Data processor memory circuit
A memory circuit for use in a data processing circuit is described, in which memory cells have at least two states, each state being determined by both a first voltage level corresponding to a first supply line and a second voltage level corresponding to a second supply line. The memory circuit comprises a readable state in which information stored in a memory cell is readable and an unreadable state in which information stored in said memory cell is reliably retained but unreadable. Changing the first voltage level but keeping the second voltage level substantially constant effects a transition between the readable state and the unreadable state. In use, the static power consumption of the memory cell in the unreadable state is less than static power consumption of the memory cell in the readable state.
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This application is a Continuation of application Ser. No. 11/353,024, filed Feb. 14, 2006, which is a Continuation of application Ser. No. 10/410,602, filed Apr. 10, 2003, the entire contents of which are incorporated herein by reference.
The U.S. Government has a paid-up license in this invention and the right in limited circumstances to require the patent owner to license others on reasonable terms as provided for by the terms of F33615-00-C-1678 awarded by Defense Advanced Research Projects Agency.
BACKGROUND OF THE INVENTION1. Field of the Invention
The present invention relates to memory circuits for data processing. More particularly, this invention relates to reducing static power consumption in such memory circuits.
2. Description of the Prior Art
Complementary metal-oxide semiconductor (CMOS) transistors are the current technology of choice for most data processors due to their advantageous characteristic of consuming power only when switching. When not switching, individual CMOS transistors consume a negligible amount of power (˜10−15 Amps for N-type or P-type transistor) although the cumulative leakage current for modern data processors which have high transistor densities is becoming more and more significant as component sizes shrink and transistor densities increase (˜10−6 Amps). It is estimated that static power consumption currently accounts for 15% to 20% of the total power on chips implemented in high-speed processes.
The total power consumption in a CMOS circuit includes a dynamic power component, Pdynamic) due to switching activity and a static power component, Pstatic, arising from transistor leakage current. Pdynamic has a contribution from each switching event of C Vdd2 f, where C is the gate output capacitance and f is the processor clock frequency. Whereas Pstatic=IleakageVdd, where: Ileakage is the total chip leakage current and is proportional to e(−Vt/T); T is the temperature; and Vdd is the power-supply voltage. Accordingly, as Vt decreases Ileakage rises dramatically.
Reduced power supply voltages have accompanied decreasing feature dimensions in successive generations of silicon process technologies. These reduced supply voltages have tended to offset the impact of increasing transistor counts and increasing clock frequencies on dynamic power. As power supply voltages decrease, it is necessary to decrease transistor threshold voltages Vt to maintain fast switching speeds and sufficient noise margins. However reduced power supply voltages Vdd result in increased static power consumption.
One known technique to reduce static power consumption is the gated-VDD technique as introduced in M. Powell et. al. “Gated-Vdd: A circuit technique to reduce leakage in deep submicron cache memories”, Proc. Of Int. Symp. Low Power Electronics and Design, 2000, pp. 90-95. Memory circuits of this type are settable to either a full-power mode or a low-leakage mode. The gated-VDD technique reduces the leakage power by employing a high threshold (high-Vt) transistor to turn off the power to the memory cell when the cell is set to a low-leakage mode. This high-Vt device drastically reduces the leakage of the circuit because of the exponential dependence of leakage current on Vt. Although the gated-VDD technique is very effective at reducing leakage current, its main disadvantage lies in that it loses any information stored in the memory cell when switched into low-leakage mode. In the case of an on-chip (L1) cache memory circuit this means that the lost data must be reloaded from off-chip (L2) cache if the data is to be retrieved and this tends to negate energy savings as well as incurring a significant performance penalty. To avoid these drawbacks, gated-VDD schemes must use complex adaptive algorithms and be conservative about which arrays of memory cells (such as cache lines) are turned off.
A second known technique for reduction of static power consumption is adaptive body-biasing with multi-threshold CMOS (ABB-MTCMOS) as described in K. Nii, et. al. “A low power SRAM using auto-backgate-controlled MT-CMOS”, Proc. of Int. Symp. Low Power Electronics and Design, 1998, pp. 293-298. Again, each cell of this memory circuit is settable to either a full-power mode or a low-leakage mode. In this case the low-leakage mode does not involve completely switching off power to the transistors, rather transistors are set to a low-power “drowsy mode” in which leakage power is reduced. The drowsy mode is implemented by dynamically increasing the threshold voltage of the transistor memory cells. This paper by Nii et. al., discloses an static random access memory (SRAM) circuit in which an active mode is achieved by setting a first virtual source line to 1.0 V (via a first PMOS transistor) whilst a second virtual supply line is forced to ground level (via an NMOS transistor). In the active mode the voltage source is set at 1.0 V. This can be contrasted with a sleep mode where the first virtual source line is set to the higher value of 2.3V whilst the second virtual source line is also increased from ground to 1.0 V. In sleep mode the voltage source is increased to 3.3V and two pairs of diodes are used (each diode having a forward bias of 0.5V) to obtain the 2.3V and 1.0 V virtual supply levels. Although the leakage current through the memory cell is reduced significantly in this ABB-MTCMOS scheme, the necessary increase in the supply voltage of the circuit in sleep mode acts to offset some of the gain derived from the reduction in total static power consumption. Accordingly the leakage power in the low-leakage mode is much higher than that achievable by switching off the transistors.
Furthermore, this ABB-MTCMOS technique requires that the voltages of both the power and ground supply lines in addition to the voltage of the N-wells are changed each time the circuit enters or exits drowsy mode. The substantial N-well capacitance of the PMOS devices increases the energy required to switch the cache memory cell to high-power mode and can also significantly increase the time needed to transition to/from drowsy mode. Since the ABB-MTCMOS technique involves changing the substrate voltages of the PMOS transistors it would be very difficult to implement other than on a cell by cell basis in memory. Similarly to the above-described gated-VDD technique, ABB-MTCMOS requires special high-Vt devices for the control logic.
Accordingly, there is a need for a memory circuit that offers better leakage power reduction and faster switching than ABB-MTCMOS type circuits yet is simple to implement (e.g. line by line in cache memory) and retains cell information in the low-leakage mode.
SUMMARY OF THE INVENTIONViewed from one aspect the present invention provides a memory circuit for use in a data processing apparatus, in which memory cells have at least two states, each state being determined by both a first voltage level corresponding to a first supply line and a second voltage level corresponding to a second supply line, said memory circuit comprising:
a readable state in which information stored in a memory cell is readable; and
an unreadable state in which information stored in said memory cell is retained but unreadable;
wherein a transition between said readable state and said unreadable state is effected by changing said first voltage level but keeping said second voltage level substantially constant and wherein, in use, static power consumption of said memory cell in said unreadable state is less than static power consumption of said memory cell in said readable state.
