LMiC adapted to work with SX1272MB2xAS LoRa shield.
Fork of LMiC by
lorabase.h
- Committer:
- GTsapparellas
- Date:
- 2018-04-02
- Revision:
- 8:5879e83f632a
- Parent:
- 7:29058a7ccf23
File content as of revision 8:5879e83f632a:
/******************************************************************************* * Copyright (c) 2014-2015 IBM Corporation. * All rights reserved. This program and the accompanying materials * are made available under the terms of the Eclipse Public License v1.0 * which accompanies this distribution, and is available at * http://www.eclipse.org/legal/epl-v10.html * * Contributors: * IBM Zurich Research Lab - initial API, implementation and documentation * * ///////////////////////////////////////////////////////////////////////////// * * Used by Giorgos Tsapparellas for Internet of Things (IoT) smart monitoring * device for agriculture using LoRaWAN technology. * * Date of issued copy: 25 January 2018 * * Modifications: * - No external modifications of the existing "AS IT IS" software. * *******************************************************************************/ #ifndef _lorabase_h_ #define _lorabase_h_ // ================================================================================ // BEG: Keep in sync with lorabase.hpp // enum _cr_t { CR_4_5=0, CR_4_6, CR_4_7, CR_4_8 }; enum _sf_t { FSK=0, SF7, SF8, SF9, SF10, SF11, SF12, SFrfu }; enum _bw_t { BW125=0, BW250, BW500, BWrfu }; typedef u1_t cr_t; typedef u1_t sf_t; typedef u1_t bw_t; typedef u1_t dr_t; // Radio parameter set (encodes SF/BW/CR/IH/NOCRC) typedef u2_t rps_t; TYPEDEF_xref2rps_t; enum { ILLEGAL_RPS = 0xFF }; enum { DR_PAGE_EU868 = 0x00 }; enum { DR_PAGE_US915 = 0x10 }; // Global maximum frame length enum { STD_PREAMBLE_LEN = 8 }; enum { MAX_LEN_FRAME = 64 }; enum { LEN_DEVNONCE = 2 }; enum { LEN_ARTNONCE = 3 }; enum { LEN_NETID = 3 }; enum { DELAY_JACC1 = 5 }; // in secs enum { DELAY_DNW1 = 1 }; // in secs down window #1 enum { DELAY_EXTDNW2 = 1 }; // in secs enum { DELAY_JACC2 = DELAY_JACC1+(int)DELAY_EXTDNW2 }; // in secs enum { DELAY_DNW2 = DELAY_DNW1 +(int)DELAY_EXTDNW2 }; // in secs down window #1 enum { BCN_INTV_exp = 7 }; enum { BCN_INTV_sec = 1<<BCN_INTV_exp }; enum { BCN_INTV_ms = BCN_INTV_sec*1000L }; enum { BCN_INTV_us = BCN_INTV_ms*1000L }; enum { BCN_RESERVE_ms = 2120 }; // space reserved for beacon and NWK management enum { BCN_GUARD_ms = 3000 }; // end of beacon period to prevent interference with beacon enum { BCN_SLOT_SPAN_ms = 30 }; // 2^12 reception slots a this span enum { BCN_WINDOW_ms = BCN_INTV_ms-(int)BCN_GUARD_ms-(int)BCN_RESERVE_ms }; enum { BCN_RESERVE_us = 2120000 }; enum { BCN_GUARD_us = 3000000 }; enum { BCN_SLOT_SPAN_us = 30000 }; #if defined(CFG_eu868) // ============================================== enum _dr_eu868_t { DR_SF12=0, DR_SF11, DR_SF10, DR_SF9, DR_SF8, DR_SF7, DR_SF7B, DR_FSK, DR_NONE }; enum { DR_DFLTMIN = DR_SF7 }; enum { DR_PAGE = DR_PAGE_EU868 }; // Default frequency plan for EU 868MHz ISM band // Bands: // g1 : 1% 14dBm // g2 : 0.1% 14dBm // g3 : 10% 27dBm // freq band datarates enum { EU868_F1 = 868100000, // g1 SF7-12 EU868_F2 = 868300000, // g1 SF7-12 FSK SF7/250 EU868_F3 = 868500000, // g1 SF7-12 EU868_F4 = 868850000, // g2 SF7-12 EU868_F5 = 869050000, // g2 SF7-12 EU868_F6 = 869525000, // g3 SF7-12 EU868_J4 = 864100000, // g2 SF7-12 used during join EU868_J5 = 864300000, // g2 SF7-12 ditto EU868_J6 = 864500000, // g2 SF7-12 ditto }; enum { EU868_FREQ_MIN = 863000000, EU868_FREQ_MAX = 870000000 }; enum { CHNL_PING = 5 }; enum { FREQ_PING = EU868_F6 }; // default ping freq enum { DR_PING = SF9 }; // default ping DR enum { CHNL_DNW2 = 5 }; enum { FREQ_DNW2 = EU868_F6 }; enum { DR_DNW2 = DR_SF12 }; enum { CHNL_BCN = 5 }; enum { FREQ_BCN = EU868_F6 }; enum { DR_BCN = DR_SF9 }; enum { AIRTIME_BCN = 144384 }; // micros enum { // Beacon frame format EU SF9 OFF_BCN_NETID = 0, OFF_BCN_TIME = 3, OFF_BCN_CRC1 = 7, OFF_BCN_INFO = 8, OFF_BCN_LAT = 9, OFF_BCN_LON = 12, OFF_BCN_CRC2 = 15, LEN_BCN = 17 }; #elif defined(CFG_us915) // ========================================= enum _dr_us915_t { DR_SF10=0, DR_SF9, DR_SF8, DR_SF7, DR_SF8C, DR_NONE, // Devices behind a router: DR_SF12CR=8, DR_SF11CR, DR_SF10CR, DR_SF9CR, DR_SF8CR, DR_SF7CR }; enum { DR_DFLTMIN = DR_SF8C }; enum { DR_PAGE = DR_PAGE_US915 }; // Default frequency plan for US 915MHz enum { US915_125kHz_UPFBASE = 902300000, //enum { US915_125kHz_UPFBASE = 911900000, US915_125kHz_UPFSTEP = 200000, US915_500kHz_UPFBASE = 903000000, US915_500kHz_UPFSTEP = 1600000, US915_500kHz_DNFBASE = 923300000, US915_500kHz_DNFSTEP = 600000 }; enum { US915_FREQ_MIN = 902000000, US915_FREQ_MAX = 928000000 }; enum { CHNL_PING = 0 }; // used only for default init of state (follows beacon - rotating) enum { FREQ_PING = US915_500kHz_DNFBASE + CHNL_PING*US915_500kHz_DNFSTEP }; // default ping freq enum { DR_PING = DR_SF10CR }; // default ping DR enum { CHNL_DNW2 = 0 }; enum { FREQ_DNW2 = US915_500kHz_DNFBASE + CHNL_DNW2*US915_500kHz_DNFSTEP }; enum { DR_DNW2 = DR_SF12CR }; enum { CHNL_BCN = 0 }; // used only for default init of state (rotating beacon scheme) enum { DR_BCN = DR_SF10CR }; enum { AIRTIME_BCN = 72192 }; // micros enum { // Beacon frame format