u-boot/board/amcc/yucca/yucca.c

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/*
* (C) Copyright 2006
* Wolfgang Denk, DENX Software Engineering, wd@denx.de.
*
* See file CREDITS for list of people who contributed to this
* project.
*
* 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., 59 Temple Place, Suite 330, Boston,
* MA 02111-1307 USA
*
* Port to AMCC-440SPE Evaluation Board SOP - April 2005
*
* PCIe supporting routines derived from Linux 440SPe PCIe driver.
*/
#include <common.h>
#include <ppc4xx.h>
#include <i2c.h>
#include <netdev.h>
#include <asm/processor.h>
#include <asm/io.h>
#include <asm/4xx_pcie.h>
#include "yucca.h"
DECLARE_GLOBAL_DATA_PTR;
void fpga_init (void);
#define DEBUG_ENV
#ifdef DEBUG_ENV
#define DEBUGF(fmt,args...) printf(fmt ,##args)
#else
#define DEBUGF(fmt,args...)
#endif
#define FALSE 0
#define TRUE 1
int board_early_init_f (void)
{
/*----------------------------------------------------------------------------+
| Define Boot devices
+----------------------------------------------------------------------------*/
#define BOOT_FROM_SMALL_FLASH 0x00
#define BOOT_FROM_LARGE_FLASH_OR_SRAM 0x01
#define BOOT_FROM_PCI 0x02
#define BOOT_DEVICE_UNKNOWN 0x03
/*----------------------------------------------------------------------------+
| EBC Devices Characteristics
| Peripheral Bank Access Parameters - EBC_BxAP
| Peripheral Bank Configuration Register - EBC_BxCR
+----------------------------------------------------------------------------*/
/*
* Small Flash and FRAM
* BU Value
* BxAP : 0x03800000 - 0 00000111 0 00 00 00 00 00 000 0 0 0 0 00000
* B0CR : 0xff098000 - BAS = ff0 - 100 11 00 0000000000000
* B2CR : 0xe7098000 - BAS = e70 - 100 11 00 0000000000000
*/
#define EBC_BXAP_SMALL_FLASH EBC_BXAP_BME_DISABLED | \
EBC_BXAP_TWT_ENCODE(7) | \
EBC_BXAP_BCE_DISABLE | \
EBC_BXAP_BCT_2TRANS | \
EBC_BXAP_CSN_ENCODE(0) | \
EBC_BXAP_OEN_ENCODE(0) | \
EBC_BXAP_WBN_ENCODE(0) | \
EBC_BXAP_WBF_ENCODE(0) | \
EBC_BXAP_TH_ENCODE(0) | \
EBC_BXAP_RE_DISABLED | \
EBC_BXAP_SOR_DELAYED | \
EBC_BXAP_BEM_WRITEONLY | \
EBC_BXAP_PEN_DISABLED
#define EBC_BXCR_SMALL_FLASH_CS0 EBC_BXCR_BAS_ENCODE(0xFF000000) | \
EBC_BXCR_BS_16MB | \
EBC_BXCR_BU_RW | \
EBC_BXCR_BW_8BIT
#define EBC_BXCR_SMALL_FLASH_CS2 EBC_BXCR_BAS_ENCODE(0xe7000000) | \
EBC_BXCR_BS_16MB | \
EBC_BXCR_BU_RW | \
EBC_BXCR_BW_8BIT
/*
* Large Flash and SRAM
* BU Value
* BxAP : 0x048ff240 - 0 00000111 0 00 00 00 00 00 000 0 0 0 0 00000
* B0CR : 0xff09a000 - BAS = ff0 - 100 11 01 0000000000000
* B2CR : 0xe709a000 - BAS = e70 - 100 11 01 0000000000000
*/
#define EBC_BXAP_LARGE_FLASH EBC_BXAP_BME_DISABLED | \
EBC_BXAP_TWT_ENCODE(7) | \
EBC_BXAP_BCE_DISABLE | \
EBC_BXAP_BCT_2TRANS | \
EBC_BXAP_CSN_ENCODE(0) | \
EBC_BXAP_OEN_ENCODE(0) | \
EBC_BXAP_WBN_ENCODE(0) | \
EBC_BXAP_WBF_ENCODE(0) | \
EBC_BXAP_TH_ENCODE(0) | \
EBC_BXAP_RE_DISABLED | \
EBC_BXAP_SOR_DELAYED | \
EBC_BXAP_BEM_WRITEONLY | \
EBC_BXAP_PEN_DISABLED
#define EBC_BXCR_LARGE_FLASH_CS0 EBC_BXCR_BAS_ENCODE(0xFF000000) | \
EBC_BXCR_BS_16MB | \
EBC_BXCR_BU_RW | \
EBC_BXCR_BW_16BIT
#define EBC_BXCR_LARGE_FLASH_CS2 EBC_BXCR_BAS_ENCODE(0xE7000000) | \
EBC_BXCR_BS_16MB | \
EBC_BXCR_BU_RW | \
EBC_BXCR_BW_16BIT
/*
* FPGA
* BU value :
* B1AP = 0x05895240 - 0 00001011 0 00 10 01 01 01 001 0 0 1 0 00000
* B1CR = 0xe201a000 - BAS = e20 - 000 11 01 00000000000000
*/
#define EBC_BXAP_FPGA EBC_BXAP_BME_DISABLED | \
EBC_BXAP_TWT_ENCODE(11) | \
EBC_BXAP_BCE_DISABLE | \
EBC_BXAP_BCT_2TRANS | \
EBC_BXAP_CSN_ENCODE(10) | \
EBC_BXAP_OEN_ENCODE(1) | \
EBC_BXAP_WBN_ENCODE(1) | \
EBC_BXAP_WBF_ENCODE(1) | \
EBC_BXAP_TH_ENCODE(1) | \
EBC_BXAP_RE_DISABLED | \
EBC_BXAP_SOR_DELAYED | \
EBC_BXAP_BEM_RW | \
EBC_BXAP_PEN_DISABLED
#define EBC_BXCR_FPGA_CS1 EBC_BXCR_BAS_ENCODE(0xe2000000) | \
EBC_BXCR_BS_1MB | \
EBC_BXCR_BU_RW | \
EBC_BXCR_BW_16BIT
unsigned long mfr;
/*
* Define Variables for EBC initialization depending on BOOTSTRAP option
*/
unsigned long sdr0_pinstp, sdr0_sdstp1 ;
unsigned long bootstrap_settings, ebc_data_width, boot_selection;
