Jim Flynn
Added support for WNC M14A2A Cellular LTE Data Module.
Dependencies: WNC14A2AInterface
Dependents: http-example-wnc http-example-wnc-modified
mcr20a-rf-driver/source/NanostackRfPhyMcr20a.cpp
- Committer:
- root@developer-sjc-cyan-compiler.local.mbed.org
- Date:
- 2017-04-23
- Revision:
- 5:391eac6a0a94
- Parent:
- 0:2563b0415d1f
File content as of revision 5:391eac6a0a94:
/*
* 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 "NanostackRfPhyMcr20a.h"
#include "ns_types.h"
#include "platform/arm_hal_interrupt.h"
#include "nanostack/platform/arm_hal_phy.h"
#include "toolchain.h"
#include <string.h>
/* Freescale headers which are for C files */
extern "C" {
#include "MCR20Drv.h"
#include "MCR20Reg.h"
#include "MCR20Overwrites.h"
}
#define RF_BUFFER_SIZE 128
/*Radio RX and TX state definitions*/
#define RFF_ON 0x01
#define RFF_RX 0x02
#define RFF_TX 0x04
#define RFF_CCA 0x08
#define RF_MODE_NORMAL 0
#define RF_MODE_SNIFFER 1
#define RF_CCA_THRESHOLD 75 /* -75 dBm */
#define RF_TX_POWER_MAX 0
/* PHY constants in symbols */
#define gPhyWarmUpTime_c 9
#define gPhySHRDuration_c 10
#define gPhySymbolsPerOctet_c 2
#define gPhyAckWaitDuration_c 54
#define gCcaED_c 0
#define gCcaCCA_MODE1_c 1
#define gXcvrRunState_d gXcvrPwrAutodoze_c
#define gXcvrLowPowerState_d gXcvrPwrHibernate_c
/* MCR20A XCVR states */
typedef enum xcvrState_tag{
gIdle_c,
gRX_c,
gTX_c,
gCCA_c,
gTR_c,
gCCCA_c,
}xcvrState_t;
/* MCR20A XCVR low power states */
typedef enum xcvrPwrMode_tag{
gXcvrPwrIdle_c,
gXcvrPwrAutodoze_c,
gXcvrPwrDoze_c,
gXcvrPwrHibernate_c
}xcvrPwrMode_t;
/*RF Part Type*/
typedef enum
{
FREESCALE_UNKNOW_DEV = 0,
FREESCALE_MCR20A
}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];
/* TX info */
static uint8_t radio_tx_power = 0x17; /* 0 dBm */
static uint8_t mac_tx_handle = 0;
static uint8_t need_ack = 0;
static uint16_t tx_len = 0;
/* RF driver data */
static xcvrState_t mPhySeqState;
static xcvrPwrMode_t mPwrState;
static phy_device_driver_s device_driver;
static uint8_t mStatusAndControlRegs[8];
static uint8_t rf_rnd = 0;
static int8_t rf_radio_driver_id = -1;
static uint8_t MAC_address[8] = {1, 2, 3, 4, 5, 6, 7, 8};
/* Driver instance handle and hardware */
static NanostackRfPhyMcr20a *rf = NULL;
static SPI *spi = NULL;
static DigitalOut *cs = NULL;
static DigitalOut *rst = NULL;
static InterruptIn *irq = NULL;
static DigitalIn *irq_pin = NULL;
/* Channel info */ /* 2405 2410 2415 2420 2425 2430 2435 2440 2445 2450 2455 2460 2465 2470 2475 2480 */
static const uint8_t pll_int[16] = {0x0B, 0x0B, 0x0B, 0x0B, 0x0B, 0x0B, 0x0C, 0x0C, 0x0C, 0x0C, 0x0C, 0x0C, 0x0D, 0x0D, 0x0D, 0x0D};
static const uint16_t pll_frac[16] = {0x2800, 0x5000, 0x7800, 0xA000, 0xC800, 0xF000, 0x1800, 0x4000, 0x6800, 0x9000, 0xB800, 0xE000, 0x0800, 0x3000, 0x5800, 0x8000};
static uint8_t rf_phy_channel = 0;
/* Channel configurations for 2.4 */
static const phy_rf_channel_configuration_s phy_24ghz = {2405000000U, 5000000U, 250000U, 16U, M_OQPSK};
static const phy_device_channel_page_s phy_channel_pages[] = {
{ CHANNEL_PAGE_0, &phy_24ghz},
{ CHANNEL_PAGE_0, NULL}
};
static rf_trx_part_e rf_radio_type_read(void);
MBED_UNUSED static void rf_ack_wait_timer_start(uint16_t slots);
MBED_UNUSED static void rf_ack_wait_timer_stop(void);
MBED_UNUSED static void rf_handle_cca_ed_done(void);
MBED_UNUSED static void rf_handle_tx_end(void);
MBED_UNUSED static void rf_handle_rx_end(void);
MBED_UNUSED static void rf_on(void);
MBED_UNUSED static void rf_receive(void);
MBED_UNUSED static void rf_poll_trx_state_change(rf_trx_states_t trx_state);
MBED_UNUSED static void rf_init(void);
MBED_UNUSED static void rf_set_mac_address(const uint8_t *ptr);
MBED_UNUSED static int8_t rf_device_register(void);
MBED_UNUSED static void rf_device_unregister(void);
MBED_UNUSED static int8_t rf_start_cca(uint8_t *data_ptr, uint16_t data_length, uint8_t tx_handle, data_protocol_e data_protocol );
MBED_UNUSED static void rf_cca_abort(void);
MBED_UNUSED static void rf_read_mac_address(uint8_t *ptr);
MBED_UNUSED static int8_t rf_read_random(void);
MBED_UNUSED static void rf_calibration_cb(void);
MBED_UNUSED static void rf_init_phy_mode(void);
MBED_UNUSED static void rf_ack_wait_timer_interrupt(void);
MBED_UNUSED static void rf_calibration_timer_interrupt(void);
MBED_UNUSED static void rf_calibration_timer_start(uint32_t slots);
MBED_UNUSED static void rf_cca_timer_interrupt(void);
MBED_UNUSED static void rf_cca_timer_start(uint32_t slots);
MBED_UNUSED static uint16_t rf_get_phy_mtu_size(void);
MBED_UNUSED static uint8_t rf_scale_lqi(int8_t rssi);
/**
* RF output power write
*
* \brief TX power has to be set before network start.
