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pigweed / third_party / github / zephyrproject-rtos / zephyr / 61d3eef9b7e85ddc9bae6a86eb3d0777cebc22bb / . / drivers / ieee802154 / ieee802154_cc2520.c
blob: 9e0a7c6fcf2baddb864a9f48c79fc6da4f55468d [file] [log] [blame]
/* ieee802154_cc2520.c - TI CC2520 driver */
/*
* Copyright (c) 2016 Intel Corporation.
*
* SPDX-License-Identifier: Apache-2.0
*/
#define SYS_LOG_LEVEL CONFIG_SYS_LOG_IEEE802154_DRIVER_LEVEL
#define SYS_LOG_DOMAIN "dev/cc2520"
#include <logging/sys_log.h>
#include <errno.h>
#include <kernel.h>
#include <arch/cpu.h>
#include <board.h>
#include <device.h>
#include <init.h>
#include <net/net_if.h>
#include <net/net_pkt.h>
#include <misc/byteorder.h>
#include <string.h>
#include <rand32.h>
#include <gpio.h>
#ifdef CONFIG_IEEE802154_CC2520_CRYPTO
#include <crypto/cipher.h>
#include <crypto/cipher_structs.h>
#endif /* CONFIG_IEEE802154_CC2520_CRYPTO */
#include <net/ieee802154_radio.h>
#include "ieee802154_cc2520.h"
/**
* Content is split as follows:
* 1 - Debug related functions
* 2 - Generic helper functions (for any parts)
* 3 - GPIO related functions
* 4 - TX related helper functions
* 5 - RX related helper functions
* 6 - Radio device API functions
* 7 - Legacy radio device API functions
* 8 - Initialization
*/
#define CC2520_AUTOMATISM (FRMCTRL0_AUTOCRC | FRMCTRL0_AUTOACK)
#define CC2520_TX_THRESHOLD (0x7F)
#define CC2520_FCS_LENGTH (2)
/*********
* DEBUG *
********/
#if CONFIG_SYS_LOG_IEEE802154_DRIVER_LEVEL == 4
static inline void _cc2520_print_gpio_config(struct device *dev)
{
struct cc2520_context *cc2520 = dev->driver_data;
SYS_LOG_DBG("GPIOCTRL0/1/2/3/4/5 = 0x%x/0x%x/0x%x/0x%x/0x%x/0x%x",
read_reg_gpioctrl0(&cc2520->spi),
read_reg_gpioctrl1(&cc2520->spi),
read_reg_gpioctrl2(&cc2520->spi),
read_reg_gpioctrl3(&cc2520->spi),
read_reg_gpioctrl4(&cc2520->spi),
read_reg_gpioctrl5(&cc2520->spi));
SYS_LOG_DBG("GPIOPOLARITY: 0x%x",
read_reg_gpiopolarity(&cc2520->spi));
SYS_LOG_DBG("GPIOCTRL: 0x%x",
read_reg_gpioctrl(&cc2520->spi));
}
static inline void _cc2520_print_exceptions(struct cc2520_context *cc2520)
{
u8_t flag = read_reg_excflag0(&cc2520->spi);
SYS_LOG_DBG("EXCFLAG0:");
if (flag & EXCFLAG0_RF_IDLE) {
SYS_LOG_BACKEND_FN("RF_IDLE ");
}
if (flag & EXCFLAG0_TX_FRM_DONE) {
SYS_LOG_BACKEND_FN("TX_FRM_DONE ");
}
if (flag & EXCFLAG0_TX_ACK_DONE) {
SYS_LOG_BACKEND_FN("TX_ACK_DONE ");
}
if (flag & EXCFLAG0_TX_UNDERFLOW) {
SYS_LOG_BACKEND_FN("TX_UNDERFLOW ");
}
if (flag & EXCFLAG0_TX_OVERFLOW) {
SYS_LOG_BACKEND_FN("TX_OVERFLOW ");
}
if (flag & EXCFLAG0_RX_UNDERFLOW) {
SYS_LOG_BACKEND_FN("RX_UNDERFLOW ");
}
if (flag & EXCFLAG0_RX_OVERFLOW) {
SYS_LOG_BACKEND_FN("RX_OVERFLOW ");
}
if (flag & EXCFLAG0_RXENABLE_ZERO) {
SYS_LOG_BACKEND_FN("RXENABLE_ZERO");
}
SYS_LOG_BACKEND_FN("\n");
flag = read_reg_excflag1(&cc2520->spi);
SYS_LOG_DBG("EXCFLAG1:");
if (flag & EXCFLAG1_RX_FRM_DONE) {
SYS_LOG_BACKEND_FN("RX_FRM_DONE ");
}
if (flag & EXCFLAG1_RX_FRM_ACCEPTED) {
SYS_LOG_BACKEND_FN("RX_FRM_ACCEPTED ");
}
if (flag & EXCFLAG1_SRC_MATCH_DONE) {
SYS_LOG_BACKEND_FN("SRC_MATCH_DONE ");
}
if (flag & EXCFLAG1_SRC_MATCH_FOUND) {
SYS_LOG_BACKEND_FN("SRC_MATCH_FOUND ");
}
if (flag & EXCFLAG1_FIFOP) {
SYS_LOG_BACKEND_FN("FIFOP ");
}
if (flag & EXCFLAG1_SFD) {
SYS_LOG_BACKEND_FN("SFD ");
}
if (flag & EXCFLAG1_DPU_DONE_L) {
SYS_LOG_BACKEND_FN("DPU_DONE_L ");
}
if (flag & EXCFLAG1_DPU_DONE_H) {
SYS_LOG_BACKEND_FN("DPU_DONE_H");
}
SYS_LOG_BACKEND_FN("\n");
}
static inline void _cc2520_print_errors(struct cc2520_context *cc2520)
{
u8_t flag = read_reg_excflag2(&cc2520->spi);
SYS_LOG_DBG("EXCFLAG2:");
if (flag & EXCFLAG2_MEMADDR_ERROR) {
SYS_LOG_BACKEND_FN("MEMADDR_ERROR ");
}
if (flag & EXCFLAG2_USAGE_ERROR) {
SYS_LOG_BACKEND_FN("USAGE_ERROR ");
}
if (flag & EXCFLAG2_OPERAND_ERROR) {
SYS_LOG_BACKEND_FN("OPERAND_ERROR ");
}
if (flag & EXCFLAG2_SPI_ERROR) {
SYS_LOG_BACKEND_FN("SPI_ERROR ");
}
if (flag & EXCFLAG2_RF_NO_LOCK) {
SYS_LOG_BACKEND_FN("RF_NO_LOCK ");
}
if (flag & EXCFLAG2_RX_FRM_ABORTED) {
SYS_LOG_BACKEND_FN("RX_FRM_ABORTED ");
}
if (flag & EXCFLAG2_RFBUFMOV_TIMEOUT) {
SYS_LOG_BACKEND_FN("RFBUFMOV_TIMEOUT");
}
SYS_LOG_BACKEND_FN("\n");
}
#else
#define _cc2520_print_gpio_config(...)
