my customized lib
Diff: atmel-rf-driver/source/NanostackRfPhyAtmel.cpp
- Revision:
- 0:8094b249013c
--- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/atmel-rf-driver/source/NanostackRfPhyAtmel.cpp Sun Nov 26 15:08:14 2017 +0000 @@ -0,0 +1,2513 @@ +/* + * Copyright (c) 2014-2015 ARM Limited. All rights reserved. + * SPDX-License-Identifier: Apache-2.0 + * Licensed under the Apache License, Version 2.0 (the License); you may + * not use this file except in compliance with the License. + * You may obtain a copy of the License at + * + * http://www.apache.org/licenses/LICENSE-2.0 + * + * Unless required by applicable law or agreed to in writing, software + * distributed under the License is distributed on an AS IS BASIS, WITHOUT + * WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. + * See the License for the specific language governing permissions and + * limitations under the License. + */ +#include <string.h> +#include "platform/arm_hal_interrupt.h" +#include "nanostack/platform/arm_hal_phy.h" +#include "ns_types.h" +#include "NanostackRfPhyAtmel.h" +#include "randLIB.h" +#include "AT86RFReg.h" +#include "nanostack/platform/arm_hal_phy.h" +#include "toolchain.h" + +/*Worst case sensitivity*/ +#define RF_DEFAULT_SENSITIVITY -88 +/*Run calibration every 5 minutes*/ +#define RF_CALIBRATION_INTERVAL 6000000 +/*Wait ACK for 2.5ms*/ +#define RF_ACK_WAIT_DEFAULT_TIMEOUT 50 +/*Base CCA backoff (50us units) - substitutes for Inter-Frame Spacing*/ +#define RF_CCA_BASE_BACKOFF 13 /* 650us */ +/*CCA random backoff (50us units)*/ +#define RF_CCA_RANDOM_BACKOFF 51 /* 2550us */ + +#define RF_BUFFER_SIZE 128 + +#define RF_PHY_MODE OQPSK_SIN_250 + +/*Radio RX and TX state definitions*/ +#define RFF_ON 0x01 +#define RFF_RX 0x02 +#define RFF_TX 0x04 +#define RFF_CCA 0x08 + +typedef enum +{ + RF_MODE_NORMAL = 0, + RF_MODE_SNIFFER = 1, + RF_MODE_ED = 2 +}rf_mode_t; + +/*Atmel RF Part Type*/ +typedef enum +{ + ATMEL_UNKNOW_DEV = 0, + ATMEL_AT86RF212, + ATMEL_AT86RF231, + ATMEL_AT86RF233 +}rf_trx_part_e; + +/*Atmel RF states*/ +typedef enum +{ + NOP = 0x00, + BUSY_RX = 0x01, + RF_TX_START = 0x02, + FORCE_TRX_OFF = 0x03, + FORCE_PLL_ON = 0x04, + RX_ON = 0x06, + TRX_OFF = 0x08, + PLL_ON = 0x09, + BUSY_RX_AACK = 0x11, + SLEEP = 0x0F, + RX_AACK_ON = 0x16, + TX_ARET_ON = 0x19 +}rf_trx_states_t; + +/*RF receive buffer*/ +static uint8_t rf_buffer[RF_BUFFER_SIZE]; +/*ACK wait duration changes depending on data rate*/ +static uint16_t rf_ack_wait_duration = RF_ACK_WAIT_DEFAULT_TIMEOUT; + +static int8_t rf_sensitivity = RF_DEFAULT_SENSITIVITY; +static rf_mode_t rf_mode = RF_MODE_NORMAL; +static uint8_t radio_tx_power = 0x00; // Default to +4dBm +static uint8_t rf_phy_channel = 12; +static uint8_t rf_tuned = 1; +static uint8_t rf_use_antenna_diversity = 0; +static uint8_t tx_sequence = 0xff; +static uint8_t need_ack = 0; +static uint8_t rf_rx_mode = 0; +static uint8_t rf_flags = 0; +static uint8_t rf_rnd_rssi = 0; +static int8_t rf_radio_driver_id = -1; +static phy_device_driver_s device_driver; +static uint8_t mac_tx_handle = 0; + +/* Channel configurations for 2.4 and sub-GHz */ +static const phy_rf_channel_configuration_s phy_24ghz = {2405000000U, 5000000U, 250000U, 16U, M_OQPSK}; +static const phy_rf_channel_configuration_s phy_subghz = {868300000U, 2000000U, 250000U, 11U, M_OQPSK}; + +static const phy_device_channel_page_s phy_channel_pages[] = { + { CHANNEL_PAGE_0, &phy_24ghz}, + { CHANNEL_PAGE_2, &phy_subghz}, + { CHANNEL_PAGE_0, NULL} +}; + +/** + * RF output power write + * + * \brief TX power has to be set before network start. + * + * \param power + * AT86RF233 + * 0 = 4 dBm + * 1 = 3.7 dBm + * 2 = 3.4 dBm + * 3 = 3 dBm + * 4 = 2.5 dBm + * 5 = 2 dBm + * 6 = 1 dBm + * 7 = 0 dBm + * 8 = -1 dBm + * 9 = -2 dBm + * 10 = -3 dBm + * 11 = -4 dBm + * 12 = -6 dBm + * 13 = -8 dBm + * 14 = -12 dBm + * 15 = -17 dBm + * + * AT86RF212B + * See datasheet for TX power settings + * + * \return 0, Supported Value + * \return -1, Not Supported Value + */ +static int8_t rf_tx_power_set(uint8_t power); +static rf_trx_part_e rf_radio_type_read(void); +static void rf_ack_wait_timer_start(uint16_t slots); +static void rf_ack_wait_timer_stop(void); +static void rf_handle_cca_ed_done(void); +static void rf_handle_tx_end(void); +static void rf_handle_rx_end(void); +static void rf_on(void); +static void rf_receive(void); +static void rf_poll_trx_state_change(rf_trx_states_t trx_state); +static void rf_init(void); +static int8_t rf_device_register(const uint8_t *mac_addr); +static void rf_device_unregister(void); +static int8_t rf_start_cca(uint8_t *data_ptr, uint16_t data_length, uint8_t tx_handle, data_protocol_e data_protocol ); +static void rf_cca_abort(void); +static void rf_calibration_cb(void); +static void rf_init_phy_mode(void); +static void rf_ack_wait_timer_interrupt(void); +static void rf_calibration_timer_interrupt(void); +static void rf_calibration_timer_start(uint32_t slots); +static void rf_cca_timer_interrupt(void); +static void rf_cca_timer_start(uint32_t slots); +static uint8_t rf_scale_lqi(int8_t rssi); + +static int8_t rf_interface_state_control(phy_interface_state_e new_state, uint8_t rf_channel); +static int8_t rf_extension(phy_extension_type_e extension_type,uint8_t *data_ptr); +static int8_t rf_address_write(phy_address_type_e address_type,uint8_t *address_ptr); + +static void rf_if_cca_timer_start(uint32_t slots); +static void rf_if_enable_promiscuous_mode(void); +static void rf_if_lock(void); +static void rf_if_unlock(void); +static uint8_t rf_if_read_rnd(void); +static void rf_if_calibration_timer_start(uint32_t slots); +static void rf_if_interrupt_handler(void); +static void rf_if_ack_wait_timer_start(uint16_t slots); +static void rf_if_ack_wait_timer_stop(void); +static void rf_if_ack_pending_ctrl(uint8_t state); +static void rf_if_calibration(void); +static uint8_t rf_if_read_register(uint8_t addr); +static void rf_if_set_bit(uint8_t addr, uint8_t bit, uint8_t bit_mask); +static void rf_if_clear_bit(uint8_t addr, uint8_t bit); +static void rf_if_write_register(uint8_t addr, uint8_t data); +static void rf_if_reset_radio(void); +static void rf_if_enable_ant_div(void); +static void rf_if_disable_ant_div(void); +static void rf_if_enable_slptr(void); +static void rf_if_disable_slptr(void); +static void rf_if_write_antenna_diversity_settings(void); +static void rf_if_write_set_tx_power_register(uint8_t value); +static void rf_if_write_rf_settings(void); +static uint8_t rf_if_check_cca(void); +static uint8_t rf_if_check_crc(void); +static uint8_t rf_if_read_trx_state(void); +static void rf_if_read_packet(uint8_t *ptr, uint8_t len); +static void rf_if_write_short_addr_registers(uint8_t *short_address); +static uint8_t rf_if_last_acked_pending(void); +static void rf_if_write_pan_id_registers(uint8_t *pan_id); +static void rf_if_write_ieee_addr_registers(uint8_t *address); +static void rf_if_write_frame_buffer(uint8_t *ptr, uint8_t length); +static void