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authorlaforge <laforge@6dc7ffe9-61d6-0310-9af1-9938baff3ed1>2006-10-16 16:37:59 +0000
committerlaforge <laforge@6dc7ffe9-61d6-0310-9af1-9938baff3ed1>2006-10-16 16:37:59 +0000
commitea1423e7c9aa7da9e1017d71d8887a0b736db81e (patch)
tree1471cc5fa542be35472f32249aecf879caed0c01
parent1d505fbf35d1f9926c065402c5bd056e34df84b7 (diff)
add some bits and pieces of documentation
git-svn-id: https://svn.openpcd.org:2342/trunk@272 6dc7ffe9-61d6-0310-9af1-9938baff3ed1
-rw-r--r--doc/common-hardware.xml0
-rw-r--r--doc/common-hostsoftware.xml44
-rw-r--r--doc/common-targetsoftware.xml17
-rw-r--r--doc/common-usbproto.xml190
-rw-r--r--doc/openpcd.xml172
-rw-r--r--doc/openpicc.xml275
6 files changed, 698 insertions, 0 deletions
diff --git a/doc/common-hardware.xml b/doc/common-hardware.xml
new file mode 100644
index 0000000..e69de29
--- /dev/null
+++ b/doc/common-hardware.xml
diff --git a/doc/common-hostsoftware.xml b/doc/common-hostsoftware.xml
new file mode 100644
index 0000000..e35a598
--- /dev/null
+++ b/doc/common-hostsoftware.xml
@@ -0,0 +1,44 @@
+<section>Device Firmware Upgrade</section>
+<para>
+Since the device firmware is Free Software licensed under GNU GPL,
+we encourage and enable users to enhance and adapt the firmware according to
+their needs. In order to really benefit from this freedom, we have embedded
+an easy mechanism to update the device firmware without any special tools /
+adapters / cables / programmers or the like.
+</para>
+<para>
+The OpenPICC implements the USB Device Firmware Upgrade speficication,
+as released by the USB Association. Using this protocol, it is possible to
+update the device firmware via special-purpose USB control requests.
+</para>
+<para>
+A software implementation of the USB DFU host side was already available for
+Linux under the name of "dfu-programmer". However, this program did not
+implement the true standard, but some vendor-specific dialect of it.
+Therefore, dfu-programmer has been enhanced to have full native support
+for standard DFU.
+</para>
+</section> <!-- DFU -->
+
+<section>Emergency Firmware Flash</section>
+<para>
+The AT91SAM7 microcontroller used in the device contains a USB flash loader
+(called SAM-BA) in read-only memory. By setting a jumper on the PCB and
+powering up the device for 20 seconds, this loader can be copied into the
+first 8kb of flash memory, overwriting the existing content.
+</para>
+<para>
+So if the DFU loader has become inoperable, e.g. because of bugs in
+experimental DFU modifications, SAM-BA can be employed to rescue the system.
+</para>
+<para>
+Apart from proprietary Windows software by Atmel, there's the Free Software
+sam7utils project which provides a host program called 'sam7' to interface
+with SAM-BA and facilitate a full-flash rewrite with DFU and the device firmware.
+</para>
+<para>
+For more information on the flash procedure, we refer to the AT91SAM7 product
+documentation, as well as the sam7utils documentation.
+</para>
+</section> <!-- SAM-BA -->
+
diff --git a/doc/common-targetsoftware.xml b/doc/common-targetsoftware.xml
new file mode 100644
index 0000000..6e328ee
--- /dev/null
+++ b/doc/common-targetsoftware.xml
@@ -0,0 +1,17 @@
+<section>
+<title>Target Software</title>
+<para>
+The software doesn't use any operating system. Everything is implemented from
+scratch. Some of the API's (e.g. timer API) are modelled after the
+corresponding Linux kernel API's. However, this does not imply that any of the
+actual implementation is shared. The reason for matching the Linux API's is
+merely because they are well-understood and there's lots of example code using
+them.
+</para>
+<para>
+The SAM7 firmware is compiled using GNU GCC 4.0.2 for ARM. It uses GNU Make for
+processing the Makefiles. All development of the system happened on Linux,
+therefore your milage of compiling it on Windows might vary, but should
+theoretically work.
