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pigweed / third_party / github / zephyrproject-rtos / zephyr / 083a42d734ebe5786f62dce6180e96bee147b7a9 / . / drivers / usb / device / usb_dc_numaker.c
blob: 0f52b165a13499ec254b964f9a75537653ccc544 [file] [log] [blame]
/*
* Copyright (c) 2023 Nuvoton Technology Corporation.
*
* SPDX-License-Identifier: Apache-2.0
*/
#define DT_DRV_COMPAT nuvoton_numaker_usbd
#include <zephyr/kernel.h>
#include <zephyr/usb/usb_device.h>
#include <zephyr/dt-bindings/usb/usb.h>
#include <zephyr/sys/math_extras.h>
#include <zephyr/drivers/clock_control.h>
#include <zephyr/drivers/clock_control/clock_control_numaker.h>
#include <zephyr/drivers/reset.h>
#include <zephyr/drivers/pinctrl.h>
#include <zephyr/logging/log.h>
LOG_MODULE_REGISTER(usb_dc_numaker, CONFIG_USB_DRIVER_LOG_LEVEL);
#include <soc.h>
#include <NuMicro.h>
/* USBD notes
*
* 1. Require 48MHz clock source
* (1) Not support HIRC48 as clock source. It involves trim with USB SOF packets
* and isn't suitable in HAL.
* (2) Instead of HICR48, core clock is required to be multiple of 48MHz e.g. 192MHz,
* to generate necessary 48MHz.
*/
/* For bus reset, keep 'SE0' (USB spec: SE0 >= 2.5 ms) */
#define NUMAKER_USBD_BUS_RESET_DRV_SE0_US 3000
/* For bus resume, generate 'K' (USB spec: 'K' >= 1 ms) */
#define NUMAKER_USBD_BUS_RESUME_DRV_K_US 1500
/* Reserve DMA buffer for Setup/CTRL OUT/CTRL IN, required to be 8-byte aligned */
#define NUMAKER_USBD_DMABUF_SIZE_SETUP 8
#define NUMAKER_USBD_DMABUF_SIZE_CTRLOUT 64
#define NUMAKER_USBD_DMABUF_SIZE_CTRLIN 64
/* Maximum number of EP contexts across all instances
* This is to static-allocate EP contexts which can accommodate all instances.
* The number of effective EP contexts per instance is passed on through its
* num_bidir_endpoints, which must not be larger than this.
*/
#define NUMAKER_USBD_EP_MAXNUM 25ul
/* Message type */
#define NUMAKER_USBD_MSG_TYPE_SW_RECONN 0 /* S/W reconnect */
#define NUMAKER_USBD_MSG_TYPE_CB_STATE 1 /* Callback for usb_dc_status_code */
#define NUMAKER_USBD_MSG_TYPE_CB_EP 2 /* Callback for usb_dc_ep_cb_status_code */
/* Message structure */
struct numaker_usbd_msg {
uint32_t type;
union {
struct {
enum usb_dc_status_code status_code;
} cb_device;
struct {
uint8_t ep;
enum usb_dc_ep_cb_status_code status_code;
} cb_ep;
};
};
/* Immutable device context */
struct numaker_usbd_config {
USBD_T *base;
const struct reset_dt_spec reset;
uint32_t clk_modidx;
uint32_t clk_src;
uint32_t clk_div;
const struct device *clkctrl_dev;
void (*irq_config_func)(const struct device *dev);
void (*irq_unconfig_func)(const struct device *dev);
const struct pinctrl_dev_config *pincfg;
uint32_t num_bidir_endpoints;
uint32_t dmabuf_size;
bool disallow_iso_inout_same;
};
/* EP context */
struct numaker_usbd_ep {
bool valid;
bool nak_clr; /* NAK cleared (ACK next transaction) */
const struct device *dev; /* Pointer to the containing device */
uint8_t ep_hw_idx; /* BSP USBD driver EP index EP0, EP1, EP2, etc */
uint32_t ep_hw_cfg; /* BSP USBD driver EP configuration */
/* EP DMA buffer */
bool dmabuf_valid;
uint32_t dmabuf_base;
uint32_t dmabuf_size;
/* On USBD, no H/W FIFO. Simulate based on above DMA buffer with
* one-shot implementation
*/
uint32_t read_fifo_pos;
uint32_t read_fifo_used;
uint32_t write_fifo_pos;
uint32_t write_fifo_free;
/* NOTE: On USBD, Setup and CTRL OUT are not completely separated. CTRL OUT MXPLD
* can be overridden to 8 by next Setup. To overcome it, we make one copy of CTRL
* OUT MXPLD immediately on its interrupt.
*/
uint32_t mxpld_ctrlout;
/* EP address */
bool addr_valid;
uint8_t addr;
/* EP MPS */
bool mps_valid;
uint16_t mps;
usb_dc_ep_callback cb; /* EP callback function */
};
/* EP context manager */
struct numaker_usbd_ep_mgmt {
/* EP context management
*
* Allocate-only, and de-allocate all on re-initialize in usb_dc_attach().
*/
uint8_t ep_idx;
/* DMA buffer management
*
* Allocate-only, and de-allocate all on re-initialize in usb_dc_attach().
*/
uint32_t dmabuf_pos;
/* Pass Setup packet from ISR to thread */
bool new_setup;
struct usb_setup_packet setup_packet;
struct numaker_usbd_ep ep_pool[NUMAKER_USBD_EP_MAXNUM];
};
/* Mutable device context */
struct numaker_usbd_data {
uint8_t addr; /* Host assigned USB device address */
struct k_mutex sync_mutex;
/* Enable interrupt top/bottom halves processing
*
* Registered callbacks may use mutex or other kernel functions which are not supported
* in interrupt context
*/
struct k_msgq msgq;
struct numaker_usbd_msg msgq_buf[CONFIG_USB_DC_NUMAKER_MSG_QUEUE_SIZE];
K_KERNEL_STACK_MEMBER(msg_hdlr_thread_stack,
CONFIG_USB_DC_NUMAKER_MSG_HANDLER_THREAD_STACK_SIZE);
struct k_thread msg_hdlr_thread;
usb_dc_status_callback status_cb; /* Status callback function */
struct numaker_usbd_ep_mgmt ep_mgmt; /* EP management */
};
static inline const struct device *numaker_usbd_device_get(void);
static inline void numaker_usbd_lock(const struct device *dev)
{
struct numaker_usbd_data *data = dev->data;
k_mutex_lock(&data->sync_mutex, K_FOREVER);
}
static inline void numaker_usbd_unlock(const struct device *dev)
{
struct numaker_usbd_data *data = dev->data;
k_mutex_unlock(&data->sync_mutex);
}
static inline void numaker_usbd_sw_connect(const struct device *dev)
{
const struct numaker_usbd_config *config = dev->config;
USBD_T *const base = config->base;
/* Clear all interrupts first for clean */
base->INTSTS = base->INTSTS;
/* Enable relevant interrupts */
base->INTEN = USBD_INT_BUS | USBD_INT_USB | USBD_INT_FLDET | USBD_INT_WAKEUP | USBD_INT_SOF;
/* Clear SE0 for connect */
base->SE0 &= ~USBD_DRVSE0;
}
static inline void numaker_usbd_sw_disconnect(const struct device *dev)
{
const struct numaker_usbd_config *config = dev->config;
USBD_T *const base = config->base;
/* Set SE0 for disconnect */
base->SE0 |= USBD_DRVSE0;
}
static inline void numaker_usbd_sw_reconnect(const struct device *dev)
{
/* Keep SE0 to trigger bus reset */
numaker_usbd_sw_disconnect(dev);
k_sleep(K_USEC(NUMAKER_USBD_BUS_RESET_DRV_SE0_US));
numaker_usbd_sw_connect(dev);
}
static inline void numaker_usbd_reset_addr(const struct device *dev)
{
const struct numaker_usbd_config *config = dev->config;
struct numaker_usbd_data *data = dev->data;
USBD_T *const base = config->base;
base->FADDR = 0;
data->addr = 0;
}
static inline void numaker_usbd_set_addr(const struct device *dev)
{
const struct numaker_usbd_config *config = dev->config;
struct numaker_usbd_data *data = dev->data;
USBD_T *const base = config->base;
if (base->FADDR != data->addr) {
base->FADDR = data->addr;
}
}
/* USBD EP base by e.g. EP0, EP1, ... */
static inline USBD_EP_T *numaker_usbd_ep_base(const struct device *dev, uint32_t ep_hw_idx)
{
const struct numaker_usbd_config *config = dev->config;
USBD_T *const base = config->base;
return base->EP + ep_hw_idx;
}
static inline uint32_t numaker_usbd_ep_fifo_max(struct numaker_usbd_ep *ep_cur)
{
/* NOTE: For one-shot implementation, effective size of EP FIFO is limited to EP MPS */
__ASSERT_NO_MSG(ep_cur->dmabuf_valid);
__ASSERT_NO_MSG(ep_cur->mps_valid);
__ASSERT_NO_MSG(ep_cur->mps <= ep_cur->dmabuf_size);
return ep_cur->mps;
}
static inline uint32_t numaker_usbd_ep_fifo_used(struct numaker_usbd_ep *ep_cur)
{
__ASSERT_NO_MSG(ep_cur->dmabuf_valid);
return USB_EP_DIR_IS_OUT(ep_cur->addr)
? ep_cur->read_fifo_used
: numaker_usbd_ep_fifo_max(ep_cur) - ep_cur->write_fifo_free;
}
/* Reset EP FIFO
*
* NOTE: EP FIFO is based on EP DMA buffer, which may not be configured yet.
