FreeCalypso > hg > freecalypso-tools

--- a/.hgignore	Sat Aug 12 17:37:02 2017 +0000
+++ b/.hgignore	Thu Aug 17 05:27:43 2017 +0000
@@ -27,12 +27,6 @@
 ^miscutil/fc-vm2hex$
 ^miscutil/imei-luhn$

-^rfcal/cmu200/fc-cmu200d$
-^rfcal/cmu200/fc-serscpi$
-^rfcal/tsid-test/fc-tsid-shell$
-^rfcal/vcxo-manual/fc-vcxo-linear$
-^rfcal/vcxo-manual/fc-vcxo-param$
-
 ^ringtools/fc-e1decode$
 ^ringtools/fc-e1gen$
--- a/doc/RF-cal/Architecture	Sat Aug 12 17:37:02 2017 +0000
+++ /dev/null	Thu Jan 01 00:00:00 1970 +0000
@@ -1,53 +0,0 @@
-The RF calibration process fundamentally consists of 3 parts:
-
-1: The FreeCalypso GSM MS device under test (DUT) to be calibrated;
-
-2: An RF test station to which the DUT is connected via an RF coax cable,
-   performing the RF signal analyzer and signal generator functions required
-   for the calibration procedures;
-
-3: A program that communicates with both the DUT and the RF test station and
-   orchestrates all of the signal generation, measurement and computation steps
-   to arrive at the final calibration results to be stored in the flash file
-   system of the DUT.  The steps are too numerous, tedious and repetitive to be
-   performed manually, hence automation is required in order to make the process
-   practical.
-
-The goal of the FreeCalypso RF calibration subproject is to produce a set of
-tools for performing part 3 of the above breakdown.  The current vision is that
-our automated calibration software will be broken down into two interfacing
-components:
-
-1: There will be a Test System Interface Daemon (TSID) that encapsulates the
-   magic specific to a particular brand of RF test station, e.g., R&S CMU200.
-   The TSID will only talk to the CMU200 or other RF test station, but not to
-   the Calypso DUT, and the intent is that the TSID only needs to be started
-   once at the beginning of a calibration work shift and then stay running as a
-   hundred or more FreeCalypso GSM devices may be calibrated on the production
-   line.  The TSID will present a local socket interface (can be changed to
-   TCP/IP if operation over a network is required) to which the other component
-   below will connect as a client.
-
-2: There will be a set of 3 programs (fc-rfcal-vcxo, fc-rfcal-rxband and
-   fc-rfcal-txband) that perform the 3 required calibration groups for each
-   individual FreeCalypso device unit on the production line.  The production
-   automation script will need to run fc-rfcal-vcxo first, then fc-rfcal-rxband
-   for each of the hardware-supported bands (e.g., 900, 1800 and 1900 on
-   FCDEV3B-900), then fc-rfcal-txband for each of the same bands.  Each of these
-   programs will talk both to the DUT (via rvinterf) and to the RF test system
-   (via the TSID), i.e., will need to connect to an already-running rvinterf
-   process and to an already-running TSID via local sockets.
-
-The programs in the second group above will contain no knowledge specific to
-R&S CMU200 or any other particular brand of RF test station, instead this
-knowledge is to be encapsulated in the TSID.  The interface between the TSID
-and its clients will be of a command-response nature, and will be defined from
-the perspective of the needs of the FreeCalypso calibration process, rather than
-from the perspective of the capabilities of the CMU200 - in other words, the
-calibration automation program will command the TSID to the effect of "I need
-this", and it will be the responsibility of the TSID to figure out how to
-perform the required measurement or signal generation on the given type of test
-equipment.
-
-See the Test-system-interface document for the details of the TSID socket
-interface.
--- a/doc/RF-cal/CMU200-notes	Sat Aug 12 17:37:02 2017 +0000
+++ /dev/null	Thu Jan 01 00:00:00 1970 +0000
@@ -1,52 +0,0 @@
-R&S CMU200 is the RF tester used for production RF calibration of FreeCalypso
-GSM devices.  The CMU200 can be operated in three ways: manually via the front
-panel, programmatically via GPIB and programmatically via SCPI commands over
-RS-232.  GPIB is the industry standard, but for FreeCalypso the Mother has
-adopted the RS-232 control interface method instead in order to avoid the
-exotic hardware and equally exotic drivers and libraries required for GPIB:
-using the RS-232 interface requires absolutely no special hardware or drivers
-or libraries, just userspace C code without any dependencies talking to a
-serial port just like we do when communicating with Calypso target serial ports.
-
-Initialization commands
-=======================
-
-Our Test System Interface Daemon for the CMU200 will issue the following SCPI
-commands to the instrument on start-up:
-
-*SEC 0
-*RST;*OPC?
-SYST:NONV:DIS
-SYST:REM:ADDR:SEC 1,"RF_NSig"
-SYST:REM:ADDR:SEC 2,"GSM900MS_NSig"
-SYST:REM:ADDR:SEC 3,"GSM1800MS_NSig"
-SYST:REM:ADDR:SEC 4,"GSM1900MS_NSig"
-SYST:REM:ADDR:SEC 5,"GSM850MS_NSig"
-
-VCXO calibration
-================
-
-When commanded to prepare for VCXO calibration, our TSID will command the
-CMU200 as follows:
-
-*SEC 2
-RFAN:CHAN 40CH
-RFAN:TSEQ GSM5
-
-Command to read frequency offset:
-
-READ:MOD?
-
-Signal generator mode
-=====================
-
-Turn signal generator on:
-
-*SEC 1
-SOUR:RFG:LEV <level_in_dbm>
-SOUR:RFG:FREQ <freq_in_hz>
-INIT:RFG
-
-Turn signal generator off:
-
-ABORT:RFG
--- a/doc/RF-cal/Test-system-interface	Sat Aug 12 17:37:02 2017 +0000
+++ /dev/null	Thu Jan 01 00:00:00 1970 +0000
@@ -1,46 +0,0 @@
-The Test System Interface Daemon (TSID) will provide a connection-oriented
-(SOCK_STREAM) UNIX domain local socket at /tmp/fc_rftest_socket, and will speak
-an ASCII line-based command-response protocol on this socket.  All command and
-response lines will end with \n only (no \r), and each TSID response including
-the initial greeting on connection establishment will begin with a '+' or '-'
-character to indicate OK or error, respectively, like in POP3.