Viewed from another aspect the present invention provides a computer program product bearing a computer program for controlling a memory circuit having a plurality of memory cells, each of said plurality of memory cells having a readable state in which information stored in a memory cell is readable and an unreadable state in which information stored in said memory cell is retained but unreadable, said computer program comprising:
resetting code operable to reset at least one of said plurality of memory cells from said readable state to said unreadable state in dependence upon a reset time.
Viewed from yet another aspect the present invention provides memory access prediction circuitry operable to predict which region of a memory circuit will next be accessed during execution of program code by a processor, said memory circuit having a plurality of memory cell arrays each memory cell array having a respective plurality of memory cells that are collectively settable to said readable state or said unreadable state, said memory access prediction circuitry comprising:
identifying logic operable to identify a transition instruction in said program code, said transition instruction being associated with a transition between said processor accessing a currently active memory region and said processor accessing a next target memory region of said memory circuit;
storage means operable to storing a transition address, said transition address corresponding to said transition instruction and to store in relation to said transition address a respective region identifier that identifies said next target memory region;
comparator logic operable to check said stored transition address on each processor access to said memory circuit to determine if a current program instruction corresponds to said transition address;
wake-up logic operable to initiate a transition of said next target memory region from said unreadable state to said readable state in dependence upon a result of said check of said stored transmission address.
The invention recognises that a state transition between a full-power mode and a low-leakage mode can be achieved using simplified circuitry by changing a single supply voltage level. This is simpler to implement than known methods that allow retention of the cell information in the low-power mode, which require changes to two supply voltages as well as the transistor substrate voltage to each memory cell. The information stored in the memory cell can be retained in the low-leakage mode yet static power consumption can be significantly reduced in comparison to known implementations of drowsy mode states by reducing the supply voltage in the unreadable state (low-leakage mode).
Although memory cells of the memory circuit need only have two possible states i.e. a readable state and an unreadable state, preferred embodiments involve the possibility of setting each memory cell to a further state which is an off-state. In the off-state, static power leakage is drastically reduced but information stored in the cell must be reloaded when it is reinstated to the readable state. This has the advantage of providing a more flexible system, in which each memory cell has three possible states so that balancing of static power reduction and performance penalties can be more finely tuned according to the memory array access history.
Although memory cells may be set to the readable state or the unreadable state on a cell by cell basis, it is preferred that memory cell arrays comprising a plurality of memory cells are collectively settable to the readable state or the unreadable state. This has the advantage of simplifying the control circuitry and mirroring the block-by-block or line-by-line co-ordination of data read/write processes in known data processor memory circuits such as RAM or cache.
Although, only the data storing portions of each memory array need be settable to the low-leakage unreadable mode to achieve static power reduction, it is preferred that in the context of a cache memory the tag memory portion associated with a memory array is also settable to the unreadable mode. This has the advantage of providing further reduced static power consumption by the memory circuit. This is particularly advantageous for use in direct mapped caches where the further reduction in static power consumption is achieved without any adverse impact on performance.
In preferred embodiments, the supply voltage level of the memory array is controlled in dependence upon the value of a readable-status bit (or “drowsy bit”). This has the advantage of simplifying the control mechanisms responsible for switching between the low-leakage state and the full power state so that, for example, only two additional transistors than the traditional memory array need be provided to effect the unreadable mode.
Although there are many alternative strategies that could be used to determine which of the plurality of memory cells in a memory circuit are set to unreadable mode at any one time, for example, based on a sophisticated tracking and analysis of the access history of each individual memory array or of groups of memory arrays. In one preferred embodiment a simple policy is used, which involves periodically setting each and every memory array to drowsy mode according to a predetermined reset time. Following each reset, only those memory arrays for which a read request is received will be restored to the readable state. This policy has the advantages that memory cells are aggressively set to drowsy mode thereby ensuring greater static power loss and it obviates the need for sophisticated memory access analysis and control algorithms yet results in surprisingly little overall access speed reduction.
In a further preferred embodiment the mode controller is operable to reset to drowsy mode, only those memory cell arrays that have not been accessed in a predetermined time interval. This has the advantage of reducing the performance impact by decreasing the number of memory arrays that have to be reinstated to full power mode in comparison to a more aggressive policy yet allowing for a simple control policy requiring only basic tracking of memory access history.
Advantageously, the mode controller is operable to calculate a performance penalty for setting each memory array into unreadable mode. This allows for more deterministic control of the trade-off between reduction in static power consumption which is increased as more memory cells are set to unreadable mode and the performance penalty incurred by having to reinstate memory cells to full power when information stored therein is required.
In a preferred embodiment, memory cell transistors of the memory's internal inverters are coupled to read/write lines of the memory circuit via a pass-transistor having a substantially higher threshold voltage than the associated cell transistors. This has the advantage of significantly reducing leakage through the pass transistors when the read/write lines are maintained in high-power mode.
In a further preferred embodiment, the memory circuit is arranged such that the capacitance of the voltage supply rail (which supplies voltage Vdd) is substantially less than the capacitance of pass-transistor. This has the advantage that it reduces the switching time for the transition between the readable state and the unreadable state, allowing for shorter switching times than achievable using techniques that involve increasing the threshold voltage of the memory cell transistors.
There are several alternative ways of allowing for cell information to be retained in the low-leakage mode. However, preferred embodiments achieve this objective by providing a memory circuit in which, in the unreadable state the first voltage (i.e. the supply voltage Vdd) is to set to be substantially 1.5 times the threshold voltage associated with the memory cell transistors. This provides for straightforward implementation of memory retention in the unreadable state.
Advantageously, in preferred embodiments transitions between the readable state and the unreadable state are effected by changing the supply voltage from a high value in the readable state to a comparatively low value in the unreadable state. This has the advantage that the change to the supply voltage in switching from the readable state to the unreadable state does not offset any of the reduction in total power consumption derived from reduction of the total leakage power for cells in the unreadable state.
Preferred embodiments of the memory circuit include at least one memory array comprising circuitry, such as a simple logic gate, operable to prevent any accesses to the memory array when it is in an unreadable state. This has the advantage of ensuring that the information stored in the memory cell is not destroyed in the event that memory cell access is attempted when the supply voltage of the drowsy cache line is lower than the pre-charge voltage of a read/write line.
