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// Pentium III instructions
OptCategory[NN_addps] = 1; // Packed Single-FP Add
OptCategory[NN_addss] = 1; // Scalar Single-FP Add
OptCategory[NN_andnps] = 1; // Bitwise Logical And Not for Single-FP
OptCategory[NN_andps] = 1; // Bitwise Logical And for Single-FP
OptCategory[NN_cmpps] = 1; // Packed Single-FP Compare
OptCategory[NN_cmpss] = 1; // Scalar Single-FP Compare
OptCategory[NN_comiss] = 1; // Scalar Ordered Single-FP Compare and Set EFLAGS
OptCategory[NN_cvtpi2ps] = 1; // Packed signed INT32 to Packed Single-FP conversion
OptCategory[NN_cvtps2pi] = 1; // Packed Single-FP to Packed INT32 conversion
OptCategory[NN_cvtsi2ss] = 1; // Scalar signed INT32 to Single-FP conversion
OptCategory[NN_cvtss2si] = 2; // Scalar Single-FP to signed INT32 conversion
OptCategory[NN_cvttps2pi] = 1; // Packed Single-FP to Packed INT32 conversion (truncate)
OptCategory[NN_cvttss2si] = 2; // Scalar Single-FP to signed INT32 conversion (truncate)
OptCategory[NN_divps] = 1; // Packed Single-FP Divide
OptCategory[NN_divss] = 1; // Scalar Single-FP Divide
OptCategory[NN_ldmxcsr] = 1; // Load Streaming SIMD Extensions Technology Control/Status Register
OptCategory[NN_maxps] = 1; // Packed Single-FP Maximum
OptCategory[NN_maxss] = 1; // Scalar Single-FP Maximum
OptCategory[NN_minps] = 1; // Packed Single-FP Minimum
OptCategory[NN_minss] = 1; // Scalar Single-FP Minimum
OptCategory[NN_movaps] = 9; // Move Aligned Four Packed Single-FP ** infer memsrc 'n'?
OptCategory[NN_movhlps] = 1; // Move High to Low Packed Single-FP
OptCategory[NN_movhps] = 1; // Move High Packed Single-FP
OptCategory[NN_movlhps] = 1; // Move Low to High Packed Single-FP
OptCategory[NN_movlps] = 1; // Move Low Packed Single-FP
OptCategory[NN_movmskps] = 1; // Move Mask to Register
OptCategory[NN_movss] = 9; // Move Scalar Single-FP
OptCategory[NN_movups] = 9; // Move Unaligned Four Packed Single-FP
OptCategory[NN_mulps] = 1; // Packed Single-FP Multiply
OptCategory[NN_mulss] = 1; // Scalar Single-FP Multiply
OptCategory[NN_orps] = 1; // Bitwise Logical OR for Single-FP Data
OptCategory[NN_rcpps] = 1; // Packed Single-FP Reciprocal
OptCategory[NN_rcpss] = 1; // Scalar Single-FP Reciprocal
OptCategory[NN_rsqrtps] = 1; // Packed Single-FP Square Root Reciprocal
OptCategory[NN_rsqrtss] = 1; // Scalar Single-FP Square Root Reciprocal
OptCategory[NN_shufps] = 1; // Shuffle Single-FP
OptCategory[NN_sqrtps] = 1; // Packed Single-FP Square Root
OptCategory[NN_sqrtss] = 1; // Scalar Single-FP Square Root
OptCategory[NN_stmxcsr] = 0; // Store Streaming SIMD Extensions Technology Control/Status Register ** Infer dest is 'n'
OptCategory[NN_subps] = 1; // Packed Single-FP Subtract
