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 RM7065ATM Microprocessor with On-Chip Secondary Cache Data Sheet Preliminary
RM7065A
RM7065ATM Microprocessor with OnChip Secondary Cache
Data Sheet
Preliminary Issue 2, June 2001
Proprietary and Confidential to PMC-Sierra, Inc and for its Customer's Internal Use Document ID: PMC-2010145, Issue 2
RM7065ATM Microprocessor with On-Chip Secondary Cache Data Sheet Preliminary
Legal Information
Copyright
(c) 2001 PMC-Sierra, Inc. The information is proprietary and confidential to PMC-Sierra, Inc., and for its customers' internal use. In any event, you cannot reproduce any part of this document, in any form, without the express written consent of PMC-Sierra, Inc. PMC-2010145 (P1)
Disclaimer
None of the information contained in this document constitutes an express or implied warranty by PMC-Sierra, Inc. as to the sufficiency, fitness or suitability for a particular purpose of any such information or the fitness, or suitability for a particular purpose, merchantability, performance, compatibility with other parts or systems, of any of the products of PMC-Sierra, Inc., or any portion thereof, referred to in this document. PMC-Sierra, Inc. expressly disclaims all representations and warranties of any kind regarding the contents or use of the information, including, but not limited to, express and implied warranties of accuracy, completeness, merchantability, fitness for a particular use, or non-infringement. In no event will PMC-Sierra, Inc. be liable for any direct, indirect, special, incidental or consequential damages, including, but not limited to, lost profits, lost business or lost data resulting from any use of or reliance upon the information, whether or not PMC-Sierra, Inc. has been advised of the possibility of such damage.
Trademarks
RM7000A and Fast Packet Cache are trademarks of PMC-Sierra, Inc.
Patents
The technology discussed is protected by one or more of the following Patents: U.S. Patent Numbers 5,953,748 5,606,683 5,760,620. Relevant patent applications and other patents may also exist.
Contacting PMC-Sierra
PMC-Sierra, Inc. 105-8555 Baxter Place Burnaby, BC Canada V5A 4V7 Tel: (604) 415-6000 Fax: (604) 415-6200 Document Information: document@pmc-sierra.com Corporate Information: info@pmc-sierra.com Technical Support: apps@pmc-sierra.com Web Site: http://www.pmc-sierra.com
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RM7065ATM Microprocessor with On-Chip Secondary Cache Data Sheet Preliminary
Revision History
Issue No.
2 1
Issue Date
June 2001 April 2001
Details of Change
Changed IP references to INT, page 34. Changed W7 pin name to SysClk. Applied PMC-Sierra template to existing MPD (QED) preliminary FrameMaker document. Updated Sections 4.33, 4.34, 4.38, 9, and 12. In the Pinout Table, changed all references from IP to Int. Changed QED references to PMC-Sierra or MIPS.
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RM7065ATM Microprocessor with On-Chip Secondary Cache Data Sheet Preliminary
Document Conventions
The following conventions are used in this datasheet: * * * All signal, pin, and bus names described in the text, such as ExtRqst*, are in boldface typeface. All bit and field names described in the text, such as Interrupt Mask, are in an italic-bold typeface. All instruction names, such as MFHI, are in san serif typeface.
