// // Copyright 2010-2013,2015 Ettus Research LLC // // This program is free software: you can redistribute it and/or modify // it under the terms of the GNU General Public License as published by // the Free Software Foundation, either version 3 of the License, or // (at your option) any later version. // // This program is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // // You should have received a copy of the GNU General Public License // along with this program. If not, see . // #include #include #include #include #include #include #include #include #include #include #include using namespace uhd; using namespace uhd::usrp; /*********************************************************************** * Constants **********************************************************************/ static const size_t SERIAL_LEN = 9; static const size_t NAME_MAX_LEN = 32 - SERIAL_LEN; /*********************************************************************** * Utility functions **********************************************************************/ //! convert a string to a byte vector to write to eeprom static byte_vector_t string_to_uint16_bytes(const std::string &num_str){ const uint16_t num = boost::lexical_cast(num_str); const byte_vector_t lsb_msb = boost::assign::list_of (uint8_t(num >> 0))(uint8_t(num >> 8)); return lsb_msb; } //! convert a byte vector read from eeprom to a string static std::string uint16_bytes_to_string(const byte_vector_t &bytes){ const uint16_t num = (uint16_t(bytes.at(0)) << 0) | (uint16_t(bytes.at(1)) << 8); return (num == 0 or num == 0xffff)? "" : boost::lexical_cast(num); } /*********************************************************************** * Implementation of N100 load/store **********************************************************************/ static const uint8_t N100_EEPROM_ADDR = 0x50; struct n100_eeprom_map{ uint16_t hardware; uint8_t mac_addr[6]; uint32_t subnet; uint32_t ip_addr; uint16_t _pad0; uint16_t revision; uint16_t product; unsigned char _pad1; unsigned char gpsdo; unsigned char serial[SERIAL_LEN]; unsigned char name[NAME_MAX_LEN]; uint32_t gateway; }; enum n200_gpsdo_type{ N200_GPSDO_NONE = 0, N200_GPSDO_INTERNAL = 1, N200_GPSDO_ONBOARD = 2 }; static void load_n100(mboard_eeprom_t &mb_eeprom, i2c_iface &iface){ //extract the hardware number mb_eeprom["hardware"] = uint16_bytes_to_string( iface.read_eeprom(N100_EEPROM_ADDR, offsetof(n100_eeprom_map, hardware), 2) ); //extract the revision number mb_eeprom["revision"] = uint16_bytes_to_string( iface.read_eeprom(N100_EEPROM_ADDR, offsetof(n100_eeprom_map, revision), 2) ); //extract the product code mb_eeprom["product"] = uint16_bytes_to_string( iface.read_eeprom(N100_EEPROM_ADDR, offsetof(n100_eeprom_map, product), 2) ); //extract the addresses mb_eeprom["mac-addr"] = mac_addr_t::from_bytes(iface.read_eeprom( N100_EEPROM_ADDR, offsetof(n100_eeprom_map, mac_addr), 6 )).to_string(); boost::asio::ip::address_v4::bytes_type ip_addr_bytes; byte_copy(iface.read_eeprom(N100_EEPROM_ADDR, offsetof(n100_eeprom_map, ip_addr), 4), ip_addr_bytes); mb_eeprom["ip-addr"] = boost::asio::ip::address_v4(ip_addr_bytes).to_string(); byte_copy(iface.read_eeprom(N100_EEPROM_ADDR, offsetof(n100_eeprom_map, subnet), 