/* hrf69_test.c D.J.Whale 03/04/2016
*
* A simple exerciser for the HopeRF RFM69 radio
* Configures for OOK, and uses a bitpattern than generates
* a fixed tone, that can be measured at the receiving end.
*/
/***** INCLUDES *****/
//#include <stdio.h>
//#include <stdlib.h>
#include "system.h"
#include "delay.h"
#include "gpio.h"
#include "spi.h"
#include "hrfm69.h"
#include "trace.h"
/***** CONFIGURATION *****/
/* Only define this if you are running mac/pc/pi,
* arduino will have a different console wrapper to drive tests, probably
*/
#define HRFM69_TEST
extern void gpio_mock_set_in(uint8_t g, uint8_t v);
/* GPIO assignments for Arduino Pro Micro */
//#define RESET 2
//#define CS 3
//#define MOSI 4
//#define MISO 5
//#define SCLK 6
/* GPIO assignments for Raspberry Pi using BCM numbering */
#define RESET 25
#define LED_GREEN 27 // (not B rev1)
#define LED_RED 22
#define CS 7 // CE1
#define SCLK 11
#define MOSI 10
#define MISO 9
SPI_CONFIG radioConfig = {CS, SCLK, MOSI, MISO, SPI_SPOL0, SPI_CPOL0, SPI_CPHA0};
//TSETTLE, THOLD, TFREQ};
/***** FUNCTION PROTOTYPES *****/
static uint8_t read_ver(void);
static void reset(void);
void hrf_test_send_ook_tick(void);
void hrf_test_send_energenie_ook_switch(void);
#if defined(HRFM69_TEST)
int main(int argc, char **argv)
{
TRACE_OUTS("start\n");
//gpio_init(); done by spi_init at moment
spi_init(&radioConfig);
gpio_setout(RESET);
gpio_low(RESET);
gpio_setout(LED_RED);
gpio_low(LED_RED);
gpio_setout(LED_GREEN);
gpio_low(LED_GREEN);
TRACE_OUTS("reset...\n");
reset();
TRACE_OUTS("reading radiover...\n");
uint8_t rv = read_ver();
TRACE_OUTN(rv);
TRACE_NL();
if (rv != 36)
{
TRACE_FAIL("unexpected radio ver, not 36(dec)\n");
}
TRACE_OUTS("standby mode\n");
HRF_change_mode(HRF_MODE_STANDBY);
HRF_pollreg(HRF_ADDR_IRQFLAGS1, HRF_MASK_MODEREADY, HRF_MASK_MODEREADY);
TRACE_OUTS("testing...\n");
//hrf_test_send_ook_tick();
hrf_test_send_energenie_ook_switch();
//spi_finished();
gpio_finished();
return 0;
}
#endif
// Reset is really a function of how the Energenie radio is wired up to the Pi or
// Arduino, so it will appear in the 'radio' module. It is here for testing convenience.
static void reset(void)
{
gpio_high(RESET);
delayms(150);
gpio_low(RESET);
delayus(100);
}
static uint8_t read_ver(void)
{
return HRF_readreg(HRF_ADDR_VERSION);
}
HRF_CONFIG_REC config_OOK[] = {
{HRF_ADDR_REGDATAMODUL, HRF_VAL_REGDATAMODUL_OOK}, // modulation scheme OOK
{HRF_ADDR_FDEVMSB, 0}, // frequency deviation:0kHz
{HRF_ADDR_FDEVLSB, 0}, // frequency deviation:0kHz
{HRF_ADDR_FRMSB, HRF_VAL_FRMSB433}, // carrier freq:433.92MHz 0x6C7AE1
{HRF_ADDR_FRMID, HRF_VAL_FRMID433}, // carrier freq:433.92MHz 0x6C7AE1
{HRF_ADDR_FRLSB, HRF_VAL_FRLSB433}, // carrier freq:433.92MHz 0x6C7AE1
{HRF_ADDR_RXBW, HRF_VAL_RXBW120}, // channel filter bandwidth:120kHz
{HRF_ADDR_BITRATEMSB, 0x1A}, // bitrate:4800b/s
{HRF_ADDR_BITRATELSB, 0x0B}, // bitrate:4800b/s
{HRF_ADDR_PREAMBLELSB, 0}, // preamble size LSB