-
-The following commands are currently defined:
-
-vcxo-cal-setup band arfcn
-
-This command is sent to the TSID to prepare the RF test system for the VCXO
-calibration procedure.  The first argument after the command keyword is the
-band to be used (850, 900, 1800 or 1900) and the second argument is the ARFCN
-in that band on which the DUT will be transmitting.
-
-freq-meas hint
-
-This command directs the RF test system to take a frequency offset measurement
-(vcxo-cal-setup must have been performed previously) and report it back to the
-client in the response line.  The hint argument after the freq-meas keyword will
-be sent by the VCXO calibration program (fc-rfcal-vcxo) to tell the RF test
-system what kind of frequency offset measurement is being made, i.e., which step
-in the VCXO calibration sequence is being performed; the hint keywords remain
-to be defined.
-
-signal-gen-setup band
-
-This command is sent to the TSID to prepare the RF test system for tests in
-which the latter acts as a signal generator.  The argument after the command
-keyword is the band number (850, 900, 1800 or 1900), and it selects the
-downlink frequency band in which the signal generator will need to operate.
-
-signal-gen-sine arfcn offset level
-
-This command directs the RF test system to turn on its signal generator and put
-out a pure sine wave at the frequency corresponding to the specified ARFCN (in
-the downlink band previously selected with signal-get-setup) plus the specified
-offset in kHz (-67 or +67 with TI's Rx path calibration procedures), and at the
-specified Tx power level in dBm.
-
-signal-gen-off
-
-Turn off the signal generator.
-
-The commands for Tx power level calibration remain to be defined.
--- a/doc/RF-cal/VCXO-notes	Sat Aug 12 17:37:02 2017 +0000
+++ /dev/null	Thu Jan 01 00:00:00 1970 +0000
@@ -1,227 +0,0 @@
-How to calibrate the VCXO on your FreeCalypso development board
-===============================================================
-
-The process of calibrating the VCXO on a Calypso+Iota+Rita GSM MS consists of
-the following fundamental parts:
-
-* The antenna needs to be disconnected and the FreeCalypso device's RF output
-  (SMA on the FCDEV3B) needs to be connected to an RF test station such as an
-  R&S CMU200.
-
-* The DUT is commanded to transmit semi-continuously as if it were transmitting
-  on TCH: Tx in one timeslot out of 8, but with the DUT running its own notion
-  of the TDMA frame not synchronized to anything, and keep transmitting
-  endlessly in 1/8 out of every 4.615 ms.
-
-* The RF test station connected to the DUT is used in the RF analyzer mode to
-  measure the frequency offset of the DUT's signal, relative to the ideal uplink
-  frequency corresponding to the selected ARFCN.
-
-* The above frequency offset measurement is performed with the AFC DAC on the
-  Calypso device set to different values, the results of the initial
-  measurements are used to guide some additional measurements, some computations
-  are made from these results, and the computed values are written into the
-  FreeCalypso device's FFS.
-
-This procedure is meant to be automated by way of a program that talks both to
-the FreeCalypso DUT and to the RF test station and orchestrates all of the
-measurement and computation steps, but until this program gets written (we
-weren't able to get a hold of TI's original, hence we have to develop our own),
-use the following instructions to perform the VCXO calibration procedure
-manually.  You still need a CMU200 or equivalent, though - it is not possible
-to do any kind of calibration on a Calypso device by itself, without connecting
-it to some appropriate RF test equipment.
-
-Reference documentation
-=======================
-
-We have the following two TI documents which describe some of the RF calibration
-procedures including the one for the VCXO:
-
-ftp://ftp.freecalypso.org/pub/GSM/Calypso/rf_calibration.pdf
-
-https://www.freecalypso.org/LoCosto-docs/Production%20test%20and%20calibration/i_sample_rf_test_and_calibration_13_03_04_01991%20-%20v026.pdf
-
-Unfortunately neither of them corresponds to the exact evolutionary time point
-of interest to us: the first one corresponds to some chipset much earlier than
-the one we are working with, and to firmware versions much earlier than ours,
-whereas the second one is for TI's later LoCosto chipset.
-
-Commanding the DUT to transmit semi-continuously
-================================================
-
-There is only one VCXO calibration that is subsequently used for all bands in
-normal MS operation.  Both of the calibration instruction documents above
-instruct the operator to run the Tx in GSM900 mode on ARFCN 40, hence we shall
-do likewise until and unless we find some good reason to do differently.
-
-Issue the following commands through fc-tmsh to start the semi-continuous Tx:
-
-tms 1		# enter RF Test Mode
-rfpw 7 6 0	# select GSM 900+1800 band pair, GSM900 band within the pair
-rfpw 2 40	# set ARFCN to 40
-rfpw 8 0	# disable AFC algorithm, i.e., control the AFC DAC manually
-txpw 1 12	# Tx power level
-rfe 3		# start Rx & Tx without network sync
-
-WARNING: Before issuing the above commands, ensure that the antenna is
-disconnected and that the RF output will be going into your test equipment,
-not on the air!  Do not EVER issue these commands with a real antenna connected,
-unless your intent is to operate a rogue transmitter or jammer.
-
-At this point your CMU200 or equivalent should detect the uplink signal
-generated by the DUT (on the CMU200 one needs to set TSC to 5, dunno about
-other test equipment), and you should see some frequency offset.
-
-The actual calibration procedure
-================================
-
-1. Set the AFC DAC to -2048:
-
-   rfpw 9 -2048
-
-   and measure the frequency offset.  Note it down.
-
-2. Set the AFC DAC to +2048:
-
-   rfpw 9 2048
-
-   and again measure the frequency offset.  Note it down.
-
-Now you need to create an ASCII text file with your frequency offset
-measurements.  Each line represents one measurement and consists of two fields:
-the first field is the DAC value and the second field is the measured frequency
-offset in Hz.  On my FCDEV3B S/N 001 the first two measurements were:
-
--2048	-30008
-+2048	+21394
-
-Next you need to apply a linear model to the VCXO frequency offset as a function
-of the DAC input: if x is the DAC value and F is the resulting frequency offset,
-then the linear model is F = ax + b, where a and b need to be determined from
-two measured points (x1, F1) and (x2, F2).  Then once you have a and b, find the
-x value that should produce F = 0.  The fc-vcxo-linear utility will do this math
-for you: run it with the name of your text file with measurements as its only
-argument.
