Revision as of 11:12, 18 September 2023

Zen 4 is a microarchitecture developed by AMD as a successor to Zen 3. See press release for details: AMD Launches Ryzen 7000 Series Desktop Processors

History

Zen 4 on the roadmap.

Zen 4 was first mentioned by Forrest Norrod during AMD's EPYC One Year Anniversary webinar. During the next horizon event which was held on November 6, 2018, AMD stated that Zen 4 was at the design completion phase.

Products

Preliminary Data! Information presented in this article deal with future products, data, features, and specifications that have yet to be finalized, announced, or released. Information may be incomplete and can change by final release.

Cores using variant Zen 4 uarch:

Architectural Codenames:

Process Technology

Processors implementing Zen 4 are SoCs configured as a Multi-Chip Module or monolithic chip. MCMs consist of a single I/O die and up to 12 Core Complex Dies attached with full-duplex serial point-to-point links. The IOD contains memory controllers, I/O controllers, microcontrollers for security purposes and power management, and other peripherals. The CCDs communicate with peripherals and each other through the Data and Control Fabrics on the I/O die, and each contain a single Core Complex (CCX). The monolithic chips integrate a subset of the IOD facilities and additional peripherals tailored for their target market, a CCX, and a GPU. A CCX contains 8 CPU cores (fewer may be usable on some models) communicating through a shared L3 cache.

("Bergamo" processors configuration TBD.)

The chips are fabricated by TSMC, CCDs and monolithic chips on a 5 nm node, IODs on a 6 nm node.

Architecture

Zen 4 is a 64-bit superscalar, out-of-order, 2-way SMT microarchitecture with advanced dynamic branch prediction, 4-way decoding of x86 instructions with a stack optimizer, multiple caches including an Op cache for decoded instructions and prefetchers for code and data, four integer/address and two floating point instruction schedulers, 3-way address generation, 5-way integer execution. 4-way 256-bit wide floating point execution, a speculative, out-of-order load/store unit capable of up to three loads or two stores per cycle with a 48/88-entry load and 64-entry store queue, write-combining, and 5-level paging with four TLBs and six hardware page table walkers.

Key changes from Zen 3

• AVX-512 instructions support, 256-bit data path^[1]
• L1 and L2 DTLB size increased from 64 to 72 and 2,048 to 3,072 entries
• Op cache size increased from 4,096 to 6,750 Ops per core
• L2 cache doubled from 512 KiB to 1 MiB per core (not all processor models), latency increased from 12 to 14 cycles minimum
• L3 cache average load-to-use latency increased from 46 to 50 cycles
• Five-level paging; Max. physical and linear address size raised from 48 to 52 and 57 bits respectively
• Improved cache load, write and prefetch from/to register (less latency)
• Higher Transistor Density, due to 5nm process
• Capable of higher all-core clockspeeds (shown by AMD to reach 5GHz+ on all cores)
• Larger integer register file (from 192 to 224), floating-point register file (from 160 to 192) and reorder buffer (from 256 to 320 entries)
• REPE CMPSB (sometimes used to implement string comparison) is significantly sped up, processes more than 32 bytes/cycle when operating on L1 data.
• BSF, BSR, and BMI1 instructions BLSI, BLSMSK, BLSR, TZCNT have smaller latency of 1 and x2 throughput (4 insn/cycle).
• Latency and/or throughput of VPERMx, V[P]BROADCASTx, VPMOV{S,Z}Xx instructions improved.
• Some ALU operations on vector registers increased throughput from 2 to 3 ops/cycle.
• Some ALU operations on vector registers (VPABSx,VPHADDx,VPHSUBx,VPSLLx,VPSRLx,VPSRAx,VPACKx,VPSIGNx,VMAXx,VMINx) increased latency by 1 cycle.

Package level changes:

• EPYC 9004 "Genoa": Max. core/thread count 96/192, up from 64/128 on EPYC 7003 "Milan"
• EPYC "Bergamo": Max. 128 cores but preliminary data shows a slightly altered architecture featuring cores that take up less space
• Support for DDR5 memory and PCIe Gen 5
• New sockets AM5 (client), SP5 and SP6 (server), FP7/FP7r2 (mobile)
• APUs: RDNA2-based iGPU with 2 compute units (128 stream processors)

New Instructions

Zen 4 introduced the following ISA enhancements:

