Bitwise ternary logic instruction

Bitwise ternary logic instructions can logically implement all possible bitwise operations between three inputs (256 permutations). They take three registers as input and an 8-bit immediate field. Each bit in the output is generated using an 8-bit Lookup table of the three corresponding bits in the inputs to select one of the 8 positions in the 8-bit immediate. Since only 8 combinations are possible using three bits, this allow all possible 3-input bitwise operations to be performed. In mathematical terminology: each corresponding bit of the three inputs is a ternary Boolean function with a Hasse diagram of order n=8.^[1] Also known as minterms.

A full table showing all 256 possible 3-operand logical bitwise instruction may be found in the Power ISA description of xxeval .^[2] An additional insight is that if the 8-bit immediate were an operand (register) then in FPGA terminology, bitwise ternary logical instructions would implement an array of Hardware LUT3s.

Description

In pseudocode the output from three single-bit inputs is illustrated by using r2, r1 and r0 as three binary digits of a 3-bit index, to treat the 8-bit immediate as a lookup table and to simply return the indexed bit:

result := imm8(r2<<2 + r1<<1 + r0)

A readable implementation in Python of three single-bit inputs (r0 r1 and r2) is shown below:

def ternlut8(r0, r1, r2, imm8):
    """Implementation of a LUT3 (ternary lookup)"""
    # index will be in range 0 to 7
    lut_index = 0
    # r0 sets bit0, r1 bit1, and r2 bit2
    if r0: lut_index |= 1 << 0
    if r1: lut_index |= 1 << 1
    if r2: lut_index |= 1 << 2
    # return the requested indexed bit of imm8
    return imm8 & (1 << lut_index) != 0

If the input registers are 64-bit then the output is correspondingly 64-bit, and would be constructed from selecting each indexed bit of the three inputs to create the corresponding indexed bit of the output:

def ternlut8_64bit(R0, R1, R2, imm8):
    """Implementation of a 64-bit ternary lookup instruction"""
    result = 0
    for i in range(64):
        m = 1 << i  # single mask bit of inputs
        r0, r1, r2 = (R0 & m), (R1 & m), (R2 & m)
        result |= ternlut8(r0, r1, r2, imm8) << i
    return result

An example table of just three possible permutations out of the total 256 for the 8-bit immediate is shown below - Double-AND, Double-OR and Bitwise-blend. The immediate (the 8-bit lookup table) is named imm8, below. Note that the column has the value in binary of its corresponding header: imm8:0xCA is binary 11001010 in the "Bitwise blend" column:

Bitwise Ternary Logic Truth table
A0	A1	A2	Double AND (imm8=0x80)	Double OR (imm8=0xFE)	Bitwise blend (imm8=0xCA)
0	0	0	0	0	0
0	0	1	0	1	1
0	1	0	0	1	0
0	1	1	0	1	1
1	0	0	0	1	0
1	0	1	0	1	0
1	1	0	0	1	1
1	1	1	1	1	1

Uses

The number of uses is significant: anywhere that three logical bitwise operations are used in algorithms. Carry-save, SHA-1 SHA-2, MD5, and exactly-one and exactly-two bitcounting used in Harley-Seal Popcount.^[3] vpternlog speeds up MD5 by 20%^[4]

Implementations

Although unusual due to the high cost in hardware this instruction is found in a number of instruction set architectures

The 1985 Amiga blitter capability in Agnus: the 8-bit immediate was termed "minterm", and the operation was memory-to-memory.^[5]
The AVX-512 extension calls it vpternlog^[6]
Power ISA v3.1 calls the instruction xxeval.^[7]
Intel Larrabee also implemented this instruction as vpternlog: Tom Forsyth explains, amusingly, the Intel test engineers being happy to have one instruction to test rather than 256.^[8]^[9]^[10]^[11]