[U-Boot] [PATCH v2] powerpc/p1010rdb: update readme for p1010rdb-pb board
Shengzhou Liu
Shengzhou.Liu at freescale.com
Thu Sep 5 05:27:12 CEST 2013
- Remove duplicate doc/README.p1010rdb
- Update for P1010RDB-PB board
P1010RDB-PB is a variation of previous P1010RDB-PA board.
Henceforth we support P1010RDB-PB board instead of P1010RDB-PA.
Signed-off-by: Shengzhou Liu <Shengzhou.Liu at freescale.com>
---
v2: removed duplicate doc/README.p1010rdb
board/freescale/p1010rdb/README | 285 ++++++++++++++++++----------------------
doc/README.p1010rdb | 199 ----------------------------
2 files changed, 127 insertions(+), 357 deletions(-)
delete mode 100644 doc/README.p1010rdb
diff --git a/board/freescale/p1010rdb/README b/board/freescale/p1010rdb/README
index 7f18aaa..4d6553d 100644
--- a/board/freescale/p1010rdb/README
+++ b/board/freescale/p1010rdb/README
@@ -1,58 +1,40 @@
Overview
=========
-The P1010RDB is a Freescale reference design board that hosts the P1010 SoC.
+The P1010RDB is a Freescale Reference Design Board that hosts the P1010 SoC.
+P1010RDB-PB is a variation of previous P1010RDB-PA board.
The P1010 is a cost-effective, low-power, highly integrated host processor
-based on a Power Architecture e500v2 core (maximum core frequency 800/1000 MHz),
-that addresses the requirements of several routing, gateways, storage, consumer,
+based on a Power Architecture e500v2 core (maximum core frequency 1GHz),that
+addresses the requirements of several routing, gateways, storage, consumer,
and industrial applications. Applications of interest include the main CPUs and
I/O processors in network attached storage (NAS), the voice over IP (VoIP)
router/gateway, and wireless LAN (WLAN) and industrial controllers.
-The P1010RDB board features are as follows:
+The P1010RDB-PB board features are as following:
Memory subsystem:
- - 1Gbyte unbuffered DDR3 SDRAM discrete devices (32-bit bus)
- - 32 Mbyte NOR flash single-chip memory
- - 32 Mbyte NAND flash memory
- - 256 Kbit M24256 I2C EEPROM
- - 16 Mbyte SPI memory
+ - 1G bytes unbuffered DDR3 SDRAM discrete devices (32-bit bus)
+ - 32M bytes NOR flash single-chip memory
+ - 2G bytes NAND flash memory
+ - 16M bytes SPI memory
+ - 256K bit M24256 I2C EEPROM
- I2C Board EEPROM 128x8 bit memory
- SD/MMC connector to interface with the SD memory card
Interfaces:
- - PCIe:
- - Lane0: x1 mini-PCIe slot
- - Lane1: x1 PCIe standard slot
- - SATA:
- - 1 internal SATA connector to 2.5” 160G SATA2 HDD
- - 1 eSATA connector to rear panel
- - 10/100/1000 BaseT Ethernet ports:
- - eTSEC1, RGMII: one 10/100/1000 port using Vitesse VSC8641XKO
- - eTSEC2, SGMII: one 10/100/1000 port using Vitesse VSC8221
- - eTSEC3, SGMII: one 10/100/1000 port using Vitesse VSC8221
- - USB 2.0 port:
- - x1 USB2.0 port via an external ULPI PHY to micro-AB connector
- - x1 USB2.0 port via an internal UTMI PHY to micro-AB connector
- - FlexCAN ports:
- - 2 DB-9 female connectors for FlexCAN bus(revision 2.0B)
- interface;
- - DUART interface:
- - DUART interface: supports two UARTs up to 115200 bps for
- console display
- - RJ45 connectors are used for these 2 UART ports.
- - TDM
- - 2 FXS ports connected via an external SLIC to the TDM interface.
- SLIC is controllled via SPI.
- - 1 FXO port connected via a relay to FXS for switchover to POTS
+ - Three 10/100/1000 BaseT Ethernet ports (One RGMII and two SGMII)
+ - PCIe 2.0: two x1 mini-PCIe slots
+ - SATA 2.0: two SATA interfaces
+ - USB 2.0: one USB interface
+ - FlexCAN: two FlexCAN interfaces (revision 2.0B)
+ - UART: one USB-to-Serial interface
+ - TDM: 2 FXS ports connected via an external SLIC to the TDM interface.
