Added new star-topology example

2011-04-01 22:53:36 -07:00 · 2011-04-01 22:53:36 -07:00 · 37d8e8b17d
parent c5c4537cdc
commit 37d8e8b17d
4 changed files with 603 additions and 0 deletions
--- a/examples/starping/.gitignore
+++ b/examples/starping/.gitignore
@ -0,0 +1 @@
 output/
--- a/examples/starping/makefile
+++ b/examples/starping/makefile
@ -0,0 +1,291 @@
 # Arduino Makefile
 # Arduino adaptation by mellis, eighthave, oli.keller
 # Modified by Kerry Wong to support NetBeans
 # Modified by Rob Gray (Graynomad) for use with Windows and no IDE
 #   This works in my environment and I use it to program two different 
 #   328-based boards and a Mega2560. It's not necessarily robust and 
 #   I may have broken something in the original file that I don't use.
 #
 # This makefile allows you to build sketches from the command line
 # without the Arduino environment.
 #
 # Instructions for using the makefile:
 #
 #  1. Copy this file into the folder with your sketch. The project code file
 #	  should have a .c extension however the file gets copied to a .cpp before
 #     compilation so you still write in C++.
 #
 #  2. Modify the lines between the double ### rows to set the paths 
 #     comm ports etc for your system. EG. c:/progra~1/arduino/arduino-00
 #     for the Arduino IDE, Note the use of short folder name, don't use
 #     "Program files" because spaces will break the build.
 #
 #     Set the line containing "MCU" to match your board's processor.
 #     Typically ATmega328 or ATmega2560.  If you're using a LilyPad Arduino,
 #     change F_CPU to 8000000.
 #
 #  3. At the command line, change to the directory containing your
 #     program's file and the makefile.
 #
 #  4. Type "make" and press enter to compile/verify your program.
 #     The default make target will also perform the uplode using avrdude.
 #
 #     The first time this is done all required libraries will be built
 #     and a core.a file will be created in the output folder.
 #
 #  NOTES:
 #     All output goes into a folder called "output" underneath the working folder.
 #     The default all: target creates symbol (.sym) and expanded assembly 
 #     (.lss) files and uploads the program.
 #
 #
 ##########################################################
 ##########################################################
 # Select processor here
 MCU 			= atmega328p
 #MCU 			= atmega2560
 ifeq ($(MCU),atmega2560)
 UPLOAD_RATE 	= 115200
 AVRDUDE_PROTOCOL = stk500v2
 COM 			= 39
 endif
 ifeq ($(MCU),atmega328p)
 UPLOAD_RATE 	= 57600
 AVRDUDE_PROTOCOL = stk500v1
 COM 			= 33
 endif
 UNAME := $(shell uname)
 ifeq ($(UNAME),Darwin)
 ARDUINO_VERSION	= 21
 ARDUINO_DIR 	= /opt/arduino-00$(ARDUINO_VERSION)
 AVR_TOOLS_PATH 	= $(ARDUINO_DIR)/hardware/tools/avr/bin
 AVRDUDECONFIG_PATH = $(ARDUINO_DIR)/hardware/tools/avr/etc
 PORT                    = /dev/tty.usbserial-A600eHIs 
 PORT2                   = /dev/tty.usbserial-A9007LmI
 else
 ARDUINO_VERSION	= 22
 ARDUINO_DIR 	= /opt/arduino-00$(ARDUINO_VERSION)
 AVR_TOOLS_PATH 	= /usr/bin
 AVRDUDECONFIG_PATH = $(ARDUINO_DIR)/hardware/tools
 PORT 			= /dev/ttyUSB0
 PORT2 			= /dev/ttyUSB1
 endif
 PROJECT_NAME 	= $(notdir $(PWD))
 PROJECT_DIR 	= . 
