path: root/target/linux/lantiq/files/drivers/usb/dwc_otg/dwc_otg_cil.c

/* ==========================================================================
 * $File: //dwh/usb_iip/dev/software/otg_ipmate/linux/drivers/dwc_otg_cil.c $
 * $Revision: 1.1.1.1 $
 * $Date: 2009-04-17 06:15:34 $
 * $Change: 631780 $
 *
 * Synopsys HS OTG Linux Software Driver and documentation (hereinafter,
 * "Software") is an Unsupported proprietary work of Synopsys, Inc. unless
 * otherwise expressly agreed to in writing between Synopsys and you.
 * 
 * The Software IS NOT an item of Licensed Software or Licensed Product under
 * any End User Software License Agreement or Agreement for Licensed Product
 * with Synopsys or any supplement thereto. You are permitted to use and
 * redistribute this Software in source and binary forms, with or without
 * modification, provided that redistributions of source code must retain this
 * notice. You may not view, use, disclose, copy or distribute this file or
 * any information contained herein except pursuant to this license grant from
 * Synopsys. If you do not agree with this notice, including the disclaimer
 * below, then you are not authorized to use the Software.
 * 
 * THIS SOFTWARE IS BEING DISTRIBUTED BY SYNOPSYS SOLELY ON AN "AS IS" BASIS
 * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
 * ARE HEREBY DISCLAIMED. IN NO EVENT SHALL SYNOPSYS BE LIABLE FOR ANY DIRECT,
 * INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
 * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
 * SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
 * CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
 * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH
 * DAMAGE.
 * ========================================================================== */

/** @file 
 *
 * The Core Interface Layer provides basic services for accessing and
 * managing the DWC_otg hardware. These services are used by both the
 * Host Controller Driver and the Peripheral Controller Driver.
 *
 * The CIL manages the memory map for the core so that the HCD and PCD
 * don't have to do this separately. It also handles basic tasks like
 * reading/writing the registers and data FIFOs in the controller.
 * Some of the data access functions provide encapsulation of several
 * operations required to perform a task, such as writing multiple
 * registers to start a transfer. Finally, the CIL performs basic
 * services that are not specific to either the host or device modes
 * of operation. These services include management of the OTG Host
 * Negotiation Protocol (HNP) and Session Request Protocol (SRP). A
 * Diagnostic API is also provided to allow testing of the controller
 * hardware.
 *
 * The Core Interface Layer has the following requirements:
 * - Provides basic controller operations.
 * - Minimal use of OS services.  
 * - The OS services used will be abstracted by using inline functions
 *   or macros.
 *
 */
#include <asm/unaligned.h>

#ifdef DEBUG
#include <linux/jiffies.h>
#endif

#include "dwc_otg_plat.h"

#include "dwc_otg_regs.h"
#include "dwc_otg_cil.h"

/** 
 * This function is called to initialize the DWC_otg CSR data
 * structures.  The register addresses in the device and host
 * structures are initialized from the base address supplied by the
 * caller.  The calling function must make the OS calls to get the
 * base address of the DWC_otg controller registers.  The core_params
 * argument holds the parameters that specify how the core should be
 * configured.
 *
 * @param[in] _reg_base_addr Base address of DWC_otg core registers
 * @param[in] _core_params Pointer to the core configuration parameters 
 *
 */
dwc_otg_core_if_t *dwc_otg_cil_init(const uint32_t *_reg_base_addr,
                                    dwc_otg_core_params_t *_core_params)
{
    dwc_otg_core_if_t *core_if = 0;
    dwc_otg_dev_if_t *dev_if = 0;
    dwc_otg_host_if_t *host_if = 0;
    uint8_t *reg_base = (uint8_t *)_reg_base_addr;
    int i = 0;

    DWC_DEBUGPL(DBG_CILV, "%s(%p,%p)\n", __func__, _reg_base_addr, _core_params);
   
    core_if = kmalloc( sizeof(dwc_otg_core_if_t), GFP_KERNEL);
    if (core_if == 0) {
        DWC_DEBUGPL(DBG_CIL, "Allocation of dwc_otg_core_if_t failed\n");
        return 0;
    }
    memset(core_if, 0, sizeof(dwc_otg_core_if_t));
        
    core_if->core_params = _core_params;
    core_if->core_global_regs = (dwc_otg_core_global_regs_t *)reg_base;
    /*
     * Allocate the Device Mode structures.
     */
    dev_if = kmalloc( sizeof(dwc_otg_dev_if_t), GFP_KERNEL);
    if (dev_if == 0) {
        DWC_DEBUGPL(DBG_CIL, "Allocation of dwc_otg_dev_if_t failed\n");
        kfree( core_if );
        return 0;
    }

    dev_if->dev_global_regs = 
        (dwc_otg_device_global_regs_t *)(reg_base + DWC_DEV_GLOBAL_REG_OFFSET);
        
    for (i=0; i<MAX_EPS_CHANNELS; i++) {
        dev_if->in_ep_regs[i] = (dwc_otg_dev_in_ep_regs_t *)
            (reg_base + DWC_DEV_IN_EP_REG_OFFSET +
            (i * DWC_EP_REG_OFFSET));
                
        dev_if->out_ep_regs[i] = (dwc_otg_dev_out_ep_regs_t *) 
            (reg_base + DWC_DEV_OUT_EP_REG_OFFSET +
            (i * DWC_EP_REG_OFFSET));
        DWC_DEBUGPL(DBG_CILV, "in_ep_regs[%d]->diepctl=%p\n", 
                            i, &dev_if->in_ep_regs[i]->diepctl);
        DWC_DEBUGPL(DBG_CILV, "out_ep_regs[%d]->doepctl=%p\n", 
                            i, &dev_if->out_ep_regs[i]->doepctl);
    }
    dev_if->speed = 0; // unknown
    //dev_if->num_eps = MAX_EPS_CHANNELS;
    //dev_if->num_perio_eps = 0;
        
    core_if->dev_if = dev_if;
    /*
    * Allocate the Host Mode structures.
    */
    host_if = kmalloc( sizeof(dwc_otg_host_if_t), GFP_KERNEL);
    if (host_if == 0) {
        DWC_DEBUGPL(DBG_CIL, "Allocation of dwc_otg_host_if_t failed\n");
        kfree( dev_if );
        kfree( core_if );
        return 0;
    }

    host_if->host_global_regs = (dwc_otg_host_global_regs_t *)
        (reg_base + DWC_OTG_HOST_GLOBAL_REG_OFFSET);
    host_if->hprt0 = (uint32_t*)(reg_base + DWC_OTG_HOST_PORT_REGS_OFFSET);
    for (i=0; i<MAX_EPS_CHANNELS; i++) {
        host_if->hc_regs[i] = (dwc_otg_hc_regs_t *)
            (reg_base + DWC_OTG_HOST_CHAN_REGS_OFFSET + 
            (i * DWC_OTG_CHAN_REGS_OFFSET));
        DWC_DEBUGPL(DBG_CILV, "hc_reg[%d]->hcchar=%p\n", 
                            i, &host_if->hc_regs[i]->hcchar);
    }
    host_if->num_host_channels = MAX_EPS_CHANNELS;
    core_if->host_if = host_if;

    for (i=0; i<MAX_EPS_CHANNELS; i++) {
        core_if->data_fifo[i] = 
            (uint32_t *)(reg_base + DWC_OTG_DATA_FIFO_OFFSET + 
            (i * DWC_OTG_DATA_FIFO_SIZE)); 
        DWC_DEBUGPL(DBG_CILV, "data_fifo[%d]=0x%08x\n", 
            i, (unsigned)core_if->data_fifo[i]);
    } // for loop.
        
    core_if->pcgcctl = (uint32_t*)(reg_base + DWC_OTG_PCGCCTL_OFFSET);

    /*
     * Store the contents of the hardware configuration registers here for
     * easy access later.
     */
    core_if->hwcfg1.d32 = dwc_read_reg32(&core_if->core_global_regs->ghwcfg1);
    core_if->hwcfg2.d32 = dwc_read_reg32(&core_if->core_global_regs->ghwcfg2);
    core_if->hwcfg3.d32 = dwc_read_reg32(&core_if->core_global_regs->ghwcfg3);
    core_if->hwcfg4.d32 = dwc_read_reg32(&core_if->core_global_regs->ghwcfg4);

    DWC_DEBUGPL(DBG_CILV,"hwcfg1=%08x\n",core_if->hwcfg1.d32);
    DWC_DEBUGPL(DBG_CILV,"hwcfg2=%08x\n",core_if->hwcfg2.d32);
    DWC_DEBUGPL(DBG_CILV,"hwcfg3=%08x\n",core_if->hwcfg3.d32);
    DWC_DEBUGPL(DBG_CILV,"hwcfg4=%08x\n",core_if->hwcfg4.d32);
        

    DWC_DEBUGPL(DBG_CILV,"op_mode=%0x\n",core_if->hwcfg2.b.op_mode);
    DWC_DEBUGPL(DBG_CILV,"arch=%0x\n",core_if->hwcfg2.b.architecture);
    DWC_DEBUGPL(DBG_CILV,"num_dev_ep=%d\n",core_if->hwcfg2.b.num_dev_ep);
    DWC_DEBUGPL(DBG_CILV,"num_host_chan=%d\n",core_if->hwcfg2.b.num_host_chan);
    DWC_DEBUGPL(DBG_CILV,"nonperio_tx_q_depth=0x%0x\n",core_if->hwcfg2.b.nonperio_tx_q_depth);
    DWC_DEBUGPL(DBG_CILV,"host_perio_tx_q_depth=0x%0x\n",core_if->hwcfg2.b.host_perio_tx_q_depth);
    DWC_DEBUGPL(DBG_CILV,"dev_token_q_depth=0x%0x\n",core_if->hwcfg2.b.dev_token_q_depth);

    DWC_DEBUGPL(DBG_CILV,"Total FIFO SZ=%d\n", core_if->hwcfg3.b.dfifo_depth);
    DWC_DEBUGPL(DBG_CILV,"xfer_size_cntr_width=%0x\n", core_if->hwcfg3.b.xfer_size_cntr_width);

    /*
     * Set the SRP sucess bit for FS-I2c
     */
    core_if->srp_success = 0;
    core_if->srp_timer_started = 0;
	
    return core_if;
}
/**
 * This function frees the structures allocated by dwc_otg_cil_init().
 * 
 * @param[in] _core_if The core interface pointer returned from
 * dwc_otg_cil_init().
 *
 */
void dwc_otg_cil_remove( dwc_otg_core_if_t *_core_if )
{
        /* Disable all interrupts */
        dwc_modify_reg32( &_core_if->core_global_regs->gahbcfg, 1, 0);
        dwc_write_reg32( &_core_if->core_global_regs->gintmsk, 0);

        if ( _core_if->dev_if ) {
                kfree( _core_if->dev_if );
        }
        if ( _core_if->host_if ) {
                kfree( _core_if->host_if );
        }
        kfree( _core_if );
}

/**
 * This function enables the controller's Global Interrupt in the AHB Config
 * register.
 *
 * @param[in] _core_if Programming view of DWC_otg controller.
 */
extern void dwc_otg_enable_global_interrupts( dwc_otg_core_if_t *_core_if )
{
        gahbcfg_data_t ahbcfg = { .d32 = 0};
        ahbcfg.b.glblintrmsk = 1; /* Enable interrupts */
        dwc_modify_reg32(&_core_if->core_global_regs->gahbcfg, 0, ahbcfg.d32);
}
/**
 * This function disables the controller's Global Interrupt in the AHB Config
 * register.
 *
 * @param[in] _core_if Programming view of DWC_otg controller.
 */
extern void dwc_otg_disable_global_interrupts( dwc_otg_core_if_t *_core_if )
{
        gahbcfg_data_t ahbcfg = { .d32 = 0};
        ahbcfg.b.glblintrmsk = 1; /* Enable interrupts */
        dwc_modify_reg32(&_core_if->core_global_regs->gahbcfg, ahbcfg.d32, 0);
}

/**
 * This function initializes the commmon interrupts, used in both
 * device and host modes.
 *
 * @param[in] _core_if Programming view of the DWC_otg controller
 *
 */
static void dwc_otg_enable_common_interrupts(dwc_otg_core_if_t *_core_if)
{
        dwc_otg_core_global_regs_t *global_regs = 
                _core_if->core_global_regs;
        gintmsk_data_t intr_mask = { .d32 = 0};
        /* Clear any pending OTG Interrupts */
        dwc_write_reg32( &global_regs->gotgint, 0xFFFFFFFF); 
        /* Clear any pending interrupts */
        dwc_write_reg32( &global_regs->gintsts, 0xFFFFFFFF); 
        /* 
         * Enable the interrupts in the GINTMSK. 
         */
        intr_mask.b.modemismatch = 1;
        intr_mask.b.otgintr = 1;
        if (!_core_if->dma_enable) {
                intr_mask.b.rxstsqlvl = 1;
        }
        intr_mask.b.conidstschng = 1;
        intr_mask.b.wkupintr = 1;
        intr_mask.b.disconnect = 1;
        intr_mask.b.usbsuspend = 1;
	intr_mask.b.sessreqintr = 1;
        dwc_write_reg32( &global_regs->gintmsk, intr_mask.d32);
}

/**
 * Initializes the FSLSPClkSel field of the HCFG register depending on the PHY
 * type.
 */
static void init_fslspclksel(dwc_otg_core_if_t *_core_if)
{
	uint32_t 	val;
	hcfg_data_t 	hcfg;

	if (((_core_if->hwcfg2.b.hs_phy_type == 2) &&
	     (_core_if->hwcfg2.b.fs_phy_type == 1) &&
	     (_core_if->core_params->ulpi_fs_ls)) ||
	    (_core_if->core_params->phy_type == DWC_PHY_TYPE_PARAM_FS))
	{
		/* Full speed PHY */
		val = DWC_HCFG_48_MHZ;
	} else {
		/* High speed PHY running at full speed or high speed */
		val = DWC_HCFG_30_60_MHZ;
	}

	DWC_DEBUGPL(DBG_CIL, "Initializing HCFG.FSLSPClkSel to 0x%1x\n", val);
	hcfg.d32 = dwc_read_reg32(&_core_if->host_if->host_global_regs->hcfg);
	hcfg.b.fslspclksel = val;
	dwc_write_reg32(&_core_if->host_if->host_global_regs->hcfg, hcfg.d32);
}

/**
 * Initializes the DevSpd field of the DCFG register depending on the PHY type
 * and the enumeration speed of the device.
 */
static void init_devspd(dwc_otg_core_if_t *_core_if)
{
	uint32_t 	val;
	dcfg_data_t 	dcfg;

	if (((_core_if->hwcfg2.b.hs_phy_type == 2) &&
	     (_core_if->hwcfg2.b.fs_phy_type == 1) &&
	     (_core_if->core_params->ulpi_fs_ls)) ||
	     (_core_if->core_params->phy_type == DWC_PHY_TYPE_PARAM_FS)) 
	{
		/* Full speed PHY */
		val = 0x3;
	} else if (_core_if->core_params->speed == DWC_SPEED_PARAM_FULL) {
		/* High speed PHY running at full speed */
		val = 0x1;
	} else {
		/* High speed PHY running at high speed */
		val = 0x0;
	}

	DWC_DEBUGPL(DBG_CIL, "Initializing DCFG.DevSpd to 0x%1x\n", val);
	dcfg.d32 = dwc_read_reg32(&_core_if->dev_if->dev_global_regs->dcfg);
	dcfg.b.devspd = val;
	dwc_write_reg32(&_core_if->dev_if->dev_global_regs->dcfg, dcfg.d32);
}

/**
 * This function calculates the number of IN EPS
 * using GHWCFG1 and GHWCFG2 registers values
 *
 * @param _pcd the pcd structure.
 */
static uint32_t calc_num_in_eps(dwc_otg_core_if_t * _core_if)
{
	uint32_t num_in_eps = 0;
	uint32_t num_eps = _core_if->hwcfg2.b.num_dev_ep;
	uint32_t hwcfg1 = _core_if->hwcfg1.d32 >> 2;
	uint32_t num_tx_fifos = _core_if->hwcfg4.b.num_in_eps;
	int i;
	for (i = 0; i < num_eps; ++i) {
		if (!(hwcfg1 & 0x1))
			num_in_eps++;
		hwcfg1 >>= 2;
	}
	if (_core_if->hwcfg4.b.ded_fifo_en) {
		num_in_eps = (num_in_eps > num_tx_fifos) ? num_tx_fifos : num_in_eps;
	}
	return num_in_eps;
}


