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fomu: semi-working dcd file

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Signed-off-by: Sean Cross <sean@xobs.io>
This commit is contained in:
Sean Cross 2019-10-31 08:35:04 +08:00
parent 83bca4a74f
commit 835a72c595
1 changed files with 93 additions and 40 deletions
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133
src/portable/foosn/fomu/dcd_fomu.c
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@ -26,6 +26,10 @@
#include "tusb_option.h" #include "tusb_option.h"
#ifndef DEBUG
#define DEBUG 0
#endif
// #if TUSB_OPT_DEVICE_ENABLED && (CFG_TUSB_MCU == OPT_MCU_FOMU_EPTRI) // #if TUSB_OPT_DEVICE_ENABLED && (CFG_TUSB_MCU == OPT_MCU_FOMU_EPTRI)
#if 1 #if 1
@ -48,16 +52,17 @@ uint8_t volatile * rx_buffer[16];
uint16_t volatile rx_buffer_max[16]; uint16_t volatile rx_buffer_max[16];
volatile uint8_t tx_ep; volatile uint8_t tx_ep;
volatile bool tx_active;
volatile uint16_t tx_buffer_offset[16]; volatile uint16_t tx_buffer_offset[16];
uint8_t volatile * tx_buffer[16]; uint8_t volatile * tx_buffer[16];
volatile uint16_t tx_buffer_max[16]; volatile uint16_t tx_buffer_max[16];
volatile uint8_t reset_count; volatile uint8_t reset_count;
#ifdef DEBUG
__attribute__((used)) uint8_t volatile * last_tx_buffer; __attribute__((used)) uint8_t volatile * last_tx_buffer;
__attribute__((used)) volatile uint8_t last_tx_ep; __attribute__((used)) volatile uint8_t last_tx_ep;
#endif
uint8_t setup_packet_bfr[10]; uint8_t setup_packet_bfr[10];
//--------------------------------------------------------------------+ //--------------------------------------------------------------------+
// PIPE HELPER // PIPE HELPER
//--------------------------------------------------------------------+ //--------------------------------------------------------------------+
@ -86,27 +91,35 @@ static void tx_more_data(void) {
} }
static void process_tx(bool in_isr) { static void process_tx(bool in_isr) {
// If the buffer is now empty, search for the next buffer to fill. #if DEBUG
if (!tx_buffer[tx_ep]) {
if (advance_tx_ep())
tx_more_data();
return;
}
// If the system isn't idle, then something is very wrong. // If the system isn't idle, then something is very wrong.
uint8_t in_status = usb_in_status_read(); uint8_t in_status = usb_in_status_read();
if (!(in_status & (1 << CSR_USB_IN_STATUS_IDLE_OFFSET))) if (!(in_status & (1 << CSR_USB_IN_STATUS_IDLE_OFFSET)))
fomu_error(__LINE__); fomu_error(__LINE__);
#endif
// If the buffer is now empty, search for the next buffer to fill.
if (!tx_buffer[tx_ep]) {
if (advance_tx_ep())
tx_more_data();
else
tx_active = false;
return;
}
tx_buffer_offset[tx_ep] += EP_SIZE; tx_buffer_offset[tx_ep] += EP_SIZE;
if (tx_buffer_offset[tx_ep] >= tx_buffer_max[tx_ep]) { if (tx_buffer_offset[tx_ep] >= tx_buffer_max[tx_ep]) {
#if DEBUG
last_tx_buffer = tx_buffer[tx_ep]; last_tx_buffer = tx_buffer[tx_ep];
last_tx_ep = tx_ep; last_tx_ep = tx_ep;
#endif
tx_buffer[tx_ep] = NULL; tx_buffer[tx_ep] = NULL;
dcd_event_xfer_complete(0, tu_edpt_addr(tx_ep, TUSB_DIR_IN), tx_buffer_max[tx_ep], XFER_RESULT_SUCCESS, in_isr);
if (!advance_tx_ep()) if (!advance_tx_ep())
tx_active = false;
dcd_event_xfer_complete(0, tu_edpt_addr(tx_ep, TUSB_DIR_IN), tx_buffer_max[tx_ep], XFER_RESULT_SUCCESS, in_isr);
if (!tx_active)
return; return;
} }
@ -115,61 +128,85 @@ static void process_tx(bool in_isr) {
} }
static void process_rx(bool in_isr) { static void process_rx(bool in_isr) {
// If the OUT handler is still waiting to send, don't do anything.
