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chromium / chromiumos / platform / ec / v2.2.0 / . / chip / stm32 / usb_pd_phy.c
blob: 8c6ecca11018e641e71f30c41c5be8c6a5ac9f45 [file] [log] [blame]
/* Copyright (c) 2014 The Chromium OS Authors. All rights reserved.
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
#include "adc.h"
#include "clock.h"
#include "common.h"
#include "console.h"
#include "crc.h"
#include "dma.h"
#include "gpio.h"
#include "hwtimer.h"
#include "hooks.h"
#include "registers.h"
#include "system.h"
#include "task.h"
#include "timer.h"
#include "util.h"
#include "usb_pd.h"
#include "usb_pd_config.h"
#ifdef CONFIG_COMMON_RUNTIME
#define CPRINTF(format, args...) cprintf(CC_USBPD, format, ## args)
#define CPRINTS(format, args...) cprints(CC_USBPD, format, ## args)
#else
#define CPRINTF(format, args...)
#define CPRINTS(format, args...)
#endif
#define PD_DATARATE 300000 /* Hz */
/*
* Maximum size of a Power Delivery packet (in bits on the wire) :
* 16-bit header + 0..7 32-bit data objects (+ 4b5b encoding)
* 64-bit preamble + SOP (4x 5b) + message in 4b5b + 32-bit CRC + EOP (1x 5b)
* = 64 + 4*5 + 16 * 5/4 + 7 * 32 * 5/4 + 32 * 5/4 + 5
*/
#define PD_BIT_LEN 429
#define PD_MAX_RAW_SIZE (PD_BIT_LEN*2)
/* maximum number of consecutive similar bits with Biphase Mark Coding */
#define MAX_BITS 2
/* alternating bit sequence used for packet preamble : 00 10 11 01 00 .. */
#define PD_PREAMBLE 0xB4B4B4B4 /* starts with 0, ends with 1 */
#define TX_CLOCK_DIV ((clock_get_freq() / (2*PD_DATARATE)))
/* threshold for 1 300-khz period */
#define PERIOD 4
#define NB_PERIOD(from, to) ((((to) - (from) + (PERIOD/2)) & 0xFF) / PERIOD)
#define PERIOD_THRESHOLD ((PERIOD + 2*PERIOD) / 2)
static struct pd_physical {
/* samples for the PD messages */
uint32_t raw_samples[DIV_ROUND_UP(PD_MAX_RAW_SIZE, sizeof(uint32_t))];
/* state of the bit decoder */
int d_toggle;
int d_lastlen;
uint32_t d_last;
int b_toggle;
/* DMA structures for each PD port */
struct dma_option dma_tx_option;
struct dma_option dma_tim_option;
/* Pointers to timer register for each port */
timer_ctlr_t *tim_tx;
timer_ctlr_t *tim_rx;
} pd_phy[CONFIG_USB_PD_PORT_COUNT];
/* keep track of RX edge timing in order to trigger receive */
static timestamp_t rx_edge_ts[CONFIG_USB_PD_PORT_COUNT][PD_RX_TRANSITION_COUNT];
static int rx_edge_ts_idx[CONFIG_USB_PD_PORT_COUNT];
/* keep track of transmit polarity for DMA interrupt */
static int tx_dma_polarities[CONFIG_USB_PD_PORT_COUNT];
void pd_init_dequeue(int port)
{
/* preamble ends with 1 */
pd_phy[port].d_toggle = 0;
pd_phy[port].d_last = 0;
pd_phy[port].d_lastlen = 0;
}
static int wait_bits(int port, int nb)
{
int avail;
stm32_dma_chan_t *rx = dma_get_channel(DMAC_TIM_RX(port));
avail = dma_bytes_done(rx, PD_MAX_RAW_SIZE);
if (avail < nb) { /* no received yet ... */
while ((dma_bytes_done(rx, PD_MAX_RAW_SIZE) < nb)
&& !(pd_phy[port].tim_rx->sr & 4))
; /* optimized for latency, not CPU usage ... */
if (dma_bytes_done(rx, PD_MAX_RAW_SIZE) < nb) {
