HackRF-Treasure-Chest/Software/portapack-mayhem/hackrf/firmware/common/usb.c

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2022-09-22 18:26:57 +02:00
/*
* Copyright 2012 Jared Boone
*
* This file is part of HackRF.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2, or (at your option)
* any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; see the file COPYING. If not, write to
* the Free Software Foundation, Inc., 51 Franklin Street,
* Boston, MA 02110-1301, USA.
*/
#include <stdint.h>
#include <stdbool.h>
#include "usb.h"
#include "usb_type.h"
#include "usb_queue.h"
#include "usb_standard_request.h"
#include <libopencm3/lpc43xx/creg.h>
#include <libopencm3/lpc43xx/m4/nvic.h>
#include <libopencm3/lpc43xx/rgu.h>
#include <libopencm3/lpc43xx/usb.h>
usb_device_t* usb_device_usb0 = 0;
usb_queue_head_t usb_qh[12] ATTR_ALIGNED(2048);
#define USB_QH_INDEX(endpoint_address) (((endpoint_address & 0xF) * 2) + ((endpoint_address >> 7) & 1))
usb_queue_head_t* usb_queue_head(
const uint_fast8_t endpoint_address
) {
return &usb_qh[USB_QH_INDEX(endpoint_address)];
}
usb_endpoint_t* usb_endpoint_from_address(
const uint_fast8_t endpoint_address
) {
return (usb_endpoint_t*)usb_queue_head(endpoint_address)->_reserved_0;
}
static uint_fast8_t usb_endpoint_address(
const usb_transfer_direction_t direction,
const uint_fast8_t number
) {
return ((direction == USB_TRANSFER_DIRECTION_IN) ? 0x80 : 0x00) + number;
}
static bool usb_endpoint_is_in(const uint_fast8_t endpoint_address) {
return (endpoint_address & 0x80) ? true : false;
}
static uint_fast8_t usb_endpoint_number(const uint_fast8_t endpoint_address) {
return (endpoint_address & 0xF);
}
void usb_peripheral_reset() {
RESET_CTRL0 = RESET_CTRL0_USB0_RST;
RESET_CTRL0 = 0;
while( (RESET_ACTIVE_STATUS0 & RESET_CTRL0_USB0_RST) == 0 );
}
void usb_phy_enable() {
CREG_CREG0 &= ~CREG_CREG0_USB0PHY;
}
static void usb_clear_pending_interrupts(const uint32_t mask) {
USB0_ENDPTNAK = mask;
USB0_ENDPTNAKEN = mask;
USB0_USBSTS_D = mask;
USB0_ENDPTSETUPSTAT = USB0_ENDPTSETUPSTAT & mask;
USB0_ENDPTCOMPLETE = USB0_ENDPTCOMPLETE & mask;
}
static void usb_clear_all_pending_interrupts() {
usb_clear_pending_interrupts(0xFFFFFFFF);
}
static void usb_wait_for_endpoint_priming_to_finish(const uint32_t mask) {
// Wait until controller has parsed new transfer descriptors and prepared
// receive buffers.
while( USB0_ENDPTPRIME & mask );
}
static void usb_flush_endpoints(const uint32_t mask) {
// Clear any primed buffers. If a packet is in progress, that transfer
// will continue until completion.
USB0_ENDPTFLUSH = mask;
}
static void usb_wait_for_endpoint_flushing_to_finish(const uint32_t mask) {
// Wait until controller has flushed all endpoints / cleared any primed
// buffers.
while( USB0_ENDPTFLUSH & mask );
}
static void usb_flush_primed_endpoints(const uint32_t mask) {
usb_wait_for_endpoint_priming_to_finish(mask);
usb_flush_endpoints(mask);
usb_wait_for_endpoint_flushing_to_finish(mask);
}
static void usb_flush_all_primed_endpoints() {
usb_flush_primed_endpoints(0xFFFFFFFF);
}
static void usb_endpoint_set_type(
const usb_endpoint_t* const endpoint,
const usb_transfer_type_t transfer_type
) {
// NOTE: UM10503 section 23.6.24 "Endpoint 1 to 5 control registers" says
// that the disabled side of an endpoint must be set to a non-control type
// (e.g. bulk, interrupt, or iso).