-
-With my measurements, the DAC_CENTER value computed by fc-vcxo-linear is 343.
-However, the linear model is not perfect, thus when you write this computed
-value into the DAC with the rfpw 9 command, the resulting frequency offset on
-the CMU200 screen may be quite far from 0.
-
-TI's instructions in the LoCosto document direct the calibration operator to do
-two more measurements at DAC_CENTER-100 and DAC_CENTER+100, where DAC_CENTER is
-the value we just computed by applying the linear model to the first two
-measurements.  However, in my case the frequency offset at DAC=343 (DAC_CENTER)
-was so negative that at DAC=443 (DAC_CENTER+100) it was still negative - and I
-assume that TI's intent was to capture a close range around the zero crossing.
-
-Therefore, when I get to writing the automated calibration program, I intend to
-change this part of the algorithm as follows: instead of adding or subtracting
-100 right now, first do an rfpw 9 with the DAC_CENTER value as computed from
-the linear model, make a frequency offset measurement, and see if it is negative
-or positive.  Then step the DAC value in the appropriate direction by some
-reasonable increment (e.g., 100) until the frequency offset changes sign.  Then
-take the two DAC values closest to the output frequency offset sign change.
-
-After doing the above, my measurement notes file became:
-
--2048	-30008
-+2048	+21394
-443	-669
-543	634
-
-This file needs to contain all four measurements, with the first two being at
-the extreme DAC values and with the second two hugging the empirically located
-zero crossing, when you feed it to the next step:
-
-fc-vcxo-param myvcxo.meas
-
-The fc-vcxo-param utility will compute the final math steps to produce the
-actual calibration values which will need to be uploaded to the FreeCalypso
-device and stored in its FFS.  With my measurements above, I got the following
-output:
-
-rf_table afcparams
-
-      3434	# Psi_sta_inv
-        15	# Psi_st
-   1000341	# Psi_st_32
-      4293	# Psi_st_inv
-
-      3954	# DAC_INIT * 8
-     -5860	# DAC_MIN * 8
-     11351	# DAC_MAX * 8
-      2560	# snr_thr
-
-# DAC_INIT: rfpw 10 494
-
-The output from fc-vcxo-param is in the rf_table format which our implementation
-of the rftw command takes as input, and the latter is the fc-tmsh command which
-you will need to issue in order to send this table to the FreeCalypso firmware
-in the DUT.
-
-Explanation of the numbers:
-
-* The Psi constants are computed from the slope of the VCXO, and are
-  subsequently used for the steering: when the DSP reports a particular
-  frequency offset (in the form of an angle in radians), by how much should the
-  DAC value be adjusted?  The slope I use for computing these Psi constants is
-  the one from the first two measurements at the extreme DAC values, as the
-  LoCosto document seems to indicate.
-
-* DAC_INIT is the DAC value at which the resulting frequency offset should be 0;
-  it is computed per the linear model from the second pair of measurements.
-
-* DAC_MIN and DAC_MAX are the DAC values which should produce frequency offsets
-  of -15 and +15 ppm, respectively, according to the LoCosto document.  I
-  compute them per the linear model from the first pair of measurements (the
-  extreme DAC ones), as that is what the LoCosto document says.
-
-* The SNR threshold is a constant that never needs to change.
-
-The 3 dac_* values in the afcparams structure are stored in the times 8 form.
-Examination of the afcparams values read out of several Openmoko-made GTA02
-units shows that the low 3 bits aren't necessarily zeros, indicating that TI's
-calibration program probably multiplied by 8 before converting from floating
-point to integer; I do likewise in fc-vcxo-param.
-
-Examination of the same afcparams values read out of Openmoko-made units also
-shows that the center, min and max DAC values do vary quite a bit from one unit
-to the next, whereas the Psi constants change very little.  The Psi constants
-which my program computed from my manual measurements on FCDEV3B S/N 001 are in
-the same range as those read out of Openmoko-made units, which is definitely a
-reassuring sign.
-
-Writing your VCXO calibration into FFS
-======================================
-
-Save the fc-vcxo-param output in a file, e.g.:
-
-fc-vcxo-param myvcxo.meas myvcxo.param
-
-Upload the generated afcparams table to your FreeCalypso device:
-
-rftw 9 myvcxo.param
-
-There is one more variable in the firmware, outside of the afcparams structure,
-which also holds the DAC_INIT value.  Set it with an rfpw 10 command as
-instructed in the last comment line emitted by fc-vcxo-param; in my case it was:
-
-rfpw 10 494
-
-Now save all of these values in the non-volatile flash file system:
-
-me 102
-me 103
-
-Cleaning up
-===========
-
-To shut off the transmitter you started earlier, issue this command:
-
-rfe 0
-
-Now power off your FreeCalypso device, disconnect the RF test setup, connect the
-antenna back, insert a SIM, do a fresh boot and see if you can connect to a real
-live GSM network with your VCXO calibration!
--- a/rfcal.note	Sat Aug 12 17:37:02 2017 +0000
+++ /dev/null	Thu Jan 01 00:00:00 1970 +0000
@@ -1,14 +0,0 @@
-The development of FreeCalypso RF calibration software (sw that requires a
-Rohde&Schwarz CMU200 RF test machine, cannot do anything useful without one,
-and is of any use only to those who engage in *physical production* of Calypso
-hardware devices) was started in the present freecalypso-tools source
-repository, but it is now being moved to a new FC production tools repository.
-The latter repository is currently kept private for business reasons, but it
-WILL be made public hopefully soon, as soon as our present-time business
-complication is resolved one way or another.
-
-When our new FC production tools repository becomes public, all rfcal tools
-will be removed from freecalypso-tools, replaced with a pointer to the new
-public repository containing current versions of these tools; until then, the
-rfcal and doc/RF-cal subdirectories contain the last frozen versions of these
-tools and docs from before the beginning of private development.
