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Seems like fixed ep0 issues, code format. 

Signed-off-by: HiFiPhile <admin@hifiphile.com>
This commit is contained in:
HiFiPhile 2021-03-03 19:34:53 +01:00 committed by MasterPhi
parent e7bee80948
commit 4f4a33b378
1 changed files with 349 additions and 398 deletions
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211
src/portable/microchip/same70/dcd_same70.c
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@ -2,7 +2,7 @@
* The MIT License (MIT) * The MIT License (MIT)
* *
* Copyright (c) 2018, hathach (tinyusb.org) * Copyright (c) 2018, hathach (tinyusb.org)
* Copyright (c) 2020, HiFiPhile * Copyright (c) 2021, HiFiPhile
* *
* Permission is hereby granted, free of charge, to any person obtaining a copy * Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal * of this software and associated documentation files (the "Software"), to deal
@ -35,7 +35,6 @@
#include "sam.h" #include "sam.h"
#include "SEGGER_RTT.h"
//--------------------------------------------------------------------+ //--------------------------------------------------------------------+
// MACRO TYPEDEF CONSTANT ENUM DECLARATION // MACRO TYPEDEF CONSTANT ENUM DECLARATION
//--------------------------------------------------------------------+ //--------------------------------------------------------------------+
@ -50,7 +49,7 @@
# define USBHS_RAM_ADDR 0xA0100000u # define USBHS_RAM_ADDR 0xA0100000u
#endif #endif
#define get_ep_fifo_ptr(ep, scale) (((volatile TU_XSTRCAT(TU_STRCAT(uint, scale),_t) (*)[0x8000 / ((scale) / 8)])USBHS_RAM_ADDR)[(ep)]) #define get_ep_fifo_ptr(ep, scale) (((TU_XSTRCAT(TU_STRCAT(uint, scale),_t) (*)[0x8000 / ((scale) / 8)])USBHS_RAM_ADDR)[(ep)])
#define EP_MAX 10 #define EP_MAX 10
@ -66,13 +65,8 @@ xfer_ctl_t xfer_status[EP_MAX+1];
static const tusb_desc_endpoint_t ep0_desc = static const tusb_desc_endpoint_t ep0_desc =
{ {
.bLength = sizeof(tusb_desc_endpoint_t),
.bDescriptorType = TUSB_DESC_ENDPOINT,
.bEndpointAddress = 0x00, .bEndpointAddress = 0x00,
.bmAttributes = { .xfer = TUSB_XFER_CONTROL },
.wMaxPacketSize = { .size = CFG_TUD_ENDPOINT0_SIZE }, .wMaxPacketSize = { .size = CFG_TUD_ENDPOINT0_SIZE },
.bInterval = 0
}; };
static tusb_speed_t get_speed(void); static tusb_speed_t get_speed(void);
@ -111,13 +105,10 @@ void dcd_int_disable (uint8_t rhport)
// Receive Set Address request, mcu port must also include status IN response // Receive Set Address request, mcu port must also include status IN response
void dcd_set_address (uint8_t rhport, uint8_t dev_addr) void dcd_set_address (uint8_t rhport, uint8_t dev_addr)
{ {
(void) rhport; // DCD can only set address after status for this request is complete
// Set the address but keep it disabled for now. It should be enabled // do it at dcd_edpt0_status_complete()
// only after the ack to the host completes.
