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path: root/firmware/target/mips/ingenic_jz47xx/usb-jz4740.c
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/***************************************************************************
 *             __________               __   ___.
 *   Open      \______   \ ____   ____ |  | _\_ |__   _______  ___
 *   Source     |       _//  _ \_/ ___\|  |/ /| __ \ /  _ \  \/  /
 *   Jukebox    |    |   (  <_> )  \___|    < | \_\ (  <_> > <  <
 *   Firmware   |____|_  /\____/ \___  >__|_ \|___  /\____/__/\_ \
 *                     \/            \/     \/    \/            \/
 * $Id$
 *
 * Copyright (C) 2008 by Maurus Cuelenaere
 *
 * This program is free software; you can redistribute it and/or
 * modify it under the terms of the GNU General Public License
 * as published by the Free Software Foundation; either version 2
 * of the License, or (at your option) any later version.
 *
 * This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY
 * KIND, either express or implied.
 *
 ****************************************************************************/

#include "config.h"
/*#define LOGF_ENABLE*/
#include "logf.h"
#include "system.h"
#include "usb_ch9.h"
#include "usb_drv.h"
#include "usb_core.h"
#include "jz4740.h"
#include "thread.h"

/*
    The Jz4740 USB controller is called MUSBHSFC in the datasheet.
    It also seems to be a more generic controller, with support for
    up to 15 endpoints (the Jz4740 only has 5).
*/

#define EP_BUF_LEFT(ep)  ((ep)->length - (ep)->sent)
#define EP_PTR(ep)       ((void*)((unsigned int)(ep)->buf + (ep)->sent))
#define EP_NUMBER(ep)    (((int)(ep) - (int)&endpoints[0])/sizeof(struct usb_endpoint))
#define EP_NUMBER2(ep)   (EP_NUMBER((ep))/2)
#define TOTAL_EP()       (sizeof(endpoints)/sizeof(struct usb_endpoint))
#define EP_IS_IN(ep)     (EP_NUMBER((ep))%2)

enum ep_type
{
    ep_control,
    ep_bulk,
    ep_interrupt,
    ep_isochronous
};

struct usb_endpoint
{
    void *buf;
    size_t length;
    union
    {
        size_t sent;
        size_t received;
    };
    bool busy;

    const enum ep_type type;
    const bool use_dma;

    const long fifo_addr;
    unsigned short fifo_size;

    bool wait;
    struct semaphore complete;
};

static unsigned char ep0_rx_buf[64];
static struct usb_endpoint endpoints[] =
{
    { .type = ep_control,   .fifo_addr = USB_FIFO_EP0, .fifo_size = 64 },
    { .type = ep_control,   .fifo_addr = USB_FIFO_EP0, .buf = &ep0_rx_buf },
    { .type = ep_bulk,      .fifo_addr = USB_FIFO_EP1, .fifo_size = 512 },
    { .type = ep_bulk,      .fifo_addr = USB_FIFO_EP1, .fifo_size = 512 },
    { .type = ep_interrupt, .fifo_addr = USB_FIFO_EP2, .fifo_size = 64 },
};

static inline void select_endpoint(int ep)
{
    REG_USB_REG_INDEX = ep;
}

static void readFIFO(struct usb_endpoint *ep, unsigned int size)
{
    logf("%s(EP%d, %d)", __func__, EP_NUMBER2(ep), size);

    register unsigned char *ptr = (unsigned char*)EP_PTR(ep);
    register unsigned int *ptr32 = (unsigned int*)ptr;
    register unsigned int s = size >> 2;
    register unsigned int x;

    if(size > 0)
    {
        if( ((unsigned int)ptr & 3) == 0 )
        {
            while(s--)
                *ptr32++ = REG32(ep->fifo_addr);

            ptr = (unsigned char*)ptr32;
        }
        else
        {
            while(s--)
            {
                x = REG32(ep->fifo_addr);
                *ptr++ = x & 0xFF; x >>= 8;
                *ptr++ = x & 0xFF; x >>= 8;
                *ptr++ = x & 0xFF; x >>= 8;
                *ptr++ = x;
            }
        }

