m4_init/3rd/libopencm3/lib/usb/usb_lm4f.c

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2023-02-02 16:50:31 +00:00
/*
* This file is part of the libopencm3 project.
*
* Copyright (C) 2013 Alexandru Gagniuc <mr.nuke.me@gmail.com>
*
* 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/>.
*/
/**
* @defgroup usb_file USB
*
* @ingroup LM4Fxx
*
* @author @htmlonly &copy; @endhtmlonly 2013
* Alexandru Gagniuc <mr.nuke.me@gmail.com>
*
* \brief <b>libopencm3 LM4F Universal Serial Bus controller </b>
*
* The LM4F USB driver is integrated with the libopencm3 USB stack. You should
* use the generic stack.
*
* To use this driver, tell the linker to look for it:
* @code{.c}
* extern usbd_driver lm4f_usb_driver;
* @endcode
*
* And pass this driver as an argument when initializing the USB stack:
* @code{.c}
* usbd_device *usbd_dev;
* usbd_dev = usbd_init(&lm4f_usb_driver, ...);
* @endcode
*
* <b>Polling or interrupt-driven? </b>
*
* The LM4F USB driver will work fine regardless of whether it is called from an
* interrupt service routine, or from the main program loop.
*
* Polling USB from the main loop requires calling @ref usbd_poll() from the
* main program loop.
* For example:
* @code{.c}
* // Main program loop
* while(1) {
* usbd_poll(usb_dev);
* do_other_stuff();
* ...
* @endcode
*
* Running @ref usbd_poll() from an interrupt has the advantage that it is only
* called when needed, saving CPU cycles for the main program.
*
* RESET, DISCON, RESUME, and SUSPEND interrupts must be enabled, along with the
* interrupts for any endpoint that is used. The EP0_TX interrupt must be
* enabled for the control endpoint to function correctly.
* For example, if EP1IN and EP2OUT are used, then the EP0_TX, EP1_TX, and
* EP2_RX interrupts should be enabled:
* @code{.c}
* // Enable USB interrupts for EP0, EP1IN, and EP2OUT
* ints = USB_INT_RESET | USB_INT_DISCON | USB_INT_RESUME |
* USB_INT_SUSPEND;
* usb_enable_interrupts(ints, USB_EP2_INT, USB_EP0_INT | USB_EP1_INT);
* // Route the interrupts through the NVIC
* nvic_enable_irq(NVIC_USB0_IRQ);
* @endcode
*
* The USB ISR only has to call @ref usbd_poll().
*
* @code{.c}
* void usb0_isr(void)
* {
* usbd_poll(usb_dev);
* }
* @endcode
* @{
*/
/*
* TODO list:
*
* 1) Driver works by reading and writing to the FIFOs one byte at a time. It
* has no knowledge of DMA.
* 2) Double-buffering is supported. How can we take advantage of it to speed
* up endpoint transfers.
* 3) No benchmarks as to the endpoint's performance has been done.
*/
/*
* The following are resources referenced in comments:
* [1] http://e2e.ti.com/support/microcontrollers/tiva_arm/f/908/t/238784.aspx
*/
#include <libopencm3/cm3/common.h>
#include <libopencm3/lm4f/usb.h>
#include <libopencm3/lm4f/rcc.h>
#include <libopencm3/usb/usbd.h>
#include "../../lib/usb/usb_private.h"
#include <stdbool.h>
#define MAX_FIFO_RAM (4 * 1024)
const struct _usbd_driver lm4f_usb_driver;
/**
* \brief Enable Specific USB Interrupts
*
* Enable any combination of interrupts. Interrupts may be OR'ed together to
* enable them with one call. For example, to enable both the RESUME and RESET
* interrupts, pass (USB_INT_RESUME | USB_INT_RESET)
*
* Note that the NVIC must be enabled and properly configured for the interrupt
* to be routed to the CPU.
*
* @param[in] ints Interrupts which to enable. Any combination of interrupts may
* be specified by OR'ing then together
* @param[in] rx_ints Endpoints for which to generate an interrupt when a packet
* packet is received.
* @param[in] tx_ints Endpoints for which to generate an interrupt when a packet
* packet is finished transmitting.