*/
static void numaker_usbd_ep_fifo_reset(struct numaker_usbd_ep *ep_cur)
{
if (ep_cur->dmabuf_valid && ep_cur->mps_valid) {
if (USB_EP_DIR_IS_OUT(ep_cur->addr)) {
/* Read FIFO */
ep_cur->read_fifo_pos = ep_cur->dmabuf_base;
ep_cur->read_fifo_used = 0;
} else {
/* Write FIFO */
ep_cur->write_fifo_pos = ep_cur->dmabuf_base;
ep_cur->write_fifo_free = numaker_usbd_ep_fifo_max(ep_cur);
}
}
}
static inline void numaker_usbd_ep_set_stall(struct numaker_usbd_ep *ep_cur)
{
const struct device *dev = ep_cur->dev;
USBD_EP_T *ep_base = numaker_usbd_ep_base(dev, ep_cur->ep_hw_idx);
/* Set EP to stalled */
ep_base->CFGP |= USBD_CFGP_SSTALL_Msk;
}
/* Reset EP to unstalled and data toggle bit to 0 */
static inline void numaker_usbd_ep_clear_stall_n_data_toggle(struct numaker_usbd_ep *ep_cur)
{
const struct device *dev = ep_cur->dev;
USBD_EP_T *ep_base = numaker_usbd_ep_base(dev, ep_cur->ep_hw_idx);
/* Reset EP to unstalled */
ep_base->CFGP &= ~USBD_CFGP_SSTALL_Msk;
/* Reset EP data toggle bit to 0 */
ep_base->CFG &= ~USBD_CFG_DSQSYNC_Msk;
}
static inline bool numaker_usbd_ep_is_stalled(struct numaker_usbd_ep *ep_cur)
{
const struct device *dev = ep_cur->dev;
USBD_EP_T *ep_base = numaker_usbd_ep_base(dev, ep_cur->ep_hw_idx);
return ep_base->CFGP & USBD_CFGP_SSTALL_Msk;
}
static int numaker_usbd_send_msg(const struct device *dev, const struct numaker_usbd_msg *msg)
{
struct numaker_usbd_data *data = dev->data;
int rc;
rc = k_msgq_put(&data->msgq, msg, K_NO_WAIT);
if (rc < 0) {
/* Try to recover by S/W reconnect */
struct numaker_usbd_msg msg_reconn = {
.type = NUMAKER_USBD_MSG_TYPE_SW_RECONN,
};
LOG_ERR("Message queue overflow");
/* Discard all not yet received messages for error recovery below */
k_msgq_purge(&data->msgq);
rc = k_msgq_put(&data->msgq, &msg_reconn, K_NO_WAIT);
if (rc < 0) {
LOG_ERR("Message queue overflow again");
}
}
return rc;
}
static int numaker_usbd_hw_setup(const struct device *dev)
{
const struct numaker_usbd_config *config = dev->config;
USBD_T *const base = config->base;
int rc;
struct numaker_scc_subsys scc_subsys;
/* Reset controller ready? */
if (!device_is_ready(config->reset.dev)) {
LOG_ERR("Reset controller not ready");
return -ENODEV;
}
SYS_UnlockReg();
/* Configure USB PHY for USBD */
SYS->USBPHY = (SYS->USBPHY & ~SYS_USBPHY_USBROLE_Msk) |
(SYS_USBPHY_USBROLE_STD_USBD | SYS_USBPHY_USBEN_Msk | SYS_USBPHY_SBO_Msk);
/* Invoke Clock controller to enable module clock */
memset(&scc_subsys, 0x00, sizeof(scc_subsys));
scc_subsys.subsys_id = NUMAKER_SCC_SUBSYS_ID_PCC;
scc_subsys.pcc.clk_modidx = config->clk_modidx;
scc_subsys.pcc.clk_src = config->clk_src;
scc_subsys.pcc.clk_div = config->clk_div;
/* Equivalent to CLK_EnableModuleClock() */
rc = clock_control_on(config->clkctrl_dev, (clock_control_subsys_t)&scc_subsys);
if (rc < 0) {
goto cleanup;
}
/* Equivalent to CLK_SetModuleClock() */
rc = clock_control_configure(config->clkctrl_dev, (clock_control_subsys_t)&scc_subsys,
NULL);
if (rc < 0) {
goto cleanup;
}
/* Configure pinmux (NuMaker's SYS MFP) */
rc = pinctrl_apply_state(config->pincfg, PINCTRL_STATE_DEFAULT);
if (rc < 0) {
goto cleanup;
}
/* Invoke Reset controller to reset module to default state */
/* Equivalent to SYS_ResetModule()
*/
reset_line_toggle_dt(&config->reset);
/* Initialize USBD engine */
/* NOTE: BSP USBD driver: ATTR = 0x7D0 */
base->ATTR = USBD_ATTR_BYTEM_Msk | BIT(9) | USBD_ATTR_DPPUEN_Msk | USBD_ATTR_USBEN_Msk |
BIT(6) | USBD_ATTR_PHYEN_Msk;
/* Set SE0 for S/W disconnect */
numaker_usbd_sw_disconnect(dev);
/* NOTE: Ignore DT maximum-speed with USBD fixed to full-speed */
/* Initialize IRQ */
config->irq_config_func(dev);
cleanup:
SYS_LockReg();
return rc;
}
static void numaker_usbd_hw_shutdown(const struct device *dev)
{
const struct numaker_usbd_config *config = dev->config;
USBD_T *const base = config->base;
struct numaker_scc_subsys scc_subsys;
SYS_UnlockReg();
/* Uninitialize IRQ */
config->irq_unconfig_func(dev);
/* Set SE0 for S/W disconnect */
numaker_usbd_sw_disconnect(dev);
/* Disable USB PHY */
base->ATTR &= ~USBD_PHY_EN;
/* Invoke Clock controller to disable module clock */
memset(&scc_subsys, 0x00, sizeof(scc_subsys));
scc_subsys.subsys_id = NUMAKER_SCC_SUBSYS_ID_PCC;
scc_subsys.pcc.clk_modidx = config->clk_modidx;
/* Equivalent to CLK_DisableModuleClock() */
clock_control_off(config->clkctrl_dev, (clock_control_subsys_t)&scc_subsys);
/* Invoke Reset controller to reset module to default state */
/* Equivalent to SYS_ResetModule() */
reset_line_toggle_dt(&config->reset);
SYS_LockReg();
}
/* Interrupt top half processing for bus reset */
static void numaker_usbd_bus_reset_th(const struct device *dev)
{
const struct numaker_usbd_config *config = dev->config;
USBD_EP_T *ep_base;
for (uint32_t i = 0ul; i < config->num_bidir_endpoints; i++) {
ep_base = numaker_usbd_ep_base(dev, EP0 + i);
/* Cancel EP on-going transaction */
ep_base->CFGP |= USBD_CFGP_CLRRDY_Msk;
/* Reset EP to unstalled */
ep_base->CFGP &= ~USBD_CFGP_SSTALL_Msk;
/* Reset EP data toggle bit to 0 */
ep_base->CFG &= ~USBD_CFG_DSQSYNC_Msk;
/* Except EP0/EP1 kept resident for CTRL OUT/IN, disable all other EPs */
if (i >= 2) {
ep_base->CFG = 0;
}
}
numaker_usbd_reset_addr(dev);
}
static void numaker_usbd_remote_wakeup(const struct device *dev)
{
const struct numaker_usbd_config *config = dev->config;
USBD_T *const base = config->base;
/* Enable back USB/PHY first */
base->ATTR |= USBD_ATTR_USBEN_Msk | USBD_ATTR_PHYEN_Msk;
/* Then generate 'K' */
base->ATTR |= USBD_ATTR_RWAKEUP_Msk;
k_sleep(K_USEC(NUMAKER_USBD_BUS_RESUME_DRV_K_US));
base->ATTR ^= USBD_ATTR_RWAKEUP_Msk;
}
/* USBD SRAM base for DMA */
static inline uint32_t numaker_usbd_buf_base(const struct device *dev)
{
const struct numaker_usbd_config *config = dev->config;
USBD_T *const base = config->base;
return ((uint32_t)base + 0x800ul);
}
/* Copy to user buffer from Setup FIFO */
static void numaker_usbd_setup_fifo_copy_to_user(const struct device *dev, uint8_t *usrbuf)
{
const struct numaker_usbd_config *config = dev->config;
USBD_T *const base = config->base;
uint32_t dmabuf_addr;
dmabuf_addr = numaker_usbd_buf_base(dev) + (base->STBUFSEG & USBD_STBUFSEG_STBUFSEG_Msk);
bytecpy(usrbuf, (uint8_t *)dmabuf_addr, 8ul);
}
/* Copy data to user buffer from EP FIFO
*
* size_p holds size to copy/copied on input/output
*/
static int numaker_usbd_ep_fifo_copy_to_user(struct numaker_usbd_ep *ep_cur, uint8_t *usrbuf,
uint32_t *size_p)
{
const struct device *dev = ep_cur->dev;
uint32_t dmabuf_addr;
