# `vpkshss` — Vector Pack Signed Half Word Signed Saturate > **Category:** [VMX (Altivec)](../categories/vmx.md) · **Form:** [VX](../forms/VX.md) · **Opcode:** `0x1000018e` ## Assembler Mnemonics | Mnemonic | XML entry | Flags | Description | | --- | --- | --- | --- | | `vpkshss` | `vpkshss` | — | Vector Pack Signed Half Word Signed Saturate | | `vpkshss128` | `vpkshss128` | — | Vector128 Pack Signed Half Word Signed Saturate | ## Syntax ```asm vpkshss [VD], [VA], [VB] vpkshss128 [VD], [VA], [VB] ``` ## Encoding ### `vpkshss` — form `VX` - **Opcode word:** `0x1000018e` - **Primary opcode (bits 0–5):** `4` - **Extended opcode:** `398` - **Synchronising:** no | Bits | Field | Meaning | | --- | --- | --- | | 0–5 | `OPCD` | primary opcode (4) | | 6–10 | `VRT/VD` | destination vector register | | 11–15 | `VRA/VA` | source A vector register | | 16–20 | `VRB/VB` | source B vector register | | 21–31 | `XO` | extended opcode (11 bits) | ### `vpkshss128` — form `VX128` - **Opcode word:** `0x14000200` - **Primary opcode (bits 0–5):** `5` - **Extended opcode:** `512` - **Synchronising:** no | Bits | Field | Meaning | | --- | --- | --- | | 0–5 | `OPCD` | primary opcode (4 or 5) | | 6–10 | `VD128l` | destination low 5 bits | | 11–15 | `VA128l` | source A low 5 bits | | 16–20 | `VB128l` | source B low 5 bits | | 21 | `VA128H` | source A high bit | | 22 | `—` | reserved | | 23–25 | `VC` | optional VC / XO sub-field | | 26 | `VA128h` | source A middle bit | | 27 | `—` | reserved | | 28–29 | `VD128h` | destination high 2 bits | | 30–31 | `VB128h` | source B high 2 bits | ## Operands | Field | Role | Description | | --- | --- | --- | | `VA` | vpkshss: read; vpkshss128: read | Source A vector register. | | `VB` | vpkshss: read; vpkshss128: read | Source B vector register. | | `VD` | vpkshss: write; vpkshss128: write | Destination vector register. | | `VSCR` | vpkshss: write; vpkshss128: write | Vector Status and Control Register (NJ/SAT bits). | ## Register Effects ### `vpkshss` - **Reads (always):** `VA`, `VB` - **Reads (conditional):** _none_ - **Writes (always):** `VD`, `VSCR` - **Writes (conditional):** _none_ ### `vpkshss128` - **Reads (always):** `VA`, `VB` - **Reads (conditional):** _none_ - **Writes (always):** `VD`, `VSCR` - **Writes (conditional):** _none_ ## Status-Register Effects - `vpkshss`: **VSCR[SAT]** may be stickied on saturating vector operations. - `vpkshss128`: **VSCR[SAT]** may be stickied on saturating vector operations. ## Operation (pseudocode) ``` ; Pseudocode derives directly from the xenia-rs interpreter ; arm (see Implementation References). Operation semantics: ; - Read source operands from the fields listed under Operands. ; - Apply the arithmetic / logical / memory action described ; in the Description field above. ; - Write results to the destination register(s); update any ; status bits enumerated under Status-Register Effects. ; Consult the IBM AIX reference link under IBM Reference for ; canonical PPC-style pseudocode where xenia's expression is ; terse. ``` ## C Translation Example ```c /* C translation: the xenia-rs interpreter arm below in */ /* Implementation References is the authoritative semantic */ /* snapshot. Translate it line-by-line: */ /* - ctx.gpr[N] -> r[N] (or f[]/v[] for FPRs/VRs) */ /* - mem.read_u*/write_u* -> mem_read_u*_be / mem_write_u*_be */ /* - ctx.update_cr_signed(fld, v) -> update_cr_signed(fld, v) */ /* - ctx.xer_ca / xer_ov / xer_so -> xer.CA / xer.OV / xer.SO */ /* The Register Effects and Status-Register Effects tables above */ /* enumerate every side effect a faithful translation must emit. */ ``` ## Implementation References **`vpkshss`** - xenia-canary XML: [`tools/ppc-instructions.xml` — search for `mnem="vpkshss"`](../../xenia-canary/tools/ppc-instructions.xml) - xenia-canary emit: [`src/xenia/cpu/ppc/ppc_emit_altivec.cc:1845`](../../xenia-canary/src/xenia/cpu/ppc/ppc_emit_altivec.cc#L1845) - xenia-rs opcode: [`crates/xenia-cpu/src/opcode.rs:113`](../../xenia-rs/crates/xenia-cpu/src/opcode.rs#L113) - xenia-rs decoder: [`crates/xenia-cpu/src/decoder.rs:471`](../../xenia-rs/crates/xenia-cpu/src/decoder.rs#L471) - xenia-rs interpreter: [`crates/xenia-cpu/src/interpreter.rs:4070-4082`](../../xenia-rs/crates/xenia-cpu/src/interpreter.rs#L4070-L4082)
xenia-rs interpreter body (frozen snapshot) ```rust PpcOpcode::vpkshss | PpcOpcode::vpkshss128 => { let is_128 = matches!