int computed_boot_device = BOOT_DEVICE_UNKNOWN;
/*-------------------------------------------------------------------+
| Initialize EBC CONFIG -
| Keep the Default value, but the bit PDT which has to be set to 1 ?TBC
| default value :
| 0x07C00000 - 0 0 000 1 1 1 1 1 0000 0 00000 000000000000
|
+-------------------------------------------------------------------*/
mtebc(xbcfg, EBC_CFG_LE_UNLOCK |
EBC_CFG_PTD_ENABLE |
EBC_CFG_RTC_16PERCLK |
EBC_CFG_ATC_PREVIOUS |
EBC_CFG_DTC_PREVIOUS |
EBC_CFG_CTC_PREVIOUS |
EBC_CFG_OEO_PREVIOUS |
EBC_CFG_EMC_DEFAULT |
EBC_CFG_PME_DISABLE |
EBC_CFG_PR_16);
/*-------------------------------------------------------------------+
|
| PART 1 : Initialize EBC Bank 1
| ==============================
| Bank1 is always associated to the EPLD.
| It has to be initialized prior to other banks settings computation
| since some board registers values may be needed to determine the
| boot type
|
+-------------------------------------------------------------------*/
mtebc(pb1ap, EBC_BXAP_FPGA);
mtebc(pb1cr, EBC_BXCR_FPGA_CS1);
/*-------------------------------------------------------------------+
|
| PART 2 : Determine which boot device was selected
| =================================================
|
| Read Pin Strap Register in PPC440SPe
| Result can either be :
| - Boot strap = boot from EBC 8bits => Small Flash
| - Boot strap = boot from PCI
| - Boot strap = IIC
| In case of boot from IIC, read Serial Device Strap Register1
|
| Result can either be :
| - Boot from EBC - EBC Bus Width = 8bits => Small Flash
| - Boot from EBC - EBC Bus Width = 16bits => Large Flash or SRAM
| - Boot from PCI
|
+-------------------------------------------------------------------*/
/* Read Pin Strap Register in PPC440SP */
mfsdr(SDR0_PINSTP, sdr0_pinstp);
bootstrap_settings = sdr0_pinstp & SDR0_PINSTP_BOOTSTRAP_MASK;
switch (bootstrap_settings) {
case SDR0_PINSTP_BOOTSTRAP_SETTINGS0:
/*
* Strapping Option A
* Boot from EBC - 8 bits , Small Flash
*/
computed_boot_device = BOOT_FROM_SMALL_FLASH;
break;
case SDR0_PINSTP_BOOTSTRAP_SETTINGS1:
/*
* Strappping Option B
* Boot from PCI
*/
computed_boot_device = BOOT_FROM_PCI;
break;
case SDR0_PINSTP_BOOTSTRAP_IIC_50_EN:
case SDR0_PINSTP_BOOTSTRAP_IIC_54_EN:
/*
* Strapping Option C or D
* Boot Settings in IIC EEprom address 0x50 or 0x54
* Read Serial Device Strap Register1 in PPC440SPe
*/
mfsdr(SDR0_SDSTP1, sdr0_sdstp1);
boot_selection = sdr0_sdstp1 & SDR0_SDSTP1_ERPN_MASK;
ebc_data_width = sdr0_sdstp1 & SDR0_SDSTP1_EBCW_MASK;
switch (boot_selection) {
case SDR0_SDSTP1_ERPN_EBC:
switch (ebc_data_width) {
case SDR0_SDSTP1_EBCW_16_BITS:
computed_boot_device =
BOOT_FROM_LARGE_FLASH_OR_SRAM;
break;
case SDR0_SDSTP1_EBCW_8_BITS :
computed_boot_device = BOOT_FROM_SMALL_FLASH;
break;
}
break;
case SDR0_SDSTP1_ERPN_PCI:
computed_boot_device = BOOT_FROM_PCI;
break;
default:
/* should not occure */
computed_boot_device = BOOT_DEVICE_UNKNOWN;
}
break;
default:
/* should not be */
computed_boot_device = BOOT_DEVICE_UNKNOWN;
break;
}
/*-------------------------------------------------------------------+
|
| PART 3 : Compute EBC settings depending on selected boot device
| ====== ======================================================
|
| Resulting EBC init will be among following configurations :
|
| - Boot from EBC 8bits => boot from Small Flash selected
| EBC-CS0 = Small Flash
| EBC-CS2 = Large Flash and SRAM
|
| - Boot from EBC 16bits => boot from Large Flash or SRAM
| EBC-CS0 = Large Flash or SRAM
| EBC-CS2 = Small Flash
|
| - Boot from PCI
| EBC-CS0 = not initialized to avoid address contention
| EBC-CS2 = same as boot from Small Flash selected
|
+-------------------------------------------------------------------*/
unsigned long ebc0_cs0_bxap_value = 0, ebc0_cs0_bxcr_value = 0;
unsigned long ebc0_cs2_bxap_value = 0, ebc0_cs2_bxcr_value = 0;
switch (computed_boot_device) {
/*-------------------------------------------------------------------*/
case BOOT_FROM_PCI:
/*-------------------------------------------------------------------*/
/*
* By Default CS2 is affected to LARGE Flash
* do not initialize SMALL FLASH to avoid address contention
* Large Flash
*/
ebc0_cs2_bxap_value = EBC_BXAP_LARGE_FLASH;
ebc0_cs2_bxcr_value = EBC_BXCR_LARGE_FLASH_CS2;
break;
/*-------------------------------------------------------------------*/
case BOOT_FROM_SMALL_FLASH:
/*-------------------------------------------------------------------*/
ebc0_cs0_bxap_value = EBC_BXAP_SMALL_FLASH;
ebc0_cs0_bxcr_value = EBC_BXCR_SMALL_FLASH_CS0;
/*
* Large Flash or SRAM
*/
/* ebc0_cs2_bxap_value = EBC_BXAP_LARGE_FLASH; */
ebc0_cs2_bxap_value = 0x048ff240;
ebc0_cs2_bxcr_value = EBC_BXCR_LARGE_FLASH_CS2;
break;
/*-------------------------------------------------------------------*/
case BOOT_FROM_LARGE_FLASH_OR_SRAM:
/*-------------------------------------------------------------------*/
ebc0_cs0_bxap_value = EBC_BXAP_LARGE_FLASH;
ebc0_cs0_bxcr_value = EBC_BXCR_LARGE_FLASH_CS0;
/* Small flash */
ebc0_cs2_bxap_value = EBC_BXAP_SMALL_FLASH;
ebc0_cs2_bxcr_value = EBC_BXCR_SMALL_FLASH_CS2;
break;
/*-------------------------------------------------------------------*/
default:
/*-------------------------------------------------------------------*/
/* BOOT_DEVICE_UNKNOWN */
break;
}
mtebc(pb0ap, ebc0_cs0_bxap_value);
mtebc(pb0cr, ebc0_cs0_bxcr_value);
mtebc(pb2ap, ebc0_cs2_bxap_value);
mtebc(pb2cr, ebc0_cs2_bxcr_value);
/*--------------------------------------------------------------------+
| Interrupt controller setup for the AMCC 440SPe Evaluation board.
+--------------------------------------------------------------------+
+---------------------------------------------------------------------+
|Interrupt| Source | Pol. | Sensi.| Crit. |
+---------+-----------------------------------+-------+-------+-------+
| IRQ 00 | UART0 | High | Level | Non |
| IRQ 01 | UART1 | High | Level | Non |
| IRQ 02 | IIC0 | High | Level | Non |
| IRQ 03 | IIC1 | High | Level | Non |
| IRQ 04 | PCI0X0 MSG IN | High | Level | Non |
| IRQ 05 | PCI0X0 CMD Write | High | Level | Non |
| IRQ 06 | PCI0X0 Power Mgt | High | Level | Non |
| IRQ 07 | PCI0X0 VPD Access | Rising| Edge | Non |
| IRQ 08 | PCI0X0 MSI level 0 | High | Lvl/ed| Non |
| IRQ 09 | External IRQ 15 - (PCI-Express) | pgm H | Pgm | Non |
| IRQ 10 | UIC2 Non-critical Int. | NA | NA | Non |
| IRQ 11 | UIC2 Critical Interrupt | NA | NA | Crit |
| IRQ 12 | PCI Express MSI Level 0 | Rising| Edge | Non |
| IRQ 13 | PCI Express MSI Level 1 | Rising| Edge | Non |
| IRQ 14 | PCI Express MSI Level 2 | Rising| Edge | Non |
| IRQ 15 | PCI Express MSI Level 3 | Rising| Edge | Non |
| IRQ 16 | UIC3 Non-critical Int. | NA | NA | Non |
| IRQ 17 | UIC3 Critical Interrupt | NA | NA | Crit |
| IRQ 18 | External IRQ 14 - (PCI-Express) | Pgm | Pgm | Non |
| IRQ 19 | DMA Channel 0 FIFO Full | High | Level | Non |
| IRQ 20 | DMA Channel 0 Stat FIFO | High | Level | Non |
| IRQ 21 | DMA Channel 1 FIFO Full | High | Level | Non |
| IRQ 22 | DMA Channel 1 Stat FIFO | High | Level | Non |
| IRQ 23 | I2O Inbound Doorbell | High | Level | Non |
| IRQ 24 | Inbound Post List FIFO Not Empt | High | Level | Non |
| IRQ 25 | I2O Region 0 LL PLB Write | High | Level | Non |
| IRQ 26 | I2O Region 1 LL PLB Write | High | Level | Non |
| IRQ 27 | I2O Region 0 HB PLB Write | High | Level | Non |
| IRQ 28 | I2O Region 1 HB PLB Write | High | Level | Non |
| IRQ 29 | GPT Down Count Timer | Rising| Edge | Non |
| IRQ 30 | UIC1 Non-critical Int. | NA | NA | Non |
| IRQ 31 | UIC1 Critical Interrupt | NA | NA | Crit. |
|----------------------------------------------------------------------
| IRQ 32 | Ext. IRQ 13 - (PCI-Express) |pgm (H)|pgm/Lvl| Non |
| IRQ 33 | MAL Serr | High | Level | Non |
| IRQ 34 | MAL Txde | High | Level | Non |
| IRQ 35 | MAL Rxde | High | Level | Non |
| IRQ 36 | DMC CE or DMC UE | High | Level | Non |
| IRQ 37 | EBC or UART2 | High |Lvl Edg| Non |
| IRQ 38 | MAL TX EOB | High | Level | Non |
