lib/i386/divdi3.S - platform/external/compiler-rt - Gitiles

 // This file is dual licensed under the MIT and the University of Illinois Open
 // Source Licenses. See LICENSE.TXT for details.

 #include "../assembly.h"

 // di_int __divdi3(di_int a, di_int b);

 // result = a / b.
 // both inputs and the output are 64-bit signed integers.
 // This will do whatever the underlying hardware is set to do on division by zero.
 // No other exceptions are generated, as the divide cannot overflow.
 //
 // This is targeted at 32-bit x86 *only*, as this can be done directly in hardware
 // on x86_64.  The performance goal is ~40 cycles per divide, which is faster than
 // currently possible via simulation of integer divides on the x87 unit.
 //
 // Stephen Canon, December 2008

 #ifdef __i386__

 .text
 .align 4
 DEFINE_COMPILERRT_FUNCTION(__divdi3)

 /* This is currently implemented by wrapping the unsigned divide up in an absolute
    value, then restoring the correct sign at the end of the computation.  This could
    certainly be improved upon. */

 	pushl		%esi
 	movl	 20(%esp),			%edx	// high word of b
 	movl	 16(%esp),			%eax	// low word of b
 	movl		%edx,			%ecx
 	sarl		$31,			%ecx	// (b < 0) ? -1 : 0
 	xorl		%ecx,			%eax
 	xorl		%ecx,			%edx	// EDX:EAX = (b < 0) ? not(b) : b
 	subl		%ecx,			%eax
 	sbbl		%ecx,			%edx	// EDX:EAX = abs(b)
 	movl		%edx,		 20(%esp)
 	movl		%eax,		 16(%esp)	// store abs(b) back to stack
 	movl		%ecx,			%esi	// set aside sign of b

 	movl	 12(%esp),			%edx	// high word of b
 	movl	  8(%esp),			%eax	// low word of b
 	movl		%edx,			%ecx
 	sarl		$31,			%ecx	// (a < 0) ? -1 : 0
 	xorl		%ecx,			%eax
 	xorl		%ecx,			%edx	// EDX:EAX = (a < 0) ? not(a) : a
 	subl		%ecx,			%eax
 	sbbl		%ecx,			%edx	// EDX:EAX = abs(a)
 	movl		%edx,		 12(%esp)
 	movl		%eax,		  8(%esp)	// store abs(a) back to stack
 	xorl		%ecx,			%esi	// sign of result = (sign of a) ^ (sign of b)

 	pushl		%ebx
 	movl	 24(%esp),			%ebx	// Find the index i of the leading bit in b.
 	bsrl		%ebx,			%ecx	// If the high word of b is zero, jump to
 	jz			9f						// the code to handle that special case [9].

 	/* High word of b is known to be non-zero on this branch */

 	movl	 20(%esp),			%eax	// Construct bhi, containing bits [1+i:32+i] of b

 	shrl		%cl,			%eax	// Practically, this means that bhi is given by:
 	shrl		%eax					//
 	notl		%ecx					//		bhi = (high word of b) << (31 - i) |
 	shll		%cl,			%ebx	//			  (low word of b) >> (1 + i)
 	orl			%eax,			%ebx	//
 	movl	 16(%esp),			%edx	// Load the high and low words of a, and jump
 	movl	 12(%esp),			%eax	// to [1] if the high word is larger than bhi
 	cmpl		%ebx,			%edx	// to avoid overflowing the upcoming divide.
 	jae			1f

 	/* High word of a is greater than or equal to (b >> (1 + i)) on this branch */

 	divl		%ebx					// eax <-- qs, edx <-- r such that ahi:alo = bs*qs + r

 	pushl		%edi
 	notl		%ecx
 	shrl		%eax
 	shrl		%cl,			%eax	// q = qs >> (1 + i)
 	movl		%eax,			%edi
 	mull	 24(%esp)					// q*blo
 	movl	 16(%esp),			%ebx
 	movl	 20(%esp),			%ecx	// ECX:EBX = a
 	subl		%eax,			%ebx
 	sbbl		%edx,			%ecx	// ECX:EBX = a - q*blo
 	movl	 28(%esp),			%eax
 	imull		%edi,			%eax	// q*bhi
 	subl		%eax,			%ecx	// ECX:EBX = a - q*b
 	sbbl		$0,				%edi	// decrement q if remainder is negative
 	xorl		%edx,			%edx
 	movl		%edi,			%eax

 	addl		%esi,			%eax	// Restore correct sign to result
 	adcl		%esi,			%edx
 	xorl		%esi,			%eax
 	xorl		%esi,			%edx
 	popl		%edi					// Restore callee-save registers
 	popl		%ebx
 	popl		%esi
 	retl								// Return


