rockbox/firmware/drivers/m66591.c

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/***************************************************************************
* __________ __ ___.
* Open \______ \ ____ ____ | | _\_ |__ _______ ___
* Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ /
* Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < <
* Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \
* \/ \/ \/ \/ \/
* $Id$
*
* Copyright (C) 2009 by Karl Kurbjun
* Portions Copyright (C) 2007 by Catalin Patulea
*
* 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.
*
****************************************************************************/
/*#define LOGF_ENABLE*/
#include "system.h"
#include "config.h"
#include "string.h"
#include "usb_ch9.h"
#include "usb_core.h"
#include "kernel.h"
#include "panic.h"
#include "usb_drv.h"
#include "logf.h"
#include "cpu.h"
#include "ata.h"
#include "usb.h"
#include "m66591.h"
/*******************************************************************************
* These are the driver specific defines.
******************************************************************************/
/* This define is primarily intended for testing, using HISPEED all the time
* should be acceptable since the device should down-train if the host does not
* support HISPEED.
*/
#define HISPEED
/* Right now sending blocks till the full transfer has completed. The driver
* will work without USB_TRAN_BLOCK set, but it is more than 50% slower.
* The driver is more "Proper" without USB_TRAN_BLOCK defined so if you start
* having freezeups or trouble using USB undefine this option.
*/
#define USB_TRAN_BLOCK
/*******************************************************************************
* The following functions are all helpers which should not be called directly
* from the USB stack. They should only be called by eachother, or the USB
* stack visible functions.
******************************************************************************/
static volatile unsigned short * pipe_ctrl_addr(int pipe);
static void pipe_handshake(int pipe, int handshake);
static void pipe_c_select (int pipe, bool dir);
#if !defined(USB_TRAN_BLOCK)
static int pipe_buffer_size (int pipe);
#endif
static int pipe_maxpack_size (int pipe);
static void control_received(void);
static void transfer_complete(int endpoint);
static int mxx_transmit_receive(int endpoint);
static int mxx_queue(int endpoint, void * ptr, int length, bool send,
bool wait);
struct M66591_epstat {
unsigned char dir; /* endpoint direction */
char *buf; /* user buffer to store data */
int length; /* how match data will fit */
volatile int count; /* actual data count */
bool waiting; /* is there data to transfer? */
bool busy; /* has the pipe been requested for use? */
} ;
static struct M66591_epstat M66591_eps[USB_NUM_ENDPOINTS];
/* This function is used to return the control address for each pipe */
static volatile unsigned short * pipe_ctrl_addr(int pipe) {
if(pipe==0) {
return &M66591_DCPCTRL;
} else {
return &M66591_PIPECTRL1 + (pipe-1);
}
}
static void pipe_init(int pipe) {
volatile unsigned short *pipe_cfg;
pipe_cfg = pipe_ctrl_addr(pipe);
*pipe_cfg |= 1<<9; /* ACLR */
*pipe_cfg &= ~(1<<9); /* Force de-assertion */
*pipe_cfg |= 1<<8; /* SQCLR */
}
/* This function sets the pipe/endpoint handshake */
static void pipe_handshake(int pipe, int handshake) {
handshake&=0x03;
if(handshake == PIPE_SHAKE_STALL) {
if( *(pipe_ctrl_addr(pipe)) & 0x03 ) {
*(pipe_ctrl_addr(pipe)) = 0x03;
} else {
*(pipe_ctrl_addr(pipe)) = 0x02;
}
} else {
*(pipe_ctrl_addr(pipe)) = handshake;
}
}
/* This function chooses the pipe desired and waits the required time before
* warites/reads are valid */
static void pipe_c_select (int pipe, bool dir) {
M66591_CPORT_CTRL0 = pipe | (1<<10) | (dir<<5);
// Wait for the Pipe to be valid;
udelay(2);
}
#if !defined(USB_TRAN_BLOCK)
/* This returns the maximum buffer size of each pipe. On this device the size
* is fixed.
*/
static int pipe_buffer_size (int pipe) {
switch(pipe) {
case 0:
return 256;
case 1:
case 2:
if(M66591_PIPE_CFGWND & (1<<9) )
return 1024;
else
return 512;
case 3:
case 4:
return 512;
case 5:
case 6:
return 64;
default:
return 0;
}
}
#endif
/* This function returns the maximum packet size for each endpoint/pipe. The
* max packet size is dependent on whether the device is running High or Full
* speed.
*/
static int pipe_maxpack_size (int pipe) {
if( (M66591_HSFS & 0xFF) == 0x03 ) { /* Device is running Highspeed */
switch(pipe) {
case 0:
/* DCP max packet size is configurable */
return M66591_DCP_MXPKSZ;
case 1:
case 2:
case 3:
case 4:
return 512;
case 5:
case 6:
return 64;
default:
return 0;
}
} else { /* Device is running Full speed */
switch(pipe) {
case 0:
/* DCP max packet size is configurable */
return M66591_DCP_MXPKSZ;
case 1:
case 2:
case 3:
case 4:
return 64;
case 5:
case 6:
return 64;
default:
return 0;
}
}
}
/* This is a helper function that is only called from the interupt handler. It
* copies the control packet information from the PHY and notifies the stack.
*/
static void control_received(void) {
/* copy setup data from packet */
static struct usb_ctrlrequest temp;
memcpy(&temp, (unsigned char*)&M66591_USB_REQ0, 8);
logf("mxx: bReqType=0x%02x bReq=0x%02x wVal=0x%04x"
" wIdx=0x%04x wLen=0x%04x",
temp.bRequestType, temp.bRequest, temp.wValue,
temp.wIndex, temp.wLength);
/* acknowledge packet recieved (clear valid) */
M66591_INTSTAT_MAIN &= ~(1<<3);
usb_core_legacy_control_request(&temp);
}
/* This is a helper function, it is used to notife the stack that a transfer is
* done.
*/
static void transfer_complete(int endpoint) {
M66591_INTCFG_EMP &= ~(1 << endpoint);
logf("mxx: ep %d transfer complete", endpoint);
int temp=M66591_eps[endpoint].dir ? USB_DIR_IN : USB_DIR_OUT;
usb_core_transfer_complete(endpoint, temp, 0,
M66591_eps[endpoint].count);
}
/* This is the main transmit routine that is typically called from the interrupt
* handler (the queue function calls it in some situations)
*/
static int mxx_transmit_receive(int endpoint) {
logf("mxx: do start");
/* Only the lower 15 bits of the endpoint correlate to the pipe number.
* For example pipe 2 will corelate to endpoint 0x82, so the upper bits
* need to be masked out.
*/
endpoint &= 0x7F;
int i; /* Used as a loop counter */
int length; /* Used in transfers to determine the amount to send/receive */
bool send=M66591_eps[endpoint].dir;
/* This is used as the internal buffer pointer */
unsigned short *ptrs;
/* Choose the pipe that data is being transfered on */
pipe_c_select(endpoint, send);
/* Check to see if the endpoint is ready and give it some time to become
* ready. If it runs out of time exit out as an error.
*/
i = 0;
while (!(M66591_CPORT_CTRL1&(1<<13))) {
if (i++ > 100000) {
logf("mxx: FIFO %d not ready", endpoint);
return -1;
}
}
/* Write to FIFO */
if(send) {
int maxpack=pipe_maxpack_size(endpoint);
#if defined(USB_TRAN_BLOCK)
length = M66591_eps[endpoint].length;
#else
int bufsize=pipe_buffer_size(endpoint);
length=MIN(M66591_eps[endpoint].length - M66591_eps[endpoint].count,
bufsize);
#endif
/* Calculate the position in the buffer, all transfers should be 2-byte
* aligned till the last packet or short packet.
*/
ptrs = (unsigned short *)(M66591_eps[endpoint].buf
+ M66591_eps[endpoint].count);
/* Check if the buffer is alligned */
if( LIKELY(((int)ptrs) & 0x01) == 0 )
{
/* Start sending data in 16-bit words (fast) */
for (i = 0; i < (length>>1); i++) {
#if defined(USB_TRAN_BLOCK)
/* This wait is dangerous in the event that something happens
* to the PHY pipe where it never becomes ready again, should
* probably add a timeout, and ideally completely remove.
*/
while(!(M66591_CPORT_CTRL1&(1<<13))){};
#endif
M66591_CPORT = *ptrs++;
M66591_eps[endpoint].count+=2;
}
/* If the length is odd, send the last byte after setting the byte
* width of the FIFO.
*/
if(length & 0x01) {
/* Unset MBW (8-bit transfer) */
M66591_CPORT_CTRL0 &= ~(1<<10);
M66591_CPORT = *((unsigned char *)ptrs);
M66591_eps[endpoint].count++;
}
}
else
{
/* The buffer is mis-aligned - data needs to be organized first.
* This is slower than the above method.
*/
unsigned short sbuf;
unsigned char *ptrc = (unsigned char*)ptrs;
/* Start sending data in 16-bit words */
for (i = 0; i < (length>>1); i++) {
#if defined(USB_TRAN_BLOCK)
/* This wait is dangerous in the event that something happens
* to the PHY pipe where it never becomes ready again, should
* probably add a timeout, and ideally completely remove.
*/
while(!(M66591_CPORT_CTRL1&(1<<13))){};
#endif
/* These are mis-aligned accesses so the data nees to be
* arranged.
*/
sbuf = (*(ptrc+1) << 8) | *ptrc;
ptrc += 2;
M66591_CPORT = sbuf;
M66591_eps[endpoint].count+=2;
}
/* If the length is odd, send the last byte after setting the byte
* width of the FIFO.
*/
if(length & 0x01) {
/* Unset MBW (8-bit transfer) */
M66591_CPORT_CTRL0 &= ~(1<<10);
M66591_CPORT = *ptrc;
M66591_eps[endpoint].count++;
}
}
/* If the transfer is complete set up interrupts to notify when FIFO is
* EMPTY, disable READY and let the handler know that there is nothing
* left to transfer on this pipe.
*/
if(M66591_eps[endpoint].count == M66591_eps[endpoint].length) {
/* Enable Empty flag */
M66591_INTCFG_EMP |= 1 << endpoint;
/* Disable ready flag */
M66591_INTCFG_RDY &= ~(1 << endpoint);
/* Nothing left to transfer */
M66591_eps[endpoint].waiting=false;
} else {
/* There is still data to transfer, make sure READY is enabled */
M66591_INTCFG_RDY |= 1 << endpoint;
}
/* Set BVAL if length is not a multiple of the maximum packet size */
if( (length == 0) || (length % maxpack != 0) ) {
logf("mxx: do set BVAL");
M66591_CPORT_CTRL1 |= (1<<15) | ((length == 0) << 14);
}
} else {
/* Read data from FIFO */
/* Read the number of bytes that the PHY received */
int receive_length=M66591_CPORT_CTRL1 & 0x03FF;
/* The number of bytes to actually read is either what's left of the
* amount requested, or the amount that the PHY received. Choose the
* smaller of the two.
*/
length = MIN(M66591_eps[endpoint].length - M66591_eps[endpoint].count,
receive_length);
/* If the length is zero, just clear the buffer as specified in the
* datasheet. Otherwise read in the data (in 16-bit pieces */
if(length==0) {
/* Set the BCLR bit */
M66591_CPORT_CTRL1 |= 1<<14;
} else {
/* Set the position in the buffer */
ptrs = (unsigned short *)(M66591_eps[endpoint].buf
+ M66591_eps[endpoint].count);
/* Read in the data (buffer size should be even). The PHY cannot
* switch from 16-bit mode to 8-bit mode on an OUT buffer.
*/
for (i = 0; i < ((length+1)>>1); i++) {
*ptrs++ = M66591_CPORT;
M66591_eps[endpoint].count+=2;
}
}
/* If the length was odd subtract 1 from the count */
M66591_eps[endpoint].count -= (length&0x01);
/* If the requested size of data was received, or the data received was
* less than the maximum packet size end the transfer.
*/
if( (M66591_eps[endpoint].count == M66591_eps[endpoint].length)
|| (length % pipe_maxpack_size(endpoint)) ) {
/* If the host tries to send anything else the FIFO is not ready/
* enabled yet (NAK).
*/
pipe_handshake(endpoint, PIPE_SHAKE_NAK);
/* Tell the interrupt handler that transfer is complete. */
M66591_eps[endpoint].waiting=false;
/* Disable ready */
M66591_INTCFG_RDY &= ~(1 << endpoint);
/* Let the stack know that the transfer is complete */
if(endpoint!=0)
transfer_complete(endpoint);
}
}
logf("mxx: do done ep %d %s len: %d cnt: %d", endpoint,
send ? "out" : "in", length, M66591_eps[endpoint].count);
return 0;
}
/* This function is used to start transfers. It is a helper function for the
* usb_drv_send_nonblocking, usb_drv_send, and usb_drv_receive functions.
*
* The functionality for wait needs to be added. Currently the driver is
* always used in a blocking mode(USB_TRAN_BLOCK) so it is not required.
*/
static int mxx_queue(int endpoint, void * ptr, int length, bool send,
bool wait)
{
#if defined(USB_TRAN_BLOCK) && !defined(LOGF_ENABLE)
(void) wait;
#endif
/* Disable IRQs */
int flags = disable_irq_save();
/* Only the lower 15 bits of the endpoint correlate to the pipe number.
* For example pipe 2 will corelate to endpoint 0x82, so the upper bits
* need to be masked out.
*/
endpoint &= 0x7F;
/* Initialize the enpoint status registers used for the transfer */
M66591_eps[endpoint].buf=ptr;
M66591_eps[endpoint].length=length;
M66591_eps[endpoint].count=0;
M66591_eps[endpoint].dir=send;
M66591_eps[endpoint].waiting=true;
logf("mxx: queue ep %d %s, len: %d, wait: %d",
endpoint, send ? "out" : "in", length, wait);
/* Pick the pipe that communications are happening on */
pipe_c_select(endpoint, send);
/* All transfers start with a BUF handshake */
pipe_handshake(endpoint, PIPE_SHAKE_BUF);
/* This USB PHY takes care of control completion packets by setting the
* CCPL bit in EP0 (endpoint 0, or DCP). If the control state is "write no
* data tranfer" then we just need to set the CCPL bit (hopefully)
* regardless of what the stack said to send.
*/
int control_state = (M66591_INTSTAT_MAIN & 0x07);
if(endpoint==0 && control_state==CTRL_WTND) {
logf("mxx: queue ep 0 ctls: 5, set ccpl");
/* Set CCPL */
M66591_DCPCTRL |= 1<<2;
} else {
/* This is the standard case for transmitting data */
if(send) {
/* If the pipe is not ready don't try and send right away; instead
* just set the READY interrupt so that the handler can initiate
* the transfer.
*/
if((M66591_CPORT_CTRL1&(1<<13))) {
mxx_transmit_receive(endpoint);
} else {
M66591_INTCFG_RDY |= 1 << endpoint;
}
if(length==0) {
transfer_complete(endpoint);
}
} else {
/* When receiving data, just enable the ready interrupt, the PHY
* will trigger it and then the reads can start.
*/
M66591_INTCFG_RDY |= 1 << endpoint;
}
}
/* Re-enable IRQs */
restore_irq(flags);
return 0;
}
/*******************************************************************************
* This is the interrupt handler for this driver. It should be called from the
* target interrupt handler routine (eg. GPIO3 on M:Robe 500).
******************************************************************************/
void USB_DEVICE(void) __attribute__ ((section(".icode")));
void USB_DEVICE(void) {
int pipe_restore=M66591_CPORT_CTRL0;
logf("\nmxx: INT BEGIN tick: %d", (int) current_tick);
logf("mxx: sMAIN0: 0x%04x, sRDY: 0x%04x",
M66591_INTSTAT_MAIN, M66591_INTSTAT_RDY);
logf("mxx: sNRDY: 0x%04x, sEMP: 0x%04x",
M66591_INTSTAT_NRDY, M66591_INTSTAT_EMP);
/* VBUS (connected) interrupt */
while ( M66591_INTSTAT_MAIN & (1<<15) ) {
M66591_INTSTAT_MAIN &= ~(1<<15);
/* If device is not clocked, interrupt flag must be set manually */
if ( !(M66591_TRN_CTRL & (1<<10)) ) {
M66591_INTSTAT_MAIN |= (1<<15);
}
}
/* Resume interrupt: This is not used. Extra logic needs to be added similar
* to the VBUS interrupt incase the PHY clock is not running.
*/
if(M66591_INTSTAT_MAIN & (1<<14)) {
M66591_INTSTAT_MAIN &= ~(1<<14);
logf("mxx: RESUME");
}
/* Device state transition interrupt: Not used, but useful for debugging */
if(M66591_INTSTAT_MAIN & (1<<12)) {
M66591_INTSTAT_MAIN &= ~(1<<12);
logf("mxx: DEV state CHANGE=%d",
((M66591_INTSTAT_MAIN & (0x07<<4)) >> 4) );
}
/* Control transfer stage interrupt */
if(M66591_INTSTAT_MAIN & (1<<11)) {
M66591_INTSTAT_MAIN &= ~(1<<11);
int control_state = (M66591_INTSTAT_MAIN & 0x07);
logf("mxx: CTRT with CTSQ=%d", control_state);
switch ( control_state ) {
case CTRL_IDLE:
transfer_complete(0);
break;
case CTRL_RTDS:
case CTRL_WTDS:
case CTRL_WTND:
/* If data is not valid stop */
if(!(M66591_INTSTAT_MAIN & (1<<3)) ) {
logf("mxx: CTRT interrupt but VALID is false");
break;
}
control_received();
break;
case CTRL_RTSS:
case CTRL_WTSS:
pipe_handshake(0, PIPE_SHAKE_BUF);
M66591_DCPCTRL |= 1<<2; /* Set CCPL */
break;
default:
logf("mxx: CTRT with unknown CTSQ");
break;
}
}
/* FIFO EMPTY interrupt: when this happens the transfer should be complete.
* When the interrupt occurs notify the stack.
*/
if(M66591_INTSTAT_MAIN & (1<<10)) {
int i;
logf("mxx: INT EMPTY: 0x%04x", M66591_INTSTAT_EMP);
for(i=0; i<USB_NUM_ENDPOINTS; i++) {
if(M66591_INTSTAT_EMP&(1<<i)) {
/* Clear the empty flag */
M66591_INTSTAT_EMP=~(1<<i);
/* Notify the stack */
transfer_complete(i);
}
}
}
/* FIFO NOT READY interrupt: This is not used, but included incase the
* interrupt is endabled.
*/
if(M66591_INTSTAT_MAIN & (1<<9)) {
logf("mxx: INT NOT READY: 0x%04x", M66591_INTSTAT_NRDY);
M66591_INTSTAT_NRDY = 0;
}
/* FIFO READY interrupt: This just initiates transfers if they are needed */
if(M66591_INTSTAT_MAIN & (1<<8)) {
int i;
logf("mxx: INT READY: 0x%04x", M66591_INTSTAT_RDY);
for(i=0; i<USB_NUM_ENDPOINTS; i++) {
/* Was this endpoint ready and waiting */
if(M66591_INTSTAT_RDY&(1<<i) && M66591_eps[i].waiting) {
/* Clear the ready flag */
M66591_INTSTAT_RDY=~(1<<i);
/* It was ready and waiting so start a transfer */
mxx_transmit_receive(i);
}
}
}
/* Make sure that the INTStatus register is completely cleared. */
M66591_INTSTAT_MAIN = 0;
/* Restore the pipe state before the interrupt occured */
M66591_CPORT_CTRL0=pipe_restore;
logf("mxx: INT END\n");
}
/*******************************************************************************
* The following functions are all called by and visible to the USB stack.
******************************************************************************/
/* The M55691 handles this automatically, nothing to do */
void usb_drv_set_address(int address) {
(void) address;
}
/* This function sets the standard test modes, it is not required, but might as
* well implement it since the hardware supports it
*/
void usb_drv_set_test_mode(int mode) {
/* This sets the test bits and assumes that mode is from 0 to 0x04 */
M66591_TESTMODE &= 0x0007;
M66591_TESTMODE |= mode;
}
/* Request an unused endpoint */
int usb_drv_request_endpoint(int type, int dir) {
int ep;
int pipecfg = 0;
if (type == USB_ENDPOINT_XFER_BULK) {
/* Enable double buffer mode (only used for ep 1 and 2) */
pipecfg |= 1<<9 | 1<<8;
/* Bulk endpoints must be between 1 and 4 inclusive */
ep=1;
while(M66591_eps[ep].busy && ep++<5);
/* If this reached 5 the endpoints were all busy */
if(ep==5) {
logf("mxx: ep %d busy", ep);
return -1;
}
} else if (type == USB_ENDPOINT_XFER_INT) {
ep=5;
pipecfg |= 1<<13;
while(M66591_eps[ep].busy && ++ep<USB_NUM_ENDPOINTS);
/* If this reached USB_NUM_ENDPOINTS the endpoints were all busy */
if(ep==USB_NUM_ENDPOINTS) {
logf("mxx: ep %d busy", ep);
return -1;
}
} else {
/* Not a supported type */
return -1;
}
if (dir == USB_DIR_IN) {
pipecfg |= (1<<4);
}
M66591_eps[ep].busy = true;
M66591_eps[ep].dir = dir;
M66591_PIPE_CFGSEL=ep;
/* Enable pipe (15) */
pipecfg |= 1<<15;
pipe_handshake(ep, PIPE_SHAKE_NAK);
/* Setup the flags */
M66591_PIPE_CFGWND=pipecfg;
pipe_init(ep);
logf("mxx: ep req ep#: %d config: 0x%04x", ep, M66591_PIPE_CFGWND);
return ep | dir;
}
/* Used by stack to tell the helper functions that the pipe is not in use */
void usb_drv_release_endpoint(int ep) {
int flags;
ep &= 0x7f;
if (ep < 1 || ep > USB_NUM_ENDPOINTS || M66591_eps[ep].busy == false)
return ;
flags = disable_irq_save();
logf("mxx: ep %d release", ep);
M66591_eps[ep].busy = false;
M66591_eps[ep].dir = -1;
restore_irq(flags);
}
/* Periodically called to check if a cable was plugged into the device */
inline int usb_detect(void)
{
if(M66591_INTSTAT_MAIN&(1<<7))
return USB_INSERTED;
else
return USB_EXTRACTED;
}
void usb_enable(bool on) {
logf("mxx: %s: %s", __FUNCTION__, on ? "true" : "false");
if (on)
usb_core_init();
else
usb_core_exit();
}
/* This is where the driver stuff starts */
void usb_drv_init(void) {
logf("mxx: Device Init");
M66591_PIN_CFG1 = 0x8000; /* Drive Current: 3.3V setting */
M66591_PIN_CFG2 = 0x0000;
M66591_TRN_CTRL = 0x8000; /* External 48 MHz clock */
M66591_TRN_CTRL |=0x0001;
M66591_INTCFG_MAIN |=0x8000; /* Enable VBUS interrupt */
}
/* fully enable driver */
void usb_attach(void) {
int i;
/* Reset Endpoint states */
for(i=0; i<USB_NUM_ENDPOINTS; i++) {
M66591_eps[i].dir = -1;
M66591_eps[i].buf = (char *) 0;
M66591_eps[i].length = 0;
M66591_eps[i].count = 0;
M66591_eps[i].waiting = false;
M66591_eps[i].busy = false;
}
/* Issue a h/w reset */
usb_init_device();
usb_core_init();
/* USB Attach Process: This follows the flow diagram in the M66591GP
* Reference Manual Rev 1.00, p. 77 */
#if defined(HISPEED)
/* Run Hi-Speed */
M66591_TRN_CTRL |= 1<<7;
#else
/* Run Full-Speed */
M66591_TRN_CTRL &= ~(1<<7);
#endif
/* Enable oscillation buffer XCKE */
M66591_TRN_CTRL |= (1<<13);
udelay(1500);
/* Enable reference clock, PLL RCKE */
M66591_TRN_CTRL |= (3<<11);
udelay(9);
/* Enable internal clock supply SCKE */
M66591_TRN_CTRL |= (1<<10);
/* Disable PIPE ready interrupts */
M66591_INTCFG_RDY = 0;
/* Disable PIPE not-ready interrupts */
M66591_INTCFG_NRDY = 0;
/* Disable PIPE empyt/size error interrupts */
M66591_INTCFG_EMP = 0;
/* Enable all interrupts except NOT READY, RESUME, and VBUS */
M66591_INTCFG_MAIN = 0x1DFF;
pipe_c_select(0, false);
/* Enable continuous transfer mode on the DCP */
M66591_DCP_CNTMD |= (1<<8);
/* Set the threshold that the PHY will automatically transmit from EP0 */
M66591_DCP_CTRLEN = 256;
pipe_handshake(0, PIPE_SHAKE_NAK);
/* Set the Max packet size to 64 */
M66591_DCP_MXPKSZ = 64;
/* Attach notification to PC (D+ pull-up) */
M66591_TRN_CTRL |= (1<<4);
logf("mxx: attached");
}
void usb_drv_exit(void) {
/* USB Detach Process: This follows the flow diagram in the M66591GP
* Reference Manual Rev 1.00, p. 78.
*/
/* Detach notification to PC (disable D+ pull-up) */
M66591_TRN_CTRL &= ~(1<<4);
/* Software reset */
M66591_TRN_CTRL &= ~0x01;
/* Disable internal clock supply */
M66591_TRN_CTRL &= ~(1<<10);
udelay(3);
/* Disable PLL */
M66591_TRN_CTRL &= ~(1<<11);
udelay(3);
/* Disable internal reference clock */
M66591_TRN_CTRL &= ~(1<<12);
udelay(3);
/* Disable oscillation buffer, reenable USB operation */
M66591_TRN_CTRL &= ~(1<<13);
M66591_TRN_CTRL |= 0x01;
logf("mxx: detached");
}
/* This function begins a transmit (on an IN endpoint), it should not block
* so the actual transmit is done in the interrupt handler.
*/
int usb_drv_send_nonblocking(int endpoint, void* ptr, int length)
{
return mxx_queue(endpoint, ptr, length, true, false);
}
/* This function begins a transmit (on an IN endpoint), it does not block
* so the actual transmit is done in the interrupt handler.
*/
int usb_drv_send(int endpoint, void* ptr, int length)
{
return mxx_queue(endpoint, ptr, length, true, true);
}
/* This function begins a receive (on an OUT endpoint), it should not block
* so the actual receive is done in the interrupt handler.
*/
int usb_drv_recv_nonblocking(int endpoint, void* ptr, int length)
{
return mxx_queue(endpoint, ptr, length, false, false);
}
/* This function checks the reset handshake speed status
* (Fullspeed or Highspeed)
*/
int usb_drv_port_speed(void)
{
int handshake = (M66591_HSFS & 0xFF);
if( handshake == 0x02) {
return 0; /* Handshook at Full-Speed */
} else if( handshake == 0x03) {
return 1; /* Handshook at Hi-Speed */
} else {
return -1; /* Error, handshake may not be complete */
}
}
/* This function checks if the endpoint is stalled (error). I am not sure what
* the "in" variable is intended for.
*/
bool usb_drv_stalled(int endpoint,bool in)
{
(void) in;
bool stalled = (*(pipe_ctrl_addr(endpoint)) & (0x02)) ? true : false;
logf("mxx: stall?: %s ep: %d", stalled ? "true" : "false", endpoint);
if(stalled) {
return true;
} else {
return false;
}
}
/* This function stalls/unstalls the endpoint. Stalls only happen on error so
* if the endpoint is functioning properly this should not be called. I am
* not sure what the "in" variable is intended for.
*/
void usb_drv_stall(int endpoint, bool stall,bool in)
{
(void) in;
logf("mxx: stall - ep: %d", endpoint);
if(stall) {
/* Stall the pipe (host needs to intervene/error) */
pipe_handshake(endpoint, PIPE_SHAKE_STALL);
} else {
/* Setting this to a NAK, not sure if it is appropriate */
pipe_handshake(endpoint, PIPE_SHAKE_NAK);
}
}
/* !!!!!!!!!!This function is likely incomplete!!!!!!!!!!!!!! */
void usb_drv_cancel_all_transfers(void)
{
int endpoint;
int flags;
logf("mxx: %s", __func__);
flags = disable_irq_save();
for (endpoint = 0; endpoint < USB_NUM_ENDPOINTS; endpoint++) {
if (M66591_eps[endpoint].buf) {
M66591_eps[endpoint].buf = NULL;
}
}
restore_irq(flags);
}