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RM7065ATM Microprocessor with On-Chip Secondary Cache Data Sheet Preliminary
Table of Contents
1 2 3 4 Features ..................................................................................................................................9 Block Diagram .......................................................................................................................10 Description ............................................................................................................................11 Hardware Overview ...............................................................................................................12 4.1 4.2 4.3 4.4 4.5 4.6 4.7 4.8 4.9 CPU Registers .............................................................................................................12 Superscalar Dispatch ...................................................................................................12 Pipeline ........................................................................................................................13 Integer Unit ..................................................................................................................14 ALU ..............................................................................................................................15 Integer Multiply/Divide ..................................................................................................15 Floating-Point Coprocessor ..........................................................................................16 Floating-Point Unit .......................................................................................................16 Floating-Point General Register File ............................................................................17
4.10 System Control Coprocessor (CP0) .............................................................................18 4.11 System Control Coprocessor Registers .......................................................................18 4.12 Virtual to Physical Address Mapping ............................................................................19 4.13 Joint TLB ......................................................................................................................20 4.14 Instruction TLB .............................................................................................................21 4.15 Data TLB ......................................................................................................................21 4.16 Cache Memory .............................................................................................................22 4.17 Instruction Cache .........................................................................................................22 4.18 Data Cache ..................................................................................................................22 4.19 Secondary Cache ........................................................................................................24 4.20 Secondary Caching Protocols ......................................................................................24 4.21 Cache Locking .............................................................................................................25 4.22 Cache Management .....................................................................................................26 4.23 Primary Write Buffer .....................................................................................................26 4.24 System Interface ..........................................................................................................26 4.25 System Address/Data Bus ...........................................................................................27 4.26 System Command Bus ................................................................................................27 4.27 Handshake Signals ......................................................................................................28 4.28 System Interface Operation .........................................................................................28 4.29 Data Prefetch ...............................................................................................................30 4.30 Enhanced Write Modes ................................................................................................31 4.31 External Requests ........................................................................................................31 4.32 Test/Breakpoint Registers ............................................................................................31 4.33 Performance Counters .................................................................................................32 4.34 Interrupt Handling ........................................................................................................34 4.35 Standby Mode ..............................................................................................................36
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4.36 JTAG Interface .............................................................................................................36 4.37 Boot-Time Options .......................................................................................................36 4.38 Boot-Time Modes .........................................................................................................36 5 6 7 8 9 Pin Descriptions ....................................................................................................................38 Absolute Maximum Ratings ..................................................................................................41 Recommended Operating Conditions ...................................................................................42 DC Electrical Characteristics .................................................................................................43 Power Consumption ..............................................................................................................44 10.1 Capacitive Load Deration .............................................................................................45 10.2 Clock Parameters ........................................................................................................45 10.3 System Interface Parameters ......................................................................................46 10.4 Boot-Time Interface Parameters ..................................................................................46 11 Timing Diagrams ...................................................................................................................47 11.1 Clock Timing ................................................................................................................47 12 Packaging Information ..........................................................................................................48 13 RM7065A Pinout ...................................................................................................................50 14 Ordering Information .............................................................................................................52
10 AC Electrical Characteristics .................................................................................................45
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List of Figures
