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#include <rcc/rcc.h>
#include <rcc/flash.h>
#include <gpio/gpio.h>
#include <interrupt/interrupt.h>
#include <timer/timer.h>
#include <os/time.h>
#include <usb/usb.h>
#include <usb/descriptor.h>
#include <usb/hid.h>
#include <string.h>
static uint32_t& reset_reason = *(uint32_t*)0x10000000;
static bool do_reset_bootloader;
static bool do_reset;
void reset() {
SCB.AIRCR = (0x5fa << 16) | (1 << 2); // SYSRESETREQ
}
void reset_bootloader() {
reset_reason = 0xb007;
reset();
}
class Configloader {
private:
enum {
MAGIC = 0xc0ff600d,
};
struct header_t {
uint32_t magic;
uint32_t size;
};
uint32_t flash_addr;
public:
Configloader(uint32_t addr) : flash_addr(addr) {}
bool read(uint32_t size, void* data) {
header_t* header = (header_t*)flash_addr;
if(header->magic != MAGIC) {
return false;
}
if(header->size < size) {
size = header->size;
}
memcpy(data, (void*)(flash_addr + sizeof(header_t)), size);
return true;
}
bool write(uint32_t size, void* data) {
header_t header = {MAGIC, size};
// Unlock flash.
FLASH.KEYR = 0x45670123;
FLASH.KEYR = 0xCDEF89AB;
// Erase page.
FLASH.CR = 1 << 1; // PER
FLASH.AR = flash_addr;
FLASH.CR = (1 << 6) | (1 << 1); // STRT, PER
while(FLASH.SR & (1 << 0)); // BSY
FLASH.SR &= ~(1 << 5); // EOP
FLASH.CR = 0;
// Write header.
uint16_t* src = (uint16_t*)&header;
uint16_t* dest = (uint16_t*)flash_addr;
for(uint32_t n = 0; n < sizeof(header); n += 2) {
FLASH.CR = 1 << 0; // PG
*dest++ = *src++;
while(FLASH.SR & (1 << 0)); // BSY
}
// Write data.
src = (uint16_t*)data;
for(uint32_t n = 0; n < size; n += 2) {
FLASH.CR = 1 << 0; // PG
*dest++ = *src++;
while(FLASH.SR & (1 << 0)); // BSY
}
// Lock flash.
FLASH.CR = 1 << 7; // LOCK
return true;
}
};
Configloader configloader(0x801f800);
struct config_t {
uint8_t label[12];
uint32_t flags;
int8_t qe1_sens;
int8_t qe2_sens;
uint8_t ps2_mode;
uint8_t ws2812b_mode;
};
config_t config;
auto report_desc = gamepad(
// Inputs.
report_id(1),
buttons(15),
padding_in(1),
usage_page(UsagePage::Desktop),
usage(DesktopUsage::X),
logical_minimum(0),
logical_maximum(255),
report_count(1),
report_size(8),
input(0x02),
usage_page(UsagePage::Desktop),
usage(DesktopUsage::Y),
logical_minimum(0),
logical_maximum(255),
report_count(1),
report_size(8),
input(0x02),
// Outputs.
