Abstract:
A memory compiler to generate a set of memories is based on a subtraction approach from a set of templates (memory templates), including at least one layout database and auxiliary design databases, by software. The software can be based on general-purpose programming language or a layout-specific language. The compiled memories can be generated by reducing the memory array sizes in row and/or column directions by moving, deleting, adding, sizing, or stretching the layout objects, and disabling the high order addresses, etc. from the memory template by software. The new auxiliary design databases, such as layout phantom, behavior model, synthesis view, placement-and-routing view or datasheet, can also be generated by modifying some parameters from the memory template by software. One-time programmable memory using junction diode, polysilicon diode, or isolated active-region diode as program selector in a cell can be generated accordingly.

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
     This application claimed priority benefit of U.S. Provisional Patent Application No. 61/443,172 filed on Feb. 15, 2011, titled “Circuit and Method of a One-Time Programmable Memory Compiler Based on Subtraction Approach”, which is hereby incorporated herein by reference. 
     This application also references U.S. Provisional Patent Application No. 61/375,653, filed on Aug. 20, 2010 and entitled “Circuit and System of Using Junction Diode As Program Selector for Resistive Devices in CMOS Logic Processes,” which is hereby incorporated herein by reference; U.S. patent application Ser. No. 13/026,725 filed on Feb. 11, 2011 based on the same title, which is hereby incorporated herein by reference; U.S. Provisional Patent Application No. 61/375,660, filed on Aug. 20, 2010 and entitled “Circuit and System of Using Polysilicon Diode As Program Selector for Resistive Devices in CMOS Logic Processes,” which is hereby incorporated herein by reference; U.S. patent application Ser. No. 13/026,650 filed on Feb. 11, 2011 based on the same title, which is hereby incorporated herein by reference. 
     This application also claimed priority benefit of U.S. Provisional Patent Application No. 61/421,184 filed on Dec. 8, 2010, titled “Method and Apparatus of A High Density Anti-fuse,” and a U.S. patent application Ser. No. 13/314,444 filed on Dec. 7, 2011 based on the same title, which is also hereby incorporated herein by reference. 
    
    
     BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates to a memory compiler and, more particularly, circuit and method to build a memory compiler based on pre-built memory templates of maximum capacities with array size reduction and component subtraction. 
     2. Description of the Related Art 
     Memory compiler is a tool to generate memories with various configurations, such as different capacities, different I/O counts, different aspect ratios, etc. by software automation. The conventional method to build a compiler is based on an additive approach or tiling, which means all basic components of a memory are pre-built and then tiled together seamlessly like tiling on the kitchen floor by running a software. 
     Compilers to generate datapath, such as adders or multipliers, or to generate register files is a very simple example of tiling. As an example to generate an 8-bit, 16-bit, 32-bit, or 64-bit adder, each bit cell is pre-designed and pre-layouted. The cells of carry look-ahead or carry select for every 4 bits can also be pre-designed and pre-layouted. Then a simple layout script or a software script tiles the bit slices together with carry look-ahead or carry select circuit between 4-bit cells to generate the required adder. Register file is another simple example for tiling. The bit cells, X-decoders, and column sense amplifiers can be put together to generate the required register file with arbitrary capacities and configurations. 
     ROM or SRAM compilers are another two common types of memory compilers that need a general purpose software rather than simple scripts to generate. A ROM or SRAM has memory bit cells, X-decoders, Y-decoders, X- and Y-address buffers, X- and Y-pre-decoders, bitline pull-ups, Y-select pass gates, sense amplifiers, output buffers, and control logic, etc. Those components need more sophisticated software to tile various components together to generate various configurations, such as capacities, I/Os, aspect ratios, on different technologies, etc. 
