iop(s1 ? vreg[rs1][i] : sreg[rs1],
s2 ? vreg[rs2][i] : sreg[rs2]); // for insts with 2 inputs
-
-
## MAXVECTORDEPTH
MAXVECTORDEPTH is the same concept as MVL in RVV. However in Simple-V,
(in each individual register) is so that each SIMD element may optionally be
predicated.
-Example:
-
-* RV32 assumed
-* CSRintbitwidth[2] = 010 # integer r2 is 16-bit
-* CSRintvlength[2] = 3 # integer r2 is a vector of length 3
-* vsetl rs1, 5 # set the vector length to 5
-
-This is interpreted as follows:
-
-* Given that the context is RV32, ELEN=32.
-* With ELEN=32 and bitwidth=16, the number of SIMD elements is 2
-* Therefore the actual vector length is up to *six* elements
-
-So when using an operation that uses r2 as a source (or destination)
-the operation is carried out as follows:
-
-* 16-bit operation on r2(15..0) - vector element index 0
-* 16-bit operation on r2(31..16) - vector element index 1
-* 16-bit operation on r3(15..0) - vector element index 2
-* 16-bit operation on r3(31..16) - vector element index 3
-* 16-bit operation on r4(15..0) - vector element index 4
-* 16-bit operation on r4(31..16) **NOT** carried out due to length being 5
-
-Predication has been left out of the above example for simplicity.
+An example of how to subdivide the register file when bitwidth != default
+is given in the section "Virtual Register Reordering".
# Example of vector / vector, vector / scalar, scalar / scalar => vector add
# P-Ext ISA
-## 16-bit Arithmetic
-
-| Mnemonic | 16-bit Instruction | Simple-V Equivalent |
-| ------------------ | ------------------------- | ------------------- |
-| ADD16 rt, ra, rb | add | RV ADD (bitwidth=16) |
-| RADD16 rt, ra, rb | Signed Halving add | |
-| URADD16 rt, ra, rb | Unsigned Halving add | |
-| KADD16 rt, ra, rb | Signed Saturating add | |
-| UKADD16 rt, ra, rb | Unsigned Saturating add | |
-| SUB16 rt, ra, rb | sub | RV SUB (bitwidth=16) |
-| RSUB16 rt, ra, rb | Signed Halving sub | |
-| URSUB16 rt, ra, rb | Unsigned Halving sub | |
-| KSUB16 rt, ra, rb | Signed Saturating sub | |
-| UKSUB16 rt, ra, rb | Unsigned Saturating sub | |
-| CRAS16 rt, ra, rb | Cross Add & Sub | |
-| RCRAS16 rt, ra, rb | Signed Halving Cross Add & Sub | |
-| URCRAS16 rt, ra, rb| Unsigned Halving Cross Add & Sub | |
-| KCRAS16 rt, ra, rb | Signed Saturating Cross Add & Sub | |
-| UKCRAS16 rt, ra, rb| Unsigned Saturating Cross Add & Sub | |
-| CRSA16 rt, ra, rb | Cross Sub & Add | |
-| RCRSA16 rt, ra, rb | Signed Halving Cross Sub & Add | |
-| URCRSA16 rt, ra, rb| Unsigned Halving Cross Sub & Add | |
-| KCRSA16 rt, ra, rb | Signed Saturating Cross Sub & Add | |
-| UKCRSA16 rt, ra, rb| Unsigned Saturating Cross Sub & Add | |
-
-## 8-bit Arithmetic
-
-| Mnemonic | 16-bit Instruction | Simple-V Equivalent |
-| ------------------ | ------------------------- | ------------------- |
-| ADD8 rt, ra, rb | add | RV ADD (bitwidth=8)|
-| RADD8 rt, ra, rb | Signed Halving add | |
-| URADD8 rt, ra, rb | Unsigned Halving add | |
-| KADD8 rt, ra, rb | Signed Saturating add | |
-| UKADD8 rt, ra, rb | Unsigned Saturating add | |
-| SUB8 rt, ra, rb | sub | RV SUB (bitwidth=8)|
-| RSUB8 rt, ra, rb | Signed Halving sub | |
-| URSUB8 rt, ra, rb | Unsigned Halving sub | |
+This section has been moved to its own page [[p_comparative_analysis]]
# Exceptions
| r5 | (32..0) |
| r6 | (32..0) |
| r7 | (32..0) |
+| .. | (32..0) |
+| r31| (32..0) |
## Vectorised CSR
## Virtual Register Reordering:
+This example assumes the above Vector Length CSR table
+
| Reg Num | Bits (0) | Bits (1) | Bits (2) |
| ------- | -------- | -------- | -------- |
| r0 | (32..0) | (32..0) |
| r4 | (32..0) | (32..0) | (32..0) |
| r7 | (32..0) |
+This example goes a little further and illustrates the effect that a
+bitwidth CSR has been set on a register
+
+* RV32 assumed
+* CSRintbitwidth[2] = 010 # integer r2 is 16-bit
+* CSRintvlength[2] = 3 # integer r2 is a vector of length 3
+* vsetl rs1, 5 # set the vector length to 5
+
+This is interpreted as follows:
+
+* Given that the context is RV32, ELEN=32.
