compiler-rt/lib/builtins/i386/divdi3.S - llvm-project - Git at Google

 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception

 #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
 .balign 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
 END_COMPILERRT_FUNCTION(__divdi3)

 #endif // __i386__

 NO_EXEC_STACK_DIRECTIVE
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception

	#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
	.balign 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
	END_COMPILERRT_FUNCTION(__divdi3)

	#endif // __i386__

	NO_EXEC_STACK_DIRECTIVE