#define _cc2520_print_exceptions(...)
#define _cc2520_print_errors(...)
#endif /* CONFIG_SYS_LOG_IEEE802154_DRIVER_LEVEL == 4 */
/*********************
* Generic functions *
********************/
#define _usleep(usec) k_busy_wait(usec)
u8_t _cc2520_read_reg(struct cc2520_spi *spi,
bool freg, u8_t addr)
{
u8_t len = freg ? 2 : 3;
spi->cmd_buf[0] = freg ? CC2520_INS_REGRD | addr : CC2520_INS_MEMRD;
spi->cmd_buf[1] = freg ? 0 : addr;
spi->cmd_buf[2] = 0;
spi_slave_select(spi->dev, spi->slave);
if (spi_transceive(spi->dev, spi->cmd_buf, len,
spi->cmd_buf, len) == 0) {
return spi->cmd_buf[len - 1];
}
return 0;
}
bool _cc2520_write_reg(struct cc2520_spi *spi, bool freg,
u8_t addr, u8_t value)
{
u8_t len = freg ? 2 : 3;
spi->cmd_buf[0] = freg ? CC2520_INS_REGWR | addr : CC2520_INS_MEMWR;
spi->cmd_buf[1] = freg ? value : addr;
spi->cmd_buf[2] = freg ? 0 : value;
spi_slave_select(spi->dev, spi->slave);
return (spi_write(spi->dev, spi->cmd_buf, len) == 0);
}
bool _cc2520_write_ram(struct cc2520_spi *spi, u16_t addr,
u8_t *data_buf, u8_t len)
{
#ifndef CONFIG_IEEE802154_CC2520_CRYPTO
u8_t *cmd_data = spi->cmd_buf;
#else
u8_t cmd_data[128];
#endif
cmd_data[0] = CC2520_INS_MEMWR | (addr >> 8);
cmd_data[1] = addr;
memcpy(&cmd_data[2], data_buf, len);
spi_slave_select(spi->dev, spi->slave);
return (spi_write(spi->dev, cmd_data, len + 2) == 0);
}
static u8_t _cc2520_status(struct cc2520_spi *spi)
{
spi->cmd_buf[0] = CC2520_INS_SNOP;
spi_slave_select(spi->dev, spi->slave);
if (spi_transceive(spi->dev, spi->cmd_buf, 1,
spi->cmd_buf, 1) == 0) {
return spi->cmd_buf[0];
}
return 0;
}
static bool verify_osc_stabilization(struct cc2520_context *cc2520)
{
u8_t timeout = 100;
u8_t status;
do {
status = _cc2520_status(&cc2520->spi);
_usleep(1);
timeout--;
} while (!(status & CC2520_STATUS_XOSC_STABLE_N_RUNNING) && timeout);
return !!(status & CC2520_STATUS_XOSC_STABLE_N_RUNNING);
}
static inline u8_t *get_mac(struct device *dev)
{
struct cc2520_context *cc2520 = dev->driver_data;
#if defined(CONFIG_IEEE802154_CC2520_RANDOM_MAC)
u32_t *ptr = (u32_t *)(cc2520->mac_addr + 4);
UNALIGNED_PUT(sys_rand32_get(), ptr);
cc2520->mac_addr[7] = (cc2520->mac_addr[7] & ~0x01) | 0x02;
#else
cc2520->mac_addr[4] = CONFIG_IEEE802154_CC2520_MAC4;
cc2520->mac_addr[5] = CONFIG_IEEE802154_CC2520_MAC5;
cc2520->mac_addr[6] = CONFIG_IEEE802154_CC2520_MAC6;
cc2520->mac_addr[7] = CONFIG_IEEE802154_CC2520_MAC7;
#endif
cc2520->mac_addr[0] = 0x00;
cc2520->mac_addr[1] = 0x12;
cc2520->mac_addr[2] = 0x4b;
cc2520->mac_addr[3] = 0x00;
return cc2520->mac_addr;
}
/******************
* GPIO functions *
*****************/
static inline void set_reset(struct device *dev, u32_t value)
{
struct cc2520_context *cc2520 = dev->driver_data;
gpio_pin_write(cc2520->gpios[CC2520_GPIO_IDX_RESET].dev,
cc2520->gpios[CC2520_GPIO_IDX_RESET].pin, value);
}
static inline void set_vreg_en(struct device *dev, u32_t value)
{
struct cc2520_context *cc2520 = dev->driver_data;
gpio_pin_write(cc2520->gpios[CC2520_GPIO_IDX_VREG_EN].dev,
cc2520->gpios[CC2520_GPIO_IDX_VREG_EN].pin, value);
}
static inline u32_t get_fifo(struct cc2520_context *cc2520)
{
u32_t pin_value;
gpio_pin_read(cc2520->gpios[CC2520_GPIO_IDX_FIFO].dev,
cc2520->gpios[CC2520_GPIO_IDX_FIFO].pin, &pin_value);
return pin_value;
}
static inline u32_t get_fifop(struct cc2520_context *cc2520)
{
u32_t pin_value;
gpio_pin_read(cc2520->gpios[CC2520_GPIO_IDX_FIFOP].dev,
cc2520->gpios[CC2520_GPIO_IDX_FIFOP].pin, &pin_value);
return pin_value;
}
static inline u32_t get_cca(struct cc2520_context *cc2520)
{
u32_t pin_value;
gpio_pin_read(cc2520->gpios[CC2520_GPIO_IDX_CCA].dev,
cc2520->gpios[CC2520_GPIO_IDX_CCA].pin, &pin_value);
return pin_value;
}
static inline void sfd_int_handler(struct device *port,
struct gpio_callback *cb, u32_t pins)
{
struct cc2520_context *cc2520 =
CONTAINER_OF(cb, struct cc2520_context, sfd_cb);
if (atomic_get(&cc2520->tx) == 1) {
atomic_set(&cc2520->tx, 0);
k_sem_give(&cc2520->tx_sync);
}
}
static inline void fifop_int_handler(struct device *port,
struct gpio_callback *cb, u32_t pins)