USBHS->USBHS_DEVCTRL &= ~(USBHS_DEVCTRL_UADD_Msk | USBHS_DEVCTRL_ADDEN);
USBHS->USBHS_DEVCTRL |= USBHS_DEVCTRL_UADD(dev_addr);
// Respond with status // Response with zlp status
dcd_edpt_xfer(rhport, tu_edpt_addr(0, TUSB_DIR_IN), NULL, 0); dcd_edpt_xfer(rhport, tu_edpt_addr(0, TUSB_DIR_IN), NULL, 0);
} }
@ -168,7 +159,7 @@ void dcd_disconnect(uint8_t rhport)
// Unfreeze USB clock // Unfreeze USB clock
USBHS->USBHS_CTRL &= ~USBHS_CTRL_FRZCLK; USBHS->USBHS_CTRL &= ~USBHS_CTRL_FRZCLK;
// Wait to unfreeze clock // Wait to unfreeze clock
while(USBHS_SR_CLKUSABLE != (USBHS->USBHS_SR & USBHS_SR_CLKUSABLE)); while (USBHS_SR_CLKUSABLE != (USBHS->USBHS_SR & USBHS_SR_CLKUSABLE));
// Clear all the pending interrupts // Clear all the pending interrupts
USBHS->USBHS_DEVICR = USBHS_DEVICR_Msk; USBHS->USBHS_DEVICR = USBHS_DEVICR_Msk;
// Disable all interrupts // Disable all interrupts
@ -182,8 +173,7 @@ void dcd_disconnect(uint8_t rhport)
static tusb_speed_t get_speed(void) static tusb_speed_t get_speed(void)
{ {
switch((USBHS->USBHS_SR & USBHS_SR_SPEED_Msk) >> USBHS_SR_SPEED_Pos) switch ((USBHS->USBHS_SR & USBHS_SR_SPEED_Msk) >> USBHS_SR_SPEED_Pos) {
{
case USBHS_SR_SPEED_FULL_SPEED_Val: case USBHS_SR_SPEED_FULL_SPEED_Val:
default: default:
return TUSB_SPEED_FULL; return TUSB_SPEED_FULL;
@ -196,95 +186,71 @@ static tusb_speed_t get_speed(void)
static void dcd_ep_handler(uint8_t ep_ix) static void dcd_ep_handler(uint8_t ep_ix)
{ {
uint32_t int_status = USBHS->USBHS_DEVEPTISR[ep_ix] & USBHS->USBHS_DEVEPTIMR[ep_ix]; uint32_t int_status = USBHS->USBHS_DEVEPTISR[ep_ix];
uint32_t dev_ctrl = USBHS->USBHS_DEVCTRL; int_status &= USBHS->USBHS_DEVEPTIMR[ep_ix];
uint16_t count = (USBHS->USBHS_DEVEPTISR[ep_ix] & uint16_t count = (USBHS->USBHS_DEVEPTISR[ep_ix] &
USBHS_DEVEPTISR_BYCT_Msk) >> USBHS_DEVEPTISR_BYCT_Pos; USBHS_DEVEPTISR_BYCT_Msk) >> USBHS_DEVEPTISR_BYCT_Pos;
SEGGER_RTT_printf(0, "ep: %u %u %u \r\n", ep_ix, count, int_status); if (ep_ix == 0U) {
if(ep_ix == 0U)
{
if (int_status & USBHS_DEVEPTISR_CTRL_RXSTPI) { if (int_status & USBHS_DEVEPTISR_CTRL_RXSTPI) {
// Setup packet should always be 8 bytes. If not, ignore it, and try again.
// Get 8-bit access to endpoint 0 FIFO from USB RAM address if (count == 8)
volatile uint8_t *ptr = get_ep_fifo_ptr(0,8); {
SCB_InvalidateDCache_by_Addr((uint32_t *) ptr, 8); uint8_t *ptr = get_ep_fifo_ptr(0,8);
dcd_event_setup_received(0, (uint8_t*)ptr, true); dcd_event_setup_received(0, ptr, true);
}
// Acknowledge the interrupt // Acknowledge the interrupt
USBHS->USBHS_DEVEPTICR[0] = USBHS_DEVEPTICR_RXSTPIC; USBHS->USBHS_DEVEPTICR[0] = USBHS_DEVEPTICR_RXSTPIC;
} }
if (int_status & USBHS_DEVEPTISR_RXOUTI) { if (int_status & USBHS_DEVEPTISR_RXOUTI) {
// Disable the interrupt
//USBHS->USBHS_DEVEPTIDR[ep_ix] = USBHS_DEVEPTIDR_RXOUTEC;
xfer_ctl_t *xfer = &xfer_status[0]; xfer_ctl_t *xfer = &xfer_status[0];
if (count) {
if(count) uint8_t *ptr = get_ep_fifo_ptr(0,8);
{
volatile uint8_t *ptr = get_ep_fifo_ptr(0,8);
for (int i = 0; i < count; i++) { for (int i = 0; i < count; i++) {
xfer->buffer[xfer->queued_len + i] = ptr[i]; xfer->buffer[xfer->queued_len + i] = ptr[i];
} }
xfer->queued_len = (uint16_t)(xfer->queued_len + count); xfer->queued_len = (uint16_t)(xfer->queued_len + count);
} }
// Acknowledge the interrupt
USBHS->USBHS_DEVEPTICR[0] = USBHS_DEVEPTICR_RXOUTIC; USBHS->USBHS_DEVEPTICR[0] = USBHS_DEVEPTICR_RXOUTIC;
if ((count < xfer->max_packet_size) || (xfer->queued_len == xfer->total_len)) {
if ((count < xfer->max_packet_size) || (xfer->queued_len == xfer->total_len))
{
// RX COMPLETE // RX COMPLETE
dcd_event_xfer_complete(0, 0, xfer->queued_len, XFER_RESULT_SUCCESS, true); dcd_event_xfer_complete(0, 0, xfer->queued_len, XFER_RESULT_SUCCESS, true);
xfer->queued_len = 0; // Disable the interrupt
SEGGER_RTT_printf(0, "rx: %u \r\n", xfer->queued_len); USBHS->USBHS_DEVEPTIDR[0] = USBHS_DEVEPTIDR_RXOUTEC;
// Though the host could still send, we don't know. // Though the host could still send, we don't know.
