# `faddx` — Floating Add

> **Category:** [Floating-Point](../categories/fpu.md) · **Form:** [A](../forms/A.md) · **Opcode:** `0xfc00002a`

<!-- GENERATED: BEGIN -->

## Assembler Mnemonics

| Mnemonic | XML entry | Flags | Description |
| --- | --- | --- | --- |
| `fadd` | `faddx` | — | Floating Add |
| `fadd.` | `faddx` | Rc=1 | Floating Add |

## Syntax

```asm
fadd[Rc] [FD], [FA], [FB]
```

## Encoding

### `faddx` — form `A`

- **Opcode word:** `0xfc00002a`
- **Primary opcode (bits 0–5):** `63`
- **Extended opcode:** `21`
- **Synchronising:** no

| Bits | Field | Meaning |
| --- | --- | --- |
| 0–5 | `OPCD` | primary opcode (59 or 63) |
| 6–10 | `FRT` | destination FPR |
| 11–15 | `FRA` | source A FPR |
| 16–20 | `FRB` | source B FPR |
| 21–25 | `FRC` | source C FPR (multiplier for madd-style ops) |
| 26–30 | `XO` | extended opcode (5 bits) |
| 31 | `Rc` | record-form flag (updates CR1) |

## Operands

| Field | Role | Description |
| --- | --- | --- |
| `FA` | faddx: read | Source A floating-point register (`fr0`–`fr31`). |
| `FB` | faddx: read | Source B floating-point register. |
| `FD` | faddx: write | Destination floating-point register. |
| `CR` | faddx: write (conditional) | Condition-register update. When `Rc=1`, CR field 0 (or CR6 for vector compares, CR1 for FPU) is updated from the result. |
| `FPSCR` | faddx: write | Floating-Point Status and Control Register. |

## Register Effects

### `faddx`

- **Reads (always):** `FA`, `FB`
- **Reads (conditional):** _none_
- **Writes (always):** `FD`, `FPSCR`
- **Writes (conditional):** `CR`

## Status-Register Effects

- `faddx`: **CR1** ← FPSCR[FX, FEX, VX, OX] when `Rc=1`.; **FPSCR** updated per IEEE-754 flags (FX, FEX, FPRF, FR, FI, exceptions).

## Operation (pseudocode)

```
FRT <- FRA + FRB                         ; double-precision
```

## C Translation Example

```c
/* fadd / fadd. — IEEE-754 double-precision add (A-form)            */
f[insn.FRT] = f[insn.FRA] + f[insn.FRB];
if (insn.Rc) update_cr1_from_fpscr();
/* FPSCR[FPRF, FR, FI, FX, exceptions] implicitly updated by the FPU. */
```

## Implementation References

**`faddx`**
- xenia-canary XML: [`tools/ppc-instructions.xml` — search for `mnem="faddx"`](../../xenia-canary/tools/ppc-instructions.xml)
- xenia-canary emit: [`src/xenia/cpu/ppc/ppc_emit_fpu.cc:38`](../../xenia-canary/src/xenia/cpu/ppc/ppc_emit_fpu.cc#L38)
- xenia-rs opcode: [`crates/xenia-cpu/src/opcode.rs:27`](../../xenia-rs/crates/xenia-cpu/src/opcode.rs#L27)
- xenia-rs decoder: [`crates/xenia-cpu/src/decoder.rs:922`](../../xenia-rs/crates/xenia-cpu/src/decoder.rs#L922)
- xenia-rs interpreter: [`crates/xenia-cpu/src/interpreter.rs:2555-2564`](../../xenia-rs/crates/xenia-cpu/src/interpreter.rs#L2555-L2564)
<details><summary>xenia-rs interpreter body (frozen snapshot)</summary>

```rust
        PpcOpcode::faddx => {
            let a = ctx.fpr[instr.ra()];
            let b = ctx.fpr[instr.rb()];
            fpscr::check_invalid_add(ctx, a, b, false);
            let result = a + b;
            ctx.fpr[instr.rd()] = result;
            fpscr::update_after_op(ctx, result, a.is_finite() && b.is_finite());
            if instr.rc_bit() { update_cr1_from_fpscr(ctx); }
            ctx.pc += 4;
        }
```
</details>