*
* \param power
* See datasheet for TX power settings
*
* \return 0, Supported Value
* \return -1, Not Supported Value
*/
MBED_UNUSED static int8_t rf_tx_power_set(uint8_t power);
MBED_UNUSED static uint8_t rf_tx_power_get(void);
MBED_UNUSED static int8_t rf_enable_antenna_diversity(void);
/* Private functions */
MBED_UNUSED static void rf_abort(void);
MBED_UNUSED static void rf_promiscuous(uint8_t mode);
MBED_UNUSED static void rf_get_timestamp(uint32_t *pRetClk);
MBED_UNUSED static void rf_set_timeout(uint32_t *pEndTime);
MBED_UNUSED static void rf_set_power_state(xcvrPwrMode_t newState);
MBED_UNUSED static uint8_t rf_if_read_rnd(void);
MBED_UNUSED static uint8_t rf_convert_LQI(uint8_t hwLqi);
MBED_UNUSED static uint8_t rf_get_channel_energy(void);
MBED_UNUSED static uint8_t rf_convert_energy_level(uint8_t energyLevel);
MBED_UNUSED static int8_t rf_convert_LQI_to_RSSI(uint8_t lqi);
MBED_UNUSED static int8_t rf_interface_state_control(phy_interface_state_e new_state, uint8_t rf_channel);
MBED_UNUSED static int8_t rf_extension(phy_extension_type_e extension_type,uint8_t *data_ptr);
MBED_UNUSED static int8_t rf_address_write(phy_address_type_e address_type,uint8_t *address_ptr);
MBED_UNUSED static void rf_mac64_read(uint8_t *address);
/*
* \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)
{
return FREESCALE_MCR20A;
}
/*
* \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(void)
{
rf_trx_part_e radio_type;
rf_init();
radio_type = rf_radio_type_read();
if(radio_type == FREESCALE_MCR20A)
{
/*Set pointer to MAC address*/
device_driver.PHY_MAC = MAC_address;
device_driver.driver_description = (char*)"FREESCALE_MAC";
//Create setup Used Radio chips
/*Type of RF PHY is SubGHz*/
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;
/*Upper layer callbacks init to NULL*/
device_driver.phy_rx_cb = NULL;
device_driver.phy_tx_done_cb = NULL;
/*Virtual upper data callback init to NULL*/
device_driver.arm_net_virtual_rx_cb = NULL;
device_driver.arm_net_virtual_tx_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(void)
{
arm_net_phy_unregister(rf_radio_driver_id);
}
/*
* \brief Function returns the generated 8-bit random value for seeding Pseudo-random generator.
*
* \param none
*
* \return random value
*/
static int8_t rf_read_random(void)
{
return rf_rnd;
}
/*
* \brief Function is a call back for ACK wait timeout.
*
* \param none
*
* \return none
*/
static void rf_ack_wait_timer_interrupt(void)
{
/* The packet was transmitted successfully, but no ACK was received */
if (device_driver.phy_tx_done_cb) {
device_driver.phy_tx_done_cb(rf_radio_driver_id, mac_tx_handle, PHY_LINK_TX_SUCCESS, 1, 1);
}
rf_receive();
}
/*
* \brief Function is a call back for calibration interval timer.
*
* \param none
*
* \return none
*/
static void rf_calibration_timer_interrupt(void)
{
}
/*
* \brief Function is a call back for cca interval timer.
*
* \param none
*
* \return none
*/
static void rf_cca_timer_interrupt(void)
{
/* CCA time-out handled by Hardware */
}
/*
* \brief Function starts the ACK wait time-out.
*
* \param slots The ACK wait time-out in [symbols]
*
* \return none
*/
static void rf_ack_wait_timer_start(uint16_t time)
{
uint32_t timeout;
rf_get_timestamp(&timeout);
timeout += time;
rf_set_timeout(&timeout);
}
/*
* \brief Function starts the calibration interval.
*
* \param slots Given slots, resolution 50us
*
* \return none
*/
static void rf_calibration_timer_start(uint32_t slots)
{
(void)slots;
}
/*
* \brief Function starts the CCA timout.
*
* \param slots Given slots, resolution 50us
*
* \return none
*/
static void rf_cca_timer_start(uint32_t slots)
{
(void)slots;
}
/*
* \brief Function stops the ACK wait timeout.
*
* \param none
*
* \return none
*/
static void rf_ack_wait_timer_stop(void)
{
}
/*
* \brief Function reads the MAC address array.
*
* \param ptr Pointer to read array
*
* \return none
*/
static void rf_read_mac_address(uint8_t *ptr)
{
memcpy(ptr, MAC_address, 8);
}
/*
* \brief Function sets the MAC address array.
*
* \param ptr Pointer to given MAC address array
*
* \return none
*/
static void rf_set_mac_address(const uint8_t *ptr)
{
memcpy(MAC_address, ptr, 8);
}
static uint16_t rf_get_phy_mtu_size(void)
{
return device_driver.phy_MTU;
}
/*
* \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)
{
/* Write one register at a time to be accessible from hibernate mode */
MCR20Drv_IndirectAccessSPIWrite(MACSHORTADDRS0_MSB, short_address[0]);
MCR20Drv_IndirectAccessSPIWrite(MACSHORTADDRS0_LSB, short_address[1]);
}
/*
* \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)
{
/* Write one register at a time to be accessible from hibernate mode */
MCR20Drv_IndirectAccessSPIWrite(MACPANID0_MSB, pan_id[0]);
MCR20Drv_IndirectAccessSPIWrite(MACPANID0_LSB, pan_id[1]);
}
/*
* \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)
{
/* Write one register at a time to be accessible from hibernate mode */
MCR20Drv_IndirectAccessSPIWrite(MACLONGADDRS0_0, address[7]);
MCR20Drv_IndirectAccessSPIWrite(MACLONGADDRS0_8, address[6]);
MCR20Drv_IndirectAccessSPIWrite(MACLONGADDRS0_16, address[5]);
MCR20Drv_IndirectAccessSPIWrite(MACLONGADDRS0_24, address[4]);
MCR20Drv_IndirectAccessSPIWrite(MACLONGADDRS0_32, address[3]);
MCR20Drv_IndirectAccessSPIWrite(MACLONGADDRS0_40, address[2]);
MCR20Drv_IndirectAccessSPIWrite(MACLONGADDRS0_48, address[1]);
MCR20Drv_IndirectAccessSPIWrite(MACLONGADDRS0_56, address[0]);
}
/*
* \brief Function sets the RF channel.
*
* \param ch New channel
*
* \return none
*/
static void rf_channel_set(uint8_t channel)
{
rf_phy_channel = channel;
MCR20Drv_DirectAccessSPIWrite(PLL_INT0, pll_int[channel - 11]);
MCR20Drv_DirectAccessSPIMultiByteWrite(PLL_FRAC0_LSB, (uint8_t *) &pll_frac[channel - 11], 2);
}
/*
* \brief Function initialises the radio driver and resets the radio.
