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https://github.com/AsahiLinux/u-boot
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99 lines
4.9 KiB
Text
99 lines
4.9 KiB
Text
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The most frequent cause of problems when porting U-Boot to new
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hardware, or when using a sloppy port on some board, is memory errors.
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In most cases these are not caused by failing hardware, but by
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incorrect initialization of the memory controller. So it appears to
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be a good idea to always test if the memory is working correctly,
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before looking for any other potential causes of any problems.
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U-Boot implements 3 different approaches to perform memory tests:
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1. The get_ram_size() function (see "common/memsize.c").
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This function is supposed to be used in each and every U-Boot port
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determine the presence and actual size of each of the potential
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memory banks on this piece of hardware. The code is supposed to be
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very fast, so running it for each reboot does not hurt. It is a
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little known and generally underrated fact that this code will also
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catch 99% of hardware related (i. e. reliably reproducible) memory
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errors. It is strongly recommended to always use this function, in
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each and every port of U-Boot.
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2. The "mtest" command.
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This is probably the best known memory test utility in U-Boot.
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Unfortunately, it is also the most problematic, and the most
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useless one.
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There are a number of serious problems with this command:
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- It is terribly slow. Running "mtest" on the whole system RAM
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takes a _long_ time before there is any significance in the fact
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that no errors have been found so far.
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- It is difficult to configure, and to use. And any errors here
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will reliably crash or hang your system. "mtest" is dumb and has
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no knowledge about memory ranges that may be in use for other
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purposes, like exception code, U-Boot code and data, stack,
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malloc arena, video buffer, log buffer, etc. If you let it, it
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will happily "test" all such areas, which of course will cause
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some problems.
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- It is not easy to configure and use, and a large number of
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systems are seriously misconfigured. The original idea was to
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test basically the whole system RAM, with only exempting the
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areas used by U-Boot itself - on most systems these are the areas
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used for the exception vectors (usually at the very lower end of
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system memory) and for U-Boot (code, data, etc. - see above;
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these are usually at the very upper end of system memory). But
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experience has shown that a very large number of ports use
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pretty much bogus settings of CONFIG_SYS_MEMTEST_START and
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CONFIG_SYS_MEMTEST_END; this results in useless tests (because
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the ranges is too small and/or badly located) or in critical
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failures (system crashes).
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Because of these issues, the "mtest" command is considered depre-
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cated. It should not be enabled in most normal ports of U-Boot,
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especially not in production. If you really need a memory test,
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then see 1. and 3. above resp. below.
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3. The most thorough memory test facility is available as part of the
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POST (Power-On Self Test) sub-system, see "post/drivers/memory.c".
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If you really need to perform memory tests (for example, because
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it is mandatory part of your requirement specification), then
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enable this test which is generic and should work on all archi-
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tectures.
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WARNING:
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It should pointed out that _all_ these memory tests have one
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fundamental, unfixable design flaw: they are based on the assumption
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that memory errors can be found by writing to and reading from memory.
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Unfortunately, this is only true for the relatively harmless, usually
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static errors like shorts between data or address lines, unconnected
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pins, etc. All the really nasty errors which will first turn your
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hair gray, only to make you tear it out later, are dynamical errors,
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which usually happen not with simple read or write cycles on the bus,
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but when performing back-to-back data transfers in burst mode. Such
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accesses usually happen only for certain DMA operations, or for heavy
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cache use (instruction fetching, cache flushing). So far I am not
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aware of any freely available code that implements a generic, and
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efficient, memory test like that. The best known test case to stress
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a system like that is to boot Linux with root file system mounted over
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NFS, and then build some larger software package natively (say,
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compile a Linux kernel on the system) - this will cause enough context
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switches, network traffic (and thus DMA transfers from the network
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controller), varying RAM use, etc. to trigger any weak spots in this
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area.
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Note: An attempt was made once to implement such a test to catch
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memory problems on a specific board. The code is pretty much board
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specific (for example, it includes setting specific GPIO signals to
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provide triggers for an attached logic analyzer), but you can get an
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idea how it works: see "examples/standalone/test_burst*".
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Note 2: Ironically enough, the "test_burst" did not catch any RAM
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errors, not a single one ever. The problems this code was supposed
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to catch did not happen when accessing the RAM, but when reading from
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NOR flash.
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