| IRQ 39 | MAL RX EOB | High | Level | Non |
| IRQ 40 | PCIX0 MSI Level 1 | High |Lvl Edg| Non |
| IRQ 41 | PCIX0 MSI level 2 | High |Lvl Edg| Non |
| IRQ 42 | PCIX0 MSI level 3 | High |Lvl Edg| Non |
| IRQ 43 | L2 Cache | Risin | Edge | Non |
| IRQ 44 | GPT Compare Timer 0 | Risin | Edge | Non |
| IRQ 45 | GPT Compare Timer 1 | Risin | Edge | Non |
| IRQ 46 | GPT Compare Timer 2 | Risin | Edge | Non |
| IRQ 47 | GPT Compare Timer 3 | Risin | Edge | Non |
| IRQ 48 | GPT Compare Timer 4 | Risin | Edge | Non |
| IRQ 49 | Ext. IRQ 12 - PCI-X |pgm/Fal|pgm/Lvl| Non |
| IRQ 50 | Ext. IRQ 11 - |pgm (H)|pgm/Lvl| Non |
| IRQ 51 | Ext. IRQ 10 - |pgm (H)|pgm/Lvl| Non |
| IRQ 52 | Ext. IRQ 9 |pgm (H)|pgm/Lvl| Non |
| IRQ 53 | Ext. IRQ 8 |pgm (H)|pgm/Lvl| Non |
| IRQ 54 | DMA Error | High | Level | Non |
| IRQ 55 | DMA I2O Error | High | Level | Non |
| IRQ 56 | Serial ROM | High | Level | Non |
| IRQ 57 | PCIX0 Error | High | Edge | Non |
| IRQ 58 | Ext. IRQ 7- |pgm (H)|pgm/Lvl| Non |
| IRQ 59 | Ext. IRQ 6- |pgm (H)|pgm/Lvl| Non |
| IRQ 60 | EMAC0 Interrupt | High | Level | Non |
| IRQ 61 | EMAC0 Wake-up | High | Level | Non |
| IRQ 62 | Reserved | High | Level | Non |
| IRQ 63 | XOR | High | Level | Non |
|----------------------------------------------------------------------
| IRQ 64 | PE0 AL | High | Level | Non |
| IRQ 65 | PE0 VPD Access | Risin | Edge | Non |
| IRQ 66 | PE0 Hot Reset Request | Risin | Edge | Non |
| IRQ 67 | PE0 Hot Reset Request | Falli | Edge | Non |
| IRQ 68 | PE0 TCR | High | Level | Non |
| IRQ 69 | PE0 BusMaster VCO | Falli | Edge | Non |
| IRQ 70 | PE0 DCR Error | High | Level | Non |
| IRQ 71 | Reserved | N/A | N/A | Non |
| IRQ 72 | PE1 AL | High | Level | Non |
| IRQ 73 | PE1 VPD Access | Risin | Edge | Non |
| IRQ 74 | PE1 Hot Reset Request | Risin | Edge | Non |
| IRQ 75 | PE1 Hot Reset Request | Falli | Edge | Non |
| IRQ 76 | PE1 TCR | High | Level | Non |
| IRQ 77 | PE1 BusMaster VCO | Falli | Edge | Non |
| IRQ 78 | PE1 DCR Error | High | Level | Non |
| IRQ 79 | Reserved | N/A | N/A | Non |
| IRQ 80 | PE2 AL | High | Level | Non |
| IRQ 81 | PE2 VPD Access | Risin | Edge | Non |
| IRQ 82 | PE2 Hot Reset Request | Risin | Edge | Non |
| IRQ 83 | PE2 Hot Reset Request | Falli | Edge | Non |
| IRQ 84 | PE2 TCR | High | Level | Non |
| IRQ 85 | PE2 BusMaster VCO | Falli | Edge | Non |
| IRQ 86 | PE2 DCR Error | High | Level | Non |
| IRQ 87 | Reserved | N/A | N/A | Non |
| IRQ 88 | External IRQ(5) | Progr | Progr | Non |
| IRQ 89 | External IRQ 4 - Ethernet | Progr | Progr | Non |
| IRQ 90 | External IRQ 3 - PCI-X | Progr | Progr | Non |
| IRQ 91 | External IRQ 2 - PCI-X | Progr | Progr | Non |
| IRQ 92 | External IRQ 1 - PCI-X | Progr | Progr | Non |
| IRQ 93 | External IRQ 0 - PCI-X | Progr | Progr | Non |
| IRQ 94 | Reserved | N/A | N/A | Non |
| IRQ 95 | Reserved | N/A | N/A | Non |
|---------------------------------------------------------------------
| IRQ 96 | PE0 INTA | High | Level | Non |
| IRQ 97 | PE0 INTB | High | Level | Non |
| IRQ 98 | PE0 INTC | High | Level | Non |
| IRQ 99 | PE0 INTD | High | Level | Non |
| IRQ 100 | PE1 INTA | High | Level | Non |
| IRQ 101 | PE1 INTB | High | Level | Non |
| IRQ 102 | PE1 INTC | High | Level | Non |
| IRQ 103 | PE1 INTD | High | Level | Non |
| IRQ 104 | PE2 INTA | High | Level | Non |
| IRQ 105 | PE2 INTB | High | Level | Non |
| IRQ 106 | PE2 INTC | High | Level | Non |
| IRQ 107 | PE2 INTD | Risin | Edge | Non |
| IRQ 108 | PCI Express MSI Level 4 | Risin | Edge | Non |
| IRQ 109 | PCI Express MSI Level 5 | Risin | Edge | Non |
| IRQ 110 | PCI Express MSI Level 6 | Risin | Edge | Non |
| IRQ 111 | PCI Express MSI Level 7 | Risin | Edge | Non |
| IRQ 116 | PCI Express MSI Level 12 | Risin | Edge | Non |
| IRQ 112 | PCI Express MSI Level 8 | Risin | Edge | Non |
| IRQ 113 | PCI Express MSI Level 9 | Risin | Edge | Non |
| IRQ 114 | PCI Express MSI Level 10 | Risin | Edge | Non |
| IRQ 115 | PCI Express MSI Level 11 | Risin | Edge | Non |