{
struct cc2520_context *cc2520 =
CONTAINER_OF(cb, struct cc2520_context, fifop_cb);
/* Note: Errata document - 1.2 */
if (!get_fifop(cc2520) && !get_fifop(cc2520)) {
return;
}
if (!get_fifo(cc2520)) {
cc2520->overflow = true;
}
k_sem_give(&cc2520->rx_lock);
}
static void enable_fifop_interrupt(struct cc2520_context *cc2520,
bool enable)
{
if (enable) {
gpio_pin_enable_callback(
cc2520->gpios[CC2520_GPIO_IDX_FIFOP].dev,
cc2520->gpios[CC2520_GPIO_IDX_FIFOP].pin);
} else {
gpio_pin_disable_callback(
cc2520->gpios[CC2520_GPIO_IDX_FIFOP].dev,
cc2520->gpios[CC2520_GPIO_IDX_FIFOP].pin);
}
}
static void enable_sfd_interrupt(struct cc2520_context *cc2520,
bool enable)
{
if (enable) {
gpio_pin_enable_callback(
cc2520->gpios[CC2520_GPIO_IDX_SFD].dev,
cc2520->gpios[CC2520_GPIO_IDX_SFD].pin);
} else {
gpio_pin_disable_callback(
cc2520->gpios[CC2520_GPIO_IDX_SFD].dev,
cc2520->gpios[CC2520_GPIO_IDX_SFD].pin);
}
}
static inline void setup_gpio_callbacks(struct device *dev)
{
struct cc2520_context *cc2520 = dev->driver_data;
gpio_init_callback(&cc2520->sfd_cb, sfd_int_handler,
BIT(cc2520->gpios[CC2520_GPIO_IDX_SFD].pin));
gpio_add_callback(cc2520->gpios[CC2520_GPIO_IDX_SFD].dev,
&cc2520->sfd_cb);
gpio_init_callback(&cc2520->fifop_cb, fifop_int_handler,
BIT(cc2520->gpios[CC2520_GPIO_IDX_FIFOP].pin));
gpio_add_callback(cc2520->gpios[CC2520_GPIO_IDX_FIFOP].dev,
&cc2520->fifop_cb);
}
/****************
* TX functions *
***************/
static inline bool write_txfifo_length(struct cc2520_spi *spi,
u8_t len)
{
spi->cmd_buf[0] = CC2520_INS_TXBUF;
spi->cmd_buf[1] = len + CC2520_FCS_LENGTH;
spi_slave_select(spi->dev, spi->slave);
return (spi_write(spi->dev, spi->cmd_buf, 2) == 0);
}
static inline bool write_txfifo_content(struct cc2520_spi *spi,
u8_t *frame, u8_t len)
{
u8_t cmd[128];
cmd[0] = CC2520_INS_TXBUF;
memcpy(&cmd[1], frame, len);
spi_slave_select(spi->dev, spi->slave);
return (spi_write(spi->dev, cmd, len + 1) == 0);
}
static inline bool verify_txfifo_status(struct cc2520_context *cc2520,
u8_t len)
{
if (read_reg_txfifocnt(&cc2520->spi) < len ||
(read_reg_excflag0(&cc2520->spi) & EXCFLAG0_TX_UNDERFLOW)) {
return false;
}
return true;
}
static inline bool verify_tx_done(struct cc2520_context *cc2520)
{
u8_t timeout = 10;
u8_t status;
do {
_usleep(1);
timeout--;
status = read_reg_excflag0(&cc2520->spi);
} while (!(status & EXCFLAG0_TX_FRM_DONE) && timeout);
return !!(status & EXCFLAG0_TX_FRM_DONE);
}
/****************
* RX functions *
***************/
static inline void flush_rxfifo(struct cc2520_context *cc2520)
{
/* Note: Errata document - 1.1 */
enable_fifop_interrupt(cc2520, false);
instruct_sflushrx(&cc2520->spi);
instruct_sflushrx(&cc2520->spi);
enable_fifop_interrupt(cc2520, true);
write_reg_excflag0(&cc2520->spi, EXCFLAG0_RESET_RX_FLAGS);
}
static inline u8_t read_rxfifo_length(struct cc2520_spi *spi)
{
spi->cmd_buf[0] = CC2520_INS_RXBUF;
spi->cmd_buf[1] = 0;
spi_slave_select(spi->dev, spi->slave);
if (spi_transceive(spi->dev, spi->cmd_buf, 2,
spi->cmd_buf, 2) == 0) {
return spi->cmd_buf[1];
}
return 0;
}
static inline bool read_rxfifo_content(struct cc2520_spi *spi,
struct net_buf *frag, u8_t len)
{
u8_t data[128+1];
data[0] = CC2520_INS_RXBUF;
memset(&data[1], 0, len);
spi_slave_select(spi->dev, spi->slave);
if (spi_transceive(spi->dev, data, len+1, data, len+1) != 0) {
return false;
}
if (read_reg_excflag0(spi) & EXCFLAG0_RX_UNDERFLOW) {
SYS_LOG_ERR("RX underflow!");
return false;
}
memcpy(frag->data, &data[1], len);
net_buf_add(frag, len);
return true;
}
static inline bool verify_crc(struct cc2520_context *cc2520,
struct net_pkt *pkt)
{
cc2520->spi.cmd_buf[0] = CC2520_INS_RXBUF;
cc2520->spi.cmd_buf[1] = 0;
cc2520->spi.cmd_buf[2] = 0;
spi_slave_select(cc2520->spi.dev, cc2520->spi.slave);
if (spi_transceive(cc2520->spi.dev, cc2520->spi.cmd_buf, 3,
cc2520->spi.cmd_buf, 3) != 0) {
return false;
}
if (!(cc2520->spi.cmd_buf[2] & CC2520_FCS_CRC_OK)) {
return false;
}
net_pkt_set_ieee802154_rssi(pkt, cc2520->spi.cmd_buf[1]);
/**
* CC2520 does not provide an LQI but a correlation factor.