 1:	/* High word of a is greater than or equal to (b >> (1 + i)) on this branch */

 	subl		%ebx,			%edx	// subtract bhi from ahi so that divide will not
 	divl		%ebx					// overflow, and find q and r such that
 										//
 										//		ahi:alo = (1:q)*bhi + r
 										//
 										// Note that q is a number in (31-i).(1+i)
 										// fix point.

 	pushl		%edi
 	notl		%ecx
 	shrl		%eax
 	orl			$0x80000000,	%eax
 	shrl		%cl,			%eax	// q = (1:qs) >> (1 + i)
 	movl		%eax,			%edi
 	mull	 24(%esp)					// q*blo
 	movl	 16(%esp),			%ebx
 	movl	 20(%esp),			%ecx	// ECX:EBX = a
 	subl		%eax,			%ebx
 	sbbl		%edx,			%ecx	// ECX:EBX = a - q*blo
 	movl	 28(%esp),			%eax
 	imull		%edi,			%eax	// q*bhi
 	subl		%eax,			%ecx	// ECX:EBX = a - q*b
 	sbbl		$0,				%edi	// decrement q if remainder is negative
 	xorl		%edx,			%edx
 	movl		%edi,			%eax

 	addl		%esi,			%eax	// Restore correct sign to result
 	adcl		%esi,			%edx
 	xorl		%esi,			%eax
 	xorl		%esi,			%edx
 	popl		%edi					// Restore callee-save registers
 	popl		%ebx
 	popl		%esi
 	retl								// Return


 9:	/* High word of b is zero on this branch */

 	movl	 16(%esp),			%eax	// Find qhi and rhi such that
 	movl	 20(%esp),			%ecx	//
 	xorl		%edx,			%edx	//		ahi = qhi*b + rhi	with	0 ≤ rhi < b
 	divl		%ecx					//
 	movl		%eax,			%ebx	//
 	movl	 12(%esp),			%eax	// Find qlo such that
 	divl		%ecx					//
 	movl		%ebx,			%edx	//		rhi:alo = qlo*b + rlo  with 0 ≤ rlo < b

 	addl		%esi,			%eax	// Restore correct sign to result
 	adcl		%esi,			%edx
 	xorl		%esi,			%eax
 	xorl		%esi,			%edx
 	popl		%ebx					// Restore callee-save registers
 	popl		%esi
 	retl								// Return

 #endif // __i386__
	// This file is dual licensed under the MIT and the University of Illinois Open
	// Source Licenses. See LICENSE.TXT for details.

	#include "../assembly.h"

	// di_int __divdi3(di_int a, di_int b);

	// result = a / b.
	// both inputs and the output are 64-bit signed integers.
	// This will do whatever the underlying hardware is set to do on division by zero.
	// No other exceptions are generated, as the divide cannot overflow.
	//
	// This is targeted at 32-bit x86 only, as this can be done directly in hardware
	// on x86_64. The performance goal is ~40 cycles per divide, which is faster than
	// currently possible via simulation of integer divides on the x87 unit.
	//
	// Stephen Canon, December 2008

	#ifdef __i386__

	.text
	.align 4
	DEFINE_COMPILERRT_FUNCTION(__divdi3)

	/* This is currently implemented by wrapping the unsigned divide up in an absolute
	value, then restoring the correct sign at the end of the computation. This could
	certainly be improved upon. */

	pushl %esi
	movl 20(%esp), %edx // high word of b
	movl 16(%esp), %eax // low word of b
	movl %edx, %ecx
	sarl $31, %ecx // (b < 0) ? -1 : 0
	xorl %ecx, %eax
	xorl %ecx, %edx // EDX:EAX = (b < 0) ? not(b) : b
	subl %ecx, %eax
	sbbl %ecx, %edx // EDX:EAX = abs(b)
	movl %edx, 20(%esp)
	movl %eax, 16(%esp) // store abs(b) back to stack
	movl %ecx, %esi // set aside sign of b