OptCategory[NN_subss] = 1; // Scalar Single-FP Subtract
OptCategory[NN_ucomiss] = 1; // Scalar Unordered Single-FP Compare and Set EFLAGS
OptCategory[NN_unpckhps] = 1; // Unpack High Packed Single-FP Data
OptCategory[NN_unpcklps] = 1; // Unpack Low Packed Single-FP Data
OptCategory[NN_xorps] = 1; // Bitwise Logical XOR for Single-FP Data
OptCategory[NN_pavgb] = 1; // Packed Average (Byte)
OptCategory[NN_pavgw] = 1; // Packed Average (Word)
OptCategory[NN_pextrw] = 2; // Extract Word
OptCategory[NN_pinsrw] = 1; // Insert Word
OptCategory[NN_pmaxsw] = 1; // Packed Signed Integer Word Maximum
OptCategory[NN_pmaxub] = 1; // Packed Unsigned Integer Byte Maximum
OptCategory[NN_pminsw] = 1; // Packed Signed Integer Word Minimum
OptCategory[NN_pminub] = 1; // Packed Unsigned Integer Byte Minimum
OptCategory[NN_pmovmskb] = 1; // Move Byte Mask to Integer
OptCategory[NN_pmulhuw] = 1; // Packed Multiply High Unsigned
OptCategory[NN_psadbw] = 1; // Packed Sum of Absolute Differences
OptCategory[NN_pshufw] = 1; // Packed Shuffle Word
OptCategory[NN_maskmovq] = 0; // Byte Mask write ** Infer dest is 'n'
OptCategory[NN_movntps] = 0; // Move Aligned Four Packed Single-FP Non Temporal * infer dest is 'n'
OptCategory[NN_movntq] = 0; // Move 64 Bits Non Temporal ** Infer dest is 'n'
OptCategory[NN_prefetcht0] = 1; // Prefetch to all cache levels
OptCategory[NN_prefetcht1] = 1; // Prefetch to all cache levels
OptCategory[NN_prefetcht2] = 1; // Prefetch to L2 cache
OptCategory[NN_prefetchnta] = 1; // Prefetch to L1 cache
OptCategory[NN_sfence] = 1; // Store Fence
// Pentium III Pseudo instructions
OptCategory[NN_cmpeqps] = 1; // Packed Single-FP Compare EQ
OptCategory[NN_cmpltps] = 1; // Packed Single-FP Compare LT
OptCategory[NN_cmpleps] = 1; // Packed Single-FP Compare LE
OptCategory[NN_cmpunordps] = 1; // Packed Single-FP Compare UNORD
OptCategory[NN_cmpneqps] = 1; // Packed Single-FP Compare NOT EQ
OptCategory[NN_cmpnltps] = 1; // Packed Single-FP Compare NOT LT
OptCategory[NN_cmpnleps] = 1; // Packed Single-FP Compare NOT LE
OptCategory[NN_cmpordps] = 1; // Packed Single-FP Compare ORDERED
OptCategory[NN_cmpeqss] = 1; // Scalar Single-FP Compare EQ
OptCategory[NN_cmpltss] = 1; // Scalar Single-FP Compare LT
OptCategory[NN_cmpless] = 1; // Scalar Single-FP Compare LE
OptCategory[NN_cmpunordss] = 1; // Scalar Single-FP Compare UNORD
OptCategory[NN_cmpneqss] = 1; // Scalar Single-FP Compare NOT EQ
OptCategory[NN_cmpnltss] = 1; // Scalar Single-FP Compare NOT LT
OptCategory[NN_cmpnless] = 1; // Scalar Single-FP Compare NOT LE
OptCategory[NN_cmpordss] = 1; // Scalar Single-FP Compare ORDERED
// AMD K7 instructions
// Revisit AMD if we port to it.