*
* \param none
*
* \return none
*/
static void rf_init(void)
{
uint32_t index;
mPhySeqState = gIdle_c;
mPwrState = gXcvrPwrIdle_c;
/*Reset RF module*/
MCR20Drv_RESET();
/* Initialize the transceiver SPI driver */
MCR20Drv_Init();
/* Disable Tristate on MISO for SPI reads */
MCR20Drv_IndirectAccessSPIWrite(MISC_PAD_CTRL, 0x02);
/* Set XCVR clock output settings */
MCR20Drv_Set_CLK_OUT_Freq(gMCR20_ClkOutFreq_d);
/* Set default XCVR power state */
rf_set_power_state(gXcvrRunState_d);
/* PHY_CTRL1 default HW settings + AUTOACK enabled */
mStatusAndControlRegs[PHY_CTRL1] = cPHY_CTRL1_AUTOACK;
/* PHY_CTRL2 : mask all PP interrupts */
mStatusAndControlRegs[PHY_CTRL2] = cPHY_CTRL2_CRC_MSK | \
cPHY_CTRL2_PLL_UNLOCK_MSK | \
/*cPHY_CTRL2_FILTERFAIL_MSK | */ \
cPHY_CTRL2_RX_WMRK_MSK | \
cPHY_CTRL2_CCAMSK | \
cPHY_CTRL2_RXMSK | \
cPHY_CTRL2_TXMSK | \
cPHY_CTRL2_SEQMSK;
/* PHY_CTRL3 : enable timer 3 and disable remaining interrupts */
mStatusAndControlRegs[PHY_CTRL3] = cPHY_CTRL3_ASM_MSK | \
cPHY_CTRL3_PB_ERR_MSK | \
cPHY_CTRL3_WAKE_MSK | \
cPHY_CTRL3_TMR3CMP_EN;
/* PHY_CTRL4 unmask global TRX interrupts, enable 16 bit mode for TC2 - TC2 prime EN */
mStatusAndControlRegs[PHY_CTRL4] = cPHY_CTRL4_TC2PRIME_EN | (gCcaCCA_MODE1_c << cPHY_CTRL4_CCATYPE_Shift_c);
/* Clear all PP IRQ bits to avoid unexpected interrupts immediately after initialization */
mStatusAndControlRegs[IRQSTS1] = cIRQSTS1_PLL_UNLOCK_IRQ | \
cIRQSTS1_FILTERFAIL_IRQ | \
cIRQSTS1_RXWTRMRKIRQ | \
cIRQSTS1_CCAIRQ | \
cIRQSTS1_RXIRQ | \
cIRQSTS1_TXIRQ | \
cIRQSTS1_SEQIRQ;
mStatusAndControlRegs[IRQSTS2] = cIRQSTS2_ASM_IRQ | cIRQSTS2_PB_ERR_IRQ | cIRQSTS2_WAKE_IRQ;
/* Mask and clear all TMR IRQs */
mStatusAndControlRegs[IRQSTS3] = cIRQSTS3_TMR4MSK | cIRQSTS3_TMR3MSK | cIRQSTS3_TMR2MSK | cIRQSTS3_TMR1MSK | \
cIRQSTS3_TMR4IRQ | cIRQSTS3_TMR3IRQ | cIRQSTS3_TMR2IRQ | cIRQSTS3_TMR1IRQ;
/* Write settings to XCVR */
MCR20Drv_DirectAccessSPIMultiByteWrite(PHY_CTRL1, &mStatusAndControlRegs[PHY_CTRL1], 5);
/* Clear all interrupts */
MCR20Drv_DirectAccessSPIMultiByteWrite(IRQSTS1, &mStatusAndControlRegs[IRQSTS1], 3);
/* RX_FRAME_FILTER. Accept FrameVersion 0 and 1 packets, reject all others */
MCR20Drv_IndirectAccessSPIWrite(RX_FRAME_FILTER, (cRX_FRAME_FLT_FRM_VER | \
cRX_FRAME_FLT_BEACON_FT | \
cRX_FRAME_FLT_DATA_FT | \
cRX_FRAME_FLT_CMD_FT ));
/* Direct register overwrites */
for (index = 0; index < sizeof(overwrites_direct)/sizeof(overwrites_t); index++)
MCR20Drv_DirectAccessSPIWrite(overwrites_direct[index].address, overwrites_direct[index].data);
/* Indirect register overwrites */
for (index = 0; index < sizeof(overwrites_indirect)/sizeof(overwrites_t); index++)
MCR20Drv_IndirectAccessSPIWrite(overwrites_indirect[index].address, overwrites_indirect[index].data);
/* Set the CCA energy threshold value */
MCR20Drv_IndirectAccessSPIWrite(CCA1_THRESH, RF_CCA_THRESHOLD);
/* Set prescaller to obtain 1 symbol (16us) timebase */
MCR20Drv_IndirectAccessSPIWrite(TMR_PRESCALE, 0x05);
MCR20Drv_IRQ_Enable();
/*Read random variable. This will be used when seeding pseudo-random generator*/
rf_rnd = rf_if_read_rnd();
/*Read eui64*/
rf_mac64_read(MAC_address);
/*set default channel to 11*/
rf_channel_set(11);
/*Start receiver*/
rf_receive();
}
/**
* \brief Function gets called when MAC is setting radio off.