CPRINTS("PD TMOUT RX %d/%d",
dma_bytes_done(rx, PD_MAX_RAW_SIZE), nb);
return -1;
}
}
return nb;
}
int pd_dequeue_bits(int port, int off, int len, uint32_t *val)
{
int w;
uint8_t cnt = 0xff;
uint8_t *samples = (uint8_t *)pd_phy[port].raw_samples;
while ((pd_phy[port].d_lastlen < len) && (off < PD_MAX_RAW_SIZE - 1)) {
w = wait_bits(port, off + 2);
if (w < 0)
goto stream_err;
cnt = samples[off] - samples[off-1];
if (!cnt || (cnt > 3*PERIOD))
goto stream_err;
off++;
if (cnt <= PERIOD_THRESHOLD) {
/*
w = wait_bits(port, off + 1);
if (w < 0)
goto stream_err;
*/
cnt = samples[off] - samples[off-1];
if (cnt > PERIOD_THRESHOLD)
goto stream_err;
off++;
}
/* enqueue the bit of the last period */
pd_phy[port].d_last = (pd_phy[port].d_last >> 1)
| (cnt <= PERIOD_THRESHOLD ? 0x80000000 : 0);
pd_phy[port].d_lastlen++;
}
if (off < PD_MAX_RAW_SIZE) {
*val = (pd_phy[port].d_last << (pd_phy[port].d_lastlen - len))
>> (32 - len);
pd_phy[port].d_lastlen -= len;
return off;
} else {
return -1;
}
stream_err:
/* CPRINTS("PD Invalid %d @%d", cnt, off); */
return -1;
}
int pd_find_preamble(int port)
{
int bit;
uint8_t *vals = (uint8_t *)pd_phy[port].raw_samples;
/*
* Detect preamble
* Alternate 1-period 1-period & 2-period.
*/
uint32_t all = 0;
stm32_dma_chan_t *rx = dma_get_channel(DMAC_TIM_RX(port));
for (bit = 1; bit < PD_MAX_RAW_SIZE - 1; bit++) {
uint8_t cnt;
/* wait if the bit is not received yet ... */
if (PD_MAX_RAW_SIZE - rx->cndtr < bit + 1) {
while ((PD_MAX_RAW_SIZE - rx->cndtr < bit + 1) &&
!(pd_phy[port].tim_rx->sr & 4))
;
if (pd_phy[port].tim_rx->sr & 4) {
CPRINTS("PD TMOUT RX %d/%d",
PD_MAX_RAW_SIZE - rx->cndtr, bit);
return -1;
}
}
cnt = vals[bit] - vals[bit-1];
all = (all >> 1) | (cnt <= PERIOD_THRESHOLD ? 1 << 31 : 0);
if (all == 0x36db6db6)
return bit - 1; /* should be SYNC-1 */
if (all == 0xF33F3F3F)
return PD_RX_ERR_HARD_RESET; /* got HARD-RESET */
if (all == 0x3c7fe0ff)
return PD_RX_ERR_CABLE_RESET; /* got CABLE-RESET */
}
return -1;
}
int pd_write_preamble(int port)
{
uint32_t *msg = pd_phy[port].raw_samples;
/* 64-bit x2 preamble */
msg[0] = PD_PREAMBLE;
msg[1] = PD_PREAMBLE;
msg[2] = PD_PREAMBLE;
msg[3] = PD_PREAMBLE;
pd_phy[port].b_toggle = 0x3FF; /* preamble ends with 1 */
return 2*64;
}
int pd_write_sym(int port, int bit_off, uint32_t val10)
{
uint32_t *msg = pd_phy[port].raw_samples;
int word_idx = bit_off / 32;
int bit_idx = bit_off % 32;
uint32_t val = pd_phy[port].b_toggle ^ val10;
pd_phy[port].b_toggle = val & 0x200 ? 0x3FF : 0;
if (bit_idx <= 22) {
if (bit_idx == 0)
msg[word_idx] = 0;
msg[word_idx] |= val << bit_idx;
} else {
msg[word_idx] |= val << bit_idx;
msg[word_idx+1] = val >> (32 - bit_idx);
/* side effect: clear the new word when starting it */
}
return bit_off + 5*2;
}
int pd_write_last_edge(int port, int bit_off)
{
uint32_t *msg = pd_phy[port].raw_samples;
int word_idx = bit_off / 32;
int bit_idx = bit_off % 32;
if (bit_idx == 0)
msg[word_idx] = 0;
if (!pd_phy[port].b_toggle /* last bit was 0 */) {
/* transition to 1, another 1, then 0 */