report_id(2),
usage_page(UsagePage::Ordinal),
usage(1),
collection(Collection::Logical,
usage_page(UsagePage::LED),
usage(0x4b),
report_size(1),
report_count(1),
output(0x02)
),
usage_page(UsagePage::Ordinal),
usage(2),
collection(Collection::Logical,
usage_page(UsagePage::LED),
usage(0x4b),
report_size(1),
report_count(1),
output(0x02)
),
usage_page(UsagePage::Ordinal),
usage(3),
collection(Collection::Logical,
usage_page(UsagePage::LED),
usage(0x4b),
report_size(1),
report_count(1),
output(0x02)
),
usage_page(UsagePage::Ordinal),
usage(4),
collection(Collection::Logical,
usage_page(UsagePage::LED),
usage(0x4b),
report_size(1),
report_count(1),
output(0x02)
),
usage_page(UsagePage::Ordinal),
usage(5),
collection(Collection::Logical,
usage_page(UsagePage::LED),
usage(0x4b),
report_size(1),
report_count(1),
output(0x02)
),
usage_page(UsagePage::Ordinal),
usage(6),
collection(Collection::Logical,
usage_page(UsagePage::LED),
usage(0x4b),
report_size(1),
report_count(1),
output(0x02)
),
usage_page(UsagePage::Ordinal),
usage(7),
collection(Collection::Logical,
usage_page(UsagePage::LED),
usage(0x4b),
report_size(1),
report_count(1),
output(0x02)
),
usage_page(UsagePage::Ordinal),
usage(8),
collection(Collection::Logical,
usage_page(UsagePage::LED),
usage(0x4b),
report_size(1),
report_count(1),
output(0x02)
),
usage_page(UsagePage::Ordinal),
usage(9),
collection(Collection::Logical,
usage_page(UsagePage::LED),
usage(0x4b),
report_size(1),
report_count(1),
output(0x02)
),
usage_page(UsagePage::Ordinal),
usage(10),
collection(Collection::Logical,
usage_page(UsagePage::LED),
usage(0x4b),
report_size(1),
report_count(1),
output(0x02)
),
usage_page(UsagePage::Ordinal),
usage(11),
collection(Collection::Logical,
usage_page(UsagePage::LED),
usage(0x4b),
report_size(1),
report_count(1),
output(0x02)
),
padding_out(5),
// Bootloader
report_id(0xb0),
usage_page(0xff55),
usage(0xb007),
logical_minimum(0),
logical_maximum(255),
report_size(8),
report_count(1),
feature(0x02), // HID bootloader function
// Configuration
report_id(0xc0),
usage(0xc000),
feature(0x02), // Config segment
usage(0xc001),
feature(0x02), // Config segment size
feature(0x01), // Padding
usage(0xc0ff),
report_count(60),
feature(0x02) // Config data
);
struct input_report_t {
uint8_t report_id;
uint16_t buttons;
uint8_t axis_x;
uint8_t axis_y;
} __attribute__((packed));
struct output_report_t {
uint8_t report_id;
uint16_t leds;
} __attribute__((packed));
struct bootloader_report_t {
uint8_t report_id;
uint8_t func;
} __attribute__((packed));
struct config_report_t {
uint8_t report_id;
uint8_t segment;
uint8_t size;
uint8_t pad;
uint8_t data[60];
} __attribute__((packed));
auto dev_desc = device_desc(0x200, 0, 0, 0, 64, 0x1d50, 0x6080, 0x110, 1, 2, 3, 1);
auto conf_desc = configuration_desc(1, 1, 0, 0xc0, 0,
// HID interface.