__ASSERT_NO_MSG(size_p);
__ASSERT_NO_MSG(ep_cur->dmabuf_valid);
dmabuf_addr = numaker_usbd_buf_base(dev) + ep_cur->read_fifo_pos;
/* Clamp to read FIFO used count */
*size_p = MIN(*size_p, numaker_usbd_ep_fifo_used(ep_cur));
bytecpy(usrbuf, (uint8_t *)dmabuf_addr, *size_p);
/* Advance read FIFO */
ep_cur->read_fifo_pos += *size_p;
ep_cur->read_fifo_used -= *size_p;
if (ep_cur->read_fifo_used == 0) {
ep_cur->read_fifo_pos = ep_cur->dmabuf_base;
}
return 0;
}
/* Copy data from user buffer to EP FIFO
*
* size_p holds size to copy/copied on input/output
*/
static int numaker_usbd_ep_fifo_copy_from_user(struct numaker_usbd_ep *ep_cur,
const uint8_t *usrbuf, uint32_t *size_p)
{
const struct device *dev = ep_cur->dev;
USBD_EP_T *ep_base = numaker_usbd_ep_base(dev, ep_cur->ep_hw_idx);
uint32_t dmabuf_addr;
uint32_t fifo_free;
__ASSERT_NO_MSG(size_p);
__ASSERT_NO_MSG(ep_cur->dmabuf_valid);
__ASSERT_NO_MSG(ep_cur->mps_valid);
__ASSERT_NO_MSG(ep_cur->mps <= ep_cur->dmabuf_size);
dmabuf_addr = numaker_usbd_buf_base(dev) + ep_base->BUFSEG;
fifo_free = numaker_usbd_ep_fifo_max(ep_cur) - numaker_usbd_ep_fifo_used(ep_cur);
*size_p = MIN(*size_p, fifo_free);
bytecpy((uint8_t *)dmabuf_addr, (uint8_t *)usrbuf, *size_p);
/* Advance write FIFO */
ep_cur->write_fifo_pos += *size_p;
ep_cur->write_fifo_free -= *size_p;
if (ep_cur->write_fifo_free == 0) {
ep_cur->write_fifo_pos = ep_cur->dmabuf_base;
}
return 0;
}
/* Update EP read/write FIFO on DATA OUT/IN completed */
static void numaker_usbd_ep_fifo_update(struct numaker_usbd_ep *ep_cur)
{
const struct device *dev = ep_cur->dev;
USBD_EP_T *ep_base = numaker_usbd_ep_base(dev, ep_cur->ep_hw_idx);
__ASSERT_NO_MSG(ep_cur->addr_valid);
__ASSERT_NO_MSG(ep_cur->dmabuf_valid);
if (USB_EP_DIR_IS_OUT(ep_cur->addr)) {
/* Read FIFO */
/* NOTE: For one-shot implementation, FIFO gets updated from empty. */
ep_cur->read_fifo_pos = ep_cur->dmabuf_base;
/* NOTE: See comment on mxpld_ctrlout for why make one copy of CTRL OUT's MXPLD */
if (USB_EP_GET_IDX(ep_cur->addr) == 0) {
ep_cur->read_fifo_used = ep_cur->mxpld_ctrlout;
} else {
ep_cur->read_fifo_used = ep_base->MXPLD;
}
} else {
/* Write FIFO */
/* NOTE: For one-shot implementation, FIFO gets to empty. */
ep_cur->write_fifo_pos = ep_cur->dmabuf_base;
ep_cur->write_fifo_free = numaker_usbd_ep_fifo_max(ep_cur);
}
}
static void numaker_usbd_ep_config_dmabuf(struct numaker_usbd_ep *ep_cur, uint32_t dmabuf_base,
uint32_t dmabuf_size)
{
const struct device *dev = ep_cur->dev;
USBD_EP_T *ep_base = numaker_usbd_ep_base(dev, ep_cur->ep_hw_idx);
ep_base->BUFSEG = dmabuf_base;
ep_cur->dmabuf_valid = true;
ep_cur->dmabuf_base = dmabuf_base;
ep_cur->dmabuf_size = dmabuf_size;
}
static void numaker_usbd_ep_abort(struct numaker_usbd_ep *ep_cur)
{
const struct device *dev = ep_cur->dev;
USBD_EP_T *ep_base = numaker_usbd_ep_base(dev, ep_cur->ep_hw_idx);
/* Abort EP on-going transaction */
ep_base->CFGP |= USBD_CFGP_CLRRDY_Msk;
/* Need to clear NAK for next transaction */
ep_cur->nak_clr = false;
}
/* Configure EP major common parts */
static void numaker_usbd_ep_config_major(struct numaker_usbd_ep *ep_cur,
const struct usb_dc_ep_cfg_data *const ep_cfg)
{
const struct device *dev = ep_cur->dev;
USBD_EP_T *ep_base = numaker_usbd_ep_base(dev, ep_cur->ep_hw_idx);
ep_cur->mps_valid = true;
ep_cur->mps = ep_cfg->ep_mps;
/* Configure EP transfer type, DATA0/1 toggle, direction, number, etc. */
ep_cur->ep_hw_cfg = 0;
/* Clear STALL Response in Setup stage */
if (ep_cfg->ep_type == USB_DC_EP_CONTROL) {
ep_cur->ep_hw_cfg |= USBD_CFG_CSTALL;
}
/* Default to DATA0 */
ep_cur->ep_hw_cfg &= ~USBD_CFG_DSQSYNC_Msk;
/* Endpoint IN/OUT, though, default to disabled */
ep_cur->ep_hw_cfg |= USBD_CFG_EPMODE_DISABLE;
/* Isochronous or not */
if (ep_cfg->ep_type == USB_DC_EP_ISOCHRONOUS) {
ep_cur->ep_hw_cfg |= USBD_CFG_TYPE_ISO;
}
/* Endpoint index */
ep_cur->ep_hw_cfg |=
(USB_EP_GET_IDX(ep_cfg->ep_addr) << USBD_CFG_EPNUM_Pos) & USBD_CFG_EPNUM_Msk;
ep_base->CFG = ep_cur->ep_hw_cfg;
}
static void numaker_usbd_ep_enable(struct numaker_usbd_ep *ep_cur)
{
const struct device *dev = ep_cur->dev;
USBD_EP_T *ep_base = numaker_usbd_ep_base(dev, ep_cur->ep_hw_idx);
/* For safe, EP (re-)enable from clean state */
numaker_usbd_ep_abort(ep_cur);
numaker_usbd_ep_clear_stall_n_data_toggle(ep_cur);
numaker_usbd_ep_fifo_reset(ep_cur);
/* Enable EP to IN/OUT */
ep_cur->ep_hw_cfg &= ~USBD_CFG_STATE_Msk;
if (USB_EP_DIR_IS_IN(ep_cur->addr)) {
ep_cur->ep_hw_cfg |= USBD_CFG_EPMODE_IN;
} else {
ep_cur->ep_hw_cfg |= USBD_CFG_EPMODE_OUT;
}
ep_base->CFG = ep_cur->ep_hw_cfg;
/* For USBD, no separate EP interrupt control */
}
static void numaker_usbd_ep_disable(struct numaker_usbd_ep *ep_cur)
{
const struct device *dev = ep_cur->dev;
USBD_EP_T *ep_base = numaker_usbd_ep_base(dev, ep_cur->ep_hw_idx);
/* For USBD, no separate EP interrupt control */
/* Disable EP */
ep_cur->ep_hw_cfg = (ep_cur->ep_hw_cfg & ~USBD_CFG_STATE_Msk) | USBD_CFG_EPMODE_DISABLE;
ep_base->CFG = ep_cur->ep_hw_cfg;
}
/* Start EP data transaction */
static void numaker_usbd_ep_trigger(struct numaker_usbd_ep *ep_cur, uint32_t len)
{
const struct device *dev = ep_cur->dev;
USBD_EP_T *ep_base = numaker_usbd_ep_base(dev, ep_cur->ep_hw_idx);
ep_base->MXPLD = len;
}
static struct numaker_usbd_ep *numaker_usbd_ep_mgmt_alloc_ep(const struct device *dev)
{
const struct numaker_usbd_config *config = dev->config;
struct numaker_usbd_data *data = dev->data;
struct numaker_usbd_ep_mgmt *ep_mgmt = &data->ep_mgmt;
struct numaker_usbd_ep *ep_cur = NULL;
if (ep_mgmt->ep_idx < config->num_bidir_endpoints) {
ep_cur = ep_mgmt->ep_pool + ep_mgmt->ep_idx;
ep_mgmt->ep_idx++;
__ASSERT_NO_MSG(!ep_cur->valid);
/* Indicate this EP context is allocated */
ep_cur->valid = true;
}
return ep_cur;
}
/* Allocate DMA buffer
*
* Return -ENOMEM on OOM error, or 0 on success with DMA buffer base/size (rounded up) allocated
*/
static int numaker_usbd_ep_mgmt_alloc_dmabuf(const struct device *dev, uint32_t size,
uint32_t *dmabuf_base_p, uint32_t *dmabuf_size_p)
{
const struct numaker_usbd_config *config = dev->config;
struct numaker_usbd_data *data = dev->data;
struct numaker_usbd_ep_mgmt *ep_mgmt = &data->ep_mgmt;
__ASSERT_NO_MSG(dmabuf_base_p);
__ASSERT_NO_MSG(dmabuf_size_p);
/* Required to be 8-byte aligned */
size = ROUND_UP(size, 8);
ep_mgmt->dmabuf_pos += size;
if (ep_mgmt->dmabuf_pos > config->dmabuf_size) {
ep_mgmt->dmabuf_pos -= size;
return -ENOMEM;
}
*dmabuf_base_p = ep_mgmt->dmabuf_pos - size;