The memory circuit according the invention could be used to reduce static power consumption in a variety of different memory types, for example in off-chip cache memory (L2 cache), random access memory (RAM), synchronous dynamic random access memory (SDRAM), tightly coupled memory (TCM), which is on-chip memory intended to store a predetermined portion of the most critical code/data associated with an application, or in other memory structures such as branch predictors. However, it is particularly advantageously used in static random access memory (SRAM) such as L1 (on-chip) cache memory because L1 cache memory typically comprises a significant proportion of a processor's transistors so that the leakage current in L1 cache is comparatively high.
The above, and other objects, features and advantages of this invention will be apparent from the following detailed description of illustrative embodiments which is to be read in connection with the accompanying drawings.
The operating voltage of an array of memory cells in SRAM (a cache line) is determined by the voltage controller 240, which switches the array voltage between a high (active) supply voltage and a low (drowsy) supply voltage in dependence upon the state of the drowsy bit. In particular, when the drowsy bit is a logical ‘1’, the supply voltage will correspond to the low-voltage (unreadable) state whereas of the drowsy bit is a logical ‘0’, the supply voltage will correspond to the high-voltage (readable) state. The way in which this is achieved by the circuit elements of
An NMOS transistor will only conduct when its input (via the transistor gate) is a logical ‘1’ whereas a PMOS transistor will only conduct when its input is a logical ‘0’. If the signal on the drowsy signal line corresponds to a logical ‘1’ then the drowsy set NMOS 212 will be conducting and will provide a path from ground 215 to the input node 213 of NMOS/PMOS transistor pair 222, 224. Accordingly a logical ‘0’ is supplied as input to transistors 222 and 224 whereupon PMOS 224 will be conducting but NMOS 222 will be non-conducting. When PMOS 224 is conducting there is a path from voltage source 226 to PMOS 244 via the inverter gate 234. Since a logical ‘1’ is input to the inverter gate 234 a logical ‘0’ is supplied to the gate of PMOS 244 which switches the low (0.3V) voltage supply to the power line 270 of the SRAM circuit 280. Thus the SRAM memory circuit that is supplied by the power line 270 is set to drowsy mode.
The word line driver controls the input to the wake-up NMOS 220. A logical ‘1’ will be supplied as input to NMOS 220 when a read request for a word-line has been received. If the input to the gate of wake-up NMOS 220 is a logical ‘1’ then the transistor 220 will conduct providing a path from ground to the input node 221 of the NMOS/CMOS transistor pair 214, 216. A logical ‘0’ input to this transistor pair renders NMOS 214 non-conducting and PMOS 216 conducting so that there is a path from voltage source 218 to the PMOS transistor 242 via the inverter gate 232. Since the input to the inverter gate 232 is a logical ‘1’, the output of the inverter 232 which is supplied to the gate of PMOS 242 is a logical ‘zero’. Accordingly, PMOS 242 is conducting and provides a path from the high (1.0V) voltage supply to the power line 270. Accordingly the SRAM 280 memory cells supplied by the power line 270 are set (or reinstated) to readable mode.
The word line AND gate 250 will only allow a word line (i.e. address line) to be read from SRAM if the word line signal is a logical ‘1’ and the output of the inverter gate 234 is also a logical ‘1’. The output of the inverter gate 234 cannot be a logical ‘1’ when PMOS 244 is conducting. Accordingly, a read operation is prevented when the SRAM memory cells are set to the drowsy state. The word line AND gate 250 serves to prevent inadvertent loss of the memory cell contents by attempting to perform a read operation when the memory cell is in drowsy mode. Loss of cell contents could otherwise arise due to the voltage of the drowsy cache line being lower than the pre-charge voltage of the cache memory circuit bit line. Note that a read operation involves driving the bit line to the same state as a flip-flop of the SRAM memory cell when the word line 260 is active. Whenever a cache line is accessed, a cache controller (not shown) monitors the voltage state of the cache line by reading the drowsy bit. If the accessed line is in readable mode the contents of the cache line can be read without adversely affecting processing performance. No performance penalty is incurred because the drowsy bit is read concurrently with the standard process of reading and comparing an address tag of the read address supplied by the central processing unit (CPU) and the address tag labelling the data stored in cache memory. However if the memory array is in drowsy mode the cache line is not read immediately, since to attempt to read data with the cache line in drowsy (unreadable) mode may result in the loss of stored data. Instead a read instruction for a drowsy cache line results in a wake-up signal being sent via NMOS transistor 220 during the next clock cycle so that data can be read during subsequent cycles once the cache line has been reinstated to readable mode.
The circuit of
The function of the SRAM flip-flop is simple. If the input to the second inverter (i.e. the signal C1 on cross-coupling 372) is a logical ‘1’ then NMOS 348 conducts providing a path to ground 310 so that the output C2 of the second inverter is a logical ‘0’. Accordingly, the input of the first inverter is a logical ‘0’ so that PMOS 342 conducts providing a path to the DC voltage 320 and the output of the first inverter is a logical ‘1’. The output equals the input so the latch is “transparent”.
If the input to the second inverter is switched to a logical ‘0’ then PMOS 346 conducts providing a path to the DC voltage 320 so that the input of the first inverter (equivalently the output of the second inverter) is a logical ‘1’. Accordingly, the NMOS 344 conducts, thereby providing a path to ground so that the output of the first inverter C1 is a logical ‘zero’. Thus the flip-flop arrangement has two stable logic states. A write operation involves sending a logical 1 or 0 on the signal bit line 330 and activating the address line 360. When the address line 360 is active the NMOS address line transistor 350 is conducting so the flip-flop is driven to a stable state that matches the bit line. A read operation also involves an active address line but in this case the bit line is driven to the same state as the flip-flop.
The voltage controller PMOS transistors 232 and 242 determine the voltage of the power line 270. If the gate input to PMOS transistor 232 is a logical ‘0’, then the high voltage (1V) power supply is selected. However, if the gate input to PMOS transistor 242 is a logical ‘0’ then the low voltage (0.3V) power supply is selected and the memory cell is in the drowsy (unreadable) state. The output of the first inverter 412, 414 is coupled to a vertical bit line 450 via a first NMOS pass transistor 430. Similarly, the output of the second inverter 420, 422 is coupled to a vertical complementary bit line 460 via a second NMOS pass transistor 440. The input gate of each pass transistor is connected to the word line 260, which mediates read/write operations. The first pass transistor 430 has a first capacitance 432 and the second pass transistor 440 has a second capacitance 442.
