diff options
Diffstat (limited to 'tinyusb/src/portable/espressif/esp32sx/dcd_esp32sx.c')
-rwxr-xr-x | tinyusb/src/portable/espressif/esp32sx/dcd_esp32sx.c | 867 |
1 files changed, 867 insertions, 0 deletions
diff --git a/tinyusb/src/portable/espressif/esp32sx/dcd_esp32sx.c b/tinyusb/src/portable/espressif/esp32sx/dcd_esp32sx.c new file mode 100755 index 00000000..d728487c --- /dev/null +++ b/tinyusb/src/portable/espressif/esp32sx/dcd_esp32sx.c @@ -0,0 +1,867 @@ +/* + * The MIT License (MIT) + * + * Copyright (c) 2018 Scott Shawcroft, 2019 William D. Jones for Adafruit Industries + * Copyright (c) 2019 Ha Thach (tinyusb.org) + * Additions Copyright (c) 2020, Espressif Systems (Shanghai) Co. Ltd. + * + * Permission is hereby granted, free of charge, to any person obtaining a copy + * of this software and associated documentation files (the "Software"), to deal + * in the Software without restriction, including without limitation the rights + * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell + * copies of the Software, and to permit persons to whom the Software is + * furnished to do so, subject to the following conditions: + * + * The above copyright notice and this permission notice shall be included in + * all copies or substantial portions of the Software. + * + * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR + * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, + * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE + * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER + * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, + * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN + * THE SOFTWARE. + * + * This file is part of the TinyUSB stack. + */ + +#include "tusb_option.h" + +#if (((CFG_TUSB_MCU == OPT_MCU_ESP32S2) || (CFG_TUSB_MCU == OPT_MCU_ESP32S3)) && TUSB_OPT_DEVICE_ENABLED) + +// Espressif +#include "driver/periph_ctrl.h" +#include "freertos/xtensa_api.h" +#include "esp_intr_alloc.h" +#include "esp_log.h" +#include "driver/gpio.h" +#include "soc/dport_reg.h" +#include "soc/gpio_sig_map.h" +#include "soc/usb_periph.h" + +#include "device/dcd.h" + +// Since TinyUSB doesn't use SOF for now, and this interrupt too often (1ms interval) +// We disable SOF for now until needed later on +#define USE_SOF 0 + +// Max number of bi-directional endpoints including EP0 +// Note: ESP32S2 specs say there are only up to 5 IN active endpoints include EP0 +// We should probably prohibit enabling Endpoint IN > 4 (not done yet) +#define EP_MAX USB_OUT_EP_NUM + +// FIFO size in bytes +#define EP_FIFO_SIZE 1024 + +// Max number of IN EP FIFOs +#define EP_FIFO_NUM 5 + +typedef struct { + uint8_t *buffer; + // tu_fifo_t * ff; // TODO support dcd_edpt_xfer_fifo API + uint16_t total_len; + uint16_t queued_len; + uint16_t max_size; + bool short_packet; +} xfer_ctl_t; + +static const char *TAG = "TUSB:DCD"; +static intr_handle_t usb_ih; + + +static uint32_t _setup_packet[2]; + +#define XFER_CTL_BASE(_ep, _dir) &xfer_status[_ep][_dir] +static xfer_ctl_t xfer_status[EP_MAX][2]; + +// Keep count of how many FIFOs are in use +static uint8_t _allocated_fifos = 1; //FIFO0 is always in use + +// Will either return an unused FIFO number, or 0 if all are used. +static uint8_t get_free_fifo(void) +{ + if (_allocated_fifos < EP_FIFO_NUM) return _allocated_fifos++; + return 0; +} + +// Setup the control endpoint 0. +static void bus_reset(void) +{ + for (int ep_num = 0; ep_num < USB_OUT_EP_NUM; ep_num++) { + USB0.out_ep_reg[ep_num].doepctl |= USB_DO_SNAK0_M; // DOEPCTL0_SNAK + } + + USB0.dcfg &= ~USB_DEVADDR_M; // reset address + + USB0.daintmsk |= USB_OUTEPMSK0_M | USB_INEPMSK0_M; + USB0.doepmsk |= USB_SETUPMSK_M | USB_XFERCOMPLMSK; + USB0.diepmsk |= USB_TIMEOUTMSK_M | USB_DI_XFERCOMPLMSK_M /*| USB_INTKNTXFEMPMSK_M*/; + + // "USB Data FIFOs" section in reference manual + // Peripheral FIFO architecture + // + // --------------- 320 or 1024 ( 1280 or 4096 bytes ) + // | IN FIFO MAX | + // --------------- + // | ... | + // --------------- y + x + 16 + GRXFSIZ + // | IN FIFO 2 | + // --------------- x + 16 + GRXFSIZ + // | IN FIFO 1 | + // --------------- 16 + GRXFSIZ + // | IN FIFO 0 | + // --------------- GRXFSIZ + // | OUT FIFO | + // | ( Shared ) | + // --------------- 0 + // + // According to "FIFO RAM allocation" section in RM, FIFO RAM are allocated as follows (each word 32-bits): + // - Each EP IN needs at least max packet size, 16 words is sufficient for EP0 IN + // + // - All EP OUT shared a unique OUT FIFO which uses + // * 10 locations in hardware for setup packets + setup control words (up to 3 setup packets). + // * 2 locations for OUT endpoint control words. + // * 16 for largest packet size of 64 bytes. ( TODO Highspeed is 512 bytes) + // * 1 location for global NAK (not required/used here). + // * It is recommended to allocate 2 times the largest packet size, therefore + // Recommended value = 10 + 1 + 2 x (16+2) = 47 --> Let's make it 52 + USB0.grstctl |= 0x10 << USB_TXFNUM_S; // fifo 0x10, + USB0.grstctl |= USB_TXFFLSH_M; // Flush fifo + USB0.grxfsiz = 52; + + // Control IN uses FIFO 0 with 64 bytes ( 16 32-bit word ) + USB0.gnptxfsiz = (16 << USB_NPTXFDEP_S) | (USB0.grxfsiz & 0x0000ffffUL); + + // Ready to receive SETUP packet + USB0.out_ep_reg[0].doeptsiz |= USB_SUPCNT0_M; + + USB0.gintmsk |= USB_IEPINTMSK_M | USB_OEPINTMSK_M; +} + +static void enum_done_processing(void) +{ + ESP_EARLY_LOGV(TAG, "dcd_int_handler - Speed enumeration done! Sending DCD_EVENT_BUS_RESET then"); + // On current silicon on the Full Speed core, speed is fixed to Full Speed. + // However, keep for debugging and in case Low Speed is ever supported. + uint32_t enum_spd = (USB0.dsts >> USB_ENUMSPD_S) & (USB_ENUMSPD_V); + + // Maximum packet size for EP 0 is set for both directions by writing DIEPCTL + if (enum_spd == 0x03) { // Full-Speed (PHY on 48 MHz) + USB0.in_ep_reg[0].diepctl &= ~USB_D_MPS0_V; // 64 bytes + USB0.in_ep_reg[0].diepctl &= ~USB_D_STALL0_M; // clear Stall + xfer_status[0][TUSB_DIR_OUT].max_size = 64; + xfer_status[0][TUSB_DIR_IN].max_size = 64; + } else { + USB0.in_ep_reg[0].diepctl |= USB_D_MPS0_V; // 8 bytes + USB0.in_ep_reg[0].diepctl &= ~USB_D_STALL0_M; // clear Stall + xfer_status[0][TUSB_DIR_OUT].max_size = 8; + xfer_status[0][TUSB_DIR_IN].max_size = 8; + } +} + + +/*------------------------------------------------------------------*/ +/* Controller API + *------------------------------------------------------------------*/ +void dcd_init(uint8_t rhport) +{ + ESP_LOGV(TAG, "DCD init - Start"); + + // A. Disconnect + ESP_LOGV(TAG, "DCD init - Soft DISCONNECT and Setting up"); + USB0.dctl |= USB_SFTDISCON_M; // Soft disconnect + + // B. Programming DCFG + /* If USB host misbehaves during status portion of control xfer + (non zero-length packet), send STALL back and discard. Full speed. */ + USB0.dcfg |= USB_NZSTSOUTHSHK_M | // NonZero .... STALL + (3 << 0); // dev speed: fullspeed 1.1 on 48 mhz // TODO no value in usb_reg.h (IDF-1476) + + USB0.gahbcfg |= USB_NPTXFEMPLVL_M | USB_GLBLLNTRMSK_M; // Global interruptions ON + USB0.gusbcfg |= USB_FORCEDEVMODE_M; // force devmode + USB0.gotgctl &= ~(USB_BVALIDOVVAL_M | USB_BVALIDOVEN_M | USB_VBVALIDOVVAL_M); //no overrides + + // C. Setting SNAKs, then connect + for (int n = 0; n < USB_OUT_EP_NUM; n++) { + USB0.out_ep_reg[n].doepctl |= USB_DO_SNAK0_M; // DOEPCTL0_SNAK + } + + // D. Interruption masking + USB0.gintmsk = 0; //mask all + USB0.gotgint = ~0U; //clear OTG ints + USB0.gintsts = ~0U; //clear pending ints + USB0.gintmsk = USB_OTGINTMSK_M | + USB_MODEMISMSK_M | + #if USE_SOF + USB_SOFMSK_M | + #endif + USB_RXFLVIMSK_M | + USB_ERLYSUSPMSK_M | + USB_USBSUSPMSK_M | + USB_USBRSTMSK_M | + USB_ENUMDONEMSK_M | + USB_RESETDETMSK_M | + USB_DISCONNINTMSK_M; // host most only + + dcd_connect(rhport); +} + +void dcd_set_address(uint8_t rhport, uint8_t dev_addr) +{ + (void)rhport; + ESP_LOGV(TAG, "DCD init - Set address : %u", dev_addr); + USB0.dcfg |= ((dev_addr & USB_DEVADDR_V) << USB_DEVADDR_S); + // Response with status after changing device address + dcd_edpt_xfer(rhport, tu_edpt_addr(0, TUSB_DIR_IN), NULL, 0); +} + +void dcd_remote_wakeup(uint8_t rhport) +{ + (void)rhport; + + // TODO must manually clear this bit after 1-15 ms + // USB0.DCTL |= USB_RMTWKUPSIG_M; +} + +// connect by enabling internal pull-up resistor on D+/D- +void dcd_connect(uint8_t rhport) +{ + (void) rhport; + USB0.dctl &= ~USB_SFTDISCON_M; +} + +// disconnect by disabling internal pull-up resistor on D+/D- +void dcd_disconnect(uint8_t rhport) +{ + (void) rhport; + USB0.dctl |= USB_SFTDISCON_M; +} + +/*------------------------------------------------------------------*/ +/* DCD Endpoint port + *------------------------------------------------------------------*/ + +bool dcd_edpt_open(uint8_t rhport, tusb_desc_endpoint_t const *desc_edpt) +{ + ESP_LOGV(TAG, "DCD endpoint opened"); + (void)rhport; + + usb_out_endpoint_t *out_ep = &(USB0.out_ep_reg[0]); + usb_in_endpoint_t *in_ep = &(USB0.in_ep_reg[0]); + + uint8_t const epnum = tu_edpt_number(desc_edpt->bEndpointAddress); + uint8_t const dir = tu_edpt_dir(desc_edpt->bEndpointAddress); + + TU_ASSERT(desc_edpt->wMaxPacketSize.size <= 64); + TU_ASSERT(epnum < EP_MAX); + + xfer_ctl_t *xfer = XFER_CTL_BASE(epnum, dir); + xfer->max_size = desc_edpt->wMaxPacketSize.size; + + if (dir == TUSB_DIR_OUT) { + out_ep[epnum].doepctl |= USB_USBACTEP0_M | + desc_edpt->bmAttributes.xfer << USB_EPTYPE0_S | + desc_edpt->wMaxPacketSize.size << USB_MPS0_S; + USB0.daintmsk |= (1 << (16 + epnum)); + } else { + // "USB Data FIFOs" section in reference manual + // Peripheral FIFO architecture + // + // --------------- 320 or 1024 ( 1280 or 4096 bytes ) + // | IN FIFO MAX | + // --------------- + // | ... | + // --------------- y + x + 16 + GRXFSIZ + // | IN FIFO 2 | + // --------------- x + 16 + GRXFSIZ + // | IN FIFO 1 | + // --------------- 16 + GRXFSIZ + // | IN FIFO 0 | + // --------------- GRXFSIZ + // | OUT FIFO | + // | ( Shared ) | + // --------------- 0 + // + // Since OUT FIFO = GRXFSIZ, FIFO 0 = 16, for simplicity, we equally allocated for the rest of endpoints + // - Size : (FIFO_SIZE/4 - GRXFSIZ - 16) / (EP_MAX-1) + // - Offset: GRXFSIZ + 16 + Size*(epnum-1) + // - IN EP 1 gets FIFO 1, IN EP "n" gets FIFO "n". + + uint8_t fifo_num = get_free_fifo(); + TU_ASSERT(fifo_num != 0); + + in_ep[epnum].diepctl &= ~(USB_D_TXFNUM1_M | USB_D_EPTYPE1_M | USB_DI_SETD0PID1 | USB_D_MPS1_M); + in_ep[epnum].diepctl |= USB_D_USBACTEP1_M | + fifo_num << USB_D_TXFNUM1_S | + desc_edpt->bmAttributes.xfer << USB_D_EPTYPE1_S | + (desc_edpt->bmAttributes.xfer != TUSB_XFER_ISOCHRONOUS ? (1 << USB_DI_SETD0PID1_S) : 0) | + desc_edpt->wMaxPacketSize.size << 0; + + USB0.daintmsk |= (1 << (0 + epnum)); + + // Both TXFD and TXSA are in unit of 32-bit words. + // IN FIFO 0 was configured during enumeration, hence the "+ 16". + uint16_t const allocated_size = (USB0.grxfsiz & 0x0000ffff) + 16; + uint16_t const fifo_size = (EP_FIFO_SIZE/4 - allocated_size) / (EP_FIFO_NUM-1); + uint32_t const fifo_offset = allocated_size + fifo_size*(fifo_num-1); + + // DIEPTXF starts at FIFO #1. + USB0.dieptxf[epnum - 1] = (fifo_size << USB_NPTXFDEP_S) | fifo_offset; + } + return true; +} + +bool dcd_edpt_xfer(uint8_t rhport, uint8_t ep_addr, uint8_t *buffer, uint16_t total_bytes) +{ + (void)rhport; + + uint8_t const epnum = tu_edpt_number(ep_addr); + uint8_t const dir = tu_edpt_dir(ep_addr); + + xfer_ctl_t * xfer = XFER_CTL_BASE(epnum, dir); + xfer->buffer = buffer; + // xfer->ff = NULL; // TODO support dcd_edpt_xfer_fifo API + xfer->total_len = total_bytes; + xfer->queued_len = 0; + xfer->short_packet = false; + + uint16_t num_packets = (total_bytes / xfer->max_size); + uint8_t short_packet_size = total_bytes % xfer->max_size; + + // Zero-size packet is special case. + if (short_packet_size > 0 || (total_bytes == 0)) { + num_packets++; + } + + ESP_LOGV(TAG, "Transfer <-> EP%i, %s, pkgs: %i, bytes: %i", + epnum, ((dir == TUSB_DIR_IN) ? "USB0.HOST (in)" : "HOST->DEV (out)"), + num_packets, total_bytes); + + // IN and OUT endpoint xfers are interrupt-driven, we just schedule them + // here. + if (dir == TUSB_DIR_IN) { + // A full IN transfer (multiple packets, possibly) triggers XFRC. + USB0.in_ep_reg[epnum].dieptsiz = (num_packets << USB_D_PKTCNT0_S) | total_bytes; + USB0.in_ep_reg[epnum].diepctl |= USB_D_EPENA1_M | USB_D_CNAK1_M; // Enable | CNAK + + // Enable fifo empty interrupt only if there are something to put in the fifo. + if(total_bytes != 0) { + USB0.dtknqr4_fifoemptymsk |= (1 << epnum); + } + } else { + // Each complete packet for OUT xfers triggers XFRC. + USB0.out_ep_reg[epnum].doeptsiz |= USB_PKTCNT0_M | ((xfer->max_size & USB_XFERSIZE0_V) << USB_XFERSIZE0_S); + USB0.out_ep_reg[epnum].doepctl |= USB_EPENA0_M | USB_CNAK0_M; + } + return true; +} + +#if 0 // TODO support dcd_edpt_xfer_fifo API +bool dcd_edpt_xfer_fifo (uint8_t rhport, uint8_t ep_addr, tu_fifo_t * ff, uint16_t total_bytes) +{ + (void)rhport; + + // USB buffers always work in bytes so to avoid unnecessary divisions we demand item_size = 1 + TU_ASSERT(ff->item_size == 1); + + uint8_t const epnum = tu_edpt_number(ep_addr); + uint8_t const dir = tu_edpt_dir(ep_addr); + + xfer_ctl_t * xfer = XFER_CTL_BASE(epnum, dir); + xfer->buffer = NULL; + xfer->ff = ff; + xfer->total_len = total_bytes; + xfer->queued_len = 0; + xfer->short_packet = false; + + uint16_t num_packets = (total_bytes / xfer->max_size); + uint8_t short_packet_size = total_bytes % xfer->max_size; + + // Zero-size packet is special case. + if (short_packet_size > 0 || (total_bytes == 0)) { + num_packets++; + } + + ESP_LOGV(TAG, "Transfer <-> EP%i, %s, pkgs: %i, bytes: %i", + epnum, ((dir == TUSB_DIR_IN) ? "USB0.HOST (in)" : "HOST->DEV (out)"), + num_packets, total_bytes); + + // IN and OUT endpoint xfers are interrupt-driven, we just schedule them + // here. + if (dir == TUSB_DIR_IN) { + // A full IN transfer (multiple packets, possibly) triggers XFRC. + USB0.in_ep_reg[epnum].dieptsiz = (num_packets << USB_D_PKTCNT0_S) | total_bytes; + USB0.in_ep_reg[epnum].diepctl |= USB_D_EPENA1_M | USB_D_CNAK1_M; // Enable | CNAK + + // Enable fifo empty interrupt only if there are