*/
void usb_enable_interrupts(enum usb_interrupt ints,
enum usb_ep_interrupt rx_ints,
enum usb_ep_interrupt tx_ints)
{
USB_IE |= ints;
USB_RXIE |= rx_ints;
USB_TXIE |= tx_ints;
}
/**
* \brief Disable Specific USB Interrupts
*
* Disable any combination of interrupts. Interrupts may be OR'ed together to
* enable them with one call. For example, to disable both the RESUME and RESET
* interrupts, pass (USB_INT_RESUME | USB_INT_RESET)
*
* Note that the NVIC must be enabled and properly configured for the interrupt
* to be routed to the CPU.
*
* @param[in] ints Interrupts which to disable. Any combination of interrupts
* may be specified by OR'ing then together
* @param[in] rx_ints Endpoints for which to stop generating an interrupt when a
* packet packet is received.
* @param[in] tx_ints Endpoints for which to stop generating an interrupt when a
* packet packet is finished transmitting.
*/
void usb_disable_interrupts(enum usb_interrupt ints,
enum usb_ep_interrupt rx_ints,
enum usb_ep_interrupt tx_ints)
{
USB_IE &= ~ints;
USB_RXIE &= ~rx_ints;
USB_TXIE &= ~tx_ints;
}
/**
* @cond private
*/
static inline void lm4f_usb_soft_disconnect(void)
{
USB_POWER &= ~USB_POWER_SOFTCONN;
}
static inline void lm4f_usb_soft_connect(void)
{
USB_POWER |= USB_POWER_SOFTCONN;
}
static void lm4f_set_address(usbd_device *usbd_dev, uint8_t addr)
{
(void)usbd_dev;
USB_FADDR = addr & USB_FADDR_FUNCADDR_MASK;
}
static void lm4f_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))
{
(void)usbd_dev;
(void)type;
uint8_t reg8;
uint16_t fifo_size;
const bool dir_tx = addr & 0x80;
const uint8_t ep = addr & 0x0f;
/*
* We do not mess with the maximum packet size, but we can only allocate
* the FIFO in power-of-two increments.
*/
if (max_size > 1024) {
fifo_size = 2048;
reg8 = USB_FIFOSZ_SIZE_2048;
} else if (max_size > 512) {
fifo_size = 1024;
reg8 = USB_FIFOSZ_SIZE_1024;
} else if (max_size > 256) {
fifo_size = 512;
reg8 = USB_FIFOSZ_SIZE_512;
} else if (max_size > 128) {
fifo_size = 256;
reg8 = USB_FIFOSZ_SIZE_256;
} else if (max_size > 64) {
fifo_size = 128;
reg8 = USB_FIFOSZ_SIZE_128;
} else if (max_size > 32) {
fifo_size = 64;
reg8 = USB_FIFOSZ_SIZE_64;
} else if (max_size > 16) {
fifo_size = 32;
reg8 = USB_FIFOSZ_SIZE_32;
} else if (max_size > 8) {
fifo_size = 16;
reg8 = USB_FIFOSZ_SIZE_16;
} else {
fifo_size = 8;
reg8 = USB_FIFOSZ_SIZE_8;
}
/* Endpoint 0 is more special */
if (addr == 0) {
USB_EPIDX = 0;
if (reg8 > USB_FIFOSZ_SIZE_64) {
reg8 = USB_FIFOSZ_SIZE_64;
}
/* The RX and TX FIFOs are shared for EP0 */
USB_RXFIFOSZ = reg8;
USB_TXFIFOSZ = reg8;
/*
* Regardless of how much we allocate, the first 64 bytes
* are always reserved for EP0.
