rename CFG_ macros to CONFIG_SYS

[karo-tx-uboot.git] / board / esd / cpci750 / pci.c

/*
 * (C) Copyright 2000
 * 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
 *
 */
/* PCI.c - PCI functions */


#include <common.h>
#ifdef CONFIG_PCI
#include <pci.h>

#ifdef CONFIG_PCI_PNP
void pciauto_config_init(struct pci_controller *hose);
int  pciauto_region_allocate(struct pci_region* res, unsigned int size, unsigned int *bar);
#endif

#include "../../Marvell/include/pci.h"

#undef DEBUG
#undef IDE_SET_NATIVE_MODE
static unsigned int local_buses[] = { 0, 0 };

static const unsigned char pci_irq_swizzle[2][PCI_MAX_DEVICES] = {
        {0, 0, 0, 0, 0, 0, 0, 27, 27, [9 ... PCI_MAX_DEVICES - 1] = 0 },
        {0, 0, 0, 0, 0, 0, 0, 29, 29, [9 ... PCI_MAX_DEVICES - 1] = 0 },
};

#ifdef CONFIG_USE_CPCIDVI
typedef struct {
        unsigned int base;
        unsigned int init;
} GT_CPCIDVI_ROM_T;

static GT_CPCIDVI_ROM_T gt_cpcidvi_rom = {0, 0};
#endif

#ifdef DEBUG
static const unsigned int pci_bus_list[] = { PCI_0_MODE, PCI_1_MODE };
static void gt_pci_bus_mode_display (PCI_HOST host)
{
        unsigned int mode;


        mode = (GTREGREAD (pci_bus_list[host]) & (BIT4 | BIT5)) >> 4;
        switch (mode) {
        case 0:
                printf ("PCI %d bus mode: Conventional PCI\n", host);
                break;
        case 1:
                printf ("PCI %d bus mode: 66 Mhz PCIX\n", host);
                break;
        case 2:
                printf ("PCI %d bus mode: 100 Mhz PCIX\n", host);
                break;
        case 3:
                printf ("PCI %d bus mode: 133 Mhz PCIX\n", host);
                break;
        default:
                printf ("Unknown BUS %d\n", mode);
        }
}
#endif

static const unsigned int pci_p2p_configuration_reg[] = {
        PCI_0P2P_CONFIGURATION, PCI_1P2P_CONFIGURATION
};

static const unsigned int pci_configuration_address[] = {
        PCI_0CONFIGURATION_ADDRESS, PCI_1CONFIGURATION_ADDRESS
};

static const unsigned int pci_configuration_data[] = {
        PCI_0CONFIGURATION_DATA_VIRTUAL_REGISTER,
        PCI_1CONFIGURATION_DATA_VIRTUAL_REGISTER
};

static const unsigned int pci_error_cause_reg[] = {
        PCI_0ERROR_CAUSE, PCI_1ERROR_CAUSE
};

static const unsigned int pci_arbiter_control[] = {
        PCI_0ARBITER_CONTROL, PCI_1ARBITER_CONTROL
};

static const unsigned int pci_address_space_en[] = {
        PCI_0_BASE_ADDR_REG_ENABLE, PCI_1_BASE_ADDR_REG_ENABLE
};

static const unsigned int pci_snoop_control_base_0_low[] = {
        PCI_0SNOOP_CONTROL_BASE_0_LOW, PCI_1SNOOP_CONTROL_BASE_0_LOW
};
static const unsigned int pci_snoop_control_top_0[] = {
        PCI_0SNOOP_CONTROL_TOP_0, PCI_1SNOOP_CONTROL_TOP_0
};

static const unsigned int pci_access_control_base_0_low[] = {
        PCI_0ACCESS_CONTROL_BASE_0_LOW, PCI_1ACCESS_CONTROL_BASE_0_LOW
};
static const unsigned int pci_access_control_top_0[] = {
        PCI_0ACCESS_CONTROL_TOP_0, PCI_1ACCESS_CONTROL_TOP_0
};

static const unsigned int pci_scs_bank_size[2][4] = {
        {PCI_0SCS_0_BANK_SIZE, PCI_0SCS_1_BANK_SIZE,
         PCI_0SCS_2_BANK_SIZE, PCI_0SCS_3_BANK_SIZE},
        {PCI_1SCS_0_BANK_SIZE, PCI_1SCS_1_BANK_SIZE,
         PCI_1SCS_2_BANK_SIZE, PCI_1SCS_3_BANK_SIZE}
};

static const unsigned int pci_p2p_configuration[] = {
        PCI_0P2P_CONFIGURATION, PCI_1P2P_CONFIGURATION
};