/**
 * This function calculates the number of OUT EPS
 * using GHWCFG1 and GHWCFG2 registers values
 *
 * @param _pcd the pcd structure.
 */
static uint32_t calc_num_out_eps(dwc_otg_core_if_t * _core_if)
{
	uint32_t num_out_eps = 0;
	uint32_t num_eps = _core_if->hwcfg2.b.num_dev_ep;
	uint32_t hwcfg1 = _core_if->hwcfg1.d32 >> 2;
	int i;
	for (i = 0; i < num_eps; ++i) {
		if (!(hwcfg1 & 0x2))
			num_out_eps++;
		hwcfg1 >>= 2;
	}
	return num_out_eps;
}
/**
 * This function initializes the DWC_otg controller registers and
 * prepares the core for device mode or host mode operation.
 *
 * @param _core_if Programming view of the DWC_otg controller
 *
 */
void dwc_otg_core_init(dwc_otg_core_if_t *_core_if) 
{
	dwc_otg_core_global_regs_t * global_regs = _core_if->core_global_regs;
    dwc_otg_dev_if_t *dev_if = _core_if->dev_if;
    int i = 0;
    gahbcfg_data_t ahbcfg = { .d32 = 0};
    gusbcfg_data_t usbcfg = { .d32 = 0 };
    gi2cctl_data_t i2cctl = {.d32 = 0};

    DWC_DEBUGPL(DBG_CILV, "dwc_otg_core_init(%p)\n",_core_if);

    /* Common Initialization */

    usbcfg.d32 = dwc_read_reg32(&global_regs->gusbcfg);
	DWC_DEBUGPL(DBG_CIL, "USB config register: 0x%08x\n", usbcfg.d32);

    /* Program the ULPI External VBUS bit if needed */
    //usbcfg.b.ulpi_ext_vbus_drv = 1;
    //usbcfg.b.ulpi_ext_vbus_drv = 0;
    usbcfg.b.ulpi_ext_vbus_drv = 
        (_core_if->core_params->phy_ulpi_ext_vbus == DWC_PHY_ULPI_EXTERNAL_VBUS) ? 1 : 0;

    /* Set external TS Dline pulsing */
    usbcfg.b.term_sel_dl_pulse = (_core_if->core_params->ts_dline == 1) ? 1 : 0;
    dwc_write_reg32 (&global_regs->gusbcfg, usbcfg.d32);

    /* Reset the Controller */
    dwc_otg_core_reset( _core_if );

    /* Initialize parameters from Hardware configuration registers. */
#if 0
    dev_if->num_eps = _core_if->hwcfg2.b.num_dev_ep;
    dev_if->num_perio_eps = _core_if->hwcfg4.b.num_dev_perio_in_ep;
#else
	dev_if->num_in_eps = calc_num_in_eps(_core_if);
	dev_if->num_out_eps = calc_num_out_eps(_core_if);
#endif        
	DWC_DEBUGPL(DBG_CIL, "num_dev_perio_in_ep=%d\n",
		       _core_if->hwcfg4.b.num_dev_perio_in_ep);
	DWC_DEBUGPL(DBG_CIL, "Is power optimization enabled?  %s\n",
		     _core_if->hwcfg4.b.power_optimiz ? "Yes" : "No");
	DWC_DEBUGPL(DBG_CIL, "vbus_valid filter enabled?  %s\n",
		     _core_if->hwcfg4.b.vbus_valid_filt_en ? "Yes" : "No");
	DWC_DEBUGPL(DBG_CIL, "iddig filter enabled?  %s\n",
		     _core_if->hwcfg4.b.iddig_filt_en ? "Yes" : "No");

    DWC_DEBUGPL(DBG_CIL, "num_dev_perio_in_ep=%d\n",_core_if->hwcfg4.b.num_dev_perio_in_ep);
    for (i=0; i < _core_if->hwcfg4.b.num_dev_perio_in_ep; i++) {
        dev_if->perio_tx_fifo_size[i] =
		    dwc_read_reg32(&global_regs->dptxfsiz_dieptxf[i]) >> 16;
		DWC_DEBUGPL(DBG_CIL, "Periodic Tx FIFO SZ #%d=0x%0x\n", i,
			     dev_if->perio_tx_fifo_size[i]);
	}
	for (i = 0; i < _core_if->hwcfg4.b.num_in_eps; i++) {
		dev_if->tx_fifo_size[i] =
		    dwc_read_reg32(&global_regs->dptxfsiz_dieptxf[i]) >> 16;
		DWC_DEBUGPL(DBG_CIL, "Tx FIFO SZ #%d=0x%0x\n", i,
			     dev_if->perio_tx_fifo_size[i]);
	}
        
    _core_if->total_fifo_size = _core_if->hwcfg3.b.dfifo_depth;
	_core_if->rx_fifo_size = dwc_read_reg32(&global_regs->grxfsiz);
	_core_if->nperio_tx_fifo_size = dwc_read_reg32(&global_regs->gnptxfsiz) >> 16;
        
    DWC_DEBUGPL(DBG_CIL, "Total FIFO SZ=%d\n", _core_if->total_fifo_size);
    DWC_DEBUGPL(DBG_CIL, "Rx FIFO SZ=%d\n", _core_if->rx_fifo_size);
    DWC_DEBUGPL(DBG_CIL, "NP Tx FIFO SZ=%d\n", _core_if->nperio_tx_fifo_size);

    /* This programming sequence needs to happen in FS mode before any other
    * programming occurs */
    if ((_core_if->core_params->speed == DWC_SPEED_PARAM_FULL) &&
        (_core_if->core_params->phy_type == DWC_PHY_TYPE_PARAM_FS)) {
        /* If FS mode with FS PHY */

        /* core_init() is now called on every switch so only call the
         * following for the first time through. */
        if (!_core_if->phy_init_done) {
            _core_if->phy_init_done = 1;
            DWC_DEBUGPL(DBG_CIL, "FS_PHY detected\n");
            usbcfg.d32 = dwc_read_reg32(&global_regs->gusbcfg);
            usbcfg.b.physel = 1;
            dwc_write_reg32 (&global_regs->gusbcfg, usbcfg.d32);

            /* Reset after a PHY select */
            dwc_otg_core_reset( _core_if );
        }

        /* Program DCFG.DevSpd or HCFG.FSLSPclkSel to 48Mhz in FS.  Also
         * do this on HNP Dev/Host mode switches (done in dev_init and
         * host_init). */
        if (dwc_otg_is_host_mode(_core_if)) {
			DWC_DEBUGPL(DBG_CIL, "host mode\n");
            init_fslspclksel(_core_if);
		} else {
			DWC_DEBUGPL(DBG_CIL, "device mode\n");
            init_devspd(_core_if);
        }

        if (_core_if->core_params->i2c_enable) {
            DWC_DEBUGPL(DBG_CIL, "FS_PHY Enabling I2c\n");
            /* Program GUSBCFG.OtgUtmifsSel to I2C */
            usbcfg.d32 = dwc_read_reg32(&global_regs->gusbcfg);
            usbcfg.b.otgutmifssel = 1;
            dwc_write_reg32 (&global_regs->gusbcfg, usbcfg.d32);
				
            /* Program GI2CCTL.I2CEn */
            i2cctl.d32 = dwc_read_reg32(&global_regs->gi2cctl);
            i2cctl.b.i2cdevaddr = 1;
            i2cctl.b.i2cen = 0;
            dwc_write_reg32 (&global_regs->gi2cctl, i2cctl.d32);
            i2cctl.b.i2cen = 1;
            dwc_write_reg32 (&global_regs->gi2cctl, i2cctl.d32);
        }

    } /* endif speed == DWC_SPEED_PARAM_FULL */
	else {
        /* High speed PHY. */
        if (!_core_if->phy_init_done) {
            _core_if->phy_init_done = 1;
			DWC_DEBUGPL(DBG_CIL, "High spped PHY\n");
            /* HS PHY parameters.  These parameters are preserved
             * during soft reset so only program the first time.  Do
             * a soft reset immediately after setting phyif.  */
            usbcfg.b.ulpi_utmi_sel = _core_if->core_params->phy_type;
            if (usbcfg.b.ulpi_utmi_sel == 2) { // winder
				DWC_DEBUGPL(DBG_CIL, "ULPI\n");
                /* ULPI interface */
                usbcfg.b.phyif = 0;
                usbcfg.b.ddrsel = _core_if->core_params->phy_ulpi_ddr;
            } else {
                /* UTMI+ interface */
                if (_core_if->core_params->phy_utmi_width == 16) {
                    usbcfg.b.phyif = 1;
					DWC_DEBUGPL(DBG_CIL, "UTMI+ 16\n");
				} else {
					DWC_DEBUGPL(DBG_CIL, "UTMI+ 8\n");
                    usbcfg.b.phyif = 0;
                }
            }
            dwc_write_reg32( &global_regs->gusbcfg, usbcfg.d32);

            /* Reset after setting the PHY parameters */
            dwc_otg_core_reset( _core_if );
        }
    }

    if ((_core_if->hwcfg2.b.hs_phy_type == 2) &&
        (_core_if->hwcfg2.b.fs_phy_type == 1) &&
        (_core_if->core_params->ulpi_fs_ls)) 
    {
        DWC_DEBUGPL(DBG_CIL, "Setting ULPI FSLS\n");
        usbcfg.d32 = dwc_read_reg32(&global_regs->gusbcfg);
        usbcfg.b.ulpi_fsls = 1;
        usbcfg.b.ulpi_clk_sus_m = 1;
        dwc_write_reg32(&global_regs->gusbcfg, usbcfg.d32);
	} else {
		DWC_DEBUGPL(DBG_CIL, "Setting ULPI FSLS=0\n");
        usbcfg.d32 = dwc_read_reg32(&global_regs->gusbcfg);
        usbcfg.b.ulpi_fsls = 0;
        usbcfg.b.ulpi_clk_sus_m = 0;
        dwc_write_reg32(&global_regs->gusbcfg, usbcfg.d32);
    }

    /* Program the GAHBCFG Register.*/
    switch (_core_if->hwcfg2.b.architecture){

        case DWC_SLAVE_ONLY_ARCH:
            DWC_DEBUGPL(DBG_CIL, "Slave Only Mode\n");
            ahbcfg.b.nptxfemplvl_txfemplvl = DWC_GAHBCFG_TXFEMPTYLVL_HALFEMPTY;
            ahbcfg.b.ptxfemplvl = DWC_GAHBCFG_TXFEMPTYLVL_HALFEMPTY;
            _core_if->dma_enable = 0;
            break;

        case DWC_EXT_DMA_ARCH:
            DWC_DEBUGPL(DBG_CIL, "External DMA Mode\n");
            ahbcfg.b.hburstlen = _core_if->core_params->dma_burst_size; 
            _core_if->dma_enable = (_core_if->core_params->dma_enable != 0);
            break;

        case DWC_INT_DMA_ARCH:
            DWC_DEBUGPL(DBG_CIL, "Internal DMA Mode\n");
            //ahbcfg.b.hburstlen = DWC_GAHBCFG_INT_DMA_BURST_INCR;
            ahbcfg.b.hburstlen = DWC_GAHBCFG_INT_DMA_BURST_INCR4;
            _core_if->dma_enable = (_core_if->core_params->dma_enable != 0);
            break;
    }
    ahbcfg.b.dmaenable = _core_if->dma_enable;
    dwc_write_reg32(&global_regs->gahbcfg, ahbcfg.d32);
	_core_if->en_multiple_tx_fifo = _core_if->hwcfg4.b.ded_fifo_en;

    /* 
     * Program the GUSBCFG register. 
     */
    usbcfg.d32 = dwc_read_reg32( &global_regs->gusbcfg );

    switch (_core_if->hwcfg2.b.op_mode) {
        case DWC_MODE_HNP_SRP_CAPABLE:
            usbcfg.b.hnpcap = (_core_if->core_params->otg_cap ==
            DWC_OTG_CAP_PARAM_HNP_SRP_CAPABLE);
            usbcfg.b.srpcap = (_core_if->core_params->otg_cap !=
            DWC_OTG_CAP_PARAM_NO_HNP_SRP_CAPABLE);
            break;

        case DWC_MODE_SRP_ONLY_CAPABLE:
            usbcfg.b.hnpcap = 0;
            usbcfg.b.srpcap = (_core_if->core_params->otg_cap !=
            DWC_OTG_CAP_PARAM_NO_HNP_SRP_CAPABLE);
            break;

        case DWC_MODE_NO_HNP_SRP_CAPABLE:
            usbcfg.b.hnpcap = 0;
            usbcfg.b.srpcap = 0;
            break;

        case DWC_MODE_SRP_CAPABLE_DEVICE:
            usbcfg.b.hnpcap = 0;
            usbcfg.b.srpcap = (_core_if->core_params->otg_cap !=
            DWC_OTG_CAP_PARAM_NO_HNP_SRP_CAPABLE);
            break;

        case DWC_MODE_NO_SRP_CAPABLE_DEVICE:
            usbcfg.b.hnpcap = 0;
            usbcfg.b.srpcap = 0;
            break;

        case DWC_MODE_SRP_CAPABLE_HOST:
            usbcfg.b.hnpcap = 0;
            usbcfg.b.srpcap = (_core_if->core_params->otg_cap !=
            DWC_OTG_CAP_PARAM_NO_HNP_SRP_CAPABLE);
            break;

        case DWC_MODE_NO_SRP_CAPABLE_HOST:
            usbcfg.b.hnpcap = 0;
            usbcfg.b.srpcap = 0;
            break;
    }

    dwc_write_reg32( &global_regs->gusbcfg, usbcfg.d32);
        
    /* Enable common interrupts */
    dwc_otg_enable_common_interrupts( _core_if );

    /* Do device or host intialization based on mode during PCD
     * and HCD initialization  */
    if (dwc_otg_is_host_mode( _core_if )) {
        DWC_DEBUGPL(DBG_ANY, "Host Mode\n" );
        _core_if->op_state = A_HOST;
    } else {
        DWC_DEBUGPL(DBG_ANY, "Device Mode\n" );
        _core_if->op_state = B_PERIPHERAL;
#ifdef DWC_DEVICE_ONLY
        dwc_otg_core_dev_init( _core_if );
#endif
    }
}


/** 
 * This function enables the Device mode interrupts.
 *
 * @param _core_if Programming view of DWC_otg controller
 */
void dwc_otg_enable_device_interrupts(dwc_otg_core_if_t *_core_if)
{
        gintmsk_data_t intr_mask = { .d32 = 0};
	dwc_otg_core_global_regs_t * global_regs = _core_if->core_global_regs;

        DWC_DEBUGPL(DBG_CIL, "%s()\n", __func__);

        /* Disable all interrupts. */
        dwc_write_reg32( &global_regs->gintmsk, 0);

        /* Clear any pending interrupts */
        dwc_write_reg32( &global_regs->gintsts, 0xFFFFFFFF); 

        /* Enable the common interrupts */
        dwc_otg_enable_common_interrupts( _core_if );

        /* Enable interrupts */
        intr_mask.b.usbreset = 1;
        intr_mask.b.enumdone = 1;
        //intr_mask.b.epmismatch = 1;
        intr_mask.b.inepintr = 1;
        intr_mask.b.outepintr = 1;
        intr_mask.b.erlysuspend = 1;
	if (_core_if->en_multiple_tx_fifo == 0) {
		intr_mask.b.epmismatch = 1;
	}

        /** @todo NGS: Should this be a module parameter? */
        intr_mask.b.isooutdrop = 1;
        intr_mask.b.eopframe = 1;
        intr_mask.b.incomplisoin = 1;
        intr_mask.b.incomplisoout = 1;

        dwc_modify_reg32( &global_regs->gintmsk, intr_mask.d32, intr_mask.d32);

        DWC_DEBUGPL(DBG_CIL, "%s() gintmsk=%0x\n", __func__, 
                    dwc_read_reg32( &global_regs->gintmsk));
}

/**
 * This function initializes the DWC_otg controller registers for
 * device mode.
 * 
 * @param _core_if Programming view of DWC_otg controller
 *
 */
void dwc_otg_core_dev_init(dwc_otg_core_if_t *_core_if)
{
        dwc_otg_core_global_regs_t *global_regs = 
                _core_if->core_global_regs;
        dwc_otg_dev_if_t *dev_if = _core_if->dev_if;
        dwc_otg_core_params_t *params = _core_if->core_params;
        dcfg_data_t dcfg = {.d32 = 0};
        grstctl_t resetctl = { .d32=0 };
        int i;
        uint32_t rx_fifo_size;
        fifosize_data_t nptxfifosize;
	fifosize_data_t txfifosize;
	dthrctl_data_t dthrctl;

        fifosize_data_t ptxfifosize;
        
        /* Restart the Phy Clock */
        dwc_write_reg32(_core_if->pcgcctl, 0);
        
        /* Device configuration register */
	init_devspd(_core_if);
	dcfg.d32 = dwc_read_reg32( &dev_if->dev_global_regs->dcfg);
        dcfg.b.perfrint = DWC_DCFG_FRAME_INTERVAL_80;
        dwc_write_reg32( &dev_if->dev_global_regs->dcfg, dcfg.d32 );

        /* Configure data FIFO sizes */
        if ( _core_if->hwcfg2.b.dynamic_fifo && params->enable_dynamic_fifo ) {
                
