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Super-Drowsy Caches Single-VDD and Single-VT Super-Drowsy Techniques for LowLeakage High-Performance Instruction Caches Nam Sung Kim, Krisztián Flautner, David Blaauw, Trevor Mudge [email protected] [email protected] {blaauw, tnm}@eecs.umich.edu ISLPED 2004, August 2004 #1 issue: energy efficiency – – – – Need ways of dealing with leakage power New processes are expensive Diminishing performance gains from process scaling Dynamic power remains high Energy efficient solutions need to cut across traditional boundaries (SW / architecture / microarch / circuits) 100 300 Technology node 1 0.01 Dynamic Power Possible trajectory if high-k dielectrics reach mainstream production 250 200 150 100 0.0001 Sub-threshold Gate-oxide Leakage Leakage 0.000001 1990 1995 2000 2005 50 2010 2015 0 2020 Data from ITRS 2001 roadmap Physical Gate Length[nm] Technology scaling trends are not in our favor Normalized Total Chip Power Dissipation What the end-users really want: supercomputer performance in their pockets… Untethered operation, always-on communications Forget about the battery, charge once a month (or year) Driven by applications (games, positioning, advanced signal processing, etc.) The drowsy cache philosophy • Leakage power reduction with low implementation complexity – Balance complexity between microarchitecture and circuits small impact on either – Low-leakage is achieved using cache line or block-level voltage scaling – Simple control policies enabled by low-leakage state-retention in caches • Drowsy wake-up policies result in negligible run-time overhead – – – – … even on in-order cores A key requirement is fast wake-up transitions Data caches: periodically putting all lines into drowsy mode yields good results Instruction caches need predictive wake-up for best results • Super-drowsy improves on our original techniques – – – – – Simpler circuit design More leakage reduction: ultra-low retention voltage, no pre-charge unless needed Lower system complexity: eliminates need for external drowsy voltage source Faster cache access: no high-VT transistors on critical path Smaller run-time overhead: simpler, yet better control policy for instruction caches Single-VDD drowsy voltage controller • • • • • • • Previous drowsy cache circuits required multiple external voltage levels to be supplied Now: no high-VT transistors required, yielding 20% faster access time 165mV is sufficient to preserve state 250mV drowsy state reduces leakage by 98% and adds noise margins Super-drowsy voltage controller uses feedback through schmitt trigger inverter to generate drowsy voltage As VDD is cut off, VVDD floats down Vx is supplied through schmitt trigger inverter to stabilize drowsy voltage Next sub-bank prediction • To reduce bitline leakage, only one cache sub-bank is precharged at a time – – • Insight: unconditional branches and sequential accesses cause most transitions – • Inter sub-bank transitions are predicted to eliminate precharge overhead of drowsy sub-banks Bitline leakage is reduced by 88% using on-demand gated precharge The targets of conditional branches are usually within the same sub-bank Next sub-bank is predicted using the current set and sub-bank indices – Even small (64 entry) predictors show significant run-time improvement over no prediction Energy savings • • • The predictive technique enables the gating of bit-line precharge for higher leakage savings over the noaccess policy at the cost of modestly increased run-time More than half of the SPEC2K workloads show more than 80% leakage reduction at close to zero run-time overhead Area overhead of 1K entry next sub-bank predictor (in terms of bits) is 1.2%or a 32K 2way associative instruction cache Conclusions Super-Drowsy Cache improves on previous techniques in multiple ways: • System complexity of drowsy caches can be reduced by using a simple on-chip drowsy-voltage source • Faster cache access can be achieved by eliminating the need for multiple threshold voltages in the design • Pre-charge gating reduces bitline leakage - an often ignored component of other cache leakage reduction techniques • Sub-bank wakeup latency is mitigated by predictive techniques Questions?!