const uint_fast8_t endpoint_number = usb_endpoint_number(endpoint->address);
USB0_ENDPTCTRL(endpoint_number)
= ( USB0_ENDPTCTRL(endpoint_number)
& ~(USB0_ENDPTCTRL_TXT1_0_MASK | USB0_ENDPTCTRL_RXT_MASK)
)
| ( USB0_ENDPTCTRL_TXT1_0(transfer_type)
| USB0_ENDPTCTRL_RXT(transfer_type)
);
}
static void usb_endpoint_enable(
const usb_endpoint_t* const endpoint
) {
const uint_fast8_t endpoint_number = usb_endpoint_number(endpoint->address);
if( usb_endpoint_is_in(endpoint->address) ) {
USB0_ENDPTCTRL(endpoint_number) |= (USB0_ENDPTCTRL_TXE | USB0_ENDPTCTRL_TXR);
} else {
USB0_ENDPTCTRL(endpoint_number) |= (USB0_ENDPTCTRL_RXE | USB0_ENDPTCTRL_RXR);
}
}
static void usb_endpoint_clear_pending_interrupts(
const usb_endpoint_t* const endpoint
) {
const uint_fast8_t endpoint_number = usb_endpoint_number(endpoint->address);
if( usb_endpoint_is_in(endpoint->address) ) {
usb_clear_pending_interrupts(USB0_ENDPTCOMPLETE_ETCE(1 << endpoint_number));
} else {
usb_clear_pending_interrupts(USB0_ENDPTCOMPLETE_ERCE(1 << endpoint_number));
}
}
void usb_endpoint_disable(
const usb_endpoint_t* const endpoint
) {
const uint_fast8_t endpoint_number = usb_endpoint_number(endpoint->address);
if( usb_endpoint_is_in(endpoint->address) ) {
USB0_ENDPTCTRL(endpoint_number) &= ~(USB0_ENDPTCTRL_TXE);
} else {
USB0_ENDPTCTRL(endpoint_number) &= ~(USB0_ENDPTCTRL_RXE);
}
usb_queue_flush_endpoint(endpoint);
usb_endpoint_clear_pending_interrupts(endpoint);
usb_endpoint_flush(endpoint);
}
void usb_endpoint_prime(
const usb_endpoint_t* const endpoint,
usb_transfer_descriptor_t* const first_td
) {
usb_queue_head_t* const qh = usb_queue_head(endpoint->address);
qh->next_dtd_pointer = first_td;
qh->total_bytes
&= ~( USB_TD_DTD_TOKEN_STATUS_ACTIVE
| USB_TD_DTD_TOKEN_STATUS_HALTED
)
;
const uint_fast8_t endpoint_number = usb_endpoint_number(endpoint->address);
if( usb_endpoint_is_in(endpoint->address) ) {
USB0_ENDPTPRIME = USB0_ENDPTPRIME_PETB(1 << endpoint_number);
} else {
USB0_ENDPTPRIME = USB0_ENDPTPRIME_PERB(1 << endpoint_number);
}
}
static bool usb_endpoint_is_priming(
const usb_endpoint_t* const endpoint
) {
const uint_fast8_t endpoint_number = usb_endpoint_number(endpoint->address);
if( usb_endpoint_is_in(endpoint->address) ) {
return USB0_ENDPTPRIME & USB0_ENDPTPRIME_PETB(1 << endpoint_number);
} else {
return USB0_ENDPTPRIME & USB0_ENDPTPRIME_PERB(1 << endpoint_number);
}
}
// Schedule an already filled-in transfer descriptor for execution on
// the given endpoint, waiting until the endpoint has finished.
void usb_endpoint_schedule_wait(
const usb_endpoint_t* const endpoint,
usb_transfer_descriptor_t* const td
) {
// Ensure that endpoint is ready to be primed.
// It may have been flushed due to an aborted transaction.
