Difference between revisions of "LDC-specific language changes"

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Besides the [http://dlang.org/version.html#PredefinedVersions predefined versions] from the D spec (in particular, of course, <tt>LDC</tt>), LDC conditionally defines a few more version identifiers for backwards compatibility reasons: <tt>LLVM</tt>, <tt>LLVM64</tt>, <tt>Thumb</tt>, <tt>mingw32</tt>, <tt>darwin</tt>, <tt>solaris</tt>. Please migrate your code to the official identifiers; the old ones might go away soon.
 
Besides the [http://dlang.org/version.html#PredefinedVersions predefined versions] from the D spec (in particular, of course, <tt>LDC</tt>), LDC conditionally defines a few more version identifiers for backwards compatibility reasons: <tt>LLVM</tt>, <tt>LLVM64</tt>, <tt>Thumb</tt>, <tt>mingw32</tt>, <tt>darwin</tt>, <tt>solaris</tt>. Please migrate your code to the official identifiers; the old ones might go away soon.
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 +
== Attributes ==
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 +
LDC provides a number of extra special attributes (UDAs) that can be applied to functions and variables and that are recognized by LDC for specific compiler behavior.
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The attributes are defined in the <tt>ldc.attributes</tt> module:
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<source lang="d">
 +
import ldc.attributes;
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@(ldc.attributes.section(".mySection")) int global;
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</source>
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 +
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=== @(ldc.attributes.section("section_name")) ===
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 +
<i>Applies to: functions and global variables</i>
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 +
This attribute overrides the default section for functions/variables and allows you to explicitly define the "section_name" into which to place function or variable (variables must be global).
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Example:
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<source lang="d">
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void foo() {/+...+/}
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@(section(".interrupt_vector"))
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void function()[3] table_interrupt_vector = [ &foo,
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                                              &foo,
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                                              &foo ];
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</source>
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 +
  
 
== Pragmas ==
 
== Pragmas ==

Revision as of 14:31, 2 January 2016

LDC tries to conform to the D specification as closely as possible. There are a few deviations, and several small extensions, which are documented here.

Violations of the specification

Some parts of the D specification are hard or impossible to implement with LLVM, they should be listed here.

Inline assembler

Almost everything works, but there are a few open issues. For instance the D spec isn't clear about at all is how asm blocks mixed with normal D code (for example code between two asm blocks) interacts.

Specific issues are:

ret

In short, LLVM inline assembler is not allowed to control program flow outside of the asm blocks, see below for a bit more information.

Gotos into inline assembly

For labels inside inline asm blocks, the D spec says "They can be the target of goto statements.", this is not supported at the moment. Basically, LLVM does not allow jumping in to or out of an asm block. We work around this for jumping out of asm by converting these branches to assignments to a temporary that is then used in a switch statement right after the inline asm block to jump to the final destination. This same workaround could be applied for jumping into inline assembly.

Deviations from the D ABI

The D spec only specifies an ABI for x86 processors on Windows and Linux. On other architectures and platforms LDC is free to do as it pleases, and does. However, on x86 the only parts of the ABI currently implemented is:

  • the callee clears any parameters from the stack
  • floating point values are returned on the x87 FPU stack
  • reversing order of parameters
  • returning delegates and dynamic arrays in EAX/EDX.
  • passing last argument in EAX
  • returning small structs in EAX

Extended inline assembly

LDC supports an LLVM-specific variant of GCC's extended inline assembly expressions. See the inline assembly expressions page for more information.

Versions

Besides the predefined versions from the D spec (in particular, of course, LDC), LDC conditionally defines a few more version identifiers for backwards compatibility reasons: LLVM, LLVM64, Thumb, mingw32, darwin, solaris. Please migrate your code to the official identifiers; the old ones might go away soon.

Attributes

LDC provides a number of extra special attributes (UDAs) that can be applied to functions and variables and that are recognized by LDC for specific compiler behavior. The attributes are defined in the ldc.attributes module:

import ldc.attributes;
@(ldc.attributes.section(".mySection")) int global;


@(ldc.attributes.section("section_name"))

Applies to: functions and global variables

This attribute overrides the default section for functions/variables and allows you to explicitly define the "section_name" into which to place function or variable (variables must be global).

