vm/mterp/armv5te/binopWide2addr.S - platform/dalvik - Gitiles

 %default {"preinstr":"", "result0":"r0", "result1":"r1", "chkzero":"0"}
     /*
      * Generic 64-bit "/2addr" binary operation.  Provide an "instr" line
      * that specifies an instruction that performs "result = r0-r1 op r2-r3".
      * This could be an ARM instruction or a function call.  (If the result
      * comes back in a register other than r0, you can override "result".)
      *
      * If "chkzero" is set to 1, we perform a divide-by-zero check on
      * vCC (r1).  Useful for integer division and modulus.
      *
      * For: add-long/2addr, sub-long/2addr, div-long/2addr, rem-long/2addr,
      *      and-long/2addr, or-long/2addr, xor-long/2addr, add-double/2addr,
      *      sub-double/2addr, mul-double/2addr, div-double/2addr,
      *      rem-double/2addr
      */
     /* binop/2addr vA, vB */
     mov     r9, rINST, lsr #8           @ r9<- A+
     mov     r1, rINST, lsr #12          @ r1<- B
     and     r9, r9, #15
     add     r1, rFP, r1, lsl #2         @ r1<- &fp[B]
     add     r9, rFP, r9, lsl #2         @ r9<- &fp[A]
     ldmia   r1, {r2-r3}                 @ r2/r3<- vBB/vBB+1
     ldmia   r9, {r0-r1}                 @ r0/r1<- vAA/vAA+1
     .if $chkzero
     orrs    ip, r2, r3                  @ second arg (r2-r3) is zero?
     beq     common_errDivideByZero
     .endif
     FETCH_ADVANCE_INST(1)               @ advance rPC, load rINST

     $preinstr                           @ optional op; may set condition codes
     $instr                              @ result<- op, r0-r3 changed
     GET_INST_OPCODE(ip)                 @ extract opcode from rINST
     stmia   r9, {$result0,$result1}     @ vAA/vAA+1<- $result0/$result1
     GOTO_OPCODE(ip)                     @ jump to next instruction
     /* 12-15 instructions */
	%default {"preinstr":"", "result0":"r0", "result1":"r1", "chkzero":"0"}
	/*
	* Generic 64-bit "/2addr" binary operation. Provide an "instr" line
	* that specifies an instruction that performs "result = r0-r1 op r2-r3".
	* This could be an ARM instruction or a function call. (If the result
	* comes back in a register other than r0, you can override "result".)
	*
	* If "chkzero" is set to 1, we perform a divide-by-zero check on
	* vCC (r1). Useful for integer division and modulus.
	*
	* For: add-long/2addr, sub-long/2addr, div-long/2addr, rem-long/2addr,
	* and-long/2addr, or-long/2addr, xor-long/2addr, add-double/2addr,
	* sub-double/2addr, mul-double/2addr, div-double/2addr,
	* rem-double/2addr
	*/
	/* binop/2addr vA, vB */
	mov r9, rINST, lsr #8 @ r9<- A+
	mov r1, rINST, lsr #12 @ r1<- B
	and r9, r9, #15
	add r1, rFP, r1, lsl #2 @ r1<- &fp[B]
	add r9, rFP, r9, lsl #2 @ r9<- &fp[A]
	ldmia r1, {r2-r3} @ r2/r3<- vBB/vBB+1
	ldmia r9, {r0-r1} @ r0/r1<- vAA/vAA+1
	.if $chkzero
	orrs ip, r2, r3 @ second arg (r2-r3) is zero?
	beq common_errDivideByZero
	.endif
	FETCH_ADVANCE_INST(1) @ advance rPC, load rINST

	$preinstr @ optional op; may set condition codes
	$instr @ result<- op, r0-r3 changed
	GET_INST_OPCODE(ip) @ extract opcode from rINST
	stmia r9, {$result0,$result1} @ vAA/vAA+1<- $result0/$result1
	GOTO_OPCODE(ip) @ jump to next instruction
	/* 12-15 instructions */