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xenia-rs/migration/project-root/ppc-manual/memory/dcbz.md
MechaCat02 e6d43a23ac chore: add migration/ bundle for cross-machine setup 
Bundles state that lives OUTSIDE the xenia-rs repo so a fresh clone on
another machine can be brought up to identical configuration via
migration/setup.sh:

  - claude-memory/             ~/.claude/projects/-home-fabi-RE-Project-Sylpheed/memory/
                               (103 files, 1.1 MB - MEMORY.md + every
                                project_xenia_rs_*.md from audits
                                addis_signext through audit-058)
  - project-root/dot-claude/   <project-root>/.claude/settings.json
                               (Stop hook + permissions)
  - project-root/ppc-manual/   <project-root>/ppc-manual/
                               (PowerPC reference docs, 397 files, 3.7 MB)
  - project-root/run-canary.sh <project-root>/run-canary.sh
  - README.md                  Human-readable setup checklist
  - setup.sh                   Idempotent installer (also reclones
                               xenia-canary at pinned HEAD 6de80dffe)
  - MANIFEST.md                Per-file mapping + per-file-not-bundled
                               restoration recipe

Excluded from bundle (not shippable via git):
  - Sylpheed ISO (7.8 GB; copyright; manual copy required)
  - sylpheed.db (395 MB; regenerable from XEX via analysis tooling)
  - target/ build artifacts (rebuild on target)
  - audit-runs probe firehoses (.log/.stdout/.stderr ~11 GB; rerun if needed)
  - audit-runs memory dumps (.bin ~4.5 GB; rerun audit-026/027/029 if needed)
  - xenia-canary checkout (setup.sh reclones from
    git.mc02.dev/fabi/Xenia-Canary.git at HEAD 6de80dffe)

Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>
2026-05-10 21:38:38 +02:00

8.2 KiB
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dcbz — Data Cache Block Clear to Zero

Category: Memory · Form: DCBZ · Opcode: 0x7c0007ec

Assembler Mnemonics

Mnemonic XML entry Flags Description
dcbz dcbz Data Cache Block Clear to Zero
dcbz128 dcbz128 Data Cache Block Clear to Zero 128

Syntax

dcbz [RA0], [RB]
dcbz128 [RA0], [RB]

Encoding

dcbz — form DCBZ

  • Opcode word: 0x7c0007ec
  • Primary opcode (bits 05): 31
  • Extended opcode: 1014
  • Synchronising: no
Bits Field Meaning
05 OPCD primary opcode (31)
610 reserved
1115 RA base register (0 ⇒ literal 0)
1620 RB offset register
2130 XO extended opcode (1014 for dcbz / 1010 for dcbz128)
31 reserved

dcbz128 — form DCBZ

  • Opcode word: 0x7c2007ec
  • Primary opcode (bits 05): 31
  • Extended opcode: 1014
  • Synchronising: no
Bits Field Meaning
05 OPCD primary opcode (31)
610 reserved
1115 RA base register (0 ⇒ literal 0)
1620 RB offset register
2130 XO extended opcode (1014 for dcbz / 1010 for dcbz128)
31 reserved

Operands

Field Role Description
RA0 dcbz: read; dcbz128: read Source GPR; when the encoded register number is 0 the operand is the literal 64-bit zero, not r0.
RB dcbz: read; dcbz128: read Source GPR.

Register Effects

dcbz

  • Reads (always): RA0, RB
  • Reads (conditional): none
  • Writes (always): none
  • Writes (conditional): none

dcbz128

  • Reads (always): RA0, RB
  • Reads (conditional): none
  • Writes (always): none
  • Writes (conditional): none

Status-Register Effects

No condition-register or status-register effects.

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 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

dcbz

xenia-rs interpreter body (frozen snapshot) 
        PpcOpcode::dcbz => {
            // Zero 32 bytes at effective address
            let ea = if instr.ra() == 0 { 0u64 } else { ctx.gpr[instr.ra()] };
            let ea = (ea.wrapping_add(ctx.gpr[instr.rb()]) as u32) & !31;
            if let Some(t) = ctx.reservation_table.as_ref().filter(|t| t.is_enabled()) {
                if t.has_active_reservers() { t.invalidate_for_write(ea); }
            }
            for i in 0..8 {
                mem.write_u32(ea + i * 4, 0);
            }
            ctx.pc += 4;
        }

dcbz128

xenia-rs interpreter body (frozen snapshot) 
        PpcOpcode::dcbz128 => {
            // Zero 128 bytes
            let ea = if instr.ra() == 0 { 0u64 } else { ctx.gpr[instr.ra()] };
            let ea = (ea.wrapping_add(ctx.gpr[instr.rb()]) as u32) & !127;
            if let Some(t) = ctx.reservation_table.as_ref().filter(|t| t.is_enabled()) {
                if t.has_active_reservers() { t.invalidate_for_write(ea); }
            }
            for i in 0..32 {
                mem.write_u32(ea + i * 4, 0);
            }
            ctx.pc += 4;
        }

Special Cases & Edge Conditions

  • Cache-line size mismatch. Stock PowerPC dcbz zeroes one architectural cache line — 32 bytes on classic POWER, but the Xenon's L1 line is 128 bytes. Microsoft added dcbz128 (encoded with bit-9 set so RT field reads as 1) to clear a true Xenon line in one instruction. Most Xbox 360 code therefore emits dcbz128; a stray dcbz only zeroes 32 bytes and silently leaves the rest of the line uncleared.
  • Alignment is forced via mask. The effective address is masked by ~31 (dcbz) or ~127 (dcbz128) before writing — the low bits are dropped, not validated. Calling dcbz r0, r3 with r3 = 0x10037 writes zeros to 0x10000..0x1007F, not 0x10037..0x100B6.
  • No memory read; pure write. Real hardware allocates the line in cache and may skip a read-from-memory fill ("cache-line zero" optimisation). Xenia simulates the architectural effect — 32 (or 128) bytes of zero in target memory — without modelling cache state.
  • RA0 semantics. RA = 0 selects literal zero as the base, so dcbz128 0, RB zeros the line containing address RB. The update form does not exist for cache-control instructions.
  • Block-fill idiom. Compilers and hand-written copy loops pair dcbz128 with stvx / stw sequences to avoid the cache-line read-allocate that a cold store would trigger. Skipping the read is the entire point.
  • Privilege. dcbz is unprivileged (problem-state); does not require supervisor mode. It can fault on protection or unmapped memory like an ordinary store.
  • Sequencing. Not synchronising. Pair with sync / lwsync when the zeros must be visible before subsequent loads on another thread.

Related Instructions

  • dcbf — flush a line back to memory.
  • dcbst — store-through (write-back without invalidate).
  • dcbi — invalidate (privileged on most cores).
  • dcbt, dcbtst — touch / touch-for-store hints.
  • icbi — instruction-cache invalidate (companion to data-cache control).
  • stvx, stw — typical pair-mates in block-fill loops.

IBM Reference

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