Example:

void foo() {/+...+/}
@(section(".interrupt_vector"))
void function()[3] table_interrupt_vector = [ &foo,
                                              &foo,
                                              &foo ];


Pragmas

LDC provides pragmas to access internal functions and can be used to tweak certain behavior.

LDC_intrinsic

The LDC_intrinsic pragma provides access to LLVM's built-in intrinsic functions. It requires a single string literal parameter with full name of the intrinsic. For example "llvm.sqrt.f32".

  • It can only be used on function declarations or funtion template declarations.
  • Any affected function declarations are not allowed to have bodies.
  • The functions must translate to the same signature as the intrinsic.
  • You may not take the address of intrinsics.

Example:

// provide square root intrinsics
pragma(LDC_intrinsic, "llvm.sqrt.f32")
  float sqrt(float);
pragma(LDC_intrinsic, "llvm.sqrt.f64")
  double sqrt(double);
pragma(LDC_intrinsic, "llvm.sqrt.f80")
  real sqrt(real); // x86 only

Overloaded intrinsics can also be accessed more easily with a templated version instead, currently only one overloaded type is supported.

Example:

// templated atomic swap intrinsic
pragma(LDC_intrinsic, "llvm.atomic.swap.i#.p0i#")
    T llvm_atomic_swap(T)(T* ptr, T val);

The # mark in the name is replaced with the size in bits of the type of the template parameter.

The LDC_intrinsic pragma should not be used in user-code directly, instead, please refer to the ldc.intrinsics module.

LDC_no_typeinfo

You can use this pragma to stop typeinfo from being implicitly generated for a declaration.

Example:

pragma(LDC_no_typeinfo) {
    struct Opaque {}
}

LDC_no_moduleinfo

This pragma disables the generation of the ModuleInfo metadata to register the current module with druntime. Note that this, among other things, leads to any static constructors not being run, and should only be used in very specific circumstances.

Example:

module my_bare_metal_module;
pragma(LDC_no_moduleinfo);

LDC_alloca

This pragma allows you to access the alloca instruction of LLVM directly. It only applies to function declarations and the final LLVM type for that declaration must be: i8* (i32/i64). The size parameter will be truncated to i32 if necessary.

Example:

pragma(LDC_alloca) void* alloca(size_t);

Variadic argument handling intrinsics

Example:

alias void* va_list;

pragma(LDC_va_start) void va_start(T)(va_list ap, ref T);

pragma(LDC_va_arg) T va_arg(T)(va_list ap);

pragma(LDC_va_end) void va_end(va_list args);

pragma(LDC_va_copy) void va_copy(va_list dst, va_list src);

LDC_allow_inline

Use this pragma statement inside a non-naked function using inline asm. This will tell the optimizers that it is safe to inline this function.

Example:

int add(int a, int b) {
    pragma(LDC_allow_inline);
    asm { mov EAX, a; add EAX, b; }
}

LDC_never_inline

Use of this pragma statement will tell the optimizers that this function should never be inlined.

Example:

void* getStackTop() {
    pragma(LDC_never_inline);
    return ldc.intrinsics.llvm_frameaddress(0);
}

LDC_inline_ir

This pragma makes it possible to use llvm assembly language from D. See the LDC inline IR page for more information.

LDC_global_crt_ctor and LDC_global_crt_dtor

If you are doing very low-level stuff then there might be the need to execute code before the D runtime is initialized. With these 2 pragmas it possible to run code as part of the C runtime construction and destruction. A possible application is the initialization of a global mutex as it is done in monitor_.d. If the pragma is specified on a function or static method then an entry is made in the corresponding list. E.g. in monitor_.d:

    extern (C) {
        pragma(LDC_global_crt_ctor, 1024)
        void _STI_monitor_staticctor()
        {
            // ...
        }
    }

The optional priority is used to order the execution of the functions. (For more information see the LLVM documentation on global ctors and global dtors variables.)

This works on Linux without problems. On Windows with MS C Runtime ctors work always but dtors are invoked only if linked against the static C runtime. Dtors on Windows require at least LLVM 3.2.