lib/Target/X86/README-X86-64.txt - external/github.com/llvm-mirror/llvm - Git at Google

 //===- README_X86_64.txt - Notes for X86-64 code gen ----------------------===//

 Implement different PIC models? Right now we only support Mac OS X with small
 PIC code model.

 //===---------------------------------------------------------------------===//

 Make use of "Red Zone".

 //===---------------------------------------------------------------------===//

 Implement __int128 and long double support.

 //===---------------------------------------------------------------------===//

 For this:

 extern void xx(void);
 void bar(void) {
   xx();
 }

 gcc compiles to:

 .globl _bar
 _bar:
 	jmp	_xx

 We need to do the tailcall optimization as well.

 //===---------------------------------------------------------------------===//

 AMD64 Optimization Manual 8.2 has some nice information about optimizing integer
 multiplication by a constant. How much of it applies to Intel's X86-64
 implementation? There are definite trade-offs to consider: latency vs. register
 pressure vs. code size.

 //===---------------------------------------------------------------------===//

 Are we better off using branches instead of cmove to implement FP to
 unsigned i64?

 _conv:
 	ucomiss	LC0(%rip), %xmm0
 	cvttss2siq	%xmm0, %rdx
 	jb	L3
 	subss	LC0(%rip), %xmm0
 	movabsq	$-9223372036854775808, %rax
 	cvttss2siq	%xmm0, %rdx
 	xorq	%rax, %rdx
 L3:
 	movq	%rdx, %rax
 	ret

 instead of

 _conv:
 	movss LCPI1_0(%rip), %xmm1
 	cvttss2siq %xmm0, %rcx
 	movaps %xmm0, %xmm2
 	subss %xmm1, %xmm2
 	cvttss2siq %xmm2, %rax
 	movabsq $-9223372036854775808, %rdx
 	xorq %rdx, %rax
 	ucomiss %xmm1, %xmm0
 	cmovb %rcx, %rax
 	ret

 Seems like the jb branch has high likelyhood of being taken. It would have
 saved a few instructions.

 //===---------------------------------------------------------------------===//

 Poor codegen:

 int X[2];
 int b;
 void test(void) {
   memset(X, b, 2*sizeof(X[0]));
 }

 llc:
 	movq _b@GOTPCREL(%rip), %rax
 	movzbq (%rax), %rax
 	movq %rax, %rcx
 	shlq $8, %rcx
 	orq %rax, %rcx
 	movq %rcx, %rax
 	shlq $16, %rax
 	orq %rcx, %rax
 	movq %rax, %rcx
 	shlq $32, %rcx
 	movq _X@GOTPCREL(%rip), %rdx
 	orq %rax, %rcx
 	movq %rcx, (%rdx)
 	ret

 gcc:
 	movq	_b@GOTPCREL(%rip), %rax
 	movabsq	$72340172838076673, %rdx
 	movzbq	(%rax), %rax
 	imulq	%rdx, %rax
 	movq	_X@GOTPCREL(%rip), %rdx
 	movq	%rax, (%rdx)
 	ret

 //===---------------------------------------------------------------------===//

 Vararg function prologue can be further optimized. Currently all XMM registers
 are stored into register save area. Most of them can be eliminated since the
 upper bound of the number of XMM registers used are passed in %al. gcc produces
 something like the following:

 	movzbl	%al, %edx
 	leaq	0(,%rdx,4), %rax
 	leaq	4+L2(%rip), %rdx
 	leaq	239(%rsp), %rax
        	jmp	*%rdx
 	movaps	%xmm7, -15(%rax)
 	movaps	%xmm6, -31(%rax)
 	movaps	%xmm5, -47(%rax)
 	movaps	%xmm4, -63(%rax)
 	movaps	%xmm3, -79(%rax)
 	movaps	%xmm2, -95(%rax)
 	movaps	%xmm1, -111(%rax)
 	movaps	%xmm0, -127(%rax)
 L2:

 It jumps over the movaps that do not need to be stored. Hard to see this being
 significant as it added 5 instruciton (including a indirect branch) to avoid
 executing 0 to 8 stores in the function prologue.