Since the bit lines 450, 460 (i.e. read/write lines) are maintained in high power mode it is necessary to prevent leakage from the NMOS pass transistors 430, 440. This is achieved by giving NMOS pass transistors 430, 440 high voltage thresholds Vt. The power controller PMOS transistors 232, 242 are also high-Vt transistors to prevent leakage from the high voltage (1.0V) supply to the low voltage (0.3V) supply. The circuit of
The high-Vt value for the NMOS pass transistors 430, 440 is determined by counterbalancing the leakage power reduction and the adverse performance impact of using a high-Vt device.
The performance degradation as a result of increasing Vt, can be estimated by measuring the delay from the word line 260 assertion to a point where there is a 50 mV voltage difference between two complementary bit lines 450, 460. This voltage difference corresponds to the known threshold for sense-amp activation. From the graph of
In the embodiment of
The memory circuit in
The memory cell layout was created using TSMC (Taiwan Semiconductor Manufacturing Company Ltd) 0.18 μm technology, which was the smallest available feature size. The dimensions of the memory cell were 1.84 um by 3.66 um, whilst those for the voltage controller were 6.18 um by 3.66 um. It is estimated that the area overhead of the voltage controller is equivalent to 3.35 memory cells for a 64×Leff (effective gate length) voltage controller. This relatively low area overhead can is achievable for this embodiment because the routing in the voltage controller is simple compared to the memory cell. The following (conservative) area overhead factors were assumed: 1.5 equivalent memory cells for the drowsy bit (the 0.5 factor arises from the two additional transistors 212, 220 for set and reset); a single equivalent memory cell for the control signal driver (two inverters 232, 234); and 1.5 equivalent memory cells for the wordline gating circuit 250. The total overhead is thus equivalent to 7.35 memory cells per cache line. The total area overhead is less than 3% for the entire cache line. To examine the effects of circuit stability and leakage power reduction, we applied a linear scaling technique to all extracted capacitances.
Table 1 below lists the advantages and disadvantages for the two traditional circuit techniques for leakage reduction as well as for the dynamic voltage scaling method (DVS) according to embodiments of the invention, and we show the power consumption for the three schemes in low-leakage mode. The leakage power in the gated-VDD method is very small compared to the other schemes. However, this technique does not preserve the state of the cache cell. Comparing the DVS technique as implemented in embodiments of the invention and known ABB-MTCMOS techniques, the DVS method reduces leakage power by a factor of 12.5, while the ABB-MTCMOS method reduces leakage by only a factor of 5.9.
Detailed power values for drowsy mode and normal-power mode for the DVS circuit are shown in Table 2 below. The energy parameters and drowsy transition time in the table correspond to a 32 KB four-way set associative cache (see explanation of set associative cache below with reference to
Embodiments of the invention implement drowsy memory cells (and cache lines) by employing a simple and effective technique of allowing for switching between two different memory cell supply voltages. This differs from the known ABB-MTCMOS drowsy cache technique which involves increasing the threshold voltages Vt of NMOS and PMOS transistors of the memory cell flip-flop. The other known technique for reducing static power consumption, gated-VDD, switches off memory cells rather than switching them to low power mode and the performance penalty for wrongly switching off a cache line is considerable.
The key difference between drowsy caches and caches that use gated-VDD is that in drowsy caches the cost of being wrong, that is putting a line into drowsy mode that will be accessed soon thereafter, is relatively small (it requires little energy and only one or two clock cycles, depending on circuit parameters). The only penalty is an additional delay and energy cost for having to wake up a drowsy line. Accordingly, one embodiment of the invention employs a simple cache line management technique that periodically resets all cache lines to drowsy mode, regardless of memory access patterns. A reset cache line will be reinstated to the active state via wake-up transistor 220 only when it is accessed again. This periodic reset technique is simple to implement since it requires only a single global counter and there is no need to monitor per-line cache accesses.
The results in the table of
The expected worst-case execution time increase for the baseline algorithm an be calculated from the following equation:
where accs specifies the number of accesses, wakelatency is the wakeup latency, accsperline the number of accesses per line, and wsize specifies the window size and memimpact is a variable used to describe how much impact a single memory access has on overall performance. If we make the assumption that any increase in cache access latency translates directly into increased execution time, it follows that memimpact=1. Using the above equation together with the variable values listed in
The right-hand side of the table of
Now consider using a predictive algorithm were to keep track of which cache lines are accessed in an update window. If the predictive algorithm puts only those cache lines that have not been accessed in a predetermined number of past windows into drowsy mode, the number of awake-to-drowsy transitions per window would potentially be reduced by about 50%. This decrease in the number of cache lines set to drowsy mode also decreases the number of later wakeups, which in turn reduces the impact on execution time. However, there is a negative impact on energy savings since a larger fraction of lines are kept in full power mode, and many of those lines will not be accessed for the next several windows, if at all.
The second arrangement 820 is a fully associative cache, in which any memory location (such as lower level memory block 12) can be cached in any cache line. This arrangement offers the best theoretical cache hit ratio since there are so many options for caching a memory address. However, complex search algorithms are required to check for a cache hit and this can result in the whole cache being slowed down by the search.
The third arrangement 830 is a set associative cache that offers a compromise between the direct mapped 810 and the fully associative 820 arrangements. In this arrangement the cache is divided into sets of N cache lines each for an N-way associative cache. A memory block is first mapped onto a set and then the block can be placed anywhere within that set. The set is usually chosen by bit selection, that is, (block address) MOD (number of sets in cache). Accordingly 12 MOD 4 is zero so memory block 12 is stored in set 0 in arrangement 830 of
Each of the two cache memory sets comprises a decoder 918 for decoding the CPU address 900, a data RAM 940 and a tag RAM 950 for storing a data index value indicative of data currently stored in a corresponding portion of the data RAM 940. Each cache line has an associated cache tag. A cache hit occurs when the CPU requests information from the cache and receives that information. A cache miss occurs when the CPU requests information from the cache but does not obtain it directly from that cache level.
Now consider how a cache hit occurs in the arrangement of
For embodiments of the invention described above, only the cache lines themselves are settable to the unreadable (or drowsy) mode whereas the cache tags 950 are always “awake” and therefore readable. However, alternative embodiments of the invention put the cache line tags into unreadable mode along with the cache line data. Reducing the supply voltage to the cache tags in addition to the cache line data has the potential benefit of further reducing static power consumption. This advantage could be partially offset by any additional latency introduced as a result of using drowsy tags. However it has been established that effect of the drowsy wake-up penalty on the processor's performance is likely to be small. Evidence for this will be presented below.