                DWC_DEBUGPL(DBG_CIL, "Total FIFO Size=%d\n", _core_if->total_fifo_size);
                DWC_DEBUGPL(DBG_CIL, "Rx FIFO Size=%d\n", params->dev_rx_fifo_size);
                DWC_DEBUGPL(DBG_CIL, "NP Tx FIFO Size=%d\n", params->dev_nperio_tx_fifo_size);

		/* Rx FIFO */
                DWC_DEBUGPL(DBG_CIL, "initial grxfsiz=%08x\n", 
                            dwc_read_reg32(&global_regs->grxfsiz));
                rx_fifo_size = params->dev_rx_fifo_size;
                dwc_write_reg32( &global_regs->grxfsiz, rx_fifo_size );
                DWC_DEBUGPL(DBG_CIL, "new grxfsiz=%08x\n", 
                            dwc_read_reg32(&global_regs->grxfsiz));

		/** Set Periodic Tx FIFO Mask all bits 0 */
	    _core_if->p_tx_msk = 0;

		/** Set Tx FIFO Mask all bits 0 */
	    _core_if->tx_msk = 0;
		if (_core_if->en_multiple_tx_fifo == 0) {
		/* Non-periodic Tx FIFO */
                DWC_DEBUGPL(DBG_CIL, "initial gnptxfsiz=%08x\n", 
                            dwc_read_reg32(&global_regs->gnptxfsiz));
                nptxfifosize.b.depth  = params->dev_nperio_tx_fifo_size;
                nptxfifosize.b.startaddr = params->dev_rx_fifo_size;
                dwc_write_reg32( &global_regs->gnptxfsiz, nptxfifosize.d32 );
                DWC_DEBUGPL(DBG_CIL, "new gnptxfsiz=%08x\n", 
                            dwc_read_reg32(&global_regs->gnptxfsiz));


                /**@todo NGS: Fix Periodic FIFO Sizing! */
		/*
		 * Periodic Tx FIFOs These FIFOs are numbered from 1 to 15.
		 * Indexes of the FIFO size module parameters in the
		 * dev_perio_tx_fifo_size array and the FIFO size registers in
		 * the dptxfsiz array run from 0 to 14.
		 */
                /** @todo Finish debug of this */   
		    ptxfifosize.b.startaddr =
		    nptxfifosize.b.startaddr + nptxfifosize.b.depth;
			for (i = 0; i < _core_if->hwcfg4.b.num_dev_perio_in_ep;i++) {
			ptxfifosize.b.depth = params->dev_perio_tx_fifo_size[i];
				DWC_DEBUGPL(DBG_CIL,"initial dptxfsiz_dieptxf[%d]=%08x\n",
				     i,dwc_read_reg32(&global_regs->dptxfsiz_dieptxf[i]));
				dwc_write_reg32(&global_regs->dptxfsiz_dieptxf[i],ptxfifosize.d32);
				DWC_DEBUGPL(DBG_CIL,"new dptxfsiz_dieptxf[%d]=%08x\n",
				     i,dwc_read_reg32(&global_regs->dptxfsiz_dieptxf[i]));
                        ptxfifosize.b.startaddr += ptxfifosize.b.depth;
                }
		} else {

		    /*
		     * Tx FIFOs These FIFOs are numbered from 1 to 15.
		     * Indexes of the FIFO size module parameters in the
		     * dev_tx_fifo_size array and the FIFO size registers in
		     * the dptxfsiz_dieptxf array run from 0 to 14.
		     */

		    /* Non-periodic Tx FIFO */
		    DWC_DEBUGPL(DBG_CIL, "initial gnptxfsiz=%08x\n",
				dwc_read_reg32(&global_regs->gnptxfsiz));
			nptxfifosize.b.depth = params->dev_nperio_tx_fifo_size;
			nptxfifosize.b.startaddr = params->dev_rx_fifo_size;
			dwc_write_reg32(&global_regs->gnptxfsiz, nptxfifosize.d32);
			DWC_DEBUGPL(DBG_CIL, "new gnptxfsiz=%08x\n",
				      dwc_read_reg32(&global_regs->gnptxfsiz));
			txfifosize.b.startaddr = nptxfifosize.b.startaddr + nptxfifosize.b.depth;
			for (i = 1;i < _core_if->hwcfg4.b.num_dev_perio_in_ep;i++) {
				txfifosize.b.depth = params->dev_tx_fifo_size[i];
				DWC_DEBUGPL(DBG_CIL,"initial dptxfsiz_dieptxf[%d]=%08x\n",
				      i,dwc_read_reg32(&global_regs->dptxfsiz_dieptxf[i]));
				dwc_write_reg32(&global_regs->dptxfsiz_dieptxf[i - 1],txfifosize.d32);
				DWC_DEBUGPL(DBG_CIL,"new dptxfsiz_dieptxf[%d]=%08x\n",
				      i,dwc_read_reg32(&global_regs->dptxfsiz_dieptxf[i-1]));
				txfifosize.b.startaddr += txfifosize.b.depth;
        }
		}
	}
        /* Flush the FIFOs */
        dwc_otg_flush_tx_fifo(_core_if, 0x10); /* all Tx FIFOs */
        dwc_otg_flush_rx_fifo(_core_if);

	/* Flush the Learning Queue. */
	resetctl.b.intknqflsh = 1;
        dwc_write_reg32( &_core_if->core_global_regs->grstctl, resetctl.d32);

        /* Clear all pending Device Interrupts */
        dwc_write_reg32( &dev_if->dev_global_regs->diepmsk, 0 );
        dwc_write_reg32( &dev_if->dev_global_regs->doepmsk, 0 );
        dwc_write_reg32( &dev_if->dev_global_regs->daint, 0xFFFFFFFF );
        dwc_write_reg32( &dev_if->dev_global_regs->daintmsk, 0 );

	for (i = 0; i <= dev_if->num_in_eps; i++) {
		depctl_data_t depctl;
		depctl.d32 = dwc_read_reg32(&dev_if->in_ep_regs[i]->diepctl);
		if (depctl.b.epena) {
			depctl.d32 = 0;
			depctl.b.epdis = 1;
			depctl.b.snak = 1;
		} else {
			depctl.d32 = 0;
		}
		dwc_write_reg32( &dev_if->in_ep_regs[i]->diepctl, depctl.d32);

		dwc_write_reg32(&dev_if->in_ep_regs[i]->dieptsiz, 0);
		dwc_write_reg32(&dev_if->in_ep_regs[i]->diepdma, 0);
		dwc_write_reg32(&dev_if->in_ep_regs[i]->diepint, 0xFF);
	}
	for (i = 0; i <= dev_if->num_out_eps; i++) {
		depctl_data_t depctl;
		depctl.d32 = dwc_read_reg32(&dev_if->out_ep_regs[i]->doepctl);
		if (depctl.b.epena) {
			depctl.d32 = 0;
			depctl.b.epdis = 1;
			depctl.b.snak = 1;
		} else {
			depctl.d32 = 0;
		}
		dwc_write_reg32( &dev_if->out_ep_regs[i]->doepctl, depctl.d32);

                //dwc_write_reg32( &dev_if->in_ep_regs[i]->dieptsiz, 0);
                dwc_write_reg32( &dev_if->out_ep_regs[i]->doeptsiz, 0);
                //dwc_write_reg32( &dev_if->in_ep_regs[i]->diepdma, 0);
                dwc_write_reg32( &dev_if->out_ep_regs[i]->doepdma, 0);
                //dwc_write_reg32( &dev_if->in_ep_regs[i]->diepint, 0xFF);
                dwc_write_reg32( &dev_if->out_ep_regs[i]->doepint, 0xFF);
        }
        
	if (_core_if->en_multiple_tx_fifo && _core_if->dma_enable) {
		dev_if->non_iso_tx_thr_en = _core_if->core_params->thr_ctl & 0x1;
		dev_if->iso_tx_thr_en = (_core_if->core_params->thr_ctl >> 1) & 0x1;
		dev_if->rx_thr_en = (_core_if->core_params->thr_ctl >> 2) & 0x1;
		dev_if->rx_thr_length = _core_if->core_params->rx_thr_length;
		dev_if->tx_thr_length = _core_if->core_params->tx_thr_length;
		dthrctl.d32 = 0;
		dthrctl.b.non_iso_thr_en = dev_if->non_iso_tx_thr_en;
		dthrctl.b.iso_thr_en = dev_if->iso_tx_thr_en;
		dthrctl.b.tx_thr_len = dev_if->tx_thr_length;
		dthrctl.b.rx_thr_en = dev_if->rx_thr_en;
		dthrctl.b.rx_thr_len = dev_if->rx_thr_length;
		dwc_write_reg32(&dev_if->dev_global_regs->dtknqr3_dthrctl,dthrctl.d32);
		DWC_DEBUGPL(DBG_CIL, "Non ISO Tx Thr - %d\nISO Tx Thr - %d\n"
					"Rx Thr - %d\nTx Thr Len - %d\nRx Thr Len - %d\n",
					dthrctl.b.non_iso_thr_en, dthrctl.b.iso_thr_en,
					dthrctl.b.rx_thr_en, dthrctl.b.tx_thr_len,
					dthrctl.b.rx_thr_len);
	}
        dwc_otg_enable_device_interrupts( _core_if );        
	{
		diepmsk_data_t msk = {.d32 = 0};
		msk.b.txfifoundrn = 1;
		dwc_modify_reg32(&dev_if->dev_global_regs->diepmsk, msk.d32,msk.d32);
}
}

/** 
 * This function enables the Host mode interrupts.
 *
 * @param _core_if Programming view of DWC_otg controller
 */
void dwc_otg_enable_host_interrupts(dwc_otg_core_if_t *_core_if)
{
        dwc_otg_core_global_regs_t *global_regs = _core_if->core_global_regs;
	gintmsk_data_t intr_mask = {.d32 = 0};

        DWC_DEBUGPL(DBG_CIL, "%s()\n", __func__);

        /* Disable all interrupts. */
        dwc_write_reg32(&global_regs->gintmsk, 0);

        /* Clear any pending interrupts. */
        dwc_write_reg32(&global_regs->gintsts, 0xFFFFFFFF); 

        /* Enable the common interrupts */
        dwc_otg_enable_common_interrupts(_core_if);

	/*
	 * Enable host mode interrupts without disturbing common
	 * interrupts.
	 */
	intr_mask.b.sofintr = 1;
	intr_mask.b.portintr = 1;
	intr_mask.b.hcintr = 1;

        //dwc_modify_reg32(&global_regs->gintmsk, intr_mask.d32, intr_mask.d32);
        //dwc_modify_reg32(&global_regs->gintmsk, 0, intr_mask.d32);
	dwc_modify_reg32(&global_regs->gintmsk, intr_mask.d32, intr_mask.d32);
}

/** 
 * This function disables the Host Mode interrupts.
 *
 * @param _core_if Programming view of DWC_otg controller
 */
void dwc_otg_disable_host_interrupts(dwc_otg_core_if_t *_core_if)
{
        dwc_otg_core_global_regs_t *global_regs =
		_core_if->core_global_regs;
	gintmsk_data_t intr_mask = {.d32 = 0};

        DWC_DEBUGPL(DBG_CILV, "%s()\n", __func__);
         
	/*
	 * Disable host mode interrupts without disturbing common
	 * interrupts.
	 */
	intr_mask.b.sofintr = 1;
	intr_mask.b.portintr = 1;
	intr_mask.b.hcintr = 1;
        intr_mask.b.ptxfempty = 1;
	intr_mask.b.nptxfempty = 1;
        
        dwc_modify_reg32(&global_regs->gintmsk, intr_mask.d32, 0);
}

#if 0
/* currently not used, keep it here as if needed later */
static int phy_read(dwc_otg_core_if_t * _core_if, int addr)
{
	u32 val;
	int timeout = 10;

	dwc_write_reg32(&_core_if->core_global_regs->gpvndctl,
			0x02000000 | (addr << 16));
	val = dwc_read_reg32(&_core_if->core_global_regs->gpvndctl);
	while (((val & 0x08000000) == 0) && (timeout--)) {
		udelay(1000);
		val = dwc_read_reg32(&_core_if->core_global_regs->gpvndctl);
	}
	val = dwc_read_reg32(&_core_if->core_global_regs->gpvndctl);
	printk("%s: addr=%02x regval=%02x\n", __func__, addr, val & 0x000000ff);

	return 0;
}
#endif

/**
 * This function initializes the DWC_otg controller registers for
 * host mode.
 *
 * This function flushes the Tx and Rx FIFOs and it flushes any entries in the
 * request queues. Host channels are reset to ensure that they are ready for
 * performing transfers.
 *
 * @param _core_if Programming view of DWC_otg controller
 *
 */
void dwc_otg_core_host_init(dwc_otg_core_if_t *_core_if)
{
        dwc_otg_core_global_regs_t *global_regs = _core_if->core_global_regs;
	dwc_otg_host_if_t 	*host_if = _core_if->host_if;
        dwc_otg_core_params_t 	*params = _core_if->core_params;
	hprt0_data_t 		hprt0 = {.d32 = 0};
        fifosize_data_t 	nptxfifosize;
        fifosize_data_t 	ptxfifosize;
	int			i;
	hcchar_data_t		hcchar;
	hcfg_data_t		hcfg;
	dwc_otg_hc_regs_t	*hc_regs;
	int			num_channels;
	gotgctl_data_t  gotgctl = {.d32 = 0};

	DWC_DEBUGPL(DBG_CILV,"%s(%p)\n", __func__, _core_if);

        /* Restart the Phy Clock */
        dwc_write_reg32(_core_if->pcgcctl, 0);
        
	/* Initialize Host Configuration Register */
	init_fslspclksel(_core_if);
	if (_core_if->core_params->speed == DWC_SPEED_PARAM_FULL) {
		hcfg.d32 = dwc_read_reg32(&host_if->host_global_regs->hcfg);
		hcfg.b.fslssupp = 1;
		dwc_write_reg32(&host_if->host_global_regs->hcfg, hcfg.d32);
	}

	/* Configure data FIFO sizes */
	if (_core_if->hwcfg2.b.dynamic_fifo && params->enable_dynamic_fifo) {
                DWC_DEBUGPL(DBG_CIL,"Total FIFO Size=%d\n", _core_if->total_fifo_size);
                DWC_DEBUGPL(DBG_CIL,"Rx FIFO Size=%d\n", params->host_rx_fifo_size);
                DWC_DEBUGPL(DBG_CIL,"NP Tx FIFO Size=%d\n", params->host_nperio_tx_fifo_size);
                DWC_DEBUGPL(DBG_CIL,"P Tx FIFO Size=%d\n", params->host_perio_tx_fifo_size);

		/* Rx FIFO */
		DWC_DEBUGPL(DBG_CIL,"initial grxfsiz=%08x\n", dwc_read_reg32(&global_regs->grxfsiz));
		dwc_write_reg32(&global_regs->grxfsiz, params->host_rx_fifo_size);
		DWC_DEBUGPL(DBG_CIL,"new grxfsiz=%08x\n", dwc_read_reg32(&global_regs->grxfsiz));

		/* Non-periodic Tx FIFO */
                DWC_DEBUGPL(DBG_CIL,"initial gnptxfsiz=%08x\n", dwc_read_reg32(&global_regs->gnptxfsiz));
                nptxfifosize.b.depth  = params->host_nperio_tx_fifo_size;
                nptxfifosize.b.startaddr = params->host_rx_fifo_size;
                dwc_write_reg32(&global_regs->gnptxfsiz, nptxfifosize.d32);
                DWC_DEBUGPL(DBG_CIL,"new gnptxfsiz=%08x\n", dwc_read_reg32(&global_regs->gnptxfsiz));
		
		/* Periodic Tx FIFO */
                DWC_DEBUGPL(DBG_CIL,"initial hptxfsiz=%08x\n", dwc_read_reg32(&global_regs->hptxfsiz));
                ptxfifosize.b.depth  = params->host_perio_tx_fifo_size;
                ptxfifosize.b.startaddr = nptxfifosize.b.startaddr + nptxfifosize.b.depth;
                dwc_write_reg32(&global_regs->hptxfsiz, ptxfifosize.d32);
                DWC_DEBUGPL(DBG_CIL,"new hptxfsiz=%08x\n", dwc_read_reg32(&global_regs->hptxfsiz));
	}

        /* Clear Host Set HNP Enable in the OTG Control Register */
        gotgctl.b.hstsethnpen = 1;
        dwc_modify_reg32( &global_regs->gotgctl, gotgctl.d32, 0);

	/* Make sure the FIFOs are flushed. */
	dwc_otg_flush_tx_fifo(_core_if, 0x10 /* all Tx FIFOs */);
	dwc_otg_flush_rx_fifo(_core_if);