+</para>
+
diff --git a/doc/common-usbproto.xml b/doc/common-usbproto.xml
new file mode 100644
index 0000000..3b8b894
--- /dev/null
+++ b/doc/common-usbproto.xml
@@ -0,0 +1,190 @@
+<section>
+<title>USB Protocol</title>
+<para>
+The USB protocol is completely non-standard. Since OpenPICC is a very
+special-purpose device, it's obvious that no standard USB protocol will be
+applicable. However, our vendor-specific protocol is completely open and
+documented to allow for development of interoperable applications.
+</para>
+
+<section>
+<Title>USB Endpoints</title>
+<para>
+Since the SAM7 hardware only provides four USB endpoints, we have to use them
+according to their endpoint type, rather than to their function within the
+protocol. We have to overload and (de)multiplex within one endpoint quite a
+bit.
+</para>
+<para>
+EP0 - Control Endpoint
+EP1 - Bulk Out endpoint (host -> device)
+EP2 - Bulik In endpoint (device -> host)
+EP3 - Interrupt In endpoint (device -> host)
+</para>
+<para>
+The control endpoint behaves according to the USB specification. It only
+takes care of usb configuration and management. No application data is
+transferred over it.
+</para>
+</section> <!-- USB Endpoints -->
+
+<section>
+<title>USB packets, transfers</title>
+<para>
+In order to understand this devices' USB prootocol, some basics about any
+communication with USB endpoints need to be known.
+</para>
+<para>
+USB endpoints exchange a stream of data by means of USB transfers. Every
+transfer is conveyed as multiple transaction. Every transaction transports
+multiple USB packets. The Endpoint buffer size of the SAM7 usb device
+controller is 64bytes for EP1, EP2 and EP3. Therefore, a single packet can be
+up to 64 bytes in size. As soon as a packet smaller than the endpoint size
+(64byte) is received, the end of that particular USB transfer is detected.
+If the transfer size is an integral size of the endpoint size, a zero-length-packet (ZLP) is sent to explicitly signal the end of the transfer.
+</para>
+<para>
+The buffer management inside the SAM7 firmware can deal with USB transfers of
+up to 2048 bytes in size. To optimize memory efficiency, all buffers are
+statically pre-allocated, and the majority of USB buffers is only 64bytes in
+size. This way, the memory consumption for small transfers (such as register read/write transfers) can be kept low.
+</para>
+<para>
+Large transfers (&gt; 64 bytes, but &let; 2024 bytes) should be used only
+when they are absolutely required.
+</para>
+</section> <!-- USB packets, transfers -->
+
+<section>
+<title>Host software interaction with USB Endpoints</title>
+<para>
+Any host software operating the USB device should take into consideration
+that memory is a scarce resource on the SAM7, especially for
+applications with relatively high speed compared to the USB 1.1 full speed bandwith), such as higher-bitrate 847kHz ISO14443 communication.
+</para>
+<para>
+Therefore it is important to serve device requests on the BULK IN and
+INTERRUPT IN endpoints as soon as possible. In most cases, the application
+will simply keep those two pipes open all the time, by re-submitting an USB
+request block as soon as the previous one at that endpiont has completed.
+</para>
+<para>
+The BULK OUT endpoint will obviously only be filled with requests from the
+host software when there are any such requests.
+</para>
+<para>
+On the highest level of the protocol, there are three different classes of device requests:
+</para>
+<para>
+1. uni-directional without high-level acknowledgement, such as a register
+write without explicit request for a response. This means that the host
+software will only send a single BULK OUT transfer. This transfer is
+acknowledged inherently by the USB protocol, and the host software can be sure
+that the transfer was correctly received by the device.
+</para>
+<para>
+2. bi-directional with a single response, such as a register read. This means
+that the host sends a single BULK OUT transfer, to which the device replies
+with a single BULK IN transfer.
+</para>
+<para>
+3. bi-directional with multiple responses. This means that even though the
+host only sends a single BULK OUT transfer, there will be multiple BULK IN
+transfers in response.
+</para>
+</section> <!-- Host software interaction -->
+
+<section>
+<title>The usb transfer header</title>
+<para>
+Application data transferred over EP1, EP2 and EP3 is prefixed with a
+four-byte header, 'struct openpcd_hdr'.
+</para>
+<para>
+The first byte is the command byte. The high nibble of the command byte
+specifies the command class, whereas the the low nibble selects the particular
+command within a given class.
