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|
; RUN: %S/ConcreteTest.py --klee=%klee --lli=%lli %s
; casting error messages
@.strTrunc = internal constant [15 x i8] c"FPTrunc broken\00"
@.strExt = internal constant [13 x i8] c"FPExt broken\00"
@.strFPToUIFlt = internal constant [20 x i8] c"FPToUI float broken\00"
@.strFPToUIDbl = internal constant [21 x i8] c"FPToUI double broken\00"
@.strFPToSIFlt = internal constant [20 x i8] c"FPToSI float broken\00"
@.strFPToSIDbl = internal constant [21 x i8] c"FPToSI double broken\00"
@.strUIToFPFlt = internal constant [20 x i8] c"UIToFP float broken\00"
@.strUIToFPDbl = internal constant [21 x i8] c"UIToFP double broken\00"
@.strSIToFPFlt = internal constant [20 x i8] c"SIToFP float broken\00"
@.strSIToFPDbl = internal constant [21 x i8] c"SIToFP double broken\00"
; mathematical operator error messages
@.strDivFlt = internal constant [18 x i8] c"FDiv float broken\00"
@.strDivDbl = internal constant [19 x i8] c"FDiv double broken\00"
@.strRemFlt = internal constant [18 x i8] c"FRem float broken\00"
@.strRemDbl = internal constant [19 x i8] c"FRem double broken\00"
@.strAddInt = internal constant [16 x i8] c"Add ints broken\00"
@.strAddFlt = internal constant [18 x i8] c"Add floats broken\00"
@.strAddDbl = internal constant [19 x i8] c"Add doubles broken\00"
@.strSubInt = internal constant [16 x i8] c"Sub ints broken\00"
@.strSubFlt = internal constant [18 x i8] c"Sub floats broken\00"
@.strSubDbl = internal constant [19 x i8] c"Sub doubles broken\00"
@.strMulInt = internal constant [16 x i8] c"Mul ints broken\00"
@.strMulFlt = internal constant [18 x i8] c"Mul floats broken\00"
@.strMulDbl = internal constant [19 x i8] c"Mul doubles broken\00"
; fcmp error messages
@.strCmpTrFlt = internal constant [19 x i8] c"floats TRUE broken\00" ; fcmp::generic broken msgs
@.strCmpFaFlt = internal constant [20 x i8] c"floats FALSE broken\00"
@.strCmpTrDbl = internal constant [19 x i8] c"double TRUE broken\00"
@.strCmpFaDbl = internal constant [20 x i8] c"double FALSE broken\00"
@.strCmpEqFlt = internal constant [17 x i8] c"floats == broken\00" ; fcmp::ordered broken msgs
@.strCmpGeFlt = internal constant [17 x i8] c"floats >= broken\00"
@.strCmpGtFlt = internal constant [17 x i8] c"floats > broken\00"
@.strCmpLeFlt = internal constant [17 x i8] c"floats <= broken\00"
@.strCmpLtFlt = internal constant [17 x i8] c"floats < broken\00"
@.strCmpNeFlt = internal constant [17 x i8] c"floats != broken\00"
@.strCmpOrdFlt = internal constant [18 x i8] c"floats ORD broken\00"
@.strCmpEqDbl = internal constant [18 x i8] c"doubles == broken\00"
@.strCmpGeDbl = internal constant [18 x i8] c"doubles >= broken\00"
@.strCmpGtDbl = internal constant [18 x i8] c"doubles > broken\00"
@.strCmpLeDbl = internal constant [18 x i8] c"doubles <= broken\00"
@.strCmpLtDbl = internal constant [18 x i8] c"doubles < broken\00"
@.strCmpNeDbl = internal constant [18 x i8] c"doubles != broken\00"
@.strCmpOrdDbl = internal constant [19 x i8] c"doubles ORD broken\00"
@.strCmpEqFltU = internal constant [17 x i8] c"U:floats==broken\00" ; fcmp::unordered broken msgs
@.strCmpGeFltU = internal constant [17 x i8] c"U:floats>=broken\00"
@.strCmpGtFltU = internal constant [17 x i8] c"U:floats> broken\00"
@.strCmpLeFltU = internal constant [17 x i8] c"U:floats<=broken\00"
@.strCmpLtFltU = internal constant [17 x i8] c"U:floats< broken\00"
@.strCmpNeFltU = internal constant [17 x i8] c"U:floats!=broken\00"
@.strCmpUnoFlt = internal constant [20 x i8] c"U:floats UNO broken\00"
@.strCmpEqDblU = internal constant [18 x i8] c"U:doubles==broken\00"
@.strCmpGeDblU = internal constant [18 x i8] c"U:doubles>=broken\00"
@.strCmpGtDblU = internal constant [18 x i8] c"U:doubles> broken\00"
@.strCmpLeDblU = internal constant [18 x i8] c"U:doubles<=broken\00"
@.strCmpLtDblU = internal constant [18 x i8] c"U:doubles< broken\00"
@.strCmpNeDblU = internal constant [18 x i8] c"U:doubles!=broken\00"
@.strCmpUnoDbl = internal constant [21 x i8] c"U:doubles UNO broken\00"
@.strWorks = internal constant [20 x i8] c"Everything works!\0D\0A\00"
@.strNL = internal constant [3 x i8] c"\0D\0A\00"
declare i32 @printf(i8*, ...)