	/* Flush out any leftover queued requests. */
	num_channels = _core_if->core_params->host_channels;
	for (i = 0; i < num_channels; i++) {
		hc_regs = _core_if->host_if->hc_regs[i];
		hcchar.d32 = dwc_read_reg32(&hc_regs->hcchar);
		hcchar.b.chen = 0;
		hcchar.b.chdis = 1;
		hcchar.b.epdir = 0;
		dwc_write_reg32(&hc_regs->hcchar, hcchar.d32);
	}
	       
	/* Halt all channels to put them into a known state. */
	for (i = 0; i < num_channels; i++) {
		int count = 0;
		hc_regs = _core_if->host_if->hc_regs[i];
		hcchar.d32 = dwc_read_reg32(&hc_regs->hcchar);
		hcchar.b.chen = 1;
		hcchar.b.chdis = 1;
		hcchar.b.epdir = 0;
		dwc_write_reg32(&hc_regs->hcchar, hcchar.d32);
		DWC_DEBUGPL(DBG_HCDV, "%s: Halt channel %d\n", __func__, i);
		do {
			hcchar.d32 = dwc_read_reg32(&hc_regs->hcchar);
			if (++count > 200) {
				DWC_ERROR("%s: Unable to clear halt on channel %d\n",
					  __func__, i);
				break;
			}
			udelay(100);
		} while (hcchar.b.chen);
	}

	/* Turn on the vbus power. */
        DWC_PRINT("Init: Port Power? op_state=%d\n", _core_if->op_state);
        if (_core_if->op_state == A_HOST){   
                hprt0.d32 = dwc_otg_read_hprt0(_core_if);
                DWC_PRINT("Init: Power Port (%d)\n", hprt0.b.prtpwr);
                if (hprt0.b.prtpwr == 0 ) {
                        hprt0.b.prtpwr = 1;
                        dwc_write_reg32(host_if->hprt0, hprt0.d32);
                }  
        }

        dwc_otg_enable_host_interrupts( _core_if );
}

/**
 * Prepares a host channel for transferring packets to/from a specific
 * endpoint. The HCCHARn register is set up with the characteristics specified
 * in _hc. Host channel interrupts that may need to be serviced while this
 * transfer is in progress are enabled.
 *
 * @param _core_if Programming view of DWC_otg controller
 * @param _hc Information needed to initialize the host channel
 */
void dwc_otg_hc_init(dwc_otg_core_if_t *_core_if, dwc_hc_t *_hc)
{
	uint32_t intr_enable;
	hcintmsk_data_t hc_intr_mask;
	gintmsk_data_t gintmsk = {.d32 = 0};
	hcchar_data_t hcchar;
	hcsplt_data_t hcsplt;

	uint8_t hc_num = _hc->hc_num;
	dwc_otg_host_if_t *host_if = _core_if->host_if;
	dwc_otg_hc_regs_t *hc_regs = host_if->hc_regs[hc_num];

	/* Clear old interrupt conditions for this host channel. */
	hc_intr_mask.d32 = 0xFFFFFFFF;
	hc_intr_mask.b.reserved = 0;
	dwc_write_reg32(&hc_regs->hcint, hc_intr_mask.d32);

	/* Enable channel interrupts required for this transfer. */
	hc_intr_mask.d32 = 0;
	hc_intr_mask.b.chhltd = 1;
	if (_core_if->dma_enable) {
		hc_intr_mask.b.ahberr = 1;
		if (_hc->error_state && !_hc->do_split &&
		    _hc->ep_type != DWC_OTG_EP_TYPE_ISOC) {
			hc_intr_mask.b.ack = 1;
			if (_hc->ep_is_in) {
				hc_intr_mask.b.datatglerr = 1;
				if (_hc->ep_type != DWC_OTG_EP_TYPE_INTR) {
					hc_intr_mask.b.nak = 1;
				}
			}
		}
	} else {
		switch (_hc->ep_type) {
		case DWC_OTG_EP_TYPE_CONTROL:
		case DWC_OTG_EP_TYPE_BULK:
			hc_intr_mask.b.xfercompl = 1;
			hc_intr_mask.b.stall = 1;
			hc_intr_mask.b.xacterr = 1;
			hc_intr_mask.b.datatglerr = 1;
			if (_hc->ep_is_in) {
				hc_intr_mask.b.bblerr = 1;
			} else {
				hc_intr_mask.b.nak = 1;
				hc_intr_mask.b.nyet = 1;
				if (_hc->do_ping) {
					hc_intr_mask.b.ack = 1;
				}
			}

			if (_hc->do_split) {
				hc_intr_mask.b.nak = 1;
				if (_hc->complete_split) {
					hc_intr_mask.b.nyet = 1;
				}
				else {
					hc_intr_mask.b.ack = 1;
				}
			}

			if (_hc->error_state) {
				hc_intr_mask.b.ack = 1;
			}
			break;
		case DWC_OTG_EP_TYPE_INTR:
			hc_intr_mask.b.xfercompl = 1;
			hc_intr_mask.b.nak = 1;
			hc_intr_mask.b.stall = 1;
			hc_intr_mask.b.xacterr = 1;
			hc_intr_mask.b.datatglerr = 1;
			hc_intr_mask.b.frmovrun = 1;

			if (_hc->ep_is_in) {
				hc_intr_mask.b.bblerr = 1;
			}
			if (_hc->error_state) {
				hc_intr_mask.b.ack = 1;
			}
			if (_hc->do_split) {
				if (_hc->complete_split) {
					hc_intr_mask.b.nyet = 1;
				}
				else {
					hc_intr_mask.b.ack = 1;
				}
			}
			break;
		case DWC_OTG_EP_TYPE_ISOC:
			hc_intr_mask.b.xfercompl = 1;
			hc_intr_mask.b.frmovrun = 1;
			hc_intr_mask.b.ack = 1;

			if (_hc->ep_is_in) {
				hc_intr_mask.b.xacterr = 1;
				hc_intr_mask.b.bblerr = 1;
			}
			break;
		}
	}
	dwc_write_reg32(&hc_regs->hcintmsk, hc_intr_mask.d32);

	/* Enable the top level host channel interrupt. */
	intr_enable = (1 << hc_num);
	dwc_modify_reg32(&host_if->host_global_regs->haintmsk, 0, intr_enable);

	/* Make sure host channel interrupts are enabled. */
	gintmsk.b.hcintr = 1;
	dwc_modify_reg32(&_core_if->core_global_regs->gintmsk, 0, gintmsk.d32);
	
	/*
	 * Program the HCCHARn register with the endpoint characteristics for
	 * the current transfer.
	 */
	hcchar.d32 = 0;
	hcchar.b.devaddr = _hc->dev_addr;
	hcchar.b.epnum = _hc->ep_num;
	hcchar.b.epdir = _hc->ep_is_in;
	hcchar.b.lspddev = (_hc->speed == DWC_OTG_EP_SPEED_LOW);
	hcchar.b.eptype = _hc->ep_type;
	hcchar.b.mps = _hc->max_packet;

	dwc_write_reg32(&host_if->hc_regs[hc_num]->hcchar, hcchar.d32);

	DWC_DEBUGPL(DBG_HCDV, "%s: Channel %d\n", __func__, _hc->hc_num);
	DWC_DEBUGPL(DBG_HCDV, "  Dev Addr: %d\n", hcchar.b.devaddr);
	DWC_DEBUGPL(DBG_HCDV, "  Ep Num: %d\n", hcchar.b.epnum);
	DWC_DEBUGPL(DBG_HCDV, "  Is In: %d\n", hcchar.b.epdir);
	DWC_DEBUGPL(DBG_HCDV, "  Is Low Speed: %d\n", hcchar.b.lspddev);
	DWC_DEBUGPL(DBG_HCDV, "  Ep Type: %d\n", hcchar.b.eptype);
	DWC_DEBUGPL(DBG_HCDV, "  Max Pkt: %d\n", hcchar.b.mps);
	DWC_DEBUGPL(DBG_HCDV, "  Multi Cnt: %d\n", hcchar.b.multicnt);

	/*
	 * Program the HCSPLIT register for SPLITs
	 */
	hcsplt.d32 = 0;
	if (_hc->do_split) {
		DWC_DEBUGPL(DBG_HCDV, "Programming HC %d with split --> %s\n", _hc->hc_num,
			   _hc->complete_split ? "CSPLIT" : "SSPLIT");
		hcsplt.b.compsplt = _hc->complete_split;
		hcsplt.b.xactpos = _hc->xact_pos;
		hcsplt.b.hubaddr = _hc->hub_addr;
		hcsplt.b.prtaddr = _hc->port_addr;
		DWC_DEBUGPL(DBG_HCDV, "   comp split %d\n", _hc->complete_split);
		DWC_DEBUGPL(DBG_HCDV, "   xact pos %d\n", _hc->xact_pos);
		DWC_DEBUGPL(DBG_HCDV, "   hub addr %d\n", _hc->hub_addr);
		DWC_DEBUGPL(DBG_HCDV, "   port addr %d\n", _hc->port_addr);
		DWC_DEBUGPL(DBG_HCDV, "   is_in %d\n", _hc->ep_is_in);
		DWC_DEBUGPL(DBG_HCDV, "   Max Pkt: %d\n", hcchar.b.mps);
		DWC_DEBUGPL(DBG_HCDV, "   xferlen: %d\n", _hc->xfer_len);		
	}
	dwc_write_reg32(&host_if->hc_regs[hc_num]->hcsplt, hcsplt.d32);

}

/**
 * Attempts to halt a host channel. This function should only be called in
 * Slave mode or to abort a transfer in either Slave mode or DMA mode. Under
 * normal circumstances in DMA mode, the controller halts the channel when the
 * transfer is complete or a condition occurs that requires application
 * intervention.
 *
 * In slave mode, checks for a free request queue entry, then sets the Channel
 * Enable and Channel Disable bits of the Host Channel Characteristics
 * register of the specified channel to intiate the halt. If there is no free
 * request queue entry, sets only the Channel Disable bit of the HCCHARn
 * register to flush requests for this channel. In the latter case, sets a
 * flag to indicate that the host channel needs to be halted when a request
 * queue slot is open.
 *
 * In DMA mode, always sets the Channel Enable and Channel Disable bits of the
 * HCCHARn register. The controller ensures there is space in the request
 * queue before submitting the halt request.
 *
 * Some time may elapse before the core flushes any posted requests for this
 * host channel and halts. The Channel Halted interrupt handler completes the
 * deactivation of the host channel.
 *
 * @param _core_if Controller register interface.
 * @param _hc Host channel to halt.
 * @param _halt_status Reason for halting the channel.
 */
void dwc_otg_hc_halt(dwc_otg_core_if_t *_core_if,
		     dwc_hc_t *_hc,
		     dwc_otg_halt_status_e _halt_status)
{
	gnptxsts_data_t 		nptxsts;
	hptxsts_data_t			hptxsts;
	hcchar_data_t 			hcchar;
	dwc_otg_hc_regs_t 		*hc_regs;
	dwc_otg_core_global_regs_t	*global_regs;
	dwc_otg_host_global_regs_t	*host_global_regs;

	hc_regs = _core_if->host_if->hc_regs[_hc->hc_num];
	global_regs = _core_if->core_global_regs;
	host_global_regs = _core_if->host_if->host_global_regs;

	WARN_ON(_halt_status == DWC_OTG_HC_XFER_NO_HALT_STATUS);

	if (_halt_status == DWC_OTG_HC_XFER_URB_DEQUEUE ||
	    _halt_status == DWC_OTG_HC_XFER_AHB_ERR) {
		/*
		 * Disable all channel interrupts except Ch Halted. The QTD
		 * and QH state associated with this transfer has been cleared
		 * (in the case of URB_DEQUEUE), so the channel needs to be
		 * shut down carefully to prevent crashes.
		 */
		hcintmsk_data_t hcintmsk;
		hcintmsk.d32 = 0;
		hcintmsk.b.chhltd = 1;
		dwc_write_reg32(&hc_regs->hcintmsk, hcintmsk.d32);

		/*
		 * Make sure no other interrupts besides halt are currently
		 * pending. Handling another interrupt could cause a crash due
		 * to the QTD and QH state.
		 */
		dwc_write_reg32(&hc_regs->hcint, ~hcintmsk.d32);

		/*
		 * Make sure the halt status is set to URB_DEQUEUE or AHB_ERR
		 * even if the channel was already halted for some other
		 * reason.
		 */
		_hc->halt_status = _halt_status;

		hcchar.d32 = dwc_read_reg32(&hc_regs->hcchar);
		if (hcchar.b.chen == 0) {
			/*
			 * The channel is either already halted or it hasn't
			 * started yet. In DMA mode, the transfer may halt if
			 * it finishes normally or a condition occurs that
			 * requires driver intervention. Don't want to halt
			 * the channel again. In either Slave or DMA mode,
			 * it's possible that the transfer has been assigned
			 * to a channel, but not started yet when an URB is
			 * dequeued. Don't want to halt a channel that hasn't
			 * started yet.
			 */
			return;
		}
	}

	if (_hc->halt_pending) {
		/*
		 * A halt has already been issued for this channel. This might
		 * happen when a transfer is aborted by a higher level in
		 * the stack.
		 */
#ifdef DEBUG
		DWC_PRINT("*** %s: Channel %d, _hc->halt_pending already set ***\n",
			  __func__, _hc->hc_num);

/* 		dwc_otg_dump_global_registers(_core_if); */
/* 		dwc_otg_dump_host_registers(_core_if); */
#endif		
		return;
	}

        hcchar.d32 = dwc_read_reg32(&hc_regs->hcchar);
	hcchar.b.chen = 1;
	hcchar.b.chdis = 1;

	if (!_core_if->dma_enable) {
		/* Check for space in the request queue to issue the halt. */
		if (_hc->ep_type == DWC_OTG_EP_TYPE_CONTROL ||
		    _hc->ep_type == DWC_OTG_EP_TYPE_BULK) {
			nptxsts.d32 = dwc_read_reg32(&global_regs->gnptxsts);
			if (nptxsts.b.nptxqspcavail == 0) {
				hcchar.b.chen = 0;
			}
		} else {
			hptxsts.d32 = dwc_read_reg32(&host_global_regs->hptxsts);
			if ((hptxsts.b.ptxqspcavail == 0) || (_core_if->queuing_high_bandwidth)) {
				hcchar.b.chen = 0;
			}
		}
	}

	dwc_write_reg32(&hc_regs->hcchar, hcchar.d32);

	_hc->halt_status = _halt_status;

	if (hcchar.b.chen) {
		_hc->halt_pending = 1;
		_hc->halt_on_queue = 0;
	} else {
		_hc->halt_on_queue = 1;
	}

	DWC_DEBUGPL(DBG_HCDV, "%s: Channel %d\n", __func__, _hc->hc_num);
	DWC_DEBUGPL(DBG_HCDV, "  hcchar: 0x%08x\n", hcchar.d32);
	DWC_DEBUGPL(DBG_HCDV, "  halt_pending: %d\n", _hc->halt_pending);
	DWC_DEBUGPL(DBG_HCDV, "  halt_on_queue: %d\n", _hc->halt_on_queue);
	DWC_DEBUGPL(DBG_HCDV, "  halt_status: %d\n", _hc->halt_status);

	return;
}

/**
 * Clears the transfer state for a host channel. This function is normally
 * called after a transfer is done and the host channel is being released.
 *
 * @param _core_if Programming view of DWC_otg controller.
 * @param _hc Identifies the host channel to clean up.
 */
void dwc_otg_hc_cleanup(dwc_otg_core_if_t *_core_if, dwc_hc_t *_hc)
{
	dwc_otg_hc_regs_t *hc_regs;

	_hc->xfer_started = 0;

	/*
	 * Clear channel interrupt enables and any unhandled channel interrupt
	 * conditions.
	 */
	hc_regs = _core_if->host_if->hc_regs[_hc->hc_num];
	dwc_write_reg32(&hc_regs->hcintmsk, 0);
	dwc_write_reg32(&hc_regs->hcint, 0xFFFFFFFF);

#ifdef DEBUG
	del_timer(&_core_if->hc_xfer_timer[_hc->hc_num]);
	{
		hcchar_data_t hcchar;
		hcchar.d32 = dwc_read_reg32(&hc_regs->hcchar);
		if (hcchar.b.chdis) {
			DWC_WARN("%s: chdis set, channel %d, hcchar 0x%08x\n",
				 __func__, _hc->hc_num, hcchar.d32);
		}
	}
#endif	
}