Figure 1 Block Diagram .............................................................................................................10 Figure 2 CP0 Registers .............................................................................................................12 Figure 3 Instruction Issue Paradigm ..........................................................................................13 Figure 4 Pipeline ........................................................................................................................14 Figure 5 CP0 Registers .............................................................................................................19 Figure 6 Kernel Mode Virtual Addressing (32-bit) .....................................................................20 Figure 7 Typical Embedded System Block Diagram .................................................................27 Figure 8 Processor Block Read .................................................................................................29 Figure 9 Processor Block Write .................................................................................................30 Figure 10 Multiple Outstanding Reads ......................................................................................30 Figure 11 Clock Timing ..............................................................................................................47 Figure 12 Input Timing ...............................................................................................................47 Figure 13 Output Timing ............................................................................................................47 Figure 14 Mechanical Diagram .................................................................................................48
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List of Tables
Table 1 Instruction Issue Rules .................................................................................................12 Table 2 Dual Issue Instruction Classes .....................................................................................13 Table 3 ALU Operations ............................................................................................................15 Table 4 Integer Multiply/Divide Operations ................................................................................15 Table 5 Floating Point Latencies and Repeat Rates .................................................................17 Table 6 Cache Attributes ...........................................................................................................25 Table 7 Cache Locking Control .................................................................................................26 Table 8 Penalty Cycles ..............................................................................................................26 Table 9 Watch Control Register ................................................................................................32 Table 10 Performance Counter Control .....................................................................................33 Table 11 Cause Register ...........................................................................................................35 Table 12 Interrupt Control Register ...........................................................................................35 Table 13 IPLLO Register ...........................................................................................................35 Table 14 IPLHI Register ............................................................................................................35 Table 15 Interrupt Vector Spacing .............................................................................................36 Table 16 Boot Time Mode Stream .............................................................................................37 Table 17 System Interface .........................................................................................................38 Table 18 Clock/Control Interface ...............................................................................................39 Table 19 Interrupt Interface .......................................................................................................40 Table 20 JTAG Interface ...........................................................................................................40 Table 21 Initialization Interface ..................................................................................................40
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1
Features
* Dual issue symmetric superscalar microprocessor with instruction prefetch optimized for system level price/performance * 300, 350 MHz operating frequency * >525 Dhrystone 2.1 MIPS @ 350 MHz High-performance system interface * 1000 MB per second peak throughput * 125 MHz max. freq., multiplexed address/data * Supports two outstanding reads with out-of-order return * Processor clock multipliers 2, 2.5, 3, 3.5, 4, 4.5, 5, 6, 7, 8, 9 Integrated primary and secondary caches * All are 4-way set associative with 32 byte line size * 16 KB instruction, 16 KB data, 256 KB on-chip secondary * Per line cache locking in primaries and secondary * Fast Packet CacheTM increases system efficiency in networking applications High-performance floating-point unit -- 800 MFLOPS maximum * Single cycle repeat rate for common single-precision operations and some double-precision operations * Single cycle repeat rate for single-precision combined multiply-add operations * Two cycle repeat rate for double-precision multiply and double-precision combined multiply-add operations MIPS IV superset instruction set architecture * Data PREFETCH instruction allows the processor to overlap cache miss latency and instruction execution * Single-cycle floating-point multiply-add Integrated memory management unit * Fully associative joint TLB (shared by I and D translations) * 64/48 dual entries map 128/96 pages * Variable page size Embedded application enhancements * Specialized DSP integer Multiply-Accumulate instructions, (MAD/MADU) and three-operand multiply instruction (MUL) * I&D Test/Break-point (Watch) registers for emulation & debug * Performance counter for system and software tuning & debug * Fourteen fully prioritized vectored interrupts -- 10 external, 2 internal, 2 software Fully static CMOS design with dynamic power down logic
*
*
*
*
*
*
*
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2
Block Diagram
Figure 1 Block Diagram
Secondary Tags Set A 256KB Secondary Cache, 4-way Set Associative Secondary Tags Set B DTag DTLB ITag ITLB Primary Instruction Cache 4-way Set Associative A/D Bus Pad Bus
Primary Data Cache 4-way Set Associative
Store Buffer Write Buffer Read Buffer
Pad Buffer Address Buffer
Prefetch Buffer Instruction Dispatch Unit F Pipe Register M Pipe Register
F-Pipe Bus M-Pipe Bus D Bus
Floating-Point Control
Floating-Point Load/Align Floating-Point Register File Packer/Unpacker Comparator Floating-Point MultAdd, Add, Sub, Cvt, Div, Sqrt Multiplier Array
Joint TLB Coprocessor 0 System/Memory Control PC Incrementer Branch PC Adder ITLB Virtual Program Counter
DVA
IVA
FA Bus
DTLB Virtual PLL/Clocks Int Mult, Div, Madd
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Integer Control
Load Aligner Integer Register File M Pipe F Pipe Adder Adder StAIn/Sh Shifter Logicals Logicals
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3
Description
PMC-Sierra's RM7065A is a highly integrated symmetric superscalar microprocessor capable of issuing two instructions each processor cycle. It has two high-performance 64-bit integer units as well as a high-throughput, fully pipelined 64-bit floating point unit. The RM7065A integrates 16 KB 4-way set associative instruction and data caches along with an integrated 256 KB 4-way set associative secondary. The primary data and secondary caches are write-back and non-blocking. The memory management unit contains a 64/48-entry fully associative TLB and a 64-bit system interface supporting multiple outstanding reads with out-of-order return and hardware prioritized and vectored interrupts. The RM7065A ideally suits high-end embedded control applications such as internetworking, high-performance image manipulation, high-speed printing, and 3-D visualization. The RM7065A is also applicable to the low end workstation market where its balanced integer and floating-point performance provide outstanding price/performance.
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4
Hardware Overview
The RM7065A offers a high-level of integration targeted at high-performance embedded applications. The key elements of the RM7065A are described throughout this section.
4.1