*
* \param none
*
* \return none
*/
static void rf_off(void)
{
/* Abort any ongoing sequences */
rf_abort();
/* Set XCVR in a low power state */
rf_set_power_state(gXcvrLowPowerState_d);
}
/*
* \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)
{
(void)trx_state;
}
/*
* \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 )
{
uint8_t ccaMode;
/* Parameter validation */
if( !data_ptr || (data_length > 125) || (PHY_LAYER_PAYLOAD != data_protocol) )
{
return -1;
}
if( mPhySeqState == gRX_c )
{
uint8_t phyReg = MCR20Drv_DirectAccessSPIRead(SEQ_STATE) & 0x1F;
/* Check for an Rx in progress. */
if((phyReg <= 0x06) || (phyReg == 0x15) || (phyReg == 0x16))
{
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);
}
return -1;
}
rf_abort();
}
/*Check if transmitter is busy*/
if( mPhySeqState != gIdle_c )
{
/*Return busy*/
return -1;
}
/*Store TX handle*/
mac_tx_handle = tx_handle;
/*Check if transmitted data needs to be acked*/
need_ack = (*data_ptr & 0x20) == 0x20;
/* Set XCVR power state in run mode */
rf_set_power_state(gXcvrRunState_d);
/* Load data into XCVR */
tx_len = data_length + 2;
MCR20Drv_PB_SPIBurstWrite(data_ptr - 1, data_length + 1);
MCR20Drv_PB_SPIByteWrite(0,tx_len);
/* Set CCA mode 1 */
ccaMode = (mStatusAndControlRegs[PHY_CTRL4] >> cPHY_CTRL4_CCATYPE_Shift_c) & cPHY_CTRL4_CCATYPE;
if( ccaMode != gCcaCCA_MODE1_c )
{
mStatusAndControlRegs[PHY_CTRL4] &= ~(cPHY_CTRL4_CCATYPE << cPHY_CTRL4_CCATYPE_Shift_c);
mStatusAndControlRegs[PHY_CTRL4] |= gCcaCCA_MODE1_c << cPHY_CTRL4_CCATYPE_Shift_c;
MCR20Drv_DirectAccessSPIWrite(PHY_CTRL4, mStatusAndControlRegs[PHY_CTRL4]);
}
/* Read XCVR registers */
mStatusAndControlRegs[0] = MCR20Drv_DirectAccessSPIMultiByteRead(IRQSTS2, &mStatusAndControlRegs[1], 4);
mStatusAndControlRegs[PHY_CTRL1] &= ~(cPHY_CTRL1_XCVSEQ);
mStatusAndControlRegs[PHY_CTRL1] |= gCCA_c;
mPhySeqState = gCCA_c;
/* Ensure that no spurious interrupts are raised */
mStatusAndControlRegs[IRQSTS3] &= 0xF0; /* do not change other IRQ status */
mStatusAndControlRegs[IRQSTS3] |= (cIRQSTS3_TMR3MSK | cIRQSTS3_TMR3IRQ);
MCR20Drv_DirectAccessSPIMultiByteWrite(IRQSTS1, mStatusAndControlRegs, 3);
/* Write XCVR settings */
MCR20Drv_DirectAccessSPIWrite(PHY_CTRL1, mStatusAndControlRegs[PHY_CTRL1]);
/* Unmask SEQ interrupt */
mStatusAndControlRegs[PHY_CTRL2] &= ~(cPHY_CTRL2_SEQMSK);
MCR20Drv_DirectAccessSPIWrite(PHY_CTRL2, mStatusAndControlRegs[PHY_CTRL2]);
/*Return success*/
return 0;
}
/*
* \brief Function aborts CCA process.
*
* \param none
*
* \return none
*/
static void rf_cca_abort(void)
{
rf_abort();
}
/*
* \brief Function starts the transmission of the frame. Called from ISR context!
*
* \param none
*
* \return none
*/
static void rf_start_tx(void)
{
/* Perform TxRxAck sequence if required by phyTxMode */
if( need_ack )
{
mStatusAndControlRegs[PHY_CTRL1] |= cPHY_CTRL1_RXACKRQD;
mPhySeqState = gTR_c;
}
else
{
mStatusAndControlRegs[PHY_CTRL1] &= ~(cPHY_CTRL1_RXACKRQD);
mPhySeqState = gTX_c;
}
mStatusAndControlRegs[PHY_CTRL1] &= ~(cPHY_CTRL1_XCVSEQ);
mStatusAndControlRegs[PHY_CTRL1] |= mPhySeqState;
/* Unmask SEQ interrupt */
mStatusAndControlRegs[PHY_CTRL2] &= ~(cPHY_CTRL2_SEQMSK);
/* Start the sequence immediately */
MCR20Drv_DirectAccessSPIMultiByteWrite(PHY_CTRL1, &mStatusAndControlRegs[PHY_CTRL1], 2);
if( need_ack )
{
rf_ack_wait_timer_start(gPhyWarmUpTime_c + gPhySHRDuration_c + tx_len * gPhySymbolsPerOctet_c + gPhyAckWaitDuration_c);
}
}
/*
* \brief Function sets the RF in RX state. Called from ISR context!
*
* \param none
*
* \return none
*/
static void rf_receive(void)
{
uint8_t phyRegs[5];
/* RX can start only from Idle state */
if( mPhySeqState != gIdle_c )
{
return;
}
/* Set XCVR power state in run mode */
rf_set_power_state(gXcvrRunState_d);
/* read XVCR settings */
phyRegs[IRQSTS1] = MCR20Drv_DirectAccessSPIMultiByteRead(IRQSTS2, &phyRegs[IRQSTS2], 4);
/* unmask SEQ interrupt */
phyRegs[PHY_CTRL2] &= ~(cPHY_CTRL2_SEQMSK);
/* set XcvrSeq to RX */
phyRegs[PHY_CTRL1] &= ~(cPHY_CTRL1_XCVSEQ);
phyRegs[PHY_CTRL1] |= gRX_c;
mPhySeqState = gRX_c;
/* Ensure that no spurious interrupts are raised */
phyRegs[IRQSTS3] &= 0xF0; /* do not change other IRQ status */
phyRegs[IRQSTS3] |= cIRQSTS3_TMR3MSK | cIRQSTS3_TMR3IRQ;
/* sync settings with XCVR */
MCR20Drv_DirectAccessSPIMultiByteWrite(IRQSTS1, phyRegs, 5);
}
/*
* \brief Function calibrates the radio.
*
* \param none
*
* \return none
*/
static void rf_calibration_cb(void)
{
}
/*
* \brief Function sets RF_ON flag when radio is powered.
*
* \param none
*
* \return none
*/
static void rf_on(void)
{
}
/*
* \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 = MCR20Drv_DirectAccessSPIRead(LQI_VALUE);
int8_t rf_rssi = 0;
uint8_t len = mStatusAndControlRegs[RX_FRM_LEN] - 2;
/*Start receiver*/
rf_receive();
/*Check the length is valid*/
if(len > 1 && len < RF_BUFFER_SIZE)
{
rf_lqi = rf_convert_LQI(rf_lqi);
rf_rssi = rf_convert_LQI_to_RSSI(rf_lqi);
/*gcararu: Scale LQI using received RSSI, to match the LQI reported by the ATMEL radio */
rf_lqi = rf_scale_lqi(rf_rssi);
/*Read received packet*/
MCR20Drv_PB_SPIBurstRead(rf_buffer, len);
if (device_driver.phy_rx_cb) {
device_driver.phy_rx_cb(rf_buffer, len, 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)
{
uint8_t rx_frame_pending = mStatusAndControlRegs[IRQSTS1] & cIRQSTS1_RX_FRM_PEND;
/*Start receiver*/
rf_receive();
if (!device_driver.phy_tx_done_cb) {
return;
}
/*Call PHY TX Done API*/
if( need_ack )
{
if( rx_frame_pending )
{
device_driver.phy_tx_done_cb(rf_radio_driver_id, mac_tx_handle, PHY_LINK_TX_DONE_PENDING, 1, 1);
}
else
{
// arm_net_phy_tx_done(rf_radio_driver_id, mac_tx_handle, PHY_LINK_TX_SUCCESS, 1, 1);
device_driver.phy_tx_done_cb(rf_radio_driver_id, mac_tx_handle, PHY_LINK_TX_DONE, 1, 1);
}
}
else
{
device_driver.phy_tx_done_cb(rf_radio_driver_id, mac_tx_handle, PHY_LINK_TX_SUCCESS, 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)
{
/*Check the result of CCA process*/
if( !(mStatusAndControlRegs[IRQSTS2] & cIRQSTS2_CCA) )
{
rf_start_tx();
}
else if (device_driver.phy_tx_done_cb)
{
/*Send CCA fail notification*/
device_driver.phy_tx_done_cb(rf_radio_driver_id, mac_tx_handle, PHY_LINK_CCA_FAIL, 1, 1);
}
}
/*
* \brief Function sets the TX power variable.
