR       17
#define CYGNUM_HAL_INTERRUPT_ATU_ERR       18
#define CYGNUM_HAL_INTERRUPT_MCU_ERR       19
#define CYGNUM_HAL_INTERRUPT_DMA0_ERR      20
#define CYGNUM_HAL_INTERRUPT_DMA1_ERR      22
#define CYGNUM_HAL_INTERRUPT_AA_ERR        23
#define CYGNUM_HAL_INTERRUPT_MSG_ERR       24
#define CYGNUM_HAL_INTERRUPT_SSP           25
#define CYGNUM_HAL_INTERRUPT_RSVD_26       26
#define CYGNUM_HAL_INTERRUPT_XINT0         27
#define CYGNUM_HAL_INTERRUPT_XINT1         28
#define CYGNUM_HAL_INTERRUPT_XINT2         29
#define CYGNUM_HAL_INTERRUPT_XINT3         30
#define CYGNUM_HAL_INTERRUPT_HPI           31
The data passed to the ISR is pulled from a data table (hal_interrupt_data) which immediately follows the interrupt vector table. With 32 interrupts, the data table starts at address 0x8084.

An application may create a normal C function with the above prototype to be an ISR. Just poke its address into the table at the correct index and enable the interrupt at its source. The return value of the ISR is ignored by RedBoot.

Memory Maps

The RAM based page table is located at RAM start + 0x4000. RedBoot may be configured for one of two memory maps. The difference between them is the location of RAM and the PCI outbound windows. The alternative memory map may be used when building RedBoot or eCos by using the RAM_ALTMAP and ROM_ALTMAP startup types in the configuration.

NOTE: The virtual memory maps in this section use a C, B, and X column to indicate the caching policy for the region..

X C B  Description
- - -  ---------------------------------------------
0 0 0  Uncached/Unbuffered
0 0 1  Uncached/Buffered
0 1 0  Cached/Buffered    Write Through, Read Allocate
0 1 1  Cached/Buffered    Write Back, Read Allocate
1 0 0  Invalid -- not used
1 0 1  Uncached/Buffered  No write buffer coalescing
1 1 0  Mini DCache - Policy set by Aux Ctl Register
1 1 1  Cached/Buffered    Write Back, Read/Write Allocate

Physical Address Range     Description
-----------------------    ----------------------------------
0x00000000 - 0x7fffffff    ATU Outbound Direct Window
0x80000000 - 0x900fffff    ATU Outbound Translate Windows
0xa0000000 - 0xbfffffff    SDRAM
0xf0000000 - 0xf0800000    FLASH               (PBIU CS0)
0xfe800000 - 0xfe800fff    UART                (PBIU CS1)
0xfe840000 - 0xfe840fff    Left 7-segment LED  (PBIU CS3)
0xfe850000 - 0xfe850fff    Right 7-segment LED (PBIU CS2)
0xfe8d0000 - 0xfe8d0fff    Rotary Switch       (PBIU CS4)
0xfe8f0000 - 0xfe8f0fff    Baterry Status      (PBIU CS5)
0xfff00000 - 0xffffffff    Verde Memory mapped Registers


Default Virtual Map      X C B  Description
-----------------------  - - -  ----------------------------------
0x00000000 - 0x1fffffff  1 1 1  SDRAM
0x20000000 - 0x9fffffff  0 0 0  ATU Outbound Direct Window
0xa0000000 - 0xb00fffff  0 0 0  ATU Outbound Translate Windows
0xc0000000 - 0xdfffffff  0 0 0  Uncached alias for SDRAM
0xe0000000 - 0xe00fffff  1 1 1  Cache flush region (no phys mem)
0xf0000000 - 0xf0800000  0 1 0  FLASH               (PBIU CS0)
0xfe800000 - 0xfe800fff  0 0 0  UART                (PBIU CS1)
0xfe840000 - 0xfe840fff  0 0 0  Left 7-segment LED  (PBIU CS3)
0xfe850000 - 0xfe850fff  0 0 0  Right 7-segment LED (PBIU CS2)
0xfe8d0000 - 0xfe8d0fff  0 0 0  Rotary Switch       (PBIU CS4)
0xfe8f0000 - 0xfe8f0fff  0 0 0  Baterry Status      (PBIU CS5)
0xfff00000 - 0xffffffff  0 0 0  Verde Memory mapped Registers

Alternate Virtual Map    X C B  Description
-----------------------  - - -  ----------------------------------
0x00000000 - 0x000fffff  1 1 1  Alias for 1st MB of SDRAM
0x00100000 - 0x7fffffff  0 0 0  ATU Outbound Direct Window
0x80000000 - 0x900fffff  0 0 0  ATU Outbound Translate Windows
0xa0000000 - 0xbfffffff  1 1 1  SDRAM
0xc0000000 - 0xdfffffff  0 0 0  Uncached alias for SDRAM
0xe0000000 - 0xe00fffff  1 1 1  Cache flush region (no phys mem)
0xf0000000 - 0xf0800000  0 1 0  FLASH               (PBIU CS0)
0xfe800000 - 0xfe800fff  0 0 0  UART                (PBIU CS1)
0xfe840000 - 0xfe840fff  0 0 0  Left 7-segment LED  (PBIU CS3)
0xfe850000 - 0xfe850fff  0 0 0  Right 7-segment LED (PBIU CS2)
0xfe8d0000 - 0xfe8d0fff  0 0 0  Rotary Switch       (PBIU CS4)
0xfe8f0000 - 0xfe8f0fff  0 0 0  Baterry Status      (PBIU CS5)
0xfff00000 - 0xffffffff  0 0 0  Verde Memory mapped Registers

Platform Resource Usage

The Verde programmable timer0 is used for timeout support for networking and XModem file transfers.