/********************************************************************
* pciWriteConfigReg - Write to a PCI configuration register
*                   - Make sure the GT is configured as a master before writing
*                     to another device on the PCI.
*                   - The function takes care of Big/Little endian conversion.
*
*
* Inputs:   unsigned int regOffset: The register offset as it apears in the GT spec
*                  (or any other PCI device spec)
*           pciDevNum: The device number needs to be addressed.
*
*  Configuration Address 0xCF8:
*
*       31 30    24 23  16 15  11 10     8 7      2  0     <=bit Number
*  |congif|Reserved|  Bus |Device|Function|Register|00|
*  |Enable|        |Number|Number| Number | Number |  |    <=field Name
*
*********************************************************************/
void pciWriteConfigReg (PCI_HOST host, unsigned int regOffset,
                        unsigned int pciDevNum, unsigned int data)
{
        volatile unsigned int DataForAddrReg;
        unsigned int functionNum;
        unsigned int busNum = 0;
        unsigned int addr;

        if (pciDevNum > 32)     /* illegal device Number */
                return;
        if (pciDevNum == SELF) {        /* configure our configuration space. */
                pciDevNum =
                        (GTREGREAD (pci_p2p_configuration_reg[host]) >> 24) &
                        0x1f;
                busNum = GTREGREAD (pci_p2p_configuration_reg[host]) &
                        0xff0000;
        }
        functionNum = regOffset & 0x00000700;
        pciDevNum = pciDevNum << 11;
        regOffset = regOffset & 0xfc;
        DataForAddrReg =
                (regOffset | pciDevNum | functionNum | busNum) | BIT31;
        GT_REG_WRITE (pci_configuration_address[host], DataForAddrReg);
        GT_REG_READ (pci_configuration_address[host], &addr);
        if (addr != DataForAddrReg)
                return;
        GT_REG_WRITE (pci_configuration_data[host], data);
}

/********************************************************************
* pciReadConfigReg  - Read from a PCI0 configuration register
*                   - Make sure the GT is configured as a master before reading
*                     from another device on the PCI.
*                   - The function takes care of Big/Little endian conversion.
* INPUTS:   regOffset: The register offset as it apears in the GT spec (or PCI
*                       spec)
*           pciDevNum: The device number needs to be addressed.
* RETURNS: data , if the data == 0xffffffff check the master abort bit in the
*                 cause register to make sure the data is valid
*
*  Configuration Address 0xCF8:
*
*       31 30    24 23  16 15  11 10     8 7      2  0     <=bit Number
*  |congif|Reserved|  Bus |Device|Function|Register|00|
*  |Enable|        |Number|Number| Number | Number |  |    <=field Name
*
*********************************************************************/
unsigned int pciReadConfigReg (PCI_HOST host, unsigned int regOffset,
                               unsigned int pciDevNum)
{
        volatile unsigned int DataForAddrReg;
        unsigned int data;
        unsigned int functionNum;
        unsigned int busNum = 0;

        if (pciDevNum > 32)     /* illegal device Number */
                return 0xffffffff;
        if (pciDevNum == SELF) {        /* configure our configuration space. */
                pciDevNum =
                        (GTREGREAD (pci_p2p_configuration_reg[host]) >> 24) &
                        0x1f;
                busNum = GTREGREAD (pci_p2p_configuration_reg[host]) &
                        0xff0000;
        }
        functionNum = regOffset & 0x00000700;
        pciDevNum = pciDevNum << 11;
        regOffset = regOffset & 0xfc;
        DataForAddrReg =
                (regOffset | pciDevNum | functionNum | busNum) | BIT31;
        GT_REG_WRITE (pci_configuration_address[host], DataForAddrReg);
        GT_REG_READ (pci_configuration_address[host], &data);
        if (data != DataForAddrReg)
                return 0xffffffff;
        GT_REG_READ (pci_configuration_data[host], &data);
        return data;
}

/********************************************************************
* pciOverBridgeWriteConfigReg - Write to a PCI configuration register where
*                               the agent is placed on another Bus. For more
*                               information read P2P in the PCI spec.
*
* Inputs:   unsigned int regOffset - The register offset as it apears in the
*           GT spec (or any other PCI device spec).
*           unsigned int pciDevNum - The device number needs to be addressed.
*           unsigned int busNum - On which bus does the Target agent connect
*                                 to.
*           unsigned int data - data to be written.
*
*  Configuration Address 0xCF8:
*
*       31 30    24 23  16 15  11 10     8 7      2  0     <=bit Number
*  |congif|Reserved|  Bus |Device|Function|Register|01|
*  |Enable|        |Number|Number| Number | Number |  |    <=field Name
*
*  The configuration Address is configure as type-I (bits[1:0] = '01') due to
*   PCI spec referring to P2P.
*
*********************************************************************/
void pciOverBridgeWriteConfigReg (PCI_HOST host,
                                  unsigned int regOffset,
                                  unsigned int pciDevNum,
                                  unsigned int busNum, unsigned int data)
{
        unsigned int DataForReg;
        unsigned int functionNum;

        functionNum = regOffset & 0x00000700;
        pciDevNum = pciDevNum << 11;
        regOffset = regOffset & 0xff;
        busNum = busNum << 16;
        if (pciDevNum == SELF) {        /* This board */
                DataForReg = (regOffset | pciDevNum | functionNum) | BIT0;
        } else {
                DataForReg = (regOffset | pciDevNum | functionNum | busNum) |
                        BIT31 | BIT0;
        }
        GT_REG_WRITE (pci_configuration_address[host], DataForReg);
        GT_REG_WRITE (pci_configuration_data[host], data);
}