rf_if_change_trx_state(rf_trx_states_t trx_state); +static void rf_if_enable_tx_end_interrupt(void); +static void rf_if_enable_rx_end_interrupt(void); +static void rf_if_enable_cca_ed_done_interrupt(void); +static void rf_if_start_cca_process(void); +static uint8_t rf_if_read_received_frame_length(void); +static int8_t rf_if_read_rssi(void); +static uint8_t rf_if_read_rx_status(void); +static void rf_if_set_channel_register(uint8_t channel); +static void rf_if_enable_promiscuous_mode(void); +static void rf_if_disable_promiscuous_mode(void); +static uint8_t rf_if_read_part_num(void); +static void rf_if_enable_irq(void); +static void rf_if_disable_irq(void); + +#ifdef MBED_CONF_RTOS_PRESENT +#include "mbed.h" +#include "rtos.h" + +static void rf_if_irq_task_process_irq(); + +#define SIG_RADIO 1 +#define SIG_TIMER_ACK 2 +#define SIG_TIMER_CAL 4 +#define SIG_TIMER_CCA 8 + +#define SIG_TIMERS (SIG_TIMER_ACK|SIG_TIMER_CAL|SIG_TIMER_CCA) +#define SIG_ALL (SIG_RADIO|SIG_TIMERS) +#endif + +// HW pins to RF chip +#define SPI_SPEED 7500000 + +class UnlockedSPI : public SPI { +public: + UnlockedSPI(PinName mosi, PinName miso, PinName sclk) : + SPI(mosi, miso, sclk) { } + virtual void lock() { } + virtual void unlock() { } +}; + +class RFBits { +public: + RFBits(PinName spi_mosi, PinName spi_miso, + PinName spi_sclk, PinName spi_cs, + PinName spi_rst, PinName spi_slp, PinName spi_irq); + UnlockedSPI spi; + DigitalOut CS; + DigitalOut RST; + DigitalOut SLP_TR; + InterruptIn IRQ; + Timeout ack_timer; + Timeout cal_timer; + Timeout cca_timer; +#ifdef MBED_CONF_RTOS_PRESENT + Thread irq_thread; + Mutex mutex; + void rf_if_irq_task(); +#endif +}; + +RFBits::RFBits(PinName spi_mosi, PinName spi_miso, + PinName spi_sclk, PinName spi_cs, + PinName spi_rst, PinName spi_slp, PinName spi_irq) + : spi(spi_mosi, spi_miso, spi_sclk), + CS(spi_cs), + RST(spi_rst), + SLP_TR(spi_slp), + IRQ(spi_irq) +#ifdef MBED_CONF_RTOS_PRESENT +,irq_thread(osPriorityRealtime, 1024) +#endif +{ +#ifdef MBED_CONF_RTOS_PRESENT + irq_thread.start(this, &RFBits::rf_if_irq_task); +#endif +} + +static RFBits *rf; +static uint8_t rf_part_num = 0; +static uint8_t rf_rx_lqi; +static int8_t rf_rx_rssi; +static uint8_t rf_rx_status; +/*TODO: RSSI Base value setting*/ +static int8_t rf_rssi_base_val = -91; + +static uint8_t rf_if_spi_exchange(uint8_t out); + +static void rf_if_lock(void) +{ + platform_enter_critical(); +} + +static void rf_if_unlock(void) +{ + platform_exit_critical(); +} + +#ifdef MBED_CONF_RTOS_PRESENT +static void rf_if_cca_timer_signal(void) +{ + rf->irq_thread.signal_set(SIG_TIMER_CCA); +} + +static void rf_if_cal_timer_signal(void) +{ + rf->irq_thread.signal_set(SIG_TIMER_CAL); +} + +static void rf_if_ack_timer_signal(void) +{ + rf->irq_thread.signal_set(SIG_TIMER_ACK); +} +#endif + + +/* Delay functions for RF Chip SPI access */ +#ifdef __CC_ARM +__asm static void delay_loop(uint32_t count) +{ +1 + SUBS a1, a1, #1 + BCS %BT1 + BX lr +} +#elif defined (__ICCARM__) +static void delay_loop(uint32_t count) +{ + __asm volatile( + "loop: \n" + " SUBS %0, %0, #1 \n" + " BCS.n loop\n" + : "+r" (count) + : + : "cc" + ); +} +#else // GCC +static void delay_loop(uint32_t count) +{ + __asm__ volatile ( + "%=:\n\t" +#if defined(__thumb__) && !defined(__thumb2__) + "SUB %0, #1\n\t" +#else + "SUBS %0, %0, #1\n\t" +#endif + "BCS %=b\n\t" + : "+l" (count) + : + : "cc" + ); +} +#endif + +static void delay_ns(uint32_t ns) +{ + uint32_t cycles_per_us = SystemCoreClock / 1000000; + // Cortex-M0 takes 4 cycles per loop (SUB=1, BCS=3) + // Cortex-M3 and M4 takes 3 cycles per loop (SUB=1, BCS=2) + // Cortex-M7 - who knows? + // Cortex M3-M7 have "CYCCNT" - would be better than a software loop, but M0 doesn't + // Assume 3 cycles per loop for now - will be 33% slow on M0. No biggie, + // as original version of code was 300% slow on M4. + // [Note that this very calculation, plus call overhead, will take multiple + // cycles. Could well be 100ns on its own... So round down here, startup is + // worth at least one loop iteration.] + uint32_t count = (cycles_per_us * ns) / 3000; + + delay_loop(count); +} + +// t1 = 180ns, SEL falling edge to MISO active [SPI setup assumed slow enough to not need manual delay] +#define CS_SELECT() {rf->CS = 0; /* delay_ns(180); */} + // t9 = 250ns, last clock to SEL rising edge, t8 = 250ns, SPI idle time between consecutive access +#define CS_RELEASE() {delay_ns(250); rf->CS = 1; delay_ns(250);} + +/* + * \brief Function sets the TX power variable. + * + * \param power TX power setting + * + * \return 0 Success + * \return -1 Fail + */ +MBED_UNUSED static int8_t rf_tx_power_set(uint8_t power) +{ + int8_t ret_val = -1; + + radio_tx_power = power; + rf_if_lock(); + rf_if_write_set_tx_power_register(radio_tx_power); + rf_if_unlock(); + ret_val = 0; + + return ret_val; +} + +/* + * \brief Read connected radio part. + * + * This function only return valid information when rf_init() is called + * + * \return + */ +static rf_trx_part_e rf_radio_type_read(void) +{ + rf_trx_part_e ret_val = ATMEL_UNKNOW_DEV; + + switch (rf_part_num) + { + case PART_AT86RF212: + ret_val = ATMEL_AT86RF212; + break; + + case PART_AT86RF231: + ret_val = ATMEL_AT86RF231; + break; + case PART_AT86RF233: + ret_val = ATMEL_AT86RF231; + break; + default: + break; + } + + return ret_val; +} + + +/* + * \brief Function starts the ACK wait timeout. + * + * \param slots Given slots, resolution 50us + * + * \return none + */ +static void rf_if_ack_wait_timer_start(uint16_t slots) +{ +#ifdef MBED_CONF_RTOS_PRESENT + rf->ack_timer.attach(rf_if_ack_timer_signal, slots*50e-6); +#else + rf->ack_timer.attach(rf_ack_wait_timer_interrupt, slots*50e-6); +#endif +} + +/* + * \brief Function starts the calibration interval. + * + * \param slots Given slots, resolution 50us + * + * \return none + */ +static void rf_if_calibration_timer_start(uint32_t slots) +{ +#ifdef MBED_CONF_RTOS_PRESENT + rf->cal_timer.attach(rf_if_cal_timer_signal, slots*50e-6); +#else + rf->cal_timer.attach(rf_calibration_timer_interrupt, slots*50e-6); +#endif +} + +/* + * \brief Function starts the CCA interval. + * + * \param slots Given slots, resolution 50us + * + * \return none + */ +static void rf_if_cca_timer_start(uint32_t slots) +{ +#ifdef MBED_CONF_RTOS_PRESENT + rf->cca_timer.attach(rf_if_cca_timer_signal, slots*50e-6); +#else + rf->cca_timer.attach(rf_cca_timer_interrupt, slots*50e-6); +#endif +} + +/* + * \brief Function stops the ACK wait timeout. + * + * \param none + * + * \return none + */ +static void rf_if_ack_wait_timer_stop(void) +{ + rf->ack_timer.detach(); +} + +/* + * \brief Function reads data from the given RF SRAM address. + * + * \param ptr Read pointer + * \param sram_address Read address in SRAM + * \param len Length of the read + * + * \return none + */ +static void rf_if_read_payload(uint8_t *ptr, uint8_t sram_address, uint8_t len) +{ + uint8_t i; + + CS_SELECT(); + rf_if_spi_exchange(0x20); + rf_if_spi_exchange(sram_address); + for(i=0; i<len; i++) + *ptr++ = rf_if_spi_exchange(0); + + /*Read LQI and RSSI in variable*/ + rf_rx_lqi = rf_if_spi_exchange(0); + rf_rx_rssi = rf_if_spi_exchange(0); + rf_rx_status = rf_if_spi_exchange(0); + CS_RELEASE(); +} + +/* + * \brief Function sets bit(s) in given RF register. + * + * \param addr Address of the register to set + * \param bit Bit(s) to set + * \param bit_mask Masks the field inside the register + * + * \return none + */ +static void rf_if_set_bit(uint8_t addr, uint8_t bit, uint8_t bit_mask) +{ + uint8_t reg = rf_if_read_register(addr); + reg &= ~bit_mask; + reg |= bit; + rf_if_write_register(addr, reg); +} + +/* + * \brief Function clears bit(s) in given RF register. + * + * \param addr Address of the register to clear + * \param bit Bit(s) to clear + * + * \return none + */ +static void rf_if_clear_bit(uint8_t addr, uint8_t bit) +{ + uint8_t reg = rf_if_read_register(addr); + reg &= ~bit; + rf_if_write_register(addr, reg); +} + +/* + * \brief Function writes register in RF. + * + * \param addr Address on the RF + * \param data Written data + * + * \return none + */ +static void rf_if_write_register(uint8_t addr, uint8_t data) +{ + uint8_t cmd = 0xC0; + CS_SELECT(); + rf_if_spi_exchange(cmd | addr); + rf_if_spi_exchange(data); + CS_RELEASE(); +} + +/* + * \brief Function reads RF register. + * + * \param addr Address on the RF + * + * \return Read data + */ +static uint8_t rf_if_read_register(uint8_t addr) +{ + uint8_t cmd = 0x80; + uint8_t data; + CS_SELECT(); + rf_if_spi_exchange(cmd | addr); + data = rf_if_spi_exchange(0); + CS_RELEASE(); + return data; +} + +/* + * \brief Function resets the RF. + * + * \param none + * + * \return none + */ +static void rf_if_reset_radio(void) +{ + rf->spi.frequency(SPI_SPEED); + rf->IRQ.rise(0); + rf->RST = 1; + wait(10e-4); + rf->RST = 0; + wait(10e-3); + CS_RELEASE(); + rf->SLP_TR = 0; + wait(10e-3); + rf->RST = 1; + wait(10e-3); + + rf->IRQ.rise(&rf_if_interrupt_handler); +} + +/* + * \brief Function enables the promiscuous mode. + * + * \param none + * + * \return none + */ +static void rf_if_enable_promiscuous_mode(void) +{ + /*Set AACK_PROM_MODE to enable the promiscuous mode*/ + rf_if_set_bit(XAH_CTRL_1, AACK_PROM_MODE, AACK_PROM_MODE); +} + +/* + * \brief Function enables the promiscuous mode. + * + * \param none + * + * \return none + */ +static void rf_if_disable_promiscuous_mode(void) +{ + /*Set AACK_PROM_MODE to enable the promiscuous mode*/ + rf_if_clear_bit(XAH_CTRL_1, AACK_PROM_MODE); +} + +/* + * \brief Function enables the Antenna diversity usage. + * + * \param none + * + * \return none + */ +static void rf_if_enable_ant_div(void) +{ + /*Set ANT_EXT_SW_EN to enable controlling of antenna diversity*/ + rf_if_set_bit(ANT_DIV, ANT_EXT_SW_EN, ANT_EXT_SW_EN); +} + +/* + * \brief Function disables the Antenna diversity usage. + * + * \param none + * + * \return none + */ +static void rf_if_disable_ant_div(void) +{ + rf_if_clear_bit(ANT_DIV, ANT_EXT_SW_EN); +} + +/* + * \brief Function sets the SLP TR pin. + * + * \param none + * + * \return none + */ +static void rf_if_enable_slptr(void) +{ + rf->SLP_TR = 1; +} + +/* + * \brief Function clears the SLP TR pin. + * + * \param none + * + * \return none + */ +static void rf_if_disable_slptr(void) +{ + rf->SLP_TR = 0; +} + +/* + * \brief Function writes the antenna diversity settings. + * + * \param none + * + * \return none + */ +static void rf_if_write_antenna_diversity_settings(void) +{ + /*Recommended setting of PDT_THRES is 3 when antenna diversity is used*/ + rf_if_set_bit(RX_CTRL, 0x03, 0x0f); + rf_if_write_register(ANT_DIV, ANT_DIV_EN | ANT_EXT_SW_EN | ANT_CTRL_DEFAULT); +} + +/* + * \brief Function writes the TX output power register. + * + * \param value Given register value + * + * \return none + */ +static void rf_if_write_set_tx_power_register(uint8_t value) +{ + rf_if_write_register(PHY_TX_PWR, value); +} + +/* + * \brief Function returns the RF part number. + * + * \param none + * + * \return part number + */ +static uint8_t rf_if_read_part_num(void) +{ + return rf_if_read_register(PART_NUM); +} + +/* + * \brief Function writes the RF settings and initialises SPI interface. + * + * \param none + * + * \return none + */ +static void rf_if_write_rf_settings(void) +{ + /*Reset RF module*/ + rf_if_reset_radio(); + + rf_part_num = rf_if_read_part_num(); + + rf_if_write_register(XAH_CTRL_0,0); + rf_if_write_register(TRX_CTRL_1, 0x20); + + /*CCA Mode - Carrier sense OR energy above threshold. Channel list is set separately*/ + rf_if_write_register(PHY_CC_CCA, 0x05); + + /*Read transceiver PART_NUM*/ + rf_part_num = rf_if_read_register(PART_NUM); + + /*Sub-GHz RF settings*/ + if(rf_part_num == PART_AT86RF212) + { + /*GC_TX_OFFS mode-dependent setting - OQPSK*/ + rf_if_write_register(RF_CTRL_0, 0x32); + + if(rf_if_read_register(VERSION_NUM) == VERSION_AT86RF212B) + { + /*TX Output Power setting - 0 dBm North American Band*/ + rf_if_write_register(PHY_TX_PWR, 0x03); + } + else + { + /*TX Output Power setting - 0 dBm North American Band*/ + rf_if_write_register(PHY_TX_PWR, 0x24); + } + + /*PHY Mode: IEEE 802.15.4-2006/2011 - OQPSK-SIN-250*/ + rf_if_write_register(TRX_CTRL_2, RF_PHY_MODE); + /*Based on receiver Characteristics. See AT86RF212B Datasheet where RSSI BASE VALUE in range -97 - -100 dBm*/ + rf_rssi_base_val = -98; + } + /*2.4GHz RF settings*/ + else + { + /*Set RPC register*/ + rf_if_write_register(TRX_RPC, 0xef); + /*PHY Mode: IEEE 802.15.4 - Data Rate 250 kb/s*/ + rf_if_write_register(TRX_CTRL_2, 0); + rf_rssi_base_val = -91; + } +} + +/* + * \brief Function checks the channel availability + * + * \param none + * + * \return 1 Channel clear + * \return 0 Channel not clear + */ +static uint8_t rf_if_check_cca(void) +{ + uint8_t retval = 0; + if(rf_if_read_register(TRX_STATUS) & CCA_STATUS) + { + retval = 1; + } + return retval; +} + +/* + * \brief Function checks if the CRC is valid in received frame + * + * \param none + * + * \return 1 CRC ok + * \return 0 CRC failed + */ +static uint8_t rf_if_check_crc(void) +{ + uint8_t retval = 0; + if(rf_if_read_register(PHY_RSSI) & CRC_VALID) + { + retval = 1; + } + return retval; +} + +/* + * \brief Function returns the RF state + * + * \param none + * + * \return RF state + */ +static uint8_t rf_if_read_trx_state(void) +{ + return rf_if_read_register(TRX_STATUS) & 0x1F; +} + +/* + * \brief Function reads data from RF SRAM. + * + * \param ptr Read pointer + * \param len Length of the read + * + * \return none + */ +static void rf_if_read_packet(uint8_t *ptr, uint8_t len) +{ + if(rf_part_num == PART_AT86RF231 || rf_part_num == PART_AT86RF212) + rf_if_read_payload(ptr, 0, len); + else if(rf_part_num == PART_AT86RF233) + rf_if_read_payload(ptr, 1, len); +} + +/* + * \brief Function writes RF short address registers + * + * \param short_address Given short address + * + * \return none + */ +static void rf_if_write_short_addr_registers(uint8_t *short_address) +{ + rf_if_write_register(SHORT_ADDR_1, *short_address++); + rf_if_write_register(SHORT_ADDR_0, *short_address); +} + +/* + * \brief Function sets the frame pending in ACK message + * + * \param state Given frame pending state + * + * \return none + */ +static void rf_if_ack_pending_ctrl(uint8_t state) +{ + rf_if_lock(); + if(state) + { + rf_if_set_bit(CSMA_SEED_1, (1 << AACK_SET_PD), (1 << AACK_SET_PD)); + } + else + { + rf_if_clear_bit(CSMA_SEED_1, (1 << AACK_SET_PD)); + } + rf_if_unlock(); +} + +/* + * \brief Function returns the state of frame pending control + * + * \param none + * + * \return Frame pending state + */ +static uint8_t rf_if_last_acked_pending(void) +{ + uint8_t last_acked_data_pending; + + rf_if_lock(); + if(rf_if_read_register(CSMA_SEED_1) & 0x20) + last_acked_data_pending = 1; + else + last_acked_data_pending = 0; + rf_if_unlock(); + + return last_acked_data_pending; +} + +/* + * \brief Function calibrates the RF part. + * + * \param none + * + * \return none + */ +static void rf_if_calibration(void) +{ + rf_if_set_bit(FTN_CTRL, FTN_START, FTN_START); + /*Wait while calibration is running*/ + while(rf_if_read_register(FTN_CTRL) & FTN_START); +} + +/* + * \brief Function writes RF PAN Id registers + * + * \param pan_id Given PAN Id + * + * \return none + */ +static void rf_if_write_pan_id_registers(uint8_t *pan_id) +{ + rf_if_write_register(PAN_ID_1, *pan_id++); + rf_if_write_register(PAN_ID_0, *pan_id); +} + +/* + * \brief Function writes RF IEEE Address registers + * + * \param address Given IEEE Address + * + * \return none + */ +static void rf_if_write_ieee_addr_registers(uint8_t *address) +{ + uint8_t i; + uint8_t temp = IEEE_ADDR_0; + + for(i=0; i<8; i++) + rf_if_write_register(temp++, address[7-i]); +} + +/* + * \brief Function writes data in RF frame buffer. + * + * \param ptr Pointer to data + * \param length Pointer to length + * + * \return none + */ +static void rf_if_write_frame_buffer(uint8_t *ptr, uint8_t length) +{ + uint8_t i; + uint8_t cmd = 0x60; + + CS_SELECT(); + rf_if_spi_exchange(cmd); + rf_if_spi_exchange(length + 2); + for(i=0; i<length; i++) + rf_if_spi_exchange(*ptr++); + + CS_RELEASE(); +} + +/* + * \brief Function returns 8-bit random value. + * + * \param none + * + * \return random value + */ +static uint8_t rf_if_read_rnd(void) +{ + uint8_t temp; + uint8_t tmp_rpc_val = 0; + /*RPC must be disabled while reading the random number*/ + if(rf_part_num == PART_AT86RF233) + { + tmp_rpc_val = rf_if_read_register(TRX_RPC); + rf_if_write_register(TRX_RPC, 0xc1); + } + + wait(1e-3); + temp = ((rf_if_read_register(PHY_RSSI)>>5) << 6); + wait(1e-3); + temp |= ((rf_if_read_register(PHY_RSSI)>>5) << 4); + wait(1e-3); + temp |= ((rf_if_read_register(PHY_RSSI)>>5) << 2); + wait(1e-3); + temp |= ((rf_if_read_register(PHY_RSSI)>>5)); + wait(1e-3); + if(rf_part_num == PART_AT86RF233) + rf_if_write_register(TRX_RPC, tmp_rpc_val); + return temp; +} + +/* + * \brief Function changes the state of the RF. + * + * \param trx_state Given RF state + * + * \return none + */ +static void rf_if_change_trx_state(rf_trx_states_t trx_state) +{ + rf_if_lock(); + rf_if_write_register(TRX_STATE, trx_state); + /*Wait while not in desired state*/ + rf_poll_trx_state_change(trx_state); + rf_if_unlock(); +} + +/* + * \brief Function enables the TX END interrupt + * + * \param none + * + * \return none + */ +static void rf_if_enable_tx_end_interrupt(void) +{ + rf_if_set_bit(IRQ_MASK, TRX_END, 0x08); +} + +/* + * \brief Function enables the RX END interrupt + * + * \param none + * + * \return none + */ +static void rf_if_enable_rx_end_interrupt(void) +{ + rf_if_set_bit(IRQ_MASK, TRX_END, 0x08); +} + +/* + * \brief Function enables the CCA ED interrupt + * + * \param none + * + * \return none + */ +static void rf_if_enable_cca_ed_done_interrupt(void) +{ + rf_if_set_bit(IRQ_MASK, CCA_ED_DONE, 0x10); +} + +/* + * \brief Function starts the CCA process + * + * \param none + * + * \return none + */ +static void rf_if_start_cca_process(void) +{ + rf_if_set_bit(PHY_CC_CCA, CCA_REQUEST, 0x80); +} + +/* + * \brief Function returns the length of the received packet + * + * \param none + * + * \return packet length + */ +static uint8_t rf_if_read_received_frame_length(void) +{ + uint8_t length; + + CS_SELECT(); + rf_if_spi_exchange(0x20); + length = rf_if_spi_exchange(0); + CS_RELEASE(); + + return length; +} + +/* + * \brief Function returns the RSSI of the received packet + * + * \param none + * + * \return packet RSSI + */ +static int8_t rf_if_read_rssi(void) +{ + int16_t rssi_calc_tmp; + if(rf_part_num == PART_AT86RF212) + rssi_calc_tmp = rf_rx_rssi * 103; + else + rssi_calc_tmp = rf_rx_rssi * 100; + rssi_calc_tmp /= 100; + rssi_calc_tmp = (rf_rssi_base_val + rssi_calc_tmp); + return (int8_t)rssi_calc_tmp; +} + +/* + * \brief Function returns the RSSI of the received packet + * + * \param none + * + * \return packet RSSI + */ +MBED_UNUSED uint8_t rf_if_read_rx_status(void) +{ + return rf_rx_status; +} + +/* + * \brief Function sets the RF channel field + * + * \param Given channel + * + * \return none + */ +static void rf_if_set_channel_register(uint8_t channel) +{ + rf_if_set_bit(PHY_CC_CCA, channel, 0x1f); +} + +/* + * \brief Function enables RF irq pin interrupts in RF interface. + * + * \param none + * + * \return none + */ +static void rf_if_enable_irq(void) +{ + rf->IRQ.enable_irq(); +} + +/* + * \brief Function disables RF irq pin interrupts in RF interface. + * + * \param none + * + * \return none + */ +static void rf_if_disable_irq(void) +{ + rf->IRQ.disable_irq(); +} + +#ifdef MBED_CONF_RTOS_PRESENT +static void rf_if_interrupt_handler(void) +{ + rf->irq_thread.signal_set(SIG_RADIO); +} + +// Started during construction of rf, so variable +// rf isn't set at the start. Uses 'this' instead. +void RFBits::rf_if_irq_task(void) +{ + for (;;) { + osEvent event = irq_thread.signal_wait(0); + if (event.status != osEventSignal) { + continue; + } + rf_if_lock(); + if (event.value.signals & SIG_RADIO) { + rf_if_irq_task_process_irq(); + } + if (event.value.signals & SIG_TIMER_ACK) { + rf_ack_wait_timer_interrupt(); + } + if (event.value.signals & SIG_TIMER_CCA) { + rf_cca_timer_interrupt(); + } + if (event.value.signals & SIG_TIMER_CAL) { + rf_calibration_timer_interrupt(); + } + rf_if_unlock(); + } +} + +static void rf_if_irq_task_process_irq(void) +#else +/* + * \brief Function is a RF interrupt vector. End of frame in RX and TX are handled here as well as CCA process interrupt. + * + * \param none + * + * \return none + */ +static void rf_if_interrupt_handler(void) +#endif +{ + uint8_t irq_status; + + /*Read interrupt flag*/ + irq_status = rf_if_read_register(IRQ_STATUS); + + /*Disable interrupt on RF*/ + rf_if_clear_bit(IRQ_MASK, irq_status); + /*RX start interrupt*/ + if(irq_status & RX_START) + { + } + /*Address matching interrupt*/ + if(irq_status & AMI) + { + } + if(irq_status & TRX_UR) + { + } + /*Frame end interrupt (RX and TX)*/ + if(irq_status & TRX_END) + { + /*TX