Table 3 below shows the latencies associated with accessing lines in a drowsy cache in comparison to accessing lines in a standard cache where all cache lines are awake. Table 3 relates to embodiments in which only the cache lines and not the tags can be put in drowsy mode. From Table 3, it can be seen that for a cache hit a standard cache takes a single cycle to access the data whereas for a drowsy cache line it takes two cycles to access the data. For a cache miss, there is no penalty for having a drowsy cache line in comparison to a standard cache line since the line wake-up overlaps with the memory latency associated with retrieving the data from lower level memory.
Table 4 below relates to an embodiment of the invention that implements drowsy (unreadable) tags along with drowsy (unreadable) cache lines. In this case the cache is set-associative i.e. at least two cache lines are associated with the CPU address index field 914. Accordingly, during the tag matching process, some lines of the relevant set are likely to be awake whilst others are likely to be drowsy. If all cache lines of the set are awake then the latencies are identical to those of the standard cache as listed in Table 3, the only difference being that following a cache miss and resulting cache line replacement, unneeded lines may be set back to drowsy mode. In the case where not all cache lines in the relevant set are awake, a cache hit may take up to 3 clock cycles which is an additional two-cycle latency in comparison to a standard cache hit.
Referring once more to Table 4, the lower right-hand entry of the table corresponds to a cache miss in a situation where not all cache lines of the set are awake. In this case there is an additional (maximum) two-cycle latency (prior to performing the line replacement) in comparison to a cache miss in which all lines and tags in the set are awake. These two additional cycles correspond to a cycle during which awake tags are checked for a match and, in the event that no match is found for awake tags, an additional cycle to wake up drowsy lines in the set. Similarly to the process for the cache miss detailed in
Note that in the case of direct-mapped caches there is no performance advantage (in comparison to implementing drowsy cache lines without drowsy tags) in keeping the tags awake since there is only one possible line for each index, thus if the cache-line is drowsy, it must be woken up immediately to be accessed.
There are a number of different possible cache control policies that can be used determine which cache lines (or lines and tags) are set to drowsy mode during process execution. In order to assess the impact on performance of different control policies a number of test simulations were performed using alternative control policies. A first policy, denoted the “simple policy” involves periodically resetting all lines in cache to drowsy mode. Here, the period corresponds to the window size. Furthermore, in this case no per-line access history is used in determining which cache lines to set to drowsy mode. A second policy, denoted the “noaccess policy” sets to drowsy mode only those lines that have not been accessed within a given update window. All of the algorithms corresponding to the tested control policies involved periodically evaluating the cache contents and selectively putting lines into drowsy mode.
The simulations were performed using a SimpleScalar systems design testbed (with SPEC2000 benchmark programs) and an Alpha instruction set. The cache parameters for the simulation were: 32K direct-mapped L1 instruction cache, 32 byte line size—1 cycle hit latency, 32K 4-way set associative L1 data cache, 32 byte line size—1 cycle hit latency, 8 cycle L2 cache latency. Two different pipeline configurations were used: an “OO4” configuration in which a 4-wide superscalar pipeline was used; and an “IO2” configuration in which a 2-wide in-order pipeline was used. All simulations were run for 1 billion instructions. The OO4 configuration has an “out-of-order core”, which is a processor that allows simultaneous or out-of order execution of multiple reads and writes to the same register. The IO2 configuration on the other hand has an “in-order core”. In some cases, results for a simpler “in-order core” have also been established.
The reason for the relatively small impact of the drowsy wake-up penalty on the in-order processor performance (IO2 policy) is due to the use of a non-blocking memory system, which can handle a number of outstanding loads and stores while simultaneously continuing execution of independent instructions. Moreover, the drowsy wake-up penalty is usually only incurred with load instructions, since stores are put into a write buffer, which—if not full—allows execution to continue without having to wait for the completion of the store instruction.
The benchmark applications on the graph can be partitioned into two groups: benchmarks associated with lines on the graph which are close to vertical (e.g. applu, art and mgrid); and benchmarks associated with lines on the graph that are more horizontal having and thus have a smaller positive slope (e.g. gzip, parser and crafty). All of the benchmarks that are close to the vertical are floating point benchmarks and their orientation implies that there is very little or no performance benefit to using the noaccess policy or larger window sizes. In fact, the mgrid, galgel, applu, facerec, and lucas benchmarks have a slight negative slope, implying that not only would the simple policy win on power savings over the noaccess policy, it would also win on performance. However, in all cases the performance difference is negligible and the potential power improvement is under 5%. The reason for this behaviour is the very bad reuse characteristics of data accesses in these benchmarks. Thus keeping lines awake (i.e. noaccess policy, or larger window sizes) is unnecessary and even counterproductive.
This anomalous behaviour in the floating-point benchmarks is not replicated on the integer benchmarks. For the integer benchmarks the noaccess policy wins on performance (i.e. gives the smallest run-time increase) in all cases but saves the least amount of power since the fraction of lines in drowsy mode at any one time is larger than for the simple policy. However, this does not imply that if performance degradation is a key issue then the more sophisticated noaccess policy should always be selected. The slope between the upper two points on each line on the graph of
We found that for a given machine configuration, a single static window size (2000 to 8000 cycles, depending on configuration) performs adequately on all of our benchmarks. However, the optimum window size varies slightly for each workload. Accordingly, alternative embodiments of the invention use an adaptive window size rather than a static window size. Use of an adaptive window size has the advantage that it allows for a finer power-performance trade-off. One such adaptive window-size embodiment involves monitoring the microarchitecture and counting the number of stall cycles that can be attributed to the drowsy wakeup latency. The cache lines of this embodiment are returned to drowsy mode again only when their previous wakeup overheads have been amortized (i.e. when the performance impact falls under a given threshold). The user can set the threshold value according to a desired compromise between reduced performance and increased power savings.
The dynamic voltage scaling (DVS) circuit according to embodiments of the invention does not offer the lowest leakage power per bit when compared with the known methods. However, the fact that each memory cell maintains its stored value when in unreadable mode, allows for an aggressive algorithm when deciding which cache lines to put into drowsy mode. It has been shown that using such an aggressive algorithm together with the DVS technique, the total energy consumed in the cache is reduced by an average of 54%. This compares well with the theoretical maximum reduction of 65% corresponding to a hypothetical circuit that consumes no leakage energy in drowsy mode. Given that the proportion of the total leakage energy consumed in drowsy mode is only 24% (on average), further reductions of leakage energy to that achievable via the simple or noaccess memory-cell state control policies will yield only diminished returns. Moreover, as the fraction of leakage energy is reduced from an average of 76% in projected conventional caches to an average of 50% in the drowsy cache, dynamic energy rather than leakage energy once again becomes a prime candidate for reduction.