*
* \param power TX power setting
*
* \return 0 Success
* \return -1 Fail
*/
static int8_t rf_tx_power_set(uint8_t power)
{
/* gcapraru: Map MCR20A Tx power levels over ATMEL values */
static uint8_t pwrLevelMapping[16] = {25,25,25,24,24,24,23,23,22,22,21,20,19,18,17,14};
if( power > 15 )
{
return -1;
}
radio_tx_power = power;
MCR20Drv_DirectAccessSPIWrite(PA_PWR, pwrLevelMapping[power]);
return 0;
}
/*
* \brief Function returns the TX power variable.
*
* \param none
*
* \return radio_tx_power TX power variable
*/
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
*/
static int8_t rf_enable_antenna_diversity(void)
{
uint8_t phyReg;
phyReg = MCR20Drv_IndirectAccessSPIRead(ANT_AGC_CTRL);
phyReg |= cANT_AGC_CTRL_FAD_EN_Mask_c;
MCR20Drv_IndirectAccessSPIWrite(ANT_AGC_CTRL, phyReg);
phyReg = MCR20Drv_IndirectAccessSPIRead(ANT_PAD_CTRL);
phyReg |= 0x02;
MCR20Drv_IndirectAccessSPIWrite(ANT_PAD_CTRL, phyReg);
return 0;
}
/*
* \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_channel_set(rf_channel);
rf_receive();
break;
/*Enable wireless interface ED scan mode*/
case PHY_INTERFACE_RX_ENERGY_STATE:
rf_abort();
rf_channel_set(rf_channel);
break;
case PHY_INTERFACE_SNIFFER_STATE: /**< Enable Sniffer state */
rf_promiscuous(1);
rf_channel_set(rf_channel);
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:
{
uint8_t reg = MCR20Drv_DirectAccessSPIRead(SRC_CTRL);
if(*data_ptr)
{
reg |= cSRC_CTRL_ACK_FRM_PND;
}
else
{
reg &= ~cSRC_CTRL_ACK_FRM_PND;
}
MCR20Drv_DirectAccessSPIWrite(SRC_CTRL, reg);
break;
}
/*Return frame pending status*/
case PHY_EXTENSION_READ_LAST_ACK_PENDING_STATUS:
*data_ptr = MCR20Drv_DirectAccessSPIRead(IRQSTS1 & cIRQSTS1_RX_FRM_PEND);
break;
/*Set channel*/
case PHY_EXTENSION_SET_CHANNEL:
break;
/*Read energy on the channel*/
case PHY_EXTENSION_READ_CHANNEL_ENERGY:
*data_ptr = rf_get_channel_energy();
break;
/*Read status of the link*/
case PHY_EXTENSION_READ_LINK_STATUS:
break;
case PHY_EXTENSION_CONVERT_SIGNAL_INFO:
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;
}
static void rf_mac64_read(uint8_t *address)
{
/* Write one register at a time to be accessible from hibernate mode */
address[7] = MCR20Drv_DirectAccessSPIRead(MACLONGADDRS0_0);
address[6] = MCR20Drv_DirectAccessSPIRead(MACLONGADDRS0_8);
address[5] = MCR20Drv_DirectAccessSPIRead(MACLONGADDRS0_16);
address[4] = MCR20Drv_DirectAccessSPIRead(MACLONGADDRS0_24);
address[3] = MCR20Drv_DirectAccessSPIRead(MACLONGADDRS0_32);
address[2] = MCR20Drv_DirectAccessSPIRead(MACLONGADDRS0_40);
address[1] = MCR20Drv_DirectAccessSPIRead(MACLONGADDRS0_48);
address[0] = MCR20Drv_DirectAccessSPIRead(MACLONGADDRS0_56);
}
/*
* \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)
{
}
/*
* \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 PHY_InterruptHandler(void)
{
uint8_t xcvseqCopy;
/* Disable and clear transceiver(IRQ_B) interrupt */
MCR20Drv_IRQ_Disable();
//MCR20Drv_IRQ_Clear();
/* Read transceiver interrupt status and control registers */
mStatusAndControlRegs[IRQSTS1] =
MCR20Drv_DirectAccessSPIMultiByteRead(IRQSTS2, &mStatusAndControlRegs[IRQSTS2], 7);
xcvseqCopy = mStatusAndControlRegs[PHY_CTRL1] & cPHY_CTRL1_XCVSEQ;
/* Flter Fail IRQ */
if( (mStatusAndControlRegs[IRQSTS1] & cIRQSTS1_FILTERFAIL_IRQ) &&
!(mStatusAndControlRegs[PHY_CTRL2] & cPHY_CTRL2_FILTERFAIL_MSK) )
{
if( xcvseqCopy == gRX_c )
{
/* Abort current SEQ */
mStatusAndControlRegs[PHY_CTRL1] &= ~(cPHY_CTRL1_XCVSEQ);
MCR20Drv_DirectAccessSPIWrite(PHY_CTRL1, mStatusAndControlRegs[PHY_CTRL1]);
/* Wait for Sequence Idle */
while ((MCR20Drv_DirectAccessSPIRead(SEQ_STATE) & 0x1F) != 0);
/* Clear IRQ flags: */
MCR20Drv_DirectAccessSPIWrite(IRQSTS1, cIRQSTS1_SEQIRQ);
/* Restart Rx asap */
mStatusAndControlRegs[PHY_CTRL1] |= gRX_c;
MCR20Drv_DirectAccessSPIWrite(PHY_CTRL1, mStatusAndControlRegs[PHY_CTRL1]);
}
}
/* TMR3 IRQ: ACK wait time-out */
if( (mStatusAndControlRegs[IRQSTS3] & cIRQSTS3_TMR3IRQ) &&
!(mStatusAndControlRegs[IRQSTS3] & cIRQSTS3_TMR3MSK) )
{
/* Disable TMR3 IRQ */
