# `addx` — Add > **Category:** [Integer ALU](../categories/alu.md) · **Form:** [XO](../forms/XO.md) · **Opcode:** `0x7c000214` ## Assembler Mnemonics | Mnemonic | XML entry | Flags | Description | | --- | --- | --- | --- | | `add` | `addx` | — | Add | | `addo` | `addx` | OE=1 | Add | | `add.` | `addx` | Rc=1 | Add | | `addo.` | `addx` | OE=1, Rc=1 | Add | ## Syntax ```asm add[OE][Rc] [RD], [RA], [RB] ``` ## Encoding ### `addx` — form `XO` - **Opcode word:** `0x7c000214` - **Primary opcode (bits 0–5):** `31` - **Extended opcode:** `266` - **Synchronising:** no | Bits | Field | Meaning | | --- | --- | --- | | 0–5 | `OPCD` | primary opcode (31) | | 6–10 | `RT` | destination GPR | | 11–15 | `RA` | source A | | 16–20 | `RB` | source B | | 21 | `OE` | overflow-enable flag | | 22–30 | `XO` | extended opcode (9 bits) | | 31 | `Rc` | record-form flag | ## Operands | Field | Role | Description | | --- | --- | --- | | `RA` | addx: read | Source GPR (`r0`–`r31`). | | `RB` | addx: read | Source GPR. | | `RD` | addx: write | Destination GPR. | | `OE` | addx: write (conditional) | Overflow-enable bit. When 1, the instruction updates `XER[OV]` and stickies `XER[SO]` on signed overflow. | | `CR` | addx: write (conditional) | Condition-register update. When `Rc=1`, CR field 0 (or CR6 for vector compares, CR1 for FPU) is updated from the result. | ## Register Effects ### `addx` - **Reads (always):** `RA`, `RB` - **Reads (conditional):** _none_ - **Writes (always):** `RD` - **Writes (conditional):** `OE`, `CR` ## Status-Register Effects - `addx`: **CR0** ← signed-compare(result, 0) with `SO ← XER[SO]`, when `Rc=1`.; **XER[OV]** ← signed-overflow(result); **XER[SO]** stickies, when `OE=1`. ## Operation (pseudocode) ``` RT <- (RA) + (RB) ``` ## C Translation Example ```c /* add / add. / addo / addo. (XO-form) */ uint64_t a = r[insn.RA], b = r[insn.RB]; uint64_t result = a + b; r[insn.RT] = result; if (insn.OE) { bool ov = (~(a ^ b) & (a ^ result)) >> 63; if (ov) { xer.OV = 1; xer.SO = 1; } else xer.OV = 0; } if (insn.Rc) update_cr0_signed((int64_t)result); ``` ## Implementation References **`addx`** - xenia-canary XML: [`tools/ppc-instructions.xml` — search for `mnem="addx"`](../../xenia-canary/tools/ppc-instructions.xml) - xenia-canary emit: [`src/xenia/cpu/ppc/ppc_emit_alu.cc:50`](../../xenia-canary/src/xenia/cpu/ppc/ppc_emit_alu.cc#L50) - xenia-rs opcode: [`crates/xenia-cpu/src/opcode.rs:8`](../../xenia-rs/crates/xenia-cpu/src/opcode.rs#L8) - xenia-rs decoder: [`crates/xenia-cpu/src/decoder.rs:875`](../../xenia-rs/crates/xenia-cpu/src/decoder.rs#L875) - xenia-rs interpreter: [`crates/xenia-cpu/src/interpreter.rs:175-189`](../../xenia-rs/crates/xenia-cpu/src/interpreter.rs#L175-L189)

xenia-rs interpreter body (frozen snapshot)

```rust PpcOpcode::addx => { // PPCBUG-012+020: 32-bit ABI writeback truncation + CR0 i32 view. let ra32 = ctx.gpr[instr.ra()] as u32; let rb32 = ctx.gpr[instr.rb()] as u32; let result32 = ra32.wrapping_add(rb32); ctx.gpr[instr.rd()] = result32 as u64; if instr.oe() { let true_sum = (ra32 as i32 as i128) + (rb32 as i32 as i128); overflow::apply(ctx, true_sum != (result32 as i32) as i128); } if instr.rc_bit() { ctx.update_cr_signed(0, result32 as i32 as i64); } ctx.pc += 4; } ```