--- a/rfcal/Makefile	Sat Aug 12 17:37:02 2017 +0000
+++ /dev/null	Thu Jan 01 00:00:00 1970 +0000
@@ -1,15 +0,0 @@
-SUBDIR=	cmu200 tsid-test vcxo-manual
-
-all:	${SUBDIR}
-
-${SUBDIR}: FRC
-	cd $@; ${MAKE} ${MFLAGS}
-
-clean: FRC
-	rm -f a.out core errs
-	for i in ${SUBDIR}; do (cd $$i; ${MAKE} ${MFLAGS} clean); done
-
-install: FRC
-	for i in ${SUBDIR}; do (cd $$i; ${MAKE} ${MFLAGS} install); done
-
-FRC:
--- a/rfcal/cmu200/Makefile	Sat Aug 12 17:37:02 2017 +0000
+++ /dev/null	Thu Jan 01 00:00:00 1970 +0000
@@ -1,22 +0,0 @@
-CC=	gcc
-CFLAGS=	-O2
-PROGS=	fc-cmu200d fc-serscpi
-INSTBIN=/opt/freecalypso/bin
-
-CMU200D_OBJS=	dispatch.o init.o main.o openport.o sercmd.o session.o socket.o
-SERSCPI_OBJS=	openport.o sertool.o
-
-all:	${PROGS}
-
-fc-cmu200d:	${CMU200D_OBJS}
-	${CC} ${CFLAGS} -o $@ ${CMU200D_OBJS}
-
-fc-serscpi:	${SERSCPI_OBJS}
-	${CC} ${CFLAGS} -o $@ ${SERSCPI_OBJS}
-
-install:
-	mkdir -p ${INSTBIN}
-	install -c ${PROGS} ${INSTBIN}
-
-clean:
-	rm -f *.o *.out *errs ${PROGS}
--- a/rfcal/cmu200/dispatch.c	Sat Aug 12 17:37:02 2017 +0000
+++ /dev/null	Thu Jan 01 00:00:00 1970 +0000
@@ -1,38 +0,0 @@
-/*
- * This module contains the code that dispatches client commands.
- */
-
-#include <stdio.h>
-#include <stdlib.h>
-#include <string.h>
-#include <strings.h>
-
-extern char *client_cmd_fields[];
-extern int client_cmd_nfields;
-
-cmd_ping()
-{
-	send_socket_response("+Pong\n");
-	return(0);
-}
-
-static struct cmdtab {
-	char	*cmd_kw;
-	int	(*handler)();
-} cmdtab[] = {
-	{"ping", cmd_ping},
-	{0, 0}
-};
-
-dispatch_client_command()
-{
-	struct cmdtab *tp;
-
-	for (tp = cmdtab; tp->cmd_kw; tp++)
-		if (!strcmp(client_cmd_fields[0], tp->cmd_kw))
-			break;
-	if (tp->handler)
-		return tp->handler();
-	send_socket_response("-Unknown or unimplemented command\n");
-	return(0);
-}
--- a/rfcal/cmu200/init.c	Sat Aug 12 17:37:02 2017 +0000
+++ /dev/null	Thu Jan 01 00:00:00 1970 +0000
@@ -1,48 +0,0 @@
-/*
- * This module contains the code that fc-cmu200d runs at startup,
- * to put the CMU200 into a known state at the global level.
- */
-
-#include <stdio.h>
-#include <stdlib.h>
-#include <string.h>
-#include <strings.h>
-#include "secaddr.h"
-
-extern char instrument_response[];
-
-static char id_string[] = "Rohde&Schwarz,CMU";
-
-static void
-assign_secondary_addr(addr, func)
-	char *func;
-{
-	char cmdbuf[80];
-
-	sprintf(cmdbuf, "SYST:REM:ADDR:SEC %d,\"%s\"\n", addr, func);
-	send_scpi_cmd(cmdbuf);
-}
-
-init_cmu200()
-{
-	/* Test if we are connected to a CMU */
-	send_scpi_cmd("*IDN?\n");
-	collect_instr_response();
-	if (strncasecmp(instrument_response, id_string, strlen(id_string))) {
-		fprintf(stderr, "error: not connected to a CMU200\n");
-		exit(1);
-	}
-	/* init commands */
-	send_scpi_cmd("*SEC 0\n");
-	send_scpi_cmd("*RST;*OPC?\n");
-	collect_staropc_response();
-	send_scpi_cmd("SYST:NONV:DIS\n");
-	assign_secondary_addr(SECADDR_RF_NSIG, "RF_NSig");
-	assign_secondary_addr(SECADDR_GSM900MS_NSIG, "GSM900MS_NSig");
-	assign_secondary_addr(SECADDR_GSM1800MS_NSIG, "GSM1800MS_NSig");
-	assign_secondary_addr(SECADDR_GSM1900MS_NSIG, "GSM1900MS_NSig");
-	assign_secondary_addr(SECADDR_GSM850MS_NSIG, "GSM850MS_NSig");
-	send_scpi_cmd("*OPC?\n");
-	collect_staropc_response();
-	printf("CMU200 init complete\n");
-}
--- a/rfcal/cmu200/main.c	Sat Aug 12 17:37:02 2017 +0000
+++ /dev/null	Thu Jan 01 00:00:00 1970 +0000
@@ -1,35 +0,0 @@
-/*
- * This module contains the main() function for fc-cmu200d.