/**
 * Sets the channel property that indicates in which frame a periodic transfer
 * should occur. This is always set to the _next_ frame. This function has no
 * effect on non-periodic transfers.
 *
 * @param _core_if Programming view of DWC_otg controller.
 * @param _hc Identifies the host channel to set up and its properties.
 * @param _hcchar Current value of the HCCHAR register for the specified host
 * channel.
 */
static inline void hc_set_even_odd_frame(dwc_otg_core_if_t *_core_if,
					 dwc_hc_t *_hc,
					 hcchar_data_t *_hcchar)
{
	if (_hc->ep_type == DWC_OTG_EP_TYPE_INTR ||
	    _hc->ep_type == DWC_OTG_EP_TYPE_ISOC) {
		hfnum_data_t	hfnum;
		hfnum.d32 = dwc_read_reg32(&_core_if->host_if->host_global_regs->hfnum);
		/* 1 if _next_ frame is odd, 0 if it's even */
		_hcchar->b.oddfrm = (hfnum.b.frnum & 0x1) ? 0 : 1;
#ifdef DEBUG
		if (_hc->ep_type == DWC_OTG_EP_TYPE_INTR && _hc->do_split && !_hc->complete_split) {
			switch (hfnum.b.frnum & 0x7) {
			case 7:
				_core_if->hfnum_7_samples++;
				_core_if->hfnum_7_frrem_accum += hfnum.b.frrem;
				break;
			case 0:
				_core_if->hfnum_0_samples++;
				_core_if->hfnum_0_frrem_accum += hfnum.b.frrem;
				break;
			default:
				_core_if->hfnum_other_samples++;
				_core_if->hfnum_other_frrem_accum += hfnum.b.frrem;
				break;
			}
		}
#endif		
	}
}

#ifdef DEBUG
static void hc_xfer_timeout(unsigned long _ptr)
{
	hc_xfer_info_t *xfer_info = (hc_xfer_info_t *)_ptr;
	int hc_num = xfer_info->hc->hc_num;
	DWC_WARN("%s: timeout on channel %d\n", __func__, hc_num);
	DWC_WARN("  start_hcchar_val 0x%08x\n", xfer_info->core_if->start_hcchar_val[hc_num]);
}
#endif

/*
 * This function does the setup for a data transfer for a host channel and
 * starts the transfer. May be called in either Slave mode or DMA mode. In
 * Slave mode, the caller must ensure that there is sufficient space in the
 * request queue and Tx Data FIFO.
 *
 * For an OUT transfer in Slave mode, it loads a data packet into the
 * appropriate FIFO. If necessary, additional data packets will be loaded in
 * the Host ISR.
 *
 * For an IN transfer in Slave mode, a data packet is requested. The data
 * packets are unloaded from the Rx FIFO in the Host ISR. If necessary,
 * additional data packets are requested in the Host ISR.
 *
 * For a PING transfer in Slave mode, the Do Ping bit is set in the HCTSIZ
 * register along with a packet count of 1 and the channel is enabled. This
 * causes a single PING transaction to occur. Other fields in HCTSIZ are
 * simply set to 0 since no data transfer occurs in this case.
 *
 * For a PING transfer in DMA mode, the HCTSIZ register is initialized with
 * all the information required to perform the subsequent data transfer. In
 * addition, the Do Ping bit is set in the HCTSIZ register. In this case, the
 * controller performs the entire PING protocol, then starts the data
 * transfer.
 *
 * @param _core_if Programming view of DWC_otg controller.
 * @param _hc Information needed to initialize the host channel. The xfer_len
 * value may be reduced to accommodate the max widths of the XferSize and
 * PktCnt fields in the HCTSIZn register. The multi_count value may be changed
 * to reflect the final xfer_len value.
 */
void dwc_otg_hc_start_transfer(dwc_otg_core_if_t *_core_if, dwc_hc_t *_hc)
{
	hcchar_data_t hcchar;
	hctsiz_data_t hctsiz;
	uint16_t num_packets;
	uint32_t max_hc_xfer_size = _core_if->core_params->max_transfer_size;
	uint16_t max_hc_pkt_count = _core_if->core_params->max_packet_count;
	dwc_otg_hc_regs_t *hc_regs = _core_if->host_if->hc_regs[_hc->hc_num];

	hctsiz.d32 = 0;

	if (_hc->do_ping) {
		if (!_core_if->dma_enable) {
			dwc_otg_hc_do_ping(_core_if, _hc);
			_hc->xfer_started = 1;
			return;
		} else {
			hctsiz.b.dopng = 1;
		}
	}

	if (_hc->do_split) {
		num_packets = 1;

		if (_hc->complete_split && !_hc->ep_is_in) {
			/* For CSPLIT OUT Transfer, set the size to 0 so the
			 * core doesn't expect any data written to the FIFO */
			_hc->xfer_len = 0;
		} else if (_hc->ep_is_in || (_hc->xfer_len > _hc->max_packet)) {
			_hc->xfer_len = _hc->max_packet;
		} else if (!_hc->ep_is_in && (_hc->xfer_len > 188)) {
			_hc->xfer_len = 188;
		}

		hctsiz.b.xfersize = _hc->xfer_len;
	} else {
		/*
		 * Ensure that the transfer length and packet count will fit
		 * in the widths allocated for them in the HCTSIZn register.
		 */
		if (_hc->ep_type == DWC_OTG_EP_TYPE_INTR ||
		    _hc->ep_type == DWC_OTG_EP_TYPE_ISOC) {
			/*
			 * Make sure the transfer size is no larger than one
			 * (micro)frame's worth of data. (A check was done
			 * when the periodic transfer was accepted to ensure
			 * that a (micro)frame's worth of data can be
			 * programmed into a channel.)
			 */
			uint32_t max_periodic_len = _hc->multi_count * _hc->max_packet;
			if (_hc->xfer_len > max_periodic_len) {
				_hc->xfer_len = max_periodic_len;
			} else {
			}
		} else if (_hc->xfer_len > max_hc_xfer_size) {
			/* Make sure that xfer_len is a multiple of max packet size. */
			_hc->xfer_len = max_hc_xfer_size - _hc->max_packet + 1;
		}

		if (_hc->xfer_len > 0) {
			num_packets = (_hc->xfer_len + _hc->max_packet - 1) / _hc->max_packet;
			if (num_packets > max_hc_pkt_count) {
				num_packets = max_hc_pkt_count;
				_hc->xfer_len = num_packets * _hc->max_packet;
			}
		} else {
			/* Need 1 packet for transfer length of 0. */
			num_packets = 1;
		}

		if (_hc->ep_is_in) {
			/* Always program an integral # of max packets for IN transfers. */
			_hc->xfer_len = num_packets * _hc->max_packet;
		}

		if (_hc->ep_type == DWC_OTG_EP_TYPE_INTR ||
		    _hc->ep_type == DWC_OTG_EP_TYPE_ISOC) {
			/*
			 * Make sure that the multi_count field matches the
			 * actual transfer length.
			 */
			_hc->multi_count = num_packets;

		}

		if (_hc->ep_type == DWC_OTG_EP_TYPE_ISOC) {
			/* Set up the initial PID for the transfer. */
			if (_hc->speed == DWC_OTG_EP_SPEED_HIGH) {
				if (_hc->ep_is_in) {
					if (_hc->multi_count == 1) {
						_hc->data_pid_start = DWC_OTG_HC_PID_DATA0;
					} else if (_hc->multi_count == 2) {
						_hc->data_pid_start = DWC_OTG_HC_PID_DATA1;
					} else {
						_hc->data_pid_start = DWC_OTG_HC_PID_DATA2;
					}
				} else {
					if (_hc->multi_count == 1) {
						_hc->data_pid_start = DWC_OTG_HC_PID_DATA0;
					} else {
						_hc->data_pid_start = DWC_OTG_HC_PID_MDATA;
					}
				}
			} else {
				_hc->data_pid_start = DWC_OTG_HC_PID_DATA0;
			}
		}

		hctsiz.b.xfersize = _hc->xfer_len;
	}

	_hc->start_pkt_count = num_packets;
	hctsiz.b.pktcnt = num_packets;
	hctsiz.b.pid = _hc->data_pid_start;
	dwc_write_reg32(&hc_regs->hctsiz, hctsiz.d32);

	DWC_DEBUGPL(DBG_HCDV, "%s: Channel %d\n", __func__, _hc->hc_num);
	DWC_DEBUGPL(DBG_HCDV, "  Xfer Size: %d\n", hctsiz.b.xfersize);
	DWC_DEBUGPL(DBG_HCDV, "  Num Pkts: %d\n", hctsiz.b.pktcnt);
	DWC_DEBUGPL(DBG_HCDV, "  Start PID: %d\n", hctsiz.b.pid);

	if (_core_if->dma_enable) {
#ifdef DEBUG
if(((uint32_t)_hc->xfer_buff)%4)
printk("dwc_otg_hc_start_transfer _hc->xfer_buff not 4 byte alignment\n");
#endif
		dwc_write_reg32(&hc_regs->hcdma, (uint32_t)_hc->xfer_buff);
	}

	/* Start the split */
	if (_hc->do_split) {
		hcsplt_data_t hcsplt;
		hcsplt.d32 = dwc_read_reg32 (&hc_regs->hcsplt);
		hcsplt.b.spltena = 1;
		dwc_write_reg32(&hc_regs->hcsplt, hcsplt.d32);
	}

	hcchar.d32 = dwc_read_reg32(&hc_regs->hcchar);
	hcchar.b.multicnt = _hc->multi_count;
	hc_set_even_odd_frame(_core_if, _hc, &hcchar);
#ifdef DEBUG
	_core_if->start_hcchar_val[_hc->hc_num] = hcchar.d32;
	if (hcchar.b.chdis) {
		DWC_WARN("%s: chdis set, channel %d, hcchar 0x%08x\n",
			 __func__, _hc->hc_num, hcchar.d32);
	}
#endif	

	/* Set host channel enable after all other setup is complete. */
	hcchar.b.chen = 1;
	hcchar.b.chdis = 0;
	dwc_write_reg32(&hc_regs->hcchar, hcchar.d32);

	_hc->xfer_started = 1;
	_hc->requests++;

	if (!_core_if->dma_enable && !_hc->ep_is_in && _hc->xfer_len > 0) {
		/* Load OUT packet into the appropriate Tx FIFO. */
		dwc_otg_hc_write_packet(_core_if, _hc);
	}

#ifdef DEBUG
	/* Start a timer for this transfer. */
	_core_if->hc_xfer_timer[_hc->hc_num].function = hc_xfer_timeout;
	_core_if->hc_xfer_info[_hc->hc_num].core_if = _core_if;
	_core_if->hc_xfer_info[_hc->hc_num].hc = _hc;
	_core_if->hc_xfer_timer[_hc->hc_num].data = (unsigned long)(&_core_if->hc_xfer_info[_hc->hc_num]);
	_core_if->hc_xfer_timer[_hc->hc_num].expires = jiffies + (HZ*10);
	add_timer(&_core_if->hc_xfer_timer[_hc->hc_num]);
#endif
}

/**
 * This function continues a data transfer that was started by previous call
 * to <code>dwc_otg_hc_start_transfer</code>. The caller must ensure there is
 * sufficient space in the request queue and Tx Data FIFO. This function
 * should only be called in Slave mode. In DMA mode, the controller acts
 * autonomously to complete transfers programmed to a host channel.
 *
 * For an OUT transfer, a new data packet is loaded into the appropriate FIFO
 * if there is any data remaining to be queued. For an IN transfer, another
 * data packet is always requested. For the SETUP phase of a control transfer,
 * this function does nothing.
 *
 * @return 1 if a new request is queued, 0 if no more requests are required
 * for this transfer.
 */
int dwc_otg_hc_continue_transfer(dwc_otg_core_if_t *_core_if, dwc_hc_t *_hc)
{
	DWC_DEBUGPL(DBG_HCDV, "%s: Channel %d\n", __func__, _hc->hc_num);

	if (_hc->do_split) {
		/* SPLITs always queue just once per channel */
		return 0;
	} else if (_hc->data_pid_start == DWC_OTG_HC_PID_SETUP) {
		/* SETUPs are queued only once since they can't be NAKed. */
		return 0;
	} else if (_hc->ep_is_in) {
		/*
		 * Always queue another request for other IN transfers. If
		 * back-to-back INs are issued and NAKs are received for both,
		 * the driver may still be processing the first NAK when the
		 * second NAK is received. When the interrupt handler clears
		 * the NAK interrupt for the first NAK, the second NAK will
		 * not be seen. So we can't depend on the NAK interrupt
		 * handler to requeue a NAKed request. Instead, IN requests
		 * are issued each time this function is called. When the
		 * transfer completes, the extra requests for the channel will
		 * be flushed.
		 */
		hcchar_data_t hcchar;
		dwc_otg_hc_regs_t *hc_regs = _core_if->host_if->hc_regs[_hc->hc_num];

		hcchar.d32 = dwc_read_reg32(&hc_regs->hcchar);
		hc_set_even_odd_frame(_core_if, _hc, &hcchar);
		hcchar.b.chen = 1;
		hcchar.b.chdis = 0;
		DWC_DEBUGPL(DBG_HCDV, "  IN xfer: hcchar = 0x%08x\n", hcchar.d32);
		dwc_write_reg32(&hc_regs->hcchar, hcchar.d32);
		_hc->requests++;
		return 1;
	} else {
		/* OUT transfers. */
		if (_hc->xfer_count < _hc->xfer_len) {
			if (_hc->ep_type == DWC_OTG_EP_TYPE_INTR ||
			    _hc->ep_type == DWC_OTG_EP_TYPE_ISOC) {
				hcchar_data_t hcchar;
				dwc_otg_hc_regs_t *hc_regs;
				hc_regs = _core_if->host_if->hc_regs[_hc->hc_num];
				hcchar.d32 = dwc_read_reg32(&hc_regs->hcchar);
				hc_set_even_odd_frame(_core_if, _hc, &hcchar);
			}

			/* Load OUT packet into the appropriate Tx FIFO. */
			dwc_otg_hc_write_packet(_core_if, _hc);
			_hc->requests++;
			return 1;
		} else {
			return 0;
		}
	}
}

/**
 * Starts a PING transfer. This function should only be called in Slave mode.
 * The Do Ping bit is set in the HCTSIZ register, then the channel is enabled.
 */
void dwc_otg_hc_do_ping(dwc_otg_core_if_t *_core_if, dwc_hc_t *_hc)
{
	hcchar_data_t hcchar;
	hctsiz_data_t hctsiz;
	dwc_otg_hc_regs_t *hc_regs = _core_if->host_if->hc_regs[_hc->hc_num];

	DWC_DEBUGPL(DBG_HCDV, "%s: Channel %d\n", __func__, _hc->hc_num);

	hctsiz.d32 = 0;
	hctsiz.b.dopng = 1;
	hctsiz.b.pktcnt = 1;
	dwc_write_reg32(&hc_regs->hctsiz, hctsiz.d32);

	hcchar.d32 = dwc_read_reg32(&hc_regs->hcchar);
	hcchar.b.chen = 1;
	hcchar.b.chdis = 0;
	dwc_write_reg32(&hc_regs->hcchar, hcchar.d32);
}

/*
 * This function writes a packet into the Tx FIFO associated with the Host
 * Channel. For a channel associated with a non-periodic EP, the non-periodic
 * Tx FIFO is written. For a channel associated with a periodic EP, the
 * periodic Tx FIFO is written. This function should only be called in Slave
 * mode.
 *
 * Upon return the xfer_buff and xfer_count fields in _hc are incremented by
 * then number of bytes written to the Tx FIFO.
 */
void dwc_otg_hc_write_packet(dwc_otg_core_if_t *_core_if, dwc_hc_t *_hc)
{
	uint32_t i;
	uint32_t remaining_count;
	uint32_t byte_count;
	uint32_t dword_count;

	uint32_t *data_buff = (uint32_t *)(_hc->xfer_buff);
	uint32_t *data_fifo = _core_if->data_fifo[_hc->hc_num];

	remaining_count = _hc->xfer_len - _hc->xfer_count;
	if (remaining_count > _hc->max_packet) {
		byte_count = _hc->max_packet;
	} else {
		byte_count = remaining_count;
	}

	dword_count = (byte_count + 3) / 4;

	if ((((unsigned long)data_buff) & 0x3) == 0) {
		/* xfer_buff is DWORD aligned. */
		for (i = 0; i < dword_count; i++, data_buff++) {
			dwc_write_reg32(data_fifo, *data_buff);
		}
	} else {
		/* xfer_buff is not DWORD aligned. */
		for (i = 0; i < dword_count; i++, data_buff++) {
			dwc_write_reg32(data_fifo, get_unaligned(data_buff));
		}
	}

	_hc->xfer_count += byte_count;
	_hc->xfer_buff += byte_count;
}

/**
 * Gets the current USB frame number. This is the frame number from the last 
 * SOF packet.  
 */
uint32_t dwc_otg_get_frame_number(dwc_otg_core_if_t *_core_if)
{
	dsts_data_t dsts;
	dsts.d32 = dwc_read_reg32(&_core_if->dev_if->dev_global_regs->dsts);

	/* read current frame/microfreme number from DSTS register */
	return dsts.b.soffn;
}

/**
 * This function reads a setup packet from the Rx FIFO into the destination 
 * buffer.  This function is called from the Rx Status Queue Level (RxStsQLvl)
 * Interrupt routine when a SETUP packet has been received in Slave mode.
 *
 * @param _core_if Programming view of DWC_otg controller.
 * @param _dest Destination buffer for packet data.
 */
void dwc_otg_read_setup_packet(dwc_otg_core_if_t *_core_if, uint32_t *_dest)
{
	/* Get the 8 bytes of a setup transaction data */