mStatusAndControlRegs[IRQSTS3] |= cIRQSTS3_TMR3MSK;
if( xcvseqCopy == gTR_c )
{
/* Set XCVR to Idle */
mPhySeqState = gIdle_c;
mStatusAndControlRegs[PHY_CTRL1] &= ~( cPHY_CTRL1_XCVSEQ );
/* Mask interrupts */
mStatusAndControlRegs[PHY_CTRL2] |= cPHY_CTRL2_CCAMSK | cPHY_CTRL2_RXMSK | cPHY_CTRL2_TXMSK | cPHY_CTRL2_SEQMSK;
/* Sync settings with XCVR */
MCR20Drv_DirectAccessSPIMultiByteWrite(IRQSTS1, mStatusAndControlRegs, 5);
rf_ack_wait_timer_interrupt();
MCR20Drv_IRQ_Enable();
return;
}
}
/* Sequencer interrupt, the autosequence has completed */
if( (mStatusAndControlRegs[IRQSTS1] & cIRQSTS1_SEQIRQ) &&
!(mStatusAndControlRegs[PHY_CTRL2] & cPHY_CTRL2_SEQMSK) )
{
/* Set XCVR to Idle */
mPhySeqState = gIdle_c;
mStatusAndControlRegs[PHY_CTRL1] &= ~( cPHY_CTRL1_XCVSEQ );
/* Mask interrupts */
mStatusAndControlRegs[PHY_CTRL2] |= cPHY_CTRL2_CCAMSK | cPHY_CTRL2_RXMSK | cPHY_CTRL2_TXMSK | cPHY_CTRL2_SEQMSK;
/* Sync settings with XCVR */
MCR20Drv_DirectAccessSPIMultiByteWrite(IRQSTS1, mStatusAndControlRegs, 5);
/* PLL unlock, the autosequence has been aborted due to PLL unlock */
if( mStatusAndControlRegs[IRQSTS1] & cIRQSTS1_PLL_UNLOCK_IRQ )
{
if(xcvseqCopy == gRX_c)
{
rf_receive();
}
MCR20Drv_IRQ_Enable();
return;
}
switch(xcvseqCopy)
{
case gTX_c:
case gTR_c:
rf_handle_tx_end();
break;
case gRX_c:
rf_handle_rx_end();
break;
case gCCA_c:
rf_handle_cca_ed_done();
break;
default:
break;
}
MCR20Drv_IRQ_Enable();
return;
}
/* Other IRQ. Clear XCVR interrupt flags */
MCR20Drv_DirectAccessSPIMultiByteWrite(IRQSTS1, mStatusAndControlRegs, 3);
MCR20Drv_IRQ_Enable();
}
/*
* \brief Function forces the XCVR to Idle state.
*
* \param none
*
* \return none
*/
static void rf_abort(void)
{
/* Mask XCVR irq */
MCR20Drv_IRQ_Disable();
mPhySeqState = gIdle_c;
mStatusAndControlRegs[IRQSTS1] = MCR20Drv_DirectAccessSPIMultiByteRead(IRQSTS2, &mStatusAndControlRegs[IRQSTS2], 5);
/* Mask SEQ interrupt */
mStatusAndControlRegs[PHY_CTRL2] |= cPHY_CTRL2_SEQMSK;
MCR20Drv_DirectAccessSPIWrite(PHY_CTRL2, mStatusAndControlRegs[PHY_CTRL2]);
if( (mStatusAndControlRegs[PHY_CTRL1] & cPHY_CTRL1_XCVSEQ) != gIdle_c )
{
/* Abort current SEQ */
mStatusAndControlRegs[PHY_CTRL1] &= ~(cPHY_CTRL1_XCVSEQ);
MCR20Drv_DirectAccessSPIWrite(PHY_CTRL1, mStatusAndControlRegs[PHY_CTRL1]);
/* Wait for Sequence Idle (if not already) */
while ((MCR20Drv_DirectAccessSPIRead(SEQ_STATE) & 0x1F) != 0);
//while ( !(MCR20Drv_DirectAccessSPIRead(IRQSTS1) & cIRQSTS1_SEQIRQ));
mStatusAndControlRegs[IRQSTS1] |= cIRQSTS1_SEQIRQ;
}
/* Clear all PP IRQ bits to avoid unexpected interrupts and mask TMR3 interrupt.
Do not change TMR IRQ status. */
mStatusAndControlRegs[IRQSTS3] &= 0xF0;
mStatusAndControlRegs[IRQSTS3] |= (cIRQSTS3_TMR3MSK | cIRQSTS3_TMR3IRQ);
MCR20Drv_DirectAccessSPIMultiByteWrite(IRQSTS1, mStatusAndControlRegs, 3);
/* Unmask XCVR irq */
MCR20Drv_IRQ_Enable();
}
/*
* \brief Function reads a time-stamp value from XCVR [symbols]
*
* \param pEndTime pointer to location where time-stamp will be stored
*
* \return none
*/
static void rf_get_timestamp(uint32_t *pRetClk)
{
if(NULL == pRetClk)
{
return;
}
platform_enter_critical();
*pRetClk = 0;
MCR20Drv_DirectAccessSPIMultiByteRead(EVENT_TMR_LSB, (uint8_t *) pRetClk, 3);
platform_exit_critical();
}
/*
* \brief Function set a time-out to an XCVR sequence.
*
* \param pEndTime pointer to the sequence time-out value [symbols]
*
* \return none
*/
static void rf_set_timeout(uint32_t *pEndTime)
{
uint8_t phyReg;
if(NULL == pEndTime)
{
return;
}
platform_enter_critical();
phyReg = MCR20Drv_DirectAccessSPIRead(IRQSTS3);
phyReg &= 0xF0; /* do not change IRQ status */
phyReg |= (cIRQSTS3_TMR3MSK); /* mask TMR3 interrupt */
MCR20Drv_DirectAccessSPIWrite(IRQSTS3, phyReg);
MCR20Drv_DirectAccessSPIMultiByteWrite(T3CMP_LSB, (uint8_t *) pEndTime, 3);
phyReg &= ~(cIRQSTS3_TMR3MSK); /* unmask TMR3 interrupt */
phyReg |= (cIRQSTS3_TMR3IRQ); /* aknowledge TMR3 IRQ */
MCR20Drv_DirectAccessSPIWrite(IRQSTS3, phyReg);
platform_exit_critical();
}
/*
* \brief Function reads a random number from RF.
