Think about this in terms of levels of logic and readability. The first two forms are fine in terms of readability, but both embody priority unnecessarily and will result in more levels of logic. The third form is also not so wonderful by either of these metrics. Lastly, there's no apparent reason to use one-hot coding here over binary coding. Here's how I'd code this:
parameter ALU_ADD = 2'b00;
parameter ALU_AND = 2'b01;
parameter ALU_OR = 2'b10;
parameter ALU_XOR = 2'b11;
reg [1:0] opcode; // 2 bits for binary coding vs. 4 for one-hot
// and later, in your always block:
case (opcode) // synopsys parallel_case
ALU_ADD: alu_out = a + b;
ALU_AND: alu_out = a & b;
ALU_OR: alu_out = a | b;
ALU_XOR: alu_out = a ^ b;
Here I've explicitly assigned values to the ALU opcodes, avoiding "magic numbers" and making it easier for others to understand what's happening. I've also used the case statement and applied a directive that tells my synthesis tool that no more than one expression can be matched, so no priority encoder will be inferred. I didn't name the intermediate signals (alu_add etc.) because these are trivial operations, but I frequently do so when I want convenient access to those signals (seeing their values after simulation in a waveform viewer for example).
You can learn more about using case statements effectively in this article from the excellent Sunburst Design site (no affiliation, just a former student).
Finally, about your question, "Is it better to have code that computes the possible answers all the time then select the answer based on the opcode" -- remember that Verilog is a hardware description language. All the implementations on this page are computing everything all the time anyway. Where they differ is in levels of logic and readability. Take a look at this page, which shows that my implementation has 1 level of logic beyond the operations themselves, where the if-else implementation has 3 additional levels of logic.