interface_desc(0, 0, 1, 0x03, 0x00, 0x00, 0,
hid_desc(0x111, 0, 1, 0x22, sizeof(report_desc)),
endpoint_desc(0x81, 0x03, 16, 1)
)
);
desc_t dev_desc_p = {sizeof(dev_desc), (void*)&dev_desc};
desc_t conf_desc_p = {sizeof(conf_desc), (void*)&conf_desc};
desc_t report_desc_p = {sizeof(report_desc), (void*)&report_desc};
static Pin usb_dm = GPIOA[11];
static Pin usb_dp = GPIOA[12];
static Pin usb_pu = GPIOA[15];
static PinArray button_inputs = GPIOB.array(0, 10);
static PinArray button_leds = GPIOC.array(0, 10);
static Pin qe1a = GPIOA[0];
static Pin qe1b = GPIOA[1];
static Pin qe2a = GPIOA[6];
static Pin qe2b = GPIOA[7];
static Pin led1 = GPIOA[8];
static Pin led2 = GPIOA[9];
USB_f1 usb(USB, dev_desc_p, conf_desc_p);
uint32_t last_led_time;
class HID_arcin : public USB_HID {
private:
bool set_feature_bootloader(bootloader_report_t* report) {
switch(report->func) {
case 0:
return true;
case 0x10: // Reset to bootloader
do_reset_bootloader = true;
return true;
case 0x20: // Reset to runtime
do_reset = true;
return true;
default:
return false;
}
}
bool set_feature_config(config_report_t* report) {
if(report->segment != 0) {
return false;
}
configloader.write(report->size, report->data);
return true;
}
bool get_feature_config() {
config_report_t report = {0xc0, 0, sizeof(config)};
memcpy(report.data, &config, sizeof(config));
usb.write(0, (uint32_t*)&report, sizeof(report));
return true;
}
public:
HID_arcin(USB_generic& usbd, desc_t rdesc) : USB_HID(usbd, rdesc, 0, 1, 64) {}
protected:
virtual bool set_output_report(uint32_t* buf, uint32_t len) {
if(len != sizeof(output_report_t)) {
return false;
}
output_report_t* report = (output_report_t*)buf;
last_led_time = Time::time();
button_leds.set(report->leds);
return true;
}
virtual bool set_feature_report(uint32_t* buf, uint32_t len) {
switch(*buf & 0xff) {
case 0xb0:
if(len != sizeof(bootloader_report_t)) {
return false;
}
return set_feature_bootloader((bootloader_report_t*)buf);
case 0xc0:
if(len != sizeof(config_report_t)) {
return false;
}
return set_feature_config((config_report_t*)buf);
default:
return false;
}
}
virtual bool get_feature_report(uint8_t report_id) {
switch(report_id) {
case 0xc0:
return get_feature_config();
default:
return false;
}
}
};
HID_arcin usb_hid(usb, report_desc_p);
uint32_t serial_num() {
uint32_t* uid = (uint32_t*)0x1ffff7ac;
return uid[0] * uid[1] * uid[2];
}
class USB_strings : public USB_class_driver {
private:
USB_generic& usb;
public:
USB_strings(USB_generic& usbd) : usb(usbd) {
usb.register_driver(this);
}
protected:
virtual SetupStatus handle_setup(uint8_t bmRequestType, uint8_t bRequest, uint16_t wValue, uint16_t wIndex, uint16_t wLength) {
// Get string descriptor.
if(bmRequestType == 0x80 && bRequest == 0x06 && (wValue & 0xff00) == 0x0300) {
const void* desc = nullptr;
uint16_t buf[64] = {0x300};
uint32_t i = 1;
switch(wValue & 0xff) {
case 0:
desc = u"\u0304\u0409";
break;
case 1:
desc = u"\u0308zyp";
break;
case 2:
for(const char* p = "arcin"; *p; p++) {
buf[i++] = *p;
}
if(config.label[0]) {
buf[i++] = ' ';
buf[i++] = '(';
for(uint8_t* p = config.label; *p; p++) {
buf[i++] = *p;
}
buf[i++] = ')';
}
buf[0] |= i * 2;
desc = buf;
break;
case 3:
{
buf[0] = 0x0312;
uint32_t id = serial_num();
for(int i = 8; i > 0; i--) {
buf[i] = (id & 0xf) > 9 ? 'A' + (id & 0xf) - 0xa : '0' + (id & 0xf);
id >>= 4;
}
desc = buf;
}
break;
}
if(!desc) {
return SetupStatus::Unhandled;
}
uint8_t len = *(uint8_t*)desc;
if(len > wLength) {
len = wLength;
}
usb.write(0, (uint32_t*)desc, len);
return SetupStatus::Ok;
}
return SetupStatus::Unhandled;
}
};
USB_strings usb_strings(usb);
int main() {
rcc_init();
// Initialize system timer.
STK.LOAD = 72000000 / 8 / 1000; // 1000 Hz.