uint8_t out_status = usb_out_status_read(); uint8_t out_status = usb_out_status_read();
#if DEBUG
// If the OUT handler is still waiting to send, don't do anything.
if (!(out_status & (1 << CSR_USB_OUT_STATUS_HAVE_OFFSET))) if (!(out_status & (1 << CSR_USB_OUT_STATUS_HAVE_OFFSET)))
fomu_error(__LINE__); fomu_error(__LINE__);
// return; // return;
#endif
uint8_t rx_ep = (out_status >> CSR_USB_OUT_STATUS_EPNO_OFFSET) & 0xf; uint8_t rx_ep = (out_status >> CSR_USB_OUT_STATUS_EPNO_OFFSET) & 0xf;
// If the destination buffer doesn't exist, don't drain the hardware // If the destination buffer doesn't exist, don't drain the hardware
// fifo. Note that this can cause deadlocks if the host is waiting // fifo. Note that this can cause deadlocks if the host is waiting
// on some other endpoint's data! // on some other endpoint's data!
#if DEBUG
if (rx_buffer[rx_ep] == NULL) { if (rx_buffer[rx_ep] == NULL) {
fomu_error(__LINE__); fomu_error(__LINE__);
return; return;
} }
#endif
// Drain the FIFO into the destination buffer
uint32_t total_read = 0; uint32_t total_read = 0;
uint32_t current_offset = rx_buffer_offset[rx_ep]; uint32_t current_offset = rx_buffer_offset[rx_ep];
#if DEBUG
if (current_offset > rx_buffer_max[rx_ep]) if (current_offset > rx_buffer_max[rx_ep])
fomu_error(__LINE__); fomu_error(__LINE__);
#endif
while (usb_out_status_read() & (1 << CSR_USB_OUT_STATUS_HAVE_OFFSET)) { while (usb_out_status_read() & (1 << CSR_USB_OUT_STATUS_HAVE_OFFSET)) {
uint8_t c = usb_out_data_read(); uint8_t c = usb_out_data_read();
total_read++; total_read++;
if ((rx_buffer_offset[rx_ep] + current_offset) < rx_buffer_max[rx_ep]) if ((rx_buffer_offset[rx_ep] + current_offset) < rx_buffer_max[rx_ep])
rx_buffer[rx_ep][current_offset++] = c; rx_buffer[rx_ep][current_offset++] = c;
} }
#if DEBUG
if (total_read > 66) if (total_read > 66)
fomu_error(__LINE__); fomu_error(__LINE__);
if (total_read < 2)
fomu_error(__LINE__);
#endif
// Strip off the CRC16 // Strip off the CRC16
rx_buffer_offset[rx_ep] += (total_read - 2); rx_buffer_offset[rx_ep] += (total_read - 2);
if (rx_buffer_offset[rx_ep] > rx_buffer_max[rx_ep]) if (rx_buffer_offset[rx_ep] > rx_buffer_max[rx_ep])
rx_buffer_offset[rx_ep] = rx_buffer_max[rx_ep]; rx_buffer_offset[rx_ep] = rx_buffer_max[rx_ep];
// If there's no more data, complete the transfer to tinyusb
if (rx_buffer_max[rx_ep] == rx_buffer_offset[rx_ep]) { if (rx_buffer_max[rx_ep] == rx_buffer_offset[rx_ep]) {
#if DEBUG
if (rx_buffer[rx_ep] == NULL) if (rx_buffer[rx_ep] == NULL)
fomu_error(__LINE__); fomu_error(__LINE__);
#endif
// Disable this endpoint (causing it to respond NAK) until we have // Free up this buffer.
// a buffer to place the data into.
rx_buffer[rx_ep] = NULL; rx_buffer[rx_ep] = NULL;
uint16_t len = rx_buffer_offset[rx_ep]; uint16_t len = rx_buffer_offset[rx_ep];
// uint16_t ep_en_mask = usb_out_enable_status_read(); #if DEBUG
// int i; // Validate that all enabled endpoints have buffers,
// for (i = 0; i < 16; i++) { // and no disabled endpoints have buffers.