 ARDUINO_CORE 	= $(ARDUINO_DIR)/hardware/arduino/cores/arduino
 ARDUINO_AVR 	= $(ARDUINO_DIR)/hardware/tools/avr/avr/include/avr
 ARDUINO_LIB 	= $(ARDUINO_DIR)/libraries
 F_CPU 			= 16000000
 ##########################################################
 ##########################################################
 # Note that if your program has dependencies other than those
 # already listed below, you will need to add them accordingly.
 C_MODULES =  \
 $(ARDUINO_CORE)/wiring_pulse.c \
 $(ARDUINO_CORE)/wiring_analog.c \
 $(ARDUINO_CORE)/pins_arduino.c \
 $(ARDUINO_CORE)/wiring.c \
 $(ARDUINO_CORE)/wiring_digital.c \
 $(ARDUINO_CORE)/WInterrupts.c \
 $(ARDUINO_CORE)/wiring_shift.c \
 CXX_MODULES = \
 $(ARDUINO_CORE)/Tone.cpp \
 $(ARDUINO_CORE)/main.cpp \
 $(ARDUINO_CORE)/WMath.cpp \
 $(ARDUINO_CORE)/Print.cpp \
 $(ARDUINO_CORE)/HardwareSerial.cpp \
 $(ARDUINO_LIB)/SPI/SPI.cpp \
 $(ARDUINO_LIB)/EEPROM/EEPROM.cpp \
 ../../RF24.cpp
 CXX_APP 	= output/$(PROJECT_NAME).cpp
 MODULES 	= $(C_MODULES) $(CXX_MODULES)
 SRC 		= $(C_MODULES)
 CXXSRC 		= $(CXX_MODULES) $(CXX_APP)
 FORMAT 		= ihex
 # Name of this Makefile (used for "make depend").
 MAKEFILE = Makefile
 # Debugging format.
 # Native formats for AVR-GCC's -g are stabs [default], or dwarf-2.
 # AVR (extended) COFF requires stabs, plus an avr-objcopy run.
 #DEBUG = stabs
 DEBUG =
 OPT = s
 # Place -D or -U options here
 CDEFS = -DF_CPU=$(F_CPU)L -DARDUINO=$(ARDUINO_VERSION)
 CXXDEFS = -DF_CPU=$(F_CPU)L -DARDUINO=$(ARDUINO_VERSION)
 # Place -I options here
 CINCS =  -I$(ARDUINO_LIB)/EEPROM -I$(ARDUINO_CORE) -I$(ARDUINO_LIB) -I$(PROJECT_DIR) -I$(ARDUINO_AVR) -I$(ARDUINO_LIB)/SPI -I../..
 CXXINCS = -I$(ARDUINO_CORE) -I$(ARDUINO_LIB)
 # Compiler flag to set the C Standard level.
 # c89   - "ANSI" C
 # gnu89 - c89 plus GCC extensions
 # c99   - ISO C99 standard (not yet fully implemented)
 # gnu99 - c99 plus GCC extensions
 #CSTANDARD = -std=gnu99
 CDEBUG 		= -g$(DEBUG)
 #CWARN 		= -Wall -Wstrict-prototypes
 #CWARN 		= -Wall   # show all warnings
 CWARN 		= -w      # suppress all warnings
 CMAP		= -Wl,-Map,output.map 
 ####CTUNING = -funsigned-char -funsigned-bitfields -fpack-struct -fshort-enums
 CTUNING = -ffunction-sections -fdata-sections
 CXXTUNING = -fno-exceptions -ffunction-sections -fdata-sections
 #CEXTRA = -Wa,-adhlns=$(<:.c=.lst)
 MMCU 		= -mmcu=$(MCU)
 CFLAGS = $(CDEBUG) -O$(OPT) $(CMAP) $(CWARN) $(CTUNING) $(MMCU) $(CDEFS) $(CINCS) $(CSTANDARD) $(CEXTRA)
 CXXFLAGS = $(CDEBUG) -O$(OPT) $(CWARN) $(CXXTUNING) $(CDEFS) $(CINCS)