/********************************************************************
* pciOverBridgeReadConfigReg  - Read from a PCIn configuration register where
*                               the agent target locate on another PCI bus.
*                             - Make sure the GT is configured as a master
*                               before reading from another device on the PCI.
*                             - The function takes care of Big/Little endian
*                               conversion.
* INPUTS:   regOffset: The register offset as it apears in the GT spec (or PCI
*                        spec). (configuration register offset.)
*           pciDevNum: The device number needs to be addressed.
*           busNum: the Bus number where the agent is place.
* RETURNS: data , if the data == 0xffffffff check the master abort bit in the
*                 cause register to make sure the data is valid
*
*  Configuration Address 0xCF8:
*
*       31 30    24 23  16 15  11 10     8 7      2  0     <=bit Number
*  |congif|Reserved|  Bus |Device|Function|Register|01|
*  |Enable|        |Number|Number| Number | Number |  |    <=field Name
*
*********************************************************************/
unsigned int pciOverBridgeReadConfigReg (PCI_HOST host,
                                         unsigned int regOffset,
                                         unsigned int pciDevNum,
                                         unsigned int busNum)
{
        unsigned int DataForReg;
        unsigned int data;
        unsigned int functionNum;

        functionNum = regOffset & 0x00000700;
        pciDevNum = pciDevNum << 11;
        regOffset = regOffset & 0xff;
        busNum = busNum << 16;
        if (pciDevNum == SELF) {        /* This board */
                DataForReg = (regOffset | pciDevNum | functionNum) | BIT31;
        } else {                /* agent on another bus */

                DataForReg = (regOffset | pciDevNum | functionNum | busNum) |
                        BIT0 | BIT31;
        }
        GT_REG_WRITE (pci_configuration_address[host], DataForReg);
        GT_REG_READ (pci_configuration_data[host], &data);
        return data;
}


/********************************************************************
* pciGetRegOffset - Gets the register offset for this region config.
*
* INPUT:   Bus, Region - The bus and region we ask for its base address.
* OUTPUT:   N/A
* RETURNS: PCI register base address
*********************************************************************/
static unsigned int pciGetRegOffset (PCI_HOST host, PCI_REGION region)
{
        switch (host) {
        case PCI_HOST0:
                switch (region) {
                case PCI_IO:
                        return PCI_0I_O_LOW_DECODE_ADDRESS;
                case PCI_REGION0:
                        return PCI_0MEMORY0_LOW_DECODE_ADDRESS;
                case PCI_REGION1:
                        return PCI_0MEMORY1_LOW_DECODE_ADDRESS;
                case PCI_REGION2:
                        return PCI_0MEMORY2_LOW_DECODE_ADDRESS;
                case PCI_REGION3:
                        return PCI_0MEMORY3_LOW_DECODE_ADDRESS;
                }
        case PCI_HOST1:
                switch (region) {
                case PCI_IO:
                        return PCI_1I_O_LOW_DECODE_ADDRESS;
                case PCI_REGION0:
                        return PCI_1MEMORY0_LOW_DECODE_ADDRESS;
                case PCI_REGION1:
                        return PCI_1MEMORY1_LOW_DECODE_ADDRESS;
                case PCI_REGION2:
                        return PCI_1MEMORY2_LOW_DECODE_ADDRESS;
                case PCI_REGION3:
                        return PCI_1MEMORY3_LOW_DECODE_ADDRESS;
                }
        }
        return PCI_0MEMORY0_LOW_DECODE_ADDRESS;
}

static unsigned int pciGetRemapOffset (PCI_HOST host, PCI_REGION region)
{
        switch (host) {
        case PCI_HOST0:
                switch (region) {
                case PCI_IO:
                        return PCI_0I_O_ADDRESS_REMAP;
                case PCI_REGION0:
                        return PCI_0MEMORY0_ADDRESS_REMAP;
                case PCI_REGION1:
                        return PCI_0MEMORY1_ADDRESS_REMAP;
                case PCI_REGION2:
                        return PCI_0MEMORY2_ADDRESS_REMAP;
                case PCI_REGION3:
                        return PCI_0MEMORY3_ADDRESS_REMAP;
                }
        case PCI_HOST1:
                switch (region) {
                case PCI_IO:
                        return PCI_1I_O_ADDRESS_REMAP;
                case PCI_REGION0:
                        return PCI_1MEMORY0_ADDRESS_REMAP;
                case PCI_REGION1:
                        return PCI_1MEMORY1_ADDRESS_REMAP;
                case PCI_REGION2:
                        return PCI_1MEMORY2_ADDRESS_REMAP;
                case PCI_REGION3:
                        return PCI_1MEMORY3_ADDRESS_REMAP;
                }
        }
        return PCI_0MEMORY0_ADDRESS_REMAP;
}

/********************************************************************
* pciGetBaseAddress - Gets the base address of a PCI.
*           - If the PCI size is 0 then this base address has no meaning!!!
*
*
* INPUT:   Bus, Region - The bus and region we ask for its base address.
* OUTPUT:   N/A
* RETURNS: PCI base address.
*********************************************************************/
unsigned int pciGetBaseAddress (PCI_HOST host, PCI_REGION region)
{
        unsigned int regBase;
        unsigned int regEnd;
        unsigned int regOffset = pciGetRegOffset (host, region);

