123456789101112131415161718192021222324252627282930313233343536373839404142434445464748495051525354555657585960616263646566676869707172737475767778798081828384858687888990919293949596979899100101102103104105106107108109110111112113114115116117118119120121122123124125126127128129130131132133134135136137138139140141142143144145146147148149150151152153154155156157158159160161162163164165166167168169170171172173174175176177178179180181182183184185186187188189190191192193194195196197198199200201202203204205206207208209210211212213214215216217218219220221222223224225226227228229230231232233234235236237238239240241242243244245246247248249250251252253254255256257258259260261262263264265266267268269270271272273274275276277278279280281282283284285286287288289290291292293294295296 |
- Freescale QUICC Engine Firmware Uploading
- -----------------------------------------
- (c) 2007 Timur Tabi <timur at freescale.com>,
- Freescale Semiconductor
- Table of Contents
- =================
- I - Software License for Firmware
- II - Microcode Availability
- III - Description and Terminology
- IV - Microcode Programming Details
- V - Firmware Structure Layout
- VI - Sample Code for Creating Firmware Files
- Revision Information
- ====================
- November 30, 2007: Rev 1.0 - Initial version
- I - Software License for Firmware
- =================================
- Each firmware file comes with its own software license. For information on
- the particular license, please see the license text that is distributed with
- the firmware.
- II - Microcode Availability
- ===========================
- Firmware files are distributed through various channels. Some are available on
- http://opensource.freescale.com. For other firmware files, please contact
- your Freescale representative or your operating system vendor.
- III - Description and Terminology
- ================================
- In this document, the term 'microcode' refers to the sequence of 32-bit
- integers that compose the actual QE microcode.
- The term 'firmware' refers to a binary blob that contains the microcode as
- well as other data that
- 1) describes the microcode's purpose
- 2) describes how and where to upload the microcode
- 3) specifies the values of various registers
- 4) includes additional data for use by specific device drivers
- Firmware files are binary files that contain only a firmware.
- IV - Microcode Programming Details
- ===================================
- The QE architecture allows for only one microcode present in I-RAM for each
- RISC processor. To replace any current microcode, a full QE reset (which
- disables the microcode) must be performed first.
- QE microcode is uploaded using the following procedure:
- 1) The microcode is placed into I-RAM at a specific location, using the
- IRAM.IADD and IRAM.IDATA registers.
- 2) The CERCR.CIR bit is set to 0 or 1, depending on whether the firmware
- needs split I-RAM. Split I-RAM is only meaningful for SOCs that have
- QEs with multiple RISC processors, such as the 8360. Splitting the I-RAM
- allows each processor to run a different microcode, effectively creating an
- asymmetric multiprocessing (AMP) system.
- 3) The TIBCR trap registers are loaded with the addresses of the trap handlers
- in the microcode.
- 4) The RSP.ECCR register is programmed with the value provided.
- 5) If necessary, device drivers that need the virtual traps and extended mode
- data will use them.
- Virtual Microcode Traps
- These virtual traps are conditional branches in the microcode. These are
- "soft" provisional introduced in the ROMcode in order to enable higher
- flexibility and save h/w traps If new features are activated or an issue is
- being fixed in the RAM package utilizing they should be activated. This data
- structure signals the microcode which of these virtual traps is active.
- This structure contains 6 words that the application should copy to some
- specific been defined. This table describes the structure.
- ---------------------------------------------------------------
- | Offset in | | Destination Offset | Size of |
- | array | Protocol | within PRAM | Operand |
- --------------------------------------------------------------|
- | 0 | Ethernet | 0xF8 | 4 bytes |
- | | interworking | | |
- ---------------------------------------------------------------
- | 4 | ATM | 0xF8 | 4 bytes |
- | | interworking | | |
- ---------------------------------------------------------------
- | 8 | PPP | 0xF8 | 4 bytes |
- | | interworking | | |
- ---------------------------------------------------------------
- | 12 | Ethernet RX | 0x22 | 1 byte |
- | | Distributor Page | | |
- ---------------------------------------------------------------
- | 16 | ATM Globtal | 0x28 | 1 byte |
- | | Params Table | | |
- ---------------------------------------------------------------
- | 20 | Insert Frame | 0xF8 | 4 bytes |
- ---------------------------------------------------------------
- Extended Modes
- This is a double word bit array (64 bits) that defines special functionality
- which has an impact on the software drivers. Each bit has its own impact
- and has special instructions for the s/w associated with it. This structure is
- described in this table:
- -----------------------------------------------------------------------
- | Bit # | Name | Description |
- -----------------------------------------------------------------------
- | 0 | General | Indicates that prior to each host command |
- | | push command | given by the application, the software must |
- | | | assert a special host command (push command)|
- | | | CECDR = 0x00800000. |
- | | | CECR = 0x01c1000f. |
- -----------------------------------------------------------------------
- | 1 | UCC ATM | Indicates that after issuing ATM RX INIT |
- | | RX INIT | command, the host must issue another special|
- | | push command | command (push command) and immediately |
- | | | following that re-issue the ATM RX INIT |
- | | | command. (This makes the sequence of |
- | | | initializing the ATM receiver a sequence of |
- | | | three host commands) |
- | | | CECDR = 0x00800000. |
- | | | CECR = 0x01c1000f. |
- -----------------------------------------------------------------------
- | 2 | Add/remove | Indicates that following the specific host |
- | | command | command: "Add/Remove entry in Hash Lookup |
- | | validation | Table" used in Interworking setup, the user |
- | | | must issue another command. |
- | | | CECDR = 0xce000003. |
- | | | CECR = 0x01c10f58. |
- -----------------------------------------------------------------------
- | 3 | General push | Indicates that the s/w has to initialize |
- | | command | some pointers in the Ethernet thread pages |
- | | | which are used when Header Compression is |
- | | | activated. The full details of these |
- | | | pointers is located in the software drivers.|
- -----------------------------------------------------------------------
- | 4 | General push | Indicates that after issuing Ethernet TX |
- | | command | INIT command, user must issue this command |
- | | | for each SNUM of Ethernet TX thread. |
- | | | CECDR = 0x00800003. |
- | | | CECR = 0x7'b{0}, 8'b{Enet TX thread SNUM}, |
- | | | 1'b{1}, 12'b{0}, 4'b{1} |
- -----------------------------------------------------------------------
- | 5 - 31 | N/A | Reserved, set to zero. |
- -----------------------------------------------------------------------
- V - Firmware Structure Layout
- ==============================
- QE microcode from Freescale is typically provided as a header file. This
- header file contains macros that define the microcode binary itself as well as
- some other data used in uploading that microcode. The format of these files
- do not lend themselves to simple inclusion into other code. Hence,
- the need for a more portable format. This section defines that format.
