in advance, accordingly: other strategies are explored in the Appendix
Section "Virtual Memory Page Faults".
+## Vectorised Copy/Move instructions
+
+There is a series of 2-operand instructions involving copying (and
+alteration): C.MV, FMV, FNEG, FABS, FCVT, FSGNJ. These operations all
+follow the same pattern, as it is *both* the source *and* destination
+predication masks that are taken into account. This is different from
+the three-operand arithmetic instructions, where the predication mask
+is taken from the *destination* register, and applied uniformly to the
+elements of the source register(s), element-for-element.
+
+### C.MV Instruction <a name="c_mv"></a>
+
+There is no MV instruction in RV however there is a C.MV instruction.
+It is used for copying integer-to-integer registers (vectorised FMV
+is used for copying floating-point).
+
+If either the source or the destination register are marked as vectors
+C.MV is reinterpreted to be a vectorised (multi-register) predicated
+move operation. The actual instruction's format does not change:
+
+[[!table data="""
+15 12 | 11 7 | 6 2 | 1 0 |
+funct4 | rd | rs | op |
+4 | 5 | 5 | 2 |
+C.MV | dest | src | C0 |
+"""]]
+
+A simplified version of the pseudocode for this operation is as follows:
+
+ function op_mv(rd, rs) # MV not VMV!
+ rd = int_vec[rd].isvector ? int_vec[rd].regidx : rd;
+ rs = int_vec[rs].isvector ? int_vec[rs].regidx : rs;
+ ps = get_pred_val(FALSE, rs); # predication on src
+ pd = get_pred_val(FALSE, rd); # ... AND on dest
+ for (int i = 0, int j = 0; i < VL && j < VL;):
+ if (int_vec[rs].isvec) while (!(ps & 1<<i)) i++;
+ if (int_vec[rd].isvec) while (!(pd & 1<<j)) j++;
+ ireg[rd+j] <= ireg[rs+i];
+ if (int_vec[rs].isvec) i++;
+ if (int_vec[rd].isvec) j++;
+
+Note that:
+
+* elwidth (SIMD) is not covered above
+* ending the loop early in scalar cases (VINSERT, VEXTRACT) is also
+ not covered
+
+There are several different instructions from RVV that are covered by
+this one opcode:
+
+[[!table data="""
+src | dest | predication | op |
+scalar | vector | none | VSPLAT |
+scalar | vector | destination | sparse VSPLAT |
+scalar | vector | 1-bit dest | VINSERT |
+vector | scalar | 1-bit? src | VEXTRACT |
+vector | vector | none | VCOPY |
+vector | vector | src | Vector Gather |
+vector | vector | dest | Vector Scatter |
+vector | vector | src & dest | Gather/Scatter |
+vector | vector | src == dest | sparse VCOPY |
+"""]]
+
+Also, VMERGE may be implemented as back-to-back (macro-op fused) C.MV
+operations with inversion on the src and dest predication for one of the
+two C.MV operations.
+
+Note that in the instance where the Compressed Extension is not implemented,
+MV may be used, but that is a pseudo-operation mapping to addi rd, x0, rs.
+Note that the behaviour is **different** from C.MV because with addi the
+predication mask to use is taken **only** from rd and is applied against
+all elements: rs[i] = rd[i].
+
+### FMV, FNEG and FABS Instructions
+
+These are identical in form to C.MV, except covering floating-point
+register copying. The same double-predication rules also apply.
+However when elwidth is not set to default the instruction is implicitly
+and automatic converted to a (vectorised) floating-point type conversion
+operation of the appropriate size covering the source and destination
+register bitwidths.
+
+(Note that FMV, FNEG and FABS are all actually pseudo-instructions)
+
+### FVCT Instructions
+
+These are again identical in form to C.MV, except that they cover
+floating-point to integer and integer to floating-point. When element
+width in each vector is set to default, the instructions behave exactly
+as they are defined for standard RV (scalar) operations, except vectorised
+in exactly the same fashion as outlined in C.MV.
+
+However when the source or destination element width is not set to default,
+the opcode's explicit element widths are *over-ridden* to new definitions,
+and the opcode's element width is taken as indicative of the SIMD width
+(if applicable i.e. if packed SIMD is requested) instead.
+
+For example FCVT.S.L would normally be used to convert a 64-bit
+integer in register rs1 to a 64-bit floating-point number in rd.
+If however the source rs1 is set to be a vector, where elwidth is set to
+default/2 and "packed SIMD" is enabled, then the first 32 bits of
+rs1 are converted to a floating-point number to be stored in rd's
+first element and the higher 32-bits *also* converted to floating-point
+and stored in the second. The 32 bit size comes from the fact that
+FCVT.S.L's integer width is 64 bit, and with elwidth on rs1 set to
+divide that by two it means that rs1 element width is to be taken as 32.
+
+Similar rules apply to the destination register.
+
# Exceptions
> What does an ADD of two different-sized vectors do in simple-V?
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