4), ip_addr_bytes); mb_eeprom["subnet"] = boost::asio::ip::address_v4(ip_addr_bytes).to_string(); byte_copy(iface.read_eeprom(N100_EEPROM_ADDR, offsetof(n100_eeprom_map, gateway), 4), ip_addr_bytes); mb_eeprom["gateway"] = boost::asio::ip::address_v4(ip_addr_bytes).to_string(); //gpsdo capabilities uint8_t gpsdo_byte = iface.read_eeprom(N100_EEPROM_ADDR, offsetof(n100_eeprom_map, gpsdo), 1).at(0); switch(n200_gpsdo_type(gpsdo_byte)){ case N200_GPSDO_INTERNAL: mb_eeprom["gpsdo"] = "internal"; break; case N200_GPSDO_ONBOARD: mb_eeprom["gpsdo"] = "onboard"; break; default: mb_eeprom["gpsdo"] = "none"; } //extract the serial mb_eeprom["serial"] = bytes_to_string(iface.read_eeprom( N100_EEPROM_ADDR, offsetof(n100_eeprom_map, serial), SERIAL_LEN )); //extract the name mb_eeprom["name"] = bytes_to_string(iface.read_eeprom( N100_EEPROM_ADDR, offsetof(n100_eeprom_map, name), NAME_MAX_LEN )); //Empty serial correction: use the mac address to determine serial. //Older usrp2 models don't have a serial burned into EEPROM. //The lower mac address bits will function as the serial number. if (mb_eeprom["serial"].empty()){ byte_vector_t mac_addr_bytes = mac_addr_t::from_string(mb_eeprom["mac-addr"]).to_bytes(); unsigned serial = mac_addr_bytes.at(5) | (unsigned(mac_addr_bytes.at(4) & 0x0f) << 8); mb_eeprom["serial"] = boost::lexical_cast(serial); } } static void store_n100(const mboard_eeprom_t &mb_eeprom, i2c_iface &iface){ //parse the revision number if (mb_eeprom.has_key("hardware")) iface.write_eeprom( N100_EEPROM_ADDR, offsetof(n100_eeprom_map, hardware), string_to_uint16_bytes(mb_eeprom["hardware"]) ); //parse the revision number if (mb_eeprom.has_key("revision")) iface.write_eeprom( N100_EEPROM_ADDR, offsetof(n100_eeprom_map, revision), string_to_uint16_bytes(mb_eeprom["revision"]) ); //parse the product code if (mb_eeprom.has_key("product")) iface.write_eeprom( N100_EEPROM_ADDR, offsetof(n100_eeprom_map, product), string_to_uint16_bytes(mb_eeprom["product"]) ); //store the addresses if (mb_eeprom.has_key("mac-addr")) iface.write_eeprom( N100_EEPROM_ADDR, offsetof(n100_eeprom_map, mac_addr), mac_addr_t::from_string(mb_eeprom["mac-addr"]).to_bytes() ); if (mb_eeprom.has_key("ip-addr")){ byte_vector_t ip_addr_bytes(4); byte_copy(boost::asio::ip::address_v4::from_string(mb_eeprom["ip-addr"]).to_bytes(), ip_addr_bytes); iface.write_eeprom(N100_EEPROM_ADDR, offsetof(n100_eeprom_map, ip_addr), ip_addr_bytes); } if (mb_eeprom.has_key("subnet")){ byte_vector_t ip_addr_bytes(4); byte_copy(boost::asio::ip::address_v4::from_string(mb_eeprom["subnet"]).to_bytes(), ip_addr_bytes); iface.write_eeprom(N100_EEPROM_ADDR, offsetof(n100_eeprom_map, subnet), ip_addr_bytes); } if (mb_eeprom.has_key("gateway")){ byte_vector_t ip_addr_bytes(4); byte_copy(boost::asio::ip::address_v4::from_string(mb_eeprom["gateway"]).to_bytes(), ip_addr_bytes); iface.write_eeprom(N100_EEPROM_ADDR, offsetof(n100_eeprom_map, gateway), ip_addr_bytes); } //gpsdo capabilities if (mb_eeprom.has_key("gpsdo")){ uint8_t gpsdo_byte = N200_GPSDO_NONE; if (mb_eeprom["gpsdo"] == "internal") gpsdo_byte = N200_GPSDO_INTERNAL; if (mb_eeprom["gpsdo"] == "onboard") gpsdo_byte = N200_GPSDO_ONBOARD; iface.write_eeprom(N100_EEPROM_ADDR, offsetof(n100_eeprom_map, gpsdo), byte_vector_t(1, gpsdo_byte)); } //store the serial if (mb_eeprom.has_key("serial")) iface.write_eeprom( N100_EEPROM_ADDR, offsetof(n100_eeprom_map, serial), string_to_bytes(mb_eeprom["serial"], SERIAL_LEN) ); //store the name if (mb_eeprom.has_key("name")) iface.write_eeprom( N100_EEPROM_ADDR, offsetof(n100_eeprom_map, name), string_to_bytes(mb_eeprom["name"], NAME_MAX_LEN) ); } /*********************************************************************** * Implementation of X300 load/store **********************************************************************/ static const uint8_t X300_EEPROM_ADDR = 0x50; struct x300_eeprom_map { //indentifying numbers unsigned char revision[2]; unsigned char product[2]; unsigned char revision_compat[2]; uint8_t _pad0[2]; //all the mac addrs uint8_t mac_addr0[6]; uint8_t _pad1[2]; uint8_t mac_addr1[6]; uint8_t _pad2[2]; //all the IP addrs uint32_t gateway; uint32_t subnet[4]; uint32_t ip_addr[4]; uint8_t _pad3[16]; //names and serials unsigned char name[NAME_MAX_LEN]; unsigned char serial[SERIAL_LEN]; }; static void load_x300(mboard_eeprom_t &mb_eeprom, i2c_iface &iface) { byte_vector_t bytes = iface.read_eeprom(X300_EEPROM_ADDR, 0, sizeof (struct x300_eeprom_map)); if (bytes.size() == 0) { return; } //extract the revision number mb_eeprom["revision"] = uint16_bytes_to_string( byte_vector_t( bytes.begin() + offsetof(x300_eeprom_map, revision), bytes.begin() + (offsetof(x300_eeprom_map, revision)+2)) ); //extract the revision compat number mb_eeprom["revision_compat"] = uint16_bytes_to_string( byte_vector_t( bytes.begin() + offsetof(x300_eeprom_map, revision_compat), bytes.begin() + (offsetof(x300_eeprom_map, revision_compat)+2)) ); //extract the product code mb_eeprom["product"] = uint16_bytes_to_string( byte_vector_t( bytes.begin() + offsetof(x300_eeprom_map, product), bytes.begin() + (offsetof(x300_eeprom_map, product)+2)) ); //extract the mac addresses mb_eeprom["mac-addr0"] = mac_addr_t::from_bytes( byte_vector_t( bytes.begin() + offsetof(x300_eeprom_map, mac_addr0), bytes.begin() + (offsetof(x300_eeprom_map, mac_addr0)+6)) ).to_string(); mb_eeprom["mac-addr1"] = mac_addr_t::from_bytes( byte_vector_t( bytes.begin() + offsetof(x300_eeprom_map, mac_addr1), bytes.begin() + (offsetof(x300_eeprom_map, mac_addr1)+6)) ).to_string(); //extract the ip addresses boost::asio::ip::address_v4::bytes_type ip_addr_bytes; byte_copy( byte_vector_t( bytes.begin() + offsetof(x300_eeprom_map, gateway), bytes.begin() + (offsetof(x300_eeprom_map, gateway)+4)), ip_addr_bytes ); mb_eeprom["gateway"] = boost::asio::ip::address_v4(ip_addr_bytes).to_string(); for (size_t i = 0; i < 4; i++) { const std::string n(1, i+'0'); byte_copy( byte_vector_t( bytes.begin() + (offsetof(x300_eeprom_map, ip_addr)+(i*4)), bytes.begin() + (offsetof(x300_eeprom_map, ip_addr)+(i*4)+4)), ip_addr_bytes ); mb_eeprom["ip-addr"+n] = boost::asio::ip::address_v4(ip_addr_bytes).to_string(); byte_copy( byte_vector_t( bytes.begin() + (offsetof(x300_eeprom_map, subnet)+(i*4)), bytes.begin() + (offsetof(x300_eeprom_map, subnet)+(i*4)+4)), ip_addr_bytes ); mb_eeprom["subnet"+n] = boost::asio::ip::address_v4(ip_addr_bytes).to_string(); } //extract the serial mb_eeprom["serial"] = bytes_to_string( byte_vector_t( bytes.begin() + offsetof(x300_eeprom_map, serial), bytes.begin() + (offsetof(x300_eeprom_map, serial)+SERIAL_LEN)) ); //extract the name mb_eeprom["name"] = bytes_to_string( byte_vector_t( bytes.begin() + offsetof(x300_eeprom_map, name), bytes.begin() + (offsetof(x300_eeprom_map, name)+NAME_MAX_LEN)) ); } static void store_x300(const mboard_eeprom_t &mb_eeprom, i2c_iface &iface) { //parse the revision number if (mb_eeprom.has_key("revision")) iface.write_eeprom( X300_EEPROM_ADDR, offsetof(x300_eeprom_map, revision), string_to_uint16_bytes(mb_eeprom["revision"]) ); //parse the revision compat number if (mb_eeprom.has_key("revision_compat")) iface.write_eeprom( X300_EEPROM_ADDR, offsetof(x300_eeprom_map, revision_compat), string_to_uint16_bytes(mb_eeprom["revision_compat"]) ); //parse the product code if (mb_eeprom.has_key("product")) iface.write_eeprom( X300_EEPROM_ADDR, offsetof(x300_eeprom_map, product), string_to_uint16_bytes(mb_eeprom["product"]) ); //store the mac addresses if (mb_eeprom.has_key("mac-addr0")) iface.write_eeprom( X300_EEPROM_ADDR, offsetof(x300_eeprom_map, mac_addr0), mac_addr_t::from_string(mb_eeprom["mac-addr0"]).to_bytes() ); if (mb_eeprom.has_key("mac-addr1")) iface.write_eeprom( X300_EEPROM_ADDR, offsetof(x300_eeprom_map, mac_addr1), mac_addr_t::from_string(mb_eeprom["mac-addr1"]).to_bytes() ); //store the ip addresses byte_vector_t ip_addr_bytes(4); if (mb_eeprom.has_key("gateway")){ byte_copy(boost::asio::ip::address_v4::from_string(mb_eeprom["gateway"]).to_bytes(), ip_addr_bytes); iface.write_eeprom(X300_EEPROM_ADDR, offsetof(x300_eeprom_map, gateway), ip_addr_bytes); } for (size_t i = 0; i < 4; i++) { const std::string n(1, i+'0'); if (mb_eeprom.has_key("ip-addr"+n)){ byte_copy(boost::asio::ip::address_v4::from_string(mb_eeprom["ip-addr"+n]).to_bytes(), ip_addr_bytes); iface.write_eeprom(X300_EEPROM_ADDR, offsetof(x300_eeprom_map, ip_addr)+(i*4), ip_addr_bytes); } if (mb_eeprom.has_key("subnet"+n)){ byte_copy(boost::asio::ip::address_v4::from_string(mb_eeprom["subnet"+n]).to_bytes(), ip_addr_bytes); iface.write_eeprom(X300_EEPROM_ADDR, offsetof(x300_eeprom_map, subnet)+(i*4), ip_addr_bytes); } } //store the serial if (mb_eeprom.has_key("serial")) iface.write_eeprom( X300_EEPROM_ADDR, offsetof(x300_eeprom_map, serial), string_to_bytes(mb_eeprom["serial"], SERIAL_LEN) ); //store the name if (mb_eeprom.has_key("name")) iface.write_eeprom( X300_EEPROM_ADDR, offsetof(x300_eeprom_map, name), string_to_bytes(mb_eeprom["name"], NAME_MAX_LEN) ); } /*********************************************************************** * Implementation of B000 load/store **********************************************************************/ static const uint8_t B000_EEPROM_ADDR = 0x50; static const size_t B000_SERIAL_LEN = 8; //use char array so we dont need to attribute packed struct b000_eeprom_map{ unsigned char _r[221]; unsigned char