- */
-
-#include <stdio.h>
-#include <stdlib.h>
-
-int target_fd;
-
-static char default_socket_pathname[] = "/tmp/fc_rftest_socket";
-
-char *bind_socket_pathname;
-
-main(argc, argv)
-	char **argv;
-{
-	if (argc < 3 || argc > 4) {
-		fprintf(stderr,
-			"usage: %s serial-port baud [socket-pathname]\n",
-			argv[0]);
-		exit(1);
-	}
-	open_target_serial(argv[1], argv[2]);
-	set_serial_nonblock(0);
-	init_cmu200();
-	if (argc > 3)
-		bind_socket_pathname = argv[3];
-	else
-		bind_socket_pathname = default_socket_pathname;
-	create_listener_socket();
-	for (;;) {
-		get_socket_connection();
-		handle_session();
-	}
-}
--- a/rfcal/cmu200/openport.c	Sat Aug 12 17:37:02 2017 +0000
+++ /dev/null	Thu Jan 01 00:00:00 1970 +0000
@@ -1,71 +0,0 @@
-/*
- * Serial port opening code for talking to CMU200
- */
-
-#include <sys/types.h>
-#include <sys/file.h>
-#include <sys/ioctl.h>
-#include <termios.h>
-#include <stdio.h>
-#include <stdlib.h>
-#include <string.h>
-#include <strings.h>
-#include <unistd.h>
-
-extern int target_fd;
-
-static struct baudrate {
-	char	*name;
-	speed_t	termios_code;
-} baud_rate_table[] = {
-	{"1200",	B1200},
-	{"2400",	B2400},
-	{"4800",	B4800},
-	{"9600",	B9600},
-	{"19200",	B19200},
-	{"38400",	B38400},
-	{"57600",	B57600},
-	{"115200",	B115200},
-	/* table search terminator */
-	{NULL,		B0}
-};
-
-open_target_serial(ttydev, baudname)
-	char *ttydev, *baudname;
-{
-	struct termios target_termios;
-	struct baudrate *br;
-
-	for (br = baud_rate_table; br->name; br++)
-		if (!strcmp(br->name, baudname))
-			break;
-	if (!br->name) {
-		fprintf(stderr, "baud rate \"%s\" unknown/unsupported\n",
-			baudname);
-		exit(1);
-	}
-	target_fd = open(ttydev, O_RDWR|O_NONBLOCK);
-	if (target_fd < 0) {
-		perror(ttydev);
-		exit(1);
-	}
-	target_termios.c_iflag = IGNBRK;
-	target_termios.c_oflag = 0;
-	target_termios.c_cflag = CLOCAL|HUPCL|CREAD|CS8|CRTSCTS;
-	target_termios.c_lflag = 0;
-	target_termios.c_cc[VMIN] = 1;
-	target_termios.c_cc[VTIME] = 0;
-	cfsetispeed(&target_termios, br->termios_code);
-	cfsetospeed(&target_termios, br->termios_code);
-	if (tcsetattr(target_fd, TCSAFLUSH, &target_termios) < 0) {
-		perror("initial tcsetattr on target");
-		exit(1);
-	}
-	return 0;
-}
-
-set_serial_nonblock(state)
-	int state;
-{
-	ioctl(target_fd, FIONBIO, &state);
-}
--- a/rfcal/cmu200/secaddr.h	Sat Aug 12 17:37:02 2017 +0000
+++ /dev/null	Thu Jan 01 00:00:00 1970 +0000
@@ -1,14 +0,0 @@
-/*
- * The assignment of secondary addresses to CMU200 function groups is
- * arbitrary, but we need *some* assignment in order to access the SCPI
- * objects that correspond to useful functions.  We define our secondary
- * address assignments in this header file, set them up on the CMU200
- * at start-up, and then use them to access the functions we need
- * when we need them.
- */
-
-#define	SECADDR_RF_NSIG		1
-#define	SECADDR_GSM900MS_NSIG	2
-#define	SECADDR_GSM1800MS_NSIG	3
-#define	SECADDR_GSM1900MS_NSIG	4
-#define	SECADDR_GSM850MS_NSIG	5
--- a/rfcal/cmu200/sercmd.c	Sat Aug 12 17:37:02 2017 +0000
+++ /dev/null	Thu Jan 01 00:00:00 1970 +0000
@@ -1,58 +0,0 @@
-/*
- * This module contains the functions that send serial commands to the CMU200
- * and collect the instrument's serial responses.
- */
-
-#include <sys/types.h>
-#include <ctype.h>
-#include <stdio.h>
-#include <stdlib.h>
-#include <unistd.h>
-#include <string.h>
-#include <strings.h>
-
-extern int target_fd;
-
-char instrument_response[4096];
-
-send_scpi_cmd(cmd)
-	char *cmd;
-{
-	printf("Command to CMU: %s", cmd);
-	write(target_fd, cmd, strlen(cmd));
-}
-
-collect_instr_response()
-{
-	char buf[BUFSIZ];
-	int cc, pos;
-
-	for (pos = 0; ; ) {
-		cc = read(target_fd, buf, sizeof buf);
-		if (cc <= 0) {
-			perror("error reading from serial port");
-			exit(1);
-		}
-		if (pos + cc > sizeof instrument_response) {
-			fprintf(stderr,
-		"error: response from CMU200 exceeds our buffer size\n");
-			exit(1);
-		}
-		bcopy(buf, instrument_response + pos, cc);
-		pos += cc;
-		if (instrument_response[pos-1] == '\n')
-			break;
-	}
-	instrument_response[pos-1] = '\0';
-	printf("Instrument response: %s\n", instrument_response);
-}
-
-collect_staropc_response()
-{
-	collect_instr_response();
-	if (instrument_response[0] != '1' ||
-	    instrument_response[1] && !isspace(instrument_response[1])) {
-		fprintf(stderr, "error: unexpected response to *OPC?\n");
-		exit(1);
-	}
-}
--- a/rfcal/cmu200/sertool.c	Sat Aug 12 17:37:02 2017 +0000
+++ /dev/null	Thu Jan 01 00:00:00 1970 +0000
@@ -1,88 +0,0 @@
-/*
- * This module contains the main() function for fc-serscpi, a manual tool
- * intended for learning how to control the CMU200 with SCPI commands
- * over RS-232.