        s = size & 3;
        while(s--)
            *ptr++ = REG8(ep->fifo_addr);
    }
}

static void writeFIFO(struct usb_endpoint *ep, size_t size)
{
    logf("%s(EP%d, %d)", __func__, EP_NUMBER2(ep), size);

    register unsigned int *d32 = (unsigned int *)EP_PTR(ep);
    register size_t s = size >> 2;

    if(size > 0)
    {
        while (s--)
            REG32(ep->fifo_addr) = *d32++;

        if( (s = size & 3) )
        {
            register unsigned char *d8 = (unsigned char *)d32;
            while (s--)
                REG8(ep->fifo_addr) = *d8++;
        }
    }
}

static void flushFIFO(struct usb_endpoint *ep)
{
    logf("%s(%d)", __func__, EP_NUMBER(ep));

    switch (ep->type)
    {
        case ep_control:
        break;

        case ep_bulk:
        case ep_interrupt:
        case ep_isochronous:
            if(EP_IS_IN(ep))
                REG_USB_REG_INCSR |= (USB_INCSR_FF | USB_INCSR_CDT);
            else
                REG_USB_REG_OUTCSR |= (USB_OUTCSR_FF | USB_OUTCSR_CDT);
        break;
    }
}

static inline void ep_transfer_completed(struct usb_endpoint* ep)
{
    ep->sent   = 0;
    ep->length = 0;
    ep->buf    = NULL;
    ep->busy   = false;
    if(ep->wait)
        semaphore_release(&ep->complete);
}

static void EP0_send(void)
{
    struct usb_endpoint* ep = &endpoints[0];
    unsigned int length;
    unsigned char csr0;

    select_endpoint(0);
    csr0 = REG_USB_REG_CSR0;

    if(ep->sent == 0)
        length = MIN(ep->length, ep->fifo_size);
    else
        length = MIN(EP_BUF_LEFT(ep), ep->fifo_size);

    writeFIFO(ep, length);
    ep->sent += length;

    if(ep->sent >= ep->length)
    {
        REG_USB_REG_CSR0 = (csr0 | USB_CSR0_INPKTRDY | USB_CSR0_DATAEND); /* Set data end! */
        usb_core_transfer_complete(0, USB_DIR_IN, 0, ep->sent);
        ep_transfer_completed(ep);
    }
    else
        REG_USB_REG_CSR0 = (csr0 | USB_CSR0_INPKTRDY);
}

static void EP0_handler(void)
{
    logf("%s()", __func__);

    unsigned char csr0;
    struct usb_endpoint *ep_send = &endpoints[0];
    struct usb_endpoint *ep_recv = &endpoints[1];

    /* Read CSR0 */
    select_endpoint(0);
    csr0 = REG_USB_REG_CSR0;

    /* Check for SentStall:
        This bit is set when a STALL handshake is transmitted. The CPU should clear this bit.
     */
    if(csr0 & USB_CSR0_SENTSTALL)
    {
        REG_USB_REG_CSR0 = csr0 & ~USB_CSR0_SENTSTALL;
        return;
    }

    /* Check for SetupEnd:
        This bit will be set when a control transaction ends before the DataEnd bit has been set.
        An interrupt will be generated and the FIFO flushed at this time.
        The bit is cleared by the CPU writing a 1 to the ServicedSetupEnd bit.
     */
    if(csr0 & USB_CSR0_SETUPEND)
    {
        REG_USB_REG_CSR0 = csr0 | USB_CSR0_SVDSETUPEND;
        return;
    }