mcr[4]; unsigned char name[NAME_MAX_LEN]; unsigned char serial[B000_SERIAL_LEN]; }; static void load_b000(mboard_eeprom_t &mb_eeprom, i2c_iface &iface){ //extract the serial mb_eeprom["serial"] = bytes_to_string(iface.read_eeprom( B000_EEPROM_ADDR, offsetof(b000_eeprom_map, serial), B000_SERIAL_LEN )); //extract the name mb_eeprom["name"] = bytes_to_string(iface.read_eeprom( B000_EEPROM_ADDR, offsetof(b000_eeprom_map, name), NAME_MAX_LEN )); //extract master clock rate as a 32-bit uint in Hz uint32_t master_clock_rate; const byte_vector_t rate_bytes = iface.read_eeprom( B000_EEPROM_ADDR, offsetof(b000_eeprom_map, mcr), sizeof(master_clock_rate) ); std::copy( rate_bytes.begin(), rate_bytes.end(), //input reinterpret_cast(&master_clock_rate) //output ); master_clock_rate = ntohl(master_clock_rate); if (master_clock_rate > 1e6 and master_clock_rate < 1e9){ mb_eeprom["mcr"] = boost::lexical_cast(master_clock_rate); } else mb_eeprom["mcr"] = ""; } static void store_b000(const mboard_eeprom_t &mb_eeprom, i2c_iface &iface){ //store the serial if (mb_eeprom.has_key("serial")) iface.write_eeprom( B000_EEPROM_ADDR, offsetof(b000_eeprom_map, serial), string_to_bytes(mb_eeprom["serial"], B000_SERIAL_LEN) ); //store the name if (mb_eeprom.has_key("name")) iface.write_eeprom( B000_EEPROM_ADDR, offsetof(b000_eeprom_map, name), string_to_bytes(mb_eeprom["name"], NAME_MAX_LEN) ); //store the master clock rate as a 32-bit uint in Hz if (mb_eeprom.has_key("mcr")){ uint32_t master_clock_rate = uint32_t(boost::lexical_cast(mb_eeprom["mcr"])); master_clock_rate = htonl(master_clock_rate); const byte_vector_t rate_bytes( reinterpret_cast(&master_clock_rate), reinterpret_cast(&master_clock_rate) + sizeof(master_clock_rate) ); iface.write_eeprom( B000_EEPROM_ADDR, offsetof(b000_eeprom_map, mcr), rate_bytes ); } } /*********************************************************************** * Implementation of B100 load/store **********************************************************************/ static const uint8_t B100_EEPROM_ADDR = 0x50; //use char array so we dont need to attribute packed struct b100_eeprom_map{ unsigned char _r[220]; unsigned char revision[2]; unsigned char product[2]; unsigned char name[NAME_MAX_LEN]; unsigned char serial[SERIAL_LEN]; }; static void load_b100(mboard_eeprom_t &mb_eeprom, i2c_iface &iface){ //extract the revision number mb_eeprom["revision"] = uint16_bytes_to_string( iface.read_eeprom(B100_EEPROM_ADDR, offsetof(b100_eeprom_map, revision), 2) ); //extract the product code mb_eeprom["product"] = uint16_bytes_to_string( iface.read_eeprom(B100_EEPROM_ADDR, offsetof(b100_eeprom_map, product), 2) ); //extract the serial mb_eeprom["serial"] = bytes_to_string(iface.read_eeprom( B100_EEPROM_ADDR, offsetof(b100_eeprom_map, serial), SERIAL_LEN )); //extract the name mb_eeprom["name"] = bytes_to_string(iface.read_eeprom( B100_EEPROM_ADDR, offsetof(b100_eeprom_map, name), NAME_MAX_LEN )); } static void store_b100(const mboard_eeprom_t &mb_eeprom, i2c_iface &iface){ //parse the revision number if (mb_eeprom.has_key("revision")) iface.write_eeprom( B100_EEPROM_ADDR, offsetof(b100_eeprom_map, revision), string_to_uint16_bytes(mb_eeprom["revision"]) ); //parse