<!-- GENERATED: END -->

## Extended Pseudocode

```
FRT <- round(FRA + FRB, FPSCR[RN])                 ; double precision, current rounding mode

; FPSCR side-effects (always)
    FPSCR[FPRF]  <- classify(FRT)                  ; sign / class bits
    FPSCR[FR,FI] <- round_info
    if overflow           then FPSCR[OX]   <- 1; FPSCR[FX] <- 1
    if underflow          then FPSCR[UX]   <- 1; FPSCR[FX] <- 1
    if inexact            then FPSCR[XX]   <- 1; FPSCR[FX] <- 1
    if NaN input or ±∞−±∞ then FPSCR[VXISI]<- 1; FPSCR[FX] <- 1
    FPSCR[FEX] <- any-enabled-exception

if Rc then
    CR1 <- FPSCR[FX, FEX, VX, OX]                  ; the four "summary" bits
```

## Special Cases & Edge Conditions

- **Double precision.** `fadd` always operates on IEEE-754 binary64 regardless of whether either source was produced by a single-precision instruction. Single-precision adds use [`faddsx`](faddsx.md) and automatically round the result to binary32 precision.
- **No immediate / carry / OE.** FPU arithmetic has no immediate forms, no carry, and no overflow-enable bit. `Rc` is the only modifier — it writes `CR1` from the four top FPSCR bits.
- **FPSCR is always updated.** Even the non-record form (`fadd`) updates `FPSCR[FPRF, FR, FI, FX, …]` as a side effect of execution; xenia's interpreter currently **does not** model this, so translations that rely on observing FPSCR bits across a pair of FPU instructions will diverge from hardware. If your translator needs compatible FPSCR state, emit explicit updates — or accept the simplification, which matches real Xbox 360 title behaviour in practice (titles rarely read FPSCR except via `mffs` for exception sanity checks).
- **NaN propagation.** Per IEEE-754, any NaN input produces a NaN output; PowerPC specifies that the *signalling* bit of the result NaN is cleared (quietening a signalling input). Xenia uses host-native `f64 +`, which may preserve the signalling bit on some platforms — assume quietening for correctness.
- **`±∞ − ±∞` is an invalid operation.** Produces a quiet NaN (`QNaN(VXISI)`) and sets `FPSCR[VXISI]`. Xenia emits the host-native NaN.
- **Denormal handling.** Xenon's default mode flushes denormal results to zero (FPSCR[NI] / "non-IEEE mode" bit set at boot). Xenia inherits host semantics by default; if title code explicitly clears NI (rare) you'll get IEEE-compliant denormals from the host FPU.
- **Rounding mode.** `FPSCR[RN]` selects one of four rounding modes (nearest-even, toward 0, toward +∞, toward −∞). Games rarely change RN from the default nearest-even. If your translator needs faithful rounding-mode support emit `fesetround` around the operation.
- **Register encoding.** A-form: `FRT`, `FRA`, `FRB`, `FRC`, `Rc` — but `fadd` ignores `FRC` (the "C" multiplier operand used by `fmadd`-style ops). The `FRC` field is architecturally don't-care but typically encoded as 0.

## Related Instructions

- [`faddsx`](faddsx.md) — single-precision add; result is rounded to binary32 then stored as binary64.
- [`fsubx`](fsubx.md), [`fsubsx`](fsubsx.md) — double / single subtract.
- [`fmulx`](fmulx.md), [`fmulsx`](fmulsx.md) — double / single multiply.
- [`fmaddx`](fmaddx.md), [`fmsubx`](fmsubx.md), [`fnmaddx`](fnmaddx.md), [`fnmsubx`](fnmsubx.md) — fused multiply-add family (single-rounding; preferred for dot products).
- [`mffsx`](mffsx.md), [`mtfsfx`](mtfsfx.md) — read/write FPSCR.

## IBM Reference

- [AIX 7.3 — `fadd` (Floating Add)](https://www.ibm.com/docs/en/aix/7.3.0?topic=set-fa-fadd-floating-add-instruction)
- [PowerISA v2.07B, Book I, Chapter 4 — Floating-Point Processor](https://openpowerfoundation.org/specifications/isa/) (complete FPSCR and NaN-propagation rules).