// if ((!!(ep_en_mask & (1 << i))) ^ (!!(rx_buffer[i]))) uint16_t ep_en_mask = usb_out_enable_status_read();
// fomu_error(__LINE__); int i;
// } for (i = 0; i < 16; i++) {
if ((!!(ep_en_mask & (1 << i))) ^ (!!(rx_buffer[i]))) {
uint8_t new_status = usb_out_status_read();
// Another IRQ came in while we were processing, so ignore this endpoint.
if ((new_status & 0x20) && ((new_status & 0xf) == i))
continue;
fomu_error(__LINE__);
}
}
#endif
dcd_event_xfer_complete(0, tu_edpt_addr(rx_ep, TUSB_DIR_OUT), len, XFER_RESULT_SUCCESS, in_isr); dcd_event_xfer_complete(0, tu_edpt_addr(rx_ep, TUSB_DIR_OUT), len, XFER_RESULT_SUCCESS, in_isr);
return; }
else {
// If there's more data, re-enable data reception on this endpoint
usb_out_ctrl_write((1 << CSR_USB_OUT_CTRL_ENABLE_OFFSET) | rx_ep);
} }
// If there's more data, re-enable data reception // Now that the buffer is drained, clear the pending IRQ.
usb_out_ctrl_write((1 << CSR_USB_OUT_CTRL_ENABLE_OFFSET) | rx_ep); usb_out_ev_pending_write(usb_out_ev_pending_read());
} }
//--------------------------------------------------------------------+ //--------------------------------------------------------------------+
@ -198,6 +235,7 @@ static void dcd_reset(void)
memset((void *)tx_buffer_max, 0, sizeof(tx_buffer_max)); memset((void *)tx_buffer_max, 0, sizeof(tx_buffer_max));
memset((void *)tx_buffer_offset, 0, sizeof(tx_buffer_offset)); memset((void *)tx_buffer_offset, 0, sizeof(tx_buffer_offset));
tx_ep = 0; tx_ep = 0;
tx_active = false;
// Enable all event handlers and clear their contents // Enable all event handlers and clear their contents
usb_setup_ev_pending_write(-1); usb_setup_ev_pending_write(-1);
@ -251,7 +289,7 @@ void dcd_set_address(uint8_t rhport, uint8_t dev_addr)
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);
// Wait for the response packet to get sent // Wait for the response packet to get sent
while (tx_buffer[0] != NULL) while (tx_active)
; ;
// Activate the new address // Activate the new address
@ -305,8 +343,12 @@ void dcd_edpt_stall(uint8_t rhport, uint8_t ep_addr)
if (tu_edpt_number(ep_addr) == 2) if (tu_edpt_number(ep_addr) == 2)
fomu_error(__LINE__); fomu_error(__LINE__);
if (tu_edpt_dir(ep_addr) == TUSB_DIR_OUT) if (tu_edpt_dir(ep_addr) == TUSB_DIR_OUT) {
usb_out_ctrl_write((1 << CSR_USB_OUT_CTRL_STALL_OFFSET) | (1 << CSR_USB_OUT_CTRL_ENABLE_OFFSET) | tu_edpt_number(ep_addr)); uint8_t enable = 0;
if (rx_buffer[ep_addr])
enable = 1;
usb_out_ctrl_write((1 << CSR_USB_OUT_CTRL_STALL_OFFSET) | (enable << CSR_USB_OUT_CTRL_ENABLE_OFFSET) | tu_edpt_number(ep_addr));
}
else else
usb_in_ctrl_write((1 << CSR_USB_IN_CTRL_STALL_OFFSET) | tu_edpt_number(ep_addr)); usb_in_ctrl_write((1 << CSR_USB_IN_CTRL_STALL_OFFSET) | tu_edpt_number(ep_addr));
} }
@ -359,32 +401,36 @@ bool dcd_edpt_xfer (uint8_t rhport, uint8_t ep_addr, uint8_t* buffer, uint16_t t
// Update the tx_ep to point to our endpoint number and queue the data. // Update the tx_ep to point to our endpoint number and queue the data.