| IRQ 117 | PCI Express MSI Level 13 | Risin | Edge | Non |
| IRQ 118 | PCI Express MSI Level 14 | Risin | Edge | Non |
| IRQ 119 | PCI Express MSI Level 15 | Risin | Edge | Non |
| IRQ 120 | PCI Express MSI Level 16 | Risin | Edge | Non |
| IRQ 121 | PCI Express MSI Level 17 | Risin | Edge | Non |
| IRQ 122 | PCI Express MSI Level 18 | Risin | Edge | Non |
| IRQ 123 | PCI Express MSI Level 19 | Risin | Edge | Non |
| IRQ 124 | PCI Express MSI Level 20 | Risin | Edge | Non |
| IRQ 125 | PCI Express MSI Level 21 | Risin | Edge | Non |
| IRQ 126 | PCI Express MSI Level 22 | Risin | Edge | Non |
| IRQ 127 | PCI Express MSI Level 23 | Risin | Edge | Non |
+---------+-----------------------------------+-------+-------+------*/
/*--------------------------------------------------------------------+
| Put UICs in PowerPC440SPemode.
| Initialise UIC registers. Clear all interrupts. Disable all
| interrupts.
| Set critical interrupt values. Set interrupt polarities. Set
| interrupt trigger levels. Make bit 0 High priority. Clear all
| interrupts again.
+-------------------------------------------------------------------*/
mtdcr (uic3sr, 0xffffffff); /* Clear all interrupts */
mtdcr (uic3er, 0x00000000); /* disable all interrupts */
mtdcr (uic3cr, 0x00000000); /* Set Critical / Non Critical
* interrupts */
mtdcr (uic3pr, 0xffffffff); /* Set Interrupt Polarities */
mtdcr (uic3tr, 0x001fffff); /* Set Interrupt Trigger Levels */
mtdcr (uic3vr, 0x00000001); /* Set Vect base=0,INT31 Highest
* priority */
mtdcr (uic3sr, 0x00000000); /* clear all interrupts */
mtdcr (uic3sr, 0xffffffff); /* clear all interrupts */
mtdcr (uic2sr, 0xffffffff); /* Clear all interrupts */
mtdcr (uic2er, 0x00000000); /* disable all interrupts */
mtdcr (uic2cr, 0x00000000); /* Set Critical / Non Critical
* interrupts */
mtdcr (uic2pr, 0xebebebff); /* Set Interrupt Polarities */
mtdcr (uic2tr, 0x74747400); /* Set Interrupt Trigger Levels */
mtdcr (uic2vr, 0x00000001); /* Set Vect base=0,INT31 Highest
* priority */
mtdcr (uic2sr, 0x00000000); /* clear all interrupts */
mtdcr (uic2sr, 0xffffffff); /* clear all interrupts */
mtdcr (uic1sr, 0xffffffff); /* Clear all interrupts */
mtdcr (uic1er, 0x00000000); /* disable all interrupts */
mtdcr (uic1cr, 0x00000000); /* Set Critical / Non Critical
* interrupts */
mtdcr (uic1pr, 0xffffffff); /* Set Interrupt Polarities */
mtdcr (uic1tr, 0x001f8040); /* Set Interrupt Trigger Levels */
mtdcr (uic1vr, 0x00000001); /* Set Vect base=0,INT31 Highest
* priority */
mtdcr (uic1sr, 0x00000000); /* clear all interrupts */
mtdcr (uic1sr, 0xffffffff); /* clear all interrupts */
mtdcr (uic0sr, 0xffffffff); /* Clear all interrupts */
mtdcr (uic0er, 0x00000000); /* disable all interrupts excepted
* cascade to be checked */
mtdcr (uic0cr, 0x00104001); /* Set Critical / Non Critical
* interrupts */
mtdcr (uic0pr, 0xffffffff); /* Set Interrupt Polarities */
mtdcr (uic0tr, 0x010f0004); /* Set Interrupt Trigger Levels */
mtdcr (uic0vr, 0x00000001); /* Set Vect base=0,INT31 Highest
* priority */
mtdcr (uic0sr, 0x00000000); /* clear all interrupts */
mtdcr (uic0sr, 0xffffffff); /* clear all interrupts */
ppc4xx: Enable hardware-fix for PCI/DMA errata on AMCC 440SP/SPe boards This patch enables the hardware-fix for the PCI/DMA errata's 19+22 by setting the FIXD bit in the SDR0_MFR register. Here a description of the symptoms: Problem Description ------------------------------ If a DMA is performed between memory and PCI with the DMA 1 Controller using prefetch, and as a result uses a special purpose buffer selected by the PCIXn Bridge Options 1 Register (PCIXn_BRDGOPT1[RBP7] - bits 31-29), the first part of the transfer sequence is performed twice. The PPC440SPe PCI Controller requests more data than was needed such that in the case of enforce memory protection, a host CPU exception can occur. No data is corrupted, because data transfer is stopped in the PCI Controller. Prefetch enable is specified by setting DMA Configuration Register (I2O0_DMAx_CFG[DXEPD] - bit 31) to 0. Behavior that may be observed in a running system --------------------------------------------------------------------------- 1. DMA performance is decreased because of the double access on the PCI bus interface. 