During the investigations of drowsy caches it was found that the “simple” policy (where cachelines are periodically put into a low-power mode without regard to their access histories) significantly reduces the cache's static power consumption whilst having only a small adverse performance impact. The simple global refresh policy is not a solution to all caches in the processor. In particular, the L1 instruction cache does not do as well in terms of leakage power reduction as the L1 data cache with the simple algorithm and the noaccess policy gives only slightly better results. Accordingly, for such instruction caches the DVS drowsy circuit technique is used alongside instruction prefetch algorithms in order to reduce leakage power.
From the simulation results presented in
The table in
An important question is whether it is worth using the drowsy tag scheme rather than simply using drowsy lines where the associated tags are awake. The energy-delay product of the benchmarks when using drowsy tags is always lower than with awake tags, so the decision about whether to use drowsy tags or not comes down to acceptable engineering trade-offs. Direct-mapped caches, tags can be put into drowsy mode without undue performance impact or implementation complexity. However, using a direct mapped data cache instead of the typical 4-way set associative cache one has its own costs: miss rates on the benchmarks are approximately tripled, which aside from the performance penalty, can significantly impact the total energy consumption of the processor.
The circuits of
It is known to use subbanks as a means of reducing power consumption in caches. For example “Reducing power in superscalar processor caches using subbanking, multiple line buffers and bit-line segmentation” by K. Ghose and M. Kamble and published in Proceedings of the International Symposium on Low Power Electronics and Design, 1999 (pp. 70-75) describes a system in which the instruction cache is partitioned into several sub-banks, and on each cache access only a limited set of sub-banks are checked for their contents. This approach reduces the dynamic power consumption of the cache although the cache access time is slightly increased due to additional decoder logic that is required for indexing the subbanks. Furthermore, the paper “Dynamic Fine-Grain Leakage Reduction using Leakage-Biased Bitlines” by S. Heo, et al. and published in the Proceedings of the International Symposium on Computer Architecture, 2002 described a sub-banked cache memory arrangement in which a leakage power reduction circuit technique was applied to the most recently accessed sub-bank. The circuit technique described therein acts to reduce the leakage power consumption of the cache memory circuit by biasing the bit-lines in dependence upon the number of ones and zeros connected to each bit-line. A significant disadvantage of this known technique is that the processor must wake up the next target subbank on the critical path and the penalty for this wake-up can be several clock cycles. It has been established that this wake-up penalty results in a run-time increase of 4.06% to 12.46% on SPEC 2000 benchmarks, even when assuming an aggressive singe cycle wake-up penalty.
According to the present technique a cache memory circuit similar to that of
The pre-charge circuit 1830 serves to reduce the leakage current through the wordline pass transistors in the conventional 6 transistor memory cell (as illustrated in
A cache can be sub-banked in two different ways: vertically or horizontally.
In the vertical configuration of
As illustrated in
Each prediction buffer entry of the address region 2122 contains an instruction address which is the address of the instruction one before the instruction (usually a branch) which leads to another sub-bank. The buffer entry also contains the next target sub-bank index and a valid bit. On each cache access, the sub-bank prediction buffer 2120 is consulted to see whether or not a new sub-bank is predicted to be awakened. If there is a mis-prediction, or no prediction at all, the old entry is updated or a new one allocated.
In the example of
The address region 2122 of the sub-bank prediction buffer 2120 contains addresses that correspond to content addressed memory (CAM) tags. A CAM cell is a RAM cell with an in-built comparator so a CAM based tag store can perform a parallel search to locate an address in any location. Both the circuit area overhead and the power overhead of the prediction buffer can be significant using the sub-bank prediction technique illustrated in
In the memory cell of
Avoiding the use of high-Vt device for the memory cells as in the instruction cache circuit of
In
The noise susceptibility problem may be corrected with careful layout because the capacitive coupling of the lines is small. To examine the stability of a memory cell in the low power mode, a simulation was performed a write operation to an adjacent memory cell that shares the same bit lines but whose supply voltage was normal. The coupling capacitance and the large voltage swing across the bit lines would make the bit in the drowsy memory cell vulnerable to flipping if the circuit had a stability problem. However, simulation results have established that the state of the drowsy memory cell is in fact stable. There was only a slight fluctuation in the core node voltage caused by the signal cross-talk between the bit lines and the memory internal nodes. In addition, there is no cross-talk noise between the word line 260 and the internal node voltage, because word line gating prevents accesses to memory cells in drowsy mode. Although the voltage scaling technique has less immunity against a single event upset (SEU) from alpha particles, this problem can be ameliorated using process techniques such as silicon on insulator (SOI). Furthermore other static memory structures also suffer from this problem, making it necessary to implement error correction codes (ECC) even for non-drowsy caches. The problem of variation of Vt, may be addressed by choosing a conservative Vdd value, such as Vdd=1V, as in the circuit of
As was the case for the circuit of
The results of experimental simulations to determine the prediction accuracy and run-time increase of the sub-bank predictors of
For the purpose of the experiments three different L1 cache sizes were selected: 16K, 32K, and 64K bytes and three different degrees of associativity: 1, 2 and 4. The sub-bank or sub-array size used was 4K bytes, which corresponds to the page size of the virtual memory system. The trade-off to be made when using smaller sub-bank sizes is between more leakage reduction and increased wake-up penalties. Benchmarks from the SPEC2000 suite were used, which were run on a modified
SimpleScalar simulator. The benchmarks were compiled using a GCC 2.6.3 compiler using O2 level optimisations and were statically linked with library code. For each simulation a total of 1 billion instructions were run.
From
From the graph of
The predictor overhead associated with achieving leakage power reduction will now be considered for each next sub-bank predictor type. Table 5 shows the required number of bits for each predictor type for a 32K byte direct-mapped cache. It can be seen from Table 5 below that the tag-based sub-bank predictor requires the same number of bits as a 64 entry prediction buffer.
For example, in a 32-entry predictor, the number of required bits are 4096 bits (512 bytes), which is equivalent to 16 cache lines (32-byte per line). If we assume that the size of the cache is 64 k-bytes and the number of the cache lines is 2048 lines then the fractions of the 32, 64, and 128 entry predictors relative to the 64 k cache are just 0.78%, 1.56%, and 3.12%.