	/* Pop 2 DWORDS off the receive data FIFO into memory */
	_dest[0] = dwc_read_reg32(_core_if->data_fifo[0]);
	_dest[1] = dwc_read_reg32(_core_if->data_fifo[0]);
    //_dest[0] = dwc_read_datafifo32(_core_if->data_fifo[0]);
	//_dest[1] = dwc_read_datafifo32(_core_if->data_fifo[0]);
}


/**
 * This function enables EP0 OUT to receive SETUP packets and configures EP0 
 * IN for transmitting packets.  It is normally called when the
 * "Enumeration Done" interrupt occurs.
 *
 * @param _core_if Programming view of DWC_otg controller.
 * @param _ep The EP0 data.
 */
void dwc_otg_ep0_activate(dwc_otg_core_if_t *_core_if, dwc_ep_t *_ep)
{
        dwc_otg_dev_if_t *dev_if = _core_if->dev_if;
	dsts_data_t dsts;
	depctl_data_t diepctl;
	depctl_data_t doepctl;
	dctl_data_t dctl ={.d32=0};        

	/* Read the Device Status and Endpoint 0 Control registers */
	dsts.d32 = dwc_read_reg32(&dev_if->dev_global_regs->dsts);
	diepctl.d32 = dwc_read_reg32(&dev_if->in_ep_regs[0]->diepctl);
	doepctl.d32 = dwc_read_reg32(&dev_if->out_ep_regs[0]->doepctl);

	/* Set the MPS of the IN EP based on the enumeration speed */
	switch (dsts.b.enumspd) {
	case DWC_DSTS_ENUMSPD_HS_PHY_30MHZ_OR_60MHZ:
	case DWC_DSTS_ENUMSPD_FS_PHY_30MHZ_OR_60MHZ:
	case DWC_DSTS_ENUMSPD_FS_PHY_48MHZ:
		diepctl.b.mps = DWC_DEP0CTL_MPS_64;
		break;
	case DWC_DSTS_ENUMSPD_LS_PHY_6MHZ:
		diepctl.b.mps = DWC_DEP0CTL_MPS_8;
		break;
	}

	dwc_write_reg32(&dev_if->in_ep_regs[0]->diepctl, diepctl.d32);

	/* Enable OUT EP for receive */
	doepctl.b.epena = 1;
	dwc_write_reg32(&dev_if->out_ep_regs[0]->doepctl, doepctl.d32);

#ifdef VERBOSE
        DWC_DEBUGPL(DBG_PCDV,"doepctl0=%0x\n", 
                    dwc_read_reg32(&dev_if->out_ep_regs[0]->doepctl));
        DWC_DEBUGPL(DBG_PCDV,"diepctl0=%0x\n", 
                    dwc_read_reg32(&dev_if->in_ep_regs[0]->diepctl));        
#endif
        dctl.b.cgnpinnak = 1;
        dwc_modify_reg32(&dev_if->dev_global_regs->dctl, dctl.d32, dctl.d32);
        DWC_DEBUGPL(DBG_PCDV,"dctl=%0x\n", 
                    dwc_read_reg32(&dev_if->dev_global_regs->dctl));
}

/**
 * This function activates an EP.  The Device EP control register for
 * the EP is configured as defined in the ep structure.  Note: This
 * function is not used for EP0.
 *
 * @param _core_if Programming view of DWC_otg controller.
 * @param _ep The EP to activate.
 */
void dwc_otg_ep_activate(dwc_otg_core_if_t *_core_if, dwc_ep_t *_ep)
{
        dwc_otg_dev_if_t *dev_if = _core_if->dev_if;
	depctl_data_t depctl;
	volatile uint32_t *addr;
        daint_data_t daintmsk = {.d32=0};

        DWC_DEBUGPL(DBG_PCDV, "%s() EP%d-%s\n", __func__, _ep->num, 
                    (_ep->is_in?"IN":"OUT"));
        
	/* Read DEPCTLn register */
	if (_ep->is_in == 1) {
		addr = &dev_if->in_ep_regs[_ep->num]->diepctl;
                daintmsk.ep.in = 1<<_ep->num;
        } else {
		addr = &dev_if->out_ep_regs[_ep->num]->doepctl;
                daintmsk.ep.out = 1<<_ep->num;
	}
        
        /* If the EP is already active don't change the EP Control
         * register. */
        depctl.d32 = dwc_read_reg32(addr);
	if (!depctl.b.usbactep) {
                depctl.b.mps = _ep->maxpacket;
                depctl.b.eptype = _ep->type;
                depctl.b.txfnum = _ep->tx_fifo_num;
                
                if (_ep->type == DWC_OTG_EP_TYPE_ISOC) {
			depctl.b.setd0pid = 1;	// ???
                } else {
                        depctl.b.setd0pid = 1;
                }
                depctl.b.usbactep = 1;

                dwc_write_reg32(addr, depctl.d32);
                DWC_DEBUGPL(DBG_PCDV,"DEPCTL=%08x\n", dwc_read_reg32(addr));
        }
        

        /* Enable the Interrupt for this EP */
        dwc_modify_reg32(&dev_if->dev_global_regs->daintmsk,
                         0, daintmsk.d32);
        DWC_DEBUGPL(DBG_PCDV,"DAINTMSK=%0x\n", 
                    dwc_read_reg32(&dev_if->dev_global_regs->daintmsk));
	_ep->stall_clear_flag = 0;
	return;
}

/**
 * This function deactivates an EP.  This is done by clearing the USB Active 
 * EP bit in the Device EP control register.  Note: This function is not used 
 * for EP0. EP0 cannot be deactivated.
 *
 * @param _core_if Programming view of DWC_otg controller.
 * @param _ep The EP to deactivate.
 */
void dwc_otg_ep_deactivate(dwc_otg_core_if_t *_core_if, dwc_ep_t *_ep)
{
	depctl_data_t depctl ={.d32 = 0};
	volatile uint32_t *addr;
        daint_data_t daintmsk = {.d32=0};
        
	/* Read DEPCTLn register */
	if (_ep->is_in == 1) {
		addr = &_core_if->dev_if->in_ep_regs[_ep->num]->diepctl;
                daintmsk.ep.in = 1<<_ep->num;
	} else {
		addr = &_core_if->dev_if->out_ep_regs[_ep->num]->doepctl;
                daintmsk.ep.out = 1<<_ep->num;
	}

	depctl.b.usbactep = 0;
	dwc_write_reg32(addr, depctl.d32);

        /* Disable the Interrupt for this EP */
        dwc_modify_reg32(&_core_if->dev_if->dev_global_regs->daintmsk,
                         daintmsk.d32, 0);

	return;
}

/**
 * This function does the setup for a data transfer for an EP and
 * starts the transfer.  For an IN transfer, the packets will be
 * loaded into the appropriate Tx FIFO in the ISR. For OUT transfers,
 * the packets are unloaded from the Rx FIFO in the ISR.  the ISR.
 *
 * @param _core_if Programming view of DWC_otg controller.
 * @param _ep The EP to start the transfer on.
 */
void dwc_otg_ep_start_transfer(dwc_otg_core_if_t *_core_if, dwc_ep_t *_ep)
{
        /** @todo Refactor this funciton to check the transfer size
         * count value does not execed the number bits in the Transfer
         * count register. */
	depctl_data_t depctl;
	deptsiz_data_t deptsiz;
        gintmsk_data_t intr_mask = { .d32 = 0};

#ifdef CHECK_PACKET_COUNTER_WIDTH
        const uint32_t MAX_XFER_SIZE = 
                _core_if->core_params->max_transfer_size;
        const uint32_t MAX_PKT_COUNT = 
                _core_if->core_params->max_packet_count;
        uint32_t num_packets;
        uint32_t transfer_len;
        dwc_otg_dev_out_ep_regs_t *out_regs = 
                _core_if->dev_if->out_ep_regs[_ep->num];
        dwc_otg_dev_in_ep_regs_t *in_regs = 
                _core_if->dev_if->in_ep_regs[_ep->num];
        gnptxsts_data_t txstatus;

        int lvl = SET_DEBUG_LEVEL(DBG_PCD);

        
        DWC_DEBUGPL(DBG_PCD, "ep%d-%s xfer_len=%d xfer_cnt=%d "
                    "xfer_buff=%p start_xfer_buff=%p\n",
                    _ep->num, (_ep->is_in?"IN":"OUT"), _ep->xfer_len, 
                    _ep->xfer_count, _ep->xfer_buff, _ep->start_xfer_buff);

        transfer_len = _ep->xfer_len - _ep->xfer_count;
        if (transfer_len > MAX_XFER_SIZE) {
                transfer_len = MAX_XFER_SIZE;
        }
        if (transfer_len == 0) {
                num_packets = 1;
                /* OUT EP to recieve Zero-length packet set transfer
                 * size to maxpacket size. */
                if (!_ep->is_in) {
                        transfer_len = _ep->maxpacket;                
                }
        } else {
                num_packets = 
                        (transfer_len + _ep->maxpacket - 1) / _ep->maxpacket;
                if (num_packets > MAX_PKT_COUNT) {
                        num_packets = MAX_PKT_COUNT;
                }
        }
        DWC_DEBUGPL(DBG_PCD, "transfer_len=%d #pckt=%d\n", transfer_len, 
                    num_packets);

        deptsiz.b.xfersize = transfer_len;
        deptsiz.b.pktcnt = num_packets;

	/* IN endpoint */
	if (_ep->is_in == 1) {
		depctl.d32 = dwc_read_reg32(&in_regs->diepctl);
        } else {/* OUT endpoint */
                depctl.d32 = dwc_read_reg32(&out_regs->doepctl);
        }
        
        /* EP enable, IN data in FIFO */
        depctl.b.cnak = 1;
        depctl.b.epena = 1;
	/* IN endpoint */
	if (_ep->is_in == 1) {
                txstatus.d32 = 
                        dwc_read_reg32(&_core_if->core_global_regs->gnptxsts);
                if (txstatus.b.nptxqspcavail == 0) {
                        DWC_DEBUGPL(DBG_ANY, "TX Queue Full (0x%0x)\n", 
                                    txstatus.d32);
                        return;
                }
                dwc_write_reg32(&in_regs->dieptsiz, deptsiz.d32);
		dwc_write_reg32(&in_regs->diepctl, depctl.d32);
                /** 
                 * Enable the Non-Periodic Tx FIFO empty interrupt, the
                 * data will be written into the fifo by the ISR.
                 */ 
                if (_core_if->dma_enable) {
			dwc_write_reg32(&in_regs->diepdma, (uint32_t) _ep->xfer_buff);
		} else {
			if (_core_if->en_multiple_tx_fifo == 0) {
                        intr_mask.b.nptxfempty = 1;
                        dwc_modify_reg32( &_core_if->core_global_regs->gintsts,
                                          intr_mask.d32, 0);
                        dwc_modify_reg32( &_core_if->core_global_regs->gintmsk,
                                          intr_mask.d32, intr_mask.d32);
			} else {
			    /* Enable the Tx FIFO Empty Interrupt for this EP */
			    if (_ep->xfer_len > 0 &&
					 _ep->type != DWC_OTG_EP_TYPE_ISOC) {
					uint32_t fifoemptymsk = 0;
					fifoemptymsk = (0x1 << _ep->num);
					dwc_modify_reg32(&_core_if->dev_if->dev_global_regs->
							dtknqr4_fifoemptymsk,0, fifoemptymsk);
                }
			}
		}
	} else {	    /* OUT endpoint */
		dwc_write_reg32(&out_regs->doeptsiz, deptsiz.d32);
		dwc_write_reg32(&out_regs->doepctl, depctl.d32);
                if (_core_if->dma_enable) {
			dwc_write_reg32(&out_regs->doepdma,(uint32_t) _ep->xfer_buff);
		}
        }
        DWC_DEBUGPL(DBG_PCD, "DOEPCTL=%08x DOEPTSIZ=%08x\n", 
                    dwc_read_reg32(&out_regs->doepctl),
                    dwc_read_reg32(&out_regs->doeptsiz));
        DWC_DEBUGPL(DBG_PCD, "DAINTMSK=%08x GINTMSK=%08x\n", 
                    dwc_read_reg32(&_core_if->dev_if->dev_global_regs->daintmsk),
                    dwc_read_reg32(&_core_if->core_global_regs->gintmsk));        

        SET_DEBUG_LEVEL(lvl);
#endif
        DWC_DEBUGPL((DBG_PCDV | DBG_CILV), "%s()\n", __func__);
        
        DWC_DEBUGPL(DBG_PCD, "ep%d-%s xfer_len=%d xfer_cnt=%d "
                    "xfer_buff=%p start_xfer_buff=%p\n",
                    _ep->num, (_ep->is_in?"IN":"OUT"), _ep->xfer_len, 
                    _ep->xfer_count, _ep->xfer_buff, _ep->start_xfer_buff);

	/* IN endpoint */
	if (_ep->is_in == 1) {
		dwc_otg_dev_in_ep_regs_t * in_regs = _core_if->dev_if->in_ep_regs[_ep->num];
		gnptxsts_data_t gtxstatus;
		gtxstatus.d32 = dwc_read_reg32(&_core_if->core_global_regs->gnptxsts);
		if (_core_if->en_multiple_tx_fifo == 0 &&
			gtxstatus.b.nptxqspcavail == 0) {
#ifdef DEBUG
                        DWC_PRINT("TX Queue Full (0x%0x)\n", gtxstatus.d32);
#endif
                        //return;
                        MDELAY(100); //james
                }
                
		depctl.d32 = dwc_read_reg32(&(in_regs->diepctl));
		deptsiz.d32 = dwc_read_reg32(&(in_regs->dieptsiz));

                /* Zero Length Packet? */
                if (_ep->xfer_len == 0) {
                        deptsiz.b.xfersize = 0;
                        deptsiz.b.pktcnt = 1;
                } else {
                        
                        /* Program the transfer size and packet count
                         *  as follows: xfersize = N * maxpacket +
                         *  short_packet pktcnt = N + (short_packet
                         *  exist ? 1 : 0)  
                         */
                        deptsiz.b.xfersize = _ep->xfer_len;
			deptsiz.b.pktcnt = (_ep->xfer_len - 1 + _ep->maxpacket) / _ep->maxpacket;
		}

                dwc_write_reg32(&in_regs->dieptsiz, deptsiz.d32);

		/* Write the DMA register */
		if (_core_if->dma_enable) {
#if 1 // winder
			dma_cache_wback_inv((unsigned long) _ep->xfer_buff, _ep->xfer_len); // winder
			dwc_write_reg32 (&(in_regs->diepdma), 
					 CPHYSADDR((uint32_t)_ep->xfer_buff)); // winder
#else
                        dwc_write_reg32 (&(in_regs->diepdma),
				         (uint32_t)_ep->dma_addr);
#endif
		} else {
			if (_ep->type != DWC_OTG_EP_TYPE_ISOC) {
			/** 
			 * Enable the Non-Periodic Tx FIFO empty interrupt,
				 * or the Tx FIFO epmty interrupt in dedicated Tx FIFO mode,
			 * the data will be written into the fifo by the ISR.
			 */ 
			    if (_core_if->en_multiple_tx_fifo == 0) {
                        intr_mask.b.nptxfempty = 1;
                        dwc_modify_reg32( &_core_if->core_global_regs->gintsts,
                                          intr_mask.d32, 0);
                        dwc_modify_reg32( &_core_if->core_global_regs->gintmsk,
                                          intr_mask.d32, intr_mask.d32);
				} else {
				    /* Enable the Tx FIFO Empty Interrupt for this EP */
				    if (_ep->xfer_len > 0) {
						uint32_t fifoemptymsk = 0;
						fifoemptymsk = 1 << _ep->num;
						dwc_modify_reg32(&_core_if->dev_if->dev_global_regs->
								  dtknqr4_fifoemptymsk,0,fifoemptymsk);
					}
				}
			}
                }
                
		/* EP enable, IN data in FIFO */
		depctl.b.cnak = 1;
		depctl.b.epena = 1;
		dwc_write_reg32(&in_regs->diepctl, depctl.d32);

		if (_core_if->dma_enable) {
		depctl.d32 = dwc_read_reg32 (&_core_if->dev_if->in_ep_regs[0]->diepctl);
		depctl.b.nextep = _ep->num;
		dwc_write_reg32 (&_core_if->dev_if->in_ep_regs[0]->diepctl, depctl.d32);

		}
	} else {
                /* OUT endpoint */
	    dwc_otg_dev_out_ep_regs_t * out_regs = _core_if->dev_if->out_ep_regs[_ep->num];

		depctl.d32 = dwc_read_reg32(&(out_regs->doepctl));
		deptsiz.d32 = dwc_read_reg32(&(out_regs->doeptsiz));