 Perhaps we can optimize for the common case where no XMM registers are used for
 parameter passing. i.e. is %al == 0 jump over all stores. Or in the case of a
 leaf function where we can determine that no XMM input parameter is need, avoid
 emitting the stores at all.

 //===---------------------------------------------------------------------===//

 AMD64 has a complex calling convention for aggregate passing by value:

 1. If the size of an object is larger than two eightbytes, or in C++, is a non-
    POD structure or union type, or contains unaligned fields, it has class
    MEMORY.
 2. Both eightbytes get initialized to class NO_CLASS.
 3. Each field of an object is classified recursively so that always two fields
    are considered. The resulting class is calculated according to the classes
    of the fields in the eightbyte:
    (a) If both classes are equal, this is the resulting class.
    (b) If one of the classes is NO_CLASS, the resulting class is the other
        class.
    (c) If one of the classes is MEMORY, the result is the MEMORY class.
    (d) If one of the classes is INTEGER, the result is the INTEGER.
    (e) If one of the classes is X87, X87UP, COMPLEX_X87 class, MEMORY is used as
       class.
    (f) Otherwise class SSE is used.
 4. Then a post merger cleanup is done:
    (a) If one of the classes is MEMORY, the whole argument is passed in memory.
    (b) If SSEUP is not preceeded by SSE, it is converted to SSE.

 Currently llvm frontend does not handle this correctly.

 Problem 1:
     typedef struct { int i; double d; } QuadWordS;
 It is currently passed in two i64 integer registers. However, gcc compiled
 callee expects the second element 'd' to be passed in XMM0.

 Problem 2:
     typedef struct { int32_t i; float j; double d; } QuadWordS;
 The size of the first two fields == i64 so they will be combined and passed in
 a integer register RDI. The third field is still passed in XMM0.

 Problem 3:
     typedef struct { int64_t i; int8_t j; int64_t d; } S;
     void test(S s)
 The size of this aggregate is greater than two i64 so it should be passed in
 memory. Currently llvm breaks this down and passed it in three integer
 registers.

 Problem 4:
 Taking problem 3 one step ahead where a function expects a aggregate value
 in memory followed by more parameter(s) passed in register(s).
     void test(S s, int b)

 LLVM IR does not allow parameter passing by aggregates, therefore it must break
 the aggregates value (in problem 3 and 4) into a number of scalar values:
     void %test(long %s.i, byte %s.j, long %s.d);

 However, if the backend were to lower this code literally it would pass the 3
 values in integer registers. To force it be passed in memory, the frontend
 should change the function signiture to:
     void %test(long %undef1, long %undef2, long %undef3, long %undef4,
                long %undef5, long %undef6,
                long %s.i, byte %s.j, long %s.d);
 And the callee would look something like this:
     call void %test( undef, undef, undef, undef, undef, undef,
                      %tmp.s.i, %tmp.s.j, %tmp.s.d );
 The first 6 undef parameters would exhaust the 6 integer registers used for
 parameter passing. The following three integer values would then be forced into
 memory.

 For problem 4, the parameter 'd' would be moved to the front of the parameter
 list so it will be passed in register:
     void %test(int %d,
                long %undef1, long %undef2, long %undef3, long %undef4,
                long %undef5, long %undef6,
                long %s.i, byte %s.j, long %s.d);

 //===---------------------------------------------------------------------===//

 Right now the asm printer assumes GlobalAddress are accessed via RIP relative
 addressing. Therefore, it is not possible to generate this:
         movabsq $__ZTV10polynomialIdE+16, %rax

 That is ok for now since we currently only support small model. So the above
 is selected as
         leaq __ZTV10polynomialIdE+16(%rip), %rax

 This is probably slightly slower but is much shorter than movabsq. However, if
 we were to support medium or larger code models, we need to use the movabs
 instruction. We should probably introduce something like AbsoluteAddress to
 distinguish it from GlobalAddress so the asm printer and JIT code emitter can
 do the right thing.

 //===---------------------------------------------------------------------===//

 It's not possible to reference AH, BH, CH, and DH registers in an instruction
 requiring REX prefix. However, divb and mulb both produce results in AH. If isel
 emits a CopyFromReg which gets turned into a movb and that can be allocated a
 r8b - r15b.