done interrupt*/ + if(rf_if_read_trx_state() == PLL_ON || rf_if_read_trx_state() == TX_ARET_ON) + { + rf_handle_tx_end(); + } + /*Frame received interrupt*/ + else + { + rf_handle_rx_end(); + } + } + if(irq_status & CCA_ED_DONE) + { + rf_handle_cca_ed_done(); + } +} + +/* + * \brief Function writes/read data in SPI interface + * + * \param out Output data + * + * \return Input data + */ +static uint8_t rf_if_spi_exchange(uint8_t out) +{ + uint8_t v; + v = rf->spi.write(out); + // t9 = t5 = 250ns, delay between LSB of last byte to next MSB or delay between LSB & SEL rising + // [SPI setup assumed slow enough to not need manual delay] + // delay_ns(250); + return v; +} + +/* + * \brief Function sets given RF flag on. + * + * \param x Given RF flag + * + * \return none + */ +static void rf_flags_set(uint8_t x) +{ + rf_flags |= x; +} + +/* + * \brief Function clears given RF flag on. + * + * \param x Given RF flag + * + * \return none + */ +static void rf_flags_clear(uint8_t x) +{ + rf_flags &= ~x; +} + +/* + * \brief Function checks if given RF flag is on. + * + * \param x Given RF flag + * + * \return states of the given flags + */ +static uint8_t rf_flags_check(uint8_t x) +{ + return (rf_flags & x); +} + +/* + * \brief Function clears all RF flags. + * + * \param none + * + * \return none + */ +static void rf_flags_reset(void) +{ + rf_flags = 0; +} + +/* + * \brief Function initialises and registers the RF driver. + * + * \param none + * + * \return rf_radio_driver_id Driver ID given by NET library + */ +static int8_t rf_device_register(const uint8_t *mac_addr) +{ + rf_trx_part_e radio_type; + + rf_init(); + + radio_type = rf_radio_type_read(); + if(radio_type != ATMEL_UNKNOW_DEV) + { + /*Set pointer to MAC address*/ + device_driver.PHY_MAC = (uint8_t *)mac_addr; + device_driver.driver_description = (char*)"ATMEL_MAC"; + //Create setup Used Radio chips + if(radio_type == ATMEL_AT86RF212) + { + device_driver.link_type = PHY_LINK_15_4_SUBGHZ_TYPE; + } + else + { + device_driver.link_type = PHY_LINK_15_4_2_4GHZ_TYPE; + } + device_driver.phy_channel_pages = phy_channel_pages; + /*Maximum size of payload is 127*/ + device_driver.phy_MTU = 127; + /*No header in PHY*/ + device_driver.phy_header_length = 0; + /*No tail in PHY*/ + device_driver.phy_tail_length = 0; + /*Set address write function*/ + device_driver.address_write = &rf_address_write; + /*Set RF extension function*/ + device_driver.extension = &rf_extension; + /*Set RF state control function*/ + device_driver.state_control = &rf_interface_state_control; + /*Set transmit function*/ + device_driver.tx = &rf_start_cca; + /*NULLIFY rx and tx_done callbacks*/ + device_driver.phy_rx_cb = NULL; + device_driver.phy_tx_done_cb = NULL; + /*Register device driver*/ + rf_radio_driver_id = arm_net_phy_register(&device_driver); + } + return rf_radio_driver_id; +} + +/* + * \brief Function unregisters the RF driver. + * + * \param none + * + * \return none + */ +static void rf_device_unregister() +{ + if (rf_radio_driver_id >= 0) { + arm_net_phy_unregister(rf_radio_driver_id); + rf_radio_driver_id = -1; + } +} + +/* + * \brief Function is a call back for ACK wait timeout. + * + * \param none + * + * \return none + */ +static void rf_ack_wait_timer_interrupt(void) +{ + rf_if_lock(); + /*Force PLL state*/ + rf_if_change_trx_state(FORCE_PLL_ON); + rf_poll_trx_state_change(PLL_ON); + /*Start receiver in RX_AACK_ON state*/ + rf_rx_mode = 0; + rf_flags_clear(RFF_RX); + rf_receive(); + rf_if_unlock(); +} + +/* + * \brief Function is a call back for calibration interval timer. + * + * \param none + * + * \return none + */ +static void rf_calibration_timer_interrupt(void) +{ + /*Calibrate RF*/ + rf_calibration_cb(); + /*Start new calibration timeout*/ + rf_calibration_timer_start(RF_CALIBRATION_INTERVAL); +} + +/* + * \brief Function is a call back for cca interval timer. + * + * \param none + * + * \return none + */ +static void rf_cca_timer_interrupt(void) +{ + /*Start CCA process*/ + if(rf_if_read_trx_state() == BUSY_RX_AACK) + { + if(device_driver.phy_tx_done_cb){ + device_driver.phy_tx_done_cb(rf_radio_driver_id, mac_tx_handle, PHY_LINK_CCA_FAIL, 1, 1); + } + } + else + { + /*Set radio in RX state to read channel*/ + rf_receive(); + rf_if_enable_cca_ed_done_interrupt(); + rf_if_start_cca_process(); + } +} + +/* + * \brief Function starts the ACK wait timeout. + * + * \param slots Given slots, resolution 50us + * + * \return none + */ +static void rf_ack_wait_timer_start(uint16_t slots) +{ + rf_if_ack_wait_timer_start(slots); +} + +/* + * \brief Function starts the calibration interval. + * + * \param slots Given slots, resolution 50us + * + * \return none + */ +static void rf_calibration_timer_start(uint32_t slots) +{ + rf_if_calibration_timer_start(slots); +} + +/* + * \brief Function starts the CCA timout. + * + * \param slots Given slots, resolution 50us + * + * \return none + */ +static void rf_cca_timer_start(uint32_t slots) +{ + rf_if_cca_timer_start(slots); +} + +/* + * \brief Function stops the ACK wait timeout. + * + * \param none + * + * \return none + */ +static void rf_ack_wait_timer_stop(void) +{ + rf_if_ack_wait_timer_stop(); +} + +/* + * \brief Function writes various RF settings in startup. + * + * \param none + * + * \return none + */ +static void rf_write_settings(void) +{ + rf_if_lock(); + rf_if_write_rf_settings(); + /*Set output power*/ + rf_if_write_set_tx_power_register(radio_tx_power); + /*Initialise Antenna Diversity*/ + if(rf_use_antenna_diversity) + rf_if_write_antenna_diversity_settings(); + rf_if_unlock(); +} + +/* + * \brief Function writes 16-bit address in RF address filter. + * + * \param short_address Given short address + * + * \return none + */ +static void rf_set_short_adr(uint8_t * short_address) +{ + rf_if_lock(); + /*Wake up RF if sleeping*/ + if(rf_flags_check(RFF_ON) == 0) + { + rf_if_disable_slptr(); + rf_poll_trx_state_change(TRX_OFF); + } + /*Write address filter registers*/ + rf_if_write_short_addr_registers(short_address); + /*RF back to sleep*/ + if(rf_flags_check(RFF_ON) == 0) + { + rf_if_enable_slptr(); + } + rf_if_unlock(); +} + +/* + * \brief Function writes PAN Id in RF PAN Id filter. + * + * \param pan_id Given PAN Id + * + * \return none + */ +static void rf_set_pan_id(uint8_t *pan_id) +{ + rf_if_lock(); + /*Wake up RF if sleeping*/ + if(rf_flags_check(RFF_ON) == 0) + { + rf_if_disable_slptr(); + rf_poll_trx_state_change(TRX_OFF); + } + /*Write address filter registers*/ + rf_if_write_pan_id_registers(pan_id); + /*RF back to sleep*/ + if(rf_flags_check(RFF_ON) == 0) + { + rf_if_enable_slptr(); + } + rf_if_unlock(); +} + +/* + * \brief Function writes 64-bit address in RF address filter. + * + * \param address Given 64-bit address + * + * \return none + */ +static void rf_set_address(uint8_t *address) +{ + rf_if_lock(); + /*Wake up RF if sleeping*/ + if(rf_flags_check(RFF_ON) == 0) + { + rf_if_disable_slptr(); + rf_poll_trx_state_change(TRX_OFF); + } + /*Write