• AVX-512 - 512-bit Vector Instructions
  • AVX512F - Foundation (first introduced with Intel Skylake)
  • AVX512CD - Conflict Detection Instructions (Skylake X)
  • AVX512VL - Vector Length Extensions (Skylake X)
  • AVX512DQ - Doubleword and Quadword Instructions (Skylake X)
  • AVX512BW - Byte and Word Instructions (Skylake X)
  • AVX512_IFMA - Integer Fused Multiply-Add (Cannon Lake)
  • AVX512_VBMI - Vector Bit Manipulation Instructions (Cannon Lake)
  • AVX512_VPOPCNTDQ - Vector Population Count Instructions (Ice Lake)
  • AVX512_BITALG - Bit Algorithms (Ice Lake)
  • AVX512_VBMI2 - Vector Bit Manipulation Instructions 2 (Ice Lake)
  • AVX512_VNNI - Vector Neural Network Instructions (Ice Lake)
  • AVX512_BF16 - BFloat16 Instructions (Cooper Lake)
  • Not supported: AVX512ER, AVX512PF (Knights Landing); AVX512 4VNNIW, 4FMAPS (Knights Mill); VP2INTERSECT (Tiger Lake); FP16 (Sapphire Rapids)
• GFNI - Galois Field New Instructions (first introduced with Intel Ice Lake)
  • VGF2P8AFFINEQB - Galois field affine transformation
  • VGF2P8AFFINEINVQB - Galois field affine transformation inverse
  • VGF2P8MULB - Galois field multiply bytes

Memory Hierarchy

Data and Instruction Caches

• L0 Op Cache:
  • Up to 6,750 Ops per core, 8-way set associative
  • 9 Op line size (restrictions apply depending on instruction type)
  • Parity protected
• L1I Cache:
  • 32 KiB per core, 8-way set associative
  • 64 B line size
  • Parity protected
• L1D Cache:
  • 32 KiB per core, 8-way set associative
  • 64 B line size
  • Write-back policy
  • 4-5 cycles latency for Int
  • 7-8 cycles latency for FP
  • ECC
• L2 Cache:
  • 512 KiB or 1 MiB per core (varies by processor model), 8-way set associative
  • 64 B line size
  • Write-back policy
  • Inclusive of L1
  • ≥ 14 cycles latency
  • DEC-TED ECC, tag & state arrays SEC-DED
• L3 Cache:
  • "Genoa": up to 32 MiB/CCX (8 cores), up to 384 MiB total
  • Shared by all cores in the CCX, configurable
  • 16-way set associative
  • 64 B line size
  • L2 victim cache
  • Write-back policy
  • 50 cycles average load-to-use latency
  • DEC-TED ECC, tag array & shadow tags SEC-DED
  • QoS Monitoring and Enforcement with BMEC, L3RR, L3SBE

Translation Lookaside Buffers

• ITLB
  • 64 entry L1 TLB, fully associative
    • 4-Kbyte, 2-Mbyte, 1-Gbyte page sizes
  • 512 entry L2 TLB, 8-way set associative
    • 4-Kbyte, 2-Mbyte, and 4-Mbyte pages
  • Parity protected
• DTLB
  • 72 entry L1 TLB, fully associative
    • 4-Kbyte, 16-Kbyte, 2-Mbyte, 1-Gbyte page sizes
  • 3,072 entry L2 TLB, 24-way set associative
    • 4-Kbyte, 16-Kbyte, 2-Mbyte, and 4-Mbyte pages, PDEs to speed up table walks
  • Parity protected

4-Mbyte pages require two 2-Mbyte entries in all TLBs. 16-Kbyte page size refers to PTE coalescing of four physically consecutive and 16-Kbyte aligned 4-Kbyte pages. All caches and TLBs are competitively shared in multi-threaded mode.

System DRAM

• Ryzen 7000 "Raphael":
  • Up to PC5-41600 (DDR5-5200) without overclocking

• EPYC 9004 "Genoa":
  • 12 channels per socket, two 40-bit (32 data, 8 ECC) DDR5 subchannels per channel
  • Up to 24 DIMMs, max. 6 TiB
  • Up to PC5-38400 (DDR5-4800)
  • SR/DR RDIMM, 4R/8R LRDIMM, 3DS DIMM
  • ECC supported (x4, x8, x16, chipkill)
  • DRAM bus parity and write data CRC options

Sources: ^[2][3][4]

All Zen 4 Processors

Designers

• Mike Clark(?), chief architect

Bibliography

References

1. ↑ "Ryzen 7000 Desktop Preview", Angstronomics, August 29, 2022
2. ↑ "Processor Programming Reference (PPR) for AMD Family 19h Models 11h, Revision B1 Processors", AMD Publ. #55901, Rev. 0.25, November 10, 2022
3. ↑ "Software Optimization Guide for the AMD Zen4 Microarchitecture", AMD Publ. #57647, Rev. 1.00, January 6, 2023
4. ↑ "AMD EPYC™ 9004 Series Architecture Overview", AMD Publ. #58015, Rev. 1.1, December 2022

See Also

• AMD Zen, Zen 2, Zen 3
• Intel Meteor Lake