} }
} }
if (int_status & USBHS_DEVEPTISR_TXINI) { if (int_status & USBHS_DEVEPTISR_TXINI) {
// Disable the interrupt // Disable the interrupt
USBHS->USBHS_DEVEPTIDR[0] = USBHS_DEVEPTIDR_TXINEC; USBHS->USBHS_DEVEPTIDR[0] = USBHS_DEVEPTIDR_TXINEC;
if (!(dev_ctrl & USBHS_DEVCTRL_ADDEN) &&
(dev_ctrl & USBHS_DEVCTRL_UADD_Msk) != 0U) {
// Commit the pending address update. This
// must be done after the ack to the host
// completes else the ack will get dropped.
USBHS->USBHS_DEVCTRL = dev_ctrl | USBHS_DEVCTRL_ADDEN;
}
xfer_ctl_t * xfer = &xfer_status[EP_MAX]; xfer_ctl_t * xfer = &xfer_status[EP_MAX];
if((xfer->total_len != xfer->queued_len)) // TX not complete if ((xfer->total_len != xfer->queued_len)) {
{ // TX not complete
dcd_transmit_packet(xfer, 0); dcd_transmit_packet(xfer, 0);
} }
else // TX Complete else {
{ // TX complete
dcd_event_xfer_complete(0, (uint8_t)(0x80 + 0), xfer->total_len, XFER_RESULT_SUCCESS, true); dcd_event_xfer_complete(0, (uint8_t)(0x80 + 0), xfer->total_len, XFER_RESULT_SUCCESS, true);
} }
} }
} }
else else {
{
if (int_status & USBHS_DEVEPTISR_RXOUTI) { if (int_status & USBHS_DEVEPTISR_RXOUTI) {
// Acknowledge the interrupt
USBHS->USBHS_DEVEPTICR[ep_ix] = USBHS_DEVEPTICR_RXOUTIC;
xfer_ctl_t *xfer = &xfer_status[ep_ix]; xfer_ctl_t *xfer = &xfer_status[ep_ix];
if (count) {
if(count) uint8_t *ptr = get_ep_fifo_ptr(ep_ix,8);
{ memcpy(xfer->buffer + xfer->queued_len, ptr, count);
volatile uint8_t *ptr = get_ep_fifo_ptr(ep_ix,8);
for (int i = 0; i < count; i++) {
xfer->buffer[xfer->queued_len + i] = ptr[i];
}
xfer->queued_len = (uint16_t)(xfer->queued_len + count); xfer->queued_len = (uint16_t)(xfer->queued_len + count);
} }
// Acknowledge the interrupt
USBHS->USBHS_DEVEPTICR[ep_ix] = USBHS_DEVEPTICR_RXOUTIC;
// Clear the FIFO control flag to receive more data. // Clear the FIFO control flag to receive more data.
USBHS->USBHS_DEVEPTIDR[ep_ix] = USBHS_DEVEPTIDR_FIFOCONC; USBHS->USBHS_DEVEPTIDR[ep_ix] = USBHS_DEVEPTIDR_FIFOCONC;
if ((count < xfer->max_packet_size) || (xfer->queued_len == xfer->total_len)) if ((count < xfer->max_packet_size) || (xfer->queued_len == xfer->total_len)) {
{
// RX COMPLETE // RX COMPLETE
dcd_event_xfer_complete(0, ep_ix, xfer->queued_len, XFER_RESULT_SUCCESS, true); dcd_event_xfer_complete(0, ep_ix, xfer->queued_len, XFER_RESULT_SUCCESS, true);
xfer->queued_len = 0; // Disable the interrupt
USBHS->USBHS_DEVEPTIDR[ep_ix] = USBHS_DEVEPTIDR_RXOUTEC;
// Though the host could still send, we don't know. // Though the host could still send, we don't know.