if (bit_idx == 31) {
msg[word_idx++] |= 1 << bit_idx;
msg[word_idx] = 1;
} else {
msg[word_idx] |= 3 << bit_idx;
}
}
/* ensure that the trailer is 0 */
msg[word_idx+1] = 0;
return bit_off + 3;
}
#ifdef CONFIG_COMMON_RUNTIME
void pd_dump_packet(int port, const char *msg)
{
uint8_t *vals = (uint8_t *)pd_phy[port].raw_samples;
int bit;
CPRINTF("ERR %s:\n000:- ", msg);
/* Packet debug output */
for (bit = 1; bit < PD_MAX_RAW_SIZE; bit++) {
int cnt = NB_PERIOD(vals[bit-1], vals[bit]);
if ((bit & 31) == 0)
CPRINTF("\n%03d:", bit);
CPRINTF("%1d ", cnt);
}
CPRINTF("><\n");
cflush();
for (bit = 0; bit < PD_MAX_RAW_SIZE; bit++) {
if ((bit & 31) == 0)
CPRINTF("\n%03d:", bit);
CPRINTF("%02x ", vals[bit]);
}
CPRINTF("||\n");
cflush();
}
#endif /* CONFIG_COMMON_RUNTIME */
/* --- SPI TX operation --- */
void pd_tx_spi_init(int port)
{
stm32_spi_regs_t *spi = SPI_REGS(port);
/* Enable Tx DMA for our first transaction */
spi->cr2 = STM32_SPI_CR2_TXDMAEN | STM32_SPI_CR2_DATASIZE(8);
/* Enable the slave SPI: LSB first, force NSS, TX only, CPHA */
spi->cr1 = STM32_SPI_CR1_SPE | STM32_SPI_CR1_LSBFIRST
| STM32_SPI_CR1_SSM | STM32_SPI_CR1_BIDIMODE
| STM32_SPI_CR1_BIDIOE | STM32_SPI_CR1_CPHA;
}
static void tx_dma_done(void *data)
{
int port = (int)data;
int polarity = tx_dma_polarities[port];
stm32_spi_regs_t *spi = SPI_REGS(port);
while (spi->sr & STM32_SPI_SR_FTLVL)
; /* wait for TX FIFO empty */
while (spi->sr & STM32_SPI_SR_BSY)
; /* wait for BSY == 0 */
/* Stop counting */
pd_phy[port].tim_tx->cr1 &= ~1;
/* put TX pins and reference in Hi-Z */
pd_tx_disable(port, polarity);
#if defined(CONFIG_COMMON_RUNTIME) && defined(CONFIG_DMA_DEFAULT_HANDLERS)
task_set_event(PD_PORT_TO_TASK_ID(port), TASK_EVENT_DMA_TC, 0);
#endif
}
int pd_start_tx(int port, int polarity, int bit_len)
{
stm32_dma_chan_t *tx = dma_get_channel(DMAC_SPI_TX(port));
#ifndef CONFIG_USB_PD_TX_PHY_ONLY
/* disable RX detection interrupt */
pd_rx_disable_monitoring(port);
/* Check that we are not receiving a frame to avoid collisions */
if (pd_rx_started(port))
return -5;
#endif /* !CONFIG_USB_PD_TX_PHY_ONLY */
/* Initialize spi peripheral to prepare for transmission. */
pd_tx_spi_init(port);
/*
* Set timer to one tick before reset so that the first tick causes
* a rising edge on the output.
*/
pd_phy[port].tim_tx->cnt = TX_CLOCK_DIV - 1;
/* update DMA configuration */
dma_prepare_tx(&(pd_phy[port].dma_tx_option),
DIV_ROUND_UP(bit_len, 8),
pd_phy[port].raw_samples);
/* Flush data in write buffer so that DMA can get the latest data */
asm volatile("dmb;");
/* Kick off the DMA to send the data */
dma_clear_isr(DMAC_SPI_TX(port));
#if defined(CONFIG_COMMON_RUNTIME) && defined(CONFIG_DMA_DEFAULT_HANDLERS)
tx_dma_polarities[port] = polarity;
if (!(pd_phy[port].dma_tx_option.flags & STM32_DMA_CCR_CIRC)) {
/* Only enable interrupt if not in circular mode */
dma_enable_tc_interrupt_callback(DMAC_SPI_TX(port),
&tx_dma_done,
(void *)port);
}
#endif
dma_go(tx);
/*
* Drive the CC line from the TX block :
* - put SPI function on TX pin.