OptCategory[NN_pf2iw] = 0; // Packed Floating-Point to Integer with Sign Extend
OptCategory[NN_pfnacc] = 0; // Packed Floating-Point Negative Accumulate
OptCategory[NN_pfpnacc] = 0; // Packed Floating-Point Mixed Positive-Negative Accumulate
OptCategory[NN_pi2fw] = 0; // Packed 16-bit Integer to Floating-Point
OptCategory[NN_pswapd] = 0; // Packed Swap Double Word
// Undocumented FP instructions (thanks to norbert.juffa@adm.com)
OptCategory[NN_fstp1] = 9; // Alias of Store Real and Pop
OptCategory[NN_fcom2] = 1; // Alias of Compare Real
OptCategory[NN_fcomp3] = 1; // Alias of Compare Real and Pop
OptCategory[NN_fxch4] = 1; // Alias of Exchange Registers
OptCategory[NN_fcomp5] = 1; // Alias of Compare Real and Pop
OptCategory[NN_ffreep] = 1; // Free Register and Pop
OptCategory[NN_fxch7] = 1; // Alias of Exchange Registers
OptCategory[NN_fstp8] = 9; // Alias of Store Real and Pop
OptCategory[NN_fstp9] = 9; // Alias of Store Real and Pop
// Pentium 4 instructions
OptCategory[NN_addpd] = 1; // Add Packed Double-Precision Floating-Point Values
OptCategory[NN_addsd] = 1; // Add Scalar Double-Precision Floating-Point Values
OptCategory[NN_andnpd] = 1; // Bitwise Logical AND NOT of Packed Double-Precision Floating-Point Values
OptCategory[NN_andpd] = 1; // Bitwise Logical AND of Packed Double-Precision Floating-Point Values
OptCategory[NN_clflush] = 1; // Flush Cache Line
OptCategory[NN_cmppd] = 1; // Compare Packed Double-Precision Floating-Point Values
OptCategory[NN_cmpsd] = 1; // Compare Scalar Double-Precision Floating-Point Values
OptCategory[NN_comisd] = 1; // Compare Scalar Ordered Double-Precision Floating-Point Values and Set EFLAGS
OptCategory[NN_cvtdq2pd] = 1; // Convert Packed Doubleword Integers to Packed Single-Precision Floating-Point Values
OptCategory[NN_cvtdq2ps] = 1; // Convert Packed Doubleword Integers to Packed Double-Precision Floating-Point Values
OptCategory[NN_cvtpd2dq] = 1; // Convert Packed Double-Precision Floating-Point Values to Packed Doubleword Integers
OptCategory[NN_cvtpd2pi] = 1; // Convert Packed Double-Precision Floating-Point Values to Packed Doubleword Integers
OptCategory[NN_cvtpd2ps] = 1; // Convert Packed Double-Precision Floating-Point Values to Packed Single-Precision Floating-Point Values
OptCategory[NN_cvtpi2pd] = 1; // Convert Packed Doubleword Integers to Packed Double-Precision Floating-Point Values
OptCategory[NN_cvtps2dq] = 1; // Convert Packed Single-Precision Floating-Point Values to Packed Doubleword Integers
OptCategory[NN_cvtps2pd] = 1; // Convert Packed Single-Precision Floating-Point Values to Packed Double-Precision Floating-Point Values
OptCategory[NN_cvtsd2si] = 2; // Convert Scalar Double-Precision Floating-Point Value to Doubleword Integer
OptCategory[NN_cvtsd2ss] = 1; // Convert Scalar Double-Precision Floating-Point Value to Scalar Single-Precision Floating-Point Value
OptCategory[NN_cvtsi2sd] = 1; // Convert Doubleword Integer to Scalar Double-Precision Floating-Point Value
OptCategory[NN_cvtss2sd] = 1; // Convert Scalar Single-Precision Floating-Point Value to Scalar Double-Precision Floating-Point Value
OptCategory[NN_cvttpd2dq] = 1; // Convert With Truncation Packed Double-Precision Floating-Point Values to Packed Doubleword Integers
OptCategory[NN_cvttpd2pi] = 1; // Convert with Truncation Packed Double-Precision Floating-Point Values to Packed Doubleword Integers
OptCategory[NN_cvttps2dq] = 1; // Convert With Truncation Packed Single-Precision Floating-Point Values to Packed Doubleword Integers
