| Wolfgang Denk | a268170 | 2013-03-08 10:51:32 +0000 | [diff] [blame] | 1 | The most frequent cause of problems when porting U-Boot to new |
| 2 | hardware, or when using a sloppy port on some board, is memory errors. |
| 3 | In most cases these are not caused by failing hardware, but by |
| 4 | incorrect initialization of the memory controller. So it appears to |
| 5 | be a good idea to always test if the memory is working correctly, |
| 6 | before looking for any other potential causes of any problems. |
| 7 | |
| 8 | U-Boot implements 3 different approaches to perform memory tests: |
| 9 | |
| 10 | 1. The get_ram_size() function (see "common/memsize.c"). |
| 11 | |
| 12 | This function is supposed to be used in each and every U-Boot port |
| 13 | determine the presence and actual size of each of the potential |
| 14 | memory banks on this piece of hardware. The code is supposed to be |
| 15 | very fast, so running it for each reboot does not hurt. It is a |
| 16 | little known and generally underrated fact that this code will also |
| 17 | catch 99% of hardware related (i. e. reliably reproducible) memory |
| 18 | errors. It is strongly recommended to always use this function, in |
| 19 | each and every port of U-Boot. |
| 20 | |
| 21 | 2. The "mtest" command. |
| 22 | |
| 23 | This is probably the best known memory test utility in U-Boot. |
| 24 | Unfortunately, it is also the most problematic, and the most |
| 25 | useless one. |
| 26 | |
| 27 | There are a number of serious problems with this command: |
| 28 | |
| 29 | - It is terribly slow. Running "mtest" on the whole system RAM |
| 30 | takes a _long_ time before there is any significance in the fact |
| 31 | that no errors have been found so far. |
| 32 | |
| 33 | - It is difficult to configure, and to use. And any errors here |
| 34 | will reliably crash or hang your system. "mtest" is dumb and has |
| 35 | no knowledge about memory ranges that may be in use for other |
| 36 | purposes, like exception code, U-Boot code and data, stack, |
| 37 | malloc arena, video buffer, log buffer, etc. If you let it, it |
| 38 | will happily "test" all such areas, which of course will cause |
| 39 | some problems. |
| 40 | |
| 41 | - It is not easy to configure and use, and a large number of |
| 42 | systems are seriously misconfigured. The original idea was to |
| 43 | test basically the whole system RAM, with only exempting the |
| 44 | areas used by U-Boot itself - on most systems these are the areas |
| 45 | used for the exception vectors (usually at the very lower end of |
| 46 | system memory) and for U-Boot (code, data, etc. - see above; |
| 47 | these are usually at the very upper end of system memory). But |
| 48 | experience has shown that a very large number of ports use |
| 49 | pretty much bogus settings of CONFIG_SYS_MEMTEST_START and |
| 50 | CONFIG_SYS_MEMTEST_END; this results in useless tests (because |
| 51 | the ranges is too small and/or badly located) or in critical |
| 52 | failures (system crashes). |
| 53 | |
| 54 | Because of these issues, the "mtest" command is considered depre- |
| 55 | cated. It should not be enabled in most normal ports of U-Boot, |
| 56 | especially not in production. If you really need a memory test, |
| 57 | then see 1. and 3. above resp. below. |
| 58 | |
| 59 | 3. The most thorough memory test facility is available as part of the |
| 60 | POST (Power-On Self Test) sub-system, see "post/drivers/memory.c". |
| 61 | |
| 62 | If you really need to perform memory tests (for example, because |
| 63 | it is mandatory part of your requirement specification), then |
| 64 | enable this test which is generic and should work on all archi- |
| 65 | tectures. |
| 66 | |
| 67 | WARNING: |
| 68 | |
| 69 | It should pointed out that _all_ these memory tests have one |
| 70 | fundamental, unfixable design flaw: they are based on the assumption |
| 71 | that memory errors can be found by writing to and reading from memory. |
| 72 | Unfortunately, this is only true for the relatively harmless, usually |
| 73 | static errors like shorts between data or address lines, unconnected |
| 74 | pins, etc. All the really nasty errors which will first turn your |
| 75 | hair gray, only to make you tear it out later, are dynamical errors, |
| 76 | which usually happen not with simple read or write cycles on the bus, |
| 77 | but when performing back-to-back data transfers in burst mode. Such |
| 78 | accesses usually happen only for certain DMA operations, or for heavy |
| 79 | cache use (instruction fetching, cache flushing). So far I am not |
| 80 | aware of any freely available code that implements a generic, and |
| 81 | efficient, memory test like that. The best known test case to stress |
| 82 | a system like that is to boot Linux with root file system mounted over |
| 83 | NFS, and then build some larger software package natively (say, |
| 84 | compile a Linux kernel on the system) - this will cause enough context |
| 85 | switches, network traffic (and thus DMA transfers from the network |
| 86 | controller), varying RAM use, etc. to trigger any weak spots in this |
| 87 | area. |
| 88 | |
| 89 | Note: An attempt was made once to implement such a test to catch |
| 90 | memory problems on a specific board. The code is pretty much board |
| 91 | specific (for example, it includes setting specific GPIO signals to |
| 92 | provide triggers for an attached logic analyzer), but you can get an |
| 93 | idea how it works: see "examples/standalone/test_burst*". |
| 94 | |
| 95 | Note 2: Ironically enough, the "test_burst" did not catch any RAM |
| 96 | errors, not a single one ever. The problems this code was supposed |
| 97 | to catch did not happen when accessing the RAM, but when reading from |
| 98 | NOR flash. |