+ 1 FXO port connected via a relay to FXS for switchover to POTS
+
Board connectors:
- Mini-ITX power supply connector
- JTAG/COP for debugging
-IEEE Std. 1588 signals for test and measurement
-Real-time clock on I2C bus
-POR
- - support critical POR setting changed via switch on board
-PCB
- - 6-layer routing (4-layer signals, 2-layer power and ground)
+POR: support critical POR setting changed via switch on board
+PCB: 6-layer routing (4-layer signals, 2-layer power and ground)
Physical Memory Map on P1010RDB
===============================
@@ -77,132 +59,119 @@ Configure the serial port of the attached computer with the following values:
-Flow Control: Hardware/None
-Settings of DIP-switch
-======================
- SW4[1:4]= 1111 and SW6[4]=0 for boot from 16bit NOR flash
- SW4[1:4]= 1000 and SW6[4]=1 for boot from 8bit NAND flash
- SW4[1:4]= 0110 and SW6[4]=0 for boot from SPI flash
+P1010RDB-PB default DIP-switch settings
+=======================================
+SW1[1:8]= 10101010
+SW2[1:8]= 11011000
+SW3[1:8]= 10010000
+SW4[1:4]= 1010
+SW5[1:8]= 11111010
+
+
+P1010RDB-PB boot mode settings via DIP-switch
+=============================================
+SW4[1:4]= 1111 and SW3[3:4]= 00 for 16bit NOR boot
+SW4[1:4]= 1010 and SW3[3:4]= 01 for 8bit NAND boot
+SW4[1:4]= 0110 and SW3[3:4]= 00 for SPI boot
+SW4[1:4]= 0111 and SW3[3:4]= 10 for SD boot
Note: 1 stands for 'on', 0 stands for 'off'
-Setting of hwconfig
+Switch P1010RDB-PB boot mode via software without setting DIP-switch
+====================================================================
+=> run boot_bank0 (boot from NOR bank0)
+=> run boot_bank1 (boot from NOR bank1)
+=> run boot_nand (boot from NAND flash)
+=> run boot_spi (boot from SPI flash)
+=> run boot_sd (boot from SD card)
+
+
+Setting of pin mux
===================
-If FlexCAN or TDM is needed, please set "fsl_p1010mux:tdm_can=can" or
-"fsl_p1010mux:tdm_can=tdm" explicitly in u-booot prompt as below for example:
-setenv hwconfig "fsl_p1010mux:tdm_can=tdm;usb1:dr_mode=host,phy_type=utmi"
-By default, don't set fsl_p1010mux:tdm_can, in this case, spi chip selection
-is set to spi-flash instead of to SLIC/TDM/DAC and tdm_can_sel is set to TDM
-instead of to CAN/UART1.
-
-
-Build and burn u-boot to NOR flash
-==================================
-1. Build u-boot.bin image
- export ARCH=powerpc
- export CROSS_COMPILE=/your_path/powerpc-linux-gnu-
- make P1010RDB_NOR
-
-2. Burn u-boot.bin into NOR flash
- => tftp $loadaddr $uboot
- => protect off eff80000 +$filesize
- => erase eff80000 +$filesize
- => cp.b $loadaddr eff80000 $filesize
-
-3. Check SW4[1:4]= 1111 and SW6[4]=0, then power on.
-
-
-Alternate NOR bank
-==================
-1. Burn u-boot.bin into alternate NOR bank
- => tftp $loadaddr $uboot
- => protect off eef80000 +$filesize
- => erase eef80000 +$filesize
- => cp.b $loadaddr eef80000 $filesize
-
-2. Switch to alternate NOR bank
- => mw.b ffb00009 1
- => reset
- or set SW1[8]= ON
-
-SW1[8]= OFF: Upper bank used for booting start
-SW1[8]= ON: Lower bank used for booting start
-CPLD NOR bank selection register address 0xFFB00009 Bit[0]:
-0 - boot from upper 4 sectors
-1 - boot from lower 4 sectors
-
-
-Build and burn u-boot to NAND flash
-===================================
-1. Build u-boot.bin image
- export ARCH=powerpc
- export CROSS_COMPILE=/your_path/powerpc-linux-gnu-
- make P1010RDB_NAND
-
-2. Burn u-boot-nand.bin into NAND flash
- => tftp $loadaddr $uboot-nand
- => nand erase 0 $filesize
- => nand write $loadaddr 0 $filesize
-
-3. Check SW4[1:4]= 1000 and SW6[4]=1, then power on.
