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glMemoryBarrier

Name

glMemoryBarrier — defines a barrier ordering memory transactions

C Specification

void glMemoryBarrier( GLbitfield barriers);
void glMemoryBarrierByRegion( GLbitfield barriers);

Parameters

barriers

Specifies the barriers to insert. Must be a bitwise combination of GL_VERTEX_ATTRIB_ARRAY_BARRIER_BIT, GL_ELEMENT_ARRAY_BARRIER_BIT, GL_UNIFORM_BARRIER_BIT, GL_TEXTURE_FETCH_BARRIER_BIT, GL_SHADER_IMAGE_ACCESS_BARRIER_BIT, GL_COMMAND_BARRIER_BIT, GL_PIXEL_BUFFER_BARRIER_BIT, GL_TEXTURE_UPDATE_BARRIER_BIT, GL_BUFFER_UPDATE_BARRIER_BIT, GL_FRAMEBUFFER_BARRIER_BIT, GL_TRANSFORM_FEEDBACK_BARRIER_BIT, GL_ATOMIC_COUNTER_BARRIER_BIT, or GL_SHADER_STORAGE_BARRIER_BIT. If the special value GL_ALL_BARRIER_BITS is specified, all supported barriers will be inserted.

Description

glMemoryBarrier defines a barrier ordering the memory transactions issued prior to the command relative to those issued after the barrier. For the purposes of this ordering, memory transactions performed by shaders are considered to be issued by the rendering command that triggered the execution of the shader. barriers is a bitfield indicating the set of operations that are synchronized with shader stores; the bits used in barriers are as follows:

GL_VERTEX_ATTRIB_ARRAY_BARRIER_BIT

If set, vertex data sourced from buffer objects after the barrier will reflect data written by shaders prior to the barrier. The set of buffer objects affected by this bit is derived from the buffer object bindings used for generic vertex attributes derived from the GL_VERTEX_ATTRIB_ARRAY_BUFFER bindings.

GL_ELEMENT_ARRAY_BARRIER_BIT

If set, vertex array indices sourced from buffer objects after the barrier will reflect data written by shaders prior to the barrier. The buffer objects affected by this bit are derived from the GL_ELEMENT_ARRAY_BUFFER binding.

GL_UNIFORM_BARRIER_BIT

Shader uniforms sourced from buffer objects after the barrier will reflect data written by shaders prior to the barrier.

GL_TEXTURE_FETCH_BARRIER_BIT

Texture fetches from shaders after the barrier will reflect data written by shaders prior to the barrier.

GL_SHADER_IMAGE_ACCESS_BARRIER_BIT

Memory accesses using shader image load, store, and atomic built-in functions issued after the barrier will reflect data written by shaders prior to the barrier. Additionally, image stores and atomics issued after the barrier will not execute until all memory accesses (e.g., loads, stores, texture fetches, vertex fetches) initiated prior to the barrier complete.

GL_COMMAND_BARRIER_BIT

Command data sourced from buffer objects by Draw*Indirect commands after the barrier will reflect data written by shaders prior to the barrier. The buffer objects affected by this bit are derived from the GL_DRAW_INDIRECT_BUFFER binding.

GL_PIXEL_BUFFER_BARRIER_BIT

Reads and writes of buffer objects via the GL_PIXEL_PACK_BUFFER and GL_PIXEL_UNPACK_BUFFER bindings (via glReadPixels, glTexSubImage, etc.) after the barrier will reflect data written by shaders prior to the barrier. Additionally, buffer object writes issued after the barrier will wait on the completion of all shader writes initiated prior to the barrier.

GL_TEXTURE_UPDATE_BARRIER_BIT

Writes to a texture via glTex(Sub)Image*, glCopyTex(Sub)Image*, glCompressedTex(Sub)Image* after the barrier will reflect data written by shaders prior to the barrier. Additionally, texture writes from these commands issued after the barrier will not execute until all shader writes initiated prior to the barrier complete.

GL_BUFFER_UPDATE_BARRIER_BIT

Reads or writes via glBufferSubData, glCopyBufferSubData, or to buffer object memory mapped by glMapBufferRange after the barrier will reflect data written by shaders prior to the barrier. Additionally, writes via these commands issued after the barrier will wait on the completion of any shader writes to the same memory initiated prior to the barrier.

GL_FRAMEBUFFER_BARRIER_BIT

Reads and writes via framebuffer object attachments after the barrier will reflect data written by shaders prior to the barrier. Additionally, framebuffer writes issued after the barrier will wait on the completion of all shader writes issued prior to the barrier.

