osd-contiki/cpu/avr/radio/rf230bb/hal.h

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/* Copyright (c) 2008, Swedish Institute of Computer Science
* All rights reserved.
*
* Additional fixes for AVR contributed by:
*
* Colin O'Flynn coflynn@newae.com
* Eric Gnoske egnoske@gmail.com
* Blake Leverett bleverett@gmail.com
* Mike Vidales mavida404@gmail.com
* Kevin Brown kbrown3@uccs.edu
* Nate Bohlmann nate@elfwerks.com
* David Kopf dak664@embarqmail.com
* Ivan Delamer delamer@ieee.com
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*
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in
* the documentation and/or other materials provided with the
* distribution.
* * Neither the name of the copyright holders nor the names of
* contributors may be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
* LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*/
/**
* \addtogroup hal
* @{
*/
/**
* \file
* \brief This file contains low-level radio driver code.
*
*/
#ifndef HAL_AVR_H
#define HAL_AVR_H
/*============================ INCLUDE =======================================*/
#include <stdint.h>
#include <stdbool.h>
//#include <util/crc16.h>
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#include "contiki-conf.h"
/*============================ MACROS ========================================*/
/** \name This is the list of pin configurations needed for a given platform.
* \brief Change these values to port to other platforms.
* \{
*/
/* Define all possible platform types/revisions here. */
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// Don't use zero, it will match if undefined!
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// RAVEN_D : Raven kit with LCD display
// RAVENUSB_C : used for RZRAVEN USB key
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// RCB_B : RZ200 kit from Atmel based on 1281V
// ZIGBIT : Zigbit module from Meshnetics
// ATMEGA128RFA1 : Bare chip with internal radio
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// IRIS : IRIS Mote from MEMSIC
#define RAVENUSB_C 1
#define RAVEN_D 2
#define RCB_B 3
#define ZIGBIT 4
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#define IRIS 5
#define ATMEGA128RFA1 6
#define ATMEGA256RFR2 7
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#if PLATFORM_TYPE == RCB_B
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/* 1281 rcb */
# define SSPORT B
# define SSPIN (0x00)
# define SPIPORT B
# define MOSIPIN (0x02)
# define MISOPIN (0x03)
# define SCKPIN (0x01)
# define RSTPORT B
# define RSTPIN (0x05)
# define IRQPORT D
# define IRQPIN (0x04)
# define SLPTRPORT B
# define SLPTRPIN (0x04)
#elif PLATFORM_TYPE == ZIGBIT
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/* 1281V Zigbit */
# define SSPORT B
# define SSPIN (0x00)
# define SPIPORT B
# define MOSIPIN (0x02)
# define MISOPIN (0x03)
# define SCKPIN (0x01)
# define RSTPORT A
# define RSTPIN (0x07)
# define IRQPORT E
# define IRQPIN (0x05)
# define SLPTRPORT B
# define SLPTRPIN (0x04)
#elif PLATFORM_TYPE == RAVEN_D
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/* 1284 raven */
# define SSPORT B
# define SSPIN (0x04)
# define SPIPORT B
# define MOSIPIN (0x05)
# define MISOPIN (0x06)
# define SCKPIN (0x07)
# define RSTPORT B
# define RSTPIN (0x01)
# define IRQPORT D
# define IRQPIN (0x06)
# define SLPTRPORT B
# define SLPTRPIN (0x03)
#elif PLATFORM_TYPE == RAVENUSB_C
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/* 1287USB raven */
# define SSPORT B
# define SSPIN (0x00)
# define SPIPORT B
# define MOSIPIN (0x02)
# define MISOPIN (0x03)
# define SCKPIN (0x01)
# define RSTPORT B
# define RSTPIN (0x05)
# define IRQPORT D
# define IRQPIN (0x04)
# define SLPTRPORT B
# define SLPTRPIN (0x04)
#elif PLATFORM_TYPE == ATMEGA128RFA1
/* ATmega1281 with internal AT86RF231 radio */
# define SLPTRPORT TRXPR
# define SLPTRPIN 1
#elif PLATFORM_TYPE == ATMEGA256RFR2
/* ATmega1281 with internal AT86RF231 radio */
# define SLPTRPORT TRXPR
# define SLPTRPIN 1
#elif CONTIKI_TARGET_MULLE
/* mulle 5.2 (TODO: move to platform specific) */
# define SSPORT 3
# define SSPIN 5
# define MOSIPORT 1
# define MOSIPIN 1
# define MISOPORT 1
# define MISOPIN 0
# define SCKPORT 3
# define SCKPIN 3
# define RSTPORT 4
# define RSTPIN 3
# define IRQPORT 8
# define IRQPIN 3
# define SLPTRPORT 0
# define SLPTRPIN 7
#elif PLATFORM_TYPE == IRIS
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/* 1281 IRIS */
# define SSPORT B
# define SSPIN (0x00)
# define SPIPORT B
# define MOSIPIN (0x02)
# define MISOPIN (0x03)
# define SCKPIN (0x01)
# define RSTPORT A
# define RSTPIN (0x06)
# define IRQPORT D
# define IRQPIN (0x04)
# define SLPTRPORT B
# define SLPTRPIN (0x07)
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#else
#error "PLATFORM_TYPE undefined in hal.h"
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#endif
/* For architectures that have all SPI signals on the same port */
#ifndef SSPORT
#define SSPORT SPIPORT
#endif
#ifndef SCKPORT
#define SCKPORT SPIPORT
#endif
#ifndef MOSIPORT
#define MOSIPORT SPIPORT
#endif
#ifndef MISOPORT
#define MISOPORT SPIPORT
#endif
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/** \} */
/**
* \name Macros used to generate read register names from platform-specific definitions of ports.