*
* \param none
*
* \return 8-bit random number
*/
static uint8_t rf_if_read_rnd(void)
{
uint8_t phyReg;
MCR20Drv_IRQ_Disable();
/* Check if XCVR is idle */
phyReg = MCR20Drv_DirectAccessSPIRead(PHY_CTRL1);
if( (phyReg & cPHY_CTRL1_XCVSEQ) == gIdle_c )
{
/* Program a new sequence */
MCR20Drv_DirectAccessSPIWrite(PHY_CTRL1, phyReg | gCCA_c);
/* Wait for sequence to finish */
while( !(MCR20Drv_DirectAccessSPIRead(IRQSTS1) & cIRQSTS1_SEQIRQ) );
/* Clear interrupt flag */
MCR20Drv_DirectAccessSPIWrite(IRQSTS1, cIRQSTS1_SEQIRQ);
}
MCR20Drv_IRQ_Enable();
return MCR20Drv_IndirectAccessSPIRead(_RNG);
}
/*
* \brief Function converts LQI into RSSI.
*
* \param LQI
*
* \return RSSI
*/
static int8_t rf_convert_LQI_to_RSSI(uint8_t lqi)
{
int32_t rssi = (50*lqi - 16820) / 163;
return (int8_t)rssi;
}
/*
* \brief Function scale the LQI value reported by RF into a 0-255 value.
*
* \param hwLqi - the LQI value reported by RF
*
* \return scaled LQI
*/
static uint8_t rf_convert_LQI(uint8_t hwLqi)
{
uint32_t tmpLQI;
/* LQI Saturation Level */
if (hwLqi >= 230)
{
return 0xFF;
}
else if (hwLqi <= 9)
{
return 0;
}
else
{
/* Rescale the LQI values from min to saturation to the 0x00 - 0xFF range */
/* The LQI value mst be multiplied by ~1.1087 */
/* tmpLQI = hwLqi * 7123 ~= hwLqi * 65536 * 0.1087 = hwLqi * 2^16 * 0.1087*/
tmpLQI = ((uint32_t)hwLqi * (uint32_t)7123 );
/* tmpLQI = (tmpLQI / 2^16) + hwLqi */
tmpLQI = (uint32_t)(tmpLQI >> 16) + (uint32_t)hwLqi;
return (uint8_t)tmpLQI;
}
}
/*
* \brief Function enables/disables Rx promiscuous mode.
*
* \param state of XCVR promiscuous mode
*
* \return none
*/
static void rf_promiscuous(uint8_t state)
{
uint8_t rxFrameFltReg, phyCtrl4Reg;
rxFrameFltReg = MCR20Drv_IndirectAccessSPIRead(RX_FRAME_FILTER);
phyCtrl4Reg = MCR20Drv_DirectAccessSPIRead(PHY_CTRL4);
if( state )
{
/* FRM_VER[1:0] = b00. 00: Any FrameVersion accepted (0,1,2 & 3) */
/* All frame types accepted*/
phyCtrl4Reg |= cPHY_CTRL4_PROMISCUOUS;
rxFrameFltReg &= ~(cRX_FRAME_FLT_FRM_VER);
rxFrameFltReg |= (cRX_FRAME_FLT_ACK_FT | cRX_FRAME_FLT_NS_FT);
}
else
{
phyCtrl4Reg &= ~cPHY_CTRL4_PROMISCUOUS;
/* FRM_VER[1:0] = b11. Accept FrameVersion 0 and 1 packets, reject all others */
/* Beacon, Data and MAC command frame types accepted */
rxFrameFltReg &= ~(cRX_FRAME_FLT_FRM_VER);
rxFrameFltReg |= (0x03 << cRX_FRAME_FLT_FRM_VER_Shift_c);
rxFrameFltReg &= ~(cRX_FRAME_FLT_ACK_FT | cRX_FRAME_FLT_NS_FT);
}
MCR20Drv_IndirectAccessSPIWrite(RX_FRAME_FILTER, rxFrameFltReg);
MCR20Drv_DirectAccessSPIWrite(PHY_CTRL4, phyCtrl4Reg);
}
/*
* \brief Function used to switch XCVR power state.
*
* \param state The XCVR power mode
*
* \return none
*/
static void rf_set_power_state(xcvrPwrMode_t newState)
{
uint8_t pwrMode;
uint8_t xtalState;
if( mPwrState == newState )
{
return;
}
/* Read power settings from RF */
pwrMode = MCR20Drv_DirectAccessSPIRead(PWR_MODES);
xtalState = pwrMode & cPWR_MODES_XTALEN;
switch( newState )
{
case gXcvrPwrIdle_c:
pwrMode &= ~(cPWR_MODES_AUTODOZE);
pwrMode |= (cPWR_MODES_XTALEN | cPWR_MODES_PMC_MODE);
break;
case gXcvrPwrAutodoze_c:
pwrMode |= (cPWR_MODES_XTALEN | cPWR_MODES_AUTODOZE | cPWR_MODES_PMC_MODE);
break;
case gXcvrPwrDoze_c:
pwrMode &= ~(cPWR_MODES_AUTODOZE | cPWR_MODES_PMC_MODE);
pwrMode |= cPWR_MODES_XTALEN;
break;
case gXcvrPwrHibernate_c:
pwrMode &= ~(cPWR_MODES_XTALEN | cPWR_MODES_AUTODOZE | cPWR_MODES_PMC_MODE);
break;
default:
return;
}
mPwrState = newState;
MCR20Drv_DirectAccessSPIWrite(PWR_MODES, pwrMode);
if( !xtalState && (pwrMode & cPWR_MODES_XTALEN))
{
/* wait for crystal oscillator to complet its warmup */
while( ( MCR20Drv_DirectAccessSPIRead(PWR_MODES) & cPWR_MODES_XTAL_READY ) != cPWR_MODES_XTAL_READY);
/* wait for radio wakeup from hibernate interrupt */
while( ( MCR20Drv_DirectAccessSPIRead(IRQSTS2) & (cIRQSTS2_WAKE_IRQ | cIRQSTS2_TMRSTATUS) ) != (cIRQSTS2_WAKE_IRQ | cIRQSTS2_TMRSTATUS) );
MCR20Drv_DirectAccessSPIWrite(IRQSTS2, cIRQSTS2_WAKE_IRQ);
}
}
/*
* \brief Function reads the energy level on the preselected channel.