+* With ELEN=32 and bitwidth=16, the number of SIMD elements is 2
+* Therefore the actual vector length is up to *six* elements
+
+So when using an operation that uses r2 as a source (or destination)
+the operation is carried out as follows:
+
+* 16-bit operation on r2(15..0) - vector element index 0
+* 16-bit operation on r2(31..16) - vector element index 1
+* 16-bit operation on r3(15..0) - vector element index 2
+* 16-bit operation on r3(31..16) - vector element index 3
+* 16-bit operation on r4(15..0) - vector element index 4
+* 16-bit operation on r4(31..16) **NOT** carried out due to length being 5
+
+Predication has been left out of the above example for simplicity, however
+predication is ANDed with the latter stages (vsetl not equal to maximum
+capacity).
+
+Note also that it is entirely an implementor's choice as to whether to have
+actual separate ALUs down to the minimum bitwidth, or whether to have something
+more akin to traditional SIMD (at any level of subdivision: 8-bit SIMD
+operations carried out 32-bits at a time is perfectly acceptable, as is
+8-bit SIMD operations carried out 16-bits at a time requiring two ALUs).
+Regardless of the internal parallelism choice, *predication must
+still be respected*, making Simple-V in effect the "consistent public API".
+
## Example Instruction translation: <a name="example_translation"></a>
Instructions "ADD r2 r4 r4" would result in three instructions being
--- /dev/null
+# P-Ext ISA
+
+[[!toc ]]
+
+# 16-bit Arithmetic
+
+| Mnemonic | 16-bit Instruction | Simple-V Equivalent |
+| ------------------ | ------------------------- | ------------------- |
+| ADD16 rt, ra, rb | add | RV ADD (bitwidth=16) |
+| RADD16 rt, ra, rb | Signed Halving add | |
+| URADD16 rt, ra, rb | Unsigned Halving add | |
+| KADD16 rt, ra, rb | Signed Saturating add | |
+| UKADD16 rt, ra, rb | Unsigned Saturating add | |
+| SUB16 rt, ra, rb | sub | RV SUB (bitwidth=16) |
+| RSUB16 rt, ra, rb | Signed Halving sub | |
+| URSUB16 rt, ra, rb | Unsigned Halving sub | |
+| KSUB16 rt, ra, rb | Signed Saturating sub | |
+| UKSUB16 rt, ra, rb | Unsigned Saturating sub | |
+| CRAS16 rt, ra, rb | Cross Add & Sub | |
+| RCRAS16 rt, ra, rb | Signed Halving Cross Add & Sub | |
+| URCRAS16 rt, ra, rb| Unsigned Halving Cross Add & Sub | |
+| KCRAS16 rt, ra, rb | Signed Saturating Cross Add & Sub | |
+| UKCRAS16 rt, ra, rb| Unsigned Saturating Cross Add & Sub | |
+| CRSA16 rt, ra, rb | Cross Sub & Add | |
+| RCRSA16 rt, ra, rb | Signed Halving Cross Sub & Add | |
+| URCRSA16 rt, ra, rb| Unsigned Halving Cross Sub & Add | |
+| KCRSA16 rt, ra, rb | Signed Saturating Cross Sub & Add | |
+| UKCRSA16 rt, ra, rb| Unsigned Saturating Cross Sub & Add | |
+
+# 8-bit Arithmetic
+
+| Mnemonic | 16-bit Instruction | Simple-V Equivalent |
+| ------------------ | ------------------------- | ------------------- |
+| ADD8 rt, ra, rb | add | RV ADD (bitwidth=8)|
+| RADD8 rt, ra, rb | Signed Halving add | |
+| URADD8 rt, ra, rb | Unsigned Halving add | |
+| KADD8 rt, ra, rb | Signed Saturating add | |
+| UKADD8 rt, ra, rb | Unsigned Saturating add | |
+| SUB8 rt, ra, rb | sub | RV SUB (bitwidth=8)|
+| RSUB8 rt, ra, rb | Signed Halving sub | |
+| URSUB8 rt, ra, rb | Unsigned Halving sub | |
+
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