        GT_REG_READ (regOffset, &regBase);
        GT_REG_READ (regOffset + 8, &regEnd);

        if (regEnd <= regBase)
                return 0xffffffff;      /* ERROR !!! */

        regBase = regBase << 16;
        return regBase;
}

bool pciMapSpace (PCI_HOST host, PCI_REGION region, unsigned int remapBase,
                  unsigned int bankBase, unsigned int bankLength)
{
        unsigned int low = 0xfff;
        unsigned int high = 0x0;
        unsigned int regOffset = pciGetRegOffset (host, region);
        unsigned int remapOffset = pciGetRemapOffset (host, region);

        if (bankLength != 0) {
                low = (bankBase >> 16) & 0xffff;
                high = ((bankBase + bankLength) >> 16) - 1;
        }

        GT_REG_WRITE (regOffset, low | (1 << 24));      /* no swapping */
        GT_REG_WRITE (regOffset + 8, high);

        if (bankLength != 0) {  /* must do AFTER writing maps */
                GT_REG_WRITE (remapOffset, remapBase >> 16);    /* sorry, 32 bits only.
                                                                   dont support upper 32
                                                                   in this driver */
        }
        return true;
}

unsigned int pciGetSpaceBase (PCI_HOST host, PCI_REGION region)
{
        unsigned int low;
        unsigned int regOffset = pciGetRegOffset (host, region);

        GT_REG_READ (regOffset, &low);
        return (low & 0xffff) << 16;
}

unsigned int pciGetSpaceSize (PCI_HOST host, PCI_REGION region)
{
        unsigned int low, high;
        unsigned int regOffset = pciGetRegOffset (host, region);

        GT_REG_READ (regOffset, &low);
        GT_REG_READ (regOffset + 8, &high);
        return ((high & 0xffff) + 1) << 16;
}


/* ronen - 7/Dec/03*/
/********************************************************************
* gtPciDisable/EnableInternalBAR - This function enable/disable PCI BARS.
* Inputs: one of the PCI BAR
*********************************************************************/
void gtPciEnableInternalBAR (PCI_HOST host, PCI_INTERNAL_BAR pciBAR)
{
        RESET_REG_BITS (pci_address_space_en[host], BIT0 << pciBAR);
}

void gtPciDisableInternalBAR (PCI_HOST host, PCI_INTERNAL_BAR pciBAR)
{
        SET_REG_BITS (pci_address_space_en[host], BIT0 << pciBAR);
}

/********************************************************************
* pciMapMemoryBank - Maps PCI_host memory bank "bank" for the slave.
*
* Inputs: base and size of PCI SCS
*********************************************************************/
void pciMapMemoryBank (PCI_HOST host, MEMORY_BANK bank,
                       unsigned int pciDramBase, unsigned int pciDramSize)
{
        /*ronen different function for 3rd bank. */
        unsigned int offset = (bank < 2) ? bank * 8 : 0x100 + (bank - 2) * 8;

        pciDramBase = pciDramBase & 0xfffff000;
        pciDramBase = pciDramBase | (pciReadConfigReg (host,
                                                       PCI_SCS_0_BASE_ADDRESS
                                                       + offset,
                                                       SELF) & 0x00000fff);
        pciWriteConfigReg (host, PCI_SCS_0_BASE_ADDRESS + offset, SELF,
                           pciDramBase);
        if (pciDramSize == 0)
                pciDramSize++;
        GT_REG_WRITE (pci_scs_bank_size[host][bank], pciDramSize - 1);
        gtPciEnableInternalBAR (host, bank);
}

/********************************************************************
* pciSetRegionFeatures - This function modifys one of the 8 regions with
*                         feature bits given as an input.
*                       - Be advised to check the spec before modifying them.
* Inputs: PCI_PROTECT_REGION region - one of the eight regions.
*         unsigned int features - See file: pci.h there are defintion for those
*                                 region features.
*         unsigned int baseAddress - The region base Address.
*         unsigned int topAddress - The region top Address.
* Returns: false if one of the parameters is erroneous true otherwise.
*********************************************************************/
bool pciSetRegionFeatures (PCI_HOST host, PCI_ACCESS_REGIONS region,
                           unsigned int features, unsigned int baseAddress,
                           unsigned int regionLength)
{
        unsigned int accessLow;
        unsigned int accessHigh;
        unsigned int accessTop = baseAddress + regionLength;

        if (regionLength == 0) {        /* close the region. */
                pciDisableAccessRegion (host, region);
                return true;
        }
        /* base Address is store is bits [11:0] */
        accessLow = (baseAddress & 0xfff00000) >> 20;
        /* All the features are update according to the defines in pci.h (to be on
           the safe side we disable bits: [11:0] */
        accessLow = accessLow | (features & 0xfffff000);
        /* write to the Low Access Region register */
        GT_REG_WRITE (pci_access_control_base_0_low[host] + 0x10 * region,
                      accessLow);

        accessHigh = (accessTop & 0xfff00000) >> 20;

        /* write to the High Access Region register */
        GT_REG_WRITE (pci_access_control_top_0[host] + 0x10 * region,
                      accessHigh - 1);
        return true;
}