*dmabuf_size_p = size;
return 0;
}
/* Initialize all endpoint-related */
static void numaker_usbd_ep_mgmt_init(const struct device *dev)
{
const struct numaker_usbd_config *config = dev->config;
struct numaker_usbd_data *data = dev->data;
USBD_T *const base = config->base;
struct numaker_usbd_ep_mgmt *ep_mgmt = &data->ep_mgmt;
struct numaker_usbd_ep *ep_cur;
struct numaker_usbd_ep *ep_end;
/* Initialize all fields to zero except persistent */
memset(ep_mgmt, 0x00, sizeof(*ep_mgmt));
ep_cur = ep_mgmt->ep_pool;
ep_end = ep_mgmt->ep_pool + config->num_bidir_endpoints;
/* Initialize all EP contexts */
for (; ep_cur != ep_end; ep_cur++) {
/* Pointer to the containing device */
ep_cur->dev = dev;
/* BSP USBD driver EP handle */
ep_cur->ep_hw_idx = EP0 + (ep_cur - ep_mgmt->ep_pool);
}
/* Reserve 1st/2nd EP contexts (BSP USBD driver EP0/EP1) for CTRL OUT/IN */
ep_mgmt->ep_idx = 2;
/* Reserve DMA buffer for Setup/CTRL OUT/CTRL IN, starting from 0 */
ep_mgmt->dmabuf_pos = 0;
/* Configure DMA buffer for Setup packet */
base->STBUFSEG = ep_mgmt->dmabuf_pos;
ep_mgmt->dmabuf_pos += NUMAKER_USBD_DMABUF_SIZE_SETUP;
/* Reserve 1st EP context (BSP USBD driver EP0) for CTRL OUT */
ep_cur = ep_mgmt->ep_pool + 0;
ep_cur->valid = true;
ep_cur->addr_valid = true;
ep_cur->addr = USB_EP_GET_ADDR(0, USB_EP_DIR_OUT);
numaker_usbd_ep_config_dmabuf(ep_cur, ep_mgmt->dmabuf_pos,
NUMAKER_USBD_DMABUF_SIZE_CTRLOUT);
ep_mgmt->dmabuf_pos += NUMAKER_USBD_DMABUF_SIZE_CTRLOUT;
ep_cur->mps_valid = true;
ep_cur->mps = NUMAKER_USBD_DMABUF_SIZE_CTRLOUT;
/* Reserve 2nd EP context (BSP USBD driver EP1) for CTRL IN */
ep_cur = ep_mgmt->ep_pool + 1;
ep_cur->valid = true;
ep_cur->addr_valid = true;
ep_cur->addr = USB_EP_GET_ADDR(0, USB_EP_DIR_IN);
numaker_usbd_ep_config_dmabuf(ep_cur, ep_mgmt->dmabuf_pos, NUMAKER_USBD_DMABUF_SIZE_CTRLIN);
ep_mgmt->dmabuf_pos += NUMAKER_USBD_DMABUF_SIZE_CTRLIN;
ep_cur->mps_valid = true;
ep_cur->mps = NUMAKER_USBD_DMABUF_SIZE_CTRLIN;
}
/* Find EP context by EP address */
static struct numaker_usbd_ep *numaker_usbd_ep_mgmt_find_ep(const struct device *dev,
const uint8_t ep)
{
const struct numaker_usbd_config *config = dev->config;
struct numaker_usbd_data *data = dev->data;
struct numaker_usbd_ep_mgmt *ep_mgmt = &data->ep_mgmt;
struct numaker_usbd_ep *ep_cur = ep_mgmt->ep_pool;
struct numaker_usbd_ep *ep_end = ep_mgmt->ep_pool + config->num_bidir_endpoints;
for (; ep_cur != ep_end; ep_cur++) {
if (!ep_cur->valid) {
continue;
}
if (!ep_cur->addr_valid) {
continue;
}
if (ep == ep_cur->addr) {
return ep_cur;
}
}
return NULL;
}
/* Bind EP context to EP address */
static struct numaker_usbd_ep *numaker_usbd_ep_mgmt_bind_ep(const struct device *dev,
const uint8_t ep)
{
struct numaker_usbd_ep *ep_cur = numaker_usbd_ep_mgmt_find_ep(dev, ep);
if (!ep_cur) {
ep_cur = numaker_usbd_ep_mgmt_alloc_ep(dev);
if (!ep_cur) {
return NULL;
}
/* Bind EP context to EP address */
ep_cur->addr = ep;
ep_cur->addr_valid = true;
}
/* Assert EP context bound to EP address */
__ASSERT_NO_MSG(ep_cur->valid);
__ASSERT_NO_MSG(ep_cur->addr_valid);
__ASSERT_NO_MSG(ep_cur->addr == ep);
return ep_cur;
}
/* Interrupt bottom half processing for bus reset */
static void numaker_usbd_bus_reset_bh(const struct device *dev)
{
const struct numaker_usbd_config *config = dev->config;
struct numaker_usbd_data *data = dev->data;
struct numaker_usbd_ep_mgmt *ep_mgmt = &data->ep_mgmt;
struct numaker_usbd_ep *ep_cur = ep_mgmt->ep_pool;
struct numaker_usbd_ep *ep_end = ep_mgmt->ep_pool + config->num_bidir_endpoints;
for (; ep_cur != ep_end; ep_cur++) {
/* Reset EP FIFO */
numaker_usbd_ep_fifo_reset(ep_cur);
/* Abort EP on-going transaction and signal H/W relinquishes DMA buffer ownership */
numaker_usbd_ep_abort(ep_cur);
/* Reset EP to unstalled and data toggle bit to 0 */
numaker_usbd_ep_clear_stall_n_data_toggle(ep_cur);
}
numaker_usbd_reset_addr(dev);
}
/* Interrupt bottom half processing for Setup/EP data transaction */
static void numaker_usbd_ep_bh(struct numaker_usbd_ep *ep_cur,
enum usb_dc_ep_cb_status_code status_code)
{
const struct device *dev = ep_cur->dev;
struct numaker_usbd_data *data = dev->data;
struct numaker_usbd_ep_mgmt *ep_mgmt = &data->ep_mgmt;
if (status_code == USB_DC_EP_SETUP) {
/* Zephyr USB device stack passes Setup packet via CTRL OUT EP. */
__ASSERT_NO_MSG(ep_cur->addr == USB_EP_GET_ADDR(0, USB_EP_DIR_OUT));
if (numaker_usbd_ep_fifo_used(ep_cur)) {
LOG_WRN("New Setup will override previous Control OUT data");
}
/* We should have reserved 1st/2nd EP contexts for CTRL OUT/IN */
__ASSERT_NO_MSG(ep_cur->addr == USB_EP_GET_ADDR(0, USB_EP_DIR_OUT));
__ASSERT_NO_MSG((ep_cur + 1)->addr == USB_EP_GET_ADDR(0, USB_EP_DIR_IN));
/* Reset CTRL OUT/IN FIFO due to new Setup packet */
numaker_usbd_ep_fifo_reset(ep_cur);
numaker_usbd_ep_fifo_reset(ep_cur + 1);
/* Relinquish CTRL OUT/IN DMA buffer ownership on behalf of H/W */
numaker_usbd_ep_abort(ep_cur);
numaker_usbd_ep_abort(ep_cur + 1);
/* Mark new Setup packet for read */
numaker_usbd_setup_fifo_copy_to_user(dev, (uint8_t *)&ep_mgmt->setup_packet);
ep_mgmt->new_setup = true;
} else if (status_code == USB_DC_EP_DATA_OUT) {
__ASSERT_NO_MSG(USB_EP_DIR_IS_OUT(ep_cur->addr));
/* Update EP read FIFO */
numaker_usbd_ep_fifo_update(ep_cur);
/* Need to clear NAK for next transaction */
ep_cur->nak_clr = false;
} else if (status_code == USB_DC_EP_DATA_IN) {
__ASSERT_NO_MSG(USB_EP_DIR_IS_IN(ep_cur->addr));
/* Update EP write FIFO */
numaker_usbd_ep_fifo_update(ep_cur);
/* Need to clear NAK for next transaction */
ep_cur->nak_clr = false;
}
}
/* Message handler for S/W reconnect */
static void numaker_usbd_msg_sw_reconn(const struct device *dev, struct numaker_usbd_msg *msg)
{
__ASSERT_NO_MSG(msg->type == NUMAKER_USBD_MSG_TYPE_SW_RECONN);
/* S/W reconnect for error recovery */
numaker_usbd_lock(dev);
numaker_usbd_sw_reconnect(dev);
numaker_usbd_unlock(dev);
}
/* Message handler for callback for usb_dc_status_code */
static void numaker_usbd_msg_cb_state(const struct device *dev, struct numaker_usbd_msg *msg)
{
struct numaker_usbd_data *data = dev->data;
__ASSERT_NO_MSG(msg->type == NUMAKER_USBD_MSG_TYPE_CB_STATE);
/* Interrupt bottom half processing for bus reset */
if (msg->cb_device.status_code == USB_DC_RESET) {
numaker_usbd_lock(dev);
numaker_usbd_bus_reset_bh(dev);
numaker_usbd_unlock(dev);
}
/* NOTE: Don't run callback with our mutex locked, or we may encounter
* deadlock because the Zephyr USB device stack can have its own
* synchronization.