something to put in the fifo. + if(total_bytes != 0) { + USB0.dtknqr4_fifoemptymsk |= (1 << epnum); + } + } else { + // Each complete packet for OUT xfers triggers XFRC. + USB0.out_ep_reg[epnum].doeptsiz |= USB_PKTCNT0_M | ((xfer->max_size & USB_XFERSIZE0_V) << USB_XFERSIZE0_S); + USB0.out_ep_reg[epnum].doepctl |= USB_EPENA0_M | USB_CNAK0_M; + } + return true; +} +#endif + +void dcd_edpt_stall(uint8_t rhport, uint8_t ep_addr) +{ + (void)rhport; + + usb_out_endpoint_t *out_ep = &(USB0.out_ep_reg[0]); + usb_in_endpoint_t *in_ep = &(USB0.in_ep_reg[0]); + + uint8_t const epnum = tu_edpt_number(ep_addr); + uint8_t const dir = tu_edpt_dir(ep_addr); + + if (dir == TUSB_DIR_IN) { + // Only disable currently enabled non-control endpoint + if ((epnum == 0) || !(in_ep[epnum].diepctl & USB_D_EPENA1_M)) { + in_ep[epnum].diepctl |= (USB_DI_SNAK1_M | USB_D_STALL1_M); + } else { + // Stop transmitting packets and NAK IN xfers. + in_ep[epnum].diepctl |= USB_DI_SNAK1_M; + while ((in_ep[epnum].diepint & USB_DI_SNAK1_M) == 0) ; + + // Disable the endpoint. Note that both SNAK and STALL are set here. + in_ep[epnum].diepctl |= (USB_DI_SNAK1_M | USB_D_STALL1_M | USB_D_EPDIS1_M); + while ((in_ep[epnum].diepint & USB_D_EPDISBLD0_M) == 0) ; + in_ep[epnum].diepint = USB_D_EPDISBLD0_M; + } + + // Flush the FIFO, and wait until we have confirmed it cleared. + uint8_t const fifo_num = ((in_ep[epnum].diepctl >> USB_D_TXFNUM1_S) & USB_D_TXFNUM1_V); + USB0.grstctl |= (fifo_num << USB_TXFNUM_S); + USB0.grstctl |= USB_TXFFLSH_M; + while ((USB0.grstctl & USB_TXFFLSH_M) != 0) ; + } else { + // Only disable currently enabled non-control endpoint + if ((epnum == 0) || !(out_ep[epnum].doepctl & USB_EPENA0_M)) { + out_ep[epnum].doepctl |= USB_STALL0_M; + } else { + // Asserting GONAK is required to STALL an OUT endpoint. + // Simpler to use polling here, we don't use the "B"OUTNAKEFF interrupt + // anyway, and it can't be cleared by user code. If this while loop never + // finishes, we have bigger problems than just the stack. + USB0.dctl |= USB_SGOUTNAK_M; + while ((USB0.gintsts & USB_GOUTNAKEFF_M) == 0) ; + + // Ditto here- disable the endpoint. Note that only STALL and not SNAK + // is set here. + out_ep[epnum].doepctl |= (USB_STALL0_M | USB_EPDIS0_M); + while ((out_ep[epnum].doepint & USB_EPDISBLD0_M) == 0) ; + out_ep[epnum].doepint = USB_EPDISBLD0_M; + + // Allow other OUT endpoints to keep receiving. + USB0.dctl |= USB_CGOUTNAK_M; + } + } +} + +void dcd_edpt_clear_stall(uint8_t rhport, uint8_t ep_addr) +{ + (void)rhport; + + usb_out_endpoint_t *out_ep = &(USB0.out_ep_reg[0]); + usb_in_endpoint_t *in_ep = &(USB0.in_ep_reg[0]); + + uint8_t const epnum = tu_edpt_number(ep_addr); + uint8_t const dir = tu_edpt_dir(ep_addr); + + if (dir == TUSB_DIR_IN) { + in_ep[epnum].diepctl &= ~USB_D_STALL1_M; + + uint8_t eptype = (in_ep[epnum].diepctl & USB_D_EPTYPE1_M) >> USB_D_EPTYPE1_S; + // Required by USB spec to reset DATA toggle bit to DATA0 on interrupt + // and bulk endpoints. + if (eptype == 2 || eptype == 3) { + in_ep[epnum].diepctl |= USB_DI_SETD0PID1_M; + } + } else { + out_ep[epnum].doepctl &= ~USB_STALL1_M; + + uint8_t eptype = (out_ep[epnum].doepctl & USB_EPTYPE1_M) >> USB_EPTYPE1_S; + // Required by USB spec to reset DATA toggle bit to DATA0 on interrupt + // and bulk endpoints. + if (eptype == 2 || eptype == 3) { + out_ep[epnum].doepctl |= USB_DO_SETD0PID1_M; + } + } +} + +/*------------------------------------------------------------------*/ + +static void receive_packet(xfer_ctl_t *xfer, /* usb_out_endpoint_t * out_ep, */ uint16_t xfer_size) +{ + ESP_EARLY_LOGV(TAG, "USB - receive_packet"); + volatile uint32_t *rx_fifo = USB0.fifo[0]; + + // See above TODO + // uint16_t remaining = (out_ep->DOEPTSIZ & UsbDOEPTSIZ_XFRSIZ_Msk) >> UsbDOEPTSIZ_XFRSIZ_Pos; + // xfer->queued_len = xfer->total_len - remaining; + + uint16_t remaining = xfer->total_len - xfer->queued_len; + uint16_t to_recv_size; + + if (remaining <= xfer->max_size) { + // Avoid buffer overflow. + to_recv_size = (xfer_size > remaining) ? remaining : xfer_size; + } else { + // Room for full packet, choose recv_size based on what the microcontroller + // claims. + to_recv_size = (xfer_size > xfer->max_size) ? xfer->max_size : xfer_size; + } + + // Common buffer read +#if 0 // TODO support dcd_edpt_xfer_fifo API + if (xfer->ff) + { + // Ring buffer + tu_fifo_write_n_const_addr_full_words(xfer->ff, (const void *) rx_fifo, to_recv_size); + } + else +#endif + { + uint8_t to_recv_rem = to_recv_size % 4; + uint16_t to_recv_size_aligned = to_recv_size - to_recv_rem; + + // Do not assume xfer buffer is aligned. + uint8_t *base = (xfer->buffer + xfer->queued_len); + + // This for loop always runs at least once- skip if less than 4 bytes + // to collect. + if (to_recv_size >= 4) { + for (uint16_t i = 0; i < to_recv_size_aligned; i += 4) { + uint32_t tmp = (*rx_fifo); + base[i] = tmp & 0x000000FF; + base[i + 1] = (tmp & 0x0000FF00) >> 8; + base[i + 2] = (tmp & 0x00FF0000) >> 16; + base[i + 3] = (tmp & 0xFF000000) >> 24; + } + } + + // Do not read invalid bytes from RX FIFO. + if (to_recv_rem != 0) { + uint32_t tmp = (*rx_fifo); + uint8_t *last_32b_bound = base + to_recv_size_aligned; + + last_32b_bound[0] = tmp & 0x000000FF; + if (to_recv_rem > 1) { + last_32b_bound[1] = (tmp & 0x0000FF00) >> 8; + } + if (to_recv_rem > 2) { + last_32b_bound[2] = (tmp & 0x00FF0000) >> 16; + } + } + } + + xfer->queued_len += xfer_size; + + // Per USB spec, a short OUT packet (including length 0) is always + // indicative of the end of a transfer (at least for ctl, bulk, int). + xfer->short_packet = (xfer_size < xfer->max_size); +} + +static void transmit_packet(xfer_ctl_t *xfer, volatile usb_in_endpoint_t *in_ep, uint8_t fifo_num) +{ + ESP_EARLY_LOGV(TAG, "USB - transmit_packet"); + volatile uint32_t *tx_fifo = USB0.fifo[fifo_num]; + + uint16_t remaining = (in_ep->dieptsiz & 0x7FFFFU) >> USB_D_XFERSIZE0_S; + xfer->queued_len = xfer->total_len - remaining; + + uint16_t to_xfer_size = (remaining > xfer->max_size) ? xfer->max_size : remaining; + +#if 0 // TODO support dcd_edpt_xfer_fifo API + if (xfer->ff) + { + tu_fifo_read_n_const_addr_full_words(xfer->ff, (void *) tx_fifo, to_xfer_size); + } + else +#endif + { + uint8_t to_xfer_rem = to_xfer_size % 4; + uint16_t to_xfer_size_aligned = to_xfer_size - to_xfer_rem; + + // Buffer might not be aligned to 32b, so we need to force alignment + // by copying to a temp var. + uint8_t *base = (xfer->buffer + xfer->queued_len); + + // This for loop always runs at least once- skip if less than 4 bytes + // to send off. + if (to_xfer_size >= 4) { + for (uint16_t i = 0; i < to_xfer_size_aligned; i += 4) { + uint32_t tmp = base[i] | (base[i + 1] << 8) | + (base[i + 2] << 16) | (base[i + 3] << 24); + (*tx_fifo) = tmp; + } + } + + // Do not read beyond end of buffer if not divisible by 4. + if (to_xfer_rem != 0) { + uint32_t tmp = 0; + uint8_t *last_32b_bound = base + to_xfer_size_aligned; + + tmp |= last_32b_bound[0]; + if (to_xfer_rem > 1) { + tmp |= (last_32b_bound[1] << 8); + } + if (to_xfer_rem > 2) { + tmp |= (last_32b_bound[2] << 