* - set the low level reference.
* Call this last before enabling timer in order to meet spec on
* timing between enabling TX and clocking out bits.
*/
pd_tx_enable(port, polarity);
/* Start counting at 300Khz*/
pd_phy[port].tim_tx->cr1 |= 1;
return bit_len;
}
void pd_tx_done(int port, int polarity)
{
#if defined(CONFIG_COMMON_RUNTIME) && defined(CONFIG_DMA_DEFAULT_HANDLERS)
/* wait for DMA, DMA interrupt will stop the SPI clock */
task_wait_event_mask(TASK_EVENT_DMA_TC, DMA_TRANSFER_TIMEOUT_US);
dma_disable_tc_interrupt(DMAC_SPI_TX(port));
#else
tx_dma_polarities[port] = polarity;
tx_dma_done((void *)port);
#endif
/* Reset SPI to clear remaining data in buffer */
pd_tx_spi_reset(port);
}
void pd_tx_set_circular_mode(int port)
{
pd_phy[port].dma_tx_option.flags |= STM32_DMA_CCR_CIRC;
}
void pd_tx_clear_circular_mode(int port)
{
/* clear the circular mode bit in flag variable */
pd_phy[port].dma_tx_option.flags &= ~STM32_DMA_CCR_CIRC;
/* disable dma transaction underway */
dma_disable(DMAC_SPI_TX(port));
#if defined(CONFIG_COMMON_RUNTIME) && defined(CONFIG_DMA_DEFAULT_HANDLERS)
tx_dma_done((void *)port);
#endif
}
/* --- RX operation using comparator linked to timer --- */
void pd_rx_start(int port)
{
/* start sampling the edges on the CC line using the RX timer */
dma_start_rx(&(pd_phy[port].dma_tim_option), PD_MAX_RAW_SIZE,
pd_phy[port].raw_samples);
/* enable TIM2 DMA requests */
pd_phy[port].tim_rx->egr = 0x0001; /* reset counter / reload PSC */;
pd_phy[port].tim_rx->sr = 0; /* clear overflows */
pd_phy[port].tim_rx->cr1 |= 1;
}
void pd_rx_complete(int port)
{
/* stop stampling TIM2 */
pd_phy[port].tim_rx->cr1 &= ~1;
/* stop DMA */
dma_disable(DMAC_TIM_RX(port));
}
int pd_rx_started(int port)
{
/* is the sampling timer running ? */
return pd_phy[port].tim_rx->cr1 & 1;
}
void pd_rx_enable_monitoring(int port)
{
/* clear comparator external interrupt */
STM32_EXTI_PR = EXTI_COMP_MASK(port);
/* enable comparator external interrupt */
STM32_EXTI_IMR |= EXTI_COMP_MASK(port);
}
void pd_rx_disable_monitoring(int port)
{
/* disable comparator external interrupt */
STM32_EXTI_IMR &= ~EXTI_COMP_MASK(port);
/* clear comparator external interrupt */
STM32_EXTI_PR = EXTI_COMP_MASK(port);
}
uint64_t get_time_since_last_edge(int port)
{
int prev_idx = (rx_edge_ts_idx[port] == 0) ?
PD_RX_TRANSITION_COUNT - 1 :
rx_edge_ts_idx[port] - 1;
return get_time().val - rx_edge_ts[port][prev_idx].val;
}
/* detect an edge on the PD RX pin */
void pd_rx_handler(void)
{
int pending, i;
int next_idx;
pending = STM32_EXTI_PR;
for (i = 0; i < CONFIG_USB_PD_PORT_COUNT; i++) {
if (pending & EXTI_COMP_MASK(i)) {
rx_edge_ts[i][rx_edge_ts_idx[i]].val = get_time().val;
next_idx = (rx_edge_ts_idx[i] ==
PD_RX_TRANSITION_COUNT - 1) ?
0 : rx_edge_ts_idx[i] + 1;
#if defined(CONFIG_LOW_POWER_IDLE) && \
defined(CONFIG_USB_PD_LOW_POWER_IDLE_WHEN_CONNECTED)
/*
* Do not deep sleep while waiting for more edges. For
* most boards, sleep is already disabled due to being
* in PD connected state, but boards which define
* CONFIG_USB_PD_LOW_POWER_IDLE_WHEN_CONNECTED can
* sleep while connected.
*/
disable_sleep(SLEEP_MASK_USB_PD);
#endif
/*
* If we have seen enough edges in a certain amount of
* time, then trigger RX start.
