usbtest/libopencm3/lib/usb/usb_dwc_common.c
Arti Zirk 244fdbc35c git subrepo clone https://github.com/libopencm3/libopencm3
subrepo:
  subdir:   "libopencm3"
  merged:   "f5813a54"
upstream:
  origin:   "https://github.com/libopencm3/libopencm3"
  branch:   "master"
  commit:   "f5813a54"
git-subrepo:
  version:  "0.4.3"
  origin:   "???"
  commit:   "???"
2021-09-30 16:34:10 +03:00

449 lines
12 KiB
C

/*
* This file is part of the libopencm3 project.
*
* Copyright (C) 2011 Gareth McMullin <gareth@blacksphere.co.nz>
*
* This library is free software: you can redistribute it and/or modify
* it under the terms of the GNU Lesser General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public License
* along with this library. If not, see <http://www.gnu.org/licenses/>.
*/
#include <string.h>
#include <libopencm3/cm3/common.h>
#include <libopencm3/usb/usbd.h>
#include <libopencm3/usb/dwc/otg_common.h>
#include "usb_private.h"
#include "usb_dwc_common.h"
/* The FS core and the HS core have the same register layout.
* As the code can be used on both cores, the registers offset is modified
* according to the selected cores base address. */
#define dev_base_address (usbd_dev->driver->base_address)
#define REBASE(x) MMIO32((x) + (dev_base_address))
void dwc_set_address(usbd_device *usbd_dev, uint8_t addr)
{
REBASE(OTG_DCFG) = (REBASE(OTG_DCFG) & ~OTG_DCFG_DAD) | (addr << 4);
}
void dwc_ep_setup(usbd_device *usbd_dev, uint8_t addr, uint8_t type,
uint16_t max_size,
void (*callback) (usbd_device *usbd_dev, uint8_t ep))
{
/*
* Configure endpoint address and type. Allocate FIFO memory for
* endpoint. Install callback function.
*/
uint8_t dir = addr & 0x80;
addr &= 0x7f;
if (addr == 0) { /* For the default control endpoint */
/* Configure IN part. */
if (max_size >= 64) {
REBASE(OTG_DIEPCTL0) = OTG_DIEPCTL0_MPSIZ_64;
} else if (max_size >= 32) {
REBASE(OTG_DIEPCTL0) = OTG_DIEPCTL0_MPSIZ_32;
} else if (max_size >= 16) {
REBASE(OTG_DIEPCTL0) = OTG_DIEPCTL0_MPSIZ_16;
} else {
REBASE(OTG_DIEPCTL0) = OTG_DIEPCTL0_MPSIZ_8;
}
REBASE(OTG_DIEPTSIZ0) =
(max_size & OTG_DIEPSIZ0_XFRSIZ_MASK);
REBASE(OTG_DIEPCTL0) |=
OTG_DIEPCTL0_EPENA | OTG_DIEPCTL0_SNAK;
/* Configure OUT part. */
usbd_dev->doeptsiz[0] = OTG_DIEPSIZ0_STUPCNT_1 |
OTG_DIEPSIZ0_PKTCNT |
(max_size & OTG_DIEPSIZ0_XFRSIZ_MASK);
REBASE(OTG_DOEPTSIZ(0)) = usbd_dev->doeptsiz[0];
REBASE(OTG_DOEPCTL(0)) |=
OTG_DOEPCTL0_EPENA | OTG_DIEPCTL0_SNAK;
REBASE(OTG_GNPTXFSIZ) = ((max_size / 4) << 16) |
usbd_dev->driver->rx_fifo_size;
usbd_dev->fifo_mem_top += max_size / 4;
usbd_dev->fifo_mem_top_ep0 = usbd_dev->fifo_mem_top;
return;
}
if (dir) {
REBASE(OTG_DIEPTXF(addr)) = ((max_size / 4) << 16) |
usbd_dev->fifo_mem_top;
usbd_dev->fifo_mem_top += max_size / 4;
REBASE(OTG_DIEPTSIZ(addr)) =
(max_size & OTG_DIEPSIZ0_XFRSIZ_MASK);
REBASE(OTG_DIEPCTL(addr)) |=
OTG_DIEPCTL0_EPENA | OTG_DIEPCTL0_SNAK | (type << 18)
| OTG_DIEPCTL0_USBAEP | OTG_DIEPCTLX_SD0PID
| (addr << 22) | max_size;
if (callback) {
usbd_dev->user_callback_ctr[addr][USB_TRANSACTION_IN] =
(void *)callback;
}
}
if (!dir) {
usbd_dev->doeptsiz[addr] = OTG_DIEPSIZ0_PKTCNT |
(max_size & OTG_DIEPSIZ0_XFRSIZ_MASK);
REBASE(OTG_DOEPTSIZ(addr)) = usbd_dev->doeptsiz[addr];
REBASE(OTG_DOEPCTL(addr)) |= OTG_DOEPCTL0_EPENA |
OTG_DOEPCTL0_USBAEP | OTG_DIEPCTL0_CNAK |
OTG_DOEPCTLX_SD0PID | (type << 18) | max_size;
if (callback) {
usbd_dev->user_callback_ctr[addr][USB_TRANSACTION_OUT] =
(void *)callback;
}
}
}
void dwc_endpoints_reset(usbd_device *usbd_dev)
{
int i;
/* The core resets the endpoints automatically on reset. */
usbd_dev->fifo_mem_top = usbd_dev->fifo_mem_top_ep0;
/* Disable any currently active endpoints */
for (i = 1; i < 4; i++) {
if (REBASE(OTG_DOEPCTL(i)) & OTG_DOEPCTL0_EPENA) {
REBASE(OTG_DOEPCTL(i)) |= OTG_DOEPCTL0_EPDIS;
}
if (REBASE(OTG_DIEPCTL(i)) & OTG_DIEPCTL0_EPENA) {
REBASE(OTG_DIEPCTL(i)) |= OTG_DIEPCTL0_EPDIS;
}
}
/* Flush all tx/rx fifos */
REBASE(OTG_GRSTCTL) = OTG_GRSTCTL_TXFFLSH | OTG_GRSTCTL_TXFNUM_ALL
| OTG_GRSTCTL_RXFFLSH;
}
void dwc_ep_stall_set(usbd_device *usbd_dev, uint8_t addr, uint8_t stall)
{
if (addr == 0) {
if (stall) {
REBASE(OTG_DIEPCTL(addr)) |= OTG_DIEPCTL0_STALL;
} else {
REBASE(OTG_DIEPCTL(addr)) &= ~OTG_DIEPCTL0_STALL;
}
}
if (addr & 0x80) {
addr &= 0x7F;
if (stall) {
REBASE(OTG_DIEPCTL(addr)) |= OTG_DIEPCTL0_STALL;
} else {
REBASE(OTG_DIEPCTL(addr)) &= ~OTG_DIEPCTL0_STALL;
REBASE(OTG_DIEPCTL(addr)) |= OTG_DIEPCTLX_SD0PID;
}
} else {
if (stall) {
REBASE(OTG_DOEPCTL(addr)) |= OTG_DOEPCTL0_STALL;
} else {
REBASE(OTG_DOEPCTL(addr)) &= ~OTG_DOEPCTL0_STALL;
REBASE(OTG_DOEPCTL(addr)) |= OTG_DOEPCTLX_SD0PID;
}
}
}
uint8_t dwc_ep_stall_get(usbd_device *usbd_dev, uint8_t addr)
{
/* Return non-zero if STALL set. */
if (addr & 0x80) {
return (REBASE(OTG_DIEPCTL(addr & 0x7f)) &
OTG_DIEPCTL0_STALL) ? 1 : 0;
} else {
return (REBASE(OTG_DOEPCTL(addr)) &
OTG_DOEPCTL0_STALL) ? 1 : 0;
}
}
void dwc_ep_nak_set(usbd_device *usbd_dev, uint8_t addr, uint8_t nak)
{
/* It does not make sense to force NAK on IN endpoints. */
if (addr & 0x80) {
return;
}
usbd_dev->force_nak[addr] = nak;
if (nak) {
REBASE(OTG_DOEPCTL(addr)) |= OTG_DOEPCTL0_SNAK;
} else {
REBASE(OTG_DOEPCTL(addr)) |= OTG_DOEPCTL0_CNAK;
}
}
uint16_t dwc_ep_write_packet(usbd_device *usbd_dev, uint8_t addr,
const void *buf, uint16_t len)
{
const uint32_t *buf32 = buf;
#if defined(__ARM_ARCH_6M__)
const uint8_t *buf8 = buf;
uint32_t word32;
#endif /* defined(__ARM_ARCH_6M__) */
int i;
addr &= 0x7F;
/* Return if endpoint is already enabled. */
if (REBASE(OTG_DIEPTSIZ(addr)) & OTG_DIEPSIZ0_PKTCNT) {
return 0;
}
/* Enable endpoint for transmission. */
REBASE(OTG_DIEPTSIZ(addr)) = OTG_DIEPSIZ0_PKTCNT | len;
REBASE(OTG_DIEPCTL(addr)) |= OTG_DIEPCTL0_EPENA |
OTG_DIEPCTL0_CNAK;
/* Copy buffer to endpoint FIFO, note - memcpy does not work.
* ARMv7M supports non-word-aligned accesses, ARMv6M does not. */
#if defined(__ARM_ARCH_7M__) || defined(__ARM_ARCH_7EM__)
for (i = len; i > 0; i -= 4) {
REBASE(OTG_FIFO(addr)) = *buf32++;
}
#endif /* defined(__ARM_ARCH_7M__) || defined(__ARM_ARCH_7EM__) */
#if defined(__ARM_ARCH_6M__)
/* Take care of word-aligned and non-word-aligned buffers */
if (((uint32_t)buf8 & 0x3) == 0) {
for (i = len; i > 0; i -= 4) {
REBASE(OTG_FIFO(addr)) = *buf32++;
}
} else {
for (i = len; i > 0; i -= 4) {
memcpy(&word32, buf8, 4);
REBASE(OTG_FIFO(addr)) = word32;
buf8 += 4;
}
}
#endif /* defined(__ARM_ARCH_6M__) */
return len;
}
uint16_t dwc_ep_read_packet(usbd_device *usbd_dev, uint8_t addr,
void *buf, uint16_t len)
{
int i;
uint32_t *buf32 = buf;
#if defined(__ARM_ARCH_6M__)
uint8_t *buf8 = buf;
uint32_t word32;
#endif /* defined(__ARM_ARCH_6M__) */
uint32_t extra;
/* We do not need to know the endpoint address since there is only one
* receive FIFO for all endpoints.
*/
(void) addr;
len = MIN(len, usbd_dev->rxbcnt);
/* ARMv7M supports non-word-aligned accesses, ARMv6M does not. */
#if defined(__ARM_ARCH_7M__) || defined(__ARM_ARCH_7EM__)
for (i = len; i >= 4; i -= 4) {
*buf32++ = REBASE(OTG_FIFO(0));
usbd_dev->rxbcnt -= 4;
}
#endif /* defined(__ARM_ARCH_7M__) || defined(__ARM_ARCH_7EM__) */
#if defined(__ARM_ARCH_6M__)
/* Take care of word-aligned and non-word-aligned buffers */
if (((uint32_t)buf8 & 0x3) == 0) {
for (i = len; i >= 4; i -= 4) {
*buf32++ = REBASE(OTG_FIFO(0));
usbd_dev->rxbcnt -= 4;
}
} else {
for (i = len; i >= 4; i -= 4) {
word32 = REBASE(OTG_FIFO(0));
memcpy(buf8, &word32, 4);
usbd_dev->rxbcnt -= 4;
buf8 += 4;
}
/* buf32 needs to be updated as it is used for extra */
buf32 = (uint32_t *)buf8;
}
#endif /* defined(__ARM_ARCH_6M__) */
if (i) {
extra = REBASE(OTG_FIFO(0));
/* we read 4 bytes from the fifo, so update rxbcnt */
if (usbd_dev->rxbcnt < 4) {
/* Be careful not to underflow (rxbcnt is unsigned) */
usbd_dev->rxbcnt = 0;
} else {
usbd_dev->rxbcnt -= 4;
}
memcpy(buf32, &extra, i);
}
return len;
}
static void dwc_flush_txfifo(usbd_device *usbd_dev, int ep)
{
uint32_t fifo;
/* set IN endpoint NAK */
REBASE(OTG_DIEPCTL(ep)) |= OTG_DIEPCTL0_SNAK;
/* wait for core to respond */
while (!(REBASE(OTG_DIEPINT(ep)) & OTG_DIEPINTX_INEPNE)) {
/* idle */
}
/* get fifo for this endpoint */
fifo = (REBASE(OTG_DIEPCTL(ep)) & OTG_DIEPCTL0_TXFNUM_MASK) >> 22;
/* wait for core to idle */
while (!(REBASE(OTG_GRSTCTL) & OTG_GRSTCTL_AHBIDL)) {
/* idle */
}
/* flush tx fifo */
REBASE(OTG_GRSTCTL) = (fifo << 6) | OTG_GRSTCTL_TXFFLSH;
/* reset packet counter */
REBASE(OTG_DIEPTSIZ(ep)) = 0;
while ((REBASE(OTG_GRSTCTL) & OTG_GRSTCTL_TXFFLSH)) {
/* idle */
}
}
void dwc_poll(usbd_device *usbd_dev)
{
/* Read interrupt status register. */
uint32_t intsts = REBASE(OTG_GINTSTS);
int i;
if (intsts & OTG_GINTSTS_ENUMDNE) {
/* Handle USB RESET condition. */
REBASE(OTG_GINTSTS) = OTG_GINTSTS_ENUMDNE;
usbd_dev->fifo_mem_top = usbd_dev->driver->rx_fifo_size;
_usbd_reset(usbd_dev);
return;
}
/*
* There is no global interrupt flag for transmit complete.
* The XFRC bit must be checked in each OTG_DIEPINT(x).
*/
for (i = 0; i < 4; i++) { /* Iterate over endpoints. */
if (REBASE(OTG_DIEPINT(i)) & OTG_DIEPINTX_XFRC) {
/* Transfer complete. */
if (usbd_dev->user_callback_ctr[i]
[USB_TRANSACTION_IN]) {
usbd_dev->user_callback_ctr[i]
[USB_TRANSACTION_IN](usbd_dev, i);
}
REBASE(OTG_DIEPINT(i)) = OTG_DIEPINTX_XFRC;
}
}
/* Note: RX and TX handled differently in this device. */
if (intsts & OTG_GINTSTS_RXFLVL) {
/* Receive FIFO non-empty. */
uint32_t rxstsp = REBASE(OTG_GRXSTSP);
uint32_t pktsts = rxstsp & OTG_GRXSTSP_PKTSTS_MASK;
uint8_t ep = rxstsp & OTG_GRXSTSP_EPNUM_MASK;
if (pktsts == OTG_GRXSTSP_PKTSTS_SETUP_COMP) {
usbd_dev->user_callback_ctr[ep][USB_TRANSACTION_SETUP] (usbd_dev, ep);
}
if (pktsts == OTG_GRXSTSP_PKTSTS_OUT_COMP
|| pktsts == OTG_GRXSTSP_PKTSTS_SETUP_COMP) {
REBASE(OTG_DOEPTSIZ(ep)) = usbd_dev->doeptsiz[ep];
REBASE(OTG_DOEPCTL(ep)) |= OTG_DOEPCTL0_EPENA |
(usbd_dev->force_nak[ep] ?
OTG_DOEPCTL0_SNAK : OTG_DOEPCTL0_CNAK);
return;
}
if ((pktsts != OTG_GRXSTSP_PKTSTS_OUT) &&
(pktsts != OTG_GRXSTSP_PKTSTS_SETUP)) {
return;
}
uint8_t type;
if (pktsts == OTG_GRXSTSP_PKTSTS_SETUP) {
type = USB_TRANSACTION_SETUP;
} else {
type = USB_TRANSACTION_OUT;
}
if (type == USB_TRANSACTION_SETUP
&& (REBASE(OTG_DIEPTSIZ(ep)) & OTG_DIEPSIZ0_PKTCNT)) {
/* SETUP received but there is still something stuck
* in the transmit fifo. Flush it.
*/
dwc_flush_txfifo(usbd_dev, ep);
}
/* Save packet size for dwc_ep_read_packet(). */
usbd_dev->rxbcnt = (rxstsp & OTG_GRXSTSP_BCNT_MASK) >> 4;
if (type == USB_TRANSACTION_SETUP) {
dwc_ep_read_packet(usbd_dev, ep, &usbd_dev->control_state.req, 8);
} else if (usbd_dev->user_callback_ctr[ep][type]) {
usbd_dev->user_callback_ctr[ep][type] (usbd_dev, ep);
}
/* Discard unread packet data. */
for (i = 0; i < usbd_dev->rxbcnt; i += 4) {
/* There is only one receive FIFO, so use OTG_FIFO(0) */
(void)REBASE(OTG_FIFO(0));
}
usbd_dev->rxbcnt = 0;
}
if (intsts & OTG_GINTSTS_USBSUSP) {
if (usbd_dev->user_callback_suspend) {
usbd_dev->user_callback_suspend();
}
REBASE(OTG_GINTSTS) = OTG_GINTSTS_USBSUSP;
}
if (intsts & OTG_GINTSTS_WKUPINT) {
if (usbd_dev->user_callback_resume) {
usbd_dev->user_callback_resume();
}
REBASE(OTG_GINTSTS) = OTG_GINTSTS_WKUPINT;
}
if (intsts & OTG_GINTSTS_SOF) {
if (usbd_dev->user_callback_sof) {
usbd_dev->user_callback_sof();
}
REBASE(OTG_GINTSTS) = OTG_GINTSTS_SOF;
}
if (usbd_dev->user_callback_sof) {
REBASE(OTG_GINTMSK) |= OTG_GINTMSK_SOFM;
} else {
REBASE(OTG_GINTMSK) &= ~OTG_GINTMSK_SOFM;
}
}
void dwc_disconnect(usbd_device *usbd_dev, bool disconnected)
{
if (disconnected) {
REBASE(OTG_DCTL) |= OTG_DCTL_SDIS;
} else {
REBASE(OTG_DCTL) &= ~OTG_DCTL_SDIS;
}
}