-
-
-Build and burn u-boot to SPI flash
-==================================
-1. Build u-boot-spi.bin image
- make P1010RDB_SPIFLASH_config; make
- Boot up kernel with rootfs.ext2.gz.uboot.p1010rdb
- Download u-boot.bin to linux and you can find some config files
- under /usr/share such as config_xx.dat. Do below command:
- boot_format config_ddr3_1gb_p1010rdb_800M.dat u-boot.bin -spi \
- u-boot-spi.bin
- to generate u-boot-spi.bin.
-
-2. Burn u-boot-spi.bin into SPI flash
- => tftp $loadaddr $uboot-spi
- => sf erase 0 100000
- => sf write $loadaddr 0 $filesize
-
-3. Check SW4[1:4]= 0110 and SW6[4]=0, then power on.
-
-
-CPLD POR setting registers
-==========================
-1. Set POR switch selection register (addr 0xFFB00011) to 0.
-2. Write CPLD POR registers (BCSR0~BCSR3, addr 0xFFB00014~0xFFB00017) with
- proper values.
- If change boot ROM location to NOR or NAND flash, need write the IFC_CS0
- switch command by I2C.
-3. Send reset command.
- After reset, the new POR setting will be implemented.
-
-Two examples are given in below:
-Switch from NOR to NAND boot with default frequency:
- => i2c dev 0
- => i2c mw 18 1 f9
- => i2c mw 18 3 f0
- => mw.b ffb00011 0
- => mw.b ffb00017 1
- => reset
-Switch from NAND to NOR boot with Core/CCB/DDR (800/400/667 MHz):
- => i2c dev 0
- => i2c mw 18 1 f1
- => i2c mw 18 3 f0
- => mw.b ffb00011 0
- => mw.b ffb00014 2
- => mw.b ffb00015 5
- => mw.b ffb00016 3
- => mw.b ffb00017 f
- => reset
-
-
-Boot Linux from network using TFTP on P1010RDB
-==============================================
-Place uImage, p1010rdb.dtb and rootfs files in the TFTP disk area.
+Since pins multiplexing, TDM and CAN are muxed with SPI flash.
+SDHC is muxed with IFC. IFC and SPI flash are enabled by default.
+
+To enable TDM:
+=> setenv hwconfig fsl_p1010mux:tdm_can=tdm
+=> save;reset
+
+To enable FlexCAN:
+=> setenv hwconfig fsl_p1010mux:tdm_can=can
+=> save;reset
+
+To enable SDHC in case of NOR/NAND/SPI boot
+ a) For temporary use case in runtime without reboot system
+ run 'mux sdhc' in u-boot to validate SDHC with invalidating IFC.
+
+ b) For long-term use case
+ set 'esdhc' in hwconfig and save it.
+
+To enable IFC in case of SD boot
+ run 'mux ifc' in u-boot to validate IFC with invalidating SDHC.
+
+
+Build images for different boot mode:
+=====================================
+First, setup cross compile environment on your build host
+ $ export ARCH=powerpc
+ $ export CROSS_COMPILE=<your-compiler-path>/powerpc-linux-gnu-
+
+1. For NOR boot
+ $ make distclean
+ $ make P1010RDB-PB_NOR
+
+2. For NAND boot
+ $ make distclean
+ $ make P1010RDB-PB_NAND
+
+3. For SPI boot
+ $ make distclean
+ $ make P1010RDB-PB_SPIFLASH
+
+4. For SD boot
+ $ make distclean
+ $ make P1010RDB-PB_SDCARD
+
+
+Steps to burn images for different boot mode:
+=============================================
+1. NOR boot
+ => tftp 1000000 u-boot.bin
+ For bank0
+ => pro off all;era eff80000 efffffff;cp.b 1000000 eff80000 $filesize
+ set SW1[8]=0, SW4[1:4]= 1111 and SW3[3:4]= 00, then power on the board
+
+ For bank1
+ => pro off all;era eef80000 eeffffff;cp.b 1000000 eef80000 $filesize
+ set SW1[8]=1, SW4[1:4]= 1111 and SW3[3:4]= 00, then power on the board
+
+2. NAND boot
+ => tftp 1000000 u-boot-nand.bin
+ => nand erase 0 $filesize; nand write $loadaddr 0 $filesize
+ Set SW4[1:4]= 1010 and SW3[3:4]= 01, then power on the board
+
+3. SPI boot
+ 1) cat p1010rdb-config-header.bin u-boot.bin > u-boot-spi-combined.bin
+ 2) => tftp 1000000 u-boot-spi-combined.bin
+ 3) => sf probe 0; sf erase 0 100000; sf write 1000000 0 100000
+ set SW4[1:4]= 0110 and SW3[3:4]= 00, then power on the board
+
+4. SD boot
+ 1) cat p1010rdb-config-header.bin u-boot.bin > u-boot-sd-combined.bin
+ 2) => tftp 1000000 u-boot-sd-combined.bin
+ 3) => mux sdhc
+ 4) => mmc write 1000000 0 1050
+ set SW4[1:4]= 0111 and SW3[3:4]= 10, then power on the board
+
+
+Boot Linux from network using TFTP on P1010RDB-PB
+=================================================
+Place uImage, p1010rdb.dtb and rootfs files in the TFTP download path.