       FIG. 1  shows a portion of a typical ROM/SRAM compiler  100  based on tiling according to a prior art. The memory bit cell  105  is built and organized as an n×m two-dimensional memory array  110  by tiling all bit cells together. Then, n X-decoders  115  are tiled and butted to the left of the memory array  110  with the height of the X-decoders  115  fitted into the height of the bit cells  105 . Similarly, m Y-decoders  120  are tiled and butted to the bottom of the memory array  110  with the width of the Y-decoders fitted into the width of the bit cell  105 . The X- and Y-decoders are called tight-pitch cells that need to fit into the pitches of the bit cells  105 , otherwise the area utilization would be very poor. S columns are multiplexed into one I/O so that one sense amplifier  125  has a width to match the width of s bit cells  105 . If there are t sense amplifiers  125  in the memory  100  and one sense amplifier fitting into the width of s cells, then the total number of column in the memory  100  is m=s*t. Output buffers  130  are tiled to the bottom of the sense amplifier  125 , one for one. All X- and Y-addresses need to be properly buffered and then pre-decoded to generate the required X- and Y-decoder signals. The X-address buffers  135  and X-pre-decoders  140  are built and generally fitted into the left-lower corner in the floor plan. So do the Y-address buffers  145  and Y-pre-decoders  150 . Then the read/write control logic  195  is built to fit into the left over space in the left-lower corner of the memory macro  100 . All components are tiled with perfect matches in the boundaries to prevent wasting valuable silicon real estate. Finally, a power/ground ring (not shown in  FIG. 1 ) is built around the whole memory macro  100  to complete the memory compiled. 
     The above compiler method is only good for a simple memory such as ROM or SRAM. For a DRAM or flash memory, the components are much more and complicated. For example, flash memory tends to need high voltage generators, reference voltages, tighter pitches but with high-voltage devices in the X- and Y-decoders to fit. As a result, they tend to build manually, rather than generated by software automatically. 
     Building memories with different configurations manually requires lots of time, efforts, and financial resources to do. Moreover, it would be subject to human errors, that may carry great financial and legal liability. Accordingly, there is a need for building a general-purpose memory compiler for those memories that are more complicated than either ROM or SRAM to save costs. 
     SUMMARY OF THE INVENTION 
     The invention pertains to a circuit and method to build a general-purpose memory compiler based on building a template of memory with maximum capacity and then subtracting some components to generate smaller memories. 
     The conventional way to build a memory compiler is based on additive approach, which means starting with a memory bit cell to tile into a memory array with tight-pitch cells, and then the control logic for a memory macro. If the memory is more complicated than either ROM or SRAM, there are some other circuits such as reference voltages, high voltage generators, memory redundancy, test mode circuits, etc. to build. Those circuits are not as regular as the memory components so that they are very hard to tile into proper space. 
     This invention about building a memory compiler is based on subtractive approach, which means starting with a template of memory with maximum capacity and then gradually subtracting some components to generate smaller capacity memories. Since all various irregular components are built in the template, no efforts spent to tile these components into proper area with a perfect fit. On the contrary, taking away some components is much easier than putting various components together in perfect match. One-time Programmable (OTP) memory can be used to illustrate the circuit and concept of the subtractive memory compiler, though the other type of memories such as DRAM or flash memories can be applicable too. The OTP memory cell generally has an OTP element, such as a polysilicon in an electrical fuse cell or a dielectric film in an anti-fuse cell, coupled to a diode as a program selector. 
       FIG. 2  shows a block diagram of a portion of memory  200  built manually, as an example of a finished memory macro. The memory macro has been design to optimize performance and silicon area. The memory  200  has a memory array  210  that has n×m memory cell  205  organized in two-dimensional. To the left of the memory array  210 , there are n X-decoders  215  to provide wordlines to fit into the height of the memory cell  205 . To the bottom of the memory array  210 , there are m Y-decoders and Y-Pass gates  220  to fit into the width of the memory cell  205 . One sense amplifier  225  can be coupled into s Y-decoders and fitted to the bottom of the Y-decoders. An output buffer  230  is coupled to the output of the sense amplifier  225  and fitted below in the layout. Their widths should match perfectly. To the left of the Y-decoder  220  and below the X-decoders  215 , there are interpose of X-/Y-pre-decoders, and X-/Y-address buffers,  235 ,  250 ,  240 , and  245  respectively to fit into the available space. In a manual design, the widths and heights of the X-/Y-pre-decoders, and X-/Y-address buffers,  235 ,  250 ,  240 , and  245  need to go through several iterations of changing aspect ratios so that tight fittings can be achieved. A control logic  295  can be designed to fit into the available space in the lower left corner of the memory  200 . To design a memory macro without too much empty space needs craftsmanship, which means need experienced circuit and layout designers spending time and efforts to practice to master the skill. At least one power/ground rings surround the memory macro  200  to provide low resistance paths in the supply voltage lines. 
