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#if defined(STM32F1) || defined(STM32F4)
#include "i2c.h"
#include <rcc/rcc.h>
#include <os/thread.h>
#if defined(STM32F1)
I2C_t I2C1(0x40005400, 36000000, Interrupt::I2C1_EV, Interrupt::I2C1_ER);
I2C_t I2C2(0x40005800, 36000000, Interrupt::I2C2_EV, Interrupt::I2C2_ER);
#elif defined(STM32F4)
I2C_t I2C1(0x40005400, 42000000, Interrupt::I2C1_EV, Interrupt::I2C1_ER);
I2C_t I2C2(0x40005800, 42000000, Interrupt::I2C2_EV, Interrupt::I2C2_ER);
//I2C_t I2C3(0x40005c00, 42000000, Interrupt::I2C3_EV, Interrupt::I2C3_ER);
#endif
void I2C_t::irq_ev() {
uint32_t sr1 = reg.SR1;
reg.SR2;
// EV5, SB = 1: Start condition sent.
if(sr1 & 0x01) {
// Send address.
reg.DR = (addr << 1) | (writing ? 0 : 1);
}
// EV6, ADDR = 1: Address sent.
if(sr1 & 0x02) {
if(writing) {
reg.DR = *write_p++;
writing--;
} else {
if(reading > 1) {
reg.CR1 |= 0x400; // Set ACK.
} else {
reg.CR1 |= 0x200; // Set STOP.
}
}
}
// EV7, RxNE = 1: Receive buffer not empty.
if(sr1 & 0x40) {
*read_p++ = reg.DR;
reading--;
if(reading == 1) {
// Unset ACK, set STOP.
reg.CR1 = (reg.CR1 & ~0x400) | 0x200;
}
if(reading == 0) {
busy = 0;
}
}
//reg.CR1 &= ~0x400;
// EV8, TxE = 1, BTF = 0: Transmit buffer empty, still writing.
if(sr1 & 0x80 && !(sr1 & 0x04)) {
if(writing) {
// Send data.
reg.DR = *write_p++;
writing--;
} else {
// All data sent.
if(reading) {
// Send repeat start.
reg.CR1 |= 0x100;
} else {
// Send stop.
reg.CR1 |= 0x200;
busy = 0;
}
}
}
}
void I2C_t::irq_er() {
handle_error();
}
void I2C_t::handle_error() {
reg.SR1;
reg.SR2;
//while(1);
reg.SR1 = 0;
reg.CR1 |= 0x200;
busy = 0;
}
void I2C_t::enable(Pin& scl, Pin& sda) {
RCC.enable(RCC.I2C1);
asm volatile("nop");
scl.set_af(4);
sda.set_af(4);
scl.set_type(Pin::OpenDrain);
sda.set_type(Pin::OpenDrain);
scl.set_mode(Pin::AF);
sda.set_mode(Pin::AF);
reg.CR1 = 0x8000;
reg.CR1 = 0;
reg.CR2 = 0x700 | (clk / 1000000);
reg.TRISE = clk / 1000000 + 1;
reg.CCR = clk / 2 / 100000;
Interrupt::enable(irq_ev_n, &I2C_t::irq_ev, this);
Interrupt::enable(irq_er_n, &I2C_t::irq_er, this);
reg.CR1 = 1;
}
void I2C_t::write_reg(uint8_t addr_, uint8_t reg_, uint8_t data) {
addr = addr_;
writing = 2;
reading = 0;
volatile uint8_t buf[] = {reg_, data};
write_p = buf;
busy = 1;
reg.CR1 |= 0x100;
while(busy) {
Thread::yield();
}
}
void I2C_t::read_reg(uint8_t addr_, uint8_t reg_, uint8_t len, uint8_t* buf) {
addr = addr_;
writing = 1;
reading = len;
write_p = ®_;
read_p = buf;
busy = 1;
reg.CR1 |= 0x100;
while(busy) {
Thread::yield();
}
}
#endif
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