declare void @exit(i32)
; if isOk is false, then print errMsg to stdout and exit(1)
define void @failCheck(i1 %isOk, i8* %errMsg) {
entry:
%fail = icmp eq i1 %isOk, 0
br i1 %fail, label %failed, label %return
failed:
; print the error msg
%ret = call i32 (i8*, ...)* @printf( i8* %errMsg )
; add a newline to the ostream
%nl = getelementptr [3 x i8]* @.strNL, i32 0, i32 0
%ret2 = call i32 (i8*, ...)* @printf( i8* %nl )
; exit with return value 1 to denote that an error occurred
call void @exit( i32 1 )
unreachable
return:
ret void
}
; test FPTrunc which casts doubles to floats
define void @testFPTrunc() {
entry:
%d_addr = alloca double, align 8
store double 8.000000e+00, double* %d_addr
%d = load double* %d_addr
%f = fptrunc double %d to float
%matches = fcmp oeq float %f, 8.000000e+00
%err_msg = getelementptr [15 x i8]* @.strTrunc, i32 0, i32 0
call void @failCheck( i1 %matches, i8* %err_msg )
ret void
}
; test FPExt which casts floats to doubles
define void @testFPExt() {
entry:
%f_addr = alloca float, align 4
store float 8.000000e+00, float* %f_addr
%f = load float* %f_addr
%d = fpext float %f to double
%matches = fcmp oeq double %d, 8.000000e+00
%err_msg = getelementptr [13 x i8]* @.strExt, i32 0, i32 0
call void @failCheck( i1 %matches, i8* %err_msg )
ret void
}
; test casting fp to an unsigned int
define void @testFPToUI() {
entry:
%f_addr = alloca float, align 4
%d_addr = alloca double, align 8
; test float to UI
store float 0x4020333340000000, float* %f_addr; %f = 8.1
%f = load float* %f_addr
%uf = fptoui float %f to i32
%matchesf = icmp eq i32 %uf, 8
%err_msgf = getelementptr [20 x i8]* @.strFPToUIFlt, i32 0, i32 0
call void @failCheck( i1 %matchesf, i8* %err_msgf )
; test double to UI
store double 8.100000e+00, double* %d_addr
%d = load double* %d_addr
%ud = fptoui double %d to i32
%matchesd = icmp eq i32 %ud, 8
%err_msgd = getelementptr [21 x i8]* @.strFPToUIDbl, i32 0, i32 0
call void @failCheck( i1 %matchesd, i8* %err_msgd )
ret void
}
; test casting fp to a signed int
define void @testFPToSI() {
entry:
%f_addr = alloca float, align 4
%d_addr = alloca double, align 8
; test float 8.1 to signed int
store float 0x4020333340000000, float* %f_addr
%f = load float* %f_addr
%sf = fptosi float %f to i32
%matchesf = icmp eq i32 %sf, 8
%err_msgf = getelementptr [20 x i8]* @.strFPToSIFlt, i32 0, i32 0
call void @failCheck( i1 %matchesf, i8* %err_msgf )
; test double -8.1 to signed int
store double -8.100000e+00, double* %d_addr
%d = load double* %d_addr
%sd = fptosi double %d to i32
%matchesd = icmp eq i32 %sd, -8
%err_msgd = getelementptr [21 x i8]* @.strFPToSIDbl, i32 0, i32 0
call void @failCheck( i1 %matchesd, i8* %err_msgd )
ret void
}
; test casting unsigned int to fp
define void @testUIToFP() {
entry:
; unsigned int to float
%f = uitofp i32 7 to float
%matchesf = fcmp oeq float %f, 7.000000e+00
%err_msgf = getelementptr [20 x i8]* @.strUIToFPFlt, i32 0, i32 0
call void @failCheck( i1 %matchesf, i8* %err_msgf )
; unsigned int to double
%d = uitofp i32 7 to double
%matchesd = fcmp oeq double %d, 7.000000e+00
%err_msgd = getelementptr [21 x i8]* @.strUIToFPDbl, i32 0, i32 0