       FIG. 3  shows a schematic of an OTP memory cell  800  with an OTP element  801  and a diode  810  as program selector. The OTP element  801  can be an electrical fuse, such as silicided polysilicon, coupled to a first supply voltage line V+ and to the P terminal of a diode  810 . The diode  810  has an N terminal coupled to a second supply voltage line V−. The diode can be constructed from a junction diode created from a P+/N well or a polysilicon diode built on a polysilicon structure with N+ and P+ implants in two ends and a silicide block layer to separate the N+ and P+ regions in standard CMOS processes. Similarly, a diode can also be a diode built on an isolated active-region structure with N+ and P+ implants in two ends and a silicide block layer to separate the N+ and P+ regions in standard SOI or FinFET processes. 
       FIG. 4(   a ) shows a cross section of an array  900  of anti-fuse cells as one particular type of OTP memory cell. Anti-fuse cells are formed at the cross-points of two perpendicular conductors with a dielectric film as OTP element and a P/N junction diode as program selector. Parallel active region lines  912  are fabricated on P type substrate  910  with oxide isolation, such as STI (Shallow Trench Isolation) or LOCOS (Local Oxidation)  911 , in between. The active region lines  912  are implanted with heavy N+, the so-called buried N+ implant, to create a conductor before polysilicon or source/drain of CMOS can be formed. The active region lines  912  are implanted with P type dopant  930  over the buried N+  920  to create a P/N junction diode and then grow a thin oxide  935  before another set of P type polysilicon lines  940  are fabricated on top running in a perpendicular direction. An anti-fuse cell is created at the cross-point of the polysilicon  940  and active region lines  912 . Another embodiment in constructing a diode is to use an intrinsic layer between P type implant  930  and buried N+  920 . The intrinsic layer means not intentionally doped with N or P type, but rather can be slightly N or P type due to out-diffusion or contamination. 
       FIG. 4(   b ) shows an equivalent circuit of the anti-fuse cell in  FIG. 4(   a ). An anti-fuse cell  945  is created at the cross-point of the polysilicon  930  and active region lines  912  having an oxide layer  941  as a dielectric film and a diode  942  as a program selector. The oxide layer  941  is fabricated before the polysilicon lines  930  in  FIG. 4(   a ), and is coupled to a first supply voltage line V+ and to the P terminal of a diode  942  in  FIG. 4(   b ). The N terminal of the diode  942  is coupled to an active region  912  in  FIG. 4(   a ) and further coupled to a second supply voltage line V− in  FIG. 4(   b ). 
       FIG. 5  shows a schematic of a portion of OTP memory cells organized as an n×m two-dimensional array  950 . The OTP memory cell  951  has an OTP element  952 , which can be a polysilicon in an electrical fuse cell or a dielectric film in an anti-fuse cell, and a diode  953  as program selector. The OTP element  952  is coupled to a first supply voltage V+ in one end and to a P terminal of a diode  953  at the other end. The diode  953  has an N terminal coupled to a second supply voltage V− at the other end. The OTP memory cells are organized as an n×m array with all V+&#39;s of the cells in the same column connected as bitlines BLj (j=0, 1, 2, . . . , m−1), and all V−&#39;s of the cells in the same row connected as wordlines WLi (i=0, 1, 2, . . . , n−1). An OTP cell located at l&#39;th row and j&#39;th column can be selected for read or write by asserting the WLi and BLj, where i=0, 1, 2, . . . , n−1 and j=0, 1, 2, . . . , m−1. 
     The invention can be implemented in numerous ways, including as a method, system, device, or apparatus (including graphical user interface and computer readable medium). Several embodiments of the invention are discussed below. 
     As a memory compiler, one embodiment can, for example, include a plurality of memory cells. At least one of the memory cells can include an OTP element coupled to a first supply voltage line, and a diode including at least a first type of silicon and a second type of silicon. The first type of silicon can have a first type of dopant and the second type of silicon can have a second type of dopant. An intrinsic layer may be inserted between the first and the second types of silicon. The first type of silicon can provide a first terminal of the diode and the second type of silicon can provide a second terminal of the diode. The first type of silicon can also be coupled to the OTP element, and the second type of silicon can be coupled to a second supply voltage line. The diode can be fabricated as a junction diode or a diode constructed from a polysilicon structure in standard CMOS processes, or an isolated active-region in standard SOI or FinFET processes. Alternatively, a memory cell can be built at the cross-points of two perpendicular conductors, such as metal-active region, active-polysilicon, or metal-polysilicon, etc. The OTP element can be a polysilicon in an electrical fuse cell or a dielectric film in an anti-fuse cell. The OTP element can be configured to be programmable by applying voltages to the first and second supply voltage lines to thereby change the resistance of the OTP element into a different logic state. Alternatively, the OTP element, such as a dielectric film, can be coupled to the second type of silicon, or in between the first and the second type of silicon in other embodiments. 