    /* Call relevant routines for endpoint 0 state */
    if(ep_send->busy)
        EP0_send();
    else if(csr0 & USB_CSR0_OUTPKTRDY)   /* There is a packet in the fifo */
    {
        readFIFO(ep_recv, REG_USB_REG_COUNT0);
        REG_USB_REG_CSR0 = csr0 | USB_CSR0_SVDOUTPKTRDY; /* clear OUTPKTRDY bit */
        usb_core_control_request((struct usb_ctrlrequest*)ep_recv->buf);
    }
}

static void EPIN_handler(unsigned int endpoint)
{
    struct usb_endpoint* ep = &endpoints[endpoint*2];
    unsigned int length, csr;

    select_endpoint(endpoint);
    csr = REG_USB_REG_INCSR;
    logf("%s(%d): 0x%x", __func__, endpoint, csr);

    if(!ep->busy)
    {
        logf("Entered EPIN handler without work!");
        return;
    }

    if(csr & USB_INCSR_SENTSTALL)
    {
        REG_USB_REG_INCSR = csr & ~USB_INCSR_SENTSTALL;
        return;
    }

    if(ep->use_dma)
        return;

    if(csr & USB_INCSR_FFNOTEMPT)
    {
        logf("FIFO is not empty! 0x%x", csr);
        return;
    }

    logf("EP%d: %d -> %d", endpoint, ep->sent, ep->length);

    if(ep->sent == 0)
        length = MIN(ep->length, ep->fifo_size);
    else
        length = MIN(EP_BUF_LEFT(ep), ep->fifo_size);

    writeFIFO(ep, length);
    REG_USB_REG_INCSR = csr | USB_INCSR_INPKTRDY;
    ep->sent += length;

    if(ep->sent >= ep->length)
    {
        usb_core_transfer_complete(endpoint, USB_DIR_IN, 0, ep->sent);
        ep_transfer_completed(ep);
        logf("sent complete");
    }
}

static void EPOUT_handler(unsigned int endpoint)
{
    struct usb_endpoint* ep = &endpoints[endpoint*2+1];
    unsigned int size, csr;

    if(!ep->busy)
    {
        logf("Entered EPOUT handler without work!");
        return;
    }

    select_endpoint(endpoint);
    while((csr = REG_USB_REG_OUTCSR) & (USB_OUTCSR_SENTSTALL|USB_OUTCSR_OUTPKTRDY))
    {
        logf("%s(%d): 0x%x", __func__, endpoint, csr);
        if(csr & USB_OUTCSR_SENTSTALL)
        {
            logf("stall sent, flushing fifo..");
            flushFIFO(ep);
            REG_USB_REG_OUTCSR = csr & ~USB_OUTCSR_SENTSTALL;
            return;
        }

        if(ep->use_dma)
            return;

        if(csr & USB_OUTCSR_OUTPKTRDY) /* There is a packet in the fifo */
        {
            size = REG_USB_REG_OUTCOUNT;

            readFIFO(ep, size);
            ep->received += size;

            /*if(csr & USB_OUTCSR_FFFULL)
                csr &= ~USB_OUTCSR_FFFULL;*/

            REG_USB_REG_OUTCSR = csr & ~USB_OUTCSR_OUTPKTRDY;

            logf("received: %d max length: %d", ep->received, ep->length);

            if(size < ep->fifo_size || ep->received >= ep->length)
            {
                usb_core_transfer_complete(endpoint, USB_DIR_OUT, 0, ep->received);
                ep_transfer_completed(ep);
                logf("receive transfer_complete");
            }
        }
    }
}

static void EPDMA_handler(int number)
{
    int endpoint = -1;
    unsigned int size = 0;

    if(number == USB_INTR_DMA_BULKIN)
        endpoint = (REG_USB_REG_CNTL1 >> 4) & 0xF;
    else if(number == USB_INTR_DMA_BULKOUT)
        endpoint = (REG_USB_REG_CNTL2 >> 4) & 0xF;

    struct usb_endpoint* ep = &endpoints[endpoint];
    logf("DMA_BULK%d %d", number, endpoint);

    if(number == USB_INTR_DMA_BULKIN)
        size = (unsigned int)ep->buf - REG_USB_REG_ADDR1;
    else if(number == USB_INTR_DMA_BULKOUT)
        size = (unsigned int)ep->buf - REG_USB_REG_ADDR2;

    if(number == USB_INTR_DMA_BULKOUT)
    {
        /* Disable DMA */
        REG_USB_REG_CNTL2 = 0;