*/
usbd_dev->fifo_mem_top_ep0 = 64;
return;
}
/* Are we out of FIFO space? */
if (usbd_dev->fifo_mem_top + fifo_size > MAX_FIFO_RAM) {
return;
}
USB_EPIDX = addr & USB_EPIDX_MASK;
/* FIXME: What about double buffering? */
if (dir_tx) {
USB_TXMAXP(ep) = max_size;
USB_TXFIFOSZ = reg8;
USB_TXFIFOADD = ((usbd_dev->fifo_mem_top) >> 3);
if (callback) {
usbd_dev->user_callback_ctr[ep][USB_TRANSACTION_IN] =
(void *)callback;
}
if (type == USB_ENDPOINT_ATTR_ISOCHRONOUS) {
USB_TXCSRH(ep) |= USB_TXCSRH_ISO;
} else {
USB_TXCSRH(ep) &= ~USB_TXCSRH_ISO;
}
} else {
USB_RXMAXP(ep) = max_size;
USB_RXFIFOSZ = reg8;
USB_RXFIFOADD = ((usbd_dev->fifo_mem_top) >> 3);
if (callback) {
usbd_dev->user_callback_ctr[ep][USB_TRANSACTION_OUT] =
(void *)callback;
}
if (type == USB_ENDPOINT_ATTR_ISOCHRONOUS) {
USB_RXCSRH(ep) |= USB_RXCSRH_ISO;
} else {
USB_RXCSRH(ep) &= ~USB_RXCSRH_ISO;
}
}
usbd_dev->fifo_mem_top += fifo_size;
}
static void lm4f_endpoints_reset(usbd_device *usbd_dev)
{
/*
* The core resets the endpoints automatically on reset.
* The first 64 bytes are always reserved for EP0
*/
usbd_dev->fifo_mem_top = 64;
}
static void lm4f_ep_stall_set(usbd_device *usbd_dev, uint8_t addr,
uint8_t stall)
{
(void)usbd_dev;
const uint8_t ep = addr & 0x0f;
const bool dir_tx = addr & 0x80;
if (ep == 0) {
if (stall) {
USB_CSRL0 |= USB_CSRL0_STALL;
} else {
USB_CSRL0 &= ~USB_CSRL0_STALL;
}
return;
}
if (dir_tx) {
if (stall) {
(USB_TXCSRL(ep)) |= USB_TXCSRL_STALL;
} else {
(USB_TXCSRL(ep)) &= ~USB_TXCSRL_STALL;
}
} else {
if (stall) {
(USB_RXCSRL(ep)) |= USB_RXCSRL_STALL;
} else {
(USB_RXCSRL(ep)) &= ~USB_RXCSRL_STALL;
}
}
}
static uint8_t lm4f_ep_stall_get(usbd_device *usbd_dev, uint8_t addr)
{
(void)usbd_dev;
const uint8_t ep = addr & 0x0f;
const bool dir_tx = addr & 0x80;
if (ep == 0) {
return USB_CSRL0 & USB_CSRL0_STALLED;
}
if (dir_tx) {
return USB_TXCSRL(ep) & USB_TXCSRL_STALLED;
} else {
return USB_RXCSRL(ep) & USB_RXCSRL_STALLED;
}
}
static void lm4f_ep_nak_set(usbd_device *usbd_dev, uint8_t addr, uint8_t nak)
{
(void)usbd_dev;
(void)addr;
(void)nak;
/* NAK's are handled automatically by hardware. Move along. */
}
static uint16_t lm4f_ep_write_packet(usbd_device *usbd_dev, uint8_t addr,
const void *buf, uint16_t len)
{
const uint8_t ep = addr & 0xf;
uint16_t i;
(void)usbd_dev;
/* Don't touch the FIFO if there is still a packet being transmitted */
if (ep == 0 && (USB_CSRL0 & USB_CSRL0_TXRDY)) {
return 0;
} else if (USB_TXCSRL(ep) & USB_TXCSRL_TXRDY) {
return 0;
}
/*
* We don't need to worry about buf not being aligned. If it's not,
* the reads are downgraded to 8-bit in hardware. We lose a bit of
* performance, but we don't crash.
*/
for (i = 0; i < (len & ~0x3); i += 4) {
USB_FIFO32(ep) = *((uint32_t *)(buf + i));
}
if (len & 0x2) {
USB_FIFO16(ep) = *((uint16_t *)(buf + i));
i += 2;
}
if (len & 0x1) {
USB_FIFO8(ep) = *((uint8_t *)(buf + i));
i += 1;
}
if (ep == 0) {
/*
* EP0 is very special. We should only set DATAEND when we
* transmit the last packet in the transaction. A transaction
* that is a multiple of 64 bytes will end with a zero-length
* packet, so our check is sane.
