blob: bc7c59dc697b7011ca0a46e9bcd163a2f1a041e4 [file] [log] [blame]
%def fpcmp(suff="d", nanval="pos"):
/*
* Compare two floating-point values. Puts 0, 1, or -1 into the
* destination register based on the results of the comparison.
*
* int compare(x, y) {
* if (x == y) {
* return 0;
* } else if (x < y) {
* return -1;
* } else if (x > y) {
* return 1;
* } else {
* return nanval ? 1 : -1;
* }
* }
*/
/* op vAA, vBB, vCC */
movzbl 3(rPC), %ecx # ecx<- CC
movzbl 2(rPC), %eax # eax<- BB
GET_VREG_XMM${suff} %xmm0, %eax
xor %eax, %eax
ucomis${suff} VREG_ADDRESS(%ecx), %xmm0
jp .L${opcode}_nan_is_${nanval}
je .L${opcode}_finish
jb .L${opcode}_less
.L${opcode}_nan_is_pos:
incl %eax
jmp .L${opcode}_finish
.L${opcode}_nan_is_neg:
.L${opcode}_less:
decl %eax
.L${opcode}_finish:
SET_VREG %eax, rINST
ADVANCE_PC_FETCH_AND_GOTO_NEXT 2
%def fpcvt(instr="", load="", store="", wide="0"):
/*
* Generic 32-bit FP conversion operation.
*/
/* unop vA, vB */
movzbl rINSTbl, %ecx # ecx <- A+
sarl $$4, rINST # rINST <- B
$load VREG_ADDRESS(rINST) # %st0 <- vB
andb $$0xf, %cl # ecx <- A
$instr
$store VREG_ADDRESS(%ecx) # vA <- %st0
.if $wide
CLEAR_WIDE_REF %ecx
.else
CLEAR_REF %ecx
.endif
ADVANCE_PC_FETCH_AND_GOTO_NEXT 1
%def sseBinop(instr="", suff=""):
movzbl 2(rPC), %ecx # ecx <- BB
movzbl 3(rPC), %eax # eax <- CC
GET_VREG_XMM${suff} %xmm0, %ecx # %xmm0 <- 1st src
${instr}${suff} VREG_ADDRESS(%eax), %xmm0
SET_VREG_XMM${suff} %xmm0, rINST # vAA <- %xmm0
pxor %xmm0, %xmm0
movs${suff} %xmm0, VREG_REF_ADDRESS(rINST) # clear ref
ADVANCE_PC_FETCH_AND_GOTO_NEXT 2
%def sseBinop2Addr(instr="", suff=""):
movzx rINSTbl, %ecx # ecx <- A+
andl $$0xf, %ecx # ecx <- A
GET_VREG_XMM${suff} %xmm0, %ecx # %xmm0 <- 1st src
sarl $$4, rINST # rINST<- B
${instr}${suff} VREG_ADDRESS(rINST), %xmm0
SET_VREG_XMM${suff} %xmm0, %ecx # vAA<- %xmm0
pxor %xmm0, %xmm0
movs${suff} %xmm0, VREG_REF_ADDRESS(rINST) # clear ref
ADVANCE_PC_FETCH_AND_GOTO_NEXT 1
%def op_add_double():
% sseBinop(instr="adds", suff="d")
%def op_add_double_2addr():
% sseBinop2Addr(instr="adds", suff="d")
%def op_add_float():
% sseBinop(instr="adds", suff="s")
%def op_add_float_2addr():
% sseBinop2Addr(instr="adds", suff="s")
%def op_cmpg_double():
% fpcmp(suff="d", nanval="pos")
%def op_cmpg_float():
% fpcmp(suff="s", nanval="pos")
%def op_cmpl_double():
% fpcmp(suff="d", nanval="neg")
%def op_cmpl_float():
% fpcmp(suff="s", nanval="neg")
%def op_div_double():
% sseBinop(instr="divs", suff="d")
%def op_div_double_2addr():
% sseBinop2Addr(instr="divs", suff="d")
%def op_div_float():
% sseBinop(instr="divs", suff="s")
%def op_div_float_2addr():
% sseBinop2Addr(instr="divs", suff="s")
%def op_double_to_float():