call void @failCheck( i1 %matchesd, i8* %err_msgd )
ret void
}
; test casting signed int to fp
define void @testSIToFP() {
entry:
; signed int to float
%f = sitofp i32 -7 to float
%matchesf = fcmp oeq float %f, -7.000000e+00
%err_msgf = getelementptr [20 x i8]* @.strSIToFPFlt, i32 0, i32 0
call void @failCheck( i1 %matchesf, i8* %err_msgf )
; signed int to double
%d = sitofp i32 -7 to double
%matchesd = fcmp oeq double %d, -7.000000e+00
%err_msgd = getelementptr [21 x i8]* @.strSIToFPDbl, i32 0, i32 0
call void @failCheck( i1 %matchesd, i8* %err_msgd )
ret void
}
; testing fp division
define void @testFDiv() {
entry:
%fN_addr = alloca float, align 4
%fD_addr = alloca float, align 4
%dN_addr = alloca double, align 8
%dD_addr = alloca double, align 8
; float division
store float 2.200000e+01, float* %fN_addr
store float 4.000000e+00, float* %fD_addr
%fN = load float* %fN_addr
%fD = load float* %fD_addr
%f = fdiv float %fN, %fD
%matchesf = fcmp oeq float %f, 5.500000e+00
%err_msgf = getelementptr [18 x i8]* @.strDivFlt, i32 0, i32 0
call void @failCheck( i1 %matchesf, i8* %err_msgf )
; double division
store double 2.200000e+01, double* %dN_addr
store double -4.000000e+00, double* %dD_addr
%dN = load double* %dN_addr
%dD = load double* %dD_addr
%d = fdiv double %dN, %dD
%matchesd = fcmp oeq double %d, -5.500000e+00
%err_msgd = getelementptr [19 x i8]* @.strDivDbl, i32 0, i32 0
call void @failCheck( i1 %matchesd, i8* %err_msgd )
ret void
}
; testing fp modulo
define void @testFRem() {
entry:
%fN_addr = alloca float, align 4
%fD_addr = alloca float, align 4
%dN_addr = alloca double, align 8
%dD_addr = alloca double, align 8
; float modoulo
store float 2.200000e+01, float* %fN_addr
store float 4.000000e+00, float* %fD_addr
%fN = load float* %fN_addr
%fD = load float* %fD_addr
%f = frem float %fN, %fD
%matchesf = fcmp oeq float %f, 2.000000e+00
%err_msgf = getelementptr [18 x i8]* @.strRemFlt, i32 0, i32 0
call void @failCheck( i1 %matchesf, i8* %err_msgf )
; double modulo
store double -2.200000e+01, double* %dN_addr
store double 4.000000e+00, double* %dD_addr
%dN = load double* %dN_addr
%dD = load double* %dD_addr
%d = frem double %dN, %dD
%matchesd = fcmp oeq double %d, -2.000000e+00
%err_msgd = getelementptr [19 x i8]* @.strRemDbl, i32 0, i32 0
call void @failCheck( i1 %matchesd, i8* %err_msgd )
ret void
}
; test addition
define void @testAdd() {
entry:
%f1_addr = alloca float, align 4
%f2_addr = alloca float, align 4
%d1_addr = alloca double, align 8
%d2_addr = alloca double, align 8
; test integer addition (3 + 4)
%sumi = add i32 3, 4
%matchesi = icmp eq i32 %sumi, 7
%err_msgi = getelementptr [16 x i8]* @.strAddInt, i32 0, i32 0
call void @failCheck( i1 %matchesi, i8* %err_msgi )
; test float addition (3.5 + 4.2)
store float 3.500000e+00, float* %f1_addr
store float 0x4010CCCCC0000000, float* %f2_addr
%f1 = load float* %f1_addr
%f2 = load float* %f2_addr
%sumf = fadd float %f1, %f2
%matchesf = fcmp oeq float %sumf, 0x401ECCCCC0000000
%err_msgf = getelementptr [18 x i8]* @.strAddFlt, i32 0, i32 0
call void @failCheck( i1 %matchesf, i8* %err_msgf )