	movl 12(%esp), %edx // high word of b
	movl 8(%esp), %eax // low word of b
	movl %edx, %ecx
	sarl $31, %ecx // (a < 0) ? -1 : 0
	xorl %ecx, %eax
	xorl %ecx, %edx // EDX:EAX = (a < 0) ? not(a) : a
	subl %ecx, %eax
	sbbl %ecx, %edx // EDX:EAX = abs(a)
	movl %edx, 12(%esp)
	movl %eax, 8(%esp) // store abs(a) back to stack
	xorl %ecx, %esi // sign of result = (sign of a) ^ (sign of b)

	pushl %ebx
	movl 24(%esp), %ebx // Find the index i of the leading bit in b.
	bsrl %ebx, %ecx // If the high word of b is zero, jump to
	jz 9f // the code to handle that special case [9].

	/* High word of b is known to be non-zero on this branch */

	movl 20(%esp), %eax // Construct bhi, containing bits [1+i:32+i] of b

	shrl %cl, %eax // Practically, this means that bhi is given by:
	shrl %eax //
	notl %ecx // bhi = (high word of b) << (31 - i) \|
	shll %cl, %ebx // (low word of b) >> (1 + i)
	orl %eax, %ebx //
	movl 16(%esp), %edx // Load the high and low words of a, and jump
	movl 12(%esp), %eax // to [1] if the high word is larger than bhi
	cmpl %ebx, %edx // to avoid overflowing the upcoming divide.
	jae 1f

	/* High word of a is greater than or equal to (b >> (1 + i)) on this branch */

	divl %ebx // eax <-- qs, edx <-- r such that ahi:alo = bs*qs + r

	pushl %edi
	notl %ecx
	shrl %eax
	shrl %cl, %eax // q = qs >> (1 + i)
	movl %eax, %edi
	mull 24(%esp) // q*blo
	movl 16(%esp), %ebx
	movl 20(%esp), %ecx // ECX:EBX = a
	subl %eax, %ebx
	sbbl %edx, %ecx // ECX:EBX = a - q*blo
	movl 28(%esp), %eax
	imull %edi, %eax // q*bhi
	subl %eax, %ecx // ECX:EBX = a - q*b
	sbbl $0, %edi // decrement q if remainder is negative
	xorl %edx, %edx
	movl %edi, %eax

	addl %esi, %eax // Restore correct sign to result
	adcl %esi, %edx
	xorl %esi, %eax
	xorl %esi, %edx
	popl %edi // Restore callee-save registers
	popl %ebx
	popl %esi
	retl // Return


	1: /* High word of a is greater than or equal to (b >> (1 + i)) on this branch */

	subl %ebx, %edx // subtract bhi from ahi so that divide will not
	divl %ebx // overflow, and find q and r such that
	//
	// ahi:alo = (1:q)*bhi + r
	//
	// Note that q is a number in (31-i).(1+i)
	// fix point.

	pushl %edi
	notl %ecx
	shrl %eax
	orl $0x80000000, %eax
	shrl %cl, %eax // q = (1:qs) >> (1 + i)
	movl %eax, %edi
	mull 24(%esp) // q*blo
	movl 16(%esp), %ebx
	movl 20(%esp), %ecx // ECX:EBX = a
	subl %eax, %ebx
	sbbl %edx, %ecx // ECX:EBX = a - q*blo
	movl 28(%esp), %eax
	imull %edi, %eax // q*bhi
	subl %eax, %ecx // ECX:EBX = a - q*b
	sbbl $0, %edi // decrement q if remainder is negative
	xorl %edx, %edx
	movl %edi, %eax

	addl %esi, %eax // Restore correct sign to result
	adcl %esi, %edx
	xorl %esi, %eax
	xorl %esi, %edx
	popl %edi // Restore callee-save registers
	popl %ebx
	popl %esi
	retl // Return


	9: /* High word of b is zero on this branch */

	movl 16(%esp), %eax // Find qhi and rhi such that
	movl 20(%esp), %ecx //
	xorl %edx, %edx // ahi = qhi*b + rhi with 0 ≤ rhi < b
	divl %ecx //
	movl %eax, %ebx //
	movl 12(%esp), %eax // Find qlo such that
	divl %ecx //
	movl %ebx, %edx // rhi:alo = qlo*b + rlo with 0 ≤ rlo < b

	addl %esi, %eax // Restore correct sign to result
	adcl %esi, %edx
	xorl %esi, %eax
	xorl %esi, %edx
	popl %ebx // Restore callee-save registers
	popl %esi
	retl // Return

	#endif // __i386__