=> tftp 1000000 uImage
=> tftp 2000000 p1010rdb.dtb
=> tftp 3000000 rootfs.ext2.gz.uboot.p1010rdb
=> bootm 1000000 3000000 2000000
-Please contact your local field applications engineer or sales representative
-to obtain related documents, such as P1010-RDB User Guide for details.
+For more details, please refer to P1010RDB-PB User Guide and access website
+www.freescale.com and Freescale QorIQ SDK Infocenter document.
diff --git a/doc/README.p1010rdb b/doc/README.p1010rdb
deleted file mode 100644
index dee63d7..0000000
--- a/doc/README.p1010rdb
+++ /dev/null
@@ -1,199 +0,0 @@
-Overview
-=========
-The P1010RDB is a Freescale reference design board that hosts the P1010 SoC.
-
-The P1010 is a cost-effective, low-power, highly integrated host processor
-based on a Power Architecture e500v2 core (maximum core frequency 800/1000 MHz),
-that addresses the requirements of several routing, gateways, storage, consumer,
-and industrial applications. Applications of interest include the main CPUs and
-I/O processors in network attached storage (NAS), the voice over IP (VoIP)
-router/gateway, and wireless LAN (WLAN) and industrial controllers.
-
-The P1010RDB board features are as follows:
-Memory subsystem:
- - 1Gbyte unbuffered DDR3 SDRAM discrete devices (32-bit bus)
- - 32 Mbyte NOR flash single-chip memory
- - 32 Mbyte NAND flash memory
- - 256 Kbit M24256 I2C EEPROM
- - 16 Mbyte SPI memory
- - I2C Board EEPROM 128x8 bit memory
- - SD/MMC connector to interface with the SD memory card
-Interfaces:
- - PCIe:
- - Lane0: x1 mini-PCIe slot
- - Lane1: x1 PCIe standard slot
- - SATA:
- - 1 internal SATA connector to 2.5" 160G SATA2 HDD
- - 1 eSATA connector to rear panel
- - 10/100/1000 BaseT Ethernet ports:
- - eTSEC1, RGMII: one 10/100/1000 port using Vitesse VSC8641XKO
- - eTSEC2, SGMII: one 10/100/1000 port using Vitesse VSC8221
- - eTSEC3, SGMII: one 10/100/1000 port using Vitesse VSC8221
- - USB 2.0 port:
- - x1 USB2.0 port: via an ULPI PHY to micro-AB connector
- - x1 USB2.0 poort via an internal PHY to micro-AB connector
- - FlexCAN ports:
- - x2 DB-9 female connectors for FlexCAN bus(revision 2.0B)
- interface;
- - DUART interface:
- - DUART interface: supports two UARTs up to 115200 bps for
- console display
- - J45 connectors are used for these 2 UART ports.
- - TDM
- - 2 FXS ports connected via an external SLIC to the TDM
- interface. SLIC is controllled via SPI.
- - 1 FXO port connected via a relay to FXS for switchover to
- POTS
-Board connectors:
- - Mini-ITX power supply connector
- - JTAG/COP for debugging
-IEEE Std. 1588 signals for test and measurement
-Real-time clock on I2C bus
-POR
- - support critical POR setting changed via switch on board
-PCB
- - 6-layer routing (4-layer signals, 2-layer power and ground)
-
-
-Serial Port Configuration on P1010RDB
-=====================================
-Configure the serial port of the attached computer with the following values:
- -Data rate: 115200 bps
- -Number of data bits: 8
- -Parity: None
- -Number of Stop bits: 1
- -Flow Control: Hardware/None
-
-
-Settings of DIP-switch
-======================
- SW4[1:4]= 1111 and SW6[4]=0 for boot from 16bit NOR flash
- SW4[1:4]= 1000 and SW6[4]=1 for boot from 8bit NAND flash
- SW4[1:4]= 0110 and SW6[4]=0 for boot from SPI flash
-Note: 1 stands for 'on', 0 stands for 'off'
-
-
-Setting of hwconfig
-===================
-If FlexCAN or TDM is needed, please set "fsl_p1010mux:tdm_can=can" or
-"fsl_p1010mux:tdm_can=tdm" explicitly in u-booot prompt as below for example:
-setenv hwconfig "fsl_p1010mux:tdm_can=tdm;usb1:dr_mode=host,phy_type=utmi"
-By default, don't set fsl_p1010mux:tdm_can, in this case, spi chip selection
-is set to spi-flash instead of to SLIC/TDM/DAC and tdm_can_sel is set to TDM
-instead of to CAN/UART1.
