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I'm developing on an AD Blackfin BF537 DSP running uClinux. I have a total of 32MB SD-RAM available. I have an ADC attached, which I can access using a simple, blocking call to read().

The most interesting part of my code is below. Running the program seems to work just fine, I get a nice data package that I can fetch from the SD-card and plot. However, if I comment out the float calculation part (as noted in the code), I get only zeroes in the ft_all.raw file. The same occurs if I change optimization level from -O3 to -O0.

I've tried countless combinations of all sorts of things, and sometimes it works, sometimes it does not - earlier (with minor modifications to below), the code would only work when optimization was disabled. It may also break if I add something else further down in the file.

My suspicion is that the data transferred by the read()-function may not have been transferred fully (is that possible, even though it returns the correct number of bytes?). This is also the first time I initialize pointers using direct memory adresses, and I have no idea how the compiler reacts to this - perhaps I missed something, here?

I've spent days on this issue now, and I'm getting desperate - I would really appreciate some help on this one! Thanks in advance.

// Clear the top 16M memory for data processing
memset((int *)0x01000000,0x0000,(size_t)SIZE_16M);

/* Prep some pointers for data processing */
int16_t *buffer;
int16_t *buf16I, *buf16Q;

buffer = (int16_t *)(0x1000000);
buf16I = (int16_t *)(0x1600000);
buf16Q = (int16_t *)(0x1680000);

/* Read data from ADC */
int rbytes = read(Sportfd, (int16_t*)buffer, 0x200000);
if (rbytes != 0x200000) {
    printf("could not sample data! %X\n",rbytes);
    goto end;
} else {
    printf("Read %X bytes\n",rbytes);

FILE *outfd;
int wbytes;

/* Commenting this region results in all zeroes in ft_all.raw */
float a,b;
int c;
b = 0;
for (c = 0; c < 1000; c++) {
    a = c;
    b = b+pow(a,3);
printf("b is %.2f\n",b);

/* Only 12 LSBs of each 32-bit word is actual data.
 * First 20 bits of nothing, then 12 bits I, then 20 bits
 * nothing, then 12 bits Q, etc...
 * Below, the I and Q parts are scaled with a factor of 16
 * and extracted to buf16I and buf16Q.
 * */
int32_t *buf32;
buf32  = (int32_t *)buffer;
uint32_t i = 0;
uint32_t n = 0;
while (n < 0x80000) {
    buf16I[i] = buf32[n] << 4;
    buf16Q[i] = buf32[n] << 4;

printf("Saving to /mnt/sd/d/ft_all.raw...");
outfd = fopen("/mnt/sd/d/ft_all.raw", "w+");
if (outfd == NULL) {
    printf("Could not open file.\n");
wbytes = fwrite((int*)0x1600000, 1, 0x100000, outfd);
if (wbytes < 0x100000) {
    printf("wbytes not correct (= %d) \n", (int)wbytes);

printf(" done.\n");

Edit: The code seems to work perfectly well if I use read() to read data from a simple file rather than the ADC. This leads me to believe that the rather hacky-looking code when extracting the I and Q parts of the input is working as intended. Inspecting the assembly generated by the compiler confirms this.

I'm trying to get in touch with the developer of the ADC driver to see if he has an explanation of this behaviour.

The ADC is connected through a SPORT, and is opened as such:

sportfd = open("/dev/sport1", O_RDWR);
ioctl(sportfd, SPORT_IOC_CONFIG, spconf);

And here are the options used when configuring the SPORT:

spconf->int_clk     = 1;
spconf->word_len    = 32;
spconf->serial_clk  = SPORT_CLK;
spconf->fsync_clk   = SPORT_CLK/34;
spconf->fsync       = 1;
spconf->late_fsync  = 1;
spconf->act_low     = 1;
spconf->dma_enabled = 1;
spconf->tckfe       = 0;
spconf->rckfe       = 1;
spconf->txse        = 0;
spconf->rxse        = 1;

A bfin_sport.h file from Analog Devices is also included: https://gist.github.com/tausen/5516954

Update After a long night of debugging with the previous developer on the project, it turned out the issue was not related to the code shown above at all. As Chris suggested, it was indeed an issue with the SPORT driver and the ADC configuration.

While debugging, this error messaged appeared whenever the data was "broken": bfin_sport: sport ffc00900 status error: TUVF. While this doesn't make much sense in the application, it was clear from printing the data, that something was out of sync: the data in buffer was on the form 0x12000000,0x34000000,... rather than 0x00000012,0x00000034,... whenever the status error was shown. It seems clear then, why buf16I and buf16Q only contained zeroes (since I am extracting the 12 LSBs).