     As an electronics system, one embodiment can, for example, include at least a processor, and a compiled OTP memory operatively connected to the processor. The compiled OTP memory can include at least a plurality of OTP memory cells for providing data storage. Each of the OTP cells can include at least an OTP element coupled to a first supply voltage line, and a diode including at least a first type of silicon and a second type of silicon. The first type of silicon can have a first type of dopant and the second type of silicon can have a second type of dopant. An intrinsic layer may be inserted between the first and the second types of silicon. The first type of silicon can provide a first terminal of the diode and the second type of silicon can provide a second terminal of the diode. The first type of silicon can be coupled to the OTP element and the second type of silicon can be coupled to a second supply voltage line. The first and second type of silicons can be fabricated as a junction diode or a diode constructed from a polysilicon structure in standard CMOS processes, or an isolated active-region in standard SOI or FinFET processes. Alternatively, an OTP cell can be built at the cross-point of two perpendicular conductors, such as metal-active region, active-polysilicon, or metal-polysilicon, etc. The OTP element can be a polysilicon in an electrical fuse cell or a dielectric film in an anti-fuse cell. The OTP element can be configured to be programmable by applying voltages to the first and the second supply voltage lines to thereby change the resistance of the OTP element into a different logic state. Alternatively, the OTP element, such as a dielectric film, can be coupled to the second type of silicon, or in between the first and the second type of silicon in other embodiments. 
     As a method for providing an OTP memory from a memory compiler, one embodiment can, for example, include at least providing a plurality of OTP memory cells, and programming a logic state into at least one of the OTP cells by applying voltages to the first and the second voltage lines. The at least one of the OTP cells can include at least (i) a OTP element coupled to a first supply voltage line, and (ii) a diode including at least a first type of silicon and a second type of silicon. The first type of silicon can have a first type of dopant and the second type of silicon can have a second type of dopant. An intrinsic layer may be inserted between the first and the second types of silicon. The first type of silicon can provide a first terminal of the diode and the second type of silicon can provide a second terminal of the diode. The first type of silicon can be coupled to the OTP element and the second type of silicon can be coupled to a second supply voltage line. The first and second type of silicons can be fabricated from a junction diode or a diode constructed from a polysilicon structure in standard CMOS processes, or an isolated active-region in standard SOI/FinFET processes. Alternatively, a memory cell can be built at the cross-point of two perpendicular conductors, such as metal-active region, active-polysilicon, or metal-polysilicon, etc. The OTP element can be a polysilicon in an electrical fuse cell or a dielectric film in an anti-fuse cell. The OTP element can be configured to be programmable by applying voltages to the first and the second supply voltage lines to thereby change the resistance of the OTP element into a different logic state. Alternatively, the OTP element, such as a dielectric film, can be coupled to the second type of silicon, or in between the first and the second type of silicon in other embodiments. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The present invention will be readily understood by the following detailed descriptions in conjunction with the accompanying drawings, wherein like reference numerals designate like structural elements, and in which: 
         FIG. 1  shows a conventional method to build a memory compiler (prior art). 
         FIG. 2  shows a block diagram of a memory built with various components. 
         FIG. 3  shows an OTP memory cell with an OTP element and a diode as program selector. 
         FIG. 4(   a ) shows a cross section of an anti-fuse cell array as a particular type of OTP memory array with a dielectric film and a diode at the cross points of two perpendicular conductors. 
         FIG. 4(   b ) shows an equivalent circuit of the OTP memory cell in  FIG. 4(   a ). 
         FIG. 5  shows a schematic of building a two-dimensional array using OTP memory cell. 
         FIG. 6(   a ) shows a method of building a smaller memory along the row direction by a subtractive method. 
         FIG. 6(   b ) shows a final floor plan of building a smaller compiled memory along the row direction by a subtractive method. 
         FIG. 7(   a ) shows a method of building a smaller memory along the column direction by a subtractive method 
         FIG. 7(   b ) shows a final floor plan of building a smaller compiled memory along the column direction by a subtractive method. 