* See Section 20.6
* Such calculation can be loosely used to transform it to lqi:
* corr <= 50 ? lqi = 0
* or:
* corr >= 110 ? lqi = 255
* else:
* lqi = (lqi - 50) * 4
*/
cc2520->lqi = cc2520->spi.cmd_buf[2] & CC2520_FCS_CORRELATION;
if (cc2520->lqi <= 50) {
cc2520->lqi = 0;
} else if (cc2520->lqi >= 110) {
cc2520->lqi = 255;
} else {
cc2520->lqi = (cc2520->lqi - 50) << 2;
}
return true;
}
static inline bool verify_rxfifo_validity(struct cc2520_spi *spi,
u8_t pkt_len)
{
if (pkt_len < 2 || read_reg_rxfifocnt(spi) != pkt_len) {
return false;
}
return true;
}
static void cc2520_rx(int arg)
{
struct device *dev = INT_TO_POINTER(arg);
struct cc2520_context *cc2520 = dev->driver_data;
struct net_buf *pkt_frag = NULL;
struct net_pkt *pkt;
u8_t pkt_len;
while (1) {
pkt = NULL;
k_sem_take(&cc2520->rx_lock, K_FOREVER);
if (cc2520->overflow) {
SYS_LOG_ERR("RX overflow!");
cc2520->overflow = false;
goto flush;
}
pkt_len = read_rxfifo_length(&cc2520->spi) & 0x7f;
if (!verify_rxfifo_validity(&cc2520->spi, pkt_len)) {
SYS_LOG_ERR("Invalid content");
goto flush;
}
pkt = net_pkt_get_reserve_rx(0, K_NO_WAIT);
if (!pkt) {
SYS_LOG_ERR("No pkt available");
goto flush;
}
#if defined(CONFIG_IEEE802154_CC2520_RAW)
/**
* Reserve 1 byte for length
*/
net_pkt_set_ll_reserve(pkt, 1);
#endif
pkt_frag = net_pkt_get_frag(pkt, K_NO_WAIT);
if (!pkt_frag) {
SYS_LOG_ERR("No pkt_frag available");
goto flush;
}
net_pkt_frag_insert(pkt, pkt_frag);
#if defined(CONFIG_IEEE802154_CC2520_RAW)
if (!read_rxfifo_content(&cc2520->spi, pkt_frag, pkt_len)) {
SYS_LOG_ERR("No content read");
goto flush;
}
if (!(pkt_frag->data[pkt_len - 1] & CC2520_FCS_CRC_OK)) {
goto out;
}
cc2520->lqi = pkt_frag->data[pkt_len - 1] &
CC2520_FCS_CORRELATION;
if (cc2520->lqi <= 50) {
cc2520->lqi = 0;
} else if (cc2520->lqi >= 110) {
cc2520->lqi = 255;
} else {
cc2520->lqi = (cc2520->lqi - 50) << 2;
}
#else
if (!read_rxfifo_content(&cc2520->spi, pkt_frag, pkt_len - 2)) {
SYS_LOG_ERR("No content read");
goto flush;
}
if (!verify_crc(cc2520, pkt)) {
SYS_LOG_ERR("Bad packet CRC");
goto out;
}
#endif
if (ieee802154_radio_handle_ack(cc2520->iface, pkt) == NET_OK) {
SYS_LOG_DBG("ACK packet handled");
goto out;
}
#if defined(CONFIG_IEEE802154_CC2520_RAW)
net_buf_add_u8(pkt_frag, cc2520->lqi);
#endif
SYS_LOG_DBG("Caught a packet (%u) (LQI: %u)",
pkt_len, cc2520->lqi);
if (net_recv_data(cc2520->iface, pkt) < 0) {
SYS_LOG_DBG("Packet dropped by NET stack");
goto out;
}
net_analyze_stack("CC2520 Rx Fiber stack",
(unsigned char *)cc2520->cc2520_rx_stack,
CONFIG_IEEE802154_CC2520_RX_STACK_SIZE);
continue;
flush:
_cc2520_print_exceptions(cc2520);
_cc2520_print_errors(cc2520);
flush_rxfifo(cc2520);
out:
if (pkt) {
net_pkt_unref(pkt);
}
}
}
/********************
* Radio device API *
*******************/
static int cc2520_cca(struct device *dev)
{
struct cc2520_context *cc2520 = dev->driver_data;
if (!get_cca(cc2520)) {
SYS_LOG_DBG("Busy");
return -EBUSY;
}
return 0;
}
static int cc2520_set_channel(struct device *dev, u16_t channel)
{
struct cc2520_context *cc2520 = dev->driver_data;
SYS_LOG_DBG("%u", channel);
if (channel < 11 || channel > 26) {
return -EINVAL;
}
/* See chapter 16 */
channel = 11 + 5 * (channel - 11);
if (!write_reg_freqctrl(&cc2520->spi, FREQCTRL_FREQ(channel))) {
SYS_LOG_ERR("Failed");
return -EIO;
}
return 0;
}
static int cc2520_set_pan_id(struct device *dev, u16_t pan_id)
{
struct cc2520_context *cc2520 = dev->driver_data;
SYS_LOG_DBG("0x%x", pan_id);
pan_id = sys_le16_to_cpu(pan_id);
if (!write_mem_pan_id(&cc2520->spi, (u8_t *) &pan_id)) {
SYS_LOG_ERR("Failed");
return -EIO;
}
return 0;
}
static int cc2520_set_short_addr(struct device *dev, u16_t short_addr)
{
struct cc2520_context *cc2520 = dev->driver_data;
SYS_LOG_DBG("0x%x", short_addr);
short_addr = sys_le16_to_cpu(short_addr);
if (!write_mem_short_addr(&cc2520->spi, (u8_t *) &short_addr)) {
SYS_LOG_ERR("Failed");
return -EIO;
}
return 0;
}
static int cc2520_set_ieee_addr(struct device *dev, const u8_t *ieee_addr)
{
struct cc2520_context *cc2520 = dev->driver_data;
