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[/] [sockit_owm/] [trunk/] [HAL/] [src/] [ownet.c] - Rev 2
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//--------------------------------------------------------------------------- // Copyright (C) 2000 Dallas Semiconductor Corporation, All Rights Reserved. // // Permission is hereby granted, free of charge, to any person obtaining a // copy of this software and associated documentation files (the "Software"), // to deal in the Software without restriction, including without limitation // the rights to use, copy, modify, merge, publish, distribute, sublicense, // and/or sell copies of the Software, and to permit persons to whom the // Software is furnished to do so, subject to the following conditions: // // The above copyright notice and this permission notice shall be included // in all copies or substantial portions of the Software. // // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS // OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF // MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. // IN NO EVENT SHALL DALLAS SEMICONDUCTOR BE LIABLE FOR ANY CLAIM, DAMAGES // OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, // ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR // OTHER DEALINGS IN THE SOFTWARE. // // Except as contained in this notice, the name of Dallas Semiconductor // shall not be used except as stated in the Dallas Semiconductor // Branding Policy. //--------------------------------------------------------------------------- // // ownet.C - Network functions for 1-Wire net devices. // // Version: 3.00 // // History: 1.00 -> 1.01 Change to owFamilySearchSetup, LastDiscrepancy[portnum] // was set to 64 instead of 8 to enable devices with // early contention to go in the '0' direction first. // 1.02 -> 1.03 Initialized goodbits in owVerify // 1.03 -> 2.00 Changed 'MLan' to 'ow'. Added support for // multiple ports. // 2.00 -> 2.01 Added support for owError library // 2.01 -> 3.00 Make search functions consistent with AN187 // #include <stdio.h> #include "ownet.h" // exportable functions defined in ownet.c SMALLINT bitacc(SMALLINT,SMALLINT,SMALLINT,uchar *); // global variables for this module to hold search state information static SMALLINT LastDiscrepancy[MAX_PORTNUM]; static SMALLINT LastFamilyDiscrepancy[MAX_PORTNUM]; static SMALLINT LastDevice[MAX_PORTNUM]; uchar SerialNum[MAX_PORTNUM][8]; //-------------------------------------------------------------------------- // The 'owFirst' finds the first device on the 1-Wire Net This function // contains one parameter 'alarm_only'. When // 'alarm_only' is TRUE (1) the find alarm command 0xEC is // sent instead of the normal search command 0xF0. // Using the find alarm command 0xEC will limit the search to only // 1-Wire devices that are in an 'alarm' state. // // 'portnum' - number 0 to MAX_PORTNUM-1. This number is provided to // indicate the symbolic port number. // 'do_reset' - TRUE (1) perform reset before search, FALSE (0) do not // perform reset before search. // 'alarm_only' - TRUE (1) the find alarm command 0xEC is // sent instead of the normal search command 0xF0 // // Returns: TRUE (1) : when a 1-Wire device was found and it's // Serial Number placed in the global SerialNum[portnum] // FALSE (0): There are no devices on the 1-Wire Net. // SMALLINT owFirst(int portnum, SMALLINT do_reset, SMALLINT alarm_only) { // reset the search state LastDiscrepancy[portnum] = 0; LastDevice[portnum] = FALSE; LastFamilyDiscrepancy[portnum] = 0; return owNext(portnum,do_reset,alarm_only); } //-------------------------------------------------------------------------- // The 'owNext' function does a general search. This function // continues from the previos search state. The search state // can be reset by using the 'owFirst' function. // This function contains one parameter 'alarm_only'. // When 'alarm_only' is TRUE (1) the find alarm command // 0xEC is sent instead of the normal search command 0xF0. // Using the find alarm command 0xEC will limit the search to only // 1-Wire devices that are in an 'alarm' state. // // 'portnum' - number 0 to