(instr.opcode, PpcOpcode::vpkshss128); let (ra, rb, rd) = if is_128 { (instr.va128(), instr.vb128(), instr.vd128()) } else { (instr.ra(), instr.rb(), instr.rd()) }; let a = crate::vmx::as_i16x8(ctx.vr[ra]); let b = crate::vmx::as_i16x8(ctx.vr[rb]); let mut r = [0i8; 16]; let mut sat = false; for i in 0..8 { let (v, s) = crate::vmx::sat_i16_to_i8(a[i]); r[i] = v; sat |= s; } for i in 0..8 { let (v, s) = crate::vmx::sat_i16_to_i8(b[i]); r[8 + i] = v; sat |= s; } if sat { ctx.set_vscr_sat(true); } ctx.vr[rd] = crate::vmx::from_i8x16(r); ctx.pc += 4; } ```
**`vpkshss128`** - xenia-canary XML: [`tools/ppc-instructions.xml` — search for `mnem="vpkshss128"`](../../xenia-canary/tools/ppc-instructions.xml) - xenia-canary emit: [`src/xenia/cpu/ppc/ppc_emit_altivec.cc:1848`](../../xenia-canary/src/xenia/cpu/ppc/ppc_emit_altivec.cc#L1848) - xenia-rs opcode: [`crates/xenia-cpu/src/opcode.rs:113`](../../xenia-rs/crates/xenia-cpu/src/opcode.rs#L113) - xenia-rs decoder: [`crates/xenia-cpu/src/decoder.rs:618`](../../xenia-rs/crates/xenia-cpu/src/decoder.rs#L618) - xenia-rs interpreter: [`crates/xenia-cpu/src/interpreter.rs:4070-4082`](../../xenia-rs/crates/xenia-cpu/src/interpreter.rs#L4070-L4082)
xenia-rs interpreter body (frozen snapshot) ```rust PpcOpcode::vpkshss | PpcOpcode::vpkshss128 => { let is_128 = matches!(instr.opcode, PpcOpcode::vpkshss128); let (ra, rb, rd) = if is_128 { (instr.va128(), instr.vb128(), instr.vd128()) } else { (instr.ra(), instr.rb(), instr.rd()) }; let a = crate::vmx::as_i16x8(ctx.vr[ra]); let b = crate::vmx::as_i16x8(ctx.vr[rb]); let mut r = [0i8; 16]; let mut sat = false; for i in 0..8 { let (v, s) = crate::vmx::sat_i16_to_i8(a[i]); r[i] = v; sat |= s; } for i in 0..8 { let (v, s) = crate::vmx::sat_i16_to_i8(b[i]); r[8 + i] = v; sat |= s; } if sat { ctx.set_vscr_sat(true); } ctx.vr[rd] = crate::vmx::from_i8x16(r); ctx.pc += 4; } ```
## Special Cases & Edge Conditions - **Signed half-word → signed byte saturating pack.** Each of the 16 input half-word lanes (8 from `VA`, 8 from `VB`) is clamped to the `int8` range `[−128, +127]`. Values outside that range produce the nearest extreme and **set the sticky `VSCR[SAT]`** bit. - **Lane-count doubling.** 8+8 = 16 half-word lanes → 16 byte lanes in `VD`. - **Big-endian ordering.** `VA`'s 8 half-words fill `VD.b[0..7]`; `VB`'s 8 fill `VD.b[8..15]`. - **Signed vs. unsigned output.** `vpkshss` has signed input and signed output. Compare with [`vpkshus`](vpkshus.md), which keeps signed input but clamps to `uint8` (`[0, 255]`). - **`VSCR[SAT]` is sticky.** Once set it remains set until an `mtvscr` clears it. Software that needs a per-block saturation signal must clear before the kernel and test after. - **No `Rc`, no XER / FPSCR.** - **VMX128 sibling [`vpkshss128`](vpkshss128.md).** Same semantics, wider register file. ## Related Instructions - [`vpkshus`](vpkshus.md) — signed → unsigned saturating (same half-word input). - [`vpkuhus`](vpkuhus.md), [`vpkuhum`](vpkuhum.md) — unsigned half-word input, unsigned byte output (saturating / modulo). - [`vpkswss`](vpkswss.md), [`vpkswus`](vpkswus.md) — the word → half-word analogues. - [`vupkhsb`](vupkhsb.md), [`vupklsb`](vupklsb.md) — the inverse unpacks that sign-extend bytes back to half-words. - [`vaddsbs`](vaddsbs.md), [`vsubsbs`](vsubsbs.md) — other sources of byte-saturating arithmetic. ## IBM Reference - [AIX 7.3 — `vpkshss` (Vector Pack Signed Half Word Signed Saturate)](https://www.ibm.com/docs/en/aix/7.3.0?topic=set-vpkshss-vector-pack-signed-half-word-signed-saturate-instruction) - [IBM AltiVec Technology Programmer's Interface Manual, Chapter 6 — Permute and Formatting](https://www.nxp.com/docs/en/reference-manual/ALTIVECPIM.pdf)