The T2080QDS is a high-performance computing evaluation, development and test platform supporting the T2080 QorIQ Power Architecture processor. T2080 SoC Overview ------------------ The T2080 QorIQ multicore processor combines four dual-threaded e6500 Power Architecture processor cores with high-performance datapath acceleration logic and network and peripheral bus interfaces required for networking, telecom/datacom, wireless infrastructure, and mil/aerospace applications. T2080 includes the following functions and features: - Four dual-threads 64-bit Power architecture e6500 cores, up to 1.8GHz - 2MB L2 cache and 512KB CoreNet platform cache (CPC) - Hierarchical interconnect fabric - One 32-/64-bit DDR3/3L SDRAM memory controllers with ECC and interleaving - Data Path Acceleration Architecture (DPAA) incorporating acceleration - 16 SerDes lanes up to 10.3125 GHz - 8 Ethernet interfaces, supporting combinations of the following: - Up to four 10 Gbps Ethernet MACs - Up to eight 1 Gbps Ethernet MACs - Up to four 2.5 Gbps Ethernet MACs - High-speed peripheral interfaces - Four PCI Express controllers (two PCIe 2.0 and two PCIe 3.0 with SR-IOV) - Two Serial RapidIO 2.0 controllers/ports running at up to 5 GHz - Additional peripheral interfaces - Two serial ATA (SATA 2.0) controllers - Two high-speed USB 2.0 controllers with integrated PHY - Enhanced secure digital host controller (SD/SDHC/SDXC/eMMC) - Enhanced serial peripheral interface (eSPI) - Four I2C controllers - Four 2-pin UARTs or two 4-pin UARTs - Integrated Flash Controller supporting NAND and NOR flash - Three eight-channel DMA engines - Support for hardware virtualization and partitioning enforcement - QorIQ Platform's Trust Architecture 2.0 Differences between T2080 and T2081 ----------------------------------- Feature T2080 T2081 1G Ethernet numbers: 8 6 10G Ethernet numbers: 4 2 SerDes lanes: 16 8 Serial RapidIO,RMan: 2 no SATA Controller: 2 no Aurora: yes no SoC Package: 896-pins 780-pins T2080QDS feature overview ------------------------- Processor: - T2080 SoC integrating four 64-bit dual-threads e6500 cores up to 1.8GHz Memory: - Single memory controller capable of supporting DDR3 and DDR3-LV devices - Two DDR3 DIMMs up to 4GB, Dual rank @ 2133MT/s and ECC support Ethernet interfaces: - Two 1Gbps RGMII on-board ports - Four 10Gbps XFI on-board cages - 1Gbps/2.5Gbps SGMII Riser card - 10Gbps XAUI Riser card Accelerator: - DPAA components consist of FMan, BMan, QMan, PME, DCE and SEC SerDes: - 16 lanes up to 10.3125GHz - Supports Aurora debug, PEX, SATA, SGMII, sRIO, HiGig, XFI and XAUI IFC: - 128MB NOR Flash, 512MB NAND Flash, PromJet debug port and FPGA eSPI: - Three SPI flash (16MB N25Q128A + 16MB EN25S64 + 512KB SST25WF040) USB: - Two USB2.0 ports with internal PHY (one Type-A + one micro Type-AB) PCIE: - Four PCI Express controllers (two PCIe 2.0 and two PCIe 3.0 with SR-IOV) SATA: - Two SATA 2.0 ports on-board SRIO: - Two Serial RapidIO 2.0 ports up to 5 GHz eSDHC: - Supports SD/SDHC/SDXC/eMMC Card I2C: - Four I2C controllers. UART: - Dual 4-pins UART serial ports System Logic: - QIXIS-II FPGA system controll Debug Features: - Support Legacy, COP/JTAG, Aurora, Event and EVT XFI: - XFI is supported on T2080QDS through Lane A/B/C/D on Serdes 1 routed to a on-board SFP+ cages, which to house optical module (fiber cable) or direct attach cable(copper), the copper cable is used to emulate 10GBASE-KR scenario. So, for