MAX_PORTNUM-1. This number is provided to // indicate the symbolic port number. // 'do_reset' - TRUE (1) perform reset before search, FALSE (0) do not // perform reset before search. // 'alarm_only' - TRUE (1) the find alarm command 0xEC is // sent instead of the normal search command 0xF0 // // Returns: TRUE (1) : when a 1-Wire device was found and it's // Serial Number placed in the global SerialNum[portnum] // FALSE (0): when no new device was found. Either the // last search was the last device or there // are no devices on the 1-Wire Net. // SMALLINT owNext(int portnum, SMALLINT do_reset, SMALLINT alarm_only) { uchar bit_test, search_direction, bit_number; uchar last_zero, serial_byte_number, next_result; uchar serial_byte_mask; uchar lastcrc8; // initialize for search bit_number = 1; last_zero = 0; serial_byte_number = 0; serial_byte_mask = 1; next_result = 0; setcrc8(portnum,0); // if the last call was not the last one if (!LastDevice[portnum]) { // check if reset first is requested if (do_reset) { // reset the 1-wire // if there are no parts on 1-wire, return FALSE if (!owTouchReset(portnum)) { // printf("owTouchReset failed\r\n"); // reset the search LastDiscrepancy[portnum] = 0; LastFamilyDiscrepancy[portnum] = 0; OWERROR(OWERROR_NO_DEVICES_ON_NET); return FALSE; } } // If finding alarming devices issue a different command if (alarm_only) owWriteByte(portnum,0xEC); // issue the alarming search command else owWriteByte(portnum,0xF0); // issue the search command //pause before beginning the search //usDelay(100); // loop to do the search do { // read a bit and its compliment bit_test = owTouchBit(portnum,1) << 1; bit_test |= owTouchBit(portnum,1); // check for no devices on 1-wire if (bit_test == 3) break; else { // all devices coupled have 0 or 1 if (bit_test > 0) search_direction = !(bit_test & 0x01); // bit write value for search else { // if this discrepancy if before the Last Discrepancy // on a previous next then pick the same as last time if (bit_number < LastDiscrepancy[portnum]) search_direction = ((SerialNum[portnum][serial_byte_number] & serial_byte_mask) > 0); else // if equal to last pick 1, if not then pick 0 search_direction = (bit_number == LastDiscrepancy[portnum]); // if 0 was picked then record its position in LastZero if (search_direction == 0) { last_zero = bit_number; // check for Last discrepancy in family if (last_zero < 9) LastFamilyDiscrepancy[portnum] = last_zero; } } // set or clear the bit in the SerialNum[portnum] byte serial_byte_number // with mask serial_byte_mask if (search_direction == 1) SerialNum[portnum][serial_byte_number] |= serial_byte_mask; else SerialNum[portnum][serial_byte_number] &= ~serial_byte_mask; // serial number search direction write bit owTouchBit(portnum,search_direction); // increment the byte counter bit_number // and shift the mask serial_byte_mask bit_number++; serial_byte_mask <<= 1; // if the mask is 0 then go to new SerialNum[portnum] byte serial_byte_number // and reset mask if (serial_byte_mask == 0) { // The below has been added to accomidate the valid CRC with the // possible changing serial number values of the DS28E04. if (((SerialNum[portnum][0] & 0x7F) == 0x1C) && (serial_byte_number == 1)) lastcrc8 = docrc8(portnum,0x7F); else lastcrc8 = docrc8(portnum,SerialNum[portnum][serial_byte_number]); // accumulate the CRC serial_byte_number++; serial_byte_mask = 1; } } } while(serial_byte_number < 8); // loop until through all SerialNum[portnum] bytes 0-7 // if the search was successful then if (!((bit_number < 65) || lastcrc8)) { // search successful so set LastDiscrepancy[portnum],LastDevice[portnum],next_result LastDiscrepancy[portnum] = last_zero; LastDevice[portnum] = (LastDiscrepancy[portnum] == 0); next_result = TRUE; } } // if no device found then reset counters so next 'next' will be // like a first if (!next_result || !SerialNum[portnum][0]) { LastDiscrepancy[portnum] = 0; LastDevice[portnum] = FALSE; LastFamilyDiscrepancy[portnum] = 0; next_result = FALSE; } return next_result; } //-------------------------------------------------------------------------- // The 'owSerialNum' function either reads or sets the SerialNum buffer // that is used in the search functions 'owFirst' and 'owNext'. // This function contains two parameters, 'serialnum_buf' is a pointer // to a buffer provided by the caller. 