} }
} }
@ -292,12 +258,12 @@ static void dcd_ep_handler(uint8_t ep_ix)
// Acknowledge the interrupt // Acknowledge the interrupt
USBHS->USBHS_DEVEPTICR[ep_ix] = USBHS_DEVEPTICR_TXINIC; USBHS->USBHS_DEVEPTICR[ep_ix] = USBHS_DEVEPTICR_TXINIC;
xfer_ctl_t * xfer = &xfer_status[ep_ix];; xfer_ctl_t * xfer = &xfer_status[ep_ix];;
if((xfer->total_len != xfer->queued_len)) // TX not complete if ((xfer->total_len != xfer->queued_len)) {
{ // TX not complete
dcd_transmit_packet(xfer, ep_ix); dcd_transmit_packet(xfer, ep_ix);
} }
else // TX Complete else {
{ // TX complete
dcd_event_xfer_complete(0, (uint8_t)(0x80 + ep_ix), xfer->total_len, XFER_RESULT_SUCCESS, true); dcd_event_xfer_complete(0, (uint8_t)(0x80 + ep_ix), xfer->total_len, XFER_RESULT_SUCCESS, true);
} }
} }
@ -314,14 +280,9 @@ void dcd_int_handler(uint8_t rhport)
USBHS->USBHS_CTRL &= ~USBHS_CTRL_FRZCLK; USBHS->USBHS_CTRL &= ~USBHS_CTRL_FRZCLK;
while(USBHS_SR_CLKUSABLE != (USBHS->USBHS_SR & USBHS_SR_CLKUSABLE)); while(USBHS_SR_CLKUSABLE != (USBHS->USBHS_SR & USBHS_SR_CLKUSABLE));
// Reset all endpoints // Reset all endpoints
for (int ep_ix = 1; ep_ix < EP_MAX; ep_ix++) for (int ep_ix = 1; ep_ix < EP_MAX; ep_ix++) {
{ USBHS->USBHS_DEVEPT |= 1 << (USBHS_DEVEPT_EPRST0_Pos + ep_ix);
// Disable endpoint interrupt USBHS->USBHS_DEVEPT &=~(1 << (USBHS_DEVEPT_EPRST0_Pos + ep_ix));
USBHS->USBHS_DEVIDR = 1 << (USBHS_DEVIDR_PEP_0_Pos + ep_ix);
// Disable endpoint and SETUP, IN or OUT interrupts
USBHS->USBHS_DEVEPT &= ~ (1 << (USBHS_DEVEPT_EPEN0_Pos + ep_ix));
// Free all endpoint memory
USBHS->USBHS_DEVEPTCFG[ep_ix] &= ~USBHS_DEVEPTCFG_ALLOC;
} }
dcd_edpt_open (0, &ep0_desc); dcd_edpt_open (0, &ep0_desc);
// Acknowledge the End of Reset interrupt // Acknowledge the End of Reset interrupt
@ -340,7 +301,7 @@ void dcd_int_handler(uint8_t rhport)
// Unfreeze USB clock // Unfreeze USB clock
USBHS->USBHS_CTRL &= ~USBHS_CTRL_FRZCLK; USBHS->USBHS_CTRL &= ~USBHS_CTRL_FRZCLK;
// Wait to unfreeze clock // Wait to unfreeze clock
while(USBHS_SR_CLKUSABLE != (USBHS->USBHS_SR & USBHS_SR_CLKUSABLE)); while (USBHS_SR_CLKUSABLE != (USBHS->USBHS_SR & USBHS_SR_CLKUSABLE));
// Acknowledge the Wakeup interrupt // Acknowledge the Wakeup interrupt
USBHS->USBHS_DEVICR = USBHS_DEVICR_WAKEUPC; USBHS->USBHS_DEVICR = USBHS_DEVICR_WAKEUPC;
// Disable Wakeup Interrupt // Disable Wakeup Interrupt
@ -355,7 +316,7 @@ void dcd_int_handler(uint8_t rhport)
// Unfreeze USB clock // Unfreeze USB clock
USBHS->USBHS_CTRL &= ~USBHS_CTRL_FRZCLK; USBHS->USBHS_CTRL &= ~USBHS_CTRL_FRZCLK;
// Wait to unfreeze clock // Wait to unfreeze clock
while(USBHS_SR_CLKUSABLE != (USBHS->USBHS_SR & USBHS_SR_CLKUSABLE)); while (USBHS_SR_CLKUSABLE != (USBHS->USBHS_SR & USBHS_SR_CLKUSABLE));
// Acknowledge the suspend interrupt // Acknowledge the suspend interrupt
USBHS->USBHS_DEVICR = USBHS_DEVICR_SUSPC; USBHS->USBHS_DEVICR = USBHS_DEVICR_SUSPC;
// Disable Suspend Interrupt // Disable Suspend Interrupt
@ -385,6 +346,21 @@ void dcd_int_handler(uint8_t rhport)
//--------------------------------------------------------------------+ //--------------------------------------------------------------------+
// Endpoint API // Endpoint API
//--------------------------------------------------------------------+ //--------------------------------------------------------------------+
// Invoked when a control transfer's status stage is complete.