- */
-
-#include <sys/types.h>
-#include <sys/errno.h>
-#include <stdio.h>
-#include <stdlib.h>
-#include <unistd.h>
-#include <strings.h>
-
-extern int errno;
-
-int target_fd;
-
-static void
-safe_output(buf, cc)
-	u_char *buf;
-{
-	int i, c;
-
-	for (i = 0; i < cc; i++) {
-		c = buf[i];
-		if (c == '\r' || c == '\n' || c == '\t' || c == '\b') {
-			putchar(c);
-			continue;
-		}
-		if (c & 0x80) {
-			putchar('M');
-			putchar('-');
-			c &= 0x7F;
-		}
-		if (c < 0x20) {
-			putchar('^');
-			putchar(c + '@');
-		} else if (c == 0x7F) {
-			putchar('^');
-			putchar('?');
-		} else
-			putchar(c);
-	}
-	fflush(stdout);
-}
-
-main(argc, argv)
-	char **argv;
-{
-	char buf[BUFSIZ];
-	fd_set fds, fds1;
-	register int i, cc, max;
-
-	if (argc != 3) {
-		fprintf(stderr, "usage: %s ttyname baudrate\n", argv[0]);
-		exit(1);
-	}
-	open_target_serial(argv[1], argv[2]);
-	set_serial_nonblock(0);
-	FD_ZERO(&fds);
-	FD_SET(0, &fds);
-	FD_SET(target_fd, &fds);
-	max = target_fd + 1;
-	for (;;) {
-		bcopy(&fds, &fds1, sizeof(fd_set));
-		i = select(max, &fds1, NULL, NULL, NULL);
-		if (i < 0) {
-			if (errno == EINTR)
-				continue;
-			perror("select");
-			exit(1);
-		}
-		if (FD_ISSET(0, &fds1)) {
-			cc = read(0, buf, sizeof buf);
-			if (cc <= 0)
-				exit(0);
-			write(target_fd, buf, cc);
-		}
-		if (FD_ISSET(target_fd, &fds1)) {
-			cc = read(target_fd, buf, sizeof buf);
-			if (cc <= 0) {
-				fprintf(stderr, "EOF/error on target tty\n");
-				exit(1);
-			}
-			safe_output(buf, cc);
-		}
-	}
-}
--- a/rfcal/cmu200/session.c	Sat Aug 12 17:37:02 2017 +0000
+++ /dev/null	Thu Jan 01 00:00:00 1970 +0000
@@ -1,86 +0,0 @@
-/*
- * This module contains the code that handles a single local socket
- * connection session.
- */
-
-#include <ctype.h>
-#include <stdio.h>
-#include <stdlib.h>
-#include <string.h>
-#include <strings.h>
-
-extern int activesock;
-
-#define	MAX_FIELDS	10
-
-char client_cmd[256], *client_cmd_fields[MAX_FIELDS+1];
-int client_cmd_nfields;
-
-parse_cmd_into_fields()
-{
-	char *cp;
-
-	client_cmd_nfields = 0;
-	for (cp = client_cmd; ; ) {
-		while (isspace(*cp))
-			cp++;
-		if (*cp == '\0')
-			break;
-		if (client_cmd_nfields >= MAX_FIELDS) {
-			send_socket_response("-Command has too many fields\n");
-			return(1);
-		}
-		client_cmd_fields[client_cmd_nfields++] = cp;
-		while (*cp && !isspace(*cp))
-			cp++;
-		if (*cp)
-			*cp++ = '\0';
-	}
-	client_cmd_fields[client_cmd_nfields] = 0;
-	return(0);
-}
-
-handle_command()
-{
-	char readbuf[256];
-	int cc, pos, rc;
-
-	for (pos = 0; ; ) {
-		cc = read(activesock, readbuf, sizeof readbuf);
-		if (cc <= 0) {
-			printf("Client program closed connection\n");
-			return(1);
-		}
-		if (pos + cc > sizeof client_cmd) {
-			send_socket_response("-Command too long\n");
-			return(1);
-		}
-		bcopy(readbuf, client_cmd + pos, cc);
-		pos += cc;
-		if (client_cmd[pos-1] == '\n')
-			break;
-	}
-	client_cmd[pos-1] = '\0';
-	printf("Client command: %s\n", client_cmd);
-	rc = parse_cmd_into_fields();
-	if (rc)
-		return(0);
-	if (!client_cmd_nfields) {
-		send_socket_response("+Empty command OK\n");
-		return(0);
-	}
-	return dispatch_client_command();
-}
-
-handle_session()
-{
-	int rc;
-
-	send_socket_response("+CMU200 interface daemon ready\n");
-	for (;;) {
-		rc = handle_command();
-		if (rc)
-			break;
-	}
-	close(activesock);
-}
--- a/rfcal/cmu200/socket.c	Sat Aug 12 17:37:02 2017 +0000
+++ /dev/null	Thu Jan 01 00:00:00 1970 +0000
@@ -1,81 +0,0 @@
-/*
- * This module handles the local UNIX domain socket interface for fc-cmu200d.
- */
-
-#include <sys/types.h>
-#include <sys/socket.h>
-#include <sys/un.h>
-#include <stdio.h>
-#include <string.h>
-#include <strings.h>
-#include <stdlib.h>
-#include <unistd.h>
-
-int listener, activesock;
-
-extern char *bind_socket_pathname;
-
-create_listener_socket()
-{
-	/* local socket binding voodoo copied from osmocon */
-	struct sockaddr_un local;
-	unsigned int namelen;
-	int rc;
-
-	listener = socket(AF_UNIX, SOCK_STREAM, 0);
-	if (listener < 0) {
-		perror("socket(AF_UNIX, SOCK_STREAM, 0)");
-		exit(1);
-	}
-
-	local.sun_family = AF_UNIX;
-	strncpy(local.sun_path, bind_socket_pathname, sizeof(local.sun_path));
-	local.sun_path[sizeof(local.sun_path) - 1] = '\0';
-	unlink(local.sun_path);
-
-	/* we use the same magic that X11 uses in Xtranssock.c for
-	 * calculating the proper length of the sockaddr */
-#if defined(BSD44SOCKETS) || defined(__UNIXWARE__)
-	local.sun_len = strlen(local.sun_path);
-#endif
-#if defined(BSD44SOCKETS) || defined(SUN_LEN)
-	namelen = SUN_LEN(&local);
-#else
-	namelen = strlen(local.sun_path) +
-		  offsetof(struct sockaddr_un, sun_path) + 1;
-#endif
-
-	rc = bind(listener, (struct sockaddr *) &local, namelen);
-	if (rc != 0) {
-		perror("bind on local socket");
-		exit(1);
-	}
-	rc = listen(listener, 1);
-	if (rc != 0) {
-		perror("listen");
-		exit(1);
-	}
-	return(0);
-}
-
-get_socket_connection()
-{
-	struct sockaddr_un un_addr;
-	socklen_t len;
-
-	len = sizeof(un_addr);
-	activesock = accept(listener, (struct sockaddr *) &un_addr, &len);
-	if (activesock < 0) {
-		perror("socket accept");
-		exit(1);
-	}
-	printf("Accepted local socket connection\n");
-	return(0);
-}
-
-send_socket_response(str)
-	char *str;
-{
-	printf("Msg to client: %s", str);
-	write(activesock, str, strlen(str));
-}
--- a/rfcal/tsid-test/Makefile	Sat Aug 12 17:37:02 2017 +0000
+++ /dev/null	Thu Jan 01 00:00:00 1970 +0000
@@ -1,16 +0,0 @@
-CC=	gcc
-CFLAGS=	-O2
-PROGS=	fc-tsid-shell
-INSTBIN=/opt/freecalypso/bin
-
-all:	${PROGS}
-
-fc-tsid-shell:	fc-tsid-shell.c
-	${CC} ${CFLAGS} -o $@ $@.c
-
-install:
-	mkdir -p ${INSTBIN}
-	install -c ${PROGS} ${INSTBIN}
-
-clean:
-	rm -f *.o *.out *errs ${PROGS}
--- a/rfcal/tsid-test/fc-tsid-shell.c	Sat Aug 12 17:37:02 2017 +0000
+++ /dev/null	Thu Jan 01 00:00:00 1970 +0000
@@ -1,109 +0,0 @@
-/*
- * This program connects to the RF calibration Test System Interface Daemon
- * (TSID) over the local socket interface and allows manual human interaction
- * with the TSID for development.