-
-
-Build and burn u-boot to NOR flash
-==================================
-1. Build u-boot.bin image
- export ARCH=powerpc
- export CROSS_COMPILE=/your_path/powerpc-linux-gnu-
- make P1010RDB_NOR
-
-2. Burn u-boot.bin into NOR flash
- => tftp $loadaddr $uboot
- => protect off eff80000 +$filesize
- => erase eff80000 +$filesize
- => cp.b $loadaddr eff80000 $filesize
-
-3. Check SW4[1:4]= 1111 and SW6[4]=0, then power on.
-
-
-Alternate NOR bank
-============================
-1. Burn u-boot.bin into alternate NOR bank
- => tftp $loadaddr $uboot
- => protect off eef80000 +$filesize
- => erase eef80000 +$filesize
- => cp.b $loadaddr eef80000 $filesize
-
-2. Switch to alternate NOR bank
- => mw.b ffb00009 1
- => reset
- or set SW1[8]= ON
-
-SW1[8]= OFF: Upper bank used for booting start
-SW1[8]= ON: Lower bank used for booting start
-CPLD NOR bank selection register address 0xFFB00009 Bit[0]:
-0 - boot from upper 4 sectors
-1 - boot from lower 4 sectors
-
-
-Build and burn u-boot to NAND flash
-===================================
-1. Build u-boot.bin image
- export ARCH=powerpc
- export CROSS_COMPILE=/your_path/powerpc-linux-gnu-
- make P1010RDB_NAND
-
-2. Burn u-boot-nand.bin into NAND flash
- => tftp $loadaddr $uboot-nand
- => nand erase 0 $filesize
- => nand write $loadaddr 0 $filesize
-
-3. Check SW4[1:4]= 1000 and SW6[4]=1, then power on.
-
-
-
-Build and burn u-boot to SPI flash
-==================================
-1. Build u-boot-spi.bin image
- make P1010RDB_SPIFLASH_config; make
- Boot up kernel with rootfs.ext2.gz.uboot.p1010rdb
- Download u-boot.bin to linux and you can find some config files
- under /usr/share such as config_xx.dat. Do below command:
- boot_format config_ddr3_1gb_p1010rdb_800M.dat u-boot.bin -spi \
- u-boot-spi.bin
- to generate u-boot-spi.bin.
-
-2. Burn u-boot-spi.bin into SPI flash
- => tftp $loadaddr $uboot-spi
- => sf erase 0 100000
- => sf write $loadaddr 0 $filesize
-
-3. Check SW4[1:4]= 0110 and SW6[4]=0, then power on.
-
-
-
-CPLD POR setting registers
-==========================
-1. Set POR switch selection register (addr 0xFFB00011) to 0.
-2. Write CPLD POR registers (BCSR0~BCSR3, addr 0xFFB00014~0xFFB00017) with
- proper values.
- If change boot ROM location to NOR or NAND flash, need write the IFC_CS0
- switch command by I2C.
-3. Send reset command.
- After reset, the new POR setting will be implemented.
-
-Two examples are given in below:
-Switch from NOR to NAND boot with default frequency:
- => i2c dev 0
- => i2c mw 18 1 f9
- => i2c mw 18 3 f0
- => mw.b ffb00011 0
- => mw.b ffb00017 1
- => reset
-Switch from NAND to NOR boot with Core/CCB/DDR (800/400/667 MHz):
- => i2c dev 0
- => i2c mw 18 1 f1
- => i2c mw 18 3 f0
- => mw.b ffb00011 0
- => mw.b ffb00014 2
- => mw.b ffb00015 5
- => mw.b ffb00016 3
- => mw.b ffb00017 f
- => reset
-
-
-
-Boot Linux from network using TFTP on P1010RDB
-==============================================
-Place uImage, p1010rdb.dtb and rootfs files in the TFTP disk area.
- => tftp 1000000 uImage
- => tftp 2000000 p1010rdb.dtb
- => tftp 3000000 rootfs.ext2.gz.uboot.p1010rdb
- => bootm 1000000 3000000 2000000
-
-
-Please contact your local field applications engineer or sales representative
-to obtain related documents, such as P1010-RDB User Guide for details.
--
1.8.0
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