// TODO: This should be preceded by a flush?
while( usb_endpoint_is_ready(endpoint) );
td->next_dtd_pointer = USB_TD_NEXT_DTD_POINTER_TERMINATE;
usb_endpoint_prime(endpoint, td);
}
// Schedule an already filled-in transfer descriptor for execution on
// the given endpoint, appending to the end of the endpoint's queue if
// there are pending TDs. Note that this requires that one knows the
// tail of the endpoint's TD queue. Moreover, the user is responsible
// for setting the TERMINATE bit of next_dtd_pointer if needed.
void usb_endpoint_schedule_append(
const usb_endpoint_t* const endpoint,
usb_transfer_descriptor_t* const tail_td,
usb_transfer_descriptor_t* const new_td
) {
bool done;
tail_td->next_dtd_pointer = new_td;
if (usb_endpoint_is_priming(endpoint)) {
return;
}
do {
USB0_USBCMD_D |= USB0_USBCMD_D_ATDTW;
done = usb_endpoint_is_ready(endpoint);
} while (!(USB0_USBCMD_D & USB0_USBCMD_D_ATDTW));
USB0_USBCMD_D &= ~USB0_USBCMD_D_ATDTW;
if(!done) {
usb_endpoint_prime(endpoint, new_td);
}
}
void usb_endpoint_flush(
const usb_endpoint_t* const endpoint
) {
const uint_fast8_t endpoint_number = usb_endpoint_number(endpoint->address);
usb_queue_flush_endpoint(endpoint);
if( usb_endpoint_is_in(endpoint->address) ) {
usb_flush_primed_endpoints(USB0_ENDPTFLUSH_FETB(1 << endpoint_number));
} else {
usb_flush_primed_endpoints(USB0_ENDPTFLUSH_FERB(1 << endpoint_number));
}
}
/*
static bool usb_endpoint_is_flushing(
const usb_endpoint_t* const endpoint
) {
const uint_fast8_t endpoint_number = usb_endpoint_number(endpoint->address);
if( usb_endpoint_is_in(endpoint->address) ) {
return USB0_ENDPTFLUSH & USB0_ENDPTFLUSH_FETB(1 << endpoint_number);
} else {
return USB0_ENDPTFLUSH & USB0_ENDPTFLUSH_FERB(1 << endpoint_number);
}
}
*/
bool usb_endpoint_is_ready(
const usb_endpoint_t* const endpoint
) {
const uint_fast8_t endpoint_number = usb_endpoint_number(endpoint->address);
if( usb_endpoint_is_in(endpoint->address) ) {
return USB0_ENDPTSTAT & USB0_ENDPTSTAT_ETBR(1 << endpoint_number);
} else {
return USB0_ENDPTSTAT & USB0_ENDPTSTAT_ERBR(1 << endpoint_number);
}
}
bool usb_endpoint_is_complete(
const usb_endpoint_t* const endpoint
) {
const uint_fast8_t endpoint_number = usb_endpoint_number(endpoint->address);
if( usb_endpoint_is_in(endpoint->address) ) {
return USB0_ENDPTCOMPLETE & USB0_ENDPTCOMPLETE_ETCE(1 << endpoint_number);
} else {
return USB0_ENDPTCOMPLETE & USB0_ENDPTCOMPLETE_ERCE(1 << endpoint_number);
}
}
void usb_endpoint_stall(
const usb_endpoint_t* const endpoint
) {
// Endpoint is to be stalled as a pair -- both OUT and IN.
// See UM10503 section 23.10.5.2 "Stalling"
const uint_fast8_t endpoint_number = usb_endpoint_number(endpoint->address);
USB0_ENDPTCTRL(endpoint_number) |= (USB0_ENDPTCTRL_RXS | USB0_ENDPTCTRL_TXS);
// TODO: Also need to reset data toggle in both directions?