Table 28B of
In summary of the experimental simulations for drowsy instruction caches, it was found that a sub-banked cache according to the present technique with the next target sub-bank predictor (i.e. where only one subbank is active and the rest of the sub-banks are in drowsy mode) can reduce the cache static power consumption by more than 86% for 64K byte caches. Furthermore, the simulation results have shown that the prediction technique using a 128 entry prediction buffer can reduce the run-time overhead by 83%, 74%, and 76% for 16K, 32K, and 64K byte caches respectively relative to the default policy where no prediction was employed. Accordingly, the combination of a DVS circuit according to the present technique with an appropriate micro-architectural mechanism provides sufficient static power savings at a modest performance impact. The present technique for reduction of leakage current has the advantage that it is simple to implement.
Although illustrative embodiments of the invention have been described in detail herein with reference to the accompanying drawings, it is to be understood that the invention is not limited to those precise embodiments, and that various changes and modifications can be effected therein by one skilled in the art without departing from the scope and spirit of the invention as defined by the appended claims.
Claims
1. A memory circuit comprising:
- at least one memory cell having:
- (i) an active state in which information stored in said at least one memory cell is active; and
- (ii) a retention state in which information stored in at least one memory cell is retained but retention, wherein static power consumption of said at least one memory cell in said retention state is less than static power consumption of said at least one memory cell in said active state, said memory circuit comprising at least one memory cell array, each memory cell array having a plurality of said memory cells that are collectively settable to said active state or said retention state; and
- a mode controller operable to set said at least one memory cell array to said retention state.
2. A memory circuit as claimed in claim 1, wherein at least one of a first voltage level and a second voltage level determine whether said at least one memory cell is in said active state or in said retention state said first voltage level corresponds to a first supply line and said second voltage level corresponds to a second supply line.
3. A memory circuit as claimed in claim 1, in which said memory circuit has an off-state in which stored information is lost.
4. A memory circuit according to claim 1, wherein said memory circuit is a cache memory circuit and wherein said at least one memory cell array is a respective cache line.
5. A memory circuit according to claim 1, wherein said memory circuit is a cache memory circuit having a plurality of cache sub-banks and wherein said at least one memory cell array is a respective cache sub-bank.
6. A memory circuit according to claim 5, comprising a pre-charge circuit responsive to a pre-charge signal and comprising a logic gate operable to gate said pre-charge signal with a signal for changing a cache sub-bank from said retention state to said active state.
7. A memory circuit according to claim 5, comprising a sub-bank prediction buffer operable to predict which of said plurality of cache sub-banks will next be accessed after a currently active cache sub-bank and hence should next be set to said active state.
8. A memory circuit according to claim 7, wherein each entry of said sub-bank prediction buffer comprises an instruction address of an instruction immediately prior to an instruction that leads to a change in a currently active cache sub-bank.
9. A memory circuit as claimed in claim 4, wherein each cache line has an address tag that identifies data currently stored in that cache line and said address tag is extended to include at least one sub-bank predictor array element.
10. A memory circuit as claimed in claim 4, wherein each cache line has an address tag that identifies data currently stored in a respective cache line, said address tag being settable to said active state or to said retention state in correspondence with a setting of the associated cache line in either said active state or said retention state.
11. A memory circuit according to claim 4, comprising a voltage controller for a respective one of said cache lines.
12. A memory circuit according to claim 5, comprising a voltage controller for a respective one of said cache sub-banks.
13. A memory circuit as claimed in claim 11, wherein said voltage controller is operable to determine said second voltage of said at least one memory array in dependence upon a value of a active-status bit associated with a respective memory array.
14. A memory circuit as claimed in claim 1, wherein said mode controller is operable to periodically reset all of said memory arrays to said retention state according to a predetermined reset time.
15. A memory circuit as claimed in claim 14, wherein said predetermined reset time is adaptive such that it is dependent upon a performance impact threshold.
16. A memory circuit as claimed in claim 14, wherein said mode controller is operable to set to retention mode only those cache lines that have not been accessed in a predetermined time window.
17. A memory circuit as claimed in claim 14, in which said mode controller is operable to calculate a performance penalty for setting each memory array to said retention state and is further operable to calculate said reset time in dependence upon said performance penalty.
18. A memory circuit as claimed in claim 3, wherein each memory cell comprises a plurality of complementary metal oxide semiconductor (CMOS) cell-transistors.
19. A memory circuit as claimed in claim 18, wherein said changing of said first voltage level to effect said transition is facilitated by connecting at least one of said memory cell arrays both to a normal voltage supply by a first CMOS transistor and to a low voltage supply by a second CMOS transistor, said first CMOS transistor and said second CMOS transistor each having a threshold voltage that is substantially higher than a threshold voltage associated with said cell transistors and said retention state corresponds to the connection to said low voltage supply being effective whereas said active state corresponds to the connection to said normal voltage supply being effective.
20. A memory circuit as claimed in claim 18, wherein each of said at least one memory cell arrays is connected to a read/write line via a CMOS pass-transistor having a threshold voltage that is substantially higher than a threshold voltage associated with said cell transistors.
21. A memory circuit as claimed in claim 20, wherein at least one of a first voltage level and a second voltage level determine whether said at least one memory cell is in said active state or in said retention state said first voltage level corresponds to a first supply line and said second voltage level corresponds to a second supply line, and in which a capacitance of said first supply line is substantially less than a capacitance of said pass-transistor.
22. A memory circuit as claimed in claim 18, wherein at least one of a first voltage level and a second voltage level determine whether said at least one memory cell is in said active state or in said retention state said first voltage level corresponds to a first supply line and said second voltage level corresponds to a second supply line, and wherein in said retention state, said first voltage level is settable to be substantially 1.5 times the value of the threshold voltage associated with said cell transistors.
23. A memory circuit as claimed in claim 1, wherein said at least one memory array comprises circuitry operable to prevent any accesses to a respective memory array when said memory array is in said retention state.
24. A memory circuit as claimed in claim 1, wherein said memory circuit is a static random access memory (SRAM) circuit and each of said at least one memory cell arrays comprises memory cells associated with a respective predetermined memory address range in SRAM.
25. A memory circuit as claimed in claim 1, wherein said memory circuit is a tightly coupled memory (TCM) circuit.
26. A memory circuit as claimed in claim 2, wherein a transition between said active state to said retention state is effected by changing said first voltage level such that it is lower in said retention state than in said active state.