the product code if (mb_eeprom.has_key("product")) iface.write_eeprom( B100_EEPROM_ADDR, offsetof(b100_eeprom_map, product), string_to_uint16_bytes(mb_eeprom["product"]) ); //store the serial if (mb_eeprom.has_key("serial")) iface.write_eeprom( B100_EEPROM_ADDR, offsetof(b100_eeprom_map, serial), string_to_bytes(mb_eeprom["serial"], SERIAL_LEN) ); //store the name if (mb_eeprom.has_key("name")) iface.write_eeprom( B100_EEPROM_ADDR, offsetof(b100_eeprom_map, name), string_to_bytes(mb_eeprom["name"], NAME_MAX_LEN) ); } /*********************************************************************** * Implementation of B200 load/store **********************************************************************/ /* On the B200, this field indicates the slave address. From the FX3, this * address is always 0. */ static const uint8_t B200_EEPROM_SLAVE_ADDR = 0x04; //use char array so we dont need to attribute packed struct b200_eeprom_map{ unsigned char _r[220]; unsigned char revision[2]; unsigned char product[2]; unsigned char name[NAME_MAX_LEN]; unsigned char serial[SERIAL_LEN]; }; static void load_b200(mboard_eeprom_t &mb_eeprom, i2c_iface &iface){ //extract the revision number mb_eeprom["revision"] = uint16_bytes_to_string( iface.read_eeprom(B200_EEPROM_SLAVE_ADDR, offsetof(b200_eeprom_map, revision), 2) ); //extract the product code mb_eeprom["product"] = uint16_bytes_to_string( iface.read_eeprom(B200_EEPROM_SLAVE_ADDR, offsetof(b200_eeprom_map, product), 2) ); //extract the serial mb_eeprom["serial"] = bytes_to_string(iface.read_eeprom( B200_EEPROM_SLAVE_ADDR, offsetof(b200_eeprom_map, serial), SERIAL_LEN )); //extract the name mb_eeprom["name"] = bytes_to_string(iface.read_eeprom( B200_EEPROM_SLAVE_ADDR, offsetof(b200_eeprom_map, name), NAME_MAX_LEN )); } static void store_b200(const mboard_eeprom_t &mb_eeprom, i2c_iface &iface){ //parse the revision number if (mb_eeprom.has_key("revision")) iface.write_eeprom( B200_EEPROM_SLAVE_ADDR, offsetof(b200_eeprom_map, revision), string_to_uint16_bytes(mb_eeprom["revision"]) ); //parse the product code if (mb_eeprom.has_key("product")) iface.write_eeprom( B200_EEPROM_SLAVE_ADDR, offsetof(b200_eeprom_map, product), string_to_uint16_bytes(mb_eeprom["product"]) ); //store the serial if (mb_eeprom.has_key("serial")) iface.write_eeprom( B200_EEPROM_SLAVE_ADDR, offsetof(b200_eeprom_map, serial), string_to_bytes(mb_eeprom["serial"], SERIAL_LEN) ); //store the name if (mb_eeprom.has_key("name")) iface.write_eeprom( B200_EEPROM_SLAVE_ADDR, offsetof(b200_eeprom_map, name), string_to_bytes(mb_eeprom["name"], NAME_MAX_LEN) ); } /*********************************************************************** * Implementation of E100 load/store **********************************************************************/ static const uint8_t E100_EEPROM_ADDR = 0x51; struct e100_eeprom_map{ uint16_t vendor; uint16_t device; unsigned char revision; unsigned char content; unsigned char model[8]; unsigned char env_var[16]; unsigned char env_setting[64]; unsigned char serial[10]; unsigned char name[NAME_MAX_LEN]; }; template static const byte_vector_t