; test double addition (3.5 + -4.2)
store double 3.500000e+00, double* %d1_addr
store double -4.200000e+00, double* %d2_addr
%d1 = load double* %d1_addr
%d2 = load double* %d2_addr
%sumd = fadd double %d1, %d2
%matchesd = fcmp oeq double %sumd, 0xBFE6666666666668
%err_msgd = getelementptr [19 x i8]* @.strAddDbl, i32 0, i32 0
call void @failCheck( i1 %matchesd, i8* %err_msgd )
ret void
}
; test subtraction
define void @testSub() {
entry:
%f1_addr = alloca float, align 4
%f2_addr = alloca float, align 4
%d1_addr = alloca double, align 8
%d2_addr = alloca double, align 8
; test integer subtraction (3 - 4)
%subi = sub i32 3, 4
%matchesi = icmp eq i32 %subi, -1
%err_msgi = getelementptr [16 x i8]* @.strSubInt, i32 0, i32 0
call void @failCheck( i1 %matchesi, i8* %err_msgi )
; test float subtraction (3.5 - 4.2)
store float 3.500000e+00, float* %f1_addr
store float 0x4010CCCCC0000000, float* %f2_addr
%f1 = load float* %f1_addr
%f2 = load float* %f2_addr
%subf = fsub float %f1, %f2
%matchesf = fcmp oeq float %subf, 0xBFE6666600000000
%err_msgf = getelementptr [18 x i8]* @.strSubFlt, i32 0, i32 0
call void @failCheck( i1 %matchesf, i8* %err_msgf )
; test double subtraction (3.5 - -4.2)
store double 3.500000e+00, double* %d1_addr
store double -4.200000e+00, double* %d2_addr
%d1 = load double* %d1_addr
%d2 = load double* %d2_addr
%subd = fsub double %d1, %d2
%matchesd = fcmp oeq double %subd, 7.700000e+00
%err_msgd = getelementptr [19 x i8]* @.strSubDbl, i32 0, i32 0
call void @failCheck( i1 %matchesd, i8* %err_msgd )
ret void
}
; test multiplication
define void @testMul() {
entry:
%f1_addr = alloca float, align 4
%f2_addr = alloca float, align 4
%d1_addr = alloca double, align 8
%d2_addr = alloca double, align 8
; test integer multiplication (3 * 4)
%muli = mul i32 3, 4
%matchesi = icmp eq i32 %muli, 12
%err_msgi = getelementptr [16 x i8]* @.strMulInt, i32 0, i32 0
call void @failCheck( i1 %matchesi, i8* %err_msgi )
; test float multiplication (3.5 * 4.2)
store float 3.500000e+00, float* %f1_addr
store float 0x4010CCCCC0000000, float* %f2_addr
%f1 = load float* %f1_addr
%f2 = load float* %f2_addr
%mulf = fmul float %f1, %f2
%matchesf = fcmp oeq float %mulf, 0x402D666640000000
%err_msgf = getelementptr [18 x i8]* @.strMulFlt, i32 0, i32 0
call void @failCheck( i1 %matchesf, i8* %err_msgf )
; test double multiplication (3.5 * -4.2)
store double 3.500000e+00, double* %d1_addr
store double -4.200000e+00, double* %d2_addr
%d1 = load double* %d1_addr
%d2 = load double* %d2_addr
%muld = fmul double %d1, %d2
%matchesd = fcmp oeq double %muld, 0xC02D666666666667
%err_msgd = getelementptr [19 x i8]* @.strMulDbl, i32 0, i32 0
call void @failCheck( i1 %matchesd, i8* %err_msgd )
ret void
}
; test float comparisons (ordered)
define void @testFCmpFOrdered(float %f1, float %f2, i1 %eq, i1 %ge, i1 %gt, i1 %le, i1 %lt, i1 %ne, i1 %ord) {
entry:
; test fcmp::true -- should always return true
%cmp_t = fcmp true float %f1, %f2
%cmp_t_ok = icmp eq i1 %cmp_t, 1
%cmp_t_em = getelementptr [19 x i8]* @.strCmpTrFlt, i32 0, i32 0
call void @failCheck( i1 %cmp_t_ok, i8* %cmp_t_em )