if (!write_mem_ext_addr(&cc2520->spi, (void *)ieee_addr)) {
SYS_LOG_ERR("Failed");
return -EIO;
}
SYS_LOG_DBG("IEEE address %02x:%02x:%02x:%02x:%02x:%02x:%02x:%02x",
ieee_addr[7], ieee_addr[6], ieee_addr[5], ieee_addr[4],
ieee_addr[3], ieee_addr[2], ieee_addr[1], ieee_addr[0]);
return 0;
}
static int cc2520_set_txpower(struct device *dev, s16_t dbm)
{
struct cc2520_context *cc2520 = dev->driver_data;
u8_t pwr;
SYS_LOG_DBG("%d", dbm);
/* See chapter 19 part 8 */
switch (dbm) {
case 5:
pwr = 0xF7;
break;
case 3:
pwr = 0xF2;
break;
case 2:
pwr = 0xAB;
break;
case 1:
pwr = 0x13;
break;
case 0:
pwr = 0x32;
break;
case -2:
pwr = 0x81;
break;
case -4:
pwr = 0x88;
break;
case -7:
pwr = 0x2C;
break;
case -18:
pwr = 0x03;
break;
default:
goto error;
}
if (!write_reg_txpower(&cc2520->spi, pwr)) {
goto error;
}
return 0;
error:
SYS_LOG_DBG("Failed");
return -EIO;
}
static int cc2520_tx(struct device *dev,
struct net_pkt *pkt,
struct net_buf *frag)
{
u8_t *frame = frag->data - net_pkt_ll_reserve(pkt);
u8_t len = net_pkt_ll_reserve(pkt) + frag->len;
struct cc2520_context *cc2520 = dev->driver_data;
u8_t retry = 2;
bool status;
SYS_LOG_DBG("%p (%u)", frag, len);
if (!write_reg_excflag0(&cc2520->spi, EXCFLAG0_RESET_TX_FLAGS) ||
!write_txfifo_length(&cc2520->spi, len) ||
!write_txfifo_content(&cc2520->spi, frame, len)) {
SYS_LOG_ERR("Cannot feed in TX fifo");
goto error;
}
if (!verify_txfifo_status(cc2520, len)) {
SYS_LOG_ERR("Did not write properly into TX FIFO");
goto error;
}
#ifdef CONFIG_IEEE802154_CC2520_CRYPTO
k_sem_take(&cc2520->access_lock, K_FOREVER);
#endif
/* 1 retry is allowed here */
do {
atomic_set(&cc2520->tx, 1);
k_sem_init(&cc2520->tx_sync, 0, UINT_MAX);
if (!instruct_stxoncca(&cc2520->spi)) {
SYS_LOG_ERR("Cannot start transmission");
goto error;
}
k_sem_take(&cc2520->tx_sync, 10);
retry--;
status = verify_tx_done(cc2520);
} while (!status && retry);
#ifdef CONFIG_IEEE802154_CC2520_CRYPTO
k_sem_give(&cc2520->access_lock);
#endif
if (status) {
return 0;
}
error:
#ifdef CONFIG_IEEE802154_CC2520_CRYPTO
k_sem_give(&cc2520->access_lock);
#endif
SYS_LOG_ERR("No TX_FRM_DONE");
_cc2520_print_exceptions(cc2520);
_cc2520_print_errors(cc2520);
atomic_set(&cc2520->tx, 0);
instruct_sflushtx(&cc2520->spi);
return -EIO;
}
static int cc2520_start(struct device *dev)
{
struct cc2520_context *cc2520 = dev->driver_data;
SYS_LOG_DBG("");
if (!instruct_sxoscon(&cc2520->spi) ||
!instruct_srxon(&cc2520->spi) ||
!verify_osc_stabilization(cc2520)) {
SYS_LOG_ERR("Error starting CC2520");
return -EIO;
}
flush_rxfifo(cc2520);
enable_fifop_interrupt(cc2520, true);
enable_sfd_interrupt(cc2520, true);
return 0;
}
static int cc2520_stop(struct device *dev)
{
struct cc2520_context *cc2520 = dev->driver_data;
SYS_LOG_DBG("");
flush_rxfifo(cc2520);
enable_fifop_interrupt(cc2520, false);
enable_sfd_interrupt(cc2520, false);
if (!instruct_srfoff(&cc2520->spi) ||
!instruct_sxoscoff(&cc2520->spi)) {
SYS_LOG_ERR("Error stopping CC2520");
return -EIO;
}
return 0;
}
static u8_t cc2520_get_lqi(struct device *dev)
{
struct cc2520_context *cc2520 = dev->driver_data;
return cc2520->lqi;
}
/******************
* Initialization *
*****************/
static int power_on_and_setup(struct device *dev)
{
struct cc2520_context *cc2520 = dev->driver_data;
/* Switching to LPM2 mode */
set_reset(dev, 0);
_usleep(150);
set_vreg_en(dev, 0);
_usleep(250);
/* Then to ACTIVE mode */
set_vreg_en(dev, 1);
_usleep(250);
set_reset(dev, 1);
_usleep(150);
if (!verify_osc_stabilization(cc2520)) {
return -EIO;
}
/* Default settings to always write (see chapter 28 part 1) */
if (!write_reg_txpower(&cc2520->spi, CC2520_TXPOWER_DEFAULT) ||
!write_reg_ccactrl0(&cc2520->spi, CC2520_CCACTRL0_DEFAULT) ||
!write_reg_mdmctrl0(&cc2520->spi, CC2520_MDMCTRL0_DEFAULT) ||
!write_reg_mdmctrl1(&cc2520->spi, CC2520_MDMCTRL1_DEFAULT) ||
!write_reg_rxctrl(&cc2520->spi, CC2520_RXCTRL_DEFAULT) ||
!write_reg_fsctrl(&cc2520->spi, CC2520_FSCTRL_DEFAULT) ||
!write_reg_fscal1(&cc2520->spi, CC2520_FSCAL1_DEFAULT) ||