2. If an illegal access to some address on the PCI bus is detected at the system level, a machine check or similar system error may occur. Workarounds Available ---------------------------------- 1. Do not program prefetch. Note that a prefetch command cannot be programmed without selecting a special purpose buffer. 2. To avoid crossing a physical boundary of the PCI slave device, add 512 bytes of address to the PCI address range. This patch was originally provided by Pravin M. Bathija <pbathija@amcc.com> from AMCC and slighly changed. Signed-off-by: Pravin M. Bathija <pbathija@amcc.com> Signed-off-by: Stefan Roese <sr@denx.de>
2007-12-06 04:58:43 +00:00
mfsdr(sdr_mfr, mfr);
mfr |= SDR0_MFR_FIXD; /* Workaround for PCI/DMA */
mtsdr(sdr_mfr, mfr);
fpga_init();
return 0;
}
int checkboard (void)
{
char *s = getenv("serial#");
printf("Board: Yucca - AMCC 440SPe Evaluation Board");
if (s != NULL) {
puts(", serial# ");
puts(s);
}
putc('\n');
return 0;
}
/*
* Override the default functions in cpu/ppc4xx/44x_spd_ddr2.c with
* board specific values.
*/
static int ppc440spe_rev_a(void)
{
if ((get_pvr() == PVR_440SPe_6_RA) || (get_pvr() == PVR_440SPe_RA))
return 1;
else
return 0;
}
u32 ddr_wrdtr(u32 default_val) {
/*
* Yucca boards with 440SPe rev. A need a slightly different setup
* for the MCIF0_WRDTR register.
*/
if (ppc440spe_rev_a())
return (SDRAM_WRDTR_LLWP_1_CYC | SDRAM_WRDTR_WTR_270_DEG_ADV);
return default_val;
}
u32 ddr_clktr(u32 default_val) {
/*
* Yucca boards with 440SPe rev. A need a slightly different setup
* for the MCIF0_CLKTR register.
*/
if (ppc440spe_rev_a())
return (SDRAM_CLKTR_CLKP_180_DEG_ADV);
return default_val;
}
/*************************************************************************
* pci_pre_init
*
* This routine is called just prior to registering the hose and gives
* the board the opportunity to check things. Returning a value of zero
* indicates that things are bad & PCI initialization should be aborted.
*
* Different boards may wish to customize the pci controller structure
* (add regions, override default access routines, etc) or perform
* certain pre-initialization actions.
*
************************************************************************/
#if defined(CONFIG_PCI)
int pci_pre_init(struct pci_controller * hose )
{
unsigned long strap;
/*-------------------------------------------------------------------+
* The yucca board is always configured as the host & requires the
* PCI arbiter to be enabled.
*-------------------------------------------------------------------*/
mfsdr(sdr_sdstp1, strap);
if( (strap & SDR0_SDSTP1_PAE_MASK) == 0 ) {
printf("PCI: SDR0_STRP1[%08lX] - PCI Arbiter disabled.\n",strap);
return 0;
}
return 1;
}
#endif /* defined(CONFIG_PCI) */
/*************************************************************************
* pci_target_init
*
* The bootstrap configuration provides default settings for the pci
* inbound map (PIM). But the bootstrap config choices are limited and
* may not be sufficient for a given board.
*
************************************************************************/
#if defined(CONFIG_PCI) && defined(CFG_PCI_TARGET_INIT)
void pci_target_init(struct pci_controller * hose )
{
/*-------------------------------------------------------------------+
* Disable everything
*-------------------------------------------------------------------*/
out32r( PCIX0_PIM0SA, 0 ); /* disable */
out32r( PCIX0_PIM1SA, 0 ); /* disable */
out32r( PCIX0_PIM2SA, 0 ); /* disable */
out32r( PCIX0_EROMBA, 0 ); /* disable expansion rom */
/*-------------------------------------------------------------------+
* Map all of SDRAM to PCI address 0x0000_0000. Note that the 440
* strapping options to not support sizes such as 128/256 MB.