/********************************************************************
* pciDisableAccessRegion - Disable The given Region by writing MAX size
*                           to its low Address and MIN size to its high Address.
*
* Inputs:   PCI_ACCESS_REGIONS region - The region we to be Disabled.
* Returns:  N/A.
*********************************************************************/
void pciDisableAccessRegion (PCI_HOST host, PCI_ACCESS_REGIONS region)
{
        /* writing back the registers default values. */
        GT_REG_WRITE (pci_access_control_base_0_low[host] + 0x10 * region,
                      0x01001fff);
        GT_REG_WRITE (pci_access_control_top_0[host] + 0x10 * region, 0);
}

/********************************************************************
* pciArbiterEnable - Enables PCI-0`s Arbitration mechanism.
*
* Inputs:   N/A
* Returns:  true.
*********************************************************************/
bool pciArbiterEnable (PCI_HOST host)
{
        unsigned int regData;

        GT_REG_READ (pci_arbiter_control[host], &regData);
        GT_REG_WRITE (pci_arbiter_control[host], regData | BIT31);
        return true;
}

/********************************************************************
* pciArbiterDisable - Disable PCI-0`s Arbitration mechanism.
*
* Inputs:   N/A
* Returns:  true
*********************************************************************/
bool pciArbiterDisable (PCI_HOST host)
{
        unsigned int regData;

        GT_REG_READ (pci_arbiter_control[host], &regData);
        GT_REG_WRITE (pci_arbiter_control[host], regData & 0x7fffffff);
        return true;
}

/********************************************************************
* pciSetArbiterAgentsPriority - Priority setup for the PCI agents (Hi or Low)
*
* Inputs:   PCI_AGENT_PRIO internalAgent - priotity for internal agent.
*           PCI_AGENT_PRIO externalAgent0 - priotity for external#0 agent.
*           PCI_AGENT_PRIO externalAgent1 - priotity for external#1 agent.
*           PCI_AGENT_PRIO externalAgent2 - priotity for external#2 agent.
*           PCI_AGENT_PRIO externalAgent3 - priotity for external#3 agent.
*           PCI_AGENT_PRIO externalAgent4 - priotity for external#4 agent.
*           PCI_AGENT_PRIO externalAgent5 - priotity for external#5 agent.
* Returns:  true
*********************************************************************/
bool pciSetArbiterAgentsPriority (PCI_HOST host, PCI_AGENT_PRIO internalAgent,
                                  PCI_AGENT_PRIO externalAgent0,
                                  PCI_AGENT_PRIO externalAgent1,
                                  PCI_AGENT_PRIO externalAgent2,
                                  PCI_AGENT_PRIO externalAgent3,
                                  PCI_AGENT_PRIO externalAgent4,
                                  PCI_AGENT_PRIO externalAgent5)
{
        unsigned int regData;
        unsigned int writeData;

        GT_REG_READ (pci_arbiter_control[host], &regData);
        writeData = (internalAgent << 7) + (externalAgent0 << 8) +
                (externalAgent1 << 9) + (externalAgent2 << 10) +
                (externalAgent3 << 11) + (externalAgent4 << 12) +
                (externalAgent5 << 13);
        regData = (regData & 0xffffc07f) | writeData;
        GT_REG_WRITE (pci_arbiter_control[host], regData & regData);
        return true;
}

/********************************************************************
* pciParkingDisable - Park on last option disable, with this function you can
*                      disable the park on last mechanism for each agent.
*                      disabling this option for all agents results parking
*                      on the internal master.
*
* Inputs: PCI_AGENT_PARK internalAgent -  parking Disable for internal agent.
*         PCI_AGENT_PARK externalAgent0 - parking Disable for external#0 agent.
*         PCI_AGENT_PARK externalAgent1 - parking Disable for external#1 agent.
*         PCI_AGENT_PARK externalAgent2 - parking Disable for external#2 agent.
*         PCI_AGENT_PARK externalAgent3 - parking Disable for external#3 agent.
*         PCI_AGENT_PARK externalAgent4 - parking Disable for external#4 agent.
*         PCI_AGENT_PARK externalAgent5 - parking Disable for external#5 agent.
* Returns:  true
*********************************************************************/
bool pciParkingDisable (PCI_HOST host, PCI_AGENT_PARK internalAgent,
                        PCI_AGENT_PARK externalAgent0,
                        PCI_AGENT_PARK externalAgent1,
                        PCI_AGENT_PARK externalAgent2,
                        PCI_AGENT_PARK externalAgent3,
                        PCI_AGENT_PARK externalAgent4,
                        PCI_AGENT_PARK externalAgent5)
{
        unsigned int regData;
        unsigned int writeData;

        GT_REG_READ (pci_arbiter_control[host], &regData);
        writeData = (internalAgent << 14) + (externalAgent0 << 15) +
                (externalAgent1 << 16) + (externalAgent2 << 17) +
                (externalAgent3 << 18) + (externalAgent4 << 19) +
                (externalAgent5 << 20);
        regData = (regData & ~(0x7f << 14)) | writeData;
        GT_REG_WRITE (pci_arbiter_control[host], regData);
        return true;
}

