FreeCalypso > hg > fc-sim-sniff
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fpga/sniffer-basic: drive pin 115 high for cardem pod
author | Mychaela Falconia <falcon@freecalypso.org> |
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date | Tue, 29 Aug 2023 18:05:09 +0000 |
parents | fbbafa93b52b |
children | 510bef2b2000 |
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Alternative implementation of SIMtrace idea, using iCE40 FPGA instead of AT91SAMx ============================================ Q: What is the principal idea behind SIMtrace, as distinct from the specific implementation realized by "standard" Osmocom SIMtrace? A: The two principal objectives of SIMtrace are: 1) Passive sniffing of communication between a phone-type device and a SIM, ideally as transparent and non-invasive as possible. 2) Card emulation: the SIMtrace apparatus presents itself to the phone (or modem or other phone-type device) as a SIM, either emulating the entire SIM CardOS functionality in software or communicating with a real SIM located somewhere remotely, across the Internet. Q: What are the shortcomings of the existing Osmocom SIMtrace implementation of the above goals? A: In the opinion of Mother Mychaela of FreeCalypso, the electrical aspects of Osmocom SIMtrace implementation are its biggest shortcoming. The following problems are most acute currently: * Current SIMtrace v2 hardware is not 5V-tolerant: connecting this apparatus to an old phone that puts out 5V (class A) on its SIM socket can damage the hardware, as class A SIM voltages exceed the absolute maximum rating spec of the AT91SAM3S4B microcontroller on the SIMtrace v2 board, which is connected directly to the SIM bus. * One option would be to revive the previous hardware generation as in SIMtrace v1, replacing the AT91SAM3S with AT91SAM7S. However, all firmware maintained by Osmocom is written for SAM3S only, thus a backport to SAM7S would involve significant work. Given that the resulting solution would still be far from my idea of perfection, I find it difficult to justify investing in that software effort - instead I would rather work on a more philosophically-proper solution. * AT91SAMx-based SIMtrace, both v1 and v2, works (most of the time, but not 100% reliably) with 1.8V phone-SIM combination (a phone that prefers class C and a SIM that supports it) only by accident. The Vih spec (the minimum required voltage on a signal line for it to register reliably as a 1) is 2.0 V for AT91SAM7S or 2.31 V (0.7 * Vddio, Vddio = 3.3 V) for AT91SAM3S, but the actual voltage on SIM interface lines in class C operation will never rise above 1.8 V. The electrical interface on this hw operates severely out of spec, and I find it rather miraculous that it works at all. Not surprisingly, reports are starting to trickle in with user experiences of it actually NOT working sometimes. * Even if the SIM interface is restricted (by the phone, by the SIM, or by SIMtrace MITM function tampering with ATR or file characteristics bytes) to operating in class B (3.0 V nominal) only, the existing AT91SAMx SIMtrace boards are still electrically unclean. Looking at the schematics, one can see that both CLK and I/O lines are pulled up (with resistors) to the SIMtrace board's 3.3V rail, which is a higher voltage that what the phone will put out (3.0 V or 1.8 V), and in the case of SIMtrace v1 with a 5V phone, that pull-up will turn into a pull-midway-down instead. * My philosophy is that the tracing apparatus should be making only a high- impedance connection to the SIM bus and nothing more, while the SIM bus itself is galvanically connected from the phone to the physical SIM without passing through any switches or other potential Heisenbug-inducing artifacts. My first thought was to gently modify the existing AT91SAMx-based SIMtrace design for electrically clean multivolt operation: * Replace the electrical switches for SIM VCC (FPF2109) and SIM RST/CLK/IO (CB3Q3244) with either a relay (my initial thought, but way too power-hungry) or a manually operated 5PDT slide switch; * Insert a Nexperia 74LVC4T3144 dual-supply buffer between the SIM bus and the MCU, providing a sniffing path that not only supports all 3 voltage classes, but is electrically clean, making only a high-impedance connection to the SIM bus as I desire; * Connect a 74LVC1G07 open drain driver (fed with TxD from the MCU) to the SIM bus I/O line, providing a signal path for card emulation mode. (In trace mode the firmware would be responsible for never turning on this OD driver, keeping the tracing apparatus High-Z.) However, as I was reading AT91SAMx datasheets more carefully in preparation for embarking on a project to turn the above idea into reality, I saw a big problem: when the USART is put into ISO 7816-3 mode, it uses the chip's TxD pin (switched to open drain operation) for both Rx and Tx, and there is no option to keep separate RxD and TxD pins with an external receiving buffer and an external OD driver. It would probably be possible to build an all-voltage SIM interface with AT91SAMx, perhaps by using one of those bidirectional level shifter ICs that somehow automagically handle driving direction reversals. But I personally am not too inclined to trust those automagical bidirectional translators, they just don't align with my design philosophy - I would much much rather have unidirectional buffers, one for sniffing and another for OD-driving the I/O line in card emulation mode. Seeing that AT91SAMx is incompatible with such electrical design, I decided to screw AT91SAMx and go for a radically different approach. Outline of FPGA-based alternative design ======================================== My (Mother Mychaela's) idea of alternative SIMtrace implementation consists of the following pieces: 1) The passive SIMtrace FPC connection board (boards/sim-fpc-pasv) is a trivial PCB that electrically interconnects a SIM socket, an FPC connection for SIMtrace FPC cables and a set of 2.54 mm header pins bringing out all SIM interface signals. 2) A second little adapter board (tentatively named mv-sniffer) will feature one active component, but will still be just as trivial: it will be a PCB hosting a single 74LVC4T3144 IC, with 2.54 mm header pins for the SIM side (SIM VCC will go to the buffer IC's VccA) and for the FPGA board side; a power rail from the latter board will go to the buffer IC's VccB. 3) The FPGA board will be an off-the-shelf item, eliminating the major hurdle of having to design and build a custom board of substantial complexity. My first attempt will be to use the Icestick board with iCE40HX1K FPGA; if this FPGA proves to be too small, I will then look for another suitable board with a bigger FPGA. The Icestick board features not only the HX1K FPGA, but also an FT2232H chip handling the USB interface. FT2232H channel A is for FPGA programming, but channel B is a regular UART, connected with PCB traces to FPGA I/O pins for user logic. The logic implemented in the FPGA will use this UART interface to communicate with higher-level software, which will be implemented as simple userspace programs - thus there is no "firmware" component per se. In terms of FPGA gateware functionality, the passive sniffer function will be implemented first; once it works, a different logic design will be implemented for card emulation mode. In terms of hardware as in boards, the first prototype version will use separate sim-fpc-pasv and mv-sniffer boards, connected with jumper wires between 2.54 mm header pins. Because the signals carried by these jumper wires reside on the "target" SIM bus side of the buffer, these wires add more than just clutter - they also add to the electrical length of the external SIM bus, which is obviously bad. Once the basic design is proven good, I plan to spin out another simple board that will feature the SIM socket, the SIMtrace FPC connector, the 74LVC4T3144 buffer and a header for connecting to the FPGA board. Because the latter connection resides past the buffer, wire length here does NOT add to the SIM bus. All of the just-described hardware config is for tracing only, not for card emulation. For the latter function yet another, albeit still very simple, adapter board will need to be made. The cardem adapter board will feature the SIMtrace FPC connector, two active ICs (74LVC4T3144 receiving buffer and 74LVC1G07 OD driver) and the header for connecting to the FPGA board. Note the absence of a SIM socket - hardware setups for sniffing a phone's communication with a real SIM on the one hand and for running with a software-emulated SIM on the other hand are different, and it does no good trying to combine them.