}
void usb_endpoint_reset_data_toggle(
const usb_endpoint_t* const endpoint
) {
const uint_fast8_t endpoint_number = usb_endpoint_number(endpoint->address);
if( usb_endpoint_is_in(endpoint->address) ) {
USB0_ENDPTCTRL(endpoint_number) |= USB0_ENDPTCTRL_TXR;
} else {
USB0_ENDPTCTRL(endpoint_number) |= USB0_ENDPTCTRL_RXR;
}
}
static void usb_controller_run() {
USB0_USBCMD_D |= USB0_USBCMD_D_RS;
}
static void usb_controller_stop() {
USB0_USBCMD_D &= ~USB0_USBCMD_D_RS;
}
static uint_fast8_t usb_controller_is_resetting() {
return (USB0_USBCMD_D & USB0_USBCMD_D_RST) != 0;
}
static void usb_controller_set_device_mode() {
// Set USB0 peripheral mode
USB0_USBMODE_D = USB0_USBMODE_D_CM1_0(2);
// Set device-related OTG flags
// OTG termination: controls pull-down on USB_DM
USB0_OTGSC = USB0_OTGSC_OT;
}
usb_speed_t usb_speed(
const usb_device_t* const device
) {
if( device == usb_device_usb0 ) {
switch( USB0_PORTSC1_D & USB0_PORTSC1_D_PSPD_MASK ) {
case USB0_PORTSC1_D_PSPD(0):
return USB_SPEED_FULL;
case USB0_PORTSC1_D_PSPD(2):
return USB_SPEED_HIGH;
default:
// TODO: What to do/return here? Is this even possible?
return USB_SPEED_FULL;
}
} else {
// TODO: This should not be possible with a more class-like
// implementation.
return USB_SPEED_FULL;
}
}
static void usb_clear_status(const uint32_t status) {
USB0_USBSTS_D = status;
}
static uint32_t usb_get_status() {
// Mask status flags with enabled flag interrupts.
const uint32_t status = USB0_USBSTS_D & USB0_USBINTR_D;
// Clear flags that were just read, leaving alone any flags that
// were just set (after the read). It's important to read and
// reset flags atomically! :-)
usb_clear_status(status);
return status;
}
static void usb_clear_endpoint_setup_status(const uint32_t endpoint_setup_status) {
USB0_ENDPTSETUPSTAT = endpoint_setup_status;
}
static uint32_t usb_get_endpoint_setup_status() {
return USB0_ENDPTSETUPSTAT;
}
static void usb_clear_endpoint_complete(const uint32_t endpoint_complete) {
USB0_ENDPTCOMPLETE = endpoint_complete;
}
static uint32_t usb_get_endpoint_complete() {
return USB0_ENDPTCOMPLETE;
}
static void usb_disable_all_endpoints() {
// Endpoint 0 is always enabled. TODO: So why set ENDPTCTRL0?
USB0_ENDPTCTRL0 &= ~(USB0_ENDPTCTRL0_RXE | USB0_ENDPTCTRL0_TXE);
USB0_ENDPTCTRL1 &= ~(USB0_ENDPTCTRL1_RXE | USB0_ENDPTCTRL1_TXE);
USB0_ENDPTCTRL2 &= ~(USB0_ENDPTCTRL2_RXE | USB0_ENDPTCTRL2_TXE);
USB0_ENDPTCTRL3 &= ~(USB0_ENDPTCTRL3_RXE | USB0_ENDPTCTRL3_TXE);
USB0_ENDPTCTRL4 &= ~(USB0_ENDPTCTRL4_RXE | USB0_ENDPTCTRL4_TXE);
USB0_ENDPTCTRL5 &= ~(USB0_ENDPTCTRL5_RXE | USB0_ENDPTCTRL5_TXE);
}
void usb_set_address_immediate(
const usb_device_t* const device,
const uint_fast8_t address
) {
if( device == usb_device_usb0 ) {
USB0_DEVICEADDR = USB0_DEVICEADDR_USBADR(address);
}
}
void usb_set_address_deferred(
const usb_device_t* const device,
const uint_fast8_t address
) {
if( device == usb_device_usb0 ) {
USB0_DEVICEADDR
= USB0_DEVICEADDR_USBADR(address)
| USB0_DEVICEADDR_USBADRA
;
}
}
static void usb_reset_all_endpoints() {
usb_disable_all_endpoints();
usb_clear_all_pending_interrupts();
usb_flush_all_primed_endpoints();
}
static void usb_controller_reset() {
// TODO: Good to disable some USB interrupts to avoid priming new
// new endpoints before the controller is reset?
usb_reset_all_endpoints();
usb_controller_stop();
// Reset controller. Resets internal pipelines, timers, counters, state
// machines to initial values. Not recommended when device is in attached
// state -- effect on attached host is undefined. Detach first by flushing
// all primed endpoints and stopping controller.