*/
if (data->status_cb) {
data->status_cb(msg->cb_device.status_code, NULL);
} else {
LOG_WRN("No status callback: status_code=%d", msg->cb_device.status_code);
}
}
/* Message handler for callback for usb_dc_ep_cb_status_code */
static void numaker_usbd_msg_cb_ep(const struct device *dev, struct numaker_usbd_msg *msg)
{
uint8_t ep;
struct numaker_usbd_ep *ep_cur;
__ASSERT_NO_MSG(msg->type == NUMAKER_USBD_MSG_TYPE_CB_EP);
ep = msg->cb_ep.ep;
/* Bind EP context to EP address */
ep_cur = numaker_usbd_ep_mgmt_bind_ep(dev, ep);
if (!ep_cur) {
LOG_ERR("Bind EP context: ep=0x%02x", ep);
return;
}
/* Interrupt bottom half processing for EP */
numaker_usbd_lock(dev);
numaker_usbd_ep_bh(ep_cur, msg->cb_ep.status_code);
numaker_usbd_unlock(dev);
/* NOTE: Same as above, don't run callback with our mutex locked */
if (ep_cur->cb) {
ep_cur->cb(ep, msg->cb_ep.status_code);
} else {
LOG_WRN("No EP callback: ep=0x%02x, status_code=%d", ep, msg->cb_ep.status_code);
}
}
/* Interrupt bottom half processing
*
* This thread is used to not run Zephyr USB device stack and callbacks in interrupt
* context. This is because callbacks from this stack may use mutex or other kernel functions
* which are not supported in interrupt context.
*/
static void numaker_usbd_msg_hdlr_thread_main(void *arg1, void *arg2, void *arg3)
{
const struct device *dev = (const struct device *)arg1;
struct numaker_usbd_data *data = dev->data;
struct numaker_usbd_msg msg;
__ASSERT_NO_MSG(arg1);
ARG_UNUSED(arg2);
ARG_UNUSED(arg3);
while (true) {
if (k_msgq_get(&data->msgq, &msg, K_FOREVER)) {
continue;
}
switch (msg.type) {
case NUMAKER_USBD_MSG_TYPE_SW_RECONN:
numaker_usbd_msg_sw_reconn(dev, &msg);
break;
case NUMAKER_USBD_MSG_TYPE_CB_STATE:
numaker_usbd_msg_cb_state(dev, &msg);
break;
case NUMAKER_USBD_MSG_TYPE_CB_EP:
numaker_usbd_msg_cb_ep(dev, &msg);
break;
default:
__ASSERT_NO_MSG(false);
}
}
}
static void numaker_udbd_isr(const struct device *dev)
{
const struct numaker_usbd_config *config = dev->config;
struct numaker_usbd_data *data = dev->data;
USBD_T *const base = config->base;
struct numaker_usbd_ep_mgmt *ep_mgmt = &data->ep_mgmt;
struct numaker_usbd_msg msg = {0};
uint32_t volatile usbd_intsts = base->INTSTS;
uint32_t volatile usbd_bus_state = base->ATTR;
/* USB plug-in/unplug */
if (usbd_intsts & USBD_INTSTS_FLDET) {
/* Floating detect */
base->INTSTS = USBD_INTSTS_FLDET;
if (base->VBUSDET & USBD_VBUSDET_VBUSDET_Msk) {
/* USB plug-in */
/* Enable back USB/PHY */
base->ATTR |= USBD_ATTR_USBEN_Msk | USBD_ATTR_PHYEN_Msk;
/* Message for bottom-half processing */
msg.type = NUMAKER_USBD_MSG_TYPE_CB_STATE;
msg.cb_device.status_code = USB_DC_CONNECTED;
numaker_usbd_send_msg(dev, &msg);
LOG_DBG("USB plug-in");
} else {
/* USB unplug */
/* Disable USB */
base->ATTR &= ~USBD_USB_EN;
/* Message for bottom-half processing */
msg.type = NUMAKER_USBD_MSG_TYPE_CB_STATE;
msg.cb_device.status_code = USB_DC_DISCONNECTED;
numaker_usbd_send_msg(dev, &msg);
LOG_DBG("USB unplug");
}
}
/* USB wake-up */
if (usbd_intsts & USBD_INTSTS_WAKEUP) {
/* Clear event flag */
base->INTSTS = USBD_INTSTS_WAKEUP;
LOG_DBG("USB wake-up");
}
/* USB reset/suspend/resume */
if (usbd_intsts & USBD_INTSTS_BUS) {
/* Clear event flag */
base->INTSTS = USBD_INTSTS_BUS;
if (usbd_bus_state & USBD_STATE_USBRST) {
/* Bus reset */
/* Enable back USB/PHY */
base->ATTR |= USBD_ATTR_USBEN_Msk | USBD_ATTR_PHYEN_Msk;
/* Bus reset top half */
numaker_usbd_bus_reset_th(dev);
/* Message for bottom-half processing */
msg.type = NUMAKER_USBD_MSG_TYPE_CB_STATE;
msg.cb_device.status_code = USB_DC_RESET;
numaker_usbd_send_msg(dev, &msg);
LOG_DBG("USB reset");
}
if (usbd_bus_state & USBD_STATE_SUSPEND) {
/* Enable USB but disable PHY */
base->ATTR &= ~USBD_PHY_EN;
/* Message for bottom-half processing */
msg.type = NUMAKER_USBD_MSG_TYPE_CB_STATE;
msg.cb_device.status_code = USB_DC_SUSPEND;
numaker_usbd_send_msg(dev, &msg);
LOG_DBG("USB suspend");
}
if (usbd_bus_state & USBD_STATE_RESUME) {
/* Enable back USB/PHY */
base->ATTR |= USBD_ATTR_USBEN_Msk | USBD_ATTR_PHYEN_Msk;
/* Message for bottom-half processing */
msg.type = NUMAKER_USBD_MSG_TYPE_CB_STATE;
msg.cb_device.status_code = USB_DC_RESUME;
numaker_usbd_send_msg(dev, &msg);
LOG_DBG("USB resume");
}
}
/* USB SOF */
if (usbd_intsts & USBD_INTSTS_SOFIF_Msk) {
/* Clear event flag */
base->INTSTS = USBD_INTSTS_SOFIF_Msk;
/* Message for bottom-half processing */
msg.type = NUMAKER_USBD_MSG_TYPE_CB_STATE;
msg.cb_device.status_code = USB_DC_SOF;
numaker_usbd_send_msg(dev, &msg);
}
/* USB Setup/EP */
if (usbd_intsts & USBD_INTSTS_USB) {
uint32_t epintsts;
/* Setup event */
if (usbd_intsts & USBD_INTSTS_SETUP) {
USBD_EP_T *ep0_base = numaker_usbd_ep_base(dev, EP0);
USBD_EP_T *ep1_base = numaker_usbd_ep_base(dev, EP1);
/* Clear event flag */
base->INTSTS = USBD_INTSTS_SETUP;
/* Clear the data IN/OUT ready flag of control endpoints */
ep0_base->CFGP |= USBD_CFGP_CLRRDY_Msk;
ep1_base->CFGP |= USBD_CFGP_CLRRDY_Msk;
/* By USB spec, following transactions, regardless of Data/Status stage,
* will always be DATA1
*/
ep0_base->CFG |= USBD_CFG_DSQSYNC_Msk;
ep1_base->CFG |= USBD_CFG_DSQSYNC_Msk;
/* Message for bottom-half processing */
/* NOTE: In Zephyr USB device stack, Setup packet is passed via
* CTRL OUT EP
*/
msg.type = NUMAKER_USBD_MSG_TYPE_CB_EP;
msg.cb_ep.ep = USB_EP_GET_ADDR(0, USB_EP_DIR_OUT);
msg.cb_ep.status_code = USB_DC_EP_SETUP;
numaker_usbd_send_msg(dev, &msg);
}
/* EP events */
epintsts = base->EPINTSTS;
base->EPINTSTS = epintsts;
while (epintsts) {
uint32_t ep_hw_idx = u32_count_trailing_zeros(epintsts);
USBD_EP_T *ep_base = numaker_usbd_ep_base(dev, ep_hw_idx);
uint8_t ep_dir;
uint8_t ep_idx;
uint8_t ep;
/* We don't enable INNAKEN interrupt, so as long as EP event occurs,
* we can just regard one data transaction has completed (ACK for
* CTRL/BULK/INT or no-ACK for Iso), that is, no need to check EPSTS0,
* EPSTS1, etc.