*/
if ((rx_edge_ts[i][rx_edge_ts_idx[i]].val -
rx_edge_ts[i][next_idx].val)
< PD_RX_TRANSITION_WINDOW) {
/* start sampling */
pd_rx_start(i);
/*
* ignore the comparator IRQ until we are done
* with current message
*/
pd_rx_disable_monitoring(i);
/* trigger the analysis in the task */
pd_rx_event(i);
} else {
/* do not trigger RX start, just clear int */
STM32_EXTI_PR = EXTI_COMP_MASK(i);
}
rx_edge_ts_idx[i] = next_idx;
}
}
}
#ifdef CONFIG_USB_PD_RX_COMP_IRQ
DECLARE_IRQ(STM32_IRQ_COMP, pd_rx_handler, 1);
#endif
/* --- release hardware --- */
void pd_hw_release(int port)
{
__hw_timer_enable_clock(TIM_CLOCK_PD_RX(port), 0);
__hw_timer_enable_clock(TIM_CLOCK_PD_TX(port), 0);
dma_disable(DMAC_SPI_TX(port));
}
/* --- Startup initialization --- */
void pd_hw_init_rx(int port)
{
struct pd_physical *phy = &pd_phy[port];
/* configure registers used for timers */
phy->tim_rx = (void *)TIM_REG_RX(port);
/* configure RX DMA */
phy->dma_tim_option.channel = DMAC_TIM_RX(port);
phy->dma_tim_option.periph = (void *)(TIM_RX_CCR_REG(port));
phy->dma_tim_option.flags = STM32_DMA_CCR_MSIZE_8_BIT |
STM32_DMA_CCR_PSIZE_16_BIT;
/* --- set counter for RX timing : 2.4Mhz rate, free-running --- */
__hw_timer_enable_clock(TIM_CLOCK_PD_RX(port), 1);
/* Timer configuration */
phy->tim_rx->cr1 = 0x0000;
phy->tim_rx->cr2 = 0x0000;
phy->tim_rx->dier = 0x0000;
/* Auto-reload value : 16-bit free running counter */
phy->tim_rx->arr = 0xFFFF;
/* Timeout for message receive */
phy->tim_rx->ccr[2] = (2400000 / 1000) * USB_PD_RX_TMOUT_US / 1000;
/* Timer ICx input configuration */
if (TIM_RX_CCR_IDX(port) == 1)
phy->tim_rx->ccmr1 |= TIM_CCR_CS << 0;
else if (TIM_RX_CCR_IDX(port) == 2)
phy->tim_rx->ccmr1 |= TIM_CCR_CS << 8;
else if (TIM_RX_CCR_IDX(port) == 4)
phy->tim_rx->ccmr2 |= TIM_CCR_CS << 8;
else
/* Unsupported RX timer capture input */
ASSERT(0);
phy->tim_rx->ccer = 0xB << ((TIM_RX_CCR_IDX(port) - 1) * 4);
/* configure DMA request on CCRx update */
phy->tim_rx->dier |= 1 << (8 + TIM_RX_CCR_IDX(port)); /* CCxDE */;
/* set prescaler to /26 (F=1.2Mhz, T=0.8us) */
phy->tim_rx->psc = (clock_get_freq() / 2400000) - 1;
/* Reload the pre-scaler and reset the counter (clear CCRx) */
phy->tim_rx->egr = 0x0001 | (1 << TIM_RX_CCR_IDX(port));
/* clear update event from reloading */
phy->tim_rx->sr = 0;
/* --- DAC configuration for comparator at 850mV --- */
#ifdef CONFIG_PD_USE_DAC_AS_REF
/* Enable DAC interface clock. */
STM32_RCC_APB1ENR |= (1 << 29);
/* Delay 1 APB clock cycle after the clock is enabled */
clock_wait_bus_cycles(BUS_APB, 1);
/* set voltage Vout=0.850V (Vref = 3.0V) */
STM32_DAC_DHR12RD = 850 * 4096 / 3000;
/* Start DAC channel 1 */
STM32_DAC_CR = STM32_DAC_CR_EN1;
#endif
/* --- COMP2 as comparator for RX vs Vmid = 850mV --- */
#ifdef CONFIG_USB_PD_INTERNAL_COMP
#if defined(CHIP_FAMILY_STM32F0) || defined(CHIP_FAMILY_STM32F3)