16); + } + + (*tx_fifo) = tmp; + } + } +} + +static void read_rx_fifo(void) +{ + // Pop control word off FIFO (completed xfers will have 2 control words, + // we only pop one ctl word each interrupt). + uint32_t const ctl_word = USB0.grxstsp; + uint8_t const pktsts = (ctl_word & USB_PKTSTS_M) >> USB_PKTSTS_S; + uint8_t const epnum = (ctl_word & USB_CHNUM_M ) >> USB_CHNUM_S; + uint16_t const bcnt = (ctl_word & USB_BCNT_M ) >> USB_BCNT_S; + + switch (pktsts) { + case 0x01: // Global OUT NAK (Interrupt) + ESP_EARLY_LOGV(TAG, "TUSB IRQ - RX type : Global OUT NAK"); + break; + + case 0x02: { // Out packet recvd + ESP_EARLY_LOGV(TAG, "TUSB IRQ - RX type : Out packet"); + xfer_ctl_t *xfer = XFER_CTL_BASE(epnum, TUSB_DIR_OUT); + receive_packet(xfer, bcnt); + } + break; + + case 0x03: // Out packet done (Interrupt) + ESP_EARLY_LOGV(TAG, "TUSB IRQ - RX type : Out packet done"); + break; + + case 0x04: // Step 2: Setup transaction completed (Interrupt) + // After this event, OEPINT interrupt will occur with SETUP bit set + ESP_EARLY_LOGV(TAG, "TUSB IRQ - RX : Setup packet done"); + USB0.out_ep_reg[epnum].doeptsiz |= USB_SUPCNT0_M; + break; + + case 0x06: { // Step1: Setup data packet received + volatile uint32_t *rx_fifo = USB0.fifo[0]; + + // We can receive up to three setup packets in succession, but + // only the last one is valid. Therefore we just overwrite it + _setup_packet[0] = (*rx_fifo); + _setup_packet[1] = (*rx_fifo); + + ESP_EARLY_LOGV(TAG, "TUSB IRQ - RX : Setup packet : 0x%08x 0x%08x", _setup_packet[0], _setup_packet[1]); + } + break; + + default: // Invalid, do something here, like breakpoint? + TU_BREAKPOINT(); + break; + } +} + +static void handle_epout_ints(void) +{ + // GINTSTS will be cleared with DAINT == 0 + // DAINT for a given EP clears when DOEPINTx is cleared. + // DOEPINT will be cleared when DAINT's out bits are cleared. + for (int n = 0; n < USB_OUT_EP_NUM; n++) { + xfer_ctl_t *xfer = XFER_CTL_BASE(n, TUSB_DIR_OUT); + + if (USB0.daint & (1 << (16 + n))) { + // SETUP packet Setup Phase done. + if ((USB0.out_ep_reg[n].doepint & USB_SETUP0_M)) { + USB0.out_ep_reg[n].doepint = USB_STUPPKTRCVD0_M | USB_SETUP0_M; // clear + dcd_event_setup_received(0, (uint8_t *)&_setup_packet[0], true); + } + + // OUT XFER complete (single packet).q + if (USB0.out_ep_reg[n].doepint & USB_XFERCOMPL0_M) { + + ESP_EARLY_LOGV(TAG, "TUSB IRQ - EP OUT - XFER complete (single packet)"); + USB0.out_ep_reg[n].doepint = USB_XFERCOMPL0_M; + + // Transfer complete if short packet or total len is transferred + if (xfer->short_packet || (xfer->queued_len == xfer->total_len)) { + xfer->short_packet = false; + dcd_event_xfer_complete(0, n, xfer->queued_len, XFER_RESULT_SUCCESS, true); + } else { + // Schedule another packet to be received. + USB0.out_ep_reg[n].doeptsiz |= USB_PKTCNT0_M | ((xfer->max_size & USB_XFERSIZE0_V) << USB_XFERSIZE0_S); + USB0.out_ep_reg[n].doepctl |= USB_EPENA0_M | USB_CNAK0_M; + } + } + } + } +} + +static void handle_epin_ints(void) +{ + // GINTSTS will be cleared with DAINT == 0 + // DAINT for a given EP clears when DIEPINTx is cleared. + // IEPINT will be cleared when DAINT's out bits are cleared. + for (uint32_t n = 0; n < USB_IN_EP_NUM; n++) { + xfer_ctl_t *xfer = &xfer_status[n][TUSB_DIR_IN]; + + if (USB0.daint & (1 << (0 + n))) { + ESP_EARLY_LOGV(TAG, "TUSB IRQ - EP IN %u", n); + // IN XFER complete (entire xfer). + if (USB0.in_ep_reg[n].diepint & USB_D_XFERCOMPL0_M) { + ESP_EARLY_LOGV(TAG, "TUSB IRQ - IN XFER complete!"); + USB0.in_ep_reg[n].diepint = USB_D_XFERCOMPL0_M; + dcd_event_xfer_complete(0, n | TUSB_DIR_IN_MASK, xfer->total_len, XFER_RESULT_SUCCESS, true); + } + + // XFER FIFO empty + if (USB0.in_ep_reg[n].diepint & USB_D_TXFEMP0_M) { + ESP_EARLY_LOGV(TAG, "TUSB IRQ - IN XFER FIFO empty!"); + USB0.in_ep_reg[n].diepint = USB_D_TXFEMP0_M; + transmit_packet(xfer, &USB0.in_ep_reg[n], n); + + // Turn off TXFE if all bytes are written. + if (xfer->queued_len == xfer->total_len) + { + USB0.dtknqr4_fifoemptymsk &= ~(1 << n); + } + } + + // XFER Timeout + if (USB0.in_ep_reg[n].diepint & USB_D_TIMEOUT0_M) { + // Clear interrupt or enpoint will hang. + USB0.in_ep_reg[n].diepint = USB_D_TIMEOUT0_M; + // Maybe retry? + } + } + } +} + + +static void _dcd_int_handler(void* arg) +{ + (void) arg; + uint8_t const rhport = 0; + + const uint32_t int_status = USB0.gintsts; + //const uint32_t int_msk = USB0.gintmsk; + + if (int_status & USB_USBRST_M) { + // start of reset + ESP_EARLY_LOGV(TAG, "dcd_int_handler - reset"); + USB0.gintsts = USB_USBRST_M; + // FIFOs will be reassigned when the endpoints are reopen + _allocated_fifos = 1; + bus_reset(); + } + + if (int_status & USB_RESETDET_M) { + ESP_EARLY_LOGV(TAG, "dcd_int_handler - reset while suspend"); + USB0.gintsts = USB_RESETDET_M; + bus_reset(); + } + + if (int_status & USB_ENUMDONE_M) { + // ENUMDNE detects speed of the link. For full-speed, we + // always expect the same value. This interrupt is considered + // the end of reset. + USB0.gintsts = USB_ENUMDONE_M; + enum_done_processing(); + dcd_event_bus_reset(rhport, TUSB_SPEED_FULL, true); + } + + if(int_status & USB_USBSUSP_M) + { + USB0.gintsts = USB_USBSUSP_M; + dcd_event_bus_signal(rhport, DCD_EVENT_SUSPEND, true); + } + + if(int_status & USB_WKUPINT_M) + { + USB0.gintsts = USB_WKUPINT_M; + dcd_event_bus_signal(rhport, DCD_EVENT_RESUME, true); + } + + if (int_status & USB_OTGINT_M) + { + // OTG INT bit is read-only + ESP_EARLY_LOGV(TAG, "dcd_int_handler - disconnected"); + + uint32_t const otg_int = USB0.gotgint; + + if (otg_int & USB_SESENDDET_M) + { + dcd_event_bus_signal(rhport, DCD_EVENT_UNPLUGGED, true); + } + + USB0.gotgint = otg_int; + } + +#if USE_SOF + if (int_status & USB_SOF_M) { + USB0.gintsts = USB_SOF_M; + dcd_event_bus_signal(rhport, DCD_EVENT_SOF, true); // do nothing actually + } +#endif + + if (int_status & USB_RXFLVI_M) { + // RXFLVL bit is read-only + ESP_EARLY_LOGV(TAG, "dcd_int_handler - rx!"); + + // Mask out RXFLVL while reading data from FIFO + USB0.gintmsk &= ~USB_RXFLVIMSK_M; + read_rx_fifo(); + USB0.gintmsk |= USB_RXFLVIMSK_M; + } + + // OUT endpoint interrupt handling. + if (int_status & USB_OEPINT_M) { + // OEPINT is read-only + ESP_EARLY_LOGV(TAG, "dcd_int_handler - OUT endpoint!"); + handle_epout_ints(); + } + + // IN endpoint interrupt handling. + if (int_status & USB_IEPINT_M) { + // IEPINT bit read-only + ESP_EARLY_LOGV(TAG, "dcd_int_handler - IN endpoint!"); + handle_epin_ints(); + } + + // Without handling + USB0.gintsts |= USB_CURMOD_INT_M | + USB_MODEMIS_M | + USB_OTGINT_M | + USB_NPTXFEMP_M | + USB_GINNAKEFF_M | + USB_GOUTNAKEFF | + USB_ERLYSUSP_M | + USB_USBSUSP_M | + USB_ISOOUTDROP_M | + USB_EOPF_M | + USB_EPMIS_M | + USB_INCOMPISOIN_M | + USB_INCOMPIP_M | + USB_FETSUSP_M | + USB_PTXFEMP_M; +} + +void dcd_int_enable (uint8_t rhport) +{ + (void) rhport; + esp_intr_alloc(ETS_USB_INTR_SOURCE, ESP_INTR_FLAG_LOWMED, (intr_handler_t) _dcd_int_handler, NULL, &usb_ih); +} + +void dcd_int_disable (uint8_t rhport) +{ + (void) rhport; + esp_intr_free(usb_ih); +} + +#endif // #if OPT_MCU_ESP32S2 || OPT_MCU_ESP32S3 + |