Putting in a few calls to usleep() between stages of ADC initialization and configuration seems to have fixed the issue - I'm hoping it stays that way!

share|improve this question
Reduce this to a minimal testcase, and I'm certain you'll find your problem. If not, post your minimal, compilable testcase here and we'll help you through it. –  undefined behaviour May 2 '13 at 22:55
FYI this is a 16bit fixed point DSP running uClinux without a memory management unit. All processes and the kernel share a single address space. malloc() exists, but without an MMU to join physically disparate blocks into a contiguous logical region, it can eventually fail from fragmentation. It's common to tell the kernel not to use all the system RAM and to manually allocate larger DSP buffers in the region so reserved. So while there is a Linux aspects, there are also concerns resembling bare-metal microcontroller work. –  Chris Stratton May 3 '13 at 13:19
Do you have a link to the ADC driver source? It's probably a derivation of bfin_sport.c but the details would be important. –  Chris Stratton May 3 '13 at 18:11
While I'm not convinced that it should be necessary, something that could be worth trying would be to declare the pointers as "volatile int16_t *" and similar, and/or use the pointer rather the constant again in the write() call. Additionally, you could try pre-filling the memory with a recognizable value before the read() call, and seeing if (the shifted and selected bits version of) that ends up in your file instead of 0's. –  Chris Stratton May 4 '13 at 0:14
I'm sorry for the delay, and thank you very much for your feedback! I'm trying to get ahold of some more driver-code, will post asap. I'll add a note on the adc in the OP, and will try your suggestion and report back. Thanks again. –  Tausen May 4 '13 at 9:17

1 Answer 1

According to this page, your implementation has malloc, and there are three valid storage types to choose from. Why aren't you using one of those in place of the following gibberish?

buffer = (int16_t *)(0x1000000);
buf16I = (int16_t *)(0x1600000);
buf16Q = (int16_t *)(0x1680000);

That is just one of the many places where your code does some pretty dodgy stuff. It looks like your buffers overlap...

Tell me... Why does buffer need to point to a 16-bit type? Why can't it point to a 32-bit type? Following on from that, why do you need to cast it to point to a 32-bit type? There is no reason, in this code. If you're not doing anything with the 16-bit type, then do the simplest and most sensible thing and work with 32-bit types.

buf16I[i] = buf32[n] << 4; doesn't look well defined at all! If you're going to be shifting left, I suggest using unsigned integer types.

Please explain why you think you need buf16I or buf16Q for this task. I don't think you do. You could extract the buf16I bits in your loop, write them to your output file and then transform it to buf16Q. The less memory your program uses, the better, right? I invision something like this:

#include <unistd.h>
#include <stdio.h>

int main(void) {
    uint32_t poor_identifier_0[0x40000];
    ssize_t poor_identifier_1 = read(STDIN_FILENO, poor_identifier_0, sizeof poor_identifier_0);

    if (poor_identifier_1 != sizeof poor_identifier_0) {
        printf("could not sample data! %zd\n", poor_identifier_1);
        /* goto end; */
        return EXIT_FAILURE;
    printf("Read %zd bytes\n", poor_identifier_1);

    FILE *output = stdout;
    if (outfd == NULL) {
        puts("Could not open file.");

    /* Only 12 LSBs of each 32-bit word is actual data.
     * First 20 bits of nothing, then 12 bits I, then 20 bits
     * nothing, then 12 bits Q, etc...
     * Below, the I and Q parts are scaled with a factor of 16
     * and extracted to buf16I and buf16Q.
     * */

    for (size_t x = 0; x < 0x40000; x++) {
        uint16_t I = poor_identifier_0[x * 2] << 4,
                 Q = poor_identifier_0[x * 2 + 1] << 4;

        /* Write I */
        if (fwrite(&I, 1, sizeof I, output) != 1) {
            printf("wbytes not correct (= %zu)\n", x);

        /* Transform into Q */
        poor_identifier_0[x] = x % 1 ? poor_identifier[x] << 16 | Q : Q;

    /* Write Q */
    size_t poor_identifier_2 = fwrite(poor_identifier_0, 1, sizeof poor_identifier_0 / 4, output);
    if (poor_identifier_2 != sizeof poor_identifier_0 / 4) {
        printf("wbytes not correct (= %zu)\n", poor_identifier_2);

share|improve this answer
The pointers are being initialized to a region of high memory which should have been reserved on the kernel command line. This hardware-aware programming technique is used to deterministically provide a large buffer for a "special" program in situations where runtime memory allocation is unsuitable, for example uClinux where the lack of arbitrary block-by-block physical-to-logical memory mappings makes system-wide memory fragmentation a concern. –  Chris Stratton May 5 '13 at 4:01
@ChrisStratton For the benefit of forming an improved answer for the OP: Which reference are you using? –  undefined behaviour May 5 '13 at 4:36
-1 due to the condescending tone of the answer ("gibberish," "Tell me, ..." and so on). The technical information is good and this would make a good answer if edited into a more courteous tone. –  TypeIA Feb 3 at 21:45

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