        select_endpoint(endpoint);
        /* Read out last packet manually */
        unsigned int lpack_size = REG_USB_REG_OUTCOUNT;
        if(lpack_size > 0)
        {
            ep->buf += ep->length - lpack_size;
            readFIFO(ep, lpack_size);
            REG_USB_REG_OUTCSR &= ~USB_OUTCSR_OUTPKTRDY;
        }
    }
    else if(number == USB_INTR_DMA_BULKIN && size % ep->fifo_size)
    {
        /* If the last packet is less than MAXP, set INPKTRDY manually */
        REG_USB_REG_INCSR |= USB_INCSR_INPKTRDY;
    }

    usb_core_transfer_complete(endpoint, EP_IS_IN(ep) ? USB_DIR_IN : USB_DIR_OUT,
                               0, ep->length);
    ep_transfer_completed(ep);
}

static void setup_endpoint(struct usb_endpoint *ep)
{
    int csr, csrh;

    select_endpoint(EP_NUMBER2(ep));

    ep->busy = false;
    ep->wait = false;
    ep->sent = 0;
    ep->length = 0;

    if(ep->type == ep_bulk)
    {
        if(REG_USB_REG_POWER & USB_POWER_HSMODE)
            ep->fifo_size = 512;
        else
            ep->fifo_size = 64;
    }

    if(EP_IS_IN(ep))
    {
        csr = (USB_INCSR_FF | USB_INCSR_CDT);
        csrh = USB_INCSRH_MODE;

        if(ep->use_dma)
            csrh |= (USB_INCSRH_DMAREQENAB | USB_INCSRH_AUTOSET | USB_INCSRH_DMAREQMODE);

        if(ep->type == ep_interrupt)
            csrh |= USB_INCSRH_FRCDATATOG;

        REG_USB_REG_INMAXP   = ep->fifo_size;
        REG_USB_REG_INCSR    = csr;
        REG_USB_REG_INCSRH   = csrh;
        REG_USB_REG_INTRINE |= USB_INTR_EP(EP_NUMBER2(ep));
    }
    else
    {
        csr = (USB_OUTCSR_FF | USB_OUTCSR_CDT);
        csrh = 0;

        if(ep->type == ep_interrupt)
            csrh |= USB_OUTCSRH_DNYT;

        if(ep->use_dma)
            csrh |= (USB_OUTCSRH_DMAREQENAB | USB_OUTCSRH_AUTOCLR | USB_OUTCSRH_DMAREQMODE);

        REG_USB_REG_OUTMAXP   = ep->fifo_size;
        REG_USB_REG_OUTCSR    = csr;
        REG_USB_REG_OUTCSRH   = csrh;
        REG_USB_REG_INTROUTE |= USB_INTR_EP(EP_NUMBER2(ep));
    }
}

static void udc_reset(void)
{
    /* From the datasheet:

       When a reset condition is detected on the USB, the controller performs the following actions:
           * Sets FAddr to 0.
           * Sets Index to 0.
           * Flushes all endpoint FIFOs.
           * Clears all control/status registers.
           * Enables all endpoint interrupts.
           * Generates a Reset interrupt.
    */

    logf("%s()", __func__);

    unsigned int i;

    /* Disable interrupts */
    REG_USB_REG_INTRINE  = 0;
    REG_USB_REG_INTROUTE = 0;
    REG_USB_REG_INTRUSBE = 0;

    /* Disable DMA */
    REG_USB_REG_CNTL1 = 0;
    REG_USB_REG_CNTL2 = 0;

    /* High speed, softconnect and suspend/resume */
    REG_USB_REG_POWER = (USB_POWER_SOFTCONN | USB_POWER_HSENAB | USB_POWER_SUSPENDM);

    /* Reset EP0 */
    select_endpoint(0);
    REG_USB_REG_CSR0 = (USB_CSR0_SVDOUTPKTRDY | USB_CSR0_SVDSETUPEND);

    /* Reset other endpoints */
    for(i=2; i<TOTAL_EP(); i++)
        setup_endpoint(&endpoints[i]);