{HRF_ADDR_SYNCCONFIG, HRF_VAL_SYNCCONFIG0}, // Size of sync word (disabled)
//{HRF_ADDR_SYNCVALUE1, 0x00},
//{HRF_ADDR_SYNCVALUE2, 0x00},
//{HRF_ADDR_SYNCVALUE3, 0x00},
//{HRF_ADDR_SYNCVALUE4, 0x00},
//{HRF_ADDR_SYNCVALUE5, 0x00},
//{HRF_ADDR_SYNCVALUE6, 0x00},
//{HRF_ADDR_SYNCVALUE7, 0x00},
//{HRF_ADDR_SYNCVALUE8, 0x00},
{HRF_ADDR_PACKETCONFIG1, 0x00}, // Fixed length, no Manchester coding
//{HRF_ADDR_PAYLOADLEN, 2}, // Payload Length
//{HRF_ADDR_FIFOTHRESH, 1} // Start tx when this is exceeded
};
#define CONFIG_OOK_COUNT (sizeof(config_OOK)/sizeof(HRF_CONFIG_REC))
// Send a test tick using OOK modulation
void hrf_test_send_ook_tick(void)
{
/* two blips, to help prove the 01 at start */
static uint8_t payload[] = {
0x41, 0x40
};
int i;
TRACE_OUTS("config\n");
HRF_config(config_OOK, CONFIG_OOK_COUNT);
HRF_writereg(HRF_ADDR_PAYLOADLEN, sizeof(payload));
HRF_writereg(HRF_ADDR_FIFOTHRESH, sizeof(payload)-1);
TRACE_OUTS("transmitter mode\n");
HRF_change_mode(HRF_MODE_TRANSMITTER);
TRACE_OUTS("wait for modeready,txready in irqflags1\n");
HRF_pollreg(HRF_ADDR_IRQFLAGS1, HRF_MASK_MODEREADY|HRF_MASK_TXREADY, HRF_MASK_MODEREADY|HRF_MASK_TXREADY);
uint8_t irqflags1 = HRF_readreg(HRF_ADDR_IRQFLAGS1);
uint8_t irqflags2 = HRF_readreg(HRF_ADDR_IRQFLAGS2);
TRACE_OUTS("irqflags1,2=");
TRACE_OUTN(irqflags1);
TRACE_OUTC(',');
TRACE_OUTN(irqflags2);
TRACE_NL();
while (1)
{
for (i=0; i<1; i++)
{
TRACE_OUTS("tx\n");
HRF_writefifo_burst(payload, sizeof(payload));
HRF_pollreg(HRF_ADDR_IRQFLAGS2, HRF_MASK_PACKETSENT, HRF_MASK_PACKETSENT);
}
uint8_t irqflags1 = HRF_readreg(HRF_ADDR_IRQFLAGS1);
uint8_t irqflags2 = HRF_readreg(HRF_ADDR_IRQFLAGS2);
TRACE_OUTS("irqflags1,2=");
TRACE_OUTN(irqflags1);
TRACE_OUTC(',');
TRACE_OUTN(irqflags2);
TRACE_NL();
if (((irqflags2 & HRF_MASK_FIFONOTEMPTY) != 0) || ((irqflags2 & HRF_MASK_FIFOOVERRUN) != 0))
{
TRACE_OUTN(irqflags2);
TRACE_NL();
TRACE_FAIL("FIFO not empty or overrun at end of burst");
}
delaysec(1);
}
//NOTE: packetsent is only cleared when exiting TX (i.e. to STANDBY or RECEIVE)
}
/* Note, D0123 are transmitted as b3210
# Coded as per the (working) C code and HS1527 datasheet bitorder
# b 3210
# 0000 UNUSED 0
# 0001 UNUSED 1
# 0010 socket 4 off 2
# 0011 socket 4 on 3
# 0100 UNUSED 4
# 0101 UNUSED 5
# 0110 socket 2 off 6
# 0111 socket 2 on 7
# 1000 UNUSED 8
# 1001 UNUSED 9
# 1010 socket 3 off A
# 1011 socket 3 on B
# 1100 all off C
# 1101 all on D
# 1110 socket 1 off E
# 1111 socket 1 on F
*/
// A hard coded test of switching an Energenie switch on and off
void hrf_test_send_energenie_ook_switch(void)
{
// Note, when PA starts up, radio inserts a 01 at start before any user data
// we might need to pad away from this by sending a sync of many zero bits
// to prevent it being misinterpreted as a preamble, and prevent it causing
// the first bit of the preamble being twice the length it should be in the
// first packet.
// Also need to confirm this bit only occurs when transmit actually starts,
// and not on every FIFO load.