; test fcmp::false -- should always return false
%cmp_f = fcmp false float %f1, %f2
%cmp_f_ok = icmp eq i1 %cmp_f, 0
%cmp_f_em = getelementptr [20 x i8]* @.strCmpFaFlt, i32 0, i32 0
call void @failCheck( i1 %cmp_f_ok, i8* %cmp_f_em )
; test fcmp::ord -- should return true if neither operand is NaN
%cmp_o = fcmp ord float %f1, %f2
%cmp_o_ok = icmp eq i1 %cmp_o, %ord
%cmp_o_em = getelementptr [18 x i8]* @.strCmpOrdFlt, i32 0, i32 0
call void @failCheck( i1 %cmp_o_ok, i8* %cmp_o_em )
; test fcmp::oeq -- should return true if neither operand is a NaN and they are equal
%cmp_eq = fcmp oeq float %f1, %f2
%cmp_eq_ok = icmp eq i1 %cmp_eq, %eq
%cmp_eq_em = getelementptr [17 x i8]* @.strCmpEqFlt, i32 0, i32 0
call void @failCheck( i1 %cmp_eq_ok, i8* %cmp_eq_em )
; test fcmp::oge -- should return true if neither operand is a NaN and the first is greater or equal
%cmp_ge = fcmp oge float %f1, %f2
%cmp_ge_ok = icmp eq i1 %cmp_ge, %ge
%cmp_ge_em = getelementptr [17 x i8]* @.strCmpGeFlt, i32 0, i32 0
call void @failCheck( i1 %cmp_ge_ok, i8* %cmp_ge_em )
; test fcmp::ogt -- should return true if neither operand is a NaN and the first is greater
%cmp_gt = fcmp ogt float %f1, %f2
%cmp_gt_ok = icmp eq i1 %cmp_gt, %gt
%cmp_gt_em = getelementptr [17 x i8]* @.strCmpGtFlt, i32 0, i32 0
call void @failCheck( i1 %cmp_gt_ok, i8* %cmp_gt_em )
; test fcmp::ole -- should return true if neither operand is a NaN and the first is less or equal
%cmp_le = fcmp ole float %f1, %f2
%cmp_le_ok = icmp eq i1 %cmp_le, %le
%cmp_le_em = getelementptr [17 x i8]* @.strCmpLeFlt, i32 0, i32 0
call void @failCheck( i1 %cmp_le_ok, i8* %cmp_le_em )
; test fcmp::olt -- should return true if neither operand is a NaN and the first is less
%cmp_lt = fcmp olt float %f1, %f2
%cmp_lt_ok = icmp eq i1 %cmp_lt, %lt
%cmp_lt_em = getelementptr [17 x i8]* @.strCmpLtFlt, i32 0, i32 0
call void @failCheck( i1 %cmp_lt_ok, i8* %cmp_lt_em )
; test fcmp::one -- should return true if neither operand is a NaN and they are not equal
%cmp_ne = fcmp one float %f1, %f2
%cmp_ne_ok = icmp eq i1 %cmp_ne, %ne
%cmp_ne_em = getelementptr [17 x i8]* @.strCmpNeFlt, i32 0, i32 0
call void @failCheck( i1 %cmp_ne_ok, i8* %cmp_ne_em )
ret void
}
; test double comparisons (ordered)
define void @testFCmpDOrdered(double %d1, double %d2, i1 %eq, i1 %ge, i1 %gt, i1 %le, i1 %lt, i1 %ne, i1 %ord) {
entry:
; test fcmp::true -- should always return true
%cmp_t = fcmp true double %d1, %d2
%cmp_t_ok = icmp eq i1 %cmp_t, 1
%cmp_t_em = getelementptr [19 x i8]* @.strCmpTrDbl, i32 0, i32 0
call void @failCheck( i1 %cmp_t_ok, i8* %cmp_t_em )
; test fcmp::false -- should always return false
%cmp_f = fcmp false double %d1, %d2
%cmp_f_ok = icmp eq i1 %cmp_f, 0
%cmp_f_em = getelementptr [20 x i8]* @.strCmpFaDbl, i32 0, i32 0
call void @failCheck( i1 %cmp_f_ok, i8* %cmp_f_em )
; test fcmp::ord -- should return true if neither operand is NaN
%cmp_o = fcmp ord double %d1, %d2
%cmp_o_ok = icmp eq i1 %cmp_o, %ord
%cmp_o_em = getelementptr [19 x i8]* @.strCmpOrdDbl, i32 0, i32 0
call void @failCheck( i1 %cmp_o_ok, i8* %cmp_o_em )
; test fcmp::oeq -- should return true if neither operand is a NaN and they are equal
