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//
// Copyright 2010-2011 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 <http://www.gnu.org/licenses/>.
//
#include <uhd/usrp/mboard_eeprom.hpp>
#include <uhd/types/mac_addr.hpp>
#include <uhd/utils/byteswap.hpp>
#include <boost/asio/ip/address_v4.hpp>
#include <boost/assign/list_of.hpp>
#include <boost/lexical_cast.hpp>
#include <boost/foreach.hpp>
#include <algorithm>
#include <cstddef>
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
**********************************************************************/
//! A wrapper around std::copy that takes ranges instead of iterators.
template<typename RangeSrc, typename RangeDst> inline
void byte_copy(const RangeSrc &src, RangeDst &dst){
std::copy(boost::begin(src), boost::end(src), boost::begin(dst));
}
//! create a string from a byte vector, return empty if invalid ascii
static const std::string bytes_to_string(const byte_vector_t &bytes){
std::string out;
BOOST_FOREACH(boost::uint8_t byte, bytes){
if (byte < 32 or byte > 127) return out;
out += byte;
}
return out;
}
//! create a byte vector from a string, null terminate unless max length
static const byte_vector_t string_to_bytes(const std::string &string, size_t max_length){
byte_vector_t bytes;
for (size_t i = 0; i < std::min(string.size(), max_length); i++){
bytes.push_back(string[i]);
}
if (bytes.size() < max_length - 1) bytes.push_back('\0');
return bytes;
}
/***********************************************************************
* Implementation of N100 load/store
**********************************************************************/
static const boost::uint8_t N100_EEPROM_ADDR = 0x50;
static const uhd::dict<std::string, boost::uint8_t> USRP_N100_OFFSETS = boost::assign::map_list_of
("rev-lsb-msb", 0x00)
("mac-addr", 0x02)
("ip-addr", 0x0C)
//leave space here for other addresses (perhaps)
("gpsdo", 0x17)
("serial", 0x18)
("name", 0x18 + SERIAL_LEN)
;
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 revision number
byte_vector_t rev_lsb_msb = iface.read_eeprom(N100_EEPROM_ADDR, USRP_N100_OFFSETS["rev-lsb-msb"], 2);
boost::uint16_t rev = (boost::uint16_t(rev_lsb_msb.at(0)) << 0) | (boost::uint16_t(rev_lsb_msb.at(1)) << 8);
mb_eeprom["rev"] = boost::lexical_cast<std::string>(rev);
//extract the addresses
mb_eeprom["mac-addr"] = mac_addr_t::from_bytes(iface.read_eeprom(
N100_EEPROM_ADDR, USRP_N100_OFFSETS["mac-addr"], 6
)).to_string();
boost::asio::ip::address_v4::bytes_type ip_addr_bytes;
byte_copy(iface.read_eeprom(N100_EEPROM_ADDR, USRP_N100_OFFSETS["ip-addr"], 4), ip_addr_bytes);
mb_eeprom["ip-addr"] = boost::asio::ip::address_v4(ip_addr_bytes).to_string();
//gpsdo capabilities
boost::uint8_t gpsdo_byte = iface.read_eeprom(N100_EEPROM_ADDR, USRP_N100_OFFSETS["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, USRP_N100_OFFSETS["serial"], SERIAL_LEN
));
//extract the name
mb_eeprom["name"] = bytes_to_string(iface.read_eeprom(
N100_EEPROM_ADDR, USRP_N100_OFFSETS["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<std::string>(serial);
}
}
static void store_n100(const mboard_eeprom_t &mb_eeprom, i2c_iface &iface){
//parse the revision number
if (mb_eeprom.has_key("rev")){
boost::uint16_t rev = boost::lexical_cast<boost::uint16_t>(mb_eeprom["rev"]);
byte_vector_t rev_lsb_msb = boost::assign::list_of
(boost::uint8_t(rev >> 0))
(boost::uint8_t(rev >> 8))
;
iface.write_eeprom(N100_EEPROM_ADDR, USRP_N100_OFFSETS["rev-lsb-msb"], rev_lsb_msb);
}
//store the addresses
if (mb_eeprom.has_key("mac-addr")) iface.write_eeprom(
N100_EEPROM_ADDR, USRP_N100_OFFSETS["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, USRP_N100_OFFSETS["ip-addr"], ip_addr_bytes);
}
//gpsdo capabilities
if (mb_eeprom.has_key("gpsdo")){
boost::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, USRP_N100_OFFSETS["gpsdo"], byte_vector_t(1, gpsdo_byte));
}
//store the serial
if (mb_eeprom.has_key("serial")) iface.write_eeprom(
N100_EEPROM_ADDR, USRP_N100_OFFSETS["serial"],
string_to_bytes(mb_eeprom["serial"], SERIAL_LEN)
);