*
* \return energy level
*/
static uint8_t rf_get_channel_energy(void)
{
uint8_t ccaMode;
MCR20Drv_IRQ_Disable();
/* RX can start only from Idle state */
if( mPhySeqState != gIdle_c )
{
MCR20Drv_IRQ_Enable();
return 0;
}
/* Set XCVR power state in run mode */
rf_set_power_state(gXcvrRunState_d);
/* Switch to ED mode */
ccaMode = (mStatusAndControlRegs[PHY_CTRL4] >> cPHY_CTRL4_CCATYPE_Shift_c) & cPHY_CTRL4_CCATYPE;
if( ccaMode != gCcaED_c )
{
mStatusAndControlRegs[PHY_CTRL4] &= ~(cPHY_CTRL4_CCATYPE << cPHY_CTRL4_CCATYPE_Shift_c);
mStatusAndControlRegs[PHY_CTRL4] |= gCcaED_c << cPHY_CTRL4_CCATYPE_Shift_c;
MCR20Drv_DirectAccessSPIWrite(PHY_CTRL4, mStatusAndControlRegs[PHY_CTRL4]);
}
/* Start ED sequence */
mStatusAndControlRegs[PHY_CTRL1] |= gCCA_c;
MCR20Drv_DirectAccessSPIWrite(IRQSTS1, cIRQSTS1_CCAIRQ | cIRQSTS1_SEQIRQ);
MCR20Drv_DirectAccessSPIWrite(PHY_CTRL1, mStatusAndControlRegs[PHY_CTRL1]);
/* Wait for sequence to finish */
while ( !(MCR20Drv_DirectAccessSPIRead(IRQSTS1) & cIRQSTS1_SEQIRQ));
/* Set XCVR to Idle */
mStatusAndControlRegs[PHY_CTRL1] &= ~(cPHY_CTRL1_XCVSEQ);
MCR20Drv_DirectAccessSPIWrite(PHY_CTRL1, mStatusAndControlRegs[PHY_CTRL1]);
MCR20Drv_DirectAccessSPIWrite(IRQSTS1, cIRQSTS1_CCAIRQ | cIRQSTS1_SEQIRQ);
MCR20Drv_IRQ_Enable();
return rf_convert_energy_level(MCR20Drv_DirectAccessSPIRead(CCA1_ED_FNL));
}
/*
* \brief Function converts the energy level from dBm to a 0-255 value.
*
* \param energyLevel in dBm
*
* \return energy level (0-255)
*/
static uint8_t rf_convert_energy_level(uint8_t energyLevel)
{
if(energyLevel >= 90)
{
/* ED value is below minimum. Return 0x00. */
energyLevel = 0x00;
}
else if(energyLevel <= 26)
{
/* ED value is above maximum. Return 0xFF. */
energyLevel = 0xFF;
}
else
{
/* Energy level (-90 dBm to -26 dBm ) --> varies form 0 to 64 */
energyLevel = (90 - energyLevel);
/* Rescale the energy level values to the 0x00-0xff range (0 to 64 translates in 0 to 255) */
/* energyLevel * 3.9844 ~= 4 */
/* Multiply with 4=2^2 by shifting left.
The multiplication will not overflow beacause energyLevel has values between 0 and 63 */
energyLevel <<= 2;
}
return energyLevel;
}
static uint8_t rf_scale_lqi(int8_t rssi)
{
uint8_t scaled_lqi;
/*Worst case sensitivity*/
const int8_t rf_sensitivity = -98;
/*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;
}
/*****************************************************************************/
/* Layer porting to the Freescale driver */
/*****************************************************************************/
extern "C" void xcvr_spi_init(uint32_t instance)
{
(void)instance;
}
extern "C" void RF_IRQ_Init(void) {
MBED_ASSERT(irq != NULL);
irq->mode(PullUp);
irq->fall(&PHY_InterruptHandler);
}
extern "C" void RF_IRQ_Enable(void) {
MBED_ASSERT(irq != NULL);
irq->enable_irq();
}
extern "C" void RF_IRQ_Disable(void) {
MBED_ASSERT(irq != NULL);
irq->disable_irq();
}
extern "C" uint8_t RF_isIRQ_Pending(void) {
MBED_ASSERT(rf != NULL);
return !irq_pin->read();
}
extern "C" void RF_RST_Set(int state) {
MBED_ASSERT(rst != NULL);
*rst = state;
}
extern "C" void gXcvrAssertCS_d(void)
{
MBED_ASSERT(cs != NULL);
*cs = 0;
}
extern "C" void gXcvrDeassertCS_d(void)
{
MBED_ASSERT(cs != NULL);
*cs = 1;
}
extern "C" void xcvr_spi_configure_speed(uint32_t instance, uint32_t freq)
{
MBED_ASSERT(spi != NULL);
(void)instance;
spi->frequency(freq);
}
extern "C" void xcvr_spi_transfer(uint32_t instance,
uint8_t * sendBuffer,
uint8_t * receiveBuffer,
size_t transferByteCount)
{
MBED_ASSERT(spi != NULL);
(void)instance;
volatile uint8_t dummy;
if( !transferByteCount )
return;
if( !sendBuffer && !receiveBuffer )
return;
while( transferByteCount-- )
{
if( sendBuffer )
{
dummy = *sendBuffer;
sendBuffer++;
}
else
{
dummy = 0xFF;
}
dummy = spi->write(dummy);
if( receiveBuffer )
{
*receiveBuffer = dummy;
receiveBuffer++;
}
}
}
/*****************************************************************************/
/*****************************************************************************/
static void rf_if_lock(void)
{
platform_enter_critical();
}
static void rf_if_unlock(void)
{
platform_exit_critical();
}
NanostackRfPhyMcr20a::NanostackRfPhyMcr20a(PinName spi_mosi, PinName spi_miso,
PinName spi_sclk, PinName spi_cs, PinName spi_rst, PinName spi_irq)
: _spi(spi_mosi, spi_miso, spi_sclk), _rf_cs(spi_cs), _rf_rst(spi_rst),
_rf_irq(spi_irq), _rf_irq_pin(spi_irq)
{
// Do nothing
}
NanostackRfPhyMcr20a::~NanostackRfPhyMcr20a()
{
// Do nothing
}
int8_t NanostackRfPhyMcr20a::rf_register()
{
rf_if_lock();
if (rf != NULL) {
rf_if_unlock();
error("Multiple registrations of NanostackRfPhyMcr20a not supported");
return -1;
}
_pins_set();
int8_t radio_id = rf_device_register();
if (radio_id < 0) {
_pins_clear();
rf = NULL;
}
rf_if_unlock();
return radio_id;
}
void NanostackRfPhyMcr20a::rf_unregister()
{
rf_if_lock();
if (rf != this) {
rf_if_unlock();
return;
}
rf_device_unregister();
rf = NULL;
_pins_clear();
rf_if_unlock();
}
void NanostackRfPhyMcr20a::get_mac_address(uint8_t *mac)
{
rf_if_lock();
memcpy((void*)mac, (void*)MAC_address, sizeof(MAC_address));
rf_if_unlock();
}
void NanostackRfPhyMcr20a::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_address, (void*)mac, sizeof(MAC_address));
rf_if_unlock();
}
void NanostackRfPhyMcr20a::_pins_set()
{
spi = &_spi;
cs = &_rf_cs;
rst = &_rf_rst;
irq = &_rf_irq;
irq_pin = &_rf_irq_pin;
}
void NanostackRfPhyMcr20a::_pins_clear()
{
spi = NULL;
cs = NULL;
rst = NULL;
irq = NULL;
irq_pin = NULL;
}