% fpcvt(load="fldl", store="fstps")
%def op_double_to_int():
% cvtfp_int(srcdouble="1", tgtlong="0")
%def op_double_to_long():
% cvtfp_int(srcdouble="1", tgtlong="1")
%def op_float_to_double():
% fpcvt(load="flds", store="fstpl", wide="1")
%def op_float_to_int():
% cvtfp_int(srcdouble="0", tgtlong="0")
%def op_float_to_long():
% cvtfp_int(srcdouble="0", tgtlong="1")
%def op_int_to_double():
% fpcvt(load="fildl", store="fstpl", wide="1")
%def op_int_to_float():
% fpcvt(load="fildl", store="fstps")
%def op_long_to_double():
% fpcvt(load="fildll", store="fstpl", wide="1")
%def op_long_to_float():
% fpcvt(load="fildll", store="fstps")
%def op_mul_double():
% sseBinop(instr="muls", suff="d")
%def op_mul_double_2addr():
% sseBinop2Addr(instr="muls", suff="d")
%def op_mul_float():
% sseBinop(instr="muls", suff="s")
%def op_mul_float_2addr():
% sseBinop2Addr(instr="muls", suff="s")
%def op_neg_double():
% fpcvt(instr="fchs", load="fldl", store="fstpl", wide="1")
%def op_neg_float():
% fpcvt(instr="fchs", load="flds", store="fstps")
%def op_rem_double():
/* rem_double vAA, vBB, vCC */
movzbl 3(rPC), %ecx # ecx <- BB
movzbl 2(rPC), %eax # eax <- CC
fldl VREG_ADDRESS(%ecx) # %st1 <- fp[vBB]
fldl VREG_ADDRESS(%eax) # %st0 <- fp[vCC]
1:
fprem
fstsw %ax
sahf
jp 1b
fstp %st(1)
fstpl VREG_ADDRESS(rINST) # fp[vAA] <- %st
CLEAR_WIDE_REF rINST
ADVANCE_PC_FETCH_AND_GOTO_NEXT 2
%def op_rem_double_2addr():
/* rem_double/2addr vA, vB */
movzx rINSTbl, %ecx # ecx <- A+
sarl $$4, rINST # rINST <- B
fldl VREG_ADDRESS(rINST) # vB to fp stack
andb $$0xf, %cl # ecx <- A
fldl VREG_ADDRESS(%ecx) # vA to fp stack
1:
fprem
fstsw %ax
sahf
jp 1b
fstp %st(1)
fstpl VREG_ADDRESS(%ecx) # %st to vA
CLEAR_WIDE_REF %ecx
ADVANCE_PC_FETCH_AND_GOTO_NEXT 1
%def op_rem_float():
/* rem_float vAA, vBB, vCC */
movzbl 3(rPC), %ecx # ecx <- BB
movzbl 2(rPC), %eax # eax <- CC
flds VREG_ADDRESS(%ecx) # vBB to fp stack
flds VREG_ADDRESS(%eax) # vCC to fp stack
1:
fprem
fstsw %ax
sahf
jp 1b
fstp %st(1)
fstps VREG_ADDRESS(rINST) # %st to vAA
CLEAR_REF rINST
ADVANCE_PC_FETCH_AND_GOTO_NEXT 2
%def op_rem_float_2addr():
/* rem_float/2addr vA, vB */
movzx rINSTbl, %ecx # ecx <- A+
sarl $$4, rINST # rINST <- B
flds VREG_ADDRESS(rINST) # vB to fp stack
andb $$0xf, %cl # ecx <- A
flds VREG_ADDRESS(%ecx) # vA to fp stack
1:
fprem
fstsw %ax
sahf
jp 1b
fstp %st(1)
fstps VREG_ADDRESS(%ecx) # %st to vA
CLEAR_REF %ecx
ADVANCE_PC_FETCH_AND_GOTO_NEXT 1
%def op_sub_double():
% sseBinop(instr="subs", suff="d")
%def op_sub_double_2addr():
% sseBinop2Addr(instr="subs", suff="d")
%def op_sub_float():
% sseBinop(instr="subs", suff="s")
%def op_sub_float_2addr():
% sseBinop2Addr(instr="subs", suff="s")