+</para>
+<para>
+The second byte specifies flags. There are currently two flags:
+</para>
+<para>
+The RESPOND flag signifies that the sender of this transfer explicitly
+requests a response back from the other side.
+</para>
+<para>
+The ERROR flag signifies that this transfer indicates some error
+</para>
+<para>
+The MULTIPLE flag signifies that this is part of a response that consists of
+multiple transfers.
+</para>
+<para>
+The LAST flag signifies that the current transfer is the last transfer
+of a multiple-transfer response.
+</para>
+<para>
+The third byte is called 'register' for historical purpose. It should
+actually rather be called address or index. Its significance differs
+according to the actual command that is being performed.
+</para>
+<para>
+The fourth byte is called 'val' for 'value'. Again, its purpose is command
+specific. In case of e.g. a register write, it is the value to be written
+into the register.
+</para>
+</section> <!-- USB Transfer Header -->
+
+<section>
+<title>The individual USB protocol commands</title>
+
+<section>
+<title>Generic USB commands: CMD_CLS_GENERIC</title>
+
+<section>
+<title>CMD_GET_VERSION</title>
+<para>
+This command is used to obtain the version number of the USB device. This
+might be used to differentiate different hardware revisions by the host software.
+</para>
+<para>
+The response to this command contains the version number in the
+variable-length 'data' section of the transfer.
+</para>
+</section>
+
+<section>
+<title>CMD_SET_LED</title>
+<para>
+Using this command, the host software can control the LED's present in the
+OpenPICC. The LED can be specified in the 'reg' section of the header.
+Currently there are two LED's, LED 1 (green) and LED 2 (red). The 'val'
+header field controls whether the LED should be switched on (1) or off (0).
+</para>
+</section>
+
+<section>
+<title>CMD_GET_SERIAL</title>
+<para>
+This command is used to obtain the serial number of the OpenPICC device.
+The serial number is returned in the 'data' section of the response transfer.
+</para>
+</section>
+
+</section> <!-- Generic USB commands -->
+
+<section>
+<title>USB Testing commands</title>
+<section>
+<title>CMD_USBTEST_IN</title>
+<para>
+</para>
+</section>
+<section>
+<title>CMD_USBTEST_OUT</title>
+<para>
+</para>
+</section>
+</section> <!-- USB testing commands -->
+
+
diff --git a/doc/openpcd.xml b/doc/openpcd.xml
new file mode 100644
index 0000000..719ba3a
--- /dev/null
+++ b/doc/openpcd.xml
@@ -0,0 +1,172 @@
+<?xml vesion='1.0' encoding='ISO-8859-1'?>
+<!DOCTYPE article PUBLIC '-//OASIS//DTD DocBook XML V4.3//EN' 'http://www.docbook.org/xml/4.3/docbook.dtd'>
+
+<article id="openpcd-reference">
+
+<articleinfo>
+ <title>OpenPCD - A 13.56MHz RFID reader</title>
+ <authorgroup>
+ <author>
+ <personname>
+ <first>Harald</first>
+ <surname>Welte</surname>
+ </personname>
+ <email>hwelte@hmw-consulting.de</email>
+ </author>
+ <author>
+ <personname>
+ <first>Milosch</first>
+ <surname>Meriac</surname>
+ </personname>
+ <email>meriac@bitmanufaktur.de</email>
+ </author>
+ </authorgroup>
+ <copyright>
+ <year>2006</year>
+ <holder>Harald Welte &lt;hwelte@hmw-consultin.de&gt; </holder>
+ </copyright>
+ <date>Oct 12, 2006</date>
+ <edition>1</edition>
+ <releaseinfo>
+ $Revision: 1.0 $
+ </releaseinfo>
+
+ <abstract>
+ <para>
+ This is the reference documentation for the OpenPCD RFID
+ reader.
+ </para>
+ <para>
+
+ </para>
+ </abstract>
+</articleinfo>
+
+<section>
+<title>Introduction</title>
+<para>
+The OpenPCD project is about desinging and building both hardware and software
+for a user-programmable reader (proximity coupling device, PCD) of the ISO
+14443 A+B (and later ISO15693) RFID protocols.
+</para>
+<para>
+The hardware is based on the Atmel AT91SAM7S128 microcontroller, featuring a
+48MHz, 32bit ARM7TDMI core with many integrated peripherals, such as USB
+device, SSC, ADC, 128kByte Flash, 32kByte SRAM, ...