         FIG. 8  shows various auxiliary databases of a memory in automated logic flow. 
         FIG. 9  shows a software or script to generate various auxiliary databases of a memory in automated logic flow. 
         FIG. 10  shows a method to generate auxiliary databases in a memory compiler for automated logic flow. 
         FIG. 11  shows a method to generate memories in a memory compiler. 
     
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     This invention is about a memory compiler based on subtractive method that can be applied to any kinds of memory. By building a full-function memory with maximum capacity as a template, smaller size memories can be generated by reducing the memory array size and the associated tight-pitch cells accordingly. The memory macro boundary can also be stretched to fit into the new floor plan of the smaller memory. Some addresses would be disabled in the new and smaller size memories. This compiler method can be applied to any memories with more components and complicated circuits, though an OTP compiler is used as an example to illustrate the key concept of this invention. 
       FIG. 6(   a ) shows a layout floor plan of a memory  200 . The memory  200  has an array of n×m memory cells  205  organized in a two-dimensional array  210 . An array of n X-decoders  215  are placed and butted to the memory array  210  in the left. Another array of m Y-decoders  220  are placed and butted to the memory array  210  in the bottom. An array of sense amplifiers  225  with the width fitted into the width of memory cells are placed and butted to the Y-decoders in the bottom. If there are t sense amplifiers in this memory  200 , then m=t*s. In one embodiment, there could be only one sense amplifier for the entire memory. X-address buffers  240  and X pre-decoders  235  are placed in the left lower corner of the memory  200 . So are the Y-address buffers  245  and Y pre-decoders  250 . A control logic  295  is built to fit into the left lower corner of the memory macro  200  in the floor plan. Finally, a power or ground ring  299  is built around the memory macro  200  to reduce the power or ground resistance. 
     To build a smaller size memory  300  based on the maximum capacity memory  200  in  FIG. 6(   a ), the memory bit cells and the X-decoders above the bold line shown in  FIG. 6(   a ) can be eliminated. The number of rows can be reduced to one-half, one quarter, or one eighth, etc. The corresponding X-address buffers (i.e. high order X-address buffers) are disabled and grounded. Reducing the number of rows by 2&#39;s powers makes the decoding scheme much easier, though it is not necessary to be in 2&#39;s powers. The power or ground ring  299  of a memory  200  in  FIG. 6(   a ) can be stretched to fit into the new floor plan of the memory as shown in an arrow in bold. The final floor plan of the new memory  300  is shown in  FIG. 6(   b ). This process can be automated much easier by using software or scripts operating on layout database. 
       FIG. 7(   a ) shows a layout floor plan of a memory  200 . The memory  200  has an array of n×m memory cells  205  organized in a two-dimensional array  210 . An array of n X-decoders  215  are placed and butted to the memory array  210  in the left. Another array of m Y-decoders  220  are placed and butted to the memory array  210  in the bottom. An array of sense amplifiers  225  with the width fitted into the width of memory cells are placed and butted to the Y-decoders in the bottom. If there are t sense amplifiers in this memory, then m=t*s. In one embodiment, there could be only one sense amplifier for the entire memory. X-address buffers,  240  and X pre-decoders  235  are placed in the left lower corner of the memory  200 . So are the Y-address buffers  245  and Y pre-decoders  250 . A control logic  295  is built to fit into the left lower corner of the memory macro  200  in the floor plan. Finally, a power or ground ring  299  is built around the memory macro  200  to reduce the power or ground resistance. 
     To build a smaller size memory  400  based on the maximum capacity memory  200  in  FIG. 7(   a ), the memory bit cells and the Y-decoders to the right of the bold line shown in  FIG. 7(   a ) can be eliminated. The number of columns can be reduced to one-half, one quarter, or one eighth, etc. The corresponding Y-address buffers (i.e. high order Y-address buffers) are disabled and grounded. Reducing the number of columns by 2&#39;s power makes the decoding scheme much easier, though it is not necessary to be in 2&#39;s powers. The power or ground ring  299  in  FIG. 7(   a ) can be stretched to fit into the new floor plan of the memory as shown in an arrow in bold. The final floor plan of the new memory  400  is shown in  FIG. 7(   b ). This process can be automated much easier by using software or scripts operating on layout database. 