* \brief The various CAT macros (DDR, PORT, and PIN) are used to
* assign port/pin/DDR names to various macro variables. The
* variables are assigned based on the specific connections made in
* the hardware. For example TCCR(TICKTIMER,A) can be used in place of TCCR0A
* if TICKTIMER is defined as 0.
* \{
*/
#if defined(__AVR__)
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#define CAT(x, y) x##y
#define DDR(x) CAT(DDR, x)
#define PORT(x) CAT(PORT, x)
#define PIN(x) CAT(PIN, x)
#endif
/* TODO: Move to CPU specific */
#if defined(CONTIKI_TARGET_MULLE)
#define CAT(x, y) x##y.BYTE
#define DDR(x) CAT(PD, x)
#define PORT(x) CAT(P, x)
#define PIN(x) CAT(P, x)
#endif
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/** \} */
/**
* \name Pin macros
* \brief These macros convert the platform-specific pin defines into names and functions
* that the source code can directly use.
* \{
*/
#if defined(__AVR_ATmega128RFA1__) || defined(__AVR_ATmega128RFR2__) || defined(__AVR_ATmega256RFR2__)
#define hal_set_rst_low( ) ( TRXPR &= ~( 1 << TRXRST ) ) /**< This macro pulls the RST pin low. */
#define hal_set_rst_high( ) ( TRXPR |= ( 1 << TRXRST ) ) /**< This macro pulls the RST pin high. */
#define hal_set_slptr_high( ) ( TRXPR |= ( 1 << SLPTR ) ) /**< This macro pulls the SLP_TR pin high. */
#define hal_set_slptr_low( ) ( TRXPR &= ~( 1 << SLPTR ) ) /**< This macro pulls the SLP_TR pin low. */
#define hal_get_slptr( ) ( TRXPR & ( 1 << SLPTR ) ) /**< Read current state of the SLP_TR pin (High/Low). */
#else
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#define SLP_TR SLPTRPIN /**< Pin number that corresponds to the SLP_TR pin. */
#define DDR_SLP_TR DDR( SLPTRPORT ) /**< Data Direction Register that corresponds to the port where SLP_TR is connected. */
#define PORT_SLP_TR PORT( SLPTRPORT ) /**< Port (Write Access) where SLP_TR is connected. */
#define PIN_SLP_TR PIN( SLPTRPORT ) /**< Pin (Read Access) where SLP_TR is connected. */
#define hal_set_slptr_high( ) ( PORT_SLP_TR |= ( 1 << SLP_TR ) ) /**< This macro pulls the SLP_TR pin high. */
#define hal_set_slptr_low( ) ( PORT_SLP_TR &= ~( 1 << SLP_TR ) ) /**< This macro pulls the SLP_TR pin low. */
#define hal_get_slptr( ) ( PIN_SLP_TR & ( 1 << SLP_TR ) ) /**< Read current state of the SLP_TR pin (High/Low). */
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#define RST RSTPIN /**< Pin number that corresponds to the RST pin. */
#define DDR_RST DDR( RSTPORT ) /**< Data Direction Register that corresponds to the port where RST is */
#define PORT_RST PORT( RSTPORT ) /**< Port (Write Access) where RST is connected. */
#define PIN_RST PIN( RSTPORT /* BUG? */) /**< Pin (Read Access) where RST is connected. */
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#define hal_set_rst_high( ) ( PORT_RST |= ( 1 << RST ) ) /**< This macro pulls the RST pin high. */
#define hal_set_rst_low( ) ( PORT_RST &= ~( 1 << RST ) ) /**< This macro pulls the RST pin low. */
#define hal_get_rst( ) ( ( PIN_RST & ( 1 << RST ) ) >> RST ) /**< Read current state of the RST pin (High/Low). */
#define HAL_SS_PIN SSPIN /**< The slave select pin. */
#define HAL_SCK_PIN SCKPIN /**< Data bit for SCK. */
#define HAL_MOSI_PIN MOSIPIN
#define HAL_MISO_PIN MISOPIN
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#define HAL_PORT_SPI PORT( SPIPORT ) /**< The SPI module is located on PORTB. */
#define HAL_PORT_SS PORT( SSPORT )
#define HAL_PORT_SCK PORT( SCKPORT )