 #ASFLAGS = -Wa,-adhlns=$(<:.S=.lst),-gstabs
 LDFLAGS = -O$(OPT) -lm -Wl,--gc-sections
 #LDFLAGS = -O$(OPT) -lm -Wl,-Map,output/$(PROJECT_NAME).map 
 # Programming support using avrdude. Settings and variables.
 AVRDUDE_PORT = $(PORT)
 AVRDUDE_WRITE_FLASH = -U flash:w:output/$(PROJECT_NAME).hex:i
 AVRDUDE_FLAGS = -V -F -D -C $(AVRDUDECONFIG_PATH)/avrdude.conf \
 -p $(MCU) -c $(AVRDUDE_PROTOCOL) -b $(UPLOAD_RATE)
 # Program settings
 CC 			= $(AVR_TOOLS_PATH)/avr-gcc
 CXX 		= $(AVR_TOOLS_PATH)/avr-g++
 LD 			= $(AVR_TOOLS_PATH)/avr-gcc
 OBJCOPY 	= $(AVR_TOOLS_PATH)/avr-objcopy
 OBJDUMP 	= $(AVR_TOOLS_PATH)/avr-objdump
 AR 			= $(AVR_TOOLS_PATH)/avr-ar
 SIZE 		= $(AVR_TOOLS_PATH)/avr-size
 NM 			= $(AVR_TOOLS_PATH)/avr-nm
 AVRDUDE 	= $(AVR_TOOLS_PATH)/avrdude
 REMOVE 		= rm -f
 MV 			= mv -f
 # Define all object files.
 OBJ = $(SRC:.c=.o) $(CXXSRC:.cpp=.o) $(ASRC:.S=.o)
 OBJ_MODULES = $(C_MODULES:.c=.o) $(CXX_MODULES:.cpp=.o)
 # Define all listing files.
 LST = $(ASRC:.S=.lst) $(CXXSRC:.cpp=.lst) $(SRC:.c=.lst)
 # Combine all necessary flags and optional flags.
 # Add target processor to flags.
 ALL_CFLAGS 	= $(CFLAGS) -mmcu=$(MCU)
 ALL_CXXFLAGS = $(CXXFLAGS) -mmcu=$(MCU)
 ALL_ASFLAGS = -x assembler-with-cpp $(ASFLAGS) -mmcu=$(MCU)
 ALL_LDFLAGS = $(LDFLAGS) -mmcu=$(MCU)
 # Default target.
 # This is th etarget that gets executed with a make command
 # that has no parameters, ie "make".
 all: applet_files build sym lss size upload
 build: elf hex
 output/$(PROJECT_NAME).cpp: $(PROJECT_NAME).pde
 	test -d output || mkdir output
 	echo "#include <WProgram.h>" > $@ 
 	echo "#line 1 \"$<\"" >> $@ 
 	cat $< >> $@ 
 elf: output/$(PROJECT_NAME).elf
 hex: output/$(PROJECT_NAME).hex
 eep: output/$(PROJECT_NAME).eep
 lss: output/$(PROJECT_NAME).lss
 #sym: output/$(PROJECT_NAME).sym
 # Upload HEX file to Arduino
 upload: output/$(PROJECT_NAME).hex
 	$(AVRDUDE) $(AVRDUDE_FLAGS) -P $(PORT) $(AVRDUDE_WRITE_FLASH)
 	$(AVRDUDE) $(AVRDUDE_FLAGS) -P $(PORT2) $(AVRDUDE_WRITE_FLASH)
 sym:
 	$(NM) -n -C --format=posix output/$(PROJECT_NAME).elf > output/$(PROJECT_NAME).sym
 # Display size of file.
 size:
 	$(SIZE) output/$(PROJECT_NAME).elf
 # Convert ELF to COFF for use in debugging / simulating in AVR Studio or VMLAB.
 COFFCONVERT=$(OBJCOPY) --debugging \
 --change-section-address .data-0x800000 \
 --change-section-address .bss-0x800000 \
 --change-section-address .noinit-0x800000 \
 --change-section-address .eeprom-0x810000
 coff: output/$(PROJECT_NAME).elf
 	$(COFFCONVERT) -O coff-avr output/$(PROJECT_NAME).elf $(PROJECT_NAME).cof
 	extcoff: $(PROJECT_NAME).elf
 	$(COFFCONVERT) -O coff-ext-avr output/$(PROJECT_NAME).elf $(PROJECT_NAME).cof
 .SUFFIXES: .elf .hex .eep .lss .sym
 .elf.hex:
 	$(OBJCOPY) -O $(FORMAT) -R .eeprom $< $@
 .elf.eep:
 	$(OBJCOPY) -O $(FORMAT) -j .eeprom --set-section-flags=.eeprom="alloc,load" \
 	--no-change-warnings \
 	--change-section-lma .eeprom=0 $< $@
 # Create extended listing file from ELF output file.
 .elf.lss:
 	$(OBJDUMP) -h -S $< > $@
 # Link: create ELF output file from library.
 #output/$(PROJECT_NAME).elf: $(PROJECT_NAME).c output/core.a
 output/$(PROJECT_NAME).elf: output/$(PROJECT_NAME).o output/core.a
 	$(LD) $(ALL_LDFLAGS) -o $@ output/$(PROJECT_NAME).o output/core.a
 output/core.a: $(OBJ_MODULES)
 	@for i in $(OBJ_MODULES); do echo $(AR) rcs output/core.a $$i; $(AR) rcs output/core.a $$i; done
 # Compile: create object files from C++ source files.
 .cpp.o:
 	$(CXX) -c $(ALL_CXXFLAGS) $< -o $@
 # Compile: create object files from C source files.
 .c.o:
 	$(CC) -c $(ALL_CFLAGS) $< -o $@
 # Compile: create assembler files from C source files.
 .c.s:
 	$(CC) -S $(ALL_CFLAGS) $< -o $@
 # Assemble: create object files from assembler source files.
 .S.o:
 	$(CC) -c $(ALL_ASFLAGS) $< -o $@
 # Automatic dependencies
 %.d: %.c
 	$(CC) -M $(ALL_CFLAGS) $< | sed "s;$(notdir $*).o:;$*.o $*.d:;" > $@
 %.d: %.cpp
 	$(CXX) -M $(ALL_CXXFLAGS) $< | sed "s;$(notdir $*).o:;$*.o $*.d:;" > $@
 # Target: clean project.
 clean:
 	$(REMOVE) output/$(PROJECT_NAME).hex output/$(PROJECT_NAME).eep output/$(PROJECT_NAME).cof output/$(PROJECT_NAME).elf \
 	output/$(PROJECT_NAME).map output/$(PROJECT_NAME).sym output/$(PROJECT_NAME).lss output/core.a \
 	$(OBJ) $(LST) $(SRC:.c=.s) $(SRC:.c=.d) $(CXXSRC:.cpp=.s) $(CXXSRC:.cpp=.d)
 #.PHONY:	all build elf hex eep lss sym program coff extcoff clean applet_files sizebefore sizeafter
 .PHONY:		all build elf hex eep lss sym program coff extcoff applet_files sizebefore sizeafter
 #include $(SRC:.c=.d)
 #include $(CXXSRC:.cpp=.d)
--- a/examples/starping/printf.h
+++ b/examples/starping/printf.h
@ -0,0 +1,31 @@
 /*
 Copyright (C) 2011 James Coliz, Jr. <maniacbug@ymail.com>
 This program is free software; you can redistribute it and/or
 modify it under the terms of the GNU General Public License
 version 2 as published by the Free Software Foundation.
 */
 /**
 * @file printf.h
 *
 * Setup necessary to direct stdout to the Arduino Serial library, which
 * enables 'printf'
 */
 #ifndef __PRINTF_H__
 #define __PRINTF_H__
 #include "WProgram.h"
 int serial_putc( char c, FILE *t ) 
 {
  Serial.write( c );
 } 
 void printf_begin(void)
 {
  fdevopen( &serial_putc, 0 );
 }
 #endif // __PRINTF_H__
--- a/examples/starping/starping.pde
+++ b/examples/starping/starping.pde
@ -0,0 +1,280 @@
 /*
 Copyright (C) 2011 James Coliz, Jr. <maniacbug@ymail.com>
 This program is free software; you can redistribute it and/or
 modify it under the terms of the GNU General Public License
 version 2 as published by the Free Software Foundation.