/********************************************************************
* pciEnableBrokenAgentDetection - A master is said to be broken if it fails to
*                       respond to grant assertion within a window specified in
*                       the input value: 'brokenValue'.
*
* Inputs: unsigned char brokenValue -  A value which limits the Master to hold the
*                       grant without asserting frame.
* Returns:  Error for illegal broken value otherwise true.
*********************************************************************/
bool pciEnableBrokenAgentDetection (PCI_HOST host, unsigned char brokenValue)
{
        unsigned int data;
        unsigned int regData;

        if (brokenValue > 0xf)
                return false;   /* brokenValue must be 4 bit */
        data = brokenValue << 3;
        GT_REG_READ (pci_arbiter_control[host], &regData);
        regData = (regData & 0xffffff87) | data;
        GT_REG_WRITE (pci_arbiter_control[host], regData | BIT1);
        return true;
}

/********************************************************************
* pciDisableBrokenAgentDetection - This function disable the Broken agent
*                           Detection mechanism.
*                           NOTE: This operation may cause a dead lock on the
*                           pci0 arbitration.
*
* Inputs:   N/A
* Returns:  true.
*********************************************************************/
bool pciDisableBrokenAgentDetection (PCI_HOST host)
{
        unsigned int regData;

        GT_REG_READ (pci_arbiter_control[host], &regData);
        regData = regData & 0xfffffffd;
        GT_REG_WRITE (pci_arbiter_control[host], regData);
        return true;
}

/********************************************************************
* pciP2PConfig - This function set the PCI_n P2P configurate.
*                 For more information on the P2P read PCI spec.
*
* Inputs:  unsigned int SecondBusLow - Secondery PCI interface Bus Range Lower
*                                      Boundry.
*          unsigned int SecondBusHigh - Secondry PCI interface Bus Range upper
*                                      Boundry.
*          unsigned int busNum - The CPI bus number to which the PCI interface
*                                      is connected.
*          unsigned int devNum - The PCI interface's device number.
*
* Returns:  true.
*********************************************************************/
bool pciP2PConfig (PCI_HOST host, unsigned int SecondBusLow,
                   unsigned int SecondBusHigh,
                   unsigned int busNum, unsigned int devNum)
{
        unsigned int regData;

        regData = (SecondBusLow & 0xff) | ((SecondBusHigh & 0xff) << 8) |
                ((busNum & 0xff) << 16) | ((devNum & 0x1f) << 24);
        GT_REG_WRITE (pci_p2p_configuration[host], regData);
        return true;
}

/********************************************************************
* pciSetRegionSnoopMode - This function modifys one of the 4 regions which
*                          supports Cache Coherency in the PCI_n interface.
* Inputs: region - One of the four regions.
*         snoopType - There is four optional Types:
*                        1. No Snoop.
*                        2. Snoop to WT region.
*                        3. Snoop to WB region.
*                        4. Snoop & Invalidate to WB region.
*         baseAddress - Base Address of this region.
*         regionLength - Region length.
* Returns: false if one of the parameters is wrong otherwise return true.
*********************************************************************/
bool pciSetRegionSnoopMode (PCI_HOST host, PCI_SNOOP_REGION region,
                            PCI_SNOOP_TYPE snoopType,
                            unsigned int baseAddress,
                            unsigned int regionLength)
{
        unsigned int snoopXbaseAddress;
        unsigned int snoopXtopAddress;
        unsigned int data;
        unsigned int snoopHigh = baseAddress + regionLength;

        if ((region > PCI_SNOOP_REGION3) || (snoopType > PCI_SNOOP_WB))
                return false;
        snoopXbaseAddress =
                pci_snoop_control_base_0_low[host] + 0x10 * region;
        snoopXtopAddress = pci_snoop_control_top_0[host] + 0x10 * region;
        if (regionLength == 0) {        /* closing the region */
                GT_REG_WRITE (snoopXbaseAddress, 0x0000ffff);
                GT_REG_WRITE (snoopXtopAddress, 0);
                return true;
        }
        baseAddress = baseAddress & 0xfff00000; /* Granularity of 1MByte */
        data = (baseAddress >> 20) | snoopType << 12;
        GT_REG_WRITE (snoopXbaseAddress, data);
        snoopHigh = (snoopHigh & 0xfff00000) >> 20;
        GT_REG_WRITE (snoopXtopAddress, snoopHigh - 1);
        return true;
}

static int gt_read_config_dword (struct pci_controller *hose,
                                 pci_dev_t dev, int offset, u32 * value)
{
        int bus = PCI_BUS (dev);

        if ((bus == local_buses[0]) || (bus == local_buses[1])) {
                *value = pciReadConfigReg ((PCI_HOST) hose->cfg_addr, offset,
                                           PCI_DEV (dev));
        } else {
                *value = pciOverBridgeReadConfigReg ((PCI_HOST) hose->
                                                     cfg_addr, offset,
                                                     PCI_DEV (dev), bus);
        }

        return 0;
}

static int gt_write_config_dword (struct pci_controller *hose,
                                  pci_dev_t dev, int offset, u32 value)
{
        int bus = PCI_BUS (dev);