- */
-
-#include <sys/types.h>
-#include <sys/socket.h>
-#include <sys/un.h>
-#include <sys/errno.h>
-#include <stdio.h>
-#include <string.h>
-#include <strings.h>
-#include <stdlib.h>
-#include <unistd.h>
-
-extern int errno;
-
-static char default_socket_pathname[] = "/tmp/fc_rftest_socket";
-
-char *socket_pathname;
-int sock;
-
-connect_local_socket()
-{
-	/* local socket binding voodoo copied from osmocon */
-	struct sockaddr_un local;
-	unsigned int namelen;
-	int rc;
-
-	sock = socket(AF_UNIX, SOCK_STREAM, 0);
-	if (sock < 0) {
-		perror("socket(AF_UNIX, SOCK_STREAM, 0)");
-		exit(1);
-	}
-
-	local.sun_family = AF_UNIX;
-	strncpy(local.sun_path, socket_pathname, sizeof(local.sun_path));
-	local.sun_path[sizeof(local.sun_path) - 1] = '\0';
-
-	/* we use the same magic that X11 uses in Xtranssock.c for
-	 * calculating the proper length of the sockaddr */
-#if defined(BSD44SOCKETS) || defined(__UNIXWARE__)
-	local.sun_len = strlen(local.sun_path);
-#endif
-#if defined(BSD44SOCKETS) || defined(SUN_LEN)
-	namelen = SUN_LEN(&local);
-#else
-	namelen = strlen(local.sun_path) +
-		  offsetof(struct sockaddr_un, sun_path) + 1;
-#endif
-
-	rc = connect(sock, (struct sockaddr *) &local, namelen);
-	if (rc != 0) {
-		perror(socket_pathname);
-		exit(1);
-	}
-
-	return(0);
-}
-
-main(argc, argv)
-	char **argv;
-{
-	char buf[BUFSIZ];
-	fd_set fds, fds1;
-	register int i, cc, max;
-
-	switch (argc) {
-	case 1:
-		socket_pathname = default_socket_pathname;
-		break;
-	case 2:
-		socket_pathname = argv[1];
-		break;
-	default:
-		fprintf(stderr, "usage: %s [socket-pathname]\n", argv[0]);
-		exit(1);
-	}
-	connect_local_socket();
-	FD_ZERO(&fds);
-	FD_SET(0, &fds);
-	FD_SET(sock, &fds);
-	max = sock + 1;
-	for (;;) {
-		bcopy(&fds, &fds1, sizeof(fd_set));
-		i = select(max, &fds1, NULL, NULL, NULL);
-		if (i < 0) {
-			if (errno == EINTR)
-				continue;
-			perror("select");
-			exit(1);
-		}
-		if (FD_ISSET(0, &fds1)) {
-			cc = read(0, buf, sizeof buf);
-			if (cc <= 0)
-				exit(0);
-			write(sock, buf, cc);
-		}
-		if (FD_ISSET(sock, &fds1)) {
-			cc = read(sock, buf, sizeof buf);
-			if (cc <= 0) {
-				fprintf(stderr, "EOF/error on socket read\n");
-				exit(1);
-			}
-			write(1, buf, cc);
-		}
-	}
-}
--- a/rfcal/vcxo-manual/Makefile	Sat Aug 12 17:37:02 2017 +0000
+++ /dev/null	Thu Jan 01 00:00:00 1970 +0000
@@ -1,22 +0,0 @@
-CC=	gcc
-CFLAGS=	-O2
-PROGS=	fc-vcxo-linear fc-vcxo-param
-INSTBIN=/opt/freecalypso/bin
-
-LINEAR_OBJS=	linear.o readmeas.o
-GENPARAMS_OBJS=	genparams.o readmeas.o
-
-all:	${PROGS}
-
-fc-vcxo-linear:	${LINEAR_OBJS}
-	${CC} ${CFLAGS} -o $@ ${LINEAR_OBJS}
-
-fc-vcxo-param:	${GENPARAMS_OBJS}
-	${CC} ${CFLAGS} -o $@ ${GENPARAMS_OBJS}
-
-install:
-	mkdir -p ${INSTBIN}
-	install -c ${PROGS} ${INSTBIN}
-
-clean:
-	rm -f *.o *.out *errs ${PROGS}
--- a/rfcal/vcxo-manual/genparams.c	Sat Aug 12 17:37:02 2017 +0000
+++ /dev/null	Thu Jan 01 00:00:00 1970 +0000
@@ -1,77 +0,0 @@
-#include <math.h>
-#include <stdio.h>
-#include <stdlib.h>
-#include "meas.h"
-
-struct meas meas[4];
-float lin_a, lin_b, lin_a2, lin_b2;
-float dac_min, dac_max, dac_init;
-float Psi_sta, Psi_st;
-
-write_output(filename)
-	char *filename;
-{
-	FILE *outf;
-
-	if (filename) {
-		outf = fopen(filename, "w");
-		if (!outf) {
-			perror(filename);
-			exit(1);
-		}
-	} else
-		outf = stdout;
-
-	fputs("rf_table afcparams\n\n", outf);
-	/* Psi parameters */
-	fprintf(outf, "%10u\t# Psi_sta_inv\n", (unsigned)(1.0f / Psi_sta));
-	fprintf(outf, "%10u\t# Psi_st\n", (unsigned)(Psi_st * 65536.0f));
-	fprintf(outf, "%10u\t# Psi_st_32\n",
-		(unsigned)(Psi_st * 65536.0f * 65536.0f));
-	fprintf(outf, "%10u\t# Psi_st_inv\n\n", (unsigned)(1.0f / Psi_st));
-	/* DAC settings */