*-------------------------------------------------------------------*/
out32r( PCIX0_PIM0LAL, CFG_SDRAM_BASE );
out32r( PCIX0_PIM0LAH, 0 );
out32r( PCIX0_PIM0SA, ~(gd->ram_size - 1) | 1 );
out32r( PCIX0_BAR0, 0 );
/*-------------------------------------------------------------------+
* Program the board's subsystem id/vendor id
*-------------------------------------------------------------------*/
out16r( PCIX0_SBSYSVID, CFG_PCI_SUBSYS_VENDORID );
out16r( PCIX0_SBSYSID, CFG_PCI_SUBSYS_DEVICEID );
out16r( PCIX0_CMD, in16r(PCIX0_CMD) | PCI_COMMAND_MEMORY );
}
#endif /* defined(CONFIG_PCI) && defined(CFG_PCI_TARGET_INIT) */
#if defined(CONFIG_PCI)
/*************************************************************************
* is_pci_host
*
* This routine is called to determine if a pci scan should be
* performed. With various hardware environments (especially cPCI and
* PPMC) it's insufficient to depend on the state of the arbiter enable
* bit in the strap register, or generic host/adapter assumptions.
*
* Rather than hard-code a bad assumption in the general 440 code, the
* 440 pci code requires the board to decide at runtime.
*
* Return 0 for adapter mode, non-zero for host (monarch) mode.
*
*
************************************************************************/
int is_pci_host(struct pci_controller *hose)
{
/* The yucca board is always configured as host. */
return 1;
}
static int yucca_pcie_card_present(int port)
{
u16 reg;
reg = in_be16((u16 *)FPGA_REG1C);
switch(port) {
case 0:
return !(reg & FPGA_REG1C_PE0_PRSNT);
case 1:
return !(reg & FPGA_REG1C_PE1_PRSNT);
case 2:
return !(reg & FPGA_REG1C_PE2_PRSNT);
default:
return 0;
}
}
/*
* For the given slot, set rootpoint mode, send power to the slot,
* turn on the green LED and turn off the yellow LED, enable the clock
* and turn off reset.
*/
void yucca_setup_pcie_fpga_rootpoint(int port)
{
u16 power, clock, green_led, yellow_led, reset_off, rootpoint, endpoint;
switch(port) {
case 0:
rootpoint = FPGA_REG1C_PE0_ROOTPOINT;
endpoint = 0;
power = FPGA_REG1A_PE0_PWRON;
green_led = FPGA_REG1A_PE0_GLED;
clock = FPGA_REG1A_PE0_REFCLK_ENABLE;
yellow_led = FPGA_REG1A_PE0_YLED;
reset_off = FPGA_REG1C_PE0_PERST;
break;
case 1:
rootpoint = 0;
endpoint = FPGA_REG1C_PE1_ENDPOINT;
power = FPGA_REG1A_PE1_PWRON;
green_led = FPGA_REG1A_PE1_GLED;
clock = FPGA_REG1A_PE1_REFCLK_ENABLE;
yellow_led = FPGA_REG1A_PE1_YLED;
reset_off = FPGA_REG1C_PE1_PERST;
break;
case 2:
rootpoint = 0;
endpoint = FPGA_REG1C_PE2_ENDPOINT;
power = FPGA_REG1A_PE2_PWRON;
green_led = FPGA_REG1A_PE2_GLED;
clock = FPGA_REG1A_PE2_REFCLK_ENABLE;
yellow_led = FPGA_REG1A_PE2_YLED;
reset_off = FPGA_REG1C_PE2_PERST;
break;
default:
return;
}
out_be16((u16 *)FPGA_REG1A,
~(power | clock | green_led) &
(yellow_led | in_be16((u16 *)FPGA_REG1A)));
out_be16((u16 *)FPGA_REG1C,
~(endpoint | reset_off) &
(rootpoint | in_be16((u16 *)FPGA_REG1C)));
/*
* Leave device in reset for a while after powering on the
* slot to give it a chance to initialize.
*/
udelay(250 * 1000);
out_be16((u16 *)FPGA_REG1C, reset_off | in_be16((u16 *)FPGA_REG1C));
}
/*
* For the given slot, set endpoint mode, send power to the slot,
* turn on the green LED and turn off the yellow LED, enable the clock
* .In end point mode reset bit is read only.
*/
void yucca_setup_pcie_fpga_endpoint(int port)
{
u16 power, clock, green_led, yellow_led, reset_off, rootpoint, endpoint;
switch(port) {
case 0:
rootpoint = FPGA_REG1C_PE0_ROOTPOINT;
endpoint = 0;
power = FPGA_REG1A_PE0_PWRON;
green_led = FPGA_REG1A_PE0_GLED;
clock = FPGA_REG1A_PE0_REFCLK_ENABLE;
yellow_led = FPGA_REG1A_PE0_YLED;
reset_off = FPGA_REG1C_PE0_PERST;
break;
case 1:
rootpoint = 0;
endpoint = FPGA_REG1C_PE1_ENDPOINT;
power = FPGA_REG1A_PE1_PWRON;
green_led = FPGA_REG1A_PE1_GLED;
clock = FPGA_REG1A_PE1_REFCLK_ENABLE;
yellow_led = FPGA_REG1A_PE1_YLED;
reset_off = FPGA_REG1C_PE1_PERST;
break;
case 2:
rootpoint = 0;
endpoint = FPGA_REG1C_PE2_ENDPOINT;
power = FPGA_REG1A_PE2_PWRON;
green_led = FPGA_REG1A_PE2_GLED;
clock = FPGA_REG1A_PE2_REFCLK_ENABLE;
yellow_led = FPGA_REG1A_PE2_YLED;
reset_off = FPGA_REG1C_PE2_PERST;
break;
default:
return;
}
out_be16((u16 *)FPGA_REG1A,
~(power | clock | green_led) &
(yellow_led | in_be16((u16 *)FPGA_REG1A)));
out_be16((u16 *)FPGA_REG1C,
~(rootpoint | reset_off) &
(endpoint | in_be16((u16 *)FPGA_REG1C)));
}
static struct pci_controller pcie_hose[3] = {{0},{0},{0}};
void pcie_setup_hoses(int busno)
{
struct pci_controller *hose;
int i, bus;
int ret = 0;
char *env;
unsigned int delay;
/*
* assume we're called after the PCIX hose is initialized, which takes
* bus ID 0 and therefore start numbering PCIe's from 1.