       FIG. 8  shows various design databases  500  for a memory macro to be integrated into an SoC according to automated logic flow. The most important file is the layout database  510  (usually in GDS format) that is the physical entity to be integrated with rest of design database for an SoC. However, during the process of designing the memory macro, a set of schematics and symbols  520  (i.e. logic gate and blocks) are built for engineers to design circuits. Building a custom memory macro is the so-called bottom-up design methodology—by starting with basic Boolean gates, building larger and larger blocks with symbols in hierarchy. After the schematics  520  are built in graphics form, the schematics  520  can be converted into SPICE netlist (*.spi)  530  so that the circuits built can be simulated to make sure the functionality and timing are correct and can meet the specifications. After the circuit simulation results are satisfactory, the schematics  520  are hand-drawn into layout database  510  in the memory template. For a memory macro to fit into an SoC, the layout database is a physical database that will go to mask making, while the rest of files are auxiliary for design purposes. The schematics  520 , SPICE netlist  530 , and layout database  510  are the resulting database of a full custom design. 
     For a layout database to be integrated into an SoC, some auxiliary files are needed so that an automated logic flow can be applied. The automated logic flow is called top-down design methodology—by writing a Hardware Description Language (HDL), such as Verilog or VHDL, in Register Transfer Level (RTL) to describe the functionality of a target circuit, so that detailed schematics can be generated by synthesis and then linked with a standard cell library for placement-and-routing (P&amp;R) to generate the final layout database. Some auxiliary files are required to describe various aspects of a memory macros in different abstraction levels without needing the physical layout database. For example, to describe the functionality of a macro, a behavior (i.e. *.v file in Verilog format) model specifies the functionality of the macro without considering the detailed implementation and timing. Synthesis means converting RTL files in HDL into schematics with different sizing or buffering to meet functionality and timing constraints. Memory macro is generally not synthesizable but built in full custom design. However, to be integrated into an SoC, a synthesis equivalent model, called synthesis view, needs to be provided for the memory macro so that the rest of the SoC circuits can be synthesized to interface with. For synthesis, such as using Design Compiler of Synopsys, synthesis views (*.db, *.lib) specify the I/O ports with the I/O capacitances, slew rate, timing arcs, or other parameters of the memory macro. Placement and Routing (P&amp;R) means calling leaf cells from a cell library (such as standard cell library), placing them in preferred orders and locations, and then routing them according to specified connectivity. For an automated Placement and Routing (P&amp;R) tool to call the memory macro as a leaf cell and to merge with a cell library for the rest of SoC circuits, a P&amp;R view (*.lef)  550  is needed to specify the connectivity of the I/O ports in physical locations. Finally, a human readable datasheet  690  (i.e. in Adobe *.pdf format) is needed for the SoC designers to understand the specifications of the memory macro. A final physical layout database is usually not needed during SoC design process. A layout phantom  580  is used to specify the boundary of the memory macro with the layers of the I/O ports shown, i.e. a phantom only shows the related layers in boundary of a memory macro for routing purpose but treats the details inside as a black box. 
       FIG. 9  shows a block diagram  600  of a software or script to generate various auxiliary database. Layout scripts  682  can be used to generate layout phantom (*.gds)  680  from a layout database  610  by deleting all the layers inside the memory macro to the layers in the boundary and I/O ports for automatic routing. Similarly Unix scripts  681  can be used to generate various design database  620 , SPICE netlist  630 , Behavior model  640 , Synthesis view, P&amp;R view, and datasheet  690 , by modifying the numbers of addresses and I/Os, timing parameters, loadings, numbers of instances, etc. from the original auxiliary database, respectively. The modifying is considered very simple that a text-based Unix scripts can do the work. 
     The scripts to generate various auxiliary files for an SoC to integrate a memory macro compiled from a memory compiler are based on template files. The method to generate layout database has been depicted in  FIGS. 6(   a ),  6 ( b ),  7 ( a ), and  7 ( b ), while the rest of auxiliary files can be generated by either using Unix scripts or layout scripts on a set of template files. The operations on layout database as shown in  FIGS. 6(   a ),  6 ( b ),  7 ( a ), and  7 ( b ) can be easily done by using layout scripts, such as Cadence&#39;s Skill Language, to change the array parameters, to move, stretch, add, delete, connect, or disconnect layout objects. Using a general purpose programming language, such as C-language, is possible, but this involves operating on more detailed and more tedious layout objects, while the Skill is a high-level language that wraps all the layout details underneath the language syntax. Similarly, layout phantom  680  can be generated by Skill or C-language accordingly. 