'serialnum_buf' should point to // an array of 8 unsigned chars. The second parameter is a flag called // 'do_read' that is TRUE (1) if the operation is to read and FALSE // (0) if the operation is to set the internal SerialNum buffer from // the data in the provided buffer. // // 'portnum' - number 0 to MAX_PORTNUM-1. This number is provided to // indicate the symbolic port number. // 'serialnum_buf' - buffer to that contains the serial number to set // when do_read = FALSE (0) and buffer to get the serial // number when do_read = TRUE (1). // 'do_read' - flag to indicate reading (1) or setting (0) the current // serial number. // void owSerialNum(int portnum, uchar *serialnum_buf, SMALLINT do_read) { uchar i; // read the internal buffer and place in 'serialnum_buf' if (do_read) { for (i = 0; i < 8; i++) serialnum_buf[i] = SerialNum[portnum][i]; } // set the internal buffer from the data in 'serialnum_buf' else { for (i = 0; i < 8; i++) SerialNum[portnum][i] = serialnum_buf[i]; } } //-------------------------------------------------------------------------- // Setup the search algorithm to find a certain family of devices // the next time a search function is called 'owNext'. // // 'portnum' - number 0 to MAX_PORTNUM-1. This number was provided to // OpenCOM to indicate the port number. // 'search_family' - family code type to set the search algorithm to find // next. // void owFamilySearchSetup(int portnum, SMALLINT search_family) { uchar i; // set the search state to find SearchFamily type devices SerialNum[portnum][0] = search_family; for (i = 1; i < 8; i++) SerialNum[portnum][i] = 0; LastDiscrepancy[portnum] = 64; LastDevice[portnum] = FALSE; } //-------------------------------------------------------------------------- // Set the current search state to skip the current family code. // // 'portnum' - number 0 to MAX_PORTNUM-1. This number is provided to // indicate the symbolic port number. // void owSkipFamily(int portnum) { // set the Last discrepancy to last family discrepancy LastDiscrepancy[portnum] = LastFamilyDiscrepancy[portnum]; LastFamilyDiscrepancy[portnum] = 0; // check for end of list if (LastDiscrepancy[portnum] == 0) LastDevice[portnum] = TRUE; } //-------------------------------------------------------------------------- // The 'owAccess' function resets the 1-Wire and sends a MATCH Serial // Number command followed by the current SerialNum code. After this // function is complete the 1-Wire device is ready to accept device-specific // commands. // // 'portnum' - number 0 to MAX_PORTNUM-1. This number is provided to // indicate the symbolic port number. // // Returns: TRUE (1) : reset indicates present and device is ready // for commands. // FALSE (0): reset does not indicate presence or echos 'writes' // are not correct. // SMALLINT owAccess(int portnum) { uchar sendpacket[9]; uchar i; // reset the 1-wire if (owTouchReset(portnum)) { // create a buffer to use with block function // match Serial Number command 0x55 sendpacket[0] = 0x55; // Serial Number for (i = 1; i < 9; i++) sendpacket[i] = SerialNum[portnum][i-1]; // send/recieve the transfer buffer if (owBlock(portnum,FALSE,sendpacket,9)) { // verify that the echo of the writes was correct for (i = 1; i < 9; i++) if (sendpacket[i] != SerialNum[portnum][i-1]) return FALSE; if (sendpacket[0] != 0x55) { OWERROR(OWERROR_WRITE_VERIFY_FAILED); return FALSE; } else return TRUE; } else OWERROR(OWERROR_BLOCK_FAILED); } else OWERROR(OWERROR_NO_DEVICES_ON_NET); // reset or match echo failed return FALSE; } //---------------------------------------------------------------------- // The function 'owVerify' verifies that the current device // is in contact with the 1-Wire Net. // Using the find alarm command 0xEC will verify that the device // is in contact with the 1-Wire Net and is in an 'alarm' state. // // 'portnum' - number 0 to MAX_PORTNUM-1. This number is provided to // indicate the symbolic port number. // 'alarm_only' - TRUE (1) the find alarm command 0xEC // is sent instead of the normal search // command 0xF0. // // Returns: TRUE (1) : when the 1-Wire device was verified // to be on the 1-Wire Net // with alarm_only == FALSE // or verified to be on the 1-Wire Net // AND in an alarm state when // alarm_only == TRUE. // FALSE (0): the 1-Wire device was not on the // 1-Wire Net or if alarm_only // == TRUE, the device may be on the // 1-Wire Net but in a non-alarm state. // SMALLINT owVerify(int portnum, SMALLINT alarm_only) { uchar i,sendlen=0,goodbits=0,cnt=0,s,tst; uchar sendpacket[50]; // construct the search if (alarm_only) sendpacket[sendlen++] = 0xEC; // issue the alarming search command else sendpacket[sendlen++] = 0xF0; // issue the search command // set all bits at first for (i = 1; i <= 24; i++) sendpacket[sendlen++] = 0xFF; // now set or clear apropriate bits for search for (i = 0; i < 64; i++) bitacc(WRITE_FUNCTION,bitacc(READ_FUNCTION,0,i,&SerialNum[portnum][0]),(int)((i+1)*3-1),&sendpacket[1]); // send/recieve the transfer buffer if (owBlock(portnum,TRUE,sendpacket,sendlen)) { // check results to see if it was a success for (i = 0; i < 192; i += 3) { tst = (bitacc(READ_FUNCTION,0,i,&sendpacket[1]) << 1) | bitacc(READ_FUNCTION,0,(int)(i+1),&sendpacket[1]); s = bitacc(READ_FUNCTION,0,cnt++,&SerialNum[portnum][0]); if (tst == 0x03) // no device on line { goodbits = 0; // number of good bits set to zero break; // quit } if (((s == 0x01) && (tst == 0x02)) || ((s == 0x00) && (tst == 0x01)) ) // correct bit goodbits++; // count as a good bit } // check too see if there were enough good bits to be successful if (goodbits >= 8) return TRUE; } else OWERROR(OWERROR_BLOCK_FAILED); // block fail or device not present return FALSE; } //---------------------------------------------------------------------- // Perform a overdrive MATCH command to select the 1-Wire device with // the address in the ID data register. // // 'portnum' - number 0 to MAX_PORTNUM-1. This number is provided to // indicate the symbolic port number. // // Returns: TRUE: If the device is present on the 1-Wire Net and // can do overdrive then the device is selected. // FALSE: Device is not present or not capable of overdrive. // // *Note: This function could be converted to send DS2480 // commands in one packet. // SMALLINT owOverdriveAccess(int portnum) { uchar sendpacket[8]; uchar i, bad_echo = FALSE; // make sure normal level owLevel(portnum,MODE_NORMAL); // force to normal communication speed owSpeed(portnum,MODE_NORMAL); // call the 1-Wire Net reset function if (owTouchReset(portnum)) { // send the match command 0x69 if (owWriteByte(portnum,0x69)) { // switch to overdrive communication speed owSpeed(portnum,MODE_OVERDRIVE); // create a buffer to use with block function // Serial Number for (i = 0; i < 8; i++) sendpacket[i] = SerialNum[portnum][i]; // send/recieve the transfer buffer if (owBlock(portnum,FALSE,sendpacket,8)) { // verify that the echo of the writes was correct for (i = 0; i < 8; i++) if (sendpacket[i] != SerialNum[portnum][i]) bad_echo = TRUE; // if echo ok then success if (!bad_echo) return TRUE; else OWERROR(OWERROR_WRITE_VERIFY_FAILED); } else OWERROR(OWERROR_BLOCK_FAILED); } else OWERROR(OWERROR_WRITE_BYTE_FAILED); } else OWERROR(OWERROR_NO_DEVICES_ON_NET); // failure, force back to normal communication speed owSpeed(portnum,MODE_NORMAL); return FALSE; } //-------------------------------------------------------------------------- // Bit utility to read and write a bit in the buffer 'buf'. // // 'op' - operation (1) to set and (0) to read // 'state' - set (1) or clear (0) if operation is write (1) // 'loc' - bit number location to read or write // 'buf' - pointer to array of bytes that contains the bit // to read or write // // Returns: 1 if operation is set (1) // 0/1 state of bit number 'loc' if operation is reading // SMALLINT bitacc(SMALLINT op, SMALLINT state, SMALLINT loc, uchar *buf) { SMALLINT nbyt,nbit; nbyt = (loc / 8); nbit = loc - (nbyt * 8); if (op == WRITE_FUNCTION) { if (state) buf[nbyt] |= (0x01 << nbit); else buf[nbyt] &= ~(0x01 << nbit); return 1; } else return ((buf[nbyt] >> nbit) & 0x01); }