FPGA-README 10 KB

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  1. This README contains extended details about FPGA mining with cgminer
  2. For ModMinerQuad (MMQ) BitForce (BFL) and Icarus (ICA, BLT, LLT, AMU, CMR)
  3. --------------------------------------------------------------------------
  4. See README 'SETTING UP USB DEVICES' for setting up USB mining with cgminer
  5. ModMinerQuad (MMQ)
  6. ------------------
  7. The mining bitstream does not survive a power cycle, so cgminer will upload
  8. it, if it needs to, before it starts mining (approx 7min 40sec)
  9. The red LED also flashes while it is uploading the bitstream
  10. -
  11. If the MMQ doesn't respond to cgminer at all, or the red LED isn't flashing
  12. then you will need to reset the MMQ
  13. The red LED should always be flashing when it is mining or ready to mine
  14. To reset the MMQ, you are best to press the left "RESET" button on the
  15. backplane, then unplug and replug the USB cable
  16. If your MMQ doesn't have a button on the "RESET" pad, you need to join
  17. the two left pads of the "RESET" pad with conductive wire to reset it.
  18. Cutting a small (metal) paper-clip in half works well for this
  19. Then unplug the USB cable, wait for 5 seconds, then plug it back in
  20. After you press reset, the red LED near the USB port should blink continuously
  21. If it still wont work, power off, wait for 5 seconds, then power on the MMQ
  22. This of course means it will upload the bitstream again when you start cgminer
  23. -
  24. Device 0 is on the power end of the board
  25. -
  26. You must make sure you have an approriate firmware in your MMQ
  27. Read here for official details of changing the firmware:
  28. http://wiki.btcfpga.com/index.php?title=Firmware
  29. The basics of changing the firmware are:
  30. You need two short pieces of conductive wire if your MMQ doesn't have
  31. buttons on the "RESET" and "ISP" pads on the backplane board
  32. Cutting a small (metal) paper-clip in half works well for this
  33. Join the 2 left pads of the "RESET" pad with wire and the led will dim
  34. Without disconnecting the "RESET", join the 2 left pads of the "ISP" pad
  35. with a wire and it will stay dim
  36. Release "RESET" then release "ISP" and is should still be dim
  37. Unplug the USB and when you plug it back in it will show up as a mass
  38. storage device
  39. Linux: (as one single line):
  40. mcopy -i /dev/disk/by-id/usb-NXP_LPC134X_IFLASH_ISP000000000-0:0
  41. modminer091012.bin ::/firmware.bin
  42. Windows: delete the MSD device file firmware.bin and copy in the new one
  43. rename the new file and put it under the same name 'firmware.bin'
  44. Disconnect the USB correctly (so writes are flushed first)
  45. Join and then disconnect "RESET" and then plug the USB back in and it's done
  46. Best to update to one of the latest 2 listed below if you don't already
  47. have one of them in your MMQ
  48. The current latest different firmware are:
  49. Latest for support of normal or TLM bitstream:
  50. http://btcfpga.com/files/firmware/modminer092612-TLM.bin
  51. Latest with only normal bitstream support (Temps/HW Fix):
  52. http://btcfpga.com/files/firmware/modminer091012.bin
  53. The code is currently tested on the modminer091012.bin firmware.
  54. This comment will be updated when others have been tested
  55. -
  56. On many linux distributions there is an app called modem-manager that
  57. may cause problems when it is enabled, due to opening the MMQ device
  58. and writing to it
  59. The problem will typically present itself by the flashing led on the
  60. backplane going out (no longer flashing) and it takes a power cycle to
  61. re-enable the MMQ firmware - which then can lead to the problem happening
  62. again
  63. You can either disable/uninstall modem-manager if you don't need it or:
  64. a (hack) solution to this is to blacklist the MMQ USB device in
  65. /lib/udev/rules.d/77-mm-usb-device-blacklist.rules
  66. Adding 2 lines like this (just above APC) should help
  67. # MMQ
  68. ATTRS{idVendor}=="1fc9", ATTRS{idProduct}=="0003", ENV{ID_MM_DEVICE_IGNORE}="1"
  69. The change will be lost and need to be re-done, next time you update the
  70. modem-manager software
  71. TODO: check that all MMQ's have the same product ID
  72. BitForce (BFL)
  73. --------------
  74. --bfl-range Use nonce range on bitforce devices if supported
  75. This option is only for bitforce devices. Earlier devices such as the single
  76. did not have any way of doing small amounts of work which meant that a lot of
  77. work could be lost across block changes. Some of the "minirigs" have support
  78. for doing this, so less work is lost across a longpoll. However, it comes at
  79. a cost of 1% in overall hashrate so this feature is disabled by default. It
  80. is only recommended you enable this if you are mining with a minirig on
  81. p2pool.
  82. C source is included for a bitforce firmware flash utility on Linux only:
  83. bitforce-firmware-flash.c
  84. Using this, you can change the bitstream firmware on bitforce singles.
  85. It is untested with other devices. Use at your own risk!
  86. To compile:
  87. make bitforce-firmware-flash
  88. To flash your BFL, specify the BFL port and the flash file e.g.:
  89. sudo ./bitforce-firmware-flash /dev/ttyUSB0 alphaminer_832.bfl
  90. It takes a bit under 3 minutes to flash a BFL and shows a progress % counter
  91. Once it completes, you may also need to wait about 15 seconds,
  92. then power the BFL off and on again
  93. If you get an error at the end of the BFL flash process stating:
  94. "Error reading response from ZBX"
  95. it may have worked successfully anyway.