%cmp_eq = fcmp oeq double %d1, %d2
%cmp_eq_ok = icmp eq i1 %cmp_eq, %eq
%cmp_eq_em = getelementptr [18 x i8]* @.strCmpEqDbl, i32 0, i32 0
call void @failCheck( i1 %cmp_eq_ok, i8* %cmp_eq_em )
; test fcmp::oge -- should return true if neither operand is a NaN and the first is greater or equal
%cmp_ge = fcmp oge double %d1, %d2
%cmp_ge_ok = icmp eq i1 %cmp_ge, %ge
%cmp_ge_em = getelementptr [18 x i8]* @.strCmpGeDbl, i32 0, i32 0
call void @failCheck( i1 %cmp_ge_ok, i8* %cmp_ge_em )
; test fcmp::ogt -- should return true if neither operand is a NaN and the first is greater
%cmp_gt = fcmp ogt double %d1, %d2
%cmp_gt_ok = icmp eq i1 %cmp_gt, %gt
%cmp_gt_em = getelementptr [18 x i8]* @.strCmpGtDbl, i32 0, i32 0
call void @failCheck( i1 %cmp_gt_ok, i8* %cmp_gt_em )
; test fcmp::ole -- should return true if neither operand is a NaN and the first is less or equal
%cmp_le = fcmp ole double %d1, %d2
%cmp_le_ok = icmp eq i1 %cmp_le, %le
%cmp_le_em = getelementptr [18 x i8]* @.strCmpLeDbl, i32 0, i32 0
call void @failCheck( i1 %cmp_le_ok, i8* %cmp_le_em )
; test fcmp::olt -- should return true if neither operand is a NaN and the first is less
%cmp_lt = fcmp olt double %d1, %d2
%cmp_lt_ok = icmp eq i1 %cmp_lt, %lt
%cmp_lt_em = getelementptr [18 x i8]* @.strCmpLtDbl, i32 0, i32 0
call void @failCheck( i1 %cmp_lt_ok, i8* %cmp_lt_em )
; test fcmp::one -- should return true if neither operand is a NaN and they are not equal
%cmp_ne = fcmp one double %d1, %d2
%cmp_ne_ok = icmp eq i1 %cmp_ne, %ne
%cmp_ne_em = getelementptr [18 x i8]* @.strCmpNeDbl, i32 0, i32 0
call void @failCheck( i1 %cmp_ne_ok, i8* %cmp_ne_em )
ret void
}
; test floating point comparisons (ordered)
define void @testFCmpBothOrdered(double %d1, double %d2, i1 %eq, i1 %ge, i1 %gt, i1 %le, i1 %lt, i1 %ne, i1 %ord) {
entry:
call void @testFCmpDOrdered( double %d1, double %d2, i1 %eq, i1 %ge, i1 %gt, i1 %le, i1 %lt, i1 %ne, i1 %ord )
%f1 = fptrunc double %d1 to float
%f2 = fptrunc double %d2 to float
call void @testFCmpFOrdered( float %f1, float %f2, i1 %eq, i1 %ge, i1 %gt, i1 %le, i1 %lt, i1 %ne, i1 %ord )
ret void
}
; test float comparisons (unordered)
define void @testFCmpFUnordered(float %f1, float %f2, i1 %eq, i1 %ge, i1 %gt, i1 %le, i1 %lt, i1 %ne, i1 %uno) {
entry:
; test fcmp::uno -- should return true if either operand is NaN
%cmp_o = fcmp uno float %f1, %f2
%cmp_o_ok = icmp eq i1 %cmp_o, %uno
%cmp_o_em = getelementptr [20 x i8]* @.strCmpUnoFlt, i32 0, i32 0
call void @failCheck( i1 %cmp_o_ok, i8* %cmp_o_em )
; test fcmp::oeq -- should return true if either operand is a NaN and they are equal
%cmp_eq = fcmp ueq float %f1, %f2
%cmp_eq_ok = icmp eq i1 %cmp_eq, %eq
%cmp_eq_em = getelementptr [17 x i8]* @.strCmpEqFltU, i32 0, i32 0
call void @failCheck( i1 %cmp_eq_ok, i8* %cmp_eq_em )
; test fcmp::oge -- should return true if either operand is a NaN and the first is greater or equal
%cmp_ge = fcmp uge float %f1, %f2
%cmp_ge_ok = icmp eq i1 %cmp_ge, %ge
%cmp_ge_em = getelementptr [17 x i8]* @.strCmpGeFltU, i32 0, i32 0
call void @failCheck( i1 %cmp_ge_ok, i8* %cmp_ge_em )