+</para>
+<para>
+Next to the AT91SAM7, there is the Pilips CL RC 632 RFID reader ASIC. It
+is attached via SPI (Serial Peripheral Interface) to the AT91SAM7.
+</para>
+<para>
+The SAM7 attaches to a host PC using a USB 1.1 interface. The SAM7 firmware
+implements various forms of interface between the RC632 and the host PC.
+There are multiple firmware images available, some of them acting as a dumb
+transceiver, while others implement the full ISO 14443 protocol suite inside
+the SAM7 firmware.
+</para>
+<para>
+All device firmware and host software source code is released under GNU General
+Public License. The hardware design (schematics, PCB) is released under
+"Creative Commons share-alike attribution" License.
+</para>
+</section> <!-- Introduction -->
+
+<section>
+<title>Hardware</title>
+<para>
+FIXME: to be filled by milosch
+</para>
+
+<xi:xinclude href="common-hardware.xml" parse="xml" xmlns:xi="http://www.w3.org/2003/XInclude"/>
+
+</section>
+
+
+<section>
+<title>Software</title>
+
+<xi:include href="common-usbproto.xml" parse="xml" xmlns:xi="http://www.w3.org/2003/XInclude"/>
+
+<section>
+<title>PICC specific commands</title>
+<section>
+<title>CMD_PICC_REG_WRITE</title>
+<para>
+Using this command, a given OpenPICC register can be written to.
+</para>
+</section>
+<section>
+<title>CMD_PICC_REG_READ</title>
+<para>
+Using this command, a given OpenPICC register can be read.
+</para>
+</section>
+</section> <!-- PICC specific commands -->
+
+<section>
+<title>ADC specific commands</title>
+</section> <!-- ADC specific commands -->
+
+<section>
+<title>GPIO IRQ commands</title>
+<para>
+Using these commands, the host software can request a USB interrupt
+transfer to be sent once a given GPIO pin changes its level
+</para>
+</section> <!-- GPIO IRQ commands -->
+
+</section> <!-- USB protocol commands -->
+</section> <!-- USB protocol -->
+
+<xi:include href="common-targetsoftware.xml" parse="xml" xmlns:xi="http://www.w3.org/2003/XInclude"/>
+
+<section>
+<title>The main_dumbreader firmware</title>
+<para>
+The main_dumbreader firmware implements a very basic PCD/VCD firmware, where
+the USB device only implements an access layer to the RC632 registers and
+FIFO. All protocol and application logic has to be implemented on the host
+PC.
+</para>
+<para>
+This provides the greatest flexibility to the host software, since it can
+easily alter the behaviour of the device completely. Host development is
+easier than cross-compilation and remote debugging required for firmware
+development.
+</para>
+<para>
+Therefore, this firmware is the choice for most security researchers, since
+all timing and every bit of the protocol can be dealt with on the host.
+</para>
+</section> <!-- main_dumbreader -->
+
+<section>
+<title>The main_librfid firmware</title>
+<para>
+This firmware is called 'main_librfid' because it contains a full copy of the
+librfid library, cross compiled for ARM. The librfid library implements
+various 13.56MHz RFID protocols from layer 2 to layer 4 and higher, including
+ISO 14443, ISO 15693, Mifare classic, Mifare ultralight and others.
+</para>
+<para>
+The USB protocol of this firmware has not yet been fully speicified, also
+there currently is no finished host software that could interface this
+firmware yet. Stay tuned for upcoming news on this subject.