-	fprintf(outf, "%10d\t# DAC_INIT * 8\n", (int)(dac_init * 8.0f));
-	fprintf(outf, "%10d\t# DAC_MIN * 8\n", (int)(dac_min * 8.0f));
-	fprintf(outf, "%10d\t# DAC_MAX * 8\n", (int)(dac_max * 8.0f));
-	fprintf(outf, "%10d\t# snr_thr\n", 2560);
-	/* rfpw 10 setting in a comment line */
-	fprintf(outf, "\n# DAC_INIT: rfpw 10 %d\n", (int)dac_init);
-
-	if (filename)
-		fclose(outf);
-}
-
-main(argc, argv)
-	char **argv;
-{
-	if (argc < 2 || argc > 3) {
-		fprintf(stderr, "usage: %s meas-file [outfile]\n", argv[0]);
-		exit(1);
-	}
-	read_meas_file(argv[1], meas, 4);
-
-	/* first linear approximation */
-	lin_a = (float)(meas[1].freq_offset - meas[0].freq_offset) /
-		(float)(meas[1].dac_value - meas[0].dac_value);
-	lin_b = (float)meas[1].freq_offset - lin_a * meas[1].dac_value;
-
-	/* second linear approximation */
-	lin_a2 = (float)(meas[3].freq_offset - meas[2].freq_offset) /
-		(float)(meas[3].dac_value - meas[2].dac_value);
-	lin_b2 = (float)meas[3].freq_offset - lin_a2 * meas[3].dac_value;
-
-	/* DAC settings */
-	dac_min = (-13500.0f - lin_b) / lin_a;
-	dac_max = (13500.0f - lin_b) / lin_a;
-	dac_init = -lin_b2 / lin_a2;
-
-	/* Psi computations */
-	Psi_sta = 2.0f * (float)M_PI *
-		(float)(meas[1].freq_offset - meas[0].freq_offset) /
-		((float)(meas[1].dac_value - meas[0].dac_value) * 270833.0f);
-	Psi_st = Psi_sta * 0.8f;
-
-	/* spit it all out */
-	write_output(argv[2]);
-	exit(0);
-}
--- a/rfcal/vcxo-manual/linear.c	Sat Aug 12 17:37:02 2017 +0000
+++ /dev/null	Thu Jan 01 00:00:00 1970 +0000
@@ -1,27 +0,0 @@
-#include <stdio.h>
-#include <stdlib.h>
-#include "meas.h"
-
-struct meas meas[2];
-float lin_a, lin_b, target_off;
-int target_dac;
-
-main(argc, argv)
-	char **argv;
-{
-	if (argc < 2 || argc > 3) {
-		fprintf(stderr, "usage: %s meas-file [target]\n", argv[0]);
-		exit(1);
-	}
-	read_meas_file(argv[1], meas, 2);
-	if (argc > 2)
-		target_off = atof(argv[2]);
-	else
-		target_off = 0;
-	lin_a = (float)(meas[1].freq_offset - meas[0].freq_offset) /
-		(float)(meas[1].dac_value - meas[0].dac_value);
-	lin_b = (float)meas[1].freq_offset - lin_a * meas[1].dac_value;
-	target_dac = (target_off - lin_b) / lin_a;
-	printf("%d\n", target_dac);
-	exit(0);
-}
--- a/rfcal/vcxo-manual/meas.h	Sat Aug 12 17:37:02 2017 +0000
+++ /dev/null	Thu Jan 01 00:00:00 1970 +0000
@@ -1,4 +0,0 @@
-struct meas {
-	int	dac_value;
-	int	freq_offset;
-};
--- a/rfcal/vcxo-manual/readmeas.c	Sat Aug 12 17:37:02 2017 +0000
+++ /dev/null	Thu Jan 01 00:00:00 1970 +0000
@@ -1,61 +0,0 @@
-#include <ctype.h>
-#include <stdio.h>
-#include <stdlib.h>
-#include "meas.h"
-
-read_meas_file(filename, meas_table, nmeas)
-	char *filename;
-	struct meas *meas_table;
-{
-	FILE *f;
-	char linebuf[256], *cp, *np;
-	int lineno;
-	struct meas *mtp;
-	int got_meas;
-
-	f = fopen(filename, "r");
-	if (!f) {
-		perror(filename);
-		exit(1);
-	}
-	mtp = meas_table;
-	got_meas = 0;
-	for (lineno = 1; fgets(linebuf, sizeof linebuf, f); lineno++) {
-		for (cp = linebuf; isspace(*cp); cp++)
-			;
-		if (*cp == '\0' || *cp == '#')
-			continue;
-		if (!isdigit(*cp) && *cp != '-' && *cp != '+') {
-inv:			fprintf(stderr, "%s line %d: invalid syntax\n",
-				filename, lineno);
-			exit(1);
-		}
-		np = cp++;
-		while (isdigit(*cp))
-			cp++;
-		if (!isspace(*cp))
-			goto inv;
-		mtp->dac_value = atoi(np);
-		while (isspace(*cp))
-			cp++;
-		if (!isdigit(*cp) && *cp != '-' && *cp != '+')
-			goto inv;
-		np = cp++;
-		while (isdigit(*cp))
-			cp++;
-		if (*cp && !isspace(*cp))
-			goto inv;
-		mtp->freq_offset = atoi(np);
-		mtp++;
-		got_meas++;
-		if (got_meas >= nmeas)
-			break;
-	}
-	fclose(f);
-	if (got_meas < nmeas) {
-		fprintf(stderr, "error: need %d measurements, got %d in %s\n",
-			nmeas, got_meas, filename);
-		exit(1);
-	}
-	return 0;
-}