Section 126.96.36.199 of the Intel Manual covers this with 5 (difficult to digest) paragraphs, for me it's page 74 on the 4 volume set you can download from Intel site or go directly here: https://software.intel.com/sites/default/files/managed/39/c5/325462-sdm-vol-1-2abcd-3abcd.pdf
What these paragraphs say is canonical addresses are anything less than a full 64 bit address. There are different implementations of addressing such as 48 bit or 57 bit. (57-bit requires an extra level of page tables, increasing the cost of page-walks. See https://en.wikipedia.org/wiki/Intel_5-level_paging for more about this new CPU feature that can be left disabled).
A 48-bit implementation would have a high half canonical address starting at
while the lower half would be
Bit 63 to whatever will signify it as a canonical address if you see all ones or all zeros. In a 57-bit implementation I'd immediately know I'm looking at a canonical address when I see 0xFF____ or 0x00____. (The low bit of the top byte is a significant address bit, and the other 7 are copies of it: i.e. correctly sign extended)
Maybe a helpful way to remember this is the word canonical itself means relating to a general rule, or way of doing something. In general, no one needs as many addresses as 64 bits can provide, so they are generally not used. Also if something is according to canon like in Star Trek or comic books, it's the way things were seen or done originally.
Now to answer WHY we have canonical addresses? No one will need to address up to 16 Exabytes (the theoretical limit of a 64 bit machine) so the second paragraph of that manual just says Intel architecture "defines" a 64 bit linear address but it looks like no one will use it. Now just in case, the third paragraph says the implementation will still check those first few bits and if NOT in canonical form, to generate a "general-protection" exception.
The main reason for checking for canonical addresses instead of silently ignoring the upper bits is to make sure software is forward compatible with future hardware that supports more virtual address bits.