27. A memory circuit according to claim 2, wherein said second voltage level is set is ground level.
28. A memory circuit comprising:
- at least one memory cell having:
- (i) a being read state;
- (ii) an active state in which information stored in said at least one memory cell is ready to be read in said being read state; and
- (iii) a retention state in which information stored in at least one memory cell is retained but is not ready to be read in said being read state; wherein static power consumption of said at least one memory cell in said retention state is less than static power consumption of said at least one memory cell in said active state.
29. A memory circuit as claimed in claim 28, wherein at least one of a first voltage level and a second voltage level determine whether said at least one memory cell is in said active state or in said retention state said first voltage level corresponds to a first supply line and said second voltage level corresponds to a second supply line.
30. A memory circuit as claimed in claim 28, in which said memory circuit has an off-state in which stored information is lost.
31. A memory circuit comprising:
- at least one memory cell having:
- (i) an active state in which information stored in said at least one memory cell is ready to be read in a separate being read state; and
- (ii) a retention state in which information stored in at least one memory cell is retained but is not ready to be read in a separate being read state;
- wherein static power consumption of said at least one memory cell in said retention state is less than static power consumption of said at least one memory cell in said active state, said memory cell comprising at least one memory cell array, each memory cell array having a plurality of said memory cells that are collectively settable to said active state or said retention state.
32. A memory circuit according to claim 31, wherein said memory circuit is a cache memory circuit and wherein said at least one memory cell array is a respective cache line.
33. A memory circuit according to claim 31, wherein said memory circuit is a cache memory circuit having a plurality of cache sub-banks and wherein said at least one memory cell array is a respective cache sub-bank.
34. A memory circuit according to claim 33, comprising a pre-charge circuit responsive to a pre-charge signal and comprising a logic gate operable to gate said pre-charge signal with a signal for changing a cache sub-bank from said retention state to said active state.
35. A memory circuit according to claim 33, comprising a sub-bank prediction buffer operable to predict which of said plurality of cache sub-banks will next be accessed after a currently active cache sub-bank and hence should next be set to said active state.
36. A memory circuit according to claim 35, wherein each entry of said sub-bank prediction buffer comprises an instruction address of an instruction immediately prior to an instruction that leads to a change in a currently active cache sub-bank.
37. A memory circuit as claimed in claim 32, wherein each cache line has an address tag that identifies data currently stored in that cache line and said address tag is extended to include at least one sub-bank predictor array element.
38. A memory circuit as claimed in claim 32, wherein each cache line has an address tag that identifies data currently stored in a respective cache line, said address tag being settable to said active state or to said retention state in correspondence with a setting of the associated cache line in either said active state or said retention state.
39. A memory circuit according to claim 32, comprising a voltage controller for a respective one of said cache lines.
40. A memory circuit according to claim 33, comprising a voltage controller for a respective one of said cache sub-banks.
41. A memory circuit as claimed in claim 39, wherein said voltage controller is operable to determine said second voltage of said at least one memory array in dependence upon a value of a active-status bit associated with a respective memory array.
42. A memory circuit as claimed in claim 31, comprising a mode controller operable to selectively set predetermined ones of a plurality of said memory cell arrays to said retention state.
43. A memory circuit as claimed in claim 42, wherein said mode controller is operable to periodically reset all of said memory arrays to said retention state according to a predetermined reset time.
44. A memory circuit as claimed in claim 43, wherein said predetermined reset time is adaptive such that it is dependent upon a performance impact threshold.
45. A memory circuit as claimed in claim 43, wherein said mode controller is operable to set to retention mode only those cache lines that have not been accessed in a predetermined time window.
46. A memory circuit as claimed in claim 43, in which said mode controller is operable to calculate a performance penalty for setting each memory array to said retention state and is further operable to calculate said reset time in dependence upon said performance penalty.
47. A memory circuit as claimed in claim 30, wherein each memory cell comprises a plurality of complementary metal oxide semiconductor (CMOS) cell-transistors.
48. A memory circuit as claimed in claim 47, wherein said changing of said first voltage level to effect said transition is facilitated by connecting at least one of said memory cell arrays both to a normal voltage supply by a first CMOS transistor and to a low voltage supply by a second CMOS transistor, said first CMOS transistor and said second CMOS transistor each having a threshold voltage that is substantially higher than a threshold voltage associated with said cell transistors and said retention state corresponds to the connection to said low voltage supply being effective whereas said active state corresponds to the connection to said normal voltage supply being effective.
49. A memory circuit as claimed in claim 47, wherein each of said at least one memory cell arrays is connected to a read/write line via a CMOS pass-transistor having a threshold voltage that is substantially higher than a threshold voltage associated with said cell transistors.
50. A memory circuit as claimed in claim 49, wherein at least one of a first voltage level and a second voltage level determine whether said at least one memory cell is in said active state or in said retention state said first voltage level corresponds to a first supply line and said second voltage level corresponds to a second supply line, and in which a capacitance of said first supply line is substantially less than a capacitance of said pass-transistor.
51. A memory circuit as claimed in claim 47, wherein at least one of a first voltage level and a second voltage level determine whether said at least one memory cell is in said active state or in said retention state said first voltage level corresponds to a first supply line and said second voltage level corresponds to a second supply line, and wherein in said retention state, said first voltage level is settable to be substantially 1.5 times the value of the threshold voltage associated with said cell transistors.
52. A memory circuit as claimed in claim 31, wherein said at least one memory array comprises circuitry operable to prevent any accesses to a respective memory array when said memory array is in said retention state.
53. A memory circuit as claimed in claim 31, wherein said memory circuit is a static random access memory (SRAM) circuit and each of said at least one memory cell arrays comprises memory cells associated with a respective predetermined memory address range in SRAM.
54. A memory circuit as claimed in claim 31, wherein said memory circuit is a tightly coupled memory (TCM) circuit.
55. A memory circuit as claimed in claim 29, wherein a transition between said active state to said retention state is effected by changing said first voltage level such that it is lower in said retention state than in said active state.
56. A memory circuit according to claim 29, wherein said second voltage level is set is ground level.
Type: Application
Filed: Mar 17, 2009
Publication Date: Aug 27, 2009
Applicants: ARM Limited (Cambridge), University of Michigan (Ann Arbor, MI)
Inventors: Krisztian Flautner (Cambridge), David T. Blaauw (Ann Arbor, MI), Trevo N. Mudge (Ann Arbor, MI), Nam S. Kim (Ann Arbor, MI), Steven M. Martin (Ann Arbor, MI)
Application Number: 12/382,450
International Classification: G11C 7/00 (20060101); G11C 5/14 (20060101); G11C 8/00 (20060101);