- Instead of distributing a header file, the microcode and related data are
- embedded into a binary blob. This blob is passed to the qe_upload_firmware()
- function, which parses the blob and performs everything necessary to upload
- the microcode.
- All integers are big-endian. See the comments for function
- qe_upload_firmware() for up-to-date implementation information.
- This structure supports versioning, where the version of the structure is
- embedded into the structure itself. To ensure forward and backwards
- compatibility, all versions of the structure must use the same 'qe_header'
- structure at the beginning.
- 'header' (type: struct qe_header):
- The 'length' field is the size, in bytes, of the entire structure,
- including all the microcode embedded in it, as well as the CRC (if
- present).
- The 'magic' field is an array of three bytes that contains the letters
- 'Q', 'E', and 'F'. This is an identifier that indicates that this
- structure is a QE Firmware structure.
- The 'version' field is a single byte that indicates the version of this
- structure. If the layout of the structure should ever need to be
- changed to add support for additional types of microcode, then the
- version number should also be changed.
- The 'id' field is a null-terminated string(suitable for printing) that
- identifies the firmware.
- The 'count' field indicates the number of 'microcode' structures. There
- must be one and only one 'microcode' structure for each RISC processor.
- Therefore, this field also represents the number of RISC processors for this
- SOC.
- The 'soc' structure contains the SOC numbers and revisions used to match
- the microcode to the SOC itself. Normally, the microcode loader should
- check the data in this structure with the SOC number and revisions, and
- only upload the microcode if there's a match. However, this check is not
- made on all platforms.
- Although it is not recommended, you can specify '0' in the soc.model
- field to skip matching SOCs altogether.
- The 'model' field is a 16-bit number that matches the actual SOC. The
- 'major' and 'minor' fields are the major and minor revision numbers,
- respectively, of the SOC.
- For example, to match the 8323, revision 1.0:
- soc.model = 8323
- soc.major = 1
- soc.minor = 0
- 'padding' is necessary for structure alignment. This field ensures that the
- 'extended_modes' field is aligned on a 64-bit boundary.
- 'extended_modes' is a bitfield that defines special functionality which has an
- impact on the device drivers. Each bit has its own impact and has special
- instructions for the driver associated with it. This field is stored in
- the QE library and available to any driver that calles qe_get_firmware_info().
- 'vtraps' is an array of 8 words that contain virtual trap values for each
- virtual traps. As with 'extended_modes', this field is stored in the QE
- library and available to any driver that calles qe_get_firmware_info().
- 'microcode' (type: struct qe_microcode):
- For each RISC processor there is one 'microcode' structure. The first
- 'microcode' structure is for the first RISC, and so on.
- The 'id' field is a null-terminated string suitable for printing that
- identifies this particular microcode.
- 'traps' is an array of 16 words that contain hardware trap values
- for each of the 16 traps. If trap[i] is 0, then this particular
- trap is to be ignored (i.e. not written to TIBCR[i]). The entire value
- is written as-is to the TIBCR[i] register, so be sure to set the EN
- and T_IBP bits if necessary.
- 'eccr' is the value to program into the ECCR register.
- 'iram_offset' is the offset into IRAM to start writing the
- microcode.
- 'count' is the number of 32-bit words in the microcode.
- 'code_offset' is the offset, in bytes, from the beginning of this
- structure where the microcode itself can be found. The first
- microcode binary should be located immediately after the 'microcode'
- array.
- 'major', 'minor', and 'revision' are the major, minor, and revision
- version numbers, respectively, of the microcode. If all values are 0,
- then these fields are ignored.
- 'reserved' is necessary for structure alignment. Since 'microcode'
- is an array, the 64-bit 'extended_modes' field needs to be aligned
- on a 64-bit boundary, and this can only happen if the size of
- 'microcode' is a multiple of 8 bytes. To ensure that, we add
- 'reserved'.
- After the last microcode is a 32-bit CRC. It can be calculated using
- this algorithm:
- u32 crc32(const u8 *p, unsigned int len)
- {
- unsigned int i;
- u32 crc = 0;
- while (len--) {
- crc ^= *p++;
- for (i = 0; i < 8; i++)
- crc = (crc >> 1) ^ ((crc & 1) ? 0xedb88320 : 0);
- }
- return crc;
- }
- VI - Sample Code for Creating Firmware Files
- ============================================
- A Python program that creates firmware binaries from the header files normally
- distributed by Freescale can be found on http://opensource.freescale.com.
|