    /* Enable interrupts */
    REG_USB_REG_INTRINE  |= USB_INTR_EP0;
    REG_USB_REG_INTRUSBE |= USB_INTR_RESET;

    usb_core_bus_reset();
}

/* Interrupt handler */
void UDC(void)
{
    /* Read interrupt registers */
    unsigned char    intrUSB = REG_USB_REG_INTRUSB & 0x07; /* Mask SOF */
    unsigned short   intrIn  = REG_USB_REG_INTRIN;
    unsigned short   intrOut = REG_USB_REG_INTROUT;
    unsigned char    intrDMA = REG_USB_REG_INTR;

    logf("%x %x %x %x", intrUSB, intrIn, intrOut, intrDMA);

    /* EPIN & EPOUT are all handled in DMA */
    if(intrIn & USB_INTR_EP0)
        EP0_handler();
    if(intrIn & USB_INTR_INEP1)
        EPIN_handler(1);
    if(intrIn & USB_INTR_INEP2)
        EPIN_handler(2);
    if(intrOut & USB_INTR_OUTEP1)
        EPOUT_handler(1);
    if(intrOut & USB_INTR_OUTEP2)
        EPOUT_handler(2);
    if(intrUSB & USB_INTR_RESET)
        udc_reset();
    if(intrUSB & USB_INTR_SUSPEND)
    {
        logf("USB suspend");
    }
    if(intrUSB & USB_INTR_RESUME)
    {
        logf("USB resume");
    }
    if(intrDMA & USB_INTR_DMA_BULKIN)
        EPDMA_handler(USB_INTR_DMA_BULKIN);
    if(intrDMA & USB_INTR_DMA_BULKOUT)
        EPDMA_handler(USB_INTR_DMA_BULKOUT);
}

bool usb_drv_stalled(int endpoint, bool in)
{
    endpoint &= 0x7F;

    logf("%s(%d, %s)", __func__, endpoint, in?"IN":"OUT");

    select_endpoint(endpoint);

    if(endpoint == EP_CONTROL)
        return (REG_USB_REG_CSR0 & USB_CSR0_SENDSTALL) != 0;
    else
    {
        if(in)
            return (REG_USB_REG_INCSR & USB_INCSR_SENDSTALL) != 0;
        else
            return (REG_USB_REG_OUTCSR & USB_OUTCSR_SENDSTALL) != 0;
    }
}

void usb_drv_stall(int endpoint, bool stall, bool in)
{
    endpoint &= 0x7F;

    logf("%s(%d,%s,%s)", __func__, endpoint, stall?"Y":"N", in?"IN":"OUT");

    select_endpoint(endpoint);

    if(endpoint == EP_CONTROL)
    {
        if(stall)
            REG_USB_REG_CSR0 |= USB_CSR0_SENDSTALL;
        else
            REG_USB_REG_CSR0 &= ~USB_CSR0_SENDSTALL;
    }
    else
    {
        if(in)
        {
            if(stall)
                REG_USB_REG_INCSR |= USB_INCSR_SENDSTALL;
            else
                REG_USB_REG_INCSR = (REG_USB_REG_INCSR & ~USB_INCSR_SENDSTALL) | USB_INCSR_CDT;
        }
        else
        {
            if(stall)
                REG_USB_REG_OUTCSR |= USB_OUTCSR_SENDSTALL;
            else
                REG_USB_REG_OUTCSR = (REG_USB_REG_OUTCSR & ~USB_OUTCSR_SENDSTALL) | USB_OUTCSR_CDT;
        }
    }
}