#define HAL_PORT_MOSI PORT( MOSIPORT ) /**< The SPI module uses GPIO might be split on different ports. */
#define HAL_PORT_MISO PORT( MISOPORT ) /**< The SPI module uses GPIO might be split on different ports. */
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#define HAL_DDR_SPI DDR( SPIPORT ) /**< Data Direction Register for PORTB. */
#define HAL_DDR_SS DDR( SSPORT ) /**< Data Direction Register for MISO GPIO pin. */
#define HAL_DDR_SCK DDR( SCKPORT ) /**< Data Direction Register for MISO GPIO pin. */
#define HAL_DDR_MOSI DDR( MOSIPORT ) /**< Data Direction Register for MISO GPIO pin. */
#define HAL_DDR_MISO DDR( MISOPORT ) /**< Data Direction Register for MOSI GPIO pin. */
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#define HAL_DD_SS SSPIN /**< Data Direction bit for SS. */
#define HAL_DD_SCK SCKPIN /**< Data Direction bit for SCK. */
#define HAL_DD_MOSI MOSIPIN /**< Data Direction bit for MOSI. */
#define HAL_DD_MISO MISOPIN /**< Data Direction bit for MISO. */
#endif /* defined(__AVR_ATmega128RFA1__) || defined(__AVR_ATmega256RFR2__) */
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/** \} */
#define HAL_SS_HIGH( ) (HAL_PORT_SS |= ( 1 << HAL_SS_PIN )) /**< MACRO for pulling SS high. */
#define HAL_SS_LOW( ) (HAL_PORT_SS &= ~( 1 << HAL_SS_PIN )) /**< MACRO for pulling SS low. */
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#if defined(__AVR__)
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#if PLATFORM_TYPE == ZIGBIT
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// IRQ E5 for Zigbit example
#define RADIO_VECT INT5_vect
#define HAL_ENABLE_RADIO_INTERRUPT( ) { ( EIMSK |= ( 1 << INT5 ) ) ; EICRB |= 0x0C ; PORTE &= ~(1<<PE5); DDRE &= ~(1<<DDE5); }
#define HAL_DISABLE_RADIO_INTERRUPT( ) ( EIMSK &= ~( 1 << INT5 ) )
#else
#define RADIO_VECT TIMER1_CAPT_vect
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// Raven and Jackdaw
#define HAL_ENABLE_RADIO_INTERRUPT( ) { TCCR1B = ( 1 << ICES1 ) | ( 1 << CS10 ); TIFR1 |= (1 << ICF1); TIMSK1 |= ( 1 << ICIE1 ) ; }
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#define HAL_DISABLE_RADIO_INTERRUPT( ) ( TIMSK1 &= ~( 1 << ICIE1 ) )
#endif
#define HAL_ENABLE_OVERFLOW_INTERRUPT( ) ( TIMSK1 |= ( 1 << TOIE1 ) )
#define HAL_DISABLE_OVERFLOW_INTERRUPT( ) ( TIMSK1 &= ~( 1 << TOIE1 ) )
/** This macro will protect the following code from interrupts.*/
#define HAL_ENTER_CRITICAL_REGION( ) {uint8_t volatile saved_sreg = SREG; cli( )
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/** This macro must always be used in conjunction with HAL_ENTER_CRITICAL_REGION
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so that interrupts are enabled again.*/
#define HAL_LEAVE_CRITICAL_REGION( ) SREG = saved_sreg;}
#else /* MULLE */
#define HAL_ENABLE_RADIO_INTERRUPT( ) ( INT1IC.BYTE |= 1 )
#define HAL_DISABLE_RADIO_INTERRUPT( ) ( INT1IC.BYTE &= ~(1) )
#define HAL_ENABLE_OVERFLOW_INTERRUPT( ) ( TB4IC.BYTE = 1 )
#define HAL_DISABLE_OVERFLOW_INTERRUPT( ) ( TB4IC.BYTE = 0 )
/** This macro will protect the following code from interrupts.*/
#define HAL_ENTER_CRITICAL_REGION( ) MULLE_ENTER_CRITICAL_REGION( )
/** This macro must always be used in conjunction with HAL_ENTER_CRITICAL_REGION
so that interrupts are enabled again.*/
#define HAL_LEAVE_CRITICAL_REGION( ) MULLE_LEAVE_CRITICAL_REGION( )
#endif /* !__AVR__ */
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/** \brief Enable the interrupt from the radio transceiver.