; test fcmp::ogt -- should return true if either operand is a NaN and the first is greater
%cmp_gt = fcmp ugt float %f1, %f2
%cmp_gt_ok = icmp eq i1 %cmp_gt, %gt
%cmp_gt_em = getelementptr [17 x i8]* @.strCmpGtFltU, i32 0, i32 0
call void @failCheck( i1 %cmp_gt_ok, i8* %cmp_gt_em )
; test fcmp::ole -- should return true if either operand is a NaN and the first is less or equal
%cmp_le = fcmp ule float %f1, %f2
%cmp_le_ok = icmp eq i1 %cmp_le, %le
%cmp_le_em = getelementptr [17 x i8]* @.strCmpLeFltU, i32 0, i32 0
call void @failCheck( i1 %cmp_le_ok, i8* %cmp_le_em )
; test fcmp::olt -- should return true if either operand is a NaN and the first is less
%cmp_lt = fcmp ult float %f1, %f2
%cmp_lt_ok = icmp eq i1 %cmp_lt, %lt
%cmp_lt_em = getelementptr [17 x i8]* @.strCmpLtFltU, i32 0, i32 0
call void @failCheck( i1 %cmp_lt_ok, i8* %cmp_lt_em )
; test fcmp::one -- should return true if either operand is a NaN and they are not equal
%cmp_ne = fcmp une float %f1, %f2
%cmp_ne_ok = icmp eq i1 %cmp_ne, %ne
%cmp_ne_em = getelementptr [17 x i8]* @.strCmpNeFltU, i32 0, i32 0
call void @failCheck( i1 %cmp_ne_ok, i8* %cmp_ne_em )
ret void
}
; test double comparisons (unordered)
define void @testFCmpDUnordered(double %d1, double %d2, i1 %eq, i1 %ge, i1 %gt, i1 %le, i1 %lt, i1 %ne, i1 %uno) {
entry:
; test fcmp::uno -- should return true if either operand is NaN
%cmp_o = fcmp uno double %d1, %d2
%cmp_o_ok = icmp eq i1 %cmp_o, %uno
%cmp_o_em = getelementptr [21 x i8]* @.strCmpUnoDbl, i32 0, i32 0
call void @failCheck( i1 %cmp_o_ok, i8* %cmp_o_em )
; test fcmp::ueq -- should return true if either operand is a NaN and they are equal
%cmp_eq = fcmp ueq double %d1, %d2
%cmp_eq_ok = icmp eq i1 %cmp_eq, %eq
%cmp_eq_em = getelementptr [18 x i8]* @.strCmpEqDblU, i32 0, i32 0
call void @failCheck( i1 %cmp_eq_ok, i8* %cmp_eq_em )
; test fcmp::uge -- should return true if either operand is a NaN and the first is greater or equal
%cmp_ge = fcmp uge double %d1, %d2
%cmp_ge_ok = icmp eq i1 %cmp_ge, %ge
%cmp_ge_em = getelementptr [18 x i8]* @.strCmpGeDblU, i32 0, i32 0
call void @failCheck( i1 %cmp_ge_ok, i8* %cmp_ge_em )
; test fcmp::ugt -- should return true if either operand is a NaN and the first is greater
%cmp_gt = fcmp ugt double %d1, %d2
%cmp_gt_ok = icmp eq i1 %cmp_gt, %gt
%cmp_gt_em = getelementptr [18 x i8]* @.strCmpGtDblU, i32 0, i32 0
call void @failCheck( i1 %cmp_gt_ok, i8* %cmp_gt_em )
; test fcmp::ule -- should return true if either operand is a NaN and the first is less or equal
%cmp_le = fcmp ule double %d1, %d2
%cmp_le_ok = icmp eq i1 %cmp_le, %le
%cmp_le_em = getelementptr [18 x i8]* @.strCmpLeDblU, i32 0, i32 0
call void @failCheck( i1 %cmp_le_ok, i8* %cmp_le_em )
; test fcmp::ult -- should return true if either operand is a NaN and the first is less
%cmp_lt = fcmp ult double %d1, %d2
%cmp_lt_ok = icmp eq i1 %cmp_lt, %lt
%cmp_lt_em = getelementptr [18 x i8]* @.strCmpLtDblU, i32 0, i32 0
call void @failCheck( i1 %cmp_lt_ok, i8* %cmp_lt_em )
; test fcmp::une -- should return true if either operand is a NaN and they are not equal
%cmp_ne = fcmp une double %d1, %d2