		/* Program the transfer size and packet count as follows:
                 * 
		 *  pktcnt = N                                         
		 *  xfersize = N * maxpacket
                 */
                if (_ep->xfer_len == 0) {
                        /* Zero Length Packet */
                        deptsiz.b.xfersize = _ep->maxpacket;
                        deptsiz.b.pktcnt = 1;
                } else {
			deptsiz.b.pktcnt = (_ep->xfer_len + (_ep->maxpacket - 1)) / _ep->maxpacket;
                        deptsiz.b.xfersize = deptsiz.b.pktcnt * _ep->maxpacket;
                }
		dwc_write_reg32(&out_regs->doeptsiz, deptsiz.d32);

                DWC_DEBUGPL(DBG_PCDV, "ep%d xfersize=%d pktcnt=%d\n",
			      _ep->num, deptsiz.b.xfersize, deptsiz.b.pktcnt);

		if (_core_if->dma_enable) {
#if 1 // winder
			dwc_write_reg32 (&(out_regs->doepdma), 
					 CPHYSADDR((uint32_t)_ep->xfer_buff)); // winder
#else
			dwc_write_reg32 (&(out_regs->doepdma), 
					 (uint32_t)_ep->dma_addr);
#endif
		}

		if (_ep->type == DWC_OTG_EP_TYPE_ISOC) {
                        /** @todo NGS: dpid is read-only. Use setd0pid
                         * or setd1pid. */
			if (_ep->even_odd_frame) {
				depctl.b.setd1pid = 1;
			} else {
				depctl.b.setd0pid = 1;
			}
		}

		/* EP enable */
		depctl.b.cnak = 1;
		depctl.b.epena = 1;

		dwc_write_reg32(&out_regs->doepctl, depctl.d32);

                DWC_DEBUGPL(DBG_PCD, "DOEPCTL=%08x DOEPTSIZ=%08x\n", 
                            dwc_read_reg32(&out_regs->doepctl),
                            dwc_read_reg32(&out_regs->doeptsiz));
                DWC_DEBUGPL(DBG_PCD, "DAINTMSK=%08x GINTMSK=%08x\n", 
                            dwc_read_reg32(&_core_if->dev_if->dev_global_regs->daintmsk),
                            dwc_read_reg32(&_core_if->core_global_regs->gintmsk));        
	}
}


/**
 * This function does the setup for a data transfer for EP0 and starts
 * the transfer.  For an IN transfer, the packets will be loaded into
 * the appropriate Tx FIFO in the ISR. For OUT transfers, the packets are
 * unloaded from the Rx FIFO in the ISR.
 *
 * @param _core_if Programming view of DWC_otg controller.
 * @param _ep The EP0 data.
 */
void dwc_otg_ep0_start_transfer(dwc_otg_core_if_t *_core_if, dwc_ep_t *_ep)
{
	volatile depctl_data_t depctl;
	volatile deptsiz0_data_t deptsiz;
        gintmsk_data_t intr_mask = { .d32 = 0};

        DWC_DEBUGPL(DBG_PCD, "ep%d-%s xfer_len=%d xfer_cnt=%d "
                    "xfer_buff=%p start_xfer_buff=%p total_len=%d\n",
                    _ep->num, (_ep->is_in?"IN":"OUT"), _ep->xfer_len, 
                    _ep->xfer_count, _ep->xfer_buff, _ep->start_xfer_buff,
                    _ep->total_len);
        _ep->total_len = _ep->xfer_len;

	/* IN endpoint */
	if (_ep->is_in == 1) {
		dwc_otg_dev_in_ep_regs_t * in_regs = _core_if->dev_if->in_ep_regs[0];
		gnptxsts_data_t gtxstatus;
		gtxstatus.d32 = dwc_read_reg32(&_core_if->core_global_regs->gnptxsts);
		if (_core_if->en_multiple_tx_fifo == 0 &&
			gtxstatus.b.nptxqspcavail == 0) {
#ifdef DEBUG
                        deptsiz.d32 = dwc_read_reg32(&in_regs->dieptsiz);
                        DWC_DEBUGPL(DBG_PCD,"DIEPCTL0=%0x\n", 
                                    dwc_read_reg32(&in_regs->diepctl));
                        DWC_DEBUGPL(DBG_PCD, "DIEPTSIZ0=%0x (sz=%d, pcnt=%d)\n", 
				     deptsiz.d32, deptsiz.b.xfersize,deptsiz.b.pktcnt);
			DWC_PRINT("TX Queue or FIFO Full (0x%0x)\n", gtxstatus.d32);
#endif	/*  */
                        			printk("TX Queue or FIFO Full!!!!\n"); // test-only
                        //return;
                        MDELAY(100); //james
                }

                depctl.d32 = dwc_read_reg32(&in_regs->diepctl);
		deptsiz.d32 = dwc_read_reg32(&in_regs->dieptsiz);

                /* Zero Length Packet? */
                if (_ep->xfer_len == 0) {
                        deptsiz.b.xfersize = 0;
                        deptsiz.b.pktcnt = 1;
                } else {
                        /* Program the transfer size and packet count
                         *  as follows: xfersize = N * maxpacket +
                         *  short_packet pktcnt = N + (short_packet
                         *  exist ? 1 : 0)  
                         */
			if (_ep->xfer_len > _ep->maxpacket) {
				_ep->xfer_len = _ep->maxpacket;
				deptsiz.b.xfersize = _ep->maxpacket;
			}
			else {
				deptsiz.b.xfersize = _ep->xfer_len;
			}
                        deptsiz.b.pktcnt = 1;

		}
                dwc_write_reg32(&in_regs->dieptsiz, deptsiz.d32);
                DWC_DEBUGPL(DBG_PCDV, "IN len=%d  xfersize=%d pktcnt=%d [%08x]\n",
			     _ep->xfer_len, deptsiz.b.xfersize,deptsiz.b.pktcnt, deptsiz.d32);

		/* Write the DMA register */
		if (_core_if->dma_enable) {
			dwc_write_reg32(&(in_regs->diepdma), (uint32_t) _ep->dma_addr);
		}

		/* EP enable, IN data in FIFO */
		depctl.b.cnak = 1;
		depctl.b.epena = 1;
		dwc_write_reg32(&in_regs->diepctl, depctl.d32);

                /** 
                 * Enable the Non-Periodic Tx FIFO empty interrupt, the
                 * data will be written into the fifo by the ISR.
                 */ 
                if (!_core_if->dma_enable) {
			if (_core_if->en_multiple_tx_fifo == 0) {
                        intr_mask.b.nptxfempty = 1;
				dwc_modify_reg32(&_core_if->core_global_regs->gintsts, intr_mask.d32, 0);
				dwc_modify_reg32(&_core_if->core_global_regs->gintmsk, intr_mask.d32,
						  intr_mask.d32);
			} else {
			    /* Enable the Tx FIFO Empty Interrupt for this EP */
			    if (_ep->xfer_len > 0) {
					uint32_t fifoemptymsk = 0;
					fifoemptymsk |= 1 << _ep->num;
					dwc_modify_reg32(&_core_if->dev_if->dev_global_regs->dtknqr4_fifoemptymsk,
						 0, fifoemptymsk);
                }
                
			}
		}
	} else {
	    /* OUT endpoint */
	    dwc_otg_dev_out_ep_regs_t * out_regs = _core_if->dev_if->out_ep_regs[_ep->num];

		depctl.d32 = dwc_read_reg32(&out_regs->doepctl);
		deptsiz.d32 = dwc_read_reg32(&out_regs->doeptsiz);

		/* Program the transfer size and packet count as follows:
		 *  xfersize = N * (maxpacket + 4 - (maxpacket % 4))
		 *  pktcnt = N                                          */
                if (_ep->xfer_len == 0) {
                        /* Zero Length Packet */
                        deptsiz.b.xfersize = _ep->maxpacket;
                        deptsiz.b.pktcnt = 1;
                } else {
			deptsiz.b.pktcnt = (_ep->xfer_len + (_ep->maxpacket - 1)) / _ep->maxpacket;
                        deptsiz.b.xfersize = deptsiz.b.pktcnt * _ep->maxpacket;
                }
                
		dwc_write_reg32(&out_regs->doeptsiz, deptsiz.d32);
                DWC_DEBUGPL(DBG_PCDV, "len=%d  xfersize=%d pktcnt=%d\n",
			     _ep->xfer_len, deptsiz.b.xfersize,deptsiz.b.pktcnt);

		if (_core_if->dma_enable) {
			dwc_write_reg32(&(out_regs->doepdma), (uint32_t) _ep->dma_addr);
		}

		/* EP enable */
		depctl.b.cnak = 1;
		depctl.b.epena = 1;
		dwc_write_reg32 (&(out_regs->doepctl), depctl.d32);
	}
}

/**
 * This function continues control IN transfers started by
 * dwc_otg_ep0_start_transfer, when the transfer does not fit in a
 * single packet.  NOTE: The DIEPCTL0/DOEPCTL0 registers only have one
 * bit for the packet count.
 *
 * @param _core_if Programming view of DWC_otg controller.
 * @param _ep The EP0 data.
 */
void dwc_otg_ep0_continue_transfer(dwc_otg_core_if_t *_core_if, dwc_ep_t *_ep)
{
	depctl_data_t depctl;
	deptsiz0_data_t deptsiz;
        gintmsk_data_t intr_mask = { .d32 = 0};

	if (_ep->is_in == 1) {
		dwc_otg_dev_in_ep_regs_t *in_regs = 
			_core_if->dev_if->in_ep_regs[0];
                gnptxsts_data_t tx_status = {.d32 = 0};

                tx_status.d32 = dwc_read_reg32( &_core_if->core_global_regs->gnptxsts );
                /** @todo Should there be check for room in the Tx
                 * Status Queue.  If not remove the code above this comment. */

                depctl.d32 = dwc_read_reg32(&in_regs->diepctl);
		deptsiz.d32 = dwc_read_reg32(&in_regs->dieptsiz);

                /* Program the transfer size and packet count
                 *  as follows: xfersize = N * maxpacket +
                 *  short_packet pktcnt = N + (short_packet
                 *  exist ? 1 : 0)  
                 */
                deptsiz.b.xfersize = (_ep->total_len - _ep->xfer_count) > _ep->maxpacket ? _ep->maxpacket : 
                        (_ep->total_len - _ep->xfer_count);
                deptsiz.b.pktcnt = 1;
		_ep->xfer_len += deptsiz.b.xfersize;

                dwc_write_reg32(&in_regs->dieptsiz, deptsiz.d32);
                DWC_DEBUGPL(DBG_PCDV, "IN len=%d  xfersize=%d pktcnt=%d [%08x]\n",
                            _ep->xfer_len, 
                            deptsiz.b.xfersize, deptsiz.b.pktcnt, deptsiz.d32);

		/* Write the DMA register */
		if (_core_if->hwcfg2.b.architecture == DWC_INT_DMA_ARCH) {
			dwc_write_reg32 (&(in_regs->diepdma), 
					 CPHYSADDR((uint32_t)_ep->dma_addr)); // winder
		}

		/* EP enable, IN data in FIFO */
		depctl.b.cnak = 1;
		depctl.b.epena = 1;
		dwc_write_reg32(&in_regs->diepctl, depctl.d32);

                /** 
                 * Enable the Non-Periodic Tx FIFO empty interrupt, the
                 * data will be written into the fifo by the ISR.
                 */ 
                if (!_core_if->dma_enable) {
                        /* First clear it from GINTSTS */
                        intr_mask.b.nptxfempty = 1;
                        dwc_write_reg32( &_core_if->core_global_regs->gintsts,
                                         intr_mask.d32 );

                        dwc_modify_reg32( &_core_if->core_global_regs->gintmsk,
                                          intr_mask.d32, intr_mask.d32);
                }
                
	} 

}

#ifdef DEBUG
void dump_msg(const u8 *buf, unsigned int length)
{
	unsigned int	start, num, i;
	char		line[52], *p;

	if (length >= 512)
		return;
	start = 0;
	while (length > 0) {
		num = min(length, 16u);
		p = line;
		for (i = 0; i < num; ++i) {
			if (i == 8)
				*p++ = ' ';
			sprintf(p, " %02x", buf[i]);
			p += 3;
		}
		*p = 0;
		DWC_PRINT( "%6x: %s\n", start, line);
		buf += num;
		start += num;
		length -= num;
	}
}
#else
static inline void dump_msg(const u8 *buf, unsigned int length)
{
}
#endif

/**
 * This function writes a packet into the Tx FIFO associated with the
 * EP.  For non-periodic EPs the non-periodic Tx FIFO is written.  For
 * periodic EPs the periodic Tx FIFO associated with the EP is written
 * with all packets for the next micro-frame.
 *
 * @param _core_if Programming view of DWC_otg controller.
 * @param _ep The EP to write packet for.
 * @param _dma Indicates if DMA is being used.
 */
void dwc_otg_ep_write_packet(dwc_otg_core_if_t *_core_if, dwc_ep_t *_ep, int _dma)
{
	/**
	 * The buffer is padded to DWORD on a per packet basis in
	 * slave/dma mode if the MPS is not DWORD aligned.  The last
	 * packet, if short, is also padded to a multiple of DWORD.
	 *
	 * ep->xfer_buff always starts DWORD aligned in memory and is a 
	 * multiple of DWORD in length
	 *
	 * ep->xfer_len can be any number of bytes
	 *
	 * ep->xfer_count is a multiple of ep->maxpacket until the last 
	 *  packet
	 *
	 * FIFO access is DWORD */

	uint32_t i;
	uint32_t byte_count;
	uint32_t dword_count;
	uint32_t *fifo;
        uint32_t *data_buff = (uint32_t *)_ep->xfer_buff;
        
        //DWC_DEBUGPL((DBG_PCDV | DBG_CILV), "%s(%p,%p)\n", __func__, _core_if, _ep);
        if (_ep->xfer_count >= _ep->xfer_len) {
                DWC_WARN("%s() No data for EP%d!!!\n", __func__, _ep->num);
                return;                
        }

	/* Find the byte length of the packet either short packet or MPS */
	if ((_ep->xfer_len - _ep->xfer_count) < _ep->maxpacket) {
		byte_count = _ep->xfer_len - _ep->xfer_count;
	}
	else {
		byte_count = _ep->maxpacket;
	}

	/* Find the DWORD length, padded by extra bytes as neccessary if MPS
	 * is not a multiple of DWORD */
	dword_count =  (byte_count + 3) / 4;

#ifdef VERBOSE
        dump_msg(_ep->xfer_buff, byte_count);        
#endif
        if (_ep->type == DWC_OTG_EP_TYPE_ISOC) {
                /**@todo NGS Where are the Periodic Tx FIFO addresses
                 * intialized?  What should this be? */
                fifo = _core_if->data_fifo[_ep->tx_fifo_num];
        } else {
                fifo = _core_if->data_fifo[_ep->num];
        }
        
        DWC_DEBUGPL((DBG_PCDV|DBG_CILV), "fifo=%p buff=%p *p=%08x bc=%d\n",
                    fifo, data_buff, *data_buff, byte_count);
        

	if (!_dma) {
		for (i=0; i<dword_count; i++, data_buff++) {
			dwc_write_reg32( fifo, *data_buff );
		}
	}

	_ep->xfer_count += byte_count;
        _ep->xfer_buff += byte_count;
#if 1 // winder, why do we need this??
	_ep->dma_addr += byte_count;
#endif
}

/** 
 * Set the EP STALL.
 *
 * @param _core_if Programming view of DWC_otg controller.
 * @param _ep The EP to set the stall on.
 */
void dwc_otg_ep_set_stall(dwc_otg_core_if_t *_core_if, dwc_ep_t *_ep)
{
	depctl_data_t depctl;
	volatile uint32_t *depctl_addr;

        DWC_DEBUGPL(DBG_PCD, "%s ep%d-%s\n", __func__, _ep->num, 
	          (_ep->is_in?"IN":"OUT"));

	if (_ep->is_in == 1) {
		depctl_addr = &(_core_if->dev_if->in_ep_regs[_ep->num]->diepctl);
		depctl.d32 = dwc_read_reg32(depctl_addr);

		/* set the disable and stall bits */
		if (depctl.b.epena) {
                        depctl.b.epdis = 1;
                }
		depctl.b.stall = 1;
		dwc_write_reg32(depctl_addr, depctl.d32);

	} else {
		depctl_addr = &(_core_if->dev_if->out_ep_regs[_ep->num]->doepctl);
		depctl.d32 = dwc_read_reg32(depctl_addr);

		/* set the stall bit */
		depctl.b.stall = 1;
		dwc_write_reg32(depctl_addr, depctl.d32);
	}
        DWC_DEBUGPL(DBG_PCD,"DEPCTL=%0x\n",dwc_read_reg32(depctl_addr));
	return;
}

/** 
 * Clear the EP STALL.
 *
 * @param _core_if Programming view of DWC_otg controller.
 * @param _ep The EP to clear stall from.
 */
void dwc_otg_ep_clear_stall(dwc_otg_core_if_t *_core_if, dwc_ep_t *_ep)
{
	depctl_data_t depctl;
	volatile uint32_t *depctl_addr;