*/
/* EP direction, number, and address */
ep_dir = ((ep_base->CFG & USBD_CFG_STATE_Msk) == USBD_CFG_EPMODE_IN)
? USB_EP_DIR_IN
: USB_EP_DIR_OUT;
ep_idx = (ep_base->CFG & USBD_CFG_EPNUM_Msk) >> USBD_CFG_EPNUM_Pos;
ep = USB_EP_GET_ADDR(ep_idx, ep_dir);
/* NOTE: See comment in usb_dc_set_address()'s implementation
* for safe place to change USB device address
*/
if (ep == USB_EP_GET_ADDR(0, USB_EP_DIR_IN)) {
numaker_usbd_set_addr(dev);
}
/* NOTE: See comment on mxpld_ctrlout for why make one copy of
* CTRL OUT's MXPLD
*/
if (ep == USB_EP_GET_ADDR(0, USB_EP_DIR_OUT)) {
struct numaker_usbd_ep *ep_ctrlout = ep_mgmt->ep_pool + 0;
USBD_EP_T *ep_ctrlout_base =
numaker_usbd_ep_base(dev, ep_ctrlout->ep_hw_idx);
ep_ctrlout->mxpld_ctrlout = ep_ctrlout_base->MXPLD;
}
/* Message for bottom-half processing */
msg.type = NUMAKER_USBD_MSG_TYPE_CB_EP;
msg.cb_ep.ep = ep;
msg.cb_ep.status_code =
USB_EP_DIR_IS_IN(ep) ? USB_DC_EP_DATA_IN : USB_DC_EP_DATA_OUT;
numaker_usbd_send_msg(dev, &msg);
/* Have handled this EP and go next */
epintsts &= ~BIT(ep_hw_idx);
}
}
}
/* Zephyr USB device controller API implementation */
int usb_dc_attach(void)
{
const struct device *dev = numaker_usbd_device_get();
int rc;
numaker_usbd_lock(dev);
/* Initialize USB DC H/W */
rc = numaker_usbd_hw_setup(dev);
if (rc < 0) {
LOG_ERR("Set up H/W");
goto cleanup;
}
/* USB device address defaults to 0 */
numaker_usbd_reset_addr(dev);
/* Initialize all EPs */
numaker_usbd_ep_mgmt_init(dev);
/* S/W connect */
numaker_usbd_sw_connect(dev);
LOG_DBG("attached");
cleanup:
if (rc < 0) {
usb_dc_detach();
}
numaker_usbd_unlock(dev);
return rc;
}
int usb_dc_detach(void)
{
const struct device *dev = numaker_usbd_device_get();
struct numaker_usbd_data *data = dev->data;
LOG_DBG("detached");
numaker_usbd_lock(dev);
/* S/W disconnect */
numaker_usbd_sw_disconnect(dev);
/* Uninitialize USB DC H/W */
numaker_usbd_hw_shutdown(numaker_usbd_device_get());
/* Purge message queue */
k_msgq_purge(&data->msgq);
numaker_usbd_unlock(dev);
return 0;
}
int usb_dc_reset(void)
{
const struct device *dev = numaker_usbd_device_get();
LOG_DBG("usb_dc_reset");
numaker_usbd_lock(dev);
usb_dc_detach();
usb_dc_attach();
numaker_usbd_unlock(dev);
return 0;
}
int usb_dc_set_address(const uint8_t addr)
{
const struct device *dev = numaker_usbd_device_get();
struct numaker_usbd_data *data = dev->data;
LOG_DBG("USB device address=%u (0x%02x)", addr, addr);
numaker_usbd_lock(dev);
/* NOTE: Timing for configuring USB device address into H/W is critical. It must be done
* in-between SET_ADDRESS control transfer and next transfer. For this, it is done in
* IN ACK ISR of SET_ADDRESS control transfer.
*/
data->addr = addr;
numaker_usbd_unlock(dev);
return 0;
}
void usb_dc_set_status_callback(const usb_dc_status_callback cb)
{
const struct device *dev = numaker_usbd_device_get();
struct numaker_usbd_data *data = dev->data;
numaker_usbd_lock(dev);
data->status_cb = cb;
numaker_usbd_unlock(dev);
}
int usb_dc_ep_check_cap(const struct usb_dc_ep_cfg_data *const ep_cfg)
{
const struct device *dev = numaker_usbd_device_get();
const struct numaker_usbd_config *config = dev->config;
int rc = 0;
struct numaker_usbd_ep *ep_cur;
numaker_usbd_lock(dev);
/* For safe, require EP number for control transfer to be 0 */
if ((ep_cfg->ep_type == USB_DC_EP_CONTROL) && USB_EP_GET_IDX(ep_cfg->ep_addr) != 0) {
LOG_ERR("EP number for control transfer must be 0");
rc = -ENOTSUP;
goto cleanup;
}
/* Some soc series don't allow ISO IN/OUT to be assigned the same EP number.
* This is addressed by limiting all OUT/IN EP addresses in top/bottom halves,
* except CTRL OUT/IN.