US SF10 OFF_BCN_NETID = 0, OFF_BCN_TIME = 3, OFF_BCN_CRC1 = 7, OFF_BCN_INFO = 9, OFF_BCN_LAT = 10, OFF_BCN_LON = 13, OFF_BCN_RFU1 = 16, OFF_BCN_CRC2 = 17, LEN_BCN = 19 }; #endif // =================================================== enum { // Join Request frame format OFF_JR_HDR = 0, OFF_JR_ARTEUI = 1, OFF_JR_DEVEUI = 9, OFF_JR_DEVNONCE = 17, OFF_JR_MIC = 19, LEN_JR = 23 }; enum { // Join Accept frame format OFF_JA_HDR = 0, OFF_JA_ARTNONCE = 1, OFF_JA_NETID = 4, OFF_JA_DEVADDR = 7, OFF_JA_RFU = 11, OFF_JA_DLSET = 11, OFF_JA_RXDLY = 12, OFF_CFLIST = 13, LEN_JA = 17, LEN_JAEXT = 17+16 }; enum { // Data frame format OFF_DAT_HDR = 0, OFF_DAT_ADDR = 1, OFF_DAT_FCT = 5, OFF_DAT_SEQNO = 6, OFF_DAT_OPTS = 8, }; enum { MAX_LEN_PAYLOAD = MAX_LEN_FRAME-(int)OFF_DAT_OPTS-4 }; enum { // Bitfields in frame format octet HDR_FTYPE = 0xE0, HDR_RFU = 0x1C, HDR_MAJOR = 0x03 }; enum { HDR_FTYPE_DNFLAG = 0x20 }; // flags DN frame except for HDR_FTYPE_PROP enum { // Values of frame type bit field HDR_FTYPE_JREQ = 0x00, HDR_FTYPE_JACC = 0x20, HDR_FTYPE_DAUP = 0x40, // data (unconfirmed) up HDR_FTYPE_DADN = 0x60, // data (unconfirmed) dn HDR_FTYPE_DCUP = 0x80, // data confirmed up HDR_FTYPE_DCDN = 0xA0, // data confirmed dn HDR_FTYPE_REJOIN = 0xC0, // rejoin for roaming HDR_FTYPE_PROP = 0xE0 }; enum { HDR_MAJOR_V1 = 0x00, }; enum { // Bitfields in frame control octet FCT_ADREN = 0x80, FCT_ADRARQ = 0x40, FCT_ACK = 0x20, FCT_MORE = 0x10, // also in DN direction: Class B indicator FCT_OPTLEN = 0x0F, }; enum { // In UP direction: signals class B enabled FCT_CLASSB = FCT_MORE }; enum { NWKID_MASK = (int)0xFE000000, NWKID_BITS = 7 }; // MAC uplink commands downwlink too enum { // Class A MCMD_LCHK_REQ = 0x02, // - link check request : - MCMD_LADR_ANS = 0x03, // - link ADR answer : u1:7-3:RFU, 3/2/1: pow/DR/Ch ACK MCMD_DCAP_ANS = 0x04, // - duty cycle answer : - MCMD_DN2P_ANS = 0x05, // - 2nd DN slot status : u1:7-2:RFU 1/0:datarate/channel ack MCMD_DEVS_ANS = 0x06, // - device status ans : u1:battery 0,1-254,255=?, u1:7-6:RFU,5-0:margin(-32..31) MCMD_SNCH_ANS = 0x07, // - set new channel : u1: 7-2=RFU, 1/0:DR/freq ACK // Class B MCMD_PING_IND = 0x10, // - pingability indic : u1: 7=RFU, 6-4:interval, 3-0:datarate MCMD_PING_ANS = 0x11, // - ack ping freq : u1: 7-1:RFU, 0:freq ok MCMD_BCNI_REQ = 0x12, // - next beacon start : - }; // MAC downlink commands enum { // Class A MCMD_LCHK_ANS = 0x02, // link check answer : u1:margin 0-254,255=unknown margin / u1:gwcnt MCMD_LADR_REQ = 0x03, // link ADR request : u1:DR/TXPow, u2:chmask, u1:chpage/repeat MCMD_DCAP_REQ = 0x04, // duty cycle cap : u1:255 