 To get around this, isel emits a CopyFromReg from AX and then right shift it
 down by 8 and truncate it. It's not pretty but it works. We need some register
 allocation magic to make the hack go away (e.g. putting additional constraints
 on the result of the movb).
	//===- README_X86_64.txt - Notes for X86-64 code gen ----------------------===//

	Implement different PIC models? Right now we only support Mac OS X with small
	PIC code model.

	//===---------------------------------------------------------------------===//

	Make use of "Red Zone".

	//===---------------------------------------------------------------------===//

	Implement __int128 and long double support.

	//===---------------------------------------------------------------------===//

	For this:

	extern void xx(void);
	void bar(void) {
	xx();
	}

	gcc compiles to:

	.globl _bar
	_bar:
	jmp _xx

	We need to do the tailcall optimization as well.

	//===---------------------------------------------------------------------===//

	AMD64 Optimization Manual 8.2 has some nice information about optimizing integer
	multiplication by a constant. How much of it applies to Intel's X86-64
	implementation? There are definite trade-offs to consider: latency vs. register
	pressure vs. code size.

	//===---------------------------------------------------------------------===//

	Are we better off using branches instead of cmove to implement FP to
	unsigned i64?

	_conv:
	ucomiss LC0(%rip), %xmm0
	cvttss2siq %xmm0, %rdx
	jb L3
	subss LC0(%rip), %xmm0
	movabsq $-9223372036854775808, %rax
	cvttss2siq %xmm0, %rdx
	xorq %rax, %rdx
	L3:
	movq %rdx, %rax
	ret

	instead of

	_conv:
	movss LCPI1_0(%rip), %xmm1
	cvttss2siq %xmm0, %rcx
	movaps %xmm0, %xmm2
	subss %xmm1, %xmm2
	cvttss2siq %xmm2, %rax
	movabsq $-9223372036854775808, %rdx
	xorq %rdx, %rax
	ucomiss %xmm1, %xmm0
	cmovb %rcx, %rax
	ret

	Seems like the jb branch has high likelyhood of being taken. It would have
	saved a few instructions.

	//===---------------------------------------------------------------------===//

	Poor codegen:

	int X[2];
	int b;
	void test(void) {
	memset(X, b, 2*sizeof(X[0]));
	}

	llc:
	movq _b@GOTPCREL(%rip), %rax
	movzbq (%rax), %rax
	movq %rax, %rcx
	shlq $8, %rcx
	orq %rax, %rcx
	movq %rcx, %rax
	shlq $16, %rax
	orq %rcx, %rax
	movq %rax, %rcx
	shlq $32, %rcx
	movq _X@GOTPCREL(%rip), %rdx
	orq %rax, %rcx
	movq %rcx, (%rdx)
	ret

	gcc:
	movq _b@GOTPCREL(%rip), %rax
	movabsq $72340172838076673, %rdx
	movzbq (%rax), %rax
	imulq %rdx, %rax
	movq _X@GOTPCREL(%rip), %rdx
	movq %rax, (%rdx)
	ret

	//===---------------------------------------------------------------------===//

	Vararg function prologue can be further optimized. Currently all XMM registers
	are stored into register save area. Most of them can be eliminated since the
	upper bound of the number of XMM registers used are passed in %al. gcc produces
	something like the following:

	movzbl %al, %edx
	leaq 0(,%rdx,4), %rax
	leaq 4+L2(%rip), %rdx
	leaq 239(%rsp), %rax
	jmp *%rdx
	movaps %xmm7, -15(%rax)
	movaps %xmm6, -31(%rax)
	movaps %xmm5, -47(%rax)
	movaps %xmm4, -63(%rax)
	movaps %xmm3, -79(%rax)
	movaps %xmm2, -95(%rax)
	movaps %xmm1, -111(%rax)
	movaps %xmm0, -127(%rax)
	L2:

	It jumps over the movaps that do not need to be stored. Hard to see this being
	significant as it added 5 instruciton (including a indirect branch) to avoid
	executing 0 to 8 stores in the function prologue.

	Perhaps we can optimize for the common case where no XMM registers are used for
	parameter passing. i.e. is %al == 0 jump over all stores. Or in the case of a
	leaf function where we can determine that no XMM input parameter is need, avoid
	emitting the stores at all.