address filter registers*/ + rf_if_write_ieee_addr_registers(address); + /*RF back to sleep*/ + if(rf_flags_check(RFF_ON) == 0) + { + rf_if_enable_slptr(); + } + rf_if_unlock(); +} + +/* + * \brief Function sets the RF channel. + * + * \param ch New channel + * + * \return none + */ +static void rf_channel_set(uint8_t ch) +{ + rf_if_lock(); + rf_phy_channel = ch; + if(ch < 0x1f) + rf_if_set_channel_register(ch); + rf_if_unlock(); +} + + +/* + * \brief Function initialises the radio driver and resets the radio. + * + * \param none + * + * \return none + */ +static void rf_init(void) +{ + /*Reset RF module*/ + rf_if_reset_radio(); + + rf_if_lock(); + + /*Write RF settings*/ + rf_write_settings(); + /*Initialise PHY mode*/ + rf_init_phy_mode(); + /*Clear RF flags*/ + rf_flags_reset(); + /*Set RF in TRX OFF state*/ + rf_if_change_trx_state(TRX_OFF); + /*Set RF in PLL_ON state*/ + rf_if_change_trx_state(PLL_ON); + /*Start receiver*/ + rf_receive(); + /*Read random variable. This will be used when seeding pseudo-random generator*/ + rf_rnd_rssi = rf_if_read_rnd(); + /*Start RF calibration timer*/ + rf_calibration_timer_start(RF_CALIBRATION_INTERVAL); + + rf_if_unlock(); +} + +/** + * \brief Function gets called when MAC is setting radio off. + * + * \param none + * + * \return none + */ +static void rf_off(void) +{ + if(rf_flags_check(RFF_ON)) + { + rf_if_lock(); + rf_cca_abort(); + uint16_t while_counter = 0; + /*Wait while receiving*/ + while(rf_if_read_trx_state() == BUSY_RX_AACK) + { + while_counter++; + if(while_counter == 0xffff) + break; + } + /*RF state change: RX_AACK_ON->PLL_ON->TRX_OFF->SLEEP*/ + if(rf_if_read_trx_state() == RX_AACK_ON) + { + rf_if_change_trx_state(PLL_ON); + } + rf_if_change_trx_state(TRX_OFF); + rf_if_enable_slptr(); + + /*Disable Antenna Diversity*/ + if(rf_use_antenna_diversity) + rf_if_disable_ant_div(); + rf_if_unlock(); + } + + /*Clears all flags*/ + rf_flags_reset(); +} + +/* + * \brief Function polls the RF state until it has changed to desired state. + * + * \param trx_state RF state + * + * \return none + */ +static void rf_poll_trx_state_change(rf_trx_states_t trx_state) +{ + uint16_t while_counter = 0; + rf_if_lock(); + + if(trx_state != RF_TX_START) + { + if(trx_state == FORCE_PLL_ON) + trx_state = PLL_ON; + else if(trx_state == FORCE_TRX_OFF) + trx_state = TRX_OFF; + + while(rf_if_read_trx_state() != trx_state) + { + while_counter++; + if(while_counter == 0x1ff) + break; + } + } + rf_if_unlock(); +} + +/* + * \brief Function starts the CCA process before starting data transmission and copies the data to RF TX FIFO. + * + * \param data_ptr Pointer to TX data + * \param data_length Length of the TX data + * \param tx_handle Handle to transmission + * \return 0 Success + * \return -1 Busy + */ +static int8_t rf_start_cca(uint8_t *data_ptr, uint16_t data_length, uint8_t tx_handle, data_protocol_e data_protocol ) +{ + (void)data_protocol; + /*Check if transmitter is busy*/ + if(rf_if_read_trx_state() == BUSY_RX_AACK) + { + /*Return busy*/ + return -1; + } + else + { + rf_if_lock(); + /*Check if transmitted data needs to be acked*/ + if(*data_ptr & 0x20) + need_ack = 1; + else + need_ack = 0; + /*Store the sequence number for ACK handling*/ + tx_sequence = *(data_ptr + 2); + + /*Write TX FIFO*/ + rf_if_write_frame_buffer(data_ptr, (uint8_t)data_length); + rf_flags_set(RFF_CCA); + /*Start CCA timeout*/ + rf_cca_timer_start(RF_CCA_BASE_BACKOFF + randLIB_get_random_in_range(0, RF_CCA_RANDOM_BACKOFF)); + /*Store TX handle*/ + mac_tx_handle = tx_handle; + rf_if_unlock(); + } + + /*Return success*/ + return 0; +} + +/* + * \brief Function aborts CCA process. + * + * \param none + * + * \return none + */ +static void rf_cca_abort(void) +{ + /*Clear RFF_CCA RF flag*/ + rf_flags_clear(RFF_CCA); +} + +/* + * \brief Function starts the transmission of the frame. + * + * \param none + * + * \return none + */ +static void rf_start_tx(void) +{ + /*Only start transmitting from RX state*/ + uint8_t trx_state = rf_if_read_trx_state(); + if(trx_state != RX_AACK_ON) + { + if(device_driver.phy_tx_done_cb){ + device_driver.phy_tx_done_cb(rf_radio_driver_id, mac_tx_handle, PHY_LINK_CCA_FAIL, 1, 1); + } + } + else + { + /*RF state change: ->PLL_ON->RF_TX_START*/ + rf_if_change_trx_state(FORCE_PLL_ON); + rf_flags_clear(RFF_RX); + rf_if_enable_tx_end_interrupt(); + rf_flags_set(RFF_TX); + rf_if_change_trx_state(RF_TX_START); + } +} + +/* + * \brief Function sets the RF in RX state. + * + * \param none + * + * \return none + */ +static void rf_receive(void) +{ + uint16_t while_counter = 0; + if(rf_flags_check(RFF_ON) == 0) + { + rf_on(); + } + /*If not yet in RX state set it*/ + if(rf_flags_check(RFF_RX) == 0) + { + rf_if_lock(); + /*Wait while receiving data*/ + while(rf_if_read_trx_state() == BUSY_RX_AACK) + { + while_counter++; + if(while_counter == 0xffff) + { + break; + } + } + + rf_if_change_trx_state(PLL_ON); + + if((rf_mode == RF_MODE_SNIFFER) || (rf_mode == RF_MODE_ED)) + { + rf_if_change_trx_state(RX_ON); + } + else + { + /*ACK is always received in promiscuous mode to bypass address filters*/ + if(rf_rx_mode) + { + rf_rx_mode = 0; + rf_if_enable_promiscuous_mode(); + } + else + { + rf_if_disable_promiscuous_mode(); + } + rf_if_change_trx_state(RX_AACK_ON); + } + /*If calibration timer was unable to calibrate the RF, run calibration now*/ + if(!rf_tuned) + { + /*Start calibration. This can be done in states TRX_OFF, PLL_ON or in any receive state*/ + rf_if_calibration(); + /*RF is tuned now*/ + rf_tuned = 1; + } + + rf_channel_set(rf_phy_channel); + rf_flags_set(RFF_RX); + // Don't receive packets when ED mode enabled + if (rf_mode != RF_MODE_ED) + { + rf_if_enable_rx_end_interrupt(); + } + rf_if_unlock(); + } + /*Stop the running CCA process*/ + if(rf_flags_check(RFF_CCA)) + rf_cca_abort(); +} + +/* + * \brief Function calibrates the radio. + * + * \param none + * + * \return none + */ +static void rf_calibration_cb(void) +{ + /*clear tuned flag to start tuning in rf_receive*/ + rf_tuned = 0; + /*If RF is in default receive state, start calibration*/ + if(rf_if_read_trx_state() == RX_AACK_ON) + { + rf_if_lock(); + /*Set RF in PLL_ON state*/ + rf_if_change_trx_state(PLL_ON); + /*Set RF in TRX_OFF state to start PLL tuning*/ + rf_if_change_trx_state(TRX_OFF); + /*Set RF in RX_ON state to calibrate*/ + rf_if_change_trx_state(RX_ON); + /*Calibrate FTN*/ + rf_if_calibration(); + /*RF is tuned now*/ + rf_tuned = 1; + /*Back to default receive state*/ + rf_flags_clear(RFF_RX); + rf_receive(); + rf_if_unlock(); + } +} + +/* + * \brief Function sets RF_ON flag when radio is powered. + * + * \param none + * + * \return none + */ +static void rf_on(void) +{ + /*Set RFF_ON flag*/ + if(rf_flags_check(RFF_ON) == 0) + { + rf_if_lock(); + rf_flags_set(RFF_ON); + /*Enable Antenna diversity*/ + if(rf_use_antenna_diversity) + /*Set ANT_EXT_SW_EN to enable controlling of antenna diversity*/ + rf_if_enable_ant_div(); + + /*Wake up from sleep state*/ + rf_if_disable_slptr(); + rf_poll_trx_state_change(TRX_OFF); + rf_if_unlock(); + } +} + +/* + * \brief Function handles the received ACK frame. + * + * \param seq_number Sequence number of received ACK + * \param data_pending Pending bit state in received ACK + * + * \return none + */ +static void rf_handle_ack(uint8_t seq_number, uint8_t data_pending) +{ + phy_link_tx_status_e phy_status; + rf_if_lock(); + /*Received ACK sequence must be equal with transmitted packet sequence*/ + if(tx_sequence == seq_number) + { + rf_ack_wait_timer_stop(); + /*When data pending bit in ACK frame is set, inform NET library*/ + if(data_pending) + phy_status = PHY_LINK_TX_DONE_PENDING; + else + phy_status = PHY_LINK_TX_DONE; + /*Call PHY TX Done API*/ + if(device_driver.phy_tx_done_cb){ + device_driver.phy_tx_done_cb(rf_radio_driver_id, mac_tx_handle,phy_status, 1, 1); + } + } + rf_if_unlock(); +} + +/* + * \brief Function is a call back for RX end interrupt. + * + * \param none + * + * \return none + */ +static void rf_handle_rx_end(void) +{ + uint8_t rf_lqi = 0; + int8_t rf_rssi = 0; + + /*Start receiver*/ + rf_flags_clear(RFF_RX); + rf_receive(); + + /*Frame received interrupt*/ + if(rf_flags_check(RFF_RX)) + { + /*Check CRC_valid bit*/ + if(rf_if_check_crc()) + { + uint8_t *rf_rx_ptr; + uint8_t receiving_ack = 0; + /*Read length*/ + uint8_t len = rf_if_read_received_frame_length(); + + rf_rx_ptr = rf_buffer; + /*ACK frame*/ + if(len == 5) + { + /*Read ACK in static ACK buffer*/ + receiving_ack = 1; + } + /*Check the length is valid*/ + if(len > 1 && len < RF_BUFFER_SIZE) + { + /*Read received packet*/ + rf_if_read_packet(rf_rx_ptr, len); + + if(!receiving_ack) + { + rf_rssi = rf_if_read_rssi(); + /*Scale LQI using received RSSI*/ + rf_lqi = rf_scale_lqi(rf_rssi); + } + if(rf_mode == RF_MODE_SNIFFER) + { + if( device_driver.phy_rx_cb ){ + device_driver.phy_rx_cb(rf_buffer,len - 2, rf_lqi, rf_rssi, rf_radio_driver_id); + } + } + else + { + /*Handle received ACK*/ + if(receiving_ack && ((rf_buffer[0] & 0x07) == 0x02)) + { + uint8_t pending = 0; + /*Check if data is pending*/ + if ((rf_buffer[0] & 0x10)) + { + pending=1; + } + /*Send sequence number in ACK handler*/ + rf_handle_ack(rf_buffer[2], pending); + } + else + { + if( device_driver.phy_rx_cb ){ + device_driver.phy_rx_cb(rf_buffer,len - 2, rf_lqi, rf_rssi, rf_radio_driver_id); + } + } + } + } + } + } +} + +/* + * \brief Function is called when MAC is shutting down the radio. + * + * \param none + * + * \return none + */ +static void rf_shutdown(void) +{ + /*Call RF OFF*/ + rf_off(); +} + +/* + * \brief Function is a call back for TX end interrupt. + * + * \param none + * + * \return none + */ +static void rf_handle_tx_end(void) +{ + phy_link_tx_status_e phy_status = PHY_LINK_TX_SUCCESS; + + rf_rx_mode = 0; + /*If ACK is needed for this transmission*/ + if(need_ack && rf_flags_check(RFF_TX)) + { + rf_ack_wait_timer_start(rf_ack_wait_duration); + rf_rx_mode = 1; + } + rf_flags_clear(RFF_RX); + /*Start receiver*/ + rf_receive(); + + /*Call PHY TX Done API*/ + if(device_driver.phy_tx_done_cb){ + device_driver.phy_tx_done_cb(rf_radio_driver_id, mac_tx_handle, phy_status, 1, 1); + } +} + +/* + * \brief Function is a call back for CCA ED done interrupt. + * + * \param none + * + * \return none + */ +static void rf_handle_cca_ed_done(void) +{ + rf_flags_clear(RFF_CCA); + /*Check the result of CCA process*/ + if(rf_if_check_cca()) + { + rf_start_tx(); + } + else + { + /*Send CCA fail notification*/ + if(device_driver.phy_tx_done_cb){ + device_driver.phy_tx_done_cb(rf_radio_driver_id, mac_tx_handle, PHY_LINK_CCA_FAIL, 1, 1); + } + } +} + +/* + * \brief Function returns the TX power variable. + * + * \param none + * + * \return radio_tx_power TX power variable + */ +MBED_UNUSED static uint8_t rf_tx_power_get(void) +{ + return radio_tx_power; +} + +/* + * \brief Function enables the usage of Antenna diversity. + * + * \param none + * + * \return 0 Success + */ +MBED_UNUSED static int8_t rf_enable_antenna_diversity(void) +{ + int8_t ret_val = 0; + rf_use_antenna_diversity = 1; + return ret_val; +} + +/* + * \brief Function gives the control of RF states to MAC. + * + * \param new_state RF state + * \param rf_channel RF channel + * + * \return 0 Success + */ +static int8_t rf_interface_state_control(phy_interface_state_e new_state, uint8_t rf_channel) +{ + int8_t ret_val = 0; + switch (new_state) + { + /*Reset PHY driver and set to idle*/ + case PHY_INTERFACE_RESET: + break; + /*Disable PHY Interface driver*/ + case PHY_INTERFACE_DOWN: + rf_shutdown(); + break; + /*Enable PHY Interface driver*/ + case PHY_INTERFACE_UP: + rf_mode = RF_MODE_NORMAL; + rf_channel_set(rf_channel); + rf_receive(); + rf_if_enable_irq(); + break; + /*Enable wireless interface ED scan mode*/ + case PHY_INTERFACE_RX_ENERGY_STATE: + rf_mode = RF_MODE_ED; + rf_channel_set(rf_channel); + rf_receive(); + rf_if_disable_irq(); + // Read status to clear pending flags. + rf_if_read_register(IRQ_STATUS); + // Must set interrupt mask to be able to read IRQ status. GPIO interrupt is disabled. + rf_if_set_bit(IRQ_MASK, CCA_ED_DONE, CCA_ED_DONE); + // ED can be initiated by writing arbitrary value to PHY_ED_LEVEL + rf_if_write_register(PHY_ED_LEVEL, 0xff); + break; + case PHY_INTERFACE_SNIFFER_STATE: /**< Enable Sniffer state */ + rf_mode = RF_MODE_SNIFFER; + rf_channel_set(rf_channel); + rf_flags_clear(RFF_RX); + rf_receive(); + break; + } + return ret_val; +} + +/* + * \brief Function controls the ACK pending, channel setting and energy detection. + * + * \param extension_type Type of control + * \param data_ptr Data from NET library + * + * \return 0 Success + */ +static int8_t rf_extension(phy_extension_type_e extension_type, uint8_t *data_ptr) +{ + switch (extension_type) + { + /*Control MAC pending bit for Indirect data transmission*/ + case PHY_EXTENSION_CTRL_PENDING_BIT: + if(*data_ptr) + { + rf_if_ack_pending_ctrl(1); + } + else + { + rf_if_ack_pending_ctrl(0); + } + break; + /*Return frame pending status*/ + case PHY_EXTENSION_READ_LAST_ACK_PENDING_STATUS: + *data_ptr = rf_if_last_acked_pending(); + break; + /*Set channel*/ + case PHY_EXTENSION_SET_CHANNEL: + break; + /*Read energy on the channel*/ + case PHY_EXTENSION_READ_CHANNEL_ENERGY: + // End of the ED measurement is indicated by CCA_ED_DONE + while (!