I'm a CUDA beginner. I have a pixel buffer of unsigned chars in global memory that can and is updated by any and all threads. To avoid weirdness in the pixel values, therefore, I want to perform an atomicExch when a thread attempts to update one. But the programming guide says that this function only works on 32- or 64-bit words, whereas I just want to atomically exchange one 8-bit byte. Is there a way to do this?


  • what is the update? if you want to flip a number to 0 or 1, yuou could use atomicAnd/Or
    – Anycorn
    Commented Mar 27, 2011 at 7:39
  • I'm incrementing the value of a pixel depending on how many objects "reside" in that pixel. So if my increment is 50 for each object, then one object will result in a pixel with RGBA of (50,50,50,50), whereas two objects will have RGBA (100,100,100,100), etc., up to (255,255,255,255) max. This enables me to vary the intensity of a pixel depending on how many objects are "inside" that pixel.
    – Andrew
    Commented Mar 27, 2011 at 18:06
  • I found a hack, BTW. Since a uchar4 takes up the same space as an int (though not guaranteed, it works on my architecture), I just take the address of the uchar4, cast it as an (int*), then use the integer version of atomicExch. I would still be interested whether you could do atomics on only a single byte, tho...
    – Andrew
    Commented Mar 27, 2011 at 18:08

3 Answers 3


I just ran into this problem recently. In theory, atomic operations / optimistic retries are supposed to be faster than locks/mutexes, so the "hack" solutions that use atomic operations on other data types seem better to me than using critical sections.

Here are some implementations based on the threads for how to implement atomicMin for char and atomicAdd for short.

I've tested all of these, and my tests seem to show that they work fine so far.

Version 1 of atomicAdd for char

__device__ static inline char atomicAdd(char* address, char val) {
    // offset, in bytes, of the char* address within the 32-bit address of the space that overlaps it
    size_t long_address_modulo = (size_t) address & 3;
    // the 32-bit address that overlaps the same memory
    auto* base_address = (unsigned int*) ((char*) address - long_address_modulo);
    // A 0x3210 selector in __byte_perm will simply select all four bytes in the first argument in the same order.
    // The "4" signifies the position where the first byte of the second argument will end up in the output.
    unsigned int selectors[] = {0x3214, 0x3240, 0x3410, 0x4210};
    // for selecting bytes within a 32-bit chunk that correspond to the char* address (relative to base_address)
    unsigned int selector = selectors[long_address_modulo];
    unsigned int long_old, long_assumed, long_val, replacement;

    long_old = *base_address;

    do {
        long_assumed = long_old;
        // replace bits in long_old that pertain to the char address with those from val
        long_val = __byte_perm(long_old, 0, long_address_modulo) + val;
        replacement = __byte_perm(long_old, long_val, selector);
        long_old = atomicCAS(base_address, long_assumed, replacement);
    } while (long_old != long_assumed);
    return __byte_perm(long_old, 0, long_address_modulo);

atomicCAS for char

__device__ static inline char atomicCAS(char* address, char expected, char desired) {
    size_t long_address_modulo = (size_t) address & 3;
    auto* base_address = (unsigned int*) ((char*) address - long_address_modulo);
    unsigned int selectors[] = {0x3214, 0x3240, 0x3410, 0x4210};

    unsigned int sel = selectors[long_address_modulo];
    unsigned int long_old, long_assumed, long_val, replacement;
    char old;

    long_val = (unsigned int) desired;
    long_old = *base_address;
    do {
        long_assumed = long_old;
        replacement = __byte_perm(long_old, long_val, sel);
        long_old = atomicCAS(base_address, long_assumed, replacement);
        old = (char) ((long_old >> (long_address_modulo * 8)) & 0x000000ff);
    } while (expected == old && long_assumed != long_old);

    return old;

Version 2 of atomicAdd for char (uses bit shifts instead of __byte_perm and has to handle overflow as a result)

__device__ static inline char atomicAdd2(char* address, char val) {
    size_t long_address_modulo = (size_t) address & 3;
    auto* base_address = (unsigned int*) ((char*) address - long_address_modulo);
    unsigned int long_val = (unsigned int) val << (8 * long_address_modulo);
    unsigned int long_old = atomicAdd(base_address, long_val);

    if (long_address_modulo == 3) {
        // the first 8 bits of long_val represent the char value,
        // hence the first 8 bits of long_old represent its previous value.
        return (char) (long_old >> 24);
    } else {
        // bits that represent the char value within long_val
        unsigned int mask = 0x000000ff << (8 * long_address_modulo);
        unsigned int masked_old = long_old & mask;
        // isolate the bits that represent the char value within long_old, add the long_val to that,
        // then re-isolate by excluding bits that represent the char value
        unsigned int overflow = (masked_old + long_val) & ~mask;
        if (overflow) {
            atomicSub(base_address, overflow);
        return (char) (masked_old >> 8 * long_address_modulo);

For atomicMin, please check this thread.


You might implement a critical section using a mutex variable. So something like



Implementing a critical section in CUDA


The other answer has a bug in its implementation of atomicCAS(). This version works for me:

static inline
atomicCAS( uint8_t * const address,
           uint8_t   const compare,
           uint8_t   const value )
    // Determine where in a byte-aligned 32-bit range our address of 8 bits occurs.
    uint8_t    const     longAddressModulo = reinterpret_cast< size_t >( address ) & 0x3;
    // Determine the base address of the byte-aligned 32-bit range that contains our address of 8 bits.
    uint32_t * const     baseAddress       = reinterpret_cast< uint32_t * >( address - longAddressModulo );
    uint32_t   constexpr byteSelection[]   = { 0x3214, 0x3240, 0x3410, 0x4210 }; // The byte position we work on is '4'.
    uint32_t   const     byteSelector      = byteSelection[ longAddressModulo ];
    uint32_t   const     longCompare       = compare;
    uint32_t   const     longValue         = value;
    uint32_t             longOldValue      = * baseAddress;
    uint32_t             longAssumed;
    uint8_t              oldValue;

        // Select bytes from the old value and new value to construct a 32-bit value to use.
        uint32_t const replacement = __byte_perm( longOldValue, longValue,   byteSelector );
        uint32_t const comparison  = __byte_perm( longOldValue, longCompare, byteSelector );

        longAssumed  = longOldValue;
        // Use 32-bit atomicCAS() to try and set the 8-bits we care about.
        longOldValue = ::atomicCAS( baseAddress, comparison, replacement );
        // Grab the 8-bit portion we care about from the old value at address.
        oldValue     = ( longOldValue >> ( 8 * longAddressModulo )) & 0xFF;
    while ( compare == oldValue and longAssumed != longOldValue ); // Repeat until other three 8-bit values stabilize.

    return oldValue;

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