	//===---------------------------------------------------------------------===//

	AMD64 has a complex calling convention for aggregate passing by value:

	1. If the size of an object is larger than two eightbytes, or in C++, is a non-
	POD structure or union type, or contains unaligned fields, it has class
	MEMORY.
	2. Both eightbytes get initialized to class NO_CLASS.
	3. Each field of an object is classified recursively so that always two fields
	are considered. The resulting class is calculated according to the classes
	of the fields in the eightbyte:
	(a) If both classes are equal, this is the resulting class.
	(b) If one of the classes is NO_CLASS, the resulting class is the other
	class.
	(c) If one of the classes is MEMORY, the result is the MEMORY class.
	(d) If one of the classes is INTEGER, the result is the INTEGER.
	(e) If one of the classes is X87, X87UP, COMPLEX_X87 class, MEMORY is used as
	class.
	(f) Otherwise class SSE is used.
	4. Then a post merger cleanup is done:
	(a) If one of the classes is MEMORY, the whole argument is passed in memory.
	(b) If SSEUP is not preceeded by SSE, it is converted to SSE.

	Currently llvm frontend does not handle this correctly.

	Problem 1:
	typedef struct { int i; double d; } QuadWordS;
	It is currently passed in two i64 integer registers. However, gcc compiled
	callee expects the second element 'd' to be passed in XMM0.

	Problem 2:
	typedef struct { int32_t i; float j; double d; } QuadWordS;
	The size of the first two fields == i64 so they will be combined and passed in
	a integer register RDI. The third field is still passed in XMM0.

	Problem 3:
	typedef struct { int64_t i; int8_t j; int64_t d; } S;
	void test(S s)
	The size of this aggregate is greater than two i64 so it should be passed in
	memory. Currently llvm breaks this down and passed it in three integer
	registers.

	Problem 4:
	Taking problem 3 one step ahead where a function expects a aggregate value
	in memory followed by more parameter(s) passed in register(s).
	void test(S s, int b)

	LLVM IR does not allow parameter passing by aggregates, therefore it must break
	the aggregates value (in problem 3 and 4) into a number of scalar values:
	void %test(long %s.i, byte %s.j, long %s.d);

	However, if the backend were to lower this code literally it would pass the 3
	values in integer registers. To force it be passed in memory, the frontend
	should change the function signiture to:
	void %test(long %undef1, long %undef2, long %undef3, long %undef4,
	long %undef5, long %undef6,
	long %s.i, byte %s.j, long %s.d);
	And the callee would look something like this:
	call void %test( undef, undef, undef, undef, undef, undef,
	%tmp.s.i, %tmp.s.j, %tmp.s.d );
	The first 6 undef parameters would exhaust the 6 integer registers used for
	parameter passing. The following three integer values would then be forced into
	memory.

	For problem 4, the parameter 'd' would be moved to the front of the parameter
	list so it will be passed in register:
	void %test(int %d,
	long %undef1, long %undef2, long %undef3, long %undef4,
	long %undef5, long %undef6,
	long %s.i, byte %s.j, long %s.d);

	//===---------------------------------------------------------------------===//

	Right now the asm printer assumes GlobalAddress are accessed via RIP relative
	addressing. Therefore, it is not possible to generate this:
	movabsq $__ZTV10polynomialIdE+16, %rax

	That is ok for now since we currently only support small model. So the above
	is selected as
	leaq __ZTV10polynomialIdE+16(%rip), %rax

	This is probably slightly slower but is much shorter than movabsq. However, if
	we were to support medium or larger code models, we need to use the movabs
	instruction. We should probably introduce something like AbsoluteAddress to
	distinguish it from GlobalAddress so the asm printer and JIT code emitter can
	do the right thing.

	//===---------------------------------------------------------------------===//

	It's not possible to reference AH, BH, CH, and DH registers in an instruction
	requiring REX prefix. However, divb and mulb both produce results in AH. If isel
	emits a CopyFromReg which gets turned into a movb and that can be allocated a
	r8b - r15b.

	To get around this, isel emits a CopyFromReg from AX and then right shift it
	down by 8 and truncate it. It's not pretty but it works. We need some register
	allocation magic to make the hack go away (e.g. putting additional constraints
	on the result of the movb).