+</para>
+
+</section> <!-- Target Software -->
+
+<section>
+<title>Host Software</title>
+<para>
+TBD
+</para>
+
+<xi:include href="common-hostsoftware.xml" parse="xml" xmlns:xi="http://www.w3.org/2003/XInclude"/>
+
+</section> <!-- Host Software -->
+
+</section> <!-- Software -->
+
+</article>
diff --git a/doc/openpicc.xml b/doc/openpicc.xml
new file mode 100644
index 0000000..c687f48
--- /dev/null
+++ b/doc/openpicc.xml
@@ -0,0 +1,275 @@
+<?xml vesion='1.0' encoding='ISO-8859-1'?>
+<!DOCTYPE article PUBLIC '-//OASIS//DTD DocBook XML V4.3//EN' 'http://www.docbook.org/xml/4.3/docbookx.dtd'>
+
+<article id="openpicc-reference">
+
+<articleinfo>
+ <title>OpenPICC - A ISO 14443 A+B PICC RFID simulator</title>
+ <authorgroup>
+ <author>
+ <personname>
+ <first>Harald</first>
+ <surname>Welte</surname>
+ </personname>
+ <email>hwelte@hmw-consulting.de</email>
+ </author>
+ <author>
+ <personname>
+ <first>Milosch</first>
+ <surname>Meriac</surname>
+ </personname>
+ <email>meriac@bitmanufaktur.de</email>
+ </author>
+ </authorgroup>
+ <copyright>
+ <year>2006</year>
+ <holder>Harald Welte &lt;hwelte@hmw-consultin.de&gt; </holder>
+ </copyright>
+ <date>Oct 12, 2006</date>
+ <edition>1</edition>
+ <releaseinfo>
+ $Revision: 1.0 $
+ </releaseinfo>
+
+ <abstract>
+ <para>
+ This is the reference documentation for the OpenPICC RFID
+ simulator for ISO 14443.
+ </para>
+ <para>
+
+ </para>
+ </abstract>
+</articleinfo>
+
+<section>
+<title>Introduction</title>
+<para>
+The OpenPICC project is about desinging and building both hardware and software
+for a user-programmable simulator of the PICC (Transponder) side of the ISO
+14443 A+B (and later ISO15693) RFID protocols.
+</para>
+<para>
+The hardware is based on the Atmel AT91SAM7S256 microcontroller, featuring a
+48MHz, 32bit ARM7TDMI core with many integrated peripherals, such as USB
+device, SSC, ADC, 256kByte Flash, 64kByte SRAM, ...
+</para>
+<para>
+The SAM7 attaches to a host PC using a USB 1.1 interface. The SAM7 firmware
+implements encoding/decoding, the auxiliary hardware modulation/demodulation.
+The host PC therefore transmits and sends raw ISO 14443-3 frames, and
+implements higher protocol levels such as ISO 14443-4 or even a Smartcard OS
+simulation according to 7816-4.
+</para>
+<para>
+All device firmware and host software source code is released under GNU General
+Public License. The hardware design (schematics, PCB) is released under
+"Creative Commons share-alike attribution" License.
+</para>
+</section> <!-- Introduction -->
+
+<section>
+<title>Hardware</title>
+<para>
+FIXME: to be filled by milosch
+</para>
+
+<xi:xinclude href="common-hardware.xml" parse="xml" xmlns:xi="http://www.w3.org/2003/XInclude"/>
+
+</section>
+
+
+<section>
+<title>Software</title>
+
+<xi:include href="common-usbproto.xml" parse="xml" xmlns:xi="http://www.w3.org/2003/XInclude"/>
+
+<section>
+<title>PICC specific commands</title>
+<section>
+<title>CMD_PICC_REG_WRITE</title>
+<para>
+Using this command, a given OpenPICC register can be written to.
+</para>
+</section>
+<section>
+<title>CMD_PICC_REG_READ</title>
+<para>
+Using this command, a given OpenPICC register can be read.
+</para>
+</section>
+</section> <!-- PICC specific commands -->
+
+<section>
+<title>ADC specific commands</title>
+</section> <!-- ADC specific commands -->
+
+<section>
+<title>GPIO IRQ commands</title>
+<para>
+Using these commands, the host software can request a USB interrupt
+transfer to be sent once a given GPIO pin changes its level
+</para>
+</section> <!-- GPIO IRQ commands -->
+
+</section> <!-- USB protocol commands -->
+</section> <!-- USB protocol -->
+
+<xi:include href="common-targetsoftware.xml" parse="xml" xmlns:xi="http://www.w3.org/2003/XInclude"/>
+
+<section> <!-- Target Software -->
+
+<section>
+<title>The OpenPICC register set</title>
+<para>
+Most of the behaviour of the OpenPICC simulator can be controlled using the
+OpenPICC register set. This is not really a register set that corresponds to
+hardware registers. The registers are actually implemented in software, and
+act as global variables present in SAM7 RAM, which influence the OpenPICC
+firmware operation.
+</para>
+<para>
+This interface was chosen because it is something that software developers
+(more specificially: driver developers) are used to.
+</para>
+
+<section>
+<title>OPICC_REG_14443A_UIDLEN</title>
+<para>
+This register defines the length of the 14443-A UID or 14443-B PUPI. The
+length value is specified in bytes.