     The schematics  620  of the newly generated smaller memories can be created by Skill or C-language as well. Usually, the schematics  620  are not necessarily provided with the memory compiler  600 , but as a reference to the memory compiler users. The same as the SPICE netlist  630 . The SPICE netlist  630 , behavior model  640 , synthesis view  660  and P&amp;R view  650  are all in human readable text files, so that Unix scripts  681 , such as Shell scripts, awk, or Perl, can be used to work on them and to generate similar files for the newly created memories in compiler. The reduced addresses and the new connectivity can be easily modified from the maximum capacity template. The I/O port location, loading, and timing arcs can also be generated from the maximum capacity template with a projection, such as linear extrapolation. The datasheet  690  is a human readable file, such as in Adobe&#39;s pdf format, that can be easily modified by Unix scripts based on the template. 
       FIG. 10  shows a method  700  in a flow chart to generate a memory from a memory compiler according to the present invention. The first step  710  is to build a memory template with the maximum capacity for a set of memories to be generated. The memory template has a layout database and all the auxiliary files for customer design and for automated logic flow. Then building a layout script  720  to keep only one half, one quarter, or one-eighth, etc, of the memory array in row and/or column directions. The associated row and/or column decoders are also reduced accordingly. The third step  730  is to build a layout script to stretch the peripheral of the memory array to fit into the new floor plan. The fourth step  740  is to disable or ground the high-order X- and/or Y-addresses so that the other portions of the memory are not needed in the new smaller memories. Then in step  750  a layout script can be created to modify the layout phantom accordingly. The last step  760  is to build at least one Unix, or Unix-like scripts to modify the other auxiliary files based on address reduction, loading and timing arcs by interpolation or extrapolation. 
       FIG. 10  show flow charts depicting a method of a memory compiler to generate layout and auxiliary database for smaller memory based on a template, in accordance with certain embodiments. The method is described in the context a memory, such as the OTP memory  200  in  FIGS. 2 ,  6 ( a ), and  7 ( a ). In addition, although described as a flow of steps, one of ordinary skilled in the art will recognize that at least some of the steps may be performed in a different order, including simultaneously, or skipped. 
       FIG. 11  shows a processor system  600  according to one embodiment. The processor system  600  can include a programmable resistive device  644 , such as in a cell array  642 , in programmable resistive memory  640 , according to one embodiment. The processor system  600  can, for example, pertain to a computer system. The computer system can include a Central Process Unit (CPU)  610 , which communicate through a common bus  615  to various memory and peripheral devices such as I/O  620 , hard disk drive  630 , CDROM  650 , programmable resistive memory  640 , and other memory  660 . Other memory  660  is a conventional memory such as SRAM, DRAM, or flash, typically interfaces to CPU  610  through a memory controller. CPU  610  generally is a microprocessor, a digital signal processor, or other programmable digital logic devices. Memory  640  is preferably constructed as an integrated circuit, which includes the memory array  642  having at least one programmable resistive device  644 . The memory  640  typically interfaces to CPU  610  through a memory controller. If desired, the memory  640  may be combined with the processor, for example CPU  610 , in a single integrated circuit. 
     There are many variations in the embodiments of this invention. For example, the memory can be ROM, SRAM, DRAM, flash, or OTP memory in particular. Moreover, the memory can be a datapath, such as adder, multiplier, or floating-point adder/multiplier, or a register file. The scripts can be any kinds of programming languages such as Skill, C, awk, Perl, Unix Shell, or Job Description Language (JCL), etc. The memory templates can be more than one to target different ranges of memory capacities. The memories compiled can be used as stand alone memories, or embedded memory to be integrated with an SoC, or used in an electronics system. The method to generate memories may include a Graphics User Interface (GUI) for users to input memory configurations and requirements so that the software can take these inputs to generate memories accordingly. Similarly, the output of the memory compiler may include a GUI to display the memories generated. For those skilled in the art understand that various embodiments are possible and they are still within the scope of this invention. 
     The many features and advantages of the present invention are apparent from the written description and, thus, it is intended by the appended claims to cover all such features and advantages of the invention. Further, since numerous modifications and changes will readily occur to those skilled in the art, it is not desired to limit the invention to the exact construction and operation as illustrated and described. Hence, all suitable modifications and equivalents may be resorted to as falling within the scope of the invention.