%cmp_ne_ok = icmp eq i1 %cmp_ne, %ne
%cmp_ne_em = getelementptr [18 x i8]* @.strCmpNeDblU, i32 0, i32 0
call void @failCheck( i1 %cmp_ne_ok, i8* %cmp_ne_em )
ret void
}
; test floating point comparisons (unordered)
define void @testFCmpBothUnordered(double %d1, double %d2, i1 %eq, i1 %ge, i1 %gt, i1 %le, i1 %lt, i1 %ne, i1 %uno) {
entry:
call void @testFCmpDUnordered( double %d1, double %d2, i1 %eq, i1 %ge, i1 %gt, i1 %le, i1 %lt, i1 %ne, i1 %uno )
%f1 = fptrunc double %d1 to float
%f2 = fptrunc double %d2 to float
call void @testFCmpFUnordered( float %f1, float %f2, i1 %eq, i1 %ge, i1 %gt, i1 %le, i1 %lt, i1 %ne, i1 %uno )
ret void
}
; test floating point comparisons (ordered and unordered)
define void @testFCmpBoth(double %d1, double %d2, i1 %eq, i1 %ge, i1 %gt, i1 %le, i1 %lt, i1 %ne, i1 %ord, i1 %uno) {
entry:
call void @testFCmpBothOrdered( double %d1, double %d2, i1 %eq, i1 %ge, i1 %gt, i1 %le, i1 %lt, i1 %ne, i1 %ord )
call void @testFCmpBothUnordered( double %d1, double %d2, i1 %eq, i1 %ge, i1 %gt, i1 %le, i1 %lt, i1 %ne, i1 %uno )
ret void
}
; test floating point comparisons (ordered and unordered) with a variety of real numbers and NaNs as operands
define void @testFCmp() {
entry:
%x = alloca i64, align 8
%nan = alloca double, align 8
; test FCmp on some real number inputs
call void @testFCmpBoth( double 0.000000e+00, double 0.000000e+00, i1 1, i1 1, i1 0, i1 1, i1 0, i1 0, i1 1, i1 0 )
call void @testFCmpBoth( double 0.000000e+00, double 1.000000e+00, i1 0, i1 0, i1 0, i1 1, i1 1, i1 1, i1 1, i1 0 )
call void @testFCmpBoth( double 1.000000e+00, double 0.000000e+00, i1 0, i1 1, i1 1, i1 0, i1 0, i1 1, i1 1, i1 0 )
; build NaN
%nan_as_i64 = bitcast double* %nan to i64*
store i64 -1, i64* %nan_as_i64
; load two copies of our NaN
%nan1 = load double* %nan
%nan2 = load double* %nan
; Warning: NaN comparisons with normal operators is BROKEN in LLVM JIT v2.0. Fixed in v2.1.
; FIXME: Just check against 2.9 and the Unordered checks work, but the ordered ones do not. Should be investigated.
; NaNs do different things depending on ordered vs unordered
; call void @testFCmpBothOrdered( double %nan1, double 0.000000e+00, i1 0, i1 0, i1 0, i1 0, i1 0, i1 0, i1 0 )
; call void @testFCmpBothOrdered( double %nan1, double %nan2, i1 0, i1 0, i1 0, i1 0, i1 0, i1 0, i1 0 )
; call void @testFCmpBothUnordered( double %nan1, double 0.000000e+00, i1 1, i1 1, i1 1, i1 1, i1 1, i1 1, i1 1 )
; call void @testFCmpBothUnordered( double %nan1, double %nan2, i1 1, i1 1, i1 1, i1 1, i1 1, i1 1, i1 1 )
ret void
}
; tes all floating point instructions
define i32 @main() {
entry:
call void @testFPTrunc( )
call void @testFPExt( )
call void @testFPToUI( )
call void @testFPToSI( )
call void @testUIToFP( )
call void @testSIToFP( )
call void @testFDiv( )
call void @testFRem( )
call void @testAdd( )
call void @testSub( )
call void @testMul( )
call void @testFCmp( )
; everything worked -- print a message saying so
%works_msg = getelementptr [20 x i8]* @.strWorks, i32 0, i32 0
%ret = call i32 (i8*, ...)* @printf( i8* %works_msg )
ret i32 0
}
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