*/
bus = busno;
for (i = 0; i <= 2; i++) {
/* Check for yucca card presence */
if (!yucca_pcie_card_present(i))
continue;
if (is_end_point(i)) {
yucca_setup_pcie_fpga_endpoint(i);
ret = ppc4xx_init_pcie_endport(i);
} else {
yucca_setup_pcie_fpga_rootpoint(i);
ret = ppc4xx_init_pcie_rootport(i);
}
if (ret) {
printf("PCIE%d: initialization as %s failed\n", i,
is_end_point(i) ? "endpoint" : "root-complex");
continue;
}
hose = &pcie_hose[i];
hose->first_busno = bus;
hose->last_busno = bus;
hose->current_busno = bus;
/* setup mem resource */
pci_set_region(hose->regions + 0,
CFG_PCIE_MEMBASE + i * CFG_PCIE_MEMSIZE,
CFG_PCIE_MEMBASE + i * CFG_PCIE_MEMSIZE,
CFG_PCIE_MEMSIZE,
PCI_REGION_MEM);
hose->region_count = 1;
pci_register_hose(hose);
if (is_end_point(i)) {
ppc4xx_setup_pcie_endpoint(hose, i);
/*
* Reson for no scanning is endpoint can not generate
* upstream configuration accesses.
*/
} else {
ppc4xx_setup_pcie_rootpoint(hose, i);
env = getenv("pciscandelay");
if (env != NULL) {
delay = simple_strtoul(env, NULL, 10);
if (delay > 5)
printf("Warning, expect noticable delay before "
"PCIe scan due to 'pciscandelay' value!\n");
mdelay(delay * 1000);
}
/*
* Config access can only go down stream
*/
hose->last_busno = pci_hose_scan(hose);
bus = hose->last_busno + 1;
}
}
}
#endif /* defined(CONFIG_PCI) */
int misc_init_f (void)
{
uint reg;
out16(FPGA_REG10, (in16(FPGA_REG10) &
~(FPGA_REG10_AUTO_NEG_DIS|FPGA_REG10_RESET_ETH)) |
FPGA_REG10_10MHZ_ENABLE |
FPGA_REG10_100MHZ_ENABLE |
FPGA_REG10_GIGABIT_ENABLE |
FPGA_REG10_FULL_DUPLEX );
udelay(10000); /* wait 10ms */
out16(FPGA_REG10, (in16(FPGA_REG10) | FPGA_REG10_RESET_ETH));
/* minimal init for PCIe */
/* pci express 0 Endpoint Mode */
mfsdr(SDRN_PESDR_DLPSET(0), reg);
reg &= (~0x00400000);
mtsdr(SDRN_PESDR_DLPSET(0), reg);
/* pci express 1 Rootpoint Mode */
mfsdr(SDRN_PESDR_DLPSET(1), reg);
reg |= 0x00400000;
mtsdr(SDRN_PESDR_DLPSET(1), reg);
/* pci express 2 Rootpoint Mode */
mfsdr(SDRN_PESDR_DLPSET(2), reg);
reg |= 0x00400000;
mtsdr(SDRN_PESDR_DLPSET(2), reg);
out16(FPGA_REG1C,(in16 (FPGA_REG1C) &
~FPGA_REG1C_PE0_ROOTPOINT &
~FPGA_REG1C_PE1_ENDPOINT &
~FPGA_REG1C_PE2_ENDPOINT));
return 0;
}
void fpga_init(void)
{
/*
* by default sdram access is disabled by fpga
*/
out16(FPGA_REG10, (in16 (FPGA_REG10) |
FPGA_REG10_SDRAM_ENABLE |
FPGA_REG10_ENABLE_DISPLAY ));
return;
}
#ifdef CONFIG_POST
/*
* Returns 1 if keys pressed to start the power-on long-running tests
* Called from board_init_f().
*/
int post_hotkeys_pressed(void)
{
return (ctrlc());
}
#endif
/*---------------------------------------------------------------------------+
| onboard_pci_arbiter_selected => from EPLD
+---------------------------------------------------------------------------*/
int onboard_pci_arbiter_selected(int core_pci)
{
#if 0
unsigned long onboard_pci_arbiter_sel;
onboard_pci_arbiter_sel = in16(FPGA_REG0) & FPGA_REG0_EXT_ARB_SEL_MASK;
if (onboard_pci_arbiter_sel == FPGA_REG0_EXT_ARB_SEL_EXTERNAL)
return (BOARD_OPTION_SELECTED);
else
#endif
return (BOARD_OPTION_NOT_SELECTED);
}
int board_eth_init(bd_t *bis)
{
return pci_eth_init(bis);
}