## Extended Pseudocode ``` RT <- (RA) + (RB) ; modulo 2^64, carry discarded if OE then XER[OV] <- (~(RA ^ RB) & (RA ^ RT))[0] ; signed overflow: same-sign inputs, opposite-sign result XER[SO] <- XER[SO] | XER[OV] if Rc then CR0[LT,GT,EQ] <- signed_compare(RT, 0) ; 64-bit comparison on the Xenon CR0[SO] <- XER[SO] ``` ## Special Cases & Edge Conditions - **No trap on overflow.** `addo` / `addo.` record overflow in `XER[OV]` and sticky-set `XER[SO]`. A trap can only be produced by a separate `td`/`tw` instruction examining the result. - **Signed-overflow predicate.** Overflow occurs iff both addends share a sign bit and the result has the opposite sign bit: `OV = ((~(a ^ b)) & (a ^ rt)) >> 63`. Unsigned carry is *not* tracked — use [`addcx`](addcx.md) when you need `XER[CA]`. - **`XER[SO]` is sticky.** Once set, it remains set until cleared by `mcrxr`. The `.` record forms copy it into `CR0[SO]`. - **64-bit CR update on Xenon.** The Xbox 360 Xenon CPU is 64-bit, so `add.` compares the full 64-bit result against zero. **Xenia-rs presently truncates to 32 bits** before the CR update (`result as i32 as i64` in [`interpreter.rs:95`](../../xenia-rs/crates/xenia-cpu/src/interpreter.rs#L95)). If your translator must match xenia bit-for-bit, emit a 32-bit compare; if it must be spec-correct, emit a 64-bit compare. Most Xbox 360 object code works either way because results that overflow 32 bits are rare outside of explicit 64-bit math. - **OE overflow detection not emulated in xenia-rs.** The `addo` / `addo.` branch in `interpreter.rs` is a `TODO` stub. A faithful translator should still emit the overflow check — titles rarely observe `XER[OV]`, but it's occasionally used by profiling / sanity-checking code paths. - **Operand aliasing.** `add r3, r3, r3`, `add r3, r3, r4`, `add r3, r4, r3` are all legal. The addition reads both source operands before writing `RT`. - **No immediate form.** For `RT = RA + imm` use [`addi`](addi.md) / [`addis`](addis.md). Those are distinct opcodes, not a flag on `add`. ## Related Instructions - [`addcx`](addcx.md) — produces the carry-out in `XER[CA]`. - [`addex`](addex.md) — sums `(RA) + (RB) + XER[CA]` (carry-in chain). - [`addmex`](addmex.md), [`addzex`](addzex.md) — add to `−1` or `0` with carry-in (used to propagate borrows across multiword subtracts). - [`addi`](addi.md), [`addis`](addis.md) — D-form immediate adds; no `Rc`/`OE`. - [`addic`](addic.md), [`addicx`](addicx.md) — D-form adds that set `XER[CA]`. - [`subfx`](subfx.md) — the dual: `RT ← (RB) − (RA)`. - [`negx`](negx.md) — two's-complement negate. ## IBM Reference - [AIX 7.3 — `add` (Add)](https://www.ibm.com/docs/en/aix/7.3.0?topic=set-add-instruction) - [PowerISA v2.07B, Book I, §3.3.8 — Fixed-Point Arithmetic Instructions](https://openpowerfoundation.org/specifications/isa/) (overflow predicate, CR0 / `XER[SO]` semantics).