!write_reg_agcctrl1(&cc2520->spi, CC2520_AGCCTRL1_DEFAULT) ||
!write_reg_adctest0(&cc2520->spi, CC2520_ADCTEST0_DEFAULT) ||
!write_reg_adctest1(&cc2520->spi, CC2520_ADCTEST1_DEFAULT) ||
!write_reg_adctest2(&cc2520->spi, CC2520_ADCTEST2_DEFAULT)) {
return -EIO;
}
/* EXTCLOCK0: Disabling external clock
* FRMCTRL0: AUTOACK and AUTOCRC enabled
* FRMCTRL1: SET_RXENMASK_ON_TX and IGNORE_TX_UNDERF
* FRMFILT0: Frame filtering (setting CC2520_FRAME_FILTERING)
* FIFOPCTRL: Set TX threshold (setting CC2520_TX_THRESHOLD)
*/
if (!write_reg_extclock(&cc2520->spi, 0) ||
!write_reg_frmctrl0(&cc2520->spi, CC2520_AUTOMATISM) ||
!write_reg_frmctrl1(&cc2520->spi, FRMCTRL1_IGNORE_TX_UNDERF |
FRMCTRL1_SET_RXENMASK_ON_TX) ||
!write_reg_frmfilt0(&cc2520->spi, FRMFILT0_FRAME_FILTER_EN |
FRMFILT0_MAX_FRAME_VERSION(3)) ||
!write_reg_frmfilt1(&cc2520->spi, FRMFILT1_ACCEPT_ALL) ||
!write_reg_srcmatch(&cc2520->spi, SRCMATCH_DEFAULTS) ||
!write_reg_fifopctrl(&cc2520->spi,
FIFOPCTRL_FIFOP_THR(CC2520_TX_THRESHOLD))) {
return -EIO;
}
/* Cleaning up TX fifo */
instruct_sflushtx(&cc2520->spi);
setup_gpio_callbacks(dev);
_cc2520_print_gpio_config(dev);
return 0;
}
static inline int configure_spi(struct device *dev)
{
struct cc2520_context *cc2520 = dev->driver_data;
struct spi_config spi_conf = {
.config = SPI_WORD(8),
.max_sys_freq = CONFIG_IEEE802154_CC2520_SPI_FREQ,
};
cc2520->spi.dev = device_get_binding(
CONFIG_IEEE802154_CC2520_SPI_DRV_NAME);
if (!cc2520->spi.dev) {
SYS_LOG_ERR("Unable to get SPI device");
return -ENODEV;
}
cc2520->spi.slave = CONFIG_IEEE802154_CC2520_SPI_SLAVE;
if (spi_configure(cc2520->spi.dev, &spi_conf) != 0 ||
spi_slave_select(cc2520->spi.dev,
cc2520->spi.slave) != 0) {
cc2520->spi.dev = NULL;
return -EIO;
}
return 0;
}
static int cc2520_init(struct device *dev)
{
struct cc2520_context *cc2520 = dev->driver_data;
atomic_set(&cc2520->tx, 0);
k_sem_init(&cc2520->rx_lock, 0, UINT_MAX);
#ifdef CONFIG_IEEE802154_CC2520_CRYPTO
k_sem_init(&cc2520->access_lock, 1, 1);
#endif
cc2520->gpios = cc2520_configure_gpios();
if (!cc2520->gpios) {
SYS_LOG_ERR("Configuring GPIOS failed");
return -EIO;
}
if (configure_spi(dev) != 0) {
SYS_LOG_ERR("Configuring SPI failed");
return -EIO;
}
SYS_LOG_DBG("GPIO and SPI configured");
if (power_on_and_setup(dev) != 0) {
SYS_LOG_ERR("Configuring CC2520 failed");
return -EIO;
}
k_thread_create(&cc2520->cc2520_rx_thread, cc2520->cc2520_rx_stack,
CONFIG_IEEE802154_CC2520_RX_STACK_SIZE,
(k_thread_entry_t)cc2520_rx,
dev, NULL, NULL, K_PRIO_COOP(2), 0, 0);
SYS_LOG_INF("CC2520 initialized");
return 0;
}
static void cc2520_iface_init(struct net_if *iface)
{
struct device *dev = net_if_get_device(iface);
struct cc2520_context *cc2520 = dev->driver_data;
u8_t *mac = get_mac(dev);
SYS_LOG_DBG("");
net_if_set_link_addr(iface, mac, 8, NET_LINK_IEEE802154);
cc2520->iface = iface;
ieee802154_init(iface);
}
static struct cc2520_context cc2520_context_data;
static struct ieee802154_radio_api cc2520_radio_api = {
.iface_api.init = cc2520_iface_init,
.iface_api.send = ieee802154_radio_send,
.cca = cc2520_cca,
.set_channel = cc2520_set_channel,
.set_pan_id = cc2520_set_pan_id,
.set_short_addr = cc2520_set_short_addr,
.set_ieee_addr = cc2520_set_ieee_addr,
.set_txpower = cc2520_set_txpower,
.start = cc2520_start,
.stop = cc2520_stop,
.tx = cc2520_tx,
.get_lqi = cc2520_get_lqi,
};
#if defined(CONFIG_IEEE802154_CC2520_RAW)
DEVICE_AND_API_INIT(cc2520, CONFIG_IEEE802154_CC2520_DRV_NAME,
cc2520_init, &cc2520_context_data, NULL,
POST_KERNEL, CONFIG_IEEE802154_CC2520_INIT_PRIO,
&cc2520_radio_api);
#else
NET_DEVICE_INIT(cc2520, CONFIG_IEEE802154_CC2520_DRV_NAME,
cc2520_init, &cc2520_context_data, NULL,
CONFIG_IEEE802154_CC2520_INIT_PRIO,
&cc2520_radio_api, IEEE802154_L2,
NET_L2_GET_CTX_TYPE(IEEE802154_L2), 125);
NET_STACK_INFO_ADDR(RX, cc2520,
CONFIG_IEEE802154_CC2520_RX_STACK_SIZE,
CONFIG_IEEE802154_CC2520_RX_STACK_SIZE,
((struct cc2520_context *)(&__device_cc2520))->
cc2520_rx_stack,
0);
#endif
#ifdef CONFIG_IEEE802154_CC2520_CRYPTO
static bool _cc2520_read_ram(struct cc2520_spi *spi, u16_t addr,