USB0_USBCMD_D = USB0_USBCMD_D_RST;
while( usb_controller_is_resetting() );
}
static void usb_bus_reset(usb_device_t* const device) {
// According to UM10503 v1.4 section 23.10.3 "Bus reset":
usb_reset_all_endpoints();
usb_set_address_immediate(device, 0);
usb_set_configuration(device, 0);
// TODO: Enable endpoint 0, which might not actually be necessary,
// as the datasheet claims it can't be disabled.
//wait_ms(3);
//
//if( USB0_PORTSC1 & USB0_PORTSC1_PR ) {
// // Port still is in the reset state.
//} else {
// usb_hardware_reset();
//}
}
static void usb_interrupt_enable(
usb_device_t* const device
) {
if( device == usb_device_usb0 ) {
nvic_enable_irq(NVIC_USB0_IRQ);
}
}
void usb_device_init(
const uint_fast8_t device_ordinal,
usb_device_t* const device
) {
if( device_ordinal == 0 ) {
usb_device_usb0 = device;
usb_phy_enable();
usb_controller_reset();
usb_controller_set_device_mode();
// Set interrupt threshold interval to 0
USB0_USBCMD_D &= ~USB0_USBCMD_D_ITC_MASK;
// Configure endpoint list address
USB0_ENDPOINTLISTADDR = (uint32_t)usb_qh;
// Enable interrupts
USB0_USBINTR_D =
USB0_USBINTR_D_UE
| USB0_USBINTR_D_UEE
| USB0_USBINTR_D_PCE
| USB0_USBINTR_D_URE
//| USB0_USBINTR_D_SRE
| USB0_USBINTR_D_SLE
//| USB0_USBINTR_D_NAKE
;
}
}
void usb_run(
usb_device_t* const device
) {
usb_interrupt_enable(device);
usb_controller_run(device);
}
static void copy_setup(usb_setup_t* const dst, const volatile uint8_t* const src) {
dst->request_type = src[0];
dst->request = src[1];
dst->value_l = src[2];
dst->value_h = src[3];
dst->index_l = src[4];
dst->index_h = src[5];
dst->length_l = src[6];
dst->length_h = src[7];
}
void usb_endpoint_init(
const usb_endpoint_t* const endpoint
) {
usb_endpoint_flush(endpoint);
uint_fast16_t max_packet_size = endpoint->device->descriptor[7];
usb_transfer_type_t transfer_type = USB_TRANSFER_TYPE_CONTROL;
const uint8_t* const endpoint_descriptor = usb_endpoint_descriptor(endpoint);
if( endpoint_descriptor ) {
max_packet_size = usb_endpoint_descriptor_max_packet_size(endpoint_descriptor);
transfer_type = usb_endpoint_descriptor_transfer_type(endpoint_descriptor);
}
// TODO: There are more capabilities to adjust based on the endpoint
// descriptor.
usb_queue_head_t* const qh = usb_queue_head(endpoint->address);
qh->capabilities
= USB_QH_CAPABILITIES_MULT(0)
| USB_QH_CAPABILITIES_ZLT
| USB_QH_CAPABILITIES_MPL(max_packet_size)
| ((transfer_type == USB_TRANSFER_TYPE_CONTROL) ? USB_QH_CAPABILITIES_IOS : 0)
;
qh->current_dtd_pointer = 0;
qh->next_dtd_pointer = USB_TD_NEXT_DTD_POINTER_TERMINATE;
qh->total_bytes
= USB_TD_DTD_TOKEN_TOTAL_BYTES(0)
| USB_TD_DTD_TOKEN_MULTO(0)
;
qh->buffer_pointer_page[0] = 0;
qh->buffer_pointer_page[1] = 0;
qh->buffer_pointer_page[2] = 0;
qh->buffer_pointer_page[3] = 0;
qh->buffer_pointer_page[4] = 0;
// This is how we look up an endpoint structure from an endpoint address:
qh->_reserved_0 = (uint32_t)endpoint;
// TODO: Should NAK be enabled? I'm kinda squishy on this...