GL_TRANSFORM_FEEDBACK_BARRIER_BIT

Writes via transform feedback bindings after the barrier will reflect data written by shaders prior to the barrier. Additionally, transform feedback writes issued after the barrier will wait on the completion of all shader writes issued prior to the barrier.

GL_ATOMIC_COUNTER_BARRIER_BIT

Accesses to atomic counters after the barrier will reflect writes prior to the barrier.

GL_SHADER_STORAGE_BARRIER_BIT

Accesses to shader storage blocks after the barrier will reflect writes prior to the barrier.

If barriers is GL_ALL_BARRIER_BITS, shader memory accesses will be synchronized relative to all the operations described above.

Implementations may cache buffer object and texture image memory that could be written by shaders in multiple caches; for example, there may be separate caches for texture, vertex fetching, and one or more caches for shader memory accesses. Implementations are not required to keep these caches coherent with shader memory writes. Stores issued by one invocation may not be immediately observable by other pipeline stages or other shader invocations because the value stored may remain in a cache local to the processor executing the store, or because data overwritten by the store is still in a cache elsewhere in the system. When glMemoryBarrier is called, the GL flushes and/or invalidates any caches relevant to the operations specified by the barriers parameter to ensure consistent ordering of operations across the barrier.

To allow for independent shader invocations to communicate by reads and writes to a common memory address, image variables in the OpenGL ES Shading Language may be declared as "coherent". Buffer object or texture image memory accessed through such variables may be cached only if caches are automatically updated due to stores issued by any other shader invocation. If the same address is accessed using both coherent and non-coherent variables, the accesses using variables declared as coherent will observe the results stored using coherent variables in other invocations. Using variables declared as "coherent" guarantees only that the results of stores will be immediately visible to shader invocations using similarly-declared variables; calling glMemoryBarrier is required to ensure that the stores are visible to other operations.

The following guidelines may be helpful in choosing when to use coherent memory accesses and when to use barriers.

  • Data that are read-only or constant may be accessed without using coherent variables or calling MemoryBarrier(). Updates to the read-only data via API calls such as BufferSubData will invalidate shader caches implicitly as required.

  • Data that are shared between shader invocations at a fine granularity (e.g., written by one invocation, consumed by another invocation) should use coherent variables to read and write the shared data.

  • Data written by one shader invocation and consumed by other shader invocations launched as a result of its execution ("dependent invocations") should use coherent variables in the producing shader invocation and call memoryBarrier() after the last write. The consuming shader invocation should also use coherent variables.

  • Data written to image variables in one rendering pass and read by the shader in a later pass need not use coherent variables or memoryBarrier(). Calling MemoryBarrier() with the SHADER_IMAGE_ACCESS_BARRIER_BIT set in barriers between passes is necessary.

  • Data written by the shader in one rendering pass and read by another mechanism (e.g., vertex or index buffer pulling) in a later pass need not use coherent variables or memoryBarrier(). Calling glMemoryBarrier with the appropriate bits set in barriers between passes is necessary.

glMemoryBarrierByRegion behaves as per glMemoryBarrier with two differences:

  • The region under consideration is narrowed so that only reads/writes of prior fragment shaders that are invoked for a smaller region of the framebuffer will be completed/reflected prior to subsequent reads/write of following fragment shaders. The size of the region is implementation dependent and may be as small as one framebuffer pixel.

  • The barrier only applies to memory transactions that may be read by or written by a fragment shader. Therefore only the barrier bits GL_ATOMIC_COUNTER_BARRIER_BIT, GL_FRAMEBUFFER_BARRIER_BIT, GL_SHADER_IMAGE_ACCESS_BARRIER_BIT, GL_SHADER_STORAGE_BARRIER_BIT, GL_TEXTURE_FETCH_BARRIER_BIT, or GL_UNIFORM_BARRIER_BIT are supported.

When barriers is GL_ALL_BARRIER_BITS, shader memory accesses will be synchronized relative to all the operations described immediately above, but not the wider list of operations described by glMemoryBarrier. This implies that reads/writes for scatter/gather-like algorithms may or may not be completed/reflected after a glMemoryBarrierByRegion command. However, for uses such as deferred shading, where a linked list of visible surfaces with the head at a framebuffer address may be constructed, and the entirety of the list is only dependent on previous executions at that framebuffer address, glMemoryBarrierByRegion may be significantly more efficient than glMemoryBarrier.

Errors

GL_INVALID_VALUE is generated if barriers contains any unsupported bits, or is not the special value GL_ALL_BARRIER_BITS.

API Version Support

OpenGL ES API Version
Function Name 2.0 3.0 3.1
glMemoryBarrier - -
glMemoryBarrierByRegion - -
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