u8_t *data_buf, u8_t len)
{
u8_t cmd_buf[128];
cmd_buf[0] = CC2520_INS_MEMRD | (addr >> 8);
cmd_buf[1] = addr;
spi_slave_select(spi->dev, spi->slave);
if (spi_transceive(spi->dev, cmd_buf, len + 2,
cmd_buf, len + 2) != 0) {
return false;
}
memcpy(data_buf, &cmd_buf[2], len);
return true;
}
static inline bool instruct_ccm(struct cc2520_context *cc2520,
u8_t key_addr,
u8_t auth_crypt,
u8_t nonce_addr,
u16_t input_addr,
u16_t output_addr,
u8_t in_len,
u8_t m)
{
u8_t cmd[9];
int ret;
SYS_LOG_DBG("CCM(P={01} K={%02x} C={%02x} N={%02x}"
" A={%03x} E={%03x} F{%02x} M={%02x})",
key_addr, auth_crypt, nonce_addr,
input_addr, output_addr, in_len, m);
cmd[0] = CC2520_INS_CCM | 1;
cmd[1] = key_addr;
cmd[2] = (auth_crypt & 0x7f);
cmd[3] = nonce_addr;
cmd[4] = (u8_t)(((input_addr & 0x0f00) >> 4) |
((output_addr & 0x0f00) >> 8));
cmd[5] = (u8_t)(input_addr & 0x00ff);
cmd[6] = (u8_t)(output_addr & 0x00ff);
cmd[7] = (in_len & 0x7f);
cmd[8] = (m & 0x03);
k_sem_take(&cc2520->access_lock, K_FOREVER);
ret = spi_write(cc2520->spi.dev, cmd, 9);
k_sem_give(&cc2520->access_lock);
if (ret) {
SYS_LOG_ERR("CCM Failed");
return false;
}
return true;
}
static inline bool instruct_uccm(struct cc2520_context *cc2520,
u8_t key_addr,
u8_t auth_crypt,
u8_t nonce_addr,
u16_t input_addr,
u16_t output_addr,
u8_t in_len,
u8_t m)
{
u8_t cmd[9];
int ret;
SYS_LOG_DBG("UCCM(P={01} K={%02x} C={%02x} N={%02x}"
" A={%03x} E={%03x} F{%02x} M={%02x})",
key_addr, auth_crypt, nonce_addr,
input_addr, output_addr, in_len, m);
cmd[0] = CC2520_INS_UCCM | 1;
cmd[1] = key_addr;
cmd[2] = (auth_crypt & 0x7f);
cmd[3] = nonce_addr;
cmd[4] = (u8_t)(((input_addr & 0x0f00) >> 4) |
((output_addr & 0x0f00) >> 8));
cmd[5] = (u8_t)(input_addr & 0x00ff);
cmd[6] = (u8_t)(output_addr & 0x00ff);
cmd[7] = (in_len & 0x7f);
cmd[8] = (m & 0x03);
k_sem_take(&cc2520->access_lock, K_FOREVER);
ret = spi_write(cc2520->spi.dev, cmd, 9);
k_sem_give(&cc2520->access_lock);
if (ret) {
SYS_LOG_ERR("UCCM Failed");
return false;
}
return true;
}
static inline void generate_nonce(u8_t *ccm_nonce, u8_t *nonce,
struct cipher_aead_pkt *apkt, u8_t m)
{
nonce[0] = 0 | (apkt->ad_len ? 0x40 : 0) | (m << 3) | 1;
memcpy(&nonce[1], ccm_nonce, 13);
nonce[14] = (u8_t)(apkt->pkt->in_len >> 8);
nonce[15] = (u8_t)(apkt->pkt->in_len);
/* See section 26.8.1 */
sys_mem_swap(nonce, 16);
}
static int insert_crypto_parameters(struct cipher_ctx *ctx,
struct cipher_aead_pkt *apkt,
u8_t *ccm_nonce, u8_t *auth_crypt)
{
struct cc2520_context *cc2520 = ctx->device->driver_data;
u8_t data[128];
u8_t *in_buf;
u8_t in_len;
u8_t m = 0;
if (!apkt->pkt->out_buf || !apkt->pkt->out_buf_max) {
SYS_LOG_ERR("Out buffer needs to be set");
return -EINVAL;
}
if (!ctx->key.bit_stream || !ctx->keylen) {
SYS_LOG_ERR("No key installed");
return -EINVAL;
}
if (!(ctx->flags & CAP_INPLACE_OPS)) {
SYS_LOG_ERR("It supports only in-place operation");
return -EINVAL;
}
if (!apkt->ad || !apkt->ad_len) {
SYS_LOG_ERR("CCM needs associated data");
return -EINVAL;
}
if (apkt->pkt->in_buf && apkt->pkt->in_buf - apkt->ad_len != apkt->ad) {
SYS_LOG_ERR("In-place needs ad and input in same memory");
return -EINVAL;
}
if (!apkt->pkt->in_buf) {
if (!ctx->mode_params.ccm_info.tag_len) {
SYS_LOG_ERR("Auth only needs a tag length");
return -EINVAL;
}
in_buf = apkt->ad;
in_len = apkt->ad_len;
*auth_crypt = 0;
} else {
in_buf = data;
memcpy(in_buf, apkt->ad, apkt->ad_len);
memcpy(in_buf + apkt->ad_len,
apkt->pkt->in_buf, apkt->pkt->in_len);
in_len = apkt->ad_len + apkt->pkt->in_len;
*auth_crypt = !apkt->tag ? apkt->pkt->in_len :
apkt->pkt->in_len - ctx->mode_params.ccm_info.tag_len;
}
if (ctx->mode_params.ccm_info.tag_len) {
if ((ctx->mode_params.ccm_info.tag_len >> 2) > 3) {
m = 3;
} else {
m = ctx->mode_params.ccm_info.tag_len >> 2;
}
}
/* Writing the frame in RAM */
if (!_cc2520_write_ram(&cc2520->spi, CC2520_MEM_DATA, in_buf, in_len)) {
SYS_LOG_ERR("Cannot write the frame in RAM");
return -EIO;
}
/* See section 26.8.1 */
sys_memcpy_swap(data, ctx->key.bit_stream, ctx->keylen);