dead [7-4]:RFU, [3-0]:cap 2^-k MCMD_DN2P_SET = 0x05, // 2nd DN window param: u1:7-4:RFU/3-0:datarate, u3:freq MCMD_DEVS_REQ = 0x06, // device status req : - MCMD_SNCH_REQ = 0x07, // set new channel : u1:chidx, u3:freq, u1:DRrange // Class B MCMD_PING_SET = 0x11, // set ping freq : u3: freq MCMD_BCNI_ANS = 0x12, // next beacon start : u2: delay(in TUNIT millis), u1:channel }; enum { MCMD_BCNI_TUNIT = 30 // time unit of delay value in millis }; enum { MCMD_LADR_ANS_RFU = 0xF8, // RFU bits MCMD_LADR_ANS_POWACK = 0x04, // 0=not supported power level MCMD_LADR_ANS_DRACK = 0x02, // 0=unknown data rate MCMD_LADR_ANS_CHACK = 0x01, // 0=unknown channel enabled }; enum { MCMD_DN2P_ANS_RFU = 0xFC, // RFU bits MCMD_DN2P_ANS_DRACK = 0x02, // 0=unknown data rate MCMD_DN2P_ANS_CHACK = 0x01, // 0=unknown channel enabled }; enum { MCMD_SNCH_ANS_RFU = 0xFC, // RFU bits MCMD_SNCH_ANS_DRACK = 0x02, // 0=unknown data rate MCMD_SNCH_ANS_FQACK = 0x01, // 0=rejected channel frequency }; enum { MCMD_PING_ANS_RFU = 0xFE, MCMD_PING_ANS_FQACK = 0x01 }; enum { MCMD_DEVS_EXT_POWER = 0x00, // external power supply MCMD_DEVS_BATT_MIN = 0x01, // min battery value MCMD_DEVS_BATT_MAX = 0xFE, // max battery value MCMD_DEVS_BATT_NOINFO = 0xFF, // unknown battery level }; // Bit fields byte#3 of MCMD_LADR_REQ payload enum { MCMD_LADR_CHP_125ON = 0x60, // special channel page enable, bits applied to 64..71 MCMD_LADR_CHP_125OFF = 0x70, // ditto MCMD_LADR_N3RFU_MASK = 0x80, MCMD_LADR_CHPAGE_MASK = 0xF0, MCMD_LADR_REPEAT_MASK = 0x0F, MCMD_LADR_REPEAT_1 = 0x01, MCMD_LADR_CHPAGE_1 = 0x10 }; // Bit fields byte#0 of MCMD_LADR_REQ payload enum { MCMD_LADR_DR_MASK = 0xF0, MCMD_LADR_POW_MASK = 0x0F, MCMD_LADR_DR_SHIFT = 4, MCMD_LADR_POW_SHIFT = 0, #if defined(CFG_eu868) MCMD_LADR_SF12 = DR_SF12<<4, MCMD_LADR_SF11 = DR_SF11<<4, MCMD_LADR_SF10 = DR_SF10<<4, MCMD_LADR_SF9 = DR_SF9 <<4, MCMD_LADR_SF8 = DR_SF8 <<4, MCMD_LADR_SF7 = DR_SF7 <<4, MCMD_LADR_SF7B = DR_SF7B<<4, MCMD_LADR_FSK = DR_FSK <<4, MCMD_LADR_20dBm = 0, MCMD_LADR_14dBm = 1, MCMD_LADR_11dBm = 2, MCMD_LADR_8dBm = 3, MCMD_LADR_5dBm = 4, MCMD_LADR_2dBm = 5, #elif defined(CFG_us915) MCMD_LADR_SF10 = DR_SF10<<4, MCMD_LADR_SF9 = DR_SF9 <<4, MCMD_LADR_SF8 = DR_SF8 <<4, MCMD_LADR_SF7 = DR_SF7 <<4, MCMD_LADR_SF8C = DR_SF8C<<4, MCMD_LADR_SF12CR = DR_SF12CR<<4, MCMD_LADR_SF11CR = DR_SF11CR<<4, MCMD_LADR_SF10CR = DR_SF10CR<<4, MCMD_LADR_SF9CR = DR_SF9CR<<4, MCMD_LADR_SF8CR = DR_SF8CR<<4, MCMD_LADR_SF7CR = DR_SF7CR<<4, MCMD_LADR_30dBm = 0, MCMD_LADR_28dBm = 1, MCMD_LADR_26dBm = 2, MCMD_LADR_24dBm = 3, MCMD_LADR_22dBm = 4, MCMD_LADR_20dBm = 5, MCMD_LADR_18dBm = 