*/
#define hal_enable_trx_interrupt( ) HAL_ENABLE_RADIO_INTERRUPT( )
/** \brief Disable the interrupt from the radio transceiver.
*
* \retval 0 if the pin is low, 1 if the pin is high.
*/
#define hal_disable_trx_interrupt( ) HAL_DISABLE_RADIO_INTERRUPT( )
/*============================ TYPDEFS =======================================*/
/*============================ PROTOTYPES ====================================*/
/*============================ MACROS ========================================*/
/** \name Macros for radio operation.
* \{
*/
#define HAL_BAT_LOW_MASK ( 0x80 ) /**< Mask for the BAT_LOW interrupt. */
#define HAL_TRX_UR_MASK ( 0x40 ) /**< Mask for the TRX_UR interrupt. */
#define HAL_TRX_END_MASK ( 0x08 ) /**< Mask for the TRX_END interrupt. */
#define HAL_RX_START_MASK ( 0x04 ) /**< Mask for the RX_START interrupt. */
#define HAL_PLL_UNLOCK_MASK ( 0x02 ) /**< Mask for the PLL_UNLOCK interrupt. */
#define HAL_PLL_LOCK_MASK ( 0x01 ) /**< Mask for the PLL_LOCK interrupt. */
#define HAL_MIN_FRAME_LENGTH ( 0x03 ) /**< A frame should be at least 3 bytes. */
#define HAL_MAX_FRAME_LENGTH ( 0x7F ) /**< A frame should no more than 127 bytes. */
/** \} */
/*============================ TYPDEFS =======================================*/
/** \struct hal_rx_frame_t
* \brief This struct defines the rx data container.
*
* \see hal_frame_read
*/
typedef struct{
uint8_t length; /**< Length of frame. */
uint8_t data[ HAL_MAX_FRAME_LENGTH ]; /**< Actual frame data. */
uint8_t lqi; /**< LQI value for received frame. */
bool crc; /**< Flag - did CRC pass for received frame? */
} hal_rx_frame_t;
/*============================ PROTOTYPES ====================================*/
void hal_init( void );
/* Hack for atmega128rfa1 with integrated radio. Access registers directly, not through SPI */
#if defined(__AVR_ATmega128RFA1__) || defined(__AVR_ATmega128RFR2__) || defined(__AVR_ATmega256RFR2__)
//#define hal_register_read(address) _SFR_MEM8((uint16_t)address)
#define hal_register_read(address) address
uint8_t hal_subregister_read( uint16_t address, uint8_t mask, uint8_t position );
void hal_subregister_write( uint16_t address, uint8_t mask, uint8_t position,
uint8_t value );
//#define hal_register_write(address, value) _SFR_MEM8((uint16_t)address)=value
#define hal_register_write(address, value) address=value
//#define hal_subregister_read( address, mask, position ) (_SFR_MEM8((uint16_t)address)&mask)>>position
//#define hal_subregister_read1( address, mask, position ) (address&mask)>>position
//#define hal_subregister_write( address, mask, position, value ) address=(address<<position)&mask
#else
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uint8_t hal_register_read( uint8_t address );
void hal_register_write( uint8_t address, uint8_t value );
uint8_t hal_subregister_read( uint8_t address, uint8_t mask, uint8_t position );
void hal_subregister_write( uint8_t address, uint8_t mask, uint8_t position,
uint8_t value );
#endif
void hal_frame_read(hal_rx_frame_t *rx_frame);
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void hal_frame_write( uint8_t *write_buffer, uint8_t length );
void hal_sram_read( uint8_t address, uint8_t length, uint8_t *data );
void hal_sram_write( uint8_t address, uint8_t length, uint8_t *data );
/* Number of receive buffers in RAM. */
#ifndef RF230_CONF_RX_BUFFERS
#define RF230_CONF_RX_BUFFERS 1
#endif
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#endif
/** @} */
/*EOF*/