+</para>
+<para>
+Permitted values for 14443-A are: 4, 7 or 10.
+</para>
+<para>
+Permitted values for 14443-B are: 4.
+</para>
+</section>
+
+<section>
+<title>OPICC_REG_14443A_FDT0</title>
+<para>
+ISO 14443A synchronous frame delay time in case last bit of PCD->PICC frame
+was 0. According to the ISO 14443-3 specification, this has to be 1236.
+</para>
+</section>
+
+<section>
+<title>OPICC_REG_14443A_FDT1</title>
+<para>
+ISO 14443-3A synchronous frame delay time in case last bit of PCD->PICC frame
+was 1. According to the ISO 14443-3A specification, this has to be 1172.
+</para>
+</section>
+
+<section>
+<title>OPICC_REG_14443A_ATQA</title>
+<para>
+The ATQA register contains a template for the 14443-3A ATQA. Only the lowest
+five bits (0...4, bit frame anti-collision) and the bits 8..11 are used, the
+rest will be masked and or specified by the OpenPICC firmware.
+</para>
+</section>
+
+<section>
+<title>OPICC_REG_14443A_STATE</title>
+<para>
+The PICC state according to ISO 14443-3A. Possible values are:
+ISO14443A_ST_POWEROFF, ISO14443A_ST_IDLE, ISO14443A_ST_READY,
+ISO14443A_ST_ACTIVE, ISO14443A_ST_HALT, ISO14443A_ST_READY2,
+ISO14443A_ST_ACTIVE2.
+</para>
+</section>
+
+<section>
+<title>OPICC_REG_RX_CLK_DIV</title>
+<para>
+The receive clock divider register. This specifies the relationship
+between SSC sample clock and re-generated carrier clock.
+</para>
+<para>
+For ISO14443-A at 106kBp/s, this is usually set to 32 in order to produce
+a four-times oversampled signal. Values for higher baudrtes are TBD.
+</para>
+</section>
+
+<section>
+<title>OPICC_REG_RX_CLK_PHASE</title>
+<para>
+This register defines the phase of the receive sample clock. Values
+are given relative to the rx sample clock synchronization pulse caused
+by the first falling edge within the frame.
+</para>
+</section>
+
+<section>
+<title>OPICC_REG_RX_CONTROL</title>
+<para>
+The receive control register controls the OpenPICC receive path
+</para>
+</section>
+
+<section>
+<title>OPICC_REG_TX_CLK_DIV</title>
+<para>
+The transmit clock divider register determines the sample clock rate of the SSC
+transmit path. Since 14443-A and -B use a 847.5kHz subcarrier, the sample
+rate will have to be configured to 1.695MHz, and thus a clock divider of 8
+programmed into this register.
+</para>
+</section>
+
+<section>
+<title>OPICC_REG_TX_CLK_PHASE</title>
+<para>
+The transmit clock phase register defines the phase relationship between carrier clock and SSC Tx clock.
+</para>
+</section>
+
+<section>
+<title>OPICC_REG_TX_CONTROL</title>
+<para>
+The transmit control register is split in two sections: Lower nibble switches between BPSK (1) and MANCHESTER (2), whereas the higher nibble is used to configure the modulation depth (0..3).
+</para>
+</section>
+
+<section>
+<title>OPICC_REG_RX_COMP_LEVEL</title>
+<para>
+The demodulated Rx signal is digitized using a comparator. Using this
+register, the comparator reference value can be specified. The value is
+conveyed as a 7bit value in the range of 0..127.
+</para>
+</section>
+
+<section>
+<title>OPICC_SREG_14443A_UID</title>
+<para>
+This string register contains the 14443-3A UID or 14443-3B PUPI.
+</para>
+</section>
+
+</section> <!-- The OpenPICC register set -->
+
+</section> <!-- Target Software -->
+
+</section>
+
+</section> <!-- The OpenPICC register set -->
+
+</section> <!-- Target Software -->
+
+<section>
+<title>Host Software</title>
+<para>
+TBD
+</para>
+
+<xi:include href="common-hostsoftware.xml" parse="xml" xmlns:xi="http://www.w3.org/2003/XInclude"/>
+
+</section> <!-- Host Software -->
+
+</section> <!-- Software -->
+
+</article>
personal git repositories of Harald Welte. Your mileage may vary