6, MCMD_LADR_16dBm = 7, MCMD_LADR_14dBm = 8, MCMD_LADR_12dBm = 9, MCMD_LADR_10dBm = 10 #endif }; // Device address typedef u4_t devaddr_t; // RX quality (device) enum { RSSI_OFF=64, SNR_SCALEUP=4 }; inline sf_t getSf (rps_t params) { return (sf_t)(params & 0x7); } inline rps_t setSf (rps_t params, sf_t sf) { return (rps_t)((params & ~0x7) | sf); } inline bw_t getBw (rps_t params) { return (bw_t)((params >> 3) & 0x3); } inline rps_t setBw (rps_t params, bw_t cr) { return (rps_t)((params & ~0x18) | (cr<<3)); } inline cr_t getCr (rps_t params) { return (cr_t)((params >> 5) & 0x3); } inline rps_t setCr (rps_t params, cr_t cr) { return (rps_t)((params & ~0x60) | (cr<<5)); } inline int getNocrc(rps_t params) { return ((params >> 7) & 0x1); } inline rps_t setNocrc(rps_t params, int nocrc) { return (rps_t)((params & ~0x80) | (nocrc<<7)); } inline int getIh (rps_t params) { return ((params >> 8) & 0xFF); } inline rps_t setIh (rps_t params, int ih) { return (rps_t)((params & ~0xFF00) | (ih<<8)); } inline rps_t makeRps (sf_t sf, bw_t bw, cr_t cr, int ih, int nocrc) { return sf | (bw<<3) | (cr<<5) | (nocrc?(1<<7):0) | ((ih&0xFF)<<8); } #define MAKERPS(sf,bw,cr,ih,nocrc) ((rps_t)((sf) | ((bw)<<3) | ((cr)<<5) | ((nocrc)?(1<<7):0) | ((ih&0xFF)<<8))) // Two frames with params r1/r2 would interfere on air: same SFx + BWx inline int sameSfBw(rps_t r1, rps_t r2) { return ((r1^r2)&0x1F) == 0; } extern const u1_t _DR2RPS_CRC[]; inline rps_t updr2rps (dr_t dr) { return (rps_t)_DR2RPS_CRC[dr+1]; } inline rps_t dndr2rps (dr_t dr) { return setNocrc(updr2rps(dr),1); } inline int isFasterDR (dr_t dr1, dr_t dr2) { return dr1 > dr2; } inline int isSlowerDR (dr_t dr1, dr_t dr2) { return dr1 < dr2; } inline dr_t incDR (dr_t dr) { return _DR2RPS_CRC[dr+2]==ILLEGAL_RPS ? dr : (dr_t)(dr+1); } // increase data rate inline dr_t decDR (dr_t dr) { return _DR2RPS_CRC[dr ]==ILLEGAL_RPS ? dr : (dr_t)(dr-1); } // decrease data rate inline dr_t assertDR (dr_t dr) { return _DR2RPS_CRC[dr+1]==ILLEGAL_RPS ? DR_DFLTMIN : dr; } // force into a valid DR inline bit_t validDR (dr_t dr) { return _DR2RPS_CRC[dr+1]!=ILLEGAL_RPS; } // in range inline dr_t lowerDR (dr_t dr, u1_t n) { while(n--){dr=decDR(dr);} return dr; } // decrease data rate by n steps // // BEG: Keep in sync with lorabase.hpp // ================================================================================ // Convert between dBm values and power codes (MCMD_LADR_XdBm) s1_t pow2dBm (u1_t mcmd_ladr_p1); // Calculate airtime ostime_t calcAirTime (rps_t rps, u1_t plen); // Sensitivity at given SF/BW int getSensitivity (rps_t rps); #endif // _lorabase_h_