OptCategory[NN_cvttsd2si] = 2; // Convert with Truncation Scalar Double-Precision Floating-Point Value to Doubleword Integer
OptCategory[NN_divpd] = 1; // Divide Packed Double-Precision Floating-Point Values
OptCategory[NN_divsd] = 1; // Divide Scalar Double-Precision Floating-Point Values
OptCategory[NN_lfence] = 1; // Load Fence
OptCategory[NN_maskmovdqu] = 0; // Store Selected Bytes of Double Quadword ** Infer dest is 'n'
OptCategory[NN_maxpd] = 1; // Return Maximum Packed Double-Precision Floating-Point Values
OptCategory[NN_maxsd] = 1; // Return Maximum Scalar Double-Precision Floating-Point Value
OptCategory[NN_mfence] = 1; // Memory Fence
OptCategory[NN_minpd] = 1; // Return Minimum Packed Double-Precision Floating-Point Values
OptCategory[NN_minsd] = 1; // Return Minimum Scalar Double-Precision Floating-Point Value
OptCategory[NN_movapd] = 9; // Move Aligned Packed Double-Precision Floating-Point Values ** Infer dest is 'n'
OptCategory[NN_movdq2q] = 1; // Move Quadword from XMM to MMX Register
OptCategory[NN_movdqa] = 9; // Move Aligned Double Quadword ** Infer dest is 'n'
OptCategory[NN_movdqu] = 9; // Move Unaligned Double Quadword ** Infer dest is 'n'
OptCategory[NN_movhpd] = 9; // Move High Packed Double-Precision Floating-Point Values ** Infer dest is 'n'
OptCategory[NN_movlpd] = 9; // Move Low Packed Double-Precision Floating-Point Values ** Infer dest is 'n'
OptCategory[NN_movmskpd] = 2; // Extract Packed Double-Precision Floating-Point Sign Mask
OptCategory[NN_movntdq] = 0; // Store Double Quadword Using Non-Temporal Hint
OptCategory[NN_movnti] = 0; // Store Doubleword Using Non-Temporal Hint
OptCategory[NN_movntpd] = 0; // Store Packed Double-Precision Floating-Point Values Using Non-Temporal Hint
OptCategory[NN_movq2dq] = 1; // Move Quadword from MMX to XMM Register
OptCategory[NN_movsd] = 9; // Move Scalar Double-Precision Floating-Point Values
OptCategory[NN_movupd] = 9; // Move Unaligned Packed Double-Precision Floating-Point Values
OptCategory[NN_mulpd] = 1; // Multiply Packed Double-Precision Floating-Point Values
OptCategory[NN_mulsd] = 1; // Multiply Scalar Double-Precision Floating-Point Values
OptCategory[NN_orpd] = 1; // Bitwise Logical OR of Double-Precision Floating-Point Values
OptCategory[NN_paddq] = 1; // Add Packed Quadword Integers
OptCategory[NN_pause] = 1; // Spin Loop Hint
OptCategory[NN_pmuludq] = 1; // Multiply Packed Unsigned Doubleword Integers
OptCategory[NN_pshufd] = 1; // Shuffle Packed Doublewords
OptCategory[NN_pshufhw] = 1; // Shuffle Packed High Words
OptCategory[NN_pshuflw] = 1; // Shuffle Packed Low Words
OptCategory[NN_pslldq] = 1; // Shift Double Quadword Left Logical
OptCategory[NN_psrldq] = 1; // Shift Double Quadword Right Logical
OptCategory[NN_psubq] = 1; // Subtract Packed Quadword Integers
OptCategory[NN_punpckhqdq] = 1; // Unpack High Data
OptCategory[NN_punpcklqdq] = 1; // Unpack Low Data
OptCategory[NN_shufpd] = 1; // Shuffle Packed Double-Precision Floating-Point Values
OptCategory[NN_sqrtpd] = 1; // Compute Square Roots of Packed Double-Precision Floating-Point Values
OptCategory[NN_sqrtsd] = 1; // Compute Square Rootof Scalar Double-Precision Floating-Point Value
OptCategory[NN_subpd] = 1; // Subtract Packed Double-Precision Floating-Point Values
OptCategory[NN_subsd] = 1; // Subtract Scalar Double-Precision Floating-Point Values
OptCategory[NN_ucomisd] = 1; // Unordered Compare Scalar Ordered Double-Precision Floating-Point Values and Set EFLAGS
OptCategory[NN_unpckhpd] = 1; // Unpack and Interleave High Packed Double-Precision Floating-Point Values
