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Difference between revisions of "intel/microarchitectures/saltwell"
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* '''{{intel|Briarwood}}''' - SoCs for Microservers | * '''{{intel|Briarwood}}''' - SoCs for Microservers | ||
* '''{{intel|Berryville}}''' - SoCs for consumer electronics (e.g. set-tops) | * '''{{intel|Berryville}}''' - SoCs for consumer electronics (e.g. set-tops) | ||
| + | |||
| + | == All Saltwell Chips == | ||
| + | <!-- NOTE: | ||
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| + | If a microprocessor is missing from the list, an appropriate article for it needs to be | ||
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| + | Missing a chip? please dump its name here: http://en.wikichip.org/wiki/WikiChip:wanted_chips | ||
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| + | <table class="wikitable sortable"> | ||
| + | <tr><th colspan="11" style="background:#D6D6FF;">Saltwell Chips</th></tr> | ||
| + | <tr><th colspan="8">CPU</th><th colspan="3">IGP</th></tr> | ||
| + | <tr><th>Model</th><th>µarch</th><th>Platform</th><th>Core</th><th>Launched</th><th>SDP</th><th>Freq</th><th>Max Mem</th><th>Name</th><th>Freq</th><th>Max Freq</th></tr> | ||
| + | {{#ask: [[Category:microprocessor models by intel]] [[microarchitecture::Saltwell]] | ||
| + | |?full page name | ||
| + | |?model number | ||
| + | |?microarchitecture | ||
| + | |?platform | ||
| + | |?core name | ||
| + | |?first launched | ||
| + | |?sdp | ||
| + | |?base frequency | ||
| + | |?max memory | ||
| + | |?integrated gpu | ||
| + | |?integrated gpu base frequency | ||
| + | |?integrated gpu max frequency | ||
| + | |format=template | ||
| + | |template=proc table 2 | ||
| + | |userparam=12 | ||
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| + | }} | ||
| + | </table> | ||
Revision as of 10:00, 10 April 2016
| Edit Values | |
| Saltwell µarch | |
| General Info |
Saltwell was a microarchitecture for Intel's 32 nm ultra-low power system on chips first introduced in late 2011 for the Atom family. Saltwell is a shrink of Bonnell which also incorporated all support chips on-die. Saltwell, unlike its predecessor was aimed directly at smartphones (as opposed to MIDs).
Contents
Codenames
| Platform | Core | Target |
|---|---|---|
| Medfield | Penwell | Smartphones |
| Cedar Trail | Cedarview | Netbooks |
| Clover Trail+ | Cloverview | Tablets |
| Bordenville | Centerton | Microservers |
| Bordenville | Briarwood | Microservers |
| Berryville | CE (set-tops) |
Architecture
Saltwell's primary goals were:
- Improve on Bonnell by getting rid of older support chips
- Add enhancements using 32 nm process while transitioning to 22 nm
- Improve GPU, power
- Burst frequencies
Key changes from Bonnell
- L2$ increase rate
- L2$ now seperate rail
- New low-power SRAM for machine state
- Larger instruction fetch
- Double the size of the branch prediction history table
Memory Hierarchy
- Cache
- Hardware prefetchers
- L1 Cache:
- 32 KB 8-way set associative instruction
- 1 read and 1 write port
- 24 KB 6-way set associative data
- 1 read and 1 write port
- 8 transistors (instead of 6) to reduce voltage
- Per core
- 32 KB 8-way set associative instruction
- L2 Cache:
- 512 KB 8-way set associative
- ECC
- Shrinkable from 512 KB to 128 KB (2-way)
- 32B/cycle and 32 outstanding cache requests
- separate voltage rail, fixed @ 1.05V
- Per core
- L3 Cache:
- No level 3 cache
- Non-Cache Shared State Memory
- 256KB low-power SRAM
- separate voltage plane
- always-on block that stores architectural states while in various power saving modes
- RAM
- Maximum of 1GB, 2 GB, and 4 GB
- dual 32-bit channels, 1 or 2 ranks per channel
Functional Units
The number of functional units were kept to minimum to cut on power consumption.
- 2 Integer ALUs (1 for jumps, 1 for shifts)
- 2 FP ALUs (1 adder, 1 for others)
- No Integer multiplier & divider
Pipeline
Saltwell has an almost identical pipeline to Bonnell's with a 16-stage pipeline with a 13-stage miss penalty. It's also still a dual-issue superscalar but with in-order execution. Reordering logic is was still omitted due to power and area restrictions.
The longer pipeline allows a more evenly spreading of heat across the chip with more units. This also allows a higher clock rate.
- Instruction Fetch
- 3 stages
- 48 Bytes/Cycle (lower if SMT)
- Instruction Decode
- 3 stages
- Instructions with up to 3 prefixes/Cycle
- Instruction Dispatch
- 2 stages
- Source Operand Read
- 1 stage
- reading register operand
- 1 stage
- Data Cache Access
- 3 stages
- 1 stage for calculating
- 2 stages for reading cache
- 3 stages
- Execution
- 2 clusters
- integers
- quick cache access due to direct connection
- floating point & SIMD
- integers
- 2 clusters
- Exception & MT Handling
- 2 stages
- Commit
- 1 stage
Multithreading
Saltwell has support for multithreading - up to two threads per core. However each thread compete for the same resources which does inherently means they run slower than they would if they were to run alone.
Branch Prediction
- Two-level adaptive predictor
- 12-bit branch history register
- Pattern history table has 8192 entries (shared between threads), twice that of Bonnell
- Branch buffer target has 128 entries (4-way, 32 sets)
- Unconditional jumps are ignored
- Always-taken and never-taken are marked in the table
- Penalties:
- 13 stages for miss prediction
- 7 stages for correct prediction but missing branch target buffer (BTB)
Cores
- Penwell - SoCs specifically for smartphones
- Cedarview - SoCs for netbooks
- Cloverview - SoCs for tablets
- Centerton - SoCs for Microservers; added support for Intel VT and ECC memory
- Briarwood - SoCs for Microservers
- Berryville - SoCs for consumer electronics (e.g. set-tops)
All Saltwell Chips
| Saltwell Chips | ||||||||||
|---|---|---|---|---|---|---|---|---|---|---|
| CPU | IGP | |||||||||
| Model | µarch | Platform | Core | Launched | SDP | Freq | Max Mem | Name | Freq | Max Freq |