 */
 /**
 * Example RF Radio Ping Star Group 
 *
 * This sketch is a more complex example of using the RF24 library for Arduino.  
 * Deploy this on up to six nodes.  Set one as the 'pong receiver' and the others
 * as 'ping transmit' units.  The ping units unit will send out the value of millis() 
 * once a second.  The pong unit will respond back with a copy of the value.  
 * The ping unit can get that response back, and
 * determine how long the whole cycle took.
 *
 * This example requires a bit more complexity to determine which unit is
 * which.  The pong receiver is identified by having its role_pin tied to ground.
 * The ping senders are further differentiated by a byte in eeprom.
 */
 #include <SPI.h>
 #include <EEPROM.h>
 #include "nRF24L01.h"
 #include "RF24.h"
 #include "printf.h"
 extern EEPROMClass EEPROM;
 //
 // Hardware configuration
 //
 // Set up nRF24L01 radio on SPI bus plus pins 8 & 9
 RF24 radio(8,9);
 // sets the role of this unit in hardware.  Connect to GND to be the 'pong' receiver
 // Leave open to be the 'pong' receiver.
 const int role_pin = 7;
 //
 // Topology
 //
 // Radio pipe addresses for the 6 nodes to communicate
 const uint64_t talking_pipes[6] = { 0xF0F0F0F0E1LL, 0xF0F0F0F0D2LL, 0xF0F0F0F0C3LL, 0xF0F0F0F0B4LL, 0xF0F0F0F0A5LL, 0xF0F0F0F096LL };
 const uint64_t listening_pipes[6] = { 0x3A3A3A3AE1LL, 0x3A3A3A3AD2LL, 0x3A3A3A3AC3LL, 0x3A3A3A3AB4LL, 0x3A3A3A3AA5LL, 0x3A3A3A3A96LL };
 //
 // Role management
 //
 // Set up role.  This sketch uses the same software for all the nodes
 // in this system.  Doing so greatly simplifies testing.  The hardware itself specifies
 // which node it is.
 //
 // This is done through the role_pin
 //
 // The various roles supported by this sketch
 typedef enum { role_invalid = 0, role_ping_out, role_pong_back } role_e;
 // The debug-friendly names of those roles
 const char* role_friendly_name[] = { "invalid", "Ping out", "Pong back"};
 // The role of the current running sketch
 role_e role;
 //
 // Address management
 //
 // Where in EEPROM is the address stored?
 const uint8_t address_at_eeprom_location = 0;
 // What is our address (SRAM cache of the address from EEPROM)
 // Note that zero is an INVALID address
 uint8_t node_address;
 void setup(void)
 {
  //
  // Role
  //
  // set up the role pin
  pinMode(role_pin, INPUT);
  digitalWrite(role_pin,HIGH);
  delay(20); // Just to get a solid reading on the role pin
  // read the address pin, establish our role
  if ( digitalRead(role_pin) )
    role = role_ping_out;
  else
    role = role_pong_back;
  //
  // Address
  //
  if ( role == role_pong_back )
    node_address = 1;
  else
  {
    // Read the address from EEPROM
    uint8_t reading = EEPROM.read(address_at_eeprom_location);
    // If it is in a valid range for node addresses, it is our
    // address.