// May help DCD to prepare for next control transfer, this API is optional.
void dcd_edpt0_status_complete(uint8_t rhport, tusb_control_request_t const * request)
{
(void) rhport;
if (request->bmRequestType_bit.recipient == TUSB_REQ_RCPT_DEVICE &&
request->bmRequestType_bit.type == TUSB_REQ_TYPE_STANDARD &&
request->bRequest == TUSB_REQ_SET_ADDRESS )
{
uint8_t const dev_addr = (uint8_t) request->wValue;
USBHS->USBHS_DEVCTRL |= dev_addr | USBHS_DEVCTRL_ADDEN;
}
}
// Configure endpoint's registers according to descriptor // Configure endpoint's registers according to descriptor
bool dcd_edpt_open (uint8_t rhport, tusb_desc_endpoint_t const * ep_desc) bool dcd_edpt_open (uint8_t rhport, tusb_desc_endpoint_t const * ep_desc)
@ -397,18 +373,18 @@ bool dcd_edpt_open (uint8_t rhport, tusb_desc_endpoint_t const * ep_desc)
uint8_t fifoSize = 0; // FIFO size uint8_t fifoSize = 0; // FIFO size
uint16_t defaultEndpointSize = 8; // Default size of Endpoint uint16_t defaultEndpointSize = 8; // Default size of Endpoint
// Find upper 2 power number of epMaxPktSize // Find upper 2 power number of epMaxPktSize
if(epMaxPktSize) if (epMaxPktSize) {
{ while (defaultEndpointSize < epMaxPktSize) {
while (defaultEndpointSize < epMaxPktSize)
{
fifoSize++; fifoSize++;
defaultEndpointSize <<= 1; defaultEndpointSize <<= 1;
} }
} }
xfer_status[epnum].max_packet_size = epMaxPktSize; xfer_status[epnum].max_packet_size = epMaxPktSize;
if(epnum == 0) USBHS->USBHS_DEVEPT |= 1 << (USBHS_DEVEPT_EPRST0_Pos + epnum);
{ USBHS->USBHS_DEVEPT &=~(1 << (USBHS_DEVEPT_EPRST0_Pos + epnum));
if (epnum == 0) {
xfer_status[EP_MAX].max_packet_size = epMaxPktSize; xfer_status[EP_MAX].max_packet_size = epMaxPktSize;
// Enable the control endpoint - Endpoint 0 // Enable the control endpoint - Endpoint 0
USBHS->USBHS_DEVEPT |= USBHS_DEVEPT_EPEN0; USBHS->USBHS_DEVEPT |= USBHS_DEVEPT_EPEN0;
@ -422,22 +398,19 @@ bool dcd_edpt_open (uint8_t rhport, tusb_desc_endpoint_t const * ep_desc)
); );
USBHS->USBHS_DEVEPTIER[0] = USBHS_DEVEPTIER_RSTDTS; USBHS->USBHS_DEVEPTIER[0] = USBHS_DEVEPTIER_RSTDTS;
USBHS->USBHS_DEVEPTIDR[0] = USBHS_DEVEPTIDR_STALLRQC; USBHS->USBHS_DEVEPTIDR[0] = USBHS_DEVEPTIDR_STALLRQC;
if(USBHS_DEVEPTISR_CFGOK == (USBHS->USBHS_DEVEPTISR[0] & USBHS_DEVEPTISR_CFGOK)) if (USBHS_DEVEPTISR_CFGOK == (USBHS->USBHS_DEVEPTISR[0] & USBHS_DEVEPTISR_CFGOK)) {
{
// Endpoint configuration is successful // Endpoint configuration is successful
USBHS->USBHS_DEVEPTIER[0] = USBHS_DEVEPTIER_RXSTPES | USBHS_DEVEPTIER_RXOUTES; USBHS->USBHS_DEVEPTIER[0] = USBHS_DEVEPTIER_RXSTPES;