*/
if (config->disallow_iso_inout_same && ep_cfg->ep_type != USB_DC_EP_CONTROL) {
/* Limit all OUT EP addresses in top-half, except CTRL OUT */
if (USB_EP_DIR_IS_OUT(ep_cfg->ep_addr) && USB_EP_GET_IDX(ep_cfg->ep_addr) >= 8) {
LOG_DBG("Support only ISO OUT EP address 0x01~0x07: 0x%02x",
ep_cfg->ep_addr);
rc = -ENOTSUP;
goto cleanup;
}
/* Limit all IN EP addresses in bottom-half , except CTRL IN */
if (USB_EP_DIR_IS_IN(ep_cfg->ep_addr) && USB_EP_GET_IDX(ep_cfg->ep_addr) < 8) {
LOG_DBG("Support only ISO IN EP address 0x88~0x8F: 0x%02x",
ep_cfg->ep_addr);
rc = -ENOTSUP;
goto cleanup;
}
}
/* To respect this capability check, pre-bind EP context to EP address,
* and pre-determined its type
*/
ep_cur = numaker_usbd_ep_mgmt_bind_ep(dev, ep_cfg->ep_addr);
if (!ep_cur) {
LOG_ERR("Bind EP context: ep=0x%02x", ep_cfg->ep_addr);
rc = -ENOMEM;
goto cleanup;
}
cleanup:
numaker_usbd_unlock(dev);
return rc;
}
int usb_dc_ep_set_callback(const uint8_t ep, const usb_dc_ep_callback cb)
{
const struct device *dev = numaker_usbd_device_get();
int rc = 0;
struct numaker_usbd_ep *ep_cur;
numaker_usbd_lock(dev);
/* Bind EP context to EP address */
ep_cur = numaker_usbd_ep_mgmt_bind_ep(dev, ep);
if (!ep_cur) {
LOG_ERR("Bind EP context: ep=0x%02x", ep);
rc = -ENOMEM;
goto cleanup;
}
ep_cur->cb = cb;
cleanup:
numaker_usbd_unlock(dev);
return rc;
}
int usb_dc_ep_configure(const struct usb_dc_ep_cfg_data *const ep_cfg)
{
const struct device *dev = numaker_usbd_device_get();
int rc = 0;
uint32_t dmabuf_base;
uint32_t dmabuf_size;
struct numaker_usbd_ep *ep_cur;
LOG_DBG("EP=0x%02x, MPS=%d, Type=%d", ep_cfg->ep_addr, ep_cfg->ep_mps, ep_cfg->ep_type);
numaker_usbd_lock(dev);
/* Bind EP context to EP address */
ep_cur = numaker_usbd_ep_mgmt_bind_ep(dev, ep_cfg->ep_addr);
if (!ep_cur) {
LOG_ERR("Bind EP context: ep=0x%02x", ep_cfg->ep_addr);
rc = -ENOMEM;
goto cleanup;
}
/* Configure EP DMA buffer */
if (!ep_cur->dmabuf_valid || ep_cur->dmabuf_size < ep_cfg->ep_mps) {
/* Allocate DMA buffer */
rc = numaker_usbd_ep_mgmt_alloc_dmabuf(dev, ep_cfg->ep_mps, &dmabuf_base,
&dmabuf_size);
if (rc < 0) {
LOG_ERR("Allocate DMA buffer failed");
goto cleanup;
}
/* Configure EP DMA buffer */
numaker_usbd_ep_config_dmabuf(ep_cur, dmabuf_base, dmabuf_size);
}
/* Configure EP majorly */
numaker_usbd_ep_config_major(ep_cur, ep_cfg);
cleanup:
numaker_usbd_unlock(dev);
return rc;
}
int usb_dc_ep_set_stall(const uint8_t ep)
{
const struct device *dev = numaker_usbd_device_get();
int rc = 0;
struct numaker_usbd_ep *ep_cur;
LOG_DBG("Set stall: ep=0x%02x", ep);
numaker_usbd_lock(dev);
/* Bind EP context to EP address */
ep_cur = numaker_usbd_ep_mgmt_bind_ep(dev, ep);
if (!ep_cur) {
LOG_ERR("Bind EP context: ep=0x%02x", ep);
rc = -ENOMEM;
goto cleanup;
}
/* Set EP to stalled */
numaker_usbd_ep_set_stall(ep_cur);
cleanup:
numaker_usbd_unlock(dev);
return rc;
}
int usb_dc_ep_clear_stall(const uint8_t ep)
{
const struct device *dev = numaker_usbd_device_get();
int rc = 0;
struct numaker_usbd_ep *ep_cur;
LOG_DBG("Clear stall: ep=0x%02x", ep);
numaker_usbd_lock(dev);
/* Bind EP context to EP address */
ep_cur = numaker_usbd_ep_mgmt_bind_ep(dev, ep);
if (!ep_cur) {
LOG_ERR("Bind EP context: ep=0x%02x", ep);
rc = -ENOMEM;
goto cleanup;
}
/* Reset EP to unstalled and data toggle bit to 0 */
numaker_usbd_ep_clear_stall_n_data_toggle(ep_cur);
cleanup:
numaker_usbd_unlock(dev);
return rc;
}
int usb_dc_ep_is_stalled(const uint8_t ep, uint8_t *const stalled)
{
const struct device *dev = numaker_usbd_device_get();
int rc = 0;
struct numaker_usbd_ep *ep_cur;
if (!stalled) {
return -EINVAL;
}
numaker_usbd_lock(dev);
/* Bind EP context to EP address */
ep_cur = numaker_usbd_ep_mgmt_bind_ep(dev, ep);
if (!ep_cur) {
LOG_ERR("Bind EP context: ep=0x%02x", ep);
rc = -ENOMEM;
goto cleanup;
}
*stalled = numaker_usbd_ep_is_stalled(ep_cur);
cleanup:
numaker_usbd_unlock(dev);
return rc;
}
int usb_dc_ep_halt(const uint8_t ep)
{
return usb_dc_ep_set_stall(ep);
}
int usb_dc_ep_enable(const uint8_t ep)
{
const struct device *dev = numaker_usbd_device_get();
int rc = 0;
struct numaker_usbd_ep *ep_cur;
LOG_DBG("Enable: ep=0x%02x", ep);
numaker_usbd_lock(dev);
/* Bind EP context to EP address */
ep_cur = numaker_usbd_ep_mgmt_bind_ep(dev, ep);
if (!ep_cur) {
LOG_ERR("Bind EP context: ep=0x%02x", ep);
rc = -ENOMEM;
goto cleanup;
}
numaker_usbd_ep_enable(ep_cur);
/* Trigger OUT transaction manually, or H/W will continue to reply NAK because
* Zephyr USB device stack is unclear on kicking off by invoking usb_dc_ep_read()
* or friends. We needn't do this for CTRL OUT because Setup sequence will involve
* this.
*/
if (USB_EP_DIR_IS_OUT(ep) && USB_EP_GET_IDX(ep) != 0) {
rc = usb_dc_ep_read_continue(ep);
if (rc < 0) {
goto cleanup;
}
}
cleanup:
numaker_usbd_unlock(dev);
return rc;
}
int usb_dc_ep_disable(const uint8_t ep)
{
const struct device *dev = numaker_usbd_device_get();
int rc = 0;
struct numaker_usbd_ep *ep_cur;
LOG_DBG("Disable: ep=0x%02x", ep);
numaker_usbd_lock(dev);
/* Bind EP context to EP address */
ep_cur = numaker_usbd_ep_mgmt_bind_ep(dev, ep);
if (!ep_cur) {
LOG_ERR("Bind EP context: ep=0x%02x", ep);
rc = -ENOMEM;
goto cleanup;
}
numaker_usbd_ep_disable(ep_cur);
cleanup:
numaker_usbd_unlock(dev);
return rc;
}
int usb_dc_ep_flush(const uint8_t ep)
{
const struct device *dev = numaker_usbd_device_get();
int rc = 0;
struct numaker_usbd_ep *ep_cur;
LOG_DBG("ep=0x%02x", ep);
numaker_usbd_lock(dev);
/* Bind EP context to EP address */
ep_cur = numaker_usbd_ep_mgmt_bind_ep(dev, ep);
if (!ep_cur) {
LOG_ERR("Bind EP context: ep=0x%02x", ep);
rc = -ENOMEM;
goto cleanup;
}
numaker_usbd_ep_fifo_reset(ep_cur);
cleanup:
numaker_usbd_unlock(dev);
return rc;
}
int usb_dc_ep_write(const uint8_t ep, const uint8_t *const data_buf, const uint32_t data_len,
uint32_t *const ret_bytes)
{
const struct device *dev = numaker_usbd_device_get();
int rc = 0;
struct numaker_usbd_ep *ep_cur;
uint32_t data_len_act;
numaker_usbd_lock(dev);
/* Bind EP context to EP address */
ep_cur = numaker_usbd_ep_mgmt_bind_ep(dev, ep);
if (!ep_cur) {
LOG_ERR("ep=0x%02x", ep);
rc = -ENOMEM;
goto cleanup;
}
if (!USB_EP_DIR_IS_IN(ep)) {
LOG_ERR("Invalid EP address 0x%02x for write", ep);
rc = -EINVAL;
goto cleanup;
}
/* For USBD, avoid duplicate NAK clear */
if (ep_cur->nak_clr) {
LOG_WRN("ep 0x%02x busy", ep);
rc = -EAGAIN;
goto cleanup;
}
/* For one-shot implementation, don't trigger next DATA IN with write FIFO not empty. */
if (numaker_usbd_ep_fifo_used(ep_cur)) {
LOG_WRN("ep 0x%02x: Write FIFO not empty for one-shot implementation", ep);
rc = -EAGAIN;
goto cleanup;
}
/* NOTE: Null data or zero data length are valid, used for ZLP */
if (data_buf && data_len) {
data_len_act = data_len;
rc = numaker_usbd_ep_fifo_copy_from_user(ep_cur, data_buf, &data_len_act);
if (rc < 0) {
LOG_ERR("Copy to FIFO from user buffer");
goto cleanup;
}
} else {
data_len_act = 0;
}
/* Now H/W actually owns EP DMA buffer */
numaker_usbd_ep_trigger(ep_cur, data_len_act);
/* NOTE: For one-shot implementation, at most MPS size can be written, though,
* null 'ret_bytes' requires all data written.