//store the name
if (mb_eeprom.has_key("name")) iface.write_eeprom(
N100_EEPROM_ADDR, USRP_N100_OFFSETS["name"],
string_to_bytes(mb_eeprom["name"], NAME_MAX_LEN)
);
}
/***********************************************************************
* Implementation of B000 load/store
**********************************************************************/
static const boost::uint8_t B000_EEPROM_ADDR = 0x50;
static const size_t B000_SERIAL_LEN = 8;
static const uhd::dict<std::string, boost::uint8_t> USRP_B000_OFFSETS = boost::assign::map_list_of
("serial", 0xf8)
("name", 0xf8 - NAME_MAX_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, USRP_B000_OFFSETS["serial"], B000_SERIAL_LEN
));
//extract the name
mb_eeprom["name"] = bytes_to_string(iface.read_eeprom(
B000_EEPROM_ADDR, USRP_B000_OFFSETS["name"], NAME_MAX_LEN
));
}
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, USRP_B000_OFFSETS["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, USRP_B000_OFFSETS["name"],
string_to_bytes(mb_eeprom["name"], NAME_MAX_LEN)
);
}
/***********************************************************************
* Implementation of E100 load/store
**********************************************************************/
static const boost::uint8_t E100_EEPROM_ADDR = 0x51;
struct e100_eeprom_map{
boost::uint16_t vendor;
boost::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];
float master_clock_rate;
};
template <typename T> static const byte_vector_t to_bytes(const T &item){
return byte_vector_t(
reinterpret_cast<const byte_vector_t::value_type *>(&item),
reinterpret_cast<const byte_vector_t::value_type *>(&item)+sizeof(item)
);
}
#define sizeof_member(struct_name, member_name) \
sizeof(reinterpret_cast<struct_name*>(NULL)->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<std::string>(uhd::ntohx(map.vendor));
mb_eeprom["device"] = boost::lexical_cast<std::string>(uhd::ntohx(map.device));
mb_eeprom["revision"] = boost::lexical_cast<std::string>(unsigned(map.revision));
mb_eeprom["content"] = boost::lexical_cast<std::string>(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);
//extract the master clock rate
float master_clock_rate = 0;
const byte_vector_t rate_bytes = iface.read_eeprom(
E100_EEPROM_ADDR, offsetof(e100_eeprom_map, master_clock_rate), sizeof(master_clock_rate)
);
std::copy(
rate_bytes.begin(), rate_bytes.end(), //source
reinterpret_cast<boost::uint8_t *>(&master_clock_rate) //destination
);
if (master_clock_rate > 1e6 and master_clock_rate < 1e9){
mb_eeprom["master_clock_rate"] = boost::lexical_cast<std::string>(master_clock_rate);
}
}
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<boost::uint16_t>(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<boost::uint16_t>(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<unsigned>(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<unsigned>(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);
//store the master clock rate
if (mb_eeprom.has_key("master_clock_rate")){
const float master_clock_rate = float(boost::lexical_cast<double>(mb_eeprom["master_clock_rate"]));
const byte_vector_t rate_bytes(
reinterpret_cast<const boost::uint8_t *>(&master_clock_rate),
reinterpret_cast<const boost::uint8_t *>(&master_clock_rate) + sizeof(master_clock_rate)
);
iface.write_eeprom(
E100_EEPROM_ADDR, offsetof(e100_eeprom_map, master_clock_rate), rate_bytes
);
}
}
/***********************************************************************
* Implementation of mboard eeprom
**********************************************************************/
mboard_eeprom_t::mboard_eeprom_t(void){
/* NOP */
}
mboard_eeprom_t::mboard_eeprom_t(i2c_iface &iface, map_type map){
switch(map){
case MAP_N100: load_n100(*this, iface); break;
case MAP_B000: load_b000(*this, iface); break;
case MAP_E100: load_e100(*this, iface); break;
}
}
void mboard_eeprom_t::commit(i2c_iface &iface, map_type map){
switch(map){
case MAP_N100: store_n100(*this, iface); break;
case MAP_B000: store_b000(*this, iface); break;
case MAP_E100: store_e100(*this, iface); break;
}
}
|