STK.CTRL = 0x03;
// Load config.
configloader.read(sizeof(config), &config);
RCC.enable(RCC.GPIOA);
RCC.enable(RCC.GPIOB);
RCC.enable(RCC.GPIOC);
usb_dm.set_mode(Pin::AF);
usb_dm.set_af(14);
usb_dp.set_mode(Pin::AF);
usb_dp.set_af(14);
RCC.enable(RCC.USB);
usb.init();
usb_pu.set_mode(Pin::Output);
usb_pu.on();
button_inputs.set_mode(Pin::Input);
button_inputs.set_pull(Pin::PullUp);
button_leds.set_mode(Pin::Output);
led1.set_mode(Pin::Output);
led1.on();
led2.set_mode(Pin::Output);
led2.on();
RCC.enable(RCC.TIM2);
RCC.enable(RCC.TIM3);
TIM2.CCMR1 = (1 << 8) | (1 << 0);
TIM2.CCER = 1 << 1;
TIM2.SMCR = 3;
TIM2.CR1 = 1;
if(config.qe1_sens < 0) {
TIM2.ARR = 256 * -config.qe1_sens - 1;
} else {
TIM2.ARR = 256 - 1;
}
TIM3.CCMR1 = (1 << 8) | (1 << 0);
TIM3.CCER = 1 << 1;
TIM3.SMCR = 3;
TIM3.CR1 = 1;
if(config.qe2_sens < 0) {
TIM3.ARR = 256 * -config.qe2_sens - 1;
} else {
TIM3.ARR = 256 - 1;
}
qe1a.set_af(1);
qe1b.set_af(1);
qe1a.set_mode(Pin::AF);
qe1b.set_mode(Pin::AF);
qe2a.set_af(2);
qe2b.set_af(2);
qe2a.set_mode(Pin::AF);
qe2b.set_mode(Pin::AF);
uint8_t last_x = 0;
uint8_t last_y = 0;
int8_t state_x = 0;
int8_t state_y = 0;
while(1) {
usb.process();
uint16_t buttons = button_inputs.get() ^ 0x7ff;
if(do_reset_bootloader) {
Time::sleep(10);
reset_bootloader();
}
if(do_reset) {
Time::sleep(10);
reset();
}
if(Time::time() - last_led_time > 1000) {
button_leds.set(buttons);
}
if(usb.ep_ready(1)) {
uint32_t qe1_count = TIM2.CNT;
uint32_t qe2_count = TIM3.CNT;
int8_t rx = qe1_count - last_x;
int8_t ry = qe2_count - last_y;
if(rx > 1) {
state_x = 100;
last_x = qe1_count;
} else if(rx < -1) {
state_x = -100;
last_x = qe1_count;
} else if(state_x > 0) {
state_x--;
last_x = qe1_count;
} else if(state_x < 0) {
state_x++;
last_x = qe1_count;
}
if(ry > 1) {
state_y = 100;
last_y = qe2_count;
} else if(ry < -1) {
state_y = -100;
last_y = qe2_count;
} else if(state_y > 0) {
state_y--;
last_y = qe2_count;
} else if(state_y < 0) {
state_y++;
last_y = qe2_count;
}
if(state_x > 0) {
buttons |= 1 << 11;
} else if(state_x < 0) {
buttons |= 1 << 12;
}
if(state_y > 0) {
buttons |= 1 << 13;
} else if(state_y < 0) {
buttons |= 1 << 14;
}
if(config.qe1_sens < 0) {
qe1_count /= -config.qe1_sens;
} else if(config.qe1_sens > 0) {
qe1_count *= config.qe1_sens;
}
if(config.qe2_sens < 0) {
qe2_count /= -config.qe2_sens;
} else if(config.qe2_sens > 0) {
qe2_count *= config.qe2_sens;
}
input_report_t report = {1, buttons, uint8_t(qe1_count), uint8_t(qe2_count)};
usb.write(1, (uint32_t*)&report, sizeof(report));
}
}
}
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