// Otherwise, let it be and it'll get picked up after the next transfer // Otherwise, let it be and it'll get picked up after the next transfer
// finishes. // finishes.
if ((tx_buffer[tx_ep] == NULL) || (tx_ep == ep_num)) { if (!tx_active) {
tx_ep = ep_num; tx_ep = ep_num;
tx_active = true;
tx_more_data(); tx_more_data();
} }
dcd_int_enable(0); dcd_int_enable(0);
} }
else if (ep_dir == TUSB_DIR_OUT) { else if (ep_dir == TUSB_DIR_OUT) {
while (rx_buffer[ep_num] != NULL) while (rx_buffer[ep_num] != NULL)
; ;
dcd_int_disable(0);
TU_ASSERT(rx_buffer[ep_num] == NULL);
rx_buffer[ep_num] = buffer;
rx_buffer_offset[ep_num] = 0; rx_buffer_offset[ep_num] = 0;
rx_buffer_max[ep_num] = total_bytes; rx_buffer_max[ep_num] = total_bytes;
dcd_int_disable(0);
rx_buffer[ep_num] = buffer;
usb_out_ctrl_write((1 << CSR_USB_OUT_CTRL_ENABLE_OFFSET) | ep_num); usb_out_ctrl_write((1 << CSR_USB_OUT_CTRL_ENABLE_OFFSET) | ep_num);
#if DEBUG
// uint16_t ep_en_mask = usb_out_enable_status_read(); uint16_t ep_en_mask = usb_out_enable_status_read();
// int i; int i;
// for (i = 0; i < 16; i++) { for (i = 0; i < 16; i++) {
// if ((!!(ep_en_mask & (1 << i))) ^ (!!(rx_buffer[i]))) { if ((!!(ep_en_mask & (1 << i))) ^ (!!(rx_buffer[i]))) {
// if (rx_buffer[i] && usb_out_ev_pending_read() && (usb_out_status_read() & 0xf) == i) if (rx_buffer[i] && usb_out_ev_pending_read() && (usb_out_status_read() & 0xf) == i)
// continue; continue;
// fomu_error(__LINE__); fomu_error(__LINE__);
// } }
// } }
#endif
dcd_int_enable(0); dcd_int_enable(0);
} }
return true; return true;
@ -412,9 +458,10 @@ void hal_dcd_isr(uint8_t rhport)
// (But only if we can accept the data) // (But only if we can accept the data)
// if (out_pending) { // if (out_pending) {
if (out_pending) { if (out_pending) {
#if DEBUG
if (!usb_out_ev_enable_read()) if (!usb_out_ev_enable_read())
fomu_error(__LINE__); fomu_error(__LINE__);
usb_out_ev_pending_write(out_pending); #endif
process_rx(true); process_rx(true);
} }
@ -426,8 +473,10 @@ void hal_dcd_isr(uint8_t rhport)
// to begin with, then make a subsequent request. If we don't handle // to begin with, then make a subsequent request. If we don't handle
// the IN packets first, then the second request will be truncated. // the IN packets first, then the second request will be truncated.
if (in_pending) { if (in_pending) {
#if DEBUG
if (!usb_in_ev_enable_read()) if (!usb_in_ev_enable_read())
fomu_error(__LINE__); fomu_error(__LINE__);
#endif
usb_in_ev_pending_write(in_pending); usb_in_ev_pending_write(in_pending);
process_tx(true); process_tx(true);
} }
@ -438,8 +487,10 @@ void hal_dcd_isr(uint8_t rhport)
// Setup packets are always 8 bytes, plus two bytes of crc16. // Setup packets are always 8 bytes, plus two bytes of crc16.
uint32_t setup_length = 0; uint32_t setup_length = 0;
#if DEBUG
if (!(usb_setup_status_read() & (1 << CSR_USB_SETUP_STATUS_HAVE_OFFSET))) if (!(usb_setup_status_read() & (1 << CSR_USB_SETUP_STATUS_HAVE_OFFSET)))
fomu_error(__LINE__); fomu_error(__LINE__);
#endif
while (usb_setup_status_read() & (1 << CSR_USB_SETUP_STATUS_HAVE_OFFSET)) { while (usb_setup_status_read() & (1 << CSR_USB_SETUP_STATUS_HAVE_OFFSET)) {
uint8_t c = usb_setup_data_read(); uint8_t c = usb_setup_data_read();
@ -458,9 +509,11 @@ void hal_dcd_isr(uint8_t rhport)
// if (!((setup_packet_bfr[0] == 0x00) && (setup_packet_bfr[1] == 0x05))) // if (!((setup_packet_bfr[0] == 0x00) && (setup_packet_bfr[1] == 0x05)))
usb_setup_ctrl_write(1 << CSR_USB_SETUP_CTRL_ACK_OFFSET); usb_setup_ctrl_write(1 << CSR_USB_SETUP_CTRL_ACK_OFFSET);
} }
#if DEBUG
else { else {
fomu_error(__LINE__); fomu_error(__LINE__);
} }
#endif
} }
} }