#define GPIO_UDC_DETE      (32 * 3 + 28) /* A18 = ADP_CHK */
#define IRQ_GPIO_UDC_DETE  (IRQ_GPIO_0 + GPIO_UDC_DETE)
#ifndef ONDA_VX767
# define USB_GPIO_IRQ GPIO124
#endif

int usb_detect(void)
{
    return (__gpio_get_pin(GPIO_UDC_DETE) == 1)
        ? USB_INSERTED : USB_EXTRACTED;
}

void usb_init_device(void)
{
#ifdef ONDA_VX767
    REG_GPIO_PXFUNS(3) = 0x10000000;
    REG_GPIO_PXSELS(3) = 0x10000000;
    REG_GPIO_PXPES(3)  = 0x10000000;
    __gpio_as_input(GPIO_UDC_DETE);
#else
    REG_GPIO_PXPES(3)  = 0x10000000;
    __gpio_as_irq_rise_edge(GPIO_UDC_DETE);
#endif

#ifdef USB_GPIO_IRQ
    system_enable_irq(IRQ_GPIO_UDC_DETE);
#endif
    system_enable_irq(IRQ_UDC);

    for(unsigned i=0; i<TOTAL_EP(); i++)
        semaphore_init(&endpoints[i].complete, 1, 0);
}

#ifdef USB_GPIO_IRQ
static unsigned long last_tick;
void USB_GPIO_IRQ(void)
{
    /* Prevent enabled-disabled bouncing */
    if(current_tick - last_tick > HZ/16)
    {
        usb_status_event(usb_detect());
        last_tick = current_tick;
    }
}
#endif

void usb_enable(bool on)
{
    if(on)
        usb_core_init();
    else
        usb_core_exit();
}

void usb_attach(void)
{
    usb_enable(true);
}

void usb_drv_init(void)
{
    logf("%s()", __func__);

    /* Set this bit to allow the UDC entering low-power mode when
     * there are no actions on the USB bus.
     * UDC still works during this bit was set.
     */
    //__cpm_stop_udc();
    __cpm_start_udc();

    /* Enable the USB PHY */
    REG_CPM_SCR |= CPM_SCR_USBPHY_ENABLE;

    /* Dis- and reconnect from USB */
    REG_USB_REG_POWER &= ~USB_POWER_SOFTCONN;
    REG_USB_REG_POWER |= USB_POWER_SOFTCONN;

    udc_reset();
}

void usb_drv_exit(void)
{
    logf("%s()", __func__);

    /* Disable interrupts */
    REG_USB_REG_INTRINE  = 0;
    REG_USB_REG_INTROUTE = 0;
    REG_USB_REG_INTRUSBE = 0;

    /* Disable DMA */
    REG_USB_REG_CNTL1 = 0;
    REG_USB_REG_CNTL2 = 0;

    /* Disconnect from USB */
    REG_USB_REG_POWER &= ~USB_POWER_SOFTCONN;

    /* Disable the USB PHY */
    REG_CPM_SCR &= ~CPM_SCR_USBPHY_ENABLE;

    __cpm_stop_udc();
}

void usb_drv_set_address(int address)
{
    logf("%s(%d)", __func__, address);

    REG_USB_REG_FADDR = address;
}

static void usb_drv_send_internal(struct usb_endpoint* ep, void* ptr, int length, bool blocking)
{
    if(ep->type == ep_control && ptr == NULL && length == 0)
        return; /* ACK request, handled in the ISR */

    int flags = disable_irq_save();

    ep->buf = ptr;
    ep->sent = 0;
    ep->length = length;
    ep->busy = true;
    if(blocking)
        ep->wait = true;

    if(ep->type == ep_control)
    {
        EP0_send();
    }
    else
    {
        if(ep->use_dma)
        {
            commit_discard_dcache_range(ptr, length);
            REG_USB_REG_ADDR1 = PHYSADDR((unsigned long)ptr);
            REG_USB_REG_COUNT1 = length;
            REG_USB_REG_CNTL1 = (USB_CNTL_INTR_EN | USB_CNTL_MODE_1 |
                                 USB_CNTL_DIR_IN  | USB_CNTL_ENA |
                                 USB_CNTL_EP(EP_NUMBER2(ep)) | USB_CNTL_BURST_16);
        }
        else
            EPIN_handler(EP_NUMBER2(ep));
    }

    restore_irq(flags);

    if(blocking)
    {
        semaphore_wait(&ep->complete, TIMEOUT_BLOCK);
        ep->wait = false;
    }
}