// Enable Endpoint 0 Interrupts // Enable Endpoint 0 Interrupts
USBHS->USBHS_DEVIER = USBHS_DEVIER_PEP_0; USBHS->USBHS_DEVIER = USBHS_DEVIER_PEP_0;
return true; return true;
} }
else else {
{
// Endpoint configuration is not successful // Endpoint configuration is not successful
return false; return false;
} }
} }
else else {
{
// Enable the endpoint // Enable the endpoint
USBHS->USBHS_DEVEPT |= ((0x01 << epnum) << USBHS_DEVEPT_EPEN0_Pos); USBHS->USBHS_DEVEPT |= ((0x01 << epnum) << USBHS_DEVEPT_EPEN0_Pos);
// Set up the maxpacket size, fifo start address fifosize // Set up the maxpacket size, fifo start address fifosize
@ -447,33 +420,25 @@ bool dcd_edpt_open (uint8_t rhport, tusb_desc_endpoint_t const * ep_desc)
USBHS_DEVEPTCFG_EPSIZE(fifoSize) | USBHS_DEVEPTCFG_EPSIZE(fifoSize) |
USBHS_DEVEPTCFG_EPTYPE(eptype) | USBHS_DEVEPTCFG_EPTYPE(eptype) |
USBHS_DEVEPTCFG_EPBK(USBHS_DEVEPTCFG_EPBK_1_BANK) | USBHS_DEVEPTCFG_EPBK(USBHS_DEVEPTCFG_EPBK_1_BANK) |
USBHS_DEVEPTCFG_ALLOC |
((dir & 0x01) << USBHS_DEVEPTCFG_EPDIR_Pos) ((dir & 0x01) << USBHS_DEVEPTCFG_EPDIR_Pos)
); );
if (eptype == TUSB_XFER_ISOCHRONOUS) if (eptype == TUSB_XFER_ISOCHRONOUS){
{ USBHS->USBHS_DEVEPTCFG[epnum] |= USBHS_DEVEPTCFG_NBTRANS(1) | USBHS_DEVEPTCFG_EPBK_2_BANK;
USBHS->USBHS_DEVEPTCFG[epnum] |= USBHS_DEVEPTCFG_NBTRANS(1);
} }
USBHS->USBHS_DEVEPTCFG[epnum] |= USBHS_DEVEPTCFG_ALLOC;
USBHS->USBHS_DEVEPTIER[epnum] = USBHS_DEVEPTIER_RSTDTS; USBHS->USBHS_DEVEPTIER[epnum] = USBHS_DEVEPTIER_RSTDTS;
USBHS->USBHS_DEVEPTIDR[epnum] = USBHS_DEVEPTIDR_STALLRQC; USBHS->USBHS_DEVEPTIDR[epnum] = USBHS_DEVEPTIDR_STALLRQC;
if(USBHS_DEVEPTISR_CFGOK == (USBHS->USBHS_DEVEPTISR[epnum] & USBHS_DEVEPTISR_CFGOK)) if (USBHS_DEVEPTISR_CFGOK == (USBHS->USBHS_DEVEPTISR[epnum] & USBHS_DEVEPTISR_CFGOK)) {
{
// Endpoint configuration is successful. Enable Endpoint Interrupts // Endpoint configuration is successful. Enable Endpoint Interrupts
if(dir == TUSB_DIR_OUT) if (dir == TUSB_DIR_IN) {
{
USBHS->USBHS_DEVEPTIER[epnum] = USBHS_DEVEPTIER_RXOUTES;
}
else
{
USBHS->USBHS_DEVEPTICR[epnum] = USBHS_DEVEPTICR_TXINIC; USBHS->USBHS_DEVEPTICR[epnum] = USBHS_DEVEPTICR_TXINIC;
USBHS->USBHS_DEVEPTIER[epnum] = USBHS_DEVEPTIER_TXINES; USBHS->USBHS_DEVEPTIER[epnum] = USBHS_DEVEPTIER_TXINES;
} }
USBHS->USBHS_DEVIER = ((0x01 << epnum) << USBHS_DEVIER_PEP_0_Pos); USBHS->USBHS_DEVIER = ((0x01 << epnum) << USBHS_DEVIER_PEP_0_Pos);
return true; return true;
} }
else else {
{
// Endpoint configuration is not successful // Endpoint configuration is not successful
return false; return false;
} }