/* turn on COMP/SYSCFG */
STM32_RCC_APB2ENR |= 1 << 0;
/* Delay 1 APB clock cycle after the clock is enabled */
clock_wait_bus_cycles(BUS_APB, 1);
/* currently in hi-speed mode : TODO revisit later, INM = PA0(INM6) */
STM32_COMP_CSR = STM32_COMP_CMP1MODE_LSPEED |
STM32_COMP_CMP1INSEL_INM6 |
CMP1OUTSEL |
STM32_COMP_CMP1HYST_HI |
STM32_COMP_CMP2MODE_LSPEED |
STM32_COMP_CMP2INSEL_INM6 |
CMP2OUTSEL |
STM32_COMP_CMP2HYST_HI;
#elif defined(CHIP_FAMILY_STM32L)
STM32_RCC_APB1ENR |= 1 << 31; /* turn on COMP */
STM32_COMP_CSR = STM32_COMP_OUTSEL_TIM2_IC4 | STM32_COMP_INSEL_DAC_OUT1
| STM32_COMP_SPEED_FAST;
/* route PB4 to COMP input2 through GR6_1 bit 4 (or PB5->GR6_2 bit 5) */
STM32_RI_ASCR2 |= 1 << 4;
#else
#error Unsupported chip family
#endif
#endif /* CONFIG_USB_PD_INTERNAL_COMP */
/* comparator interrupt setup */
EXTI_XTSR |= EXTI_COMP_MASK(port);
STM32_EXTI_IMR |= EXTI_COMP_MASK(port);
task_enable_irq(IRQ_COMP);
}
void pd_hw_init(int port, int role)
{
struct pd_physical *phy = &pd_phy[port];
uint32_t val;
/* Initialize all PD pins to default state based on desired role */
pd_config_init(port, role);
/* set 40 MHz pin speed on communication pins */
pd_set_pins_speed(port);
/* --- SPI init --- */
/* Enable clocks to SPI module */
spi_enable_clock(port);
/* Initialize SPI peripheral registers */
pd_tx_spi_init(port);
/* configure TX DMA */
phy->dma_tx_option.channel = DMAC_SPI_TX(port);
phy->dma_tx_option.periph = (void *)&SPI_REGS(port)->dr;
phy->dma_tx_option.flags = STM32_DMA_CCR_MSIZE_8_BIT |
STM32_DMA_CCR_PSIZE_8_BIT;
dma_prepare_tx(&(phy->dma_tx_option), PD_MAX_RAW_SIZE,
phy->raw_samples);
/* configure registers used for timers */
phy->tim_tx = (void *)TIM_REG_TX(port);
/* --- set the TX timer with updates at 600KHz (BMC frequency) --- */
__hw_timer_enable_clock(TIM_CLOCK_PD_TX(port), 1);
/* Timer configuration */
phy->tim_tx->cr1 = 0x0000;
phy->tim_tx->cr2 = 0x0000;
phy->tim_tx->dier = 0x0000;
/* Auto-reload value : 600000 Khz overflow */
phy->tim_tx->arr = TX_CLOCK_DIV;
/* 50% duty cycle on the output */
phy->tim_tx->ccr[TIM_TX_CCR_IDX(port)] = phy->tim_tx->arr / 2;
/* Timer channel output configuration */
val = (6 << 4) | (1 << 3);
if ((TIM_TX_CCR_IDX(port) & 1) == 0) /* CH2 or CH4 */
val <<= 8;
if (TIM_TX_CCR_IDX(port) <= 2)
phy->tim_tx->ccmr1 = val;
else
phy->tim_tx->ccmr2 = val;
phy->tim_tx->ccer = 1 << ((TIM_TX_CCR_IDX(port) - 1) * 4);
phy->tim_tx->bdtr = 0x8000;
/* set prescaler to /1 */
phy->tim_tx->psc = 0;
/* Reload the pre-scaler and reset the counter */
phy->tim_tx->egr = 0x0001;
#ifndef CONFIG_USB_PD_TX_PHY_ONLY
/* Configure the reception side : comparators + edge timer + DMA */
pd_hw_init_rx(port);
#endif /* CONFIG_USB_PD_TX_PHY_ONLY */
CPRINTS("USB PD initialized");
}
void pd_set_clock(int port, int freq)
{
pd_phy[port].tim_tx->arr = clock_get_freq() / (2*freq);
}