        DWC_DEBUGPL(DBG_PCD, "%s ep%d-%s\n", __func__, _ep->num, 
                    (_ep->is_in?"IN":"OUT"));

	if (_ep->is_in == 1) {
		depctl_addr = &(_core_if->dev_if->in_ep_regs[_ep->num]->diepctl);
	} else {
		depctl_addr = &(_core_if->dev_if->out_ep_regs[_ep->num]->doepctl);
	}

	depctl.d32 = dwc_read_reg32(depctl_addr);

	/* clear the stall bits */
	depctl.b.stall = 0;

        /* 
         * USB Spec 9.4.5: For endpoints using data toggle, regardless
         * of whether an endpoint has the Halt feature set, a
         * ClearFeature(ENDPOINT_HALT) request always results in the
         * data toggle being reinitialized to DATA0.
         */
        if (_ep->type == DWC_OTG_EP_TYPE_INTR || 
            _ep->type == DWC_OTG_EP_TYPE_BULK) {
                depctl.b.setd0pid = 1; /* DATA0 */
        }
        
	dwc_write_reg32(depctl_addr, depctl.d32);
        DWC_DEBUGPL(DBG_PCD,"DEPCTL=%0x\n",dwc_read_reg32(depctl_addr));
	return;
}

/** 
 * This function reads a packet from the Rx FIFO into the destination
 * buffer.  To read SETUP data use dwc_otg_read_setup_packet.
 *
 * @param _core_if Programming view of DWC_otg controller.
 * @param _dest   Destination buffer for the packet.
 * @param _bytes  Number of bytes to copy to the destination.
 */
void dwc_otg_read_packet(dwc_otg_core_if_t *_core_if,
			 uint8_t *_dest, 
			 uint16_t _bytes)
{
	int i;
	int word_count = (_bytes + 3) / 4;

	volatile uint32_t *fifo = _core_if->data_fifo[0];
	uint32_t *data_buff = (uint32_t *)_dest;

	/**
	 * @todo Account for the case where _dest is not dword aligned. This
	 * requires reading data from the FIFO into a uint32_t temp buffer,
	 * then moving it into the data buffer.
	 */

        DWC_DEBUGPL((DBG_PCDV | DBG_CILV), "%s(%p,%p,%d)\n", __func__, 
                    _core_if, _dest, _bytes);

	for (i=0; i<word_count; i++, data_buff++) {
		*data_buff = dwc_read_reg32(fifo);
	}

	return;
}


#ifdef DEBUG
/**
 * This functions reads the device registers and prints them
 *
 * @param _core_if Programming view of DWC_otg controller.
 */
void dwc_otg_dump_dev_registers(dwc_otg_core_if_t *_core_if)
{
	int i;
	volatile uint32_t *addr;

	DWC_PRINT("Device Global Registers\n");
	addr=&_core_if->dev_if->dev_global_regs->dcfg;
	DWC_PRINT("DCFG      @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
	addr=&_core_if->dev_if->dev_global_regs->dctl;
	DWC_PRINT("DCTL      @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
	addr=&_core_if->dev_if->dev_global_regs->dsts;
	DWC_PRINT("DSTS      @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
	addr=&_core_if->dev_if->dev_global_regs->diepmsk;
	DWC_PRINT("DIEPMSK   @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
	addr=&_core_if->dev_if->dev_global_regs->doepmsk;
	DWC_PRINT("DOEPMSK   @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
	addr=&_core_if->dev_if->dev_global_regs->daint;
	DWC_PRINT("DAINT     @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
	addr=&_core_if->dev_if->dev_global_regs->dtknqr1;
	DWC_PRINT("DTKNQR1   @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
        if (_core_if->hwcfg2.b.dev_token_q_depth > 6) {
                addr=&_core_if->dev_if->dev_global_regs->dtknqr2;
                DWC_PRINT("DTKNQR2   @0x%08X : 0x%08X\n",
                          (uint32_t)addr,dwc_read_reg32(addr));
        }
        
	addr=&_core_if->dev_if->dev_global_regs->dvbusdis;
	DWC_PRINT("DVBUSID   @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));

	addr=&_core_if->dev_if->dev_global_regs->dvbuspulse;
	DWC_PRINT("DVBUSPULSE   @0x%08X : 0x%08X\n",
                  (uint32_t)addr,dwc_read_reg32(addr));

        if (_core_if->hwcfg2.b.dev_token_q_depth > 14) {
		addr = &_core_if->dev_if->dev_global_regs->dtknqr3_dthrctl;
                DWC_PRINT("DTKNQR3   @0x%08X : 0x%08X\n",
                          (uint32_t)addr, dwc_read_reg32(addr));
        }

        if (_core_if->hwcfg2.b.dev_token_q_depth > 22) {
		addr = &_core_if->dev_if->dev_global_regs->dtknqr4_fifoemptymsk;
		DWC_PRINT("DTKNQR4	 @0x%08X : 0x%08X\n", (uint32_t) addr,
			   dwc_read_reg32(addr));
	}
	for (i = 0; i <= _core_if->dev_if->num_in_eps; i++) {
		DWC_PRINT("Device IN EP %d Registers\n", i);
		addr=&_core_if->dev_if->in_ep_regs[i]->diepctl;
		DWC_PRINT("DIEPCTL   @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
		addr=&_core_if->dev_if->in_ep_regs[i]->diepint;
		DWC_PRINT("DIEPINT   @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
		addr=&_core_if->dev_if->in_ep_regs[i]->dieptsiz;
		DWC_PRINT("DIETSIZ   @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
		addr=&_core_if->dev_if->in_ep_regs[i]->diepdma;
		DWC_PRINT("DIEPDMA   @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
		
addr = &_core_if->dev_if->in_ep_regs[i]->dtxfsts;
		DWC_PRINT("DTXFSTS	 @0x%08X : 0x%08X\n", (uint32_t) addr,
			   dwc_read_reg32(addr));
	}
	for (i = 0; i <= _core_if->dev_if->num_out_eps; i++) {
		DWC_PRINT("Device OUT EP %d Registers\n", i);
		addr=&_core_if->dev_if->out_ep_regs[i]->doepctl;
		DWC_PRINT("DOEPCTL   @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
		addr=&_core_if->dev_if->out_ep_regs[i]->doepfn;
		DWC_PRINT("DOEPFN    @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
		addr=&_core_if->dev_if->out_ep_regs[i]->doepint;
		DWC_PRINT("DOEPINT   @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
		addr=&_core_if->dev_if->out_ep_regs[i]->doeptsiz;
		DWC_PRINT("DOETSIZ   @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
		addr=&_core_if->dev_if->out_ep_regs[i]->doepdma;
		DWC_PRINT("DOEPDMA   @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
	}
	return;
}

/**
 * This function reads the host registers and prints them
 *
 * @param _core_if Programming view of DWC_otg controller.
 */
void dwc_otg_dump_host_registers(dwc_otg_core_if_t *_core_if)
{
	int i;
	volatile uint32_t *addr;

	DWC_PRINT("Host Global Registers\n");
	addr=&_core_if->host_if->host_global_regs->hcfg;
	DWC_PRINT("HCFG      @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
	addr=&_core_if->host_if->host_global_regs->hfir;
	DWC_PRINT("HFIR      @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
	addr=&_core_if->host_if->host_global_regs->hfnum;
	DWC_PRINT("HFNUM     @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
	addr=&_core_if->host_if->host_global_regs->hptxsts;
	DWC_PRINT("HPTXSTS   @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
	addr=&_core_if->host_if->host_global_regs->haint;
	DWC_PRINT("HAINT     @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
	addr=&_core_if->host_if->host_global_regs->haintmsk;
	DWC_PRINT("HAINTMSK  @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
	addr=_core_if->host_if->hprt0;
	DWC_PRINT("HPRT0     @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));

	for (i=0; i<_core_if->core_params->host_channels; i++) {
		DWC_PRINT("Host Channel %d Specific Registers\n", i);
		addr=&_core_if->host_if->hc_regs[i]->hcchar;
		DWC_PRINT("HCCHAR    @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
		addr=&_core_if->host_if->hc_regs[i]->hcsplt;
		DWC_PRINT("HCSPLT    @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
		addr=&_core_if->host_if->hc_regs[i]->hcint;
		DWC_PRINT("HCINT     @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
		addr=&_core_if->host_if->hc_regs[i]->hcintmsk;
		DWC_PRINT("HCINTMSK  @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
		addr=&_core_if->host_if->hc_regs[i]->hctsiz;
		DWC_PRINT("HCTSIZ    @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
		addr=&_core_if->host_if->hc_regs[i]->hcdma;
		DWC_PRINT("HCDMA     @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));

	}
	return;
}

/**
 * This function reads the core global registers and prints them
 *
 * @param _core_if Programming view of DWC_otg controller.
 */
void dwc_otg_dump_global_registers(dwc_otg_core_if_t *_core_if)
{
	int i;
	volatile uint32_t *addr;

	DWC_PRINT("Core Global Registers\n");
	addr=&_core_if->core_global_regs->gotgctl;
	DWC_PRINT("GOTGCTL   @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
	addr=&_core_if->core_global_regs->gotgint;
	DWC_PRINT("GOTGINT   @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
	addr=&_core_if->core_global_regs->gahbcfg;
	DWC_PRINT("GAHBCFG   @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
	addr=&_core_if->core_global_regs->gusbcfg;
	DWC_PRINT("GUSBCFG   @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
	addr=&_core_if->core_global_regs->grstctl;
	DWC_PRINT("GRSTCTL   @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
	addr=&_core_if->core_global_regs->gintsts;
	DWC_PRINT("GINTSTS   @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
	addr=&_core_if->core_global_regs->gintmsk;
	DWC_PRINT("GINTMSK   @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
	addr=&_core_if->core_global_regs->grxstsr;
	DWC_PRINT("GRXSTSR   @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
	//addr=&_core_if->core_global_regs->grxstsp;
	//DWC_PRINT("GRXSTSP   @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
	addr=&_core_if->core_global_regs->grxfsiz;
	DWC_PRINT("GRXFSIZ   @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
	addr=&_core_if->core_global_regs->gnptxfsiz;
	DWC_PRINT("GNPTXFSIZ @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
	addr=&_core_if->core_global_regs->gnptxsts;
	DWC_PRINT("GNPTXSTS  @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
	addr=&_core_if->core_global_regs->gi2cctl;
	DWC_PRINT("GI2CCTL   @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
	addr=&_core_if->core_global_regs->gpvndctl;
	DWC_PRINT("GPVNDCTL  @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
	addr=&_core_if->core_global_regs->ggpio;
	DWC_PRINT("GGPIO     @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
	addr=&_core_if->core_global_regs->guid;
	DWC_PRINT("GUID      @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
	addr=&_core_if->core_global_regs->gsnpsid;
	DWC_PRINT("GSNPSID   @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
	addr=&_core_if->core_global_regs->ghwcfg1;
	DWC_PRINT("GHWCFG1   @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
	addr=&_core_if->core_global_regs->ghwcfg2;
	DWC_PRINT("GHWCFG2   @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
	addr=&_core_if->core_global_regs->ghwcfg3;
	DWC_PRINT("GHWCFG3   @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
	addr=&_core_if->core_global_regs->ghwcfg4;
	DWC_PRINT("GHWCFG4   @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));
	addr=&_core_if->core_global_regs->hptxfsiz;
	DWC_PRINT("HPTXFSIZ  @0x%08X : 0x%08X\n",(uint32_t)addr,dwc_read_reg32(addr));

        for (i=0; i<_core_if->hwcfg4.b.num_dev_perio_in_ep; i++) {
		addr=&_core_if->core_global_regs->dptxfsiz_dieptxf[i];
		DWC_PRINT("DPTXFSIZ[%d] @0x%08X : 0x%08X\n",i,(uint32_t)addr,dwc_read_reg32(addr));
	}

}
#endif

/**
 * Flush a Tx FIFO.
 *
 * @param _core_if Programming view of DWC_otg controller.
 * @param _num Tx FIFO to flush.
 */
extern void dwc_otg_flush_tx_fifo( dwc_otg_core_if_t *_core_if, 
                                   const int _num ) 
{
        dwc_otg_core_global_regs_t *global_regs = _core_if->core_global_regs;
        volatile grstctl_t greset = { .d32 = 0};
        int count = 0;
        
        DWC_DEBUGPL((DBG_CIL|DBG_PCDV), "Flush Tx FIFO %d\n", _num);

        greset.b.txfflsh = 1;
        greset.b.txfnum = _num;
        dwc_write_reg32( &global_regs->grstctl, greset.d32 );
        
        do {
                greset.d32 = dwc_read_reg32( &global_regs->grstctl);
                if (++count > 10000){
                        DWC_WARN("%s() HANG! GRSTCTL=%0x GNPTXSTS=0x%08x\n",
                                  __func__, greset.d32,
                                  dwc_read_reg32( &global_regs->gnptxsts));
                        break;
                }

		udelay(1);
        } while (greset.b.txfflsh == 1);
        /* Wait for 3 PHY Clocks*/
        UDELAY(1);
}

/**
 * Flush Rx FIFO.
 *
 * @param _core_if Programming view of DWC_otg controller.
 */
extern void dwc_otg_flush_rx_fifo( dwc_otg_core_if_t *_core_if ) 
{
        dwc_otg_core_global_regs_t *global_regs = _core_if->core_global_regs;
        volatile grstctl_t greset = { .d32 = 0};
        int count = 0;
        
        DWC_DEBUGPL((DBG_CIL|DBG_PCDV), "%s\n", __func__);
        /*
         * 
         */
        greset.b.rxfflsh = 1;
        dwc_write_reg32( &global_regs->grstctl, greset.d32 );
        
        do {
                greset.d32 = dwc_read_reg32( &global_regs->grstctl);
                if (++count > 10000){
                        DWC_WARN("%s() HANG! GRSTCTL=%0x\n", __func__, 
                                 greset.d32);
                        break;
                }
        } while (greset.b.rxfflsh == 1);        
        /* Wait for 3 PHY Clocks*/
        UDELAY(1);
}

/**
 * Do core a soft reset of the core.  Be careful with this because it
 * resets all the internal state machines of the core.
 */

void dwc_otg_core_reset(dwc_otg_core_if_t *_core_if)
{
	dwc_otg_core_global_regs_t *global_regs = _core_if->core_global_regs;
	volatile grstctl_t greset = { .d32 = 0};
	int count = 0;

	DWC_DEBUGPL(DBG_CILV, "%s\n", __func__);
	/* Wait for AHB master IDLE state. */
	do {
		UDELAY(10);
		greset.d32 = dwc_read_reg32( &global_regs->grstctl);
		if (++count > 100000){
			DWC_WARN("%s() HANG! AHB Idle GRSTCTL=%0x %x\n", __func__, 
			greset.d32, greset.b.ahbidle);
			return;
		}
	} while (greset.b.ahbidle == 0);
        
// winder add.
#if 1
	/* Note: Actually, I don't exactly why we need to put delay here. */
	MDELAY(100);
#endif
	/* Core Soft Reset */
	count = 0;
	greset.b.csftrst = 1;
	dwc_write_reg32( &global_regs->grstctl, greset.d32 );
// winder add.
#if 1
	/* Note: Actually, I don't exactly why we need to put delay here. */
	MDELAY(100);
#endif
	do {
		greset.d32 = dwc_read_reg32( &global_regs->grstctl);
		if (++count > 10000){
			DWC_WARN("%s() HANG! Soft Reset GRSTCTL=%0x\n", __func__, 
				greset.d32);
			break;
		}
		udelay(1);
	} while (greset.b.csftrst == 1);        
	/* Wait for 3 PHY Clocks*/
	//DWC_PRINT("100ms\n");
	MDELAY(100);
}



/**
 * Register HCD callbacks.  The callbacks are used to start and stop
 * the HCD for interrupt processing.
 *
 * @param _core_if Programming view of DWC_otg controller.
 * @param _cb the HCD callback structure.
 * @param _p pointer to be passed to callback function (usb_hcd*).
 */
extern void dwc_otg_cil_register_hcd_callbacks( dwc_otg_core_if_t *_core_if,
                                                dwc_otg_cil_callbacks_t *_cb,
                                                void *_p)
{
        _core_if->hcd_cb = _cb;        
        _cb->p = _p;        
}

/**
 * Register PCD callbacks.  The callbacks are used to start and stop
 * the PCD for interrupt processing.
 *
 * @param _core_if Programming view of DWC_otg controller.
 * @param _cb the PCD callback structure.
 * @param _p pointer to be passed to callback function (pcd*).
 */
extern void dwc_otg_cil_register_pcd_callbacks( dwc_otg_core_if_t *_core_if,
                                                dwc_otg_cil_callbacks_t *_cb,
                                                void *_p)
{
        _core_if->pcd_cb = _cb;
        _cb->p = _p;
}