int usb_drv_send_nonblocking(int endpoint, void* ptr, int length)
{
    logf("%s(%d, 0x%x, %d)", __func__, endpoint, (int)ptr, length);

    usb_drv_send_internal(&endpoints[(endpoint & 0x7F)*2], ptr, length, false);

    return 0;
}

int usb_drv_send(int endpoint, void* ptr, int length)
{
    logf("%s(%d, 0x%x, %d)", __func__, endpoint, (int)ptr, length);

    usb_drv_send_internal(&endpoints[(endpoint & 0x7F)*2], ptr, length, true);

    return 0;
}

int usb_drv_recv_nonblocking(int endpoint, void* ptr, int length)
{
    int flags;
    struct usb_endpoint *ep;
    endpoint &= 0x7F;

    logf("%s(%d, 0x%x, %d)", __func__, endpoint, (int)ptr, length);

    if(endpoint == EP_CONTROL)
        return 0; /* all EP0 OUT transactions are handled within the ISR */
    else
    {
        flags = disable_irq_save();
        ep = &endpoints[endpoint*2+1];

        ep->buf = ptr;
        ep->received = 0;
        ep->length = length;
        ep->busy = true;
        if(ep->use_dma)
        {
            discard_dcache_range(ptr, length);
            REG_USB_REG_ADDR2 = PHYSADDR((unsigned long)ptr);
            REG_USB_REG_COUNT2 = length;
            REG_USB_REG_CNTL2 = (USB_CNTL_INTR_EN | USB_CNTL_MODE_1 |
                                 USB_CNTL_ENA | USB_CNTL_EP(endpoint) |
                                 USB_CNTL_BURST_16);
        }
        else
            EPOUT_handler(endpoint);

        restore_irq(flags);
        return 0;
    }
}

void usb_drv_set_test_mode(int mode)
{
    logf("%s(%d)", __func__, mode);

    switch(mode)
    {
        case 0:
            REG_USB_REG_TESTMODE &= ~USB_TEST_ALL;
            break;
        case 1:
            REG_USB_REG_TESTMODE |= USB_TEST_J;
            break;
        case 2:
            REG_USB_REG_TESTMODE |= USB_TEST_K;
            break;
        case 3:
            REG_USB_REG_TESTMODE |= USB_TEST_SE0NAK;
            break;
        case 4:
            REG_USB_REG_TESTMODE |= USB_TEST_PACKET;
            break;
    }
}

int usb_drv_port_speed(void)
{
    return (REG_USB_REG_POWER & USB_POWER_HSMODE) ? 1 : 0;
}

void usb_drv_cancel_all_transfers(void)
{
    logf("%s()", __func__);

    unsigned int i, flags;
    flags = disable_irq_save();

    for(i=0; i<TOTAL_EP(); i++)
    {
        if(i != 1) /* ep0 out needs special handling */
            endpoints[i].buf = NULL;

        endpoints[i].sent = 0;
        endpoints[i].length = 0;

        select_endpoint(i/2);
        flushFIFO(&endpoints[i]);
    }
    restore_irq(flags);
}

void usb_drv_release_endpoint(int ep)
{
    (void)ep;
    logf("%s(%d, %s)", __func__, (ep & 0x7F), (ep >> 7) ? "IN" : "OUT");
}

int usb_drv_request_endpoint(int type, int dir)
{
    logf("%s(%d, %s)", __func__, type, (dir == USB_DIR_IN) ? "IN" : "OUT");

    dir  &= USB_ENDPOINT_DIR_MASK;
    type &= USB_ENDPOINT_XFERTYPE_MASK;

    /* There are only 3+2 endpoints, so hardcode this ... */
    switch(type)
    {
        case USB_ENDPOINT_XFER_BULK:
            if(dir == USB_DIR_IN)
                return (1 | USB_DIR_IN);
            else
                return (1 | USB_DIR_OUT);

        case USB_ENDPOINT_XFER_INT:
            if(dir == USB_DIR_IN)
                return (2 | USB_DIR_IN);

        default:
            return -1;
    }
}