    if ( reading >= 2 && reading <= 6 )
      node_address = reading;
    // Otherwise, it is invalid, so set our address AND ROLE to 'invalid'
    else
    {
      node_address = 0;
      role = role_invalid;
    }
  }
  //
  // Print preamble
  //
  Serial.begin(9600);
  printf_begin();
  printf("\n\rRF24/examples/starping/\n\r");
  printf("ROLE: %s\n\r",role_friendly_name[role]);
  printf("ADDRESS: %i\n\r",node_address);
  //
  // Setup and configure rf radio
  //
  radio.begin();
  //
  // Open pipes to other nodes for communication
  //
  // Open 'our' pipe for writing
  // ping nodes open the parent's pipe for reading
  // pong node opens all children's pipes for reading
  if ( role == role_pong_back )
  {
    // Listen to all ping nodes' talking pipes 
    radio.openReadingPipe(1,talking_pipes[1]);
    radio.openReadingPipe(2,talking_pipes[2]);
    radio.openReadingPipe(3,talking_pipes[3]);
    radio.openReadingPipe(4,talking_pipes[4]);
    radio.openReadingPipe(5,talking_pipes[5]);
  }
  if ( role == role_ping_out )
  {
    // Write on our talking pipe
    radio.openWritingPipe(talking_pipes[node_address-1]);
    // Listen on our listening pipe 
    radio.openReadingPipe(1,listening_pipes[node_address-1]);
  }
  //
  // Start listening
  //
  radio.startListening();
  //
  // Dump the configuration of the rf unit for debugging
  //
  radio.printDetails();
 }
 void loop(void)
 {
  //
  // Ping out role.  Repeatedly send the current time
  //
  if (role == role_ping_out)
  {
    // First, stop listening so we can talk.
    radio.stopListening();
    // Take the time, and send it.  This will block until complete
    unsigned long time = millis();
    printf("Now sending %lu...",time);
    bool ok = radio.write( &time, sizeof(unsigned long) );  
    // Now, continue listening
    radio.startListening();
    // Wait here until we get a response, or timeout (250ms)
    unsigned long started_waiting_at = millis();
    bool timeout = false;
    while ( ! radio.available() && ! timeout )
      if (millis() - started_waiting_at > 250 )
        timeout = true;
    // Describe the results
    if ( timeout )
    {
      printf("Failed, response timed out.\n\r");
    }
    else
    {
      // Grab the response, compare, and send to debugging spew
      unsigned long got_time;
      radio.read( &got_time, sizeof(unsigned long) );
      // Spew it
      printf("Got response %lu, round-trip delay: %lu\n\r",got_time,millis()-got_time);
    }
    // Try again 1s later
    delay(1000);
  }
  //
  // Pong back role.  Receive each packet, dump it out, and send it back
  //
  if ( role == role_pong_back )
  {
    // if there is data ready
    uint8_t pipe_num;
    if ( radio.available(&pipe_num) )
    {
      // Dump the payloads until we've gotten everything
      unsigned long got_time;
      boolean done = false;
      while (!done)
      {
        // Fetch the payload, and see if this was the last one.
        done = radio.read( &got_time, sizeof(unsigned long) );
        // Spew it
        printf("Got payload %lu from %i...",got_time,pipe_num);
      }
      // First, stop listening so we can talk
      radio.stopListening();
      // Open the correct pipe for writing
      radio.openWritingPipe(listening_pipes[pipe_num]);
      // Retain the low 2 bytes to identify the pipe for the spew
      uint16_t pipe_id = listening_pipes[pipe_num] & 0xffff;
      // Send the final one back.
      radio.write( &got_time, sizeof(unsigned long) );  
      printf("Sent response to %04x.\n\r",pipe_id);
      // Now, resume listening so we catch the next packets.
      radio.startListening();
    }
  }
  //
  // Listen for serial input, which is how we set the address
  //
  if (Serial.available())
  {
    // If the character on serial input is in a valid range...
    char c = Serial.read();
    if ( c >= '1' && c <= '6' )
    {
      // It is our address
      EEPROM.write(address_at_eeprom_location,c-'0');
      // And we are done right now (no easy way to soft reset)
      printf("\n\rManually reset address to: %c\n\rPress RESET to continue!",c);
      while(1);
    }
  }
 }
 // vim:ai sts=2 sw=2 ft=cpp