(rf_if_read_register(IRQ_STATUS) & CCA_ED_DONE)); + // RF input power: RSSI base level + 1[db] * PHY_ED_LEVEL + *data_ptr = rf_sensitivity + rf_if_read_register(PHY_ED_LEVEL); + // Read status to clear pending flags. + rf_if_read_register(IRQ_STATUS); + // Next ED measurement is started, next PHY_EXTENSION_READ_CHANNEL_ENERGY call will return the result. + rf_if_write_register(PHY_ED_LEVEL, 0xff); + break; + /*Read status of the link*/ + case PHY_EXTENSION_READ_LINK_STATUS: + break; + default: + break; + } + return 0; +} + +/* + * \brief Function sets the addresses to RF address filters. + * + * \param address_type Type of address + * \param address_ptr Pointer to given address + * + * \return 0 Success + */ +static int8_t rf_address_write(phy_address_type_e address_type, uint8_t *address_ptr) +{ + int8_t ret_val = 0; + switch (address_type) + { + /*Set 48-bit address*/ + case PHY_MAC_48BIT: + break; + /*Set 64-bit address*/ + case PHY_MAC_64BIT: + rf_set_address(address_ptr); + break; + /*Set 16-bit address*/ + case PHY_MAC_16BIT: + rf_set_short_adr(address_ptr); + break; + /*Set PAN Id*/ + case PHY_MAC_PANID: + rf_set_pan_id(address_ptr); + break; + } + return ret_val; +} + +/* + * \brief Function initialises the ACK wait time and returns the used PHY mode. + * + * \param none + * + * \return tmp Used PHY mode + */ +static void rf_init_phy_mode(void) +{ + uint8_t tmp = 0; + uint8_t part = rf_if_read_part_num(); + /*Read used PHY Mode*/ + tmp = rf_if_read_register(TRX_CTRL_2); + /*Set ACK wait time for used data rate*/ + if(part == PART_AT86RF212) + { + if((tmp & 0x1f) == 0x00) + { + rf_sensitivity = -110; + rf_ack_wait_duration = 938; + tmp = BPSK_20; + } + else if((tmp & 0x1f) == 0x04) + { + rf_sensitivity = -108; + rf_ack_wait_duration = 469; + tmp = BPSK_40; + } + else if((tmp & 0x1f) == 0x14) + { + rf_sensitivity = -108; + rf_ack_wait_duration = 469; + tmp = BPSK_40_ALT; + } + else if((tmp & 0x1f) == 0x08) + { + rf_sensitivity = -101; + rf_ack_wait_duration = 50; + tmp = OQPSK_SIN_RC_100; + } + else if((tmp & 0x1f) == 0x09) + { + rf_sensitivity = -99; + rf_ack_wait_duration = 30; + tmp = OQPSK_SIN_RC_200; + } + else if((tmp & 0x1f) == 0x18) + { + rf_sensitivity = -102; + rf_ack_wait_duration = 50; + tmp = OQPSK_RC_100; + } + else if((tmp & 0x1f) == 0x19) + { + rf_sensitivity = -100; + rf_ack_wait_duration = 30; + tmp = OQPSK_RC_200; + } + else if((tmp & 0x1f) == 0x0c) + { + rf_sensitivity = -100; + rf_ack_wait_duration = 20; + tmp = OQPSK_SIN_250; + } + else if((tmp & 0x1f) == 0x0d) + { + rf_sensitivity = -98; + rf_ack_wait_duration = 25; + tmp = OQPSK_SIN_500; + } + else if((tmp & 0x1f) == 0x0f) + { + rf_sensitivity = -98; + rf_ack_wait_duration = 25; + tmp = OQPSK_SIN_500_ALT; + } + else if((tmp & 0x1f) == 0x1c) + { + rf_sensitivity = -101; + rf_ack_wait_duration = 20; + tmp = OQPSK_RC_250; + } + else if((tmp & 0x1f) == 0x1d) + { + rf_sensitivity = -99; + rf_ack_wait_duration = 25; + tmp = OQPSK_RC_500; + } + else if((tmp & 0x1f) == 0x1f) + { + rf_sensitivity = -99; + rf_ack_wait_duration = 25; + tmp = OQPSK_RC_500_ALT; + } + else if((tmp & 0x3f) == 0x2A) + { + rf_sensitivity = -91; + rf_ack_wait_duration = 25; + tmp = OQPSK_SIN_RC_400_SCR_ON; + } + else if((tmp & 0x3f) == 0x0A) + { + rf_sensitivity = -91; + rf_ack_wait_duration = 25; + tmp = OQPSK_SIN_RC_400_SCR_OFF; + } + else if((tmp & 0x3f) == 0x3A) + { + rf_sensitivity = -97; + rf_ack_wait_duration = 25; + tmp = OQPSK_RC_400_SCR_ON; + } + else if((tmp & 0x3f) == 0x1A) + { + rf_sensitivity = -97; + rf_ack_wait_duration = 25; + tmp = OQPSK_RC_400_SCR_OFF; + } + else if((tmp & 0x3f) == 0x2E) + { + rf_sensitivity = -93; + rf_ack_wait_duration = 13; + tmp = OQPSK_SIN_1000_SCR_ON; + } + else if((tmp & 0x3f) == 0x0E) + { + rf_sensitivity = -93; + rf_ack_wait_duration = 13; + tmp = OQPSK_SIN_1000_SCR_OFF; + } + else if((tmp & 0x3f) == 0x3E) + { + rf_sensitivity = -95; + rf_ack_wait_duration = 13; + tmp = OQPSK_RC_1000_SCR_ON; + } + else if((tmp & 0x3f) == 0x1E) + { + rf_sensitivity = -95; + rf_ack_wait_duration = 13; + tmp = OQPSK_RC_1000_SCR_OFF; + } + } + else + { + rf_sensitivity = -101; + rf_ack_wait_duration = 20; + } + /*Board design might reduces the sensitivity*/ + //rf_sensitivity += RF_SENSITIVITY_CALIBRATION; +} + + +static uint8_t rf_scale_lqi(int8_t rssi) +{ + uint8_t scaled_lqi; + + /*rssi < RF sensitivity*/ + if(rssi < rf_sensitivity) + scaled_lqi=0; + /*-91 dBm < rssi < -81 dBm (AT86RF233 XPro)*/ + /*-90 dBm < rssi < -80 dBm (AT86RF212B XPro)*/ + else if(rssi < (rf_sensitivity + 10)) + scaled_lqi=31; + /*-81 dBm < rssi < -71 dBm (AT86RF233 XPro)*/ + /*-80 dBm < rssi < -70 dBm (AT86RF212B XPro)*/ + else if(rssi < (rf_sensitivity + 20)) + scaled_lqi=207; + /*-71 dBm < rssi < -61 dBm (AT86RF233 XPro)*/ + /*-70 dBm < rssi < -60 dBm (AT86RF212B XPro)*/ + else if(rssi < (rf_sensitivity + 30)) + scaled_lqi=255; + /*-61 dBm < rssi < -51 dBm (AT86RF233 XPro)*/ + /*-60 dBm < rssi < -50 dBm (AT86RF212B XPro)*/ + else if(rssi < (rf_sensitivity + 40)) + scaled_lqi=255; + /*-51 dBm < rssi < -41 dBm (AT86RF233 XPro)*/ + /*-50 dBm < rssi < -40 dBm (AT86RF212B XPro)*/ + else if(rssi < (rf_sensitivity + 50)) + scaled_lqi=255; + /*-41 dBm < rssi < -31 dBm (AT86RF233 XPro)*/ + /*-40 dBm < rssi < -30 dBm (AT86RF212B XPro)*/ + else if(rssi < (rf_sensitivity + 60)) + scaled_lqi=255; + /*-31 dBm < rssi < -21 dBm (AT86RF233 XPro)*/ + /*-30 dBm < rssi < -20 dBm (AT86RF212B XPro)*/ + else if(rssi < (rf_sensitivity + 70)) + scaled_lqi=255; + /*rssi > RF saturation*/ + else if(rssi > (rf_sensitivity + 80)) + scaled_lqi=111; + /*-21 dBm < rssi < -11 dBm (AT86RF233 XPro)*/ + /*-20 dBm < rssi < -10 dBm (AT86RF212B XPro)*/ + else + scaled_lqi=255; + + return scaled_lqi; +} + +NanostackRfPhyAtmel::NanostackRfPhyAtmel(PinName spi_mosi, PinName spi_miso, + PinName spi_sclk, PinName spi_cs, PinName spi_rst, PinName spi_slp, PinName spi_irq, + PinName i2c_sda, PinName i2c_scl) + : _mac(i2c_sda, i2c_scl), _mac_addr(), _rf(NULL), _mac_set(false), + _spi_mosi(spi_mosi), _spi_miso(spi_miso), _spi_sclk(spi_sclk), + _spi_cs(spi_cs), _spi_rst(spi_rst), _spi_slp(spi_slp), _spi_irq(spi_irq) +{ + _rf = new RFBits(_spi_mosi, _spi_miso, _spi_sclk, _spi_cs, _spi_rst, _spi_slp, _spi_irq); +} + +NanostackRfPhyAtmel::~NanostackRfPhyAtmel() +{ + delete _rf; +} + +int8_t NanostackRfPhyAtmel::rf_register() +{ + if (NULL == _rf) { + return -1; + } + + rf_if_lock(); + + if (rf != NULL) { + rf_if_unlock(); + error("Multiple registrations of NanostackRfPhyAtmel not supported"); + return -1; + } + + // Read the mac address if it hasn't been set by a user + rf = _rf; + if (!_mac_set) { + int ret = _mac.read_eui64((void*)_mac_addr); + if (ret < 0) { + rf = NULL; + rf_if_unlock(); + return -1; + } + } + + int8_t radio_id = rf_device_register(_mac_addr); + if (radio_id < 0) { + rf = NULL; + } + + rf_if_unlock(); + return radio_id; +} + +void NanostackRfPhyAtmel::rf_unregister() +{ + rf_if_lock(); + + if (NULL == rf) { + rf_if_unlock(); + return; + } + + rf_device_unregister(); + rf = NULL; + + rf_if_unlock(); +} + +void NanostackRfPhyAtmel::get_mac_address(uint8_t *mac) +{ + rf_if_lock(); + + if (NULL == rf) { + error("NanostackRfPhyAtmel Must be registered to read mac address"); + rf_if_unlock(); + return; + } + memcpy((void*)mac, (void*)_mac_addr, sizeof(_mac_addr)); + + rf_if_unlock(); +} + +void NanostackRfPhyAtmel::set_mac_address(uint8_t *mac) +{ + rf_if_lock(); + + if (NULL != rf) { + error("NanostackRfPhyAtmel cannot change mac address when running"); + rf_if_unlock(); + return; + } + memcpy((void*)_mac_addr, (void*)mac, sizeof(_mac_addr)); + _mac_set = true; + + rf_if_unlock(); +} +