        if ((bus == local_buses[0]) || (bus == local_buses[1])) {
                pciWriteConfigReg ((PCI_HOST) hose->cfg_addr, offset,
                                   PCI_DEV (dev), value);
        } else {
                pciOverBridgeWriteConfigReg ((PCI_HOST) hose->cfg_addr,
                                             offset, PCI_DEV (dev), bus,
                                             value);
        }
        return 0;
}


static void gt_setup_ide (struct pci_controller *hose,
                          pci_dev_t dev, struct pci_config_table *entry)
{
        static const int ide_bar[] = { 8, 4, 8, 4, 0, 0 };
        u32 bar_response, bar_value;
        int bar;

        for (bar = 0; bar < 6; bar++) {
                /*ronen different function for 3rd bank. */
                unsigned int offset =
                        (bar < 2) ? bar * 8 : 0x100 + (bar - 2) * 8;

                pci_hose_write_config_dword (hose, dev, PCI_BASE_ADDRESS_0 + offset,
                                             0x0);
                pci_hose_read_config_dword (hose, dev, PCI_BASE_ADDRESS_0 + offset,
                                            &bar_response);

                pciauto_region_allocate (bar_response &
                                         PCI_BASE_ADDRESS_SPACE_IO ? hose->
                                         pci_io : hose->pci_mem, ide_bar[bar],
                                         &bar_value);

                pci_hose_write_config_dword (hose, dev, PCI_BASE_ADDRESS_0 + bar * 4,
                                             bar_value);
        }
}

#ifdef CONFIG_USE_CPCIDVI
static void gt_setup_cpcidvi (struct pci_controller *hose,
                              pci_dev_t dev, struct pci_config_table *entry)
{
        u32               bar_value, pci_response;

        pci_hose_read_config_dword (hose, dev, PCI_COMMAND, &pci_response);
        pci_hose_write_config_dword (hose, dev, PCI_BASE_ADDRESS_0, 0xffffffff);
        pci_hose_read_config_dword (hose, dev, PCI_BASE_ADDRESS_0, &pci_response);
        pciauto_region_allocate (hose->pci_mem, 0x01000000, &bar_value);
        pci_hose_write_config_dword (hose, dev, PCI_BASE_ADDRESS_0, (bar_value & 0xffffff00));
        pci_hose_write_config_dword (hose, dev, PCI_ROM_ADDRESS, 0x0);
        pciauto_region_allocate (hose->pci_mem, 0x40000, &bar_value);
        pci_hose_write_config_dword (hose, dev, PCI_ROM_ADDRESS, (bar_value & 0xffffff00) | 0x01);
        gt_cpcidvi_rom.base = bar_value & 0xffffff00;
        gt_cpcidvi_rom.init = 1;
}

unsigned char gt_cpcidvi_in8(unsigned int offset)
{
        unsigned char     data;

        if (gt_cpcidvi_rom.init == 0) {
                return(0);
                }
        data = in8((offset & 0x04) + 0x3f000 + gt_cpcidvi_rom.base);
        return(data);
}

void gt_cpcidvi_out8(unsigned int offset, unsigned char data)
{
        unsigned int      off;

        if (gt_cpcidvi_rom.init == 0) {
                return;
        }
        off = data;
        off = ((off << 3) & 0x7f8) + (offset & 0x4) + 0x3e000 + gt_cpcidvi_rom.base;
        in8(off);
        return;
}
#endif

/* TODO BJW: Change this for DB64360. This was pulled from the EV64260  */
/* and is curently not called *. */
#if 0
static void gt_fixup_irq (struct pci_controller *hose, pci_dev_t dev)
{
        unsigned char pin, irq;

        pci_read_config_byte (dev, PCI_INTERRUPT_PIN, &pin);

        if (pin == 1) {         /* only allow INT A */
                irq = pci_irq_swizzle[(PCI_HOST) hose->
                                      cfg_addr][PCI_DEV (dev)];
                if (irq)
                        pci_write_config_byte (dev, PCI_INTERRUPT_LINE, irq);
        }
}
#endif

struct pci_config_table gt_config_table[] = {
#ifdef CONFIG_USE_CPCIDVI
        {PCI_VENDOR_ID_CT, PCI_DEVICE_ID_CT_69030, PCI_CLASS_DISPLAY_VGA,
         PCI_ANY_ID, PCI_ANY_ID, PCI_ANY_ID, gt_setup_cpcidvi},
#endif
        {PCI_ANY_ID, PCI_ANY_ID, PCI_CLASS_STORAGE_IDE,
         PCI_ANY_ID, PCI_ANY_ID, PCI_ANY_ID, gt_setup_ide},
        {}
};

struct pci_controller pci0_hose = {
/*    fixup_irq: gt_fixup_irq, */
        config_table:gt_config_table,
};

struct pci_controller pci1_hose = {
/*    fixup_irq: gt_fixup_irq, */
        config_table:gt_config_table,
};

void pci_init_board (void)
{
        unsigned int command;
#ifdef CONFIG_PCI_PNP
        unsigned int bar;
#endif
#ifdef DEBUG
        gt_pci_bus_mode_display (PCI_HOST0);
#endif
#ifdef CONFIG_USE_CPCIDVI
        gt_cpcidvi_rom.init = 0;
        gt_cpcidvi_rom.base = 0;
#endif

        pci0_hose.config_table = gt_config_table;
        pci1_hose.config_table = gt_config_table;