XFI usage, there are two scenarios, one will use fiber cable, another will use copper cable. An hwconfig env "fsl_10gkr_copper" is introduced to indicate a XFI port will use copper cable, and U-Boot will fixup the dtb accordingly. It's used as: fsl_10gkr_copper:<10g_mac_name> The <10g_mac_name> can be fm1_10g1, fm1_10g2, fm1_10g3, fm1_10g4, they do not have to be coexist in hwconfig. If a MAC is listed in the env "fsl_10gkr_copper", it will use copper cable, otherwise, fiber cable will be used by default. for ex. set "fsl_10gkr_copper:fm1_10g1,fm1_10g2,fm1_10g3,fm1_10g4" in hwconfig, then both four XFI ports will use copper cable. set "fsl_10gkr_copper:fm1_10g1,fm1_10g2" in hwconfig, then first two XFI ports will use copper cable, the other two XFI ports will use fiber cable. 1000BASE-KX(1G-KX): - T2080QDS can support 1G-KX by using SGMII protocol, but serdes lane runs in 1G-KX mode. By default, the lane runs in SGMII mode, to set a lane in 1G-KX mode, need to set corresponding bit in SerDes Protocol Configuration Register 1 (PCCR1), and U-Boot fixup the dtb for kernel to do proper initialization. Hwconfig "fsl_1gkx" is used to indicate a lane runs in 1G-KX mode, MAC 1/2/5/6/9/10 are available for 1G-KX, MAC 3/4 run in RGMII mode. To set a MAC to use 1G-KX mode, set its' corresponding env in "fsl_1gkx", 'fm1_1g1' stands for MAC 1, 'fm1_1g2' stands for MAC 2, etc. For ex. set "fsl_1gkx:fm1_1g1,fm1_1g2,fm1_1g5,fm1_1g6,fm1_1g9,fm1_1g10" in hwconfig, MAC 1/2/5/6/9/10 will use 1G-KX mode. System Memory map ---------------- Start Address End Address Description Size 0xF_FFDF_0000 0xF_FFDF_0FFF IFC - CPLD 4KB 0xF_FF80_0000 0xF_FF80_FFFF IFC - NAND Flash 64KB 0xF_FE00_0000 0xF_FEFF_FFFF CCSRBAR 16MB 0xF_F803_0000 0xF_F803_FFFF PCI Express 4 I/O Space 64KB 0xF_F802_0000 0xF_F802_FFFF PCI Express 3 I/O Space 64KB 0xF_F801_0000 0xF_F801_FFFF PCI Express 2 I/O Space 64KB 0xF_F800_0000 0xF_F800_FFFF PCI Express 1 I/O Space 64KB 0xF_F600_0000 0xF_F7FF_FFFF Queue manager software portal 32MB 0xF_F400_0000 0xF_F5FF_FFFF Buffer manager software portal 32MB 0xF_E800_0000 0xF_EFFF_FFFF IFC - NOR Flash 128MB 0xF_0000_0000 0xF_003F_FFFF DCSR 4MB 0xC_4000_0000 0xC_4FFF_FFFF PCI Express 4 Mem Space 256MB 0xC_3000_0000 0xC_3FFF_FFFF PCI Express 3 Mem Space 256MB 0xC_2000_0000 0xC_2FFF_FFFF PCI Express 2 Mem Space 256MB 0xC_0000_0000 0xC_1FFF_FFFF PCI Express 1 Mem Space 512MB 0x0_0000_0000 0x0_ffff_ffff DDR 4GB 128M NOR Flash memory Map ------------------------- Start Address End Address Definition Max size 0xEFF40000 0xEFFFFFFF U-Boot (current bank) 768KB 0xEFF20000 0xEFF3FFFF U-Boot env (current bank) 128KB 0xEFF00000 0xEFF1FFFF FMAN Ucode (current bank) 128KB 0xED300000 0xEFEFFFFF rootfs (alt bank) 44MB 0xEC800000 0xEC8FFFFF Hardware device tree (alt bank) 1MB 0xEC020000 0xEC7FFFFF Linux.uImage (alt bank) 7MB + 875KB 0xEC000000 0xEC01FFFF RCW (alt bank) 128KB 0xEBF40000 0xEBFFFFFF U-Boot (alt bank) 768KB 0xEBF20000 0xEBF3FFFF U-Boot env (alt bank) 128KB 0xEBF00000 0xEBF1FFFF FMAN ucode (alt bank) 128KB 0xE9300000 0xEBEFFFFF rootfs (current bank) 44MB 0xE8800000 0xE88FFFFF Hardware device tree (cur bank) 1MB 0xE8020000 0xE86FFFFF Linux.uImage (current bank) 7MB + 875KB 0xE8000000 0xE801FFFF RCW (current bank) 128KB Software configurations and board settings ------------------------------------------ 1. NOR boot: a. build NOR boot image $ make T2080QDS_config $ make b. program u-boot.bin image to