OptCategory[NN_unpcklpd] = 1; // Unpack and Interleave Low Packed Double-Precision Floating-Point Values
OptCategory[NN_xorpd] = 1; // Bitwise Logical OR of Double-Precision Floating-Point Values
// AMD syscall/sysret instructions NOTE: not AMD, found in Intel manual
OptCategory[NN_syscall] = 1; // Low latency system call
OptCategory[NN_sysret] = 1; // Return from system call
// AMD64 instructions NOTE: not AMD, found in Intel manual
OptCategory[NN_swapgs] = 1; // Exchange GS base with KernelGSBase MSR
// New Pentium instructions (SSE3)
OptCategory[NN_movddup] = 9; // Move One Double-FP and Duplicate
OptCategory[NN_movshdup] = 9; // Move Packed Single-FP High and Duplicate
OptCategory[NN_movsldup] = 9; // Move Packed Single-FP Low and Duplicate
// Missing AMD64 instructions NOTE: also found in Intel manual
OptCategory[NN_movsxd] = 2; // Move with Sign-Extend Doubleword
OptCategory[NN_cmpxchg16b] = 0; // Compare and Exchange 16 Bytes
// SSE3 instructions
OptCategory[NN_addsubpd] = 1; // Add /Sub packed DP FP numbers
OptCategory[NN_addsubps] = 1; // Add /Sub packed SP FP numbers
OptCategory[NN_haddpd] = 1; // Add horizontally packed DP FP numbers
OptCategory[NN_haddps] = 1; // Add horizontally packed SP FP numbers
OptCategory[NN_hsubpd] = 1; // Sub horizontally packed DP FP numbers
OptCategory[NN_hsubps] = 1; // Sub horizontally packed SP FP numbers
OptCategory[NN_monitor] = 1; // Set up a linear address range to be monitored by hardware
OptCategory[NN_mwait] = 1; // Wait until write-back store performed within the range specified by the MONITOR instruction
OptCategory[NN_fisttp] = 0; // Store ST in intXX (chop) and pop
OptCategory[NN_lddqu] = 1; // Load unaligned integer 128-bit
2214
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2255
// SSSE3 instructions
OptCategory[NN_psignb] = 1; // Packed SIGN Byte
OptCategory[NN_psignw] = 1; // Packed SIGN Word
OptCategory[NN_psignd] = 1; // Packed SIGN Doubleword
OptCategory[NN_pshufb] = 1; // Packed Shuffle Bytes
OptCategory[NN_pmulhrsw] = 1; // Packed Multiply High with Round and Scale
OptCategory[NN_pmaddubsw] = 1; // Multiply and Add Packed Signed and Unsigned Bytes
OptCategory[NN_phsubsw] = 1; // Packed Horizontal Subtract and Saturate
OptCategory[NN_phaddsw] = 1; // Packed Horizontal Add and Saturate
OptCategory[NN_phaddw] = 1; // Packed Horizontal Add Word
OptCategory[NN_phaddd] = 1; // Packed Horizontal Add Doubleword
OptCategory[NN_phsubw] = 1; // Packed Horizontal Subtract Word
OptCategory[NN_phsubd] = 1; // Packed Horizontal Subtract Doubleword
OptCategory[NN_palignr] = 1; // Packed Align Right
OptCategory[NN_pabsb] = 1; // Packed Absolute Value Byte
OptCategory[NN_pabsw] = 1; // Packed Absolute Value Word
OptCategory[NN_pabsd] = 1; // Packed Absolute Value Doubleword
// VMX instructions
OptCategory[NN_vmcall] = 1; // Call to VM Monitor
OptCategory[NN_vmclear] = 0; // Clear Virtual Machine Control Structure
OptCategory[NN_vmlaunch] = 1; // Launch Virtual Machine
OptCategory[NN_vmresume] = 1; // Resume Virtual Machine
OptCategory[NN_vmptrld] = 6; // Load Pointer to Virtual Machine Control Structure
OptCategory[NN_vmptrst] = 0; // Store Pointer to Virtual Machine Control Structure
OptCategory[NN_vmread] = 0; // Read Field from Virtual Machine Control Structure
OptCategory[NN_vmwrite] = 0; // Write Field from Virtual Machine Control Structure
OptCategory[NN_vmxoff] = 1; // Leave VMX Operation
OptCategory[NN_vmxon] = 1; // Enter VMX Operation
OptCategory[NN_last] = 1;
return;
} // end InitOptCategory()