to_bytes(const T &item){ return byte_vector_t( reinterpret_cast(&item), reinterpret_cast(&item)+sizeof(item) ); } #define sizeof_member(struct_name, member_name) \ sizeof(reinterpret_cast(0)->member_name) static void load_e100(mboard_eeprom_t &mb_eeprom, i2c_iface &iface){ const size_t num_bytes = offsetof(e100_eeprom_map, model); byte_vector_t map_bytes = iface.read_eeprom(E100_EEPROM_ADDR, 0, num_bytes); e100_eeprom_map map; std::memcpy(&map, &map_bytes[0], map_bytes.size()); mb_eeprom["vendor"] = boost::lexical_cast(uhd::ntohx(map.vendor)); mb_eeprom["device"] = boost::lexical_cast(uhd::ntohx(map.device)); mb_eeprom["revision"] = boost::lexical_cast(unsigned(map.revision)); mb_eeprom["content"] = boost::lexical_cast(unsigned(map.content)); #define load_e100_string_xx(key) mb_eeprom[#key] = bytes_to_string(iface.read_eeprom( \ E100_EEPROM_ADDR, offsetof(e100_eeprom_map, key), sizeof_member(e100_eeprom_map, key) \ )); load_e100_string_xx(model); load_e100_string_xx(env_var); load_e100_string_xx(env_setting); load_e100_string_xx(serial); load_e100_string_xx(name); } static void store_e100(const mboard_eeprom_t &mb_eeprom, i2c_iface &iface){ if (mb_eeprom.has_key("vendor")) iface.write_eeprom( E100_EEPROM_ADDR, offsetof(e100_eeprom_map, vendor), to_bytes(uhd::htonx(boost::lexical_cast(mb_eeprom["vendor"]))) ); if (mb_eeprom.has_key("device")) iface.write_eeprom( E100_EEPROM_ADDR, offsetof(e100_eeprom_map, device), to_bytes(uhd::htonx(boost::lexical_cast(mb_eeprom["device"]))) ); if (mb_eeprom.has_key("revision")) iface.write_eeprom( E100_EEPROM_ADDR, offsetof(e100_eeprom_map, revision), byte_vector_t(1, boost::lexical_cast(mb_eeprom["revision"])) ); if (mb_eeprom.has_key("content")) iface.write_eeprom( E100_EEPROM_ADDR, offsetof(e100_eeprom_map, content), byte_vector_t(1, boost::lexical_cast(mb_eeprom["content"])) ); #define store_e100_string_xx(key) if (mb_eeprom.has_key(#key)) iface.write_eeprom( \ E100_EEPROM_ADDR, offsetof(e100_eeprom_map, key), \ string_to_bytes(mb_eeprom[#key], sizeof_member(e100_eeprom_map, key)) \ ); store_e100_string_xx(model); store_e100_string_xx(env_var); store_e100_string_xx(env_setting); store_e100_string_xx(serial); store_e100_string_xx(name); } /*********************************************************************** * Implementation of mboard eeprom **********************************************************************/ mboard_eeprom_t::mboard_eeprom_t(void){ /* NOP */ } mboard_eeprom_t::mboard_eeprom_t(i2c_iface &iface, const std::string &which){ if (which == "N100") load_n100(*this, iface); if (which == "X300") load_x300(*this, iface); if (which == "B000") load_b000(*this, iface); if (which == "B100") load_b100(*this, iface); if (which == "B200") load_b200(*this, iface); if (which == "E100") load_e100(*this, iface); } void mboard_eeprom_t::commit(i2c_iface &iface, const std::string &which) const{ if (which == "N100") store_n100(*this, iface); if (which == "X300") store_x300(*this, iface); if (which == "B000") store_b000(*this, iface); if (which == "B100") store_b100(*this, iface); if (which == "B200") store_b200(*this, iface); if (which == "E100") store_e100(*this, iface); }