/* manual preamble, 20 bit encoded address, 4 encoded data bits */
static uint8_t payload[16] = {
0x80, 0x00, 0x00, 0x00, // preamble pulse with timing violation gap
// Energenie 'random' 20 bit address is 0x6C6C6
// 0110 1100 0110 1100 0110
// 0 encoded as 8 (1000)
// 1 encoded as E (1110)
0x8E, 0xE8, 0xEE, 0x88, 0x8E, 0xE8, 0xEE, 0x88, 0x8E, 0xE8,
// Energenie 'switch 1 ON' command F 1111 (0xEE, 0xEE)
0xEE, 0xEE
// Energenie 'switch 1 OFF' command E 1110 (0xEE, 0xE8)
//0xEE, 0xE8
};
/* Last byte of the payload for switch 1 */
#define ON 0xEE
#define OFF 0xE8
// Limited by U8 size of PAYLOADLEN reg (15*16=240)
#define REPEATS 15
// To get longer repeats, we'll have to design a new 'unlimited'
// payload sender, and use FIFOEMPTY as a way to detect end of transmit.
int i;
uint8_t irqflags1;
uint8_t irqflags2;
TRACE_OUTS("config\n");
HRF_config(config_OOK, CONFIG_OOK_COUNT);
// the full packet/burst consists of repeated payloads
// packetsent will trigger when this number of bytes have been transmitted
HRF_writereg(HRF_ADDR_PAYLOADLEN, sizeof(payload) * REPEATS);
// but the FIFO is filled in 1 message (4+10+2=16 byte) sections
// level triggers when it 'strictly exceeds' level (i.e. 16 bytes starts tx,
// and <=15 bytes triggers fifolevel irqflag to be cleared)
HRF_writereg(HRF_ADDR_FIFOTHRESH, sizeof(payload)-1);
uint8_t last_byte = ON;
while (1)
{
/* Bring into transmitter mode and ramp up the PA */
TRACE_OUTS("transmitter mode\n");
HRF_change_mode(HRF_MODE_TRANSMITTER);
TRACE_OUTS("wait for modeready,txready in irqflags1\n");
HRF_pollreg(HRF_ADDR_IRQFLAGS1, HRF_MASK_MODEREADY|HRF_MASK_TXREADY, HRF_MASK_MODEREADY|HRF_MASK_TXREADY);
irqflags1 = HRF_readreg(HRF_ADDR_IRQFLAGS1);
irqflags2 = HRF_readreg(HRF_ADDR_IRQFLAGS2);
TRACE_OUTS("irqflags1,2=");
TRACE_OUTN(irqflags1);
TRACE_OUTC(',');
TRACE_OUTN(irqflags2);
TRACE_NL();
/* Set this as alternate ON or OFF bursts */
payload[sizeof(payload)-1] = last_byte;
TRACE_OUTS("tx repeats in a single burst:");
TRACE_OUTN(last_byte);
TRACE_NL();
// send a number of payload repeats for the whole packet burst
for (i=0; i<REPEATS; i++)
{
HRF_writefifo_burst(payload, sizeof(payload));
// Tx will auto start when fifolevel is exceeded by loading the payload
// so the level register must be correct for the size of the payload
// otherwise transmit will never start.
/* wait for FIFO to not exceed threshold level */
HRF_pollreg(HRF_ADDR_IRQFLAGS2, HRF_MASK_FIFOLEVEL, 0);
}
// wait for packet sent (num bytes tx'ed matches PAYLOADLEN reg)
HRF_pollreg(HRF_ADDR_IRQFLAGS2, HRF_MASK_PACKETSENT, HRF_MASK_PACKETSENT);
// Check final flags in case of overruns etc
irqflags1 = HRF_readreg(HRF_ADDR_IRQFLAGS1);
irqflags2 = HRF_readreg(HRF_ADDR_IRQFLAGS2);
TRACE_OUTS("irqflags1,2=");
TRACE_OUTN(irqflags1);
TRACE_OUTC(',');
TRACE_OUTN(irqflags2);
TRACE_NL();
// Read back PAYLOADLENGTH to confirm chip doesn't use it as a counter itself
uint8_t pl = HRF_readreg(HRF_ADDR_PAYLOADLEN);
TRACE_OUTS("payloadlen reg at end:");
TRACE_OUTN(pl);
TRACE_NL();
/* Back to STANDBY, this clears packetsent flag */
// always back to standby, regardless of errors above
// otherwise PA/carrier might be left permanently on.
TRACE_OUTS("standby mode\n");
HRF_change_mode(HRF_MODE_STANDBY);
HRF_pollreg(HRF_ADDR_IRQFLAGS1, HRF_MASK_MODEREADY, HRF_MASK_MODEREADY);
if (((irqflags2 & HRF_MASK_FIFONOTEMPTY) != 0) || ((irqflags2 & HRF_MASK_FIFOOVERRUN) != 0))
{
TRACE_OUTN(irqflags2);
TRACE_NL();
TRACE_FAIL("FIFO not empty or overrun at end of burst");
}
/* Inter-burst delay */
delaysec(1);
/* Toggle next switch state */
if (last_byte == OFF)
{
last_byte = ON;
}
else
{
last_byte = OFF;
}
}
}
/***** END OF FILE *****/
David Whale