NOR flash => tftp 1000000 u-boot.bin => pro off all;era eff40000 efffffff;cp.b 1000000 eff40000 $filesize set SW1[1:8] = '00010011', SW2[1] = '1', SW6[1:4] = '0000' for NOR boot Switching between default bank0 and alternate bank4 on NOR flash To change boot source to vbank4: by software: run command 'qixis_reset altbank' in U-Boot. by DIP-switch: set SW6[1:4] = '0100' To change boot source to vbank0: by software: run command 'qixis_reset' in U-Boot. by DIP-Switch: set SW6[1:4] = '0000' 2. NAND Boot: a. build PBL image for NAND boot $ make T2080QDS_NAND_config $ make b. program u-boot-with-spl-pbl.bin to NAND flash => tftp 1000000 u-boot-with-spl-pbl.bin => nand erase 0 $filesize => nand write 1000000 0 $filesize set SW1[1:8] = '10000010', SW2[1] = '0' and SW6[1:4] = '1001' for NAND boot 3. SPI Boot: a. build PBL image for SPI boot $ make T2080QDS_SPIFLASH_config $ make b. program u-boot-with-spl-pbl.bin to SPI flash => tftp 1000000 u-boot-with-spl-pbl.bin => sf probe 0 => sf erase 0 f0000 => sf write 1000000 0 $filesize set SW1[1:8] = '00100010', SW2[1] ='1' for SPI boot 4. SD Boot: a. build PBL image for SD boot $ make T2080QDS_SDCARD_config $ make b. program u-boot-with-spl-pbl.bin to SD/MMC card => tftp 1000000 u-boot-with-spl-pbl.bin => mmc write 1000000 8 0x800 => tftp 1000000 fsl_fman_ucode_T2080_xx.bin => mmc write 1000000 0x820 80 set SW1[1:8] = '00100000', SW2[1] = '0' for SD boot 2-stage NAND/SPI/SD boot loader ------------------------------- PBL initializes the internal CPC-SRAM and copy SPL(160K) to SRAM. SPL further initializes DDR using SPD and environment variables and copy U-Boot(768 KB) from NAND/SPI/SD device to DDR. Finally SPL transers control to U-Boot for futher booting. SPL has following features: - Executes within 256K - No relocation required Run time view of SPL framework ------------------------------------------------- |Area | Address | ------------------------------------------------- |SecureBoot header | 0xFFFC0000 (32KB) | ------------------------------------------------- |GD, BD | 0xFFFC8000 (4KB) | ------------------------------------------------- |ENV | 0xFFFC9000 (8KB) | ------------------------------------------------- |HEAP | 0xFFFCB000 (50KB) | ------------------------------------------------- |STACK | 0xFFFD8000 (22KB) | ------------------------------------------------- |U-Boot SPL | 0xFFFD8000 (160KB) | ------------------------------------------------- NAND Flash memory Map on T2080QDS -------------------------------------------------------------- Start End Definition Size 0x000000 0x0FFFFF U-Boot img 1MB (2 blocks) 0x100000 0x17FFFF U-Boot env 512KB (1 block) 0x180000 0x1FFFFF FMAN ucode 512KB (1 block) Micro SD Card memory Map on T2080QDS ---------------------------------------------------- Block #blocks Definition Size 0x008 2048 U-Boot img 1MB 0x800 0016 U-Boot env 8KB 0x820 0128 FMAN ucode 64KB SPI Flash memory Map on T2080QDS ---------------------------------------------------- Start End Definition Size 0x000000 0x0FFFFF U-Boot img 1MB 0x100000 0x101FFF U-Boot env 8KB 0x110000 0x11FFFF FMAN ucode 64KB How to update the ucode of Freescale FMAN ----------------------------------------- => tftp 1000000 fsl_fman_ucode_t2080_xx.bin => pro off all;erase 0xeff00000 0xeff1ffff;cp 1000000 0xeff00000 $filesize For more details, please refer to T2080QDS User Guide and access website www.freescale.com and Freescale QorIQ SDK Infocenter document.