*/
if (len != 64) {
USB_CSRL0 |= USB_CSRL0_TXRDY | USB_CSRL0_DATAEND;
} else {
USB_CSRL0 |= USB_CSRL0_TXRDY;
}
} else {
USB_TXCSRL(ep) |= USB_TXCSRL_TXRDY;
}
return i;
}
static uint16_t lm4f_ep_read_packet(usbd_device *usbd_dev, uint8_t addr,
void *buf, uint16_t len)
{
(void)usbd_dev;
uint16_t rlen;
uint8_t ep = addr & 0xf;
uint16_t fifoin = USB_RXCOUNT(ep);
rlen = (fifoin > len) ? len : fifoin;
/*
* We don't need to worry about buf not being aligned. If it's not,
* the writes are downgraded to 8-bit in hardware. We lose a bit of
* performance, but we don't crash.
*/
for (len = 0; len < (rlen & ~0x3); len += 4) {
*((uint32_t *)(buf + len)) = USB_FIFO32(ep);
}
if (rlen & 0x2) {
*((uint16_t *)(buf + len)) = USB_FIFO16(ep);
len += 2;
}
if (rlen & 0x1) {
*((uint8_t *)(buf + len)) = USB_FIFO8(ep);
}
if (ep == 0) {
/*
* Clear RXRDY
* Datasheet says that DATAEND must also be set when clearing
* RXRDY. We don't do that. If did this when transmitting a
* packet larger than 64 bytes, only the first 64 bytes would
* be transmitted, followed by a handshake. The host would only
* get 64 bytes, seeing it as a malformed packet. Usually, we
* would not get past enumeration.
*/
USB_CSRL0 |= USB_CSRL0_RXRDYC;
} else {
USB_RXCSRL(ep) &= ~USB_RXCSRL_RXRDY;
}
return rlen;
}
static void lm4f_poll(usbd_device *usbd_dev)
{
void (*tx_cb)(usbd_device *usbd_dev, uint8_t ea);
void (*rx_cb)(usbd_device *usbd_dev, uint8_t ea);
int i;
/*
* The initial state of these registers might change, as we process the
* interrupt, but we need the initial state in order to decide how to
* handle events.
*/
const uint8_t usb_is = USB_IS;
const uint8_t usb_rxis = USB_RXIS;
const uint8_t usb_txis = USB_TXIS;
const uint8_t usb_csrl0 = USB_CSRL0;
if ((usb_is & USB_IM_SUSPEND) && (usbd_dev->user_callback_suspend)) {
usbd_dev->user_callback_suspend();
}
if ((usb_is & USB_IM_RESUME) && (usbd_dev->user_callback_resume)) {
usbd_dev->user_callback_resume();
}
if (usb_is & USB_IM_RESET) {
_usbd_reset(usbd_dev);
}
if ((usb_is & USB_IM_SOF) && (usbd_dev->user_callback_sof)) {
usbd_dev->user_callback_sof();
}
if (usb_txis & USB_EP0) {
/*
* The EP0 bit in USB_TXIS is special. It tells us that
* something happened on EP0, but does not tell us what. This
* bit does not necessarily tell us that a packet was
* transmitted, so we have to go through all the possibilities
* to figure out exactly what did. Only after we've exhausted
* all other possibilities, can we assume this is a EPO
* "transmit complete" interrupt.
*/
if (usb_csrl0 & USB_CSRL0_RXRDY) {
enum _usbd_transaction type;
type = (usbd_dev->control_state.state != DATA_OUT &&
usbd_dev->control_state.state != LAST_DATA_OUT)
? USB_TRANSACTION_SETUP :
USB_TRANSACTION_OUT;
if (type == USB_TRANSACTION_SETUP) {
lm4f_ep_read_packet(usbd_dev, 0, &usbd_dev->control_state.req, 8);
}
if (usbd_dev->user_callback_ctr[0][type]) {
usbd_dev->
user_callback_ctr[0][type](usbd_dev, 0);
}
} else {
tx_cb = usbd_dev->user_callback_ctr[0]
[USB_TRANSACTION_IN];
/*
* EP0 bit in TXIS is set not only when a packet is
* finished transmitting, but also when RXRDY is set, or
* when we set TXRDY to transmit a packet. If any of
* those are the case, then we do not want to call our
* IN callback, since the state machine will be in the
* wrong state, and we'll just stall our control
* endpoint.