#ifdef CONFIG_USE_CPCIDVI
        gt_config_table[0].config_device =  gt_setup_cpcidvi;
#endif
        gt_config_table[1].config_device =  gt_setup_ide;

        pci0_hose.first_busno = 0;
        pci0_hose.last_busno = 0xff;
        local_buses[0] = pci0_hose.first_busno;

        /* PCI memory space */
        pci_set_region (pci0_hose.regions + 0,
                        CONFIG_SYS_PCI0_0_MEM_SPACE,
                        CONFIG_SYS_PCI0_0_MEM_SPACE,
                        CONFIG_SYS_PCI0_MEM_SIZE, PCI_REGION_MEM);

        /* PCI I/O space */
        pci_set_region (pci0_hose.regions + 1,
                        CONFIG_SYS_PCI0_IO_SPACE_PCI,
                        CONFIG_SYS_PCI0_IO_SPACE, CONFIG_SYS_PCI0_IO_SIZE, PCI_REGION_IO);

        pci_set_ops (&pci0_hose,
                     pci_hose_read_config_byte_via_dword,
                     pci_hose_read_config_word_via_dword,
                     gt_read_config_dword,
                     pci_hose_write_config_byte_via_dword,
                     pci_hose_write_config_word_via_dword,
                     gt_write_config_dword);
        pci0_hose.region_count = 2;

        pci0_hose.cfg_addr = (unsigned int *) PCI_HOST0;

        pci_register_hose (&pci0_hose);
        pciArbiterEnable (PCI_HOST0);
        pciParkingDisable (PCI_HOST0, 1, 1, 1, 1, 1, 1, 1);
        command = pciReadConfigReg (PCI_HOST0, PCI_COMMAND, SELF);
        command |= PCI_COMMAND_MASTER;
        pciWriteConfigReg (PCI_HOST0, PCI_COMMAND, SELF, command);
        command = pciReadConfigReg (PCI_HOST0, PCI_COMMAND, SELF);
        command |= PCI_COMMAND_MEMORY;
        pciWriteConfigReg (PCI_HOST0, PCI_COMMAND, SELF, command);

#ifdef CONFIG_PCI_PNP
        pciauto_config_init(&pci0_hose);
        pciauto_region_allocate(pci0_hose.pci_io, 0x400, &bar);
#endif
#ifdef CONFIG_PCI_SCAN_SHOW
        printf("PCI:   Bus Dev VenId DevId Class Int\n");
#endif
        pci0_hose.last_busno = pci_hose_scan_bus (&pci0_hose, pci0_hose.first_busno);

#ifdef DEBUG
        gt_pci_bus_mode_display (PCI_HOST1);
#endif
        pci1_hose.first_busno = pci0_hose.last_busno + 1;
        pci1_hose.last_busno = 0xff;
        pci1_hose.current_busno = pci1_hose.first_busno;
        local_buses[1] = pci1_hose.first_busno;

        /* PCI memory space */
        pci_set_region (pci1_hose.regions + 0,
                        CONFIG_SYS_PCI1_0_MEM_SPACE,
                        CONFIG_SYS_PCI1_0_MEM_SPACE,
                        CONFIG_SYS_PCI1_MEM_SIZE, PCI_REGION_MEM);

        /* PCI I/O space */
        pci_set_region (pci1_hose.regions + 1,
                        CONFIG_SYS_PCI1_IO_SPACE_PCI,
                        CONFIG_SYS_PCI1_IO_SPACE, CONFIG_SYS_PCI1_IO_SIZE, PCI_REGION_IO);

        pci_set_ops (&pci1_hose,
                     pci_hose_read_config_byte_via_dword,
                     pci_hose_read_config_word_via_dword,
                     gt_read_config_dword,
                     pci_hose_write_config_byte_via_dword,
                     pci_hose_write_config_word_via_dword,
                     gt_write_config_dword);

        pci1_hose.region_count = 2;

        pci1_hose.cfg_addr = (unsigned int *) PCI_HOST1;

        pci_register_hose (&pci1_hose);

        pciArbiterEnable (PCI_HOST1);
        pciParkingDisable (PCI_HOST1, 1, 1, 1, 1, 1, 1, 1);

        command = pciReadConfigReg (PCI_HOST1, PCI_COMMAND, SELF);
        command |= PCI_COMMAND_MASTER;
        pciWriteConfigReg (PCI_HOST1, PCI_COMMAND, SELF, command);

#ifdef CONFIG_PCI_PNP
        pciauto_config_init(&pci1_hose);
        pciauto_region_allocate(pci1_hose.pci_io, 0x400, &bar);
#endif
        pci1_hose.last_busno = pci_hose_scan_bus (&pci1_hose, pci1_hose.first_busno);

        command = pciReadConfigReg (PCI_HOST1, PCI_COMMAND, SELF);
        command |= PCI_COMMAND_MEMORY;
        pciWriteConfigReg (PCI_HOST1, PCI_COMMAND, SELF, command);

}
#endif /* of CONFIG_PCI */