*/
if (ret_bytes) {
*ret_bytes = data_len_act;
} else if (data_len_act != data_len) {
LOG_ERR("Expected write all %d bytes, but actual %d bytes written", data_len,
data_len_act);
rc = -EIO;
goto cleanup;
}
cleanup:
numaker_usbd_unlock(dev);
return rc;
}
int usb_dc_ep_read(const uint8_t ep, uint8_t *const data, const uint32_t max_data_len,
uint32_t *const read_bytes)
{
const struct device *dev = numaker_usbd_device_get();
int rc = 0;
numaker_usbd_lock(dev);
rc = usb_dc_ep_read_wait(ep, data, max_data_len, read_bytes);
if (rc < 0) {
goto cleanup;
}
rc = usb_dc_ep_read_continue(ep);
if (rc < 0) {
goto cleanup;
}
cleanup:
numaker_usbd_unlock(dev);
return rc;
}
int usb_dc_ep_read_wait(uint8_t ep, uint8_t *data_buf, uint32_t max_data_len, uint32_t *read_bytes)
{
const struct device *dev = numaker_usbd_device_get();
struct numaker_usbd_data *data = dev->data;
int rc = 0;
struct numaker_usbd_ep_mgmt *ep_mgmt = &data->ep_mgmt;
struct numaker_usbd_ep *ep_cur;
uint32_t data_len_act = 0;
numaker_usbd_lock(dev);
/* Bind EP context to EP address */
ep_cur = numaker_usbd_ep_mgmt_bind_ep(dev, ep);
if (!ep_cur) {
LOG_ERR("Bind EP context: ep=0x%02x", ep);
rc = -ENOMEM;
goto cleanup;
}
if (!USB_EP_DIR_IS_OUT(ep)) {
LOG_ERR("Invalid EP address 0x%02x for read", ep);
rc = -EINVAL;
goto cleanup;
}
/* Special handling for USB_CONTROL_EP_OUT on Setup packet */
if (ep == USB_CONTROL_EP_OUT && ep_mgmt->new_setup) {
if (!data_buf || max_data_len != 8) {
LOG_ERR("Invalid parameter for reading Setup packet");
rc = -EINVAL;
goto cleanup;
}
memcpy(data_buf, &ep_mgmt->setup_packet, 8);
ep_mgmt->new_setup = false;
if (read_bytes) {
*read_bytes = 8;
}
goto cleanup;
}
/* For one-shot implementation, don't read FIFO with EP busy. */
if (ep_cur->nak_clr) {
LOG_WRN("ep 0x%02x busy", ep);
rc = -EAGAIN;
goto cleanup;
}
/* NOTE: Null data and zero data length is valid, used for returning number of
* available bytes for read
*/
if (data_buf) {
data_len_act = max_data_len;
rc = numaker_usbd_ep_fifo_copy_to_user(ep_cur, data_buf, &data_len_act);
if (rc < 0) {
LOG_ERR("Copy from FIFO to user buffer");
goto cleanup;
}
if (read_bytes) {
*read_bytes = data_len_act;
}
} else if (max_data_len) {
LOG_ERR("Null data but non-zero data length");
rc = -EINVAL;
goto cleanup;
} else {
if (read_bytes) {
*read_bytes = numaker_usbd_ep_fifo_used(ep_cur);
}
}
/* Suppress further USB_DC_EP_DATA_OUT events by replying NAK or disabling interrupt
*
* For USBD, further control is unnecessary because NAK is automatically replied until
* next USBD_SET_PAYLOAD_LEN().
*/
cleanup:
numaker_usbd_unlock(dev);
return rc;
}
int usb_dc_ep_read_continue(uint8_t ep)
{
const struct device *dev = numaker_usbd_device_get();
int rc = 0;
struct numaker_usbd_ep *ep_cur;
numaker_usbd_lock(dev);
/* Bind EP context to EP address */
ep_cur = numaker_usbd_ep_mgmt_bind_ep(dev, ep);
if (!ep_cur) {
LOG_ERR("Bind EP context: ep=0x%02x", ep);
rc = -ENOMEM;
goto cleanup;
}
if (!USB_EP_DIR_IS_OUT(ep)) {
LOG_ERR("Invalid EP address 0x%02x for read", ep);
rc = -EINVAL;
goto cleanup;
}
/* Avoid duplicate NAK clear */
if (ep_cur->nak_clr) {
rc = 0;
goto cleanup;
}
/* For one-shot implementation, don't trigger next DATA OUT, or overwrite. */
if (numaker_usbd_ep_fifo_used(ep_cur)) {
goto cleanup;
}
__ASSERT_NO_MSG(ep_cur->mps_valid);
numaker_usbd_ep_trigger(ep_cur, ep_cur->mps);
cleanup:
numaker_usbd_unlock(dev);
return rc;
}
int usb_dc_ep_mps(const uint8_t ep)
{
const struct device *dev = numaker_usbd_device_get();
int rc = 0;
struct numaker_usbd_ep *ep_cur;
uint16_t ep_mps = 0;
numaker_usbd_lock(dev);
/* Bind EP context to EP address */
ep_cur = numaker_usbd_ep_mgmt_bind_ep(dev, ep);
if (!ep_cur) {
LOG_ERR("Bind EP context: ep=0x%02x", ep);
rc = -ENOMEM;
goto cleanup;
}
__ASSERT_NO_MSG(ep_cur->mps_valid);
ep_mps = ep_cur->mps;
cleanup:
numaker_usbd_unlock(dev);
return rc == 0 ? ep_mps : rc;
}
int usb_dc_wakeup_request(void)
{
const struct device *dev = numaker_usbd_device_get();
int rc = 0;
LOG_DBG("Remote wakeup");
numaker_usbd_lock(dev);
numaker_usbd_remote_wakeup(dev);
numaker_usbd_unlock(dev);
return rc;
}
static int numaker_udbd_init(const struct device *dev)
{
struct numaker_usbd_data *data = dev->data;
int rc = 0;
/* Initialize all fields to zero */
memset(data, 0x00, sizeof(*data));
k_mutex_init(&data->sync_mutex);
/* Set up interrupt top/bottom halves processing */
k_msgq_init(&data->msgq, (char *)data->msgq_buf, sizeof(struct numaker_usbd_msg),
CONFIG_USB_DC_NUMAKER_MSG_QUEUE_SIZE);
k_thread_create(&data->msg_hdlr_thread, data->msg_hdlr_thread_stack,
CONFIG_USB_DC_NUMAKER_MSG_HANDLER_THREAD_STACK_SIZE,
numaker_usbd_msg_hdlr_thread_main, (void *)dev, NULL, NULL, K_PRIO_COOP(2),
0, K_NO_WAIT);
k_thread_name_set(&data->msg_hdlr_thread, "numaker_usbd");
return rc;
}
#define USB_DC_NUMAKER_INIT(inst) \
PINCTRL_DT_INST_DEFINE(inst); \
\
static void numaker_usbd_irq_config_func_##inst(const struct device *dev) \
{ \
IRQ_CONNECT(DT_INST_IRQN(inst), DT_INST_IRQ(inst, priority), numaker_udbd_isr, \
DEVICE_DT_INST_GET(inst), 0); \
\
irq_enable(DT_INST_IRQN(inst)); \
} \
\
static void numaker_uusbd_irq_unconfig_func_##inst(const struct device *dev) \
{ \
irq_disable(DT_INST_IRQN(inst)); \
} \
\
static const struct numaker_usbd_config numaker_usbd_config_##inst = { \
.base = (USBD_T *)DT_INST_REG_ADDR(inst), \
.reset = RESET_DT_SPEC_INST_GET(inst), \
.clk_modidx = DT_INST_CLOCKS_CELL(inst, clock_module_index), \
.clk_src = DT_INST_CLOCKS_CELL(inst, clock_source), \
.clk_div = DT_INST_CLOCKS_CELL(inst, clock_divider), \
.clkctrl_dev = DEVICE_DT_GET(DT_PARENT(DT_INST_CLOCKS_CTLR(inst))), \
.irq_config_func = numaker_usbd_irq_config_func_##inst, \
.irq_unconfig_func = numaker_uusbd_irq_unconfig_func_##inst, \
.pincfg = PINCTRL_DT_INST_DEV_CONFIG_GET(inst), \
.num_bidir_endpoints = DT_INST_PROP(inst, num_bidir_endpoints), \
.dmabuf_size = DT_INST_PROP(inst, dma_buffer_size), \
.disallow_iso_inout_same = DT_INST_PROP(inst, disallow_iso_in_out_same_number), \
}; \
\
static struct numaker_usbd_data numaker_usbd_data_##inst; \
\
BUILD_ASSERT(DT_INST_PROP(inst, num_bidir_endpoints) <= NUMAKER_USBD_EP_MAXNUM, \
"num_bidir_endpoints exceeds support limit by USBD driver"); \
\
DEVICE_DT_INST_DEFINE(inst, numaker_udbd_init, NULL, &numaker_usbd_data_##inst, \
&numaker_usbd_config_##inst, POST_KERNEL, \
CONFIG_KERNEL_INIT_PRIORITY_DEVICE, NULL);
USB_DC_NUMAKER_INIT(0);
/* Get USB DC device context instance 0 */
static inline const struct device *numaker_usbd_device_get(void)
{
return DEVICE_DT_INST_GET(0);
}