  96. Test mining on it to be sure if it worked or not.
  97. You need to give cgminer about 10 minutes mining with the BFL to be sure of
  98. the MH/s value reported with the changed firmware - and the MH/s reported
  99. will be less than the firmware speed since you lose work on every block change.
  100. Icarus (ICA, BLT, LLT, AMU, CMR)
  101. --------------------------------
  102. There are two hidden options in cgminer when Icarus support is compiled in:
  103. --icarus-options <arg> Set specific FPGA board configurations - one set of values for all or comma separated
  104. baud:work_division:fpga_count
  105. baud The Serial/USB baud rate - 115200 or 57600 only - default 115200
  106. work_division The fraction of work divided up for each FPGA chip - 1, 2, 4 or 8
  107. e.g. 2 means each FPGA does half the nonce range - default 2
  108. fpga_count The actual number of FPGA working - this would normally be the same
  109. as work_division - range is from 1 up to 'work_division'
  110. It defaults to the value of work_division - or 2 if you don't specify
  111. work_division
  112. If you define fewer comma seperated values than Icarus devices, the last values will be used
  113. for all extra devices
  114. An example would be: --icarus-options 57600:2:1
  115. This would mean: use 57600 baud, the FPGA board divides the work in half however
  116. only 1 FPGA actually runs on the board (e.g. like an early CM1 Icarus copy bitstream)
  117. --icarus-timing <arg> Set how the Icarus timing is calculated - one setting/value for all or comma separated
  118. default[=N] Use the default Icarus hash time (2.6316ns)
  119. short=[N] Calculate the hash time and stop adjusting it at ~315 difficulty 1 shares (~1hr)
  120. long=[N] Re-calculate the hash time continuously
  121. value[=N] Specify the hash time in nanoseconds (e.g. 2.6316) and abort time (e.g. 2.6316=80)
  122. If you define fewer comma seperated values than Icarus devices, the last values will be used
  123. for all extra devices
  124. Icarus timing is required for devices that do not exactly match a default Icarus Rev3 in
  125. processing speed
  126. If you have an Icarus Rev3 you should not normally need to use --icarus-timing since the
  127. default values will maximise the MH/s and display it correctly
  128. Icarus timing is used to determine the number of hashes that have been checked when it aborts
  129. a nonce range (including on a LongPoll)
  130. It is also used to determine the elapsed time when it should abort a nonce range to avoid
  131. letting the Icarus go idle, but also to safely maximise that time
  132. 'short' or 'long' mode should only be used on a computer that has enough CPU available to run
  133. cgminer without any CPU delays (an active desktop or swapping computer would not be stable enough)
  134. Any CPU delays while calculating the hash time will affect the result
  135. 'short' mode only requires the computer to be stable until it has completed ~315 difficulty 1 shares
  136. 'long' mode requires it to always be stable to ensure accuracy, however, over time it continually
  137. corrects itself
  138. The optional additional =N for 'short' or 'long' specifies the limit to set the timeout to in N * 100ms
  139. thus if the timing code calculation is higher while running, it will instead use N * 100ms
  140. This can be set to the appropriate value to ensure the device never goes idle even if the
  141. calculation is negatively affected by system performance
  142. When in 'short' or 'long' mode, it will report the hash time value each time it is re-calculated
  143. In 'short' or 'long' mode, the scan abort time starts at 5 seconds and uses the default 2.6316ns
  144. scan hash time, for the first 5 nonce's or one minute (whichever is longer)
  145. In 'default' or 'value' mode the 'constants' are calculated once at the start, based on the default
  146. value or the value specified
  147. The optional additional =N specifies to set the default abort at N * 100ms, not the calculated
  148. value, which is ~112 for 2.6316ns
  149. To determine the hash time value for a non Icarus Rev3 device or an Icarus Rev3 with a different
  150. bitstream to the default one, use 'long' mode and give it at least a few hundred shares, or use
  151. 'short' mode and take note of the final hash time value (Hs) calculated
  152. You can also use the RPC API 'stats' command to see the current hash time (Hs) at any time
  153. The Icarus code currently only works with an FPGA device that supports the same commands as
  154. Icarus Rev3 requires and also is less than ~840MH/s and greater than 2MH/s
  155. If an FPGA device does hash faster than ~840MH/s it should work correctly if you supply the
  156. correct hash time nanoseconds value
  157. The Icarus code will automatically detect Icarus, Lancelot, AsicminerUSB and Cairnsmore1
  158. FPGA devices and set default settings to match those devices if you don't specify them
  159. The timing code itself will affect the Icarus performance since it increases the delay after
  160. work is completed or aborted until it starts again
  161. The increase is, however, extremely small and the actual increase is reported with the
  162. RPC API 'stats' command (a very slow CPU will make it more noticeable)
  163. Using the 'short' mode will remove this delay after 'short' mode completes
  164. The delay doesn't affect the calculation of the correct hash time