/* Writing the key in RAM */
if (!_cc2520_write_ram(&cc2520->spi, CC2520_MEM_KEY, data, 16)) {
SYS_LOG_ERR("Cannot write the key in RAM");
return -EIO;
}
generate_nonce(ccm_nonce, data, apkt, m);
/* Writing the nonce in RAM */
if (!_cc2520_write_ram(&cc2520->spi, CC2520_MEM_NONCE, data, 16)) {
SYS_LOG_ERR("Cannot write the nonce in RAM");
return -EIO;
}
return m;
}
static int _cc2520_crypto_ccm(struct cipher_ctx *ctx,
struct cipher_aead_pkt *apkt,
u8_t *ccm_nonce)
{
struct cc2520_context *cc2520 = ctx->device->driver_data;
u8_t auth_crypt;
int m;
if (!apkt || !apkt->pkt) {
SYS_LOG_ERR("Invalid crypto packet to operate with");
return -EINVAL;
}
if (apkt->tag) {
SYS_LOG_ERR("CCM encryption does not take a tag");
return -EINVAL;
}
m = insert_crypto_parameters(ctx, apkt, ccm_nonce, &auth_crypt);
if (m < 0) {
SYS_LOG_ERR("Inserting crypto parameters failed");
return m;
}
apkt->pkt->out_len = apkt->pkt->in_len + apkt->ad_len +
(m ? ctx->mode_params.ccm_info.tag_len : 0);
if (apkt->pkt->out_len > apkt->pkt->out_buf_max) {
SYS_LOG_ERR("Result will not fit into out buffer %u vs %u",
apkt->pkt->out_len, apkt->pkt->out_buf_max);
return -ENOBUFS;
}
if (!instruct_ccm(cc2520, CC2520_MEM_KEY >> 4, auth_crypt,
CC2520_MEM_NONCE >> 4, CC2520_MEM_DATA,
0x000, apkt->ad_len, m) ||
!_cc2520_read_ram(&cc2520->spi, CC2520_MEM_DATA,
apkt->pkt->out_buf, apkt->pkt->out_len)) {
SYS_LOG_ERR("CCM or reading result from RAM failed");
return -EIO;
}
apkt->tag = apkt->pkt->out_buf + apkt->pkt->in_len;
return 0;
}
static int _cc2520_crypto_uccm(struct cipher_ctx *ctx,
struct cipher_aead_pkt *apkt,
u8_t *ccm_nonce)
{
struct cc2520_context *cc2520 = ctx->device->driver_data;
u8_t auth_crypt;
int m;
if (!apkt || !apkt->pkt) {
SYS_LOG_ERR("Invalid crypto packet to operate with");
return -EINVAL;
}
if (ctx->mode_params.ccm_info.tag_len && !apkt->tag) {
SYS_LOG_ERR("In case of MIC you need to provide a tag");
return -EINVAL;
}
m = insert_crypto_parameters(ctx, apkt, ccm_nonce, &auth_crypt);
if (m < 0) {
return m;
}
apkt->pkt->out_len = apkt->pkt->in_len + apkt->ad_len;
if (!instruct_uccm(cc2520, CC2520_MEM_KEY >> 4, auth_crypt,
CC2520_MEM_NONCE >> 4, CC2520_MEM_DATA,
0x000, apkt->ad_len, m) ||
!_cc2520_read_ram(&cc2520->spi, CC2520_MEM_DATA,
apkt->pkt->out_buf, apkt->pkt->out_len)) {
SYS_LOG_ERR("UCCM or reading result from RAM failed");
return -EIO;
}
if (m && (!(read_reg_dpustat(&cc2520->spi) & DPUSTAT_AUTHSTAT_H))) {
SYS_LOG_ERR("Authentication of the frame failed");
return -EBADMSG;
}
return 0;
}
static int cc2520_crypto_hw_caps(struct device *dev)
{
return CAP_RAW_KEY | CAP_INPLACE_OPS | CAP_SYNC_OPS;
}
static int cc2520_crypto_begin_session(struct device *dev,
struct cipher_ctx *ctx,
enum cipher_algo algo,
enum cipher_mode mode,
enum cipher_op op_type)
{
if (algo != CRYPTO_CIPHER_ALGO_AES || mode != CRYPTO_CIPHER_MODE_CCM) {
SYS_LOG_ERR("Wrong algo (%u) or mode (%u)", algo, mode);
return -EINVAL;
}
if (ctx->mode_params.ccm_info.nonce_len != 13) {
SYS_LOG_ERR("Nonce length erroneous (%u)",
ctx->mode_params.ccm_info.nonce_len);
return -EINVAL;
}
if (op_type == CRYPTO_CIPHER_OP_ENCRYPT) {
ctx->ops.ccm_crypt_hndlr = _cc2520_crypto_ccm;
} else {
ctx->ops.ccm_crypt_hndlr = _cc2520_crypto_uccm;
}
ctx->ops.cipher_mode = mode;
ctx->device = dev;
return 0;
}
static int cc2520_crypto_free_session(struct device *dev,
struct cipher_ctx *ctx)
{
ARG_UNUSED(dev);
ctx->ops.ccm_crypt_hndlr = NULL;
ctx->device = NULL;
return 0;
}
static int cc2520_crypto_init(struct device *dev)
{
SYS_LOG_INF("CC2520 crypto part initialized");
return 0;
}
struct crypto_driver_api cc2520_crypto_api = {
.query_hw_caps = cc2520_crypto_hw_caps,
.begin_session = cc2520_crypto_begin_session,
.free_session = cc2520_crypto_free_session,
.crypto_async_callback_set = NULL
};
DEVICE_AND_API_INIT(cc2520_crypto, CONFIG_IEEE802154_CC2520_CRYPTO_DRV_NAME,
cc2520_crypto_init, &cc2520_context_data, NULL,
POST_KERNEL, CONFIG_IEEE802154_CC2520_CRYPTO_INIT_PRIO,
&cc2520_crypto_api);
#endif /* CONFIG_IEEE802154_CC2520_CRYPTO */