@ -484,33 +449,27 @@ static void dcd_transmit_packet(xfer_ctl_t * xfer, uint8_t ep_ix)
{ {
uint16_t len = (uint16_t)(xfer->total_len - xfer->queued_len); uint16_t len = (uint16_t)(xfer->total_len - xfer->queued_len);
if(len > xfer->max_packet_size) // max packet size for FS transfer if (len > xfer->max_packet_size) {
{
len = xfer->max_packet_size; len = xfer->max_packet_size;
} }
volatile uint8_t *ptr = get_ep_fifo_ptr(ep_ix,8); uint8_t *ptr = get_ep_fifo_ptr(ep_ix,8);
for (int i = 0; i < len; i++) { memcpy(ptr, xfer->buffer + xfer->queued_len, len);
ptr[i] = xfer->buffer[xfer->queued_len + i];
}
xfer->queued_len = (uint16_t)(xfer->queued_len + len); xfer->queued_len = (uint16_t)(xfer->queued_len + len);
if (ep_ix == 0U) { if (ep_ix == 0U) {
// Control endpoint: clear the interrupt flag to send the data, // Control endpoint: clear the interrupt flag to send the data,
// and re-enable the interrupts to trigger an interrupt at the // and re-enable the interrupts to trigger an interrupt at the
// end of the transfer. // end of the transfer.
USBHS->USBHS_DEVEPTICR[0] = USBHS_DEVEPTICR_TXINIC; USBHS->USBHS_DEVEPTICR[0] = USBHS_DEVEPTICR_TXINIC;
USBHS->USBHS_DEVEPTIER[0] = USBHS_DEVEPTIER_TXINES; USBHS->USBHS_DEVEPTIER[0] = USBHS_DEVEPTIER_TXINES;
} else { } else {
// Other endpoint types: clear the FIFO control flag to send the data. // Other endpoint types: clear the FIFO control flag to send the data.
USBHS->USBHS_DEVEPTIDR[ep_ix] = USBHS_DEVEPTIDR_FIFOCONC; USBHS->USBHS_DEVEPTIDR[ep_ix] = USBHS_DEVEPTIDR_FIFOCONC;
} }
} }
// Submit a transfer, When complete dcd_event_xfer_complete() is invoked to notify the stack // Submit a transfer, When complete dcd_event_xfer_complete() is invoked to notify the stack
bool dcd_edpt_xfer (uint8_t rhport, uint8_t ep_addr, uint8_t * buffer, uint16_t total_bytes) bool dcd_edpt_xfer (uint8_t rhport, uint8_t ep_addr, uint8_t * buffer, uint16_t total_bytes)
{ {
@ -527,18 +486,10 @@ bool dcd_edpt_xfer (uint8_t rhport, uint8_t ep_addr, uint8_t * buffer, uint16_t
xfer->total_len = total_bytes; xfer->total_len = total_bytes;
xfer->queued_len = 0; xfer->queued_len = 0;
SEGGER_RTT_printf(0, "xfer: %u %u %u \r\n", epnum, dir, total_bytes); if (dir == TUSB_DIR_OUT){
USBHS->USBHS_DEVEPTIER[epnum] = USBHS_DEVEPTIER_RXOUTES;
if ( dir == TUSB_DIR_OUT )
{
// Endpoint configuration is successful
// Acknowledge the interrupt
//USBHS->USBHS_DEVEPTICR[epnum] = USBHS_DEVEPTICR_RXOUTIC;
//USBHS->USBHS_DEVEPTIER[epnum] = USBHS_DEVEPTIER_RXOUTES;
} }
else // IN else {
{
dcd_transmit_packet(xfer,epnum); dcd_transmit_packet(xfer,epnum);
} }
return true; return true;