//USB0_ENDPTNAKEN |=
// USB0_ENDPTNAKEN_EPRNE(1 << endpoint_out->number);
usb_endpoint_set_type(endpoint, transfer_type);
usb_endpoint_enable(endpoint);
}
static void usb_check_for_setup_events() {
const uint32_t endptsetupstat = usb_get_endpoint_setup_status();
if( endptsetupstat ) {
for( uint_fast8_t i=0; i<6; i++ ) {
const uint32_t endptsetupstat_bit = USB0_ENDPTSETUPSTAT_ENDPTSETUPSTAT(1 << i);
if( endptsetupstat & endptsetupstat_bit ) {
usb_endpoint_t* const endpoint =
usb_endpoint_from_address(
usb_endpoint_address(USB_TRANSFER_DIRECTION_OUT, i)
);
if( endpoint && endpoint->setup_complete ) {
copy_setup(&endpoint->setup, usb_queue_head(endpoint->address)->setup);
// TODO: Clean up this duplicated effort by providing
// a cleaner way to get the SETUP data.
copy_setup(&endpoint->in->setup, usb_queue_head(endpoint->address)->setup);
usb_clear_endpoint_setup_status(endptsetupstat_bit);
endpoint->setup_complete(endpoint);
} else {
usb_clear_endpoint_setup_status(endptsetupstat_bit);
}
}
}
}
}
static void usb_check_for_transfer_events() {
const uint32_t endptcomplete = usb_get_endpoint_complete();
if( endptcomplete ) {
for( uint_fast8_t i=0; i<6; i++ ) {
const uint32_t endptcomplete_out_bit = USB0_ENDPTCOMPLETE_ERCE(1 << i);
if( endptcomplete & endptcomplete_out_bit ) {
usb_clear_endpoint_complete(endptcomplete_out_bit);
usb_endpoint_t* const endpoint =
usb_endpoint_from_address(
usb_endpoint_address(USB_TRANSFER_DIRECTION_OUT, i)
);
if( endpoint && endpoint->transfer_complete ) {
endpoint->transfer_complete(endpoint);
}
}
const uint32_t endptcomplete_in_bit = USB0_ENDPTCOMPLETE_ETCE(1 << i);
if( endptcomplete & endptcomplete_in_bit ) {
usb_clear_endpoint_complete(endptcomplete_in_bit);
usb_endpoint_t* const endpoint =
usb_endpoint_from_address(
usb_endpoint_address(USB_TRANSFER_DIRECTION_IN, i)
);
if( endpoint && endpoint->transfer_complete ) {
endpoint->transfer_complete(endpoint);
}
}
}
}
}
void usb0_isr() {
const uint32_t status = usb_get_status();
if( status == 0 ) {
// Nothing to do.
return;
}
if( status & USB0_USBSTS_D_UI ) {
// USB:
// - Completed transaction transfer descriptor has IOC set.
// - Short packet detected.
// - SETUP packet received.
usb_check_for_setup_events();
usb_check_for_transfer_events();
// TODO: Reset ignored ENDPTSETUPSTAT and ENDPTCOMPLETE flags?
}
if( status & USB0_USBSTS_D_SRI ) {
// Start Of Frame received.
}
if( status & USB0_USBSTS_D_PCI ) {
// Port change detect:
// Port controller entered full- or high-speed operational state.
}
if( status & USB0_USBSTS_D_SLI ) {
// Device controller suspend.
}
if( status & USB0_USBSTS_D_URI ) {
// USB reset received.
usb_bus_reset(usb_device_usb0);
}
if( status & USB0_USBSTS_D_UEI ) {
// USB error:
// Completion of a USB transaction resulted in an error condition.
// Set along with USBINT if the TD on which the error interrupt
// occurred also had its interrupt on complete (IOC) bit set.
// The device controller detects resume signalling only.
}
if( status & USB0_USBSTS_D_NAKI ) {
// Both the TX/RX endpoint NAK bit and corresponding TX/RX endpoint
// NAK enable bit are set.
}
}