* In fact, the only way to know if it's time to call
* our TX callback is to know what to expect. The
* hardware does not tell us what sort of transaction
* this is. We need to work with the state machine to
* figure it all out. See [1] for details.
*/
if ((usbd_dev->control_state.state != DATA_IN) &&
(usbd_dev->control_state.state != LAST_DATA_IN) &&
(usbd_dev->control_state.state != STATUS_IN)) {
return;
}
if (tx_cb) {
tx_cb(usbd_dev, 0);
}
}
}
/* See which interrupt occurred */
for (i = 1; i < 8; i++) {
tx_cb = usbd_dev->user_callback_ctr[i][USB_TRANSACTION_IN];
rx_cb = usbd_dev->user_callback_ctr[i][USB_TRANSACTION_OUT];
if ((usb_txis & (1 << i)) && tx_cb) {
tx_cb(usbd_dev, i);
}
if ((usb_rxis & (1 << i)) && rx_cb) {
rx_cb(usbd_dev, i);
}
}
}
static void lm4f_disconnect(usbd_device *usbd_dev, bool disconnected)
{
(void)usbd_dev;
/*
* This is all it takes:
* usbd_disconnect(dev, 1) followed by usbd_disconnect(dev, 0)
* causes the device to re-enumerate and re-configure properly.
*/
if (disconnected) {
lm4f_usb_soft_disconnect();
} else {
lm4f_usb_soft_connect();
}
}
/*
* A static struct works as long as we have only one USB peripheral. If we
* meet LM4Fs with more than one USB, then we need to rework this approach.
*/
static struct _usbd_device usbd_dev;
/** Initialize the USB device controller hardware of the LM4F. */
static usbd_device *lm4f_usbd_init(void)
{
int i;
/* Start the USB clock */
periph_clock_enable(RCC_USB0);
/* Enable the USB PLL interrupts - used to assert PLL lock */
SYSCTL_IMC |= (SYSCTL_IMC_USBPLLLIM | SYSCTL_IMC_PLLLIM);
rcc_usb_pll_on();
/* Make sure we're disconnected. We'll reconnect later */
lm4f_usb_soft_disconnect();
/* Software reset USB */
SYSCTL_SRUSB = 1;
for (i = 0; i < 1000; i++) {
__asm__("nop");
}
SYSCTL_SRUSB = 0;
/*
* Wait for the PLL to lock before soft connecting
* This will result in a deadlock if the system clock is not setup
* correctly (clock from main oscillator).
*/
/* Wait for it */
i = 0;
while ((SYSCTL_RIS & SYSCTL_RIS_USBPLLLRIS) == 0) {
i++;
if (i > 0xffff) {
return 0;
}
}
/* Now connect to USB */
lm4f_usb_soft_connect();
/* No FIFO allocated yet, but the first 64 bytes are still reserved */
usbd_dev.fifo_mem_top = 64;
return &usbd_dev;
}
/* What is this thing even good for */
#define RX_FIFO_SIZE 512
const struct _usbd_driver lm4f_usb_driver = {
.init = lm4f_usbd_init,
.set_address = lm4f_set_address,
.ep_setup = lm4f_ep_setup,
.ep_reset = lm4f_endpoints_reset,
.ep_stall_set = lm4f_ep_stall_set,
.ep_stall_get = lm4f_ep_stall_get,
.ep_nak_set = lm4f_ep_nak_set,
.ep_write_packet = lm4f_ep_write_packet,
.ep_read_packet = lm4f_ep_read_packet,
.poll = lm4f_poll,
.disconnect = lm4f_disconnect,
.base_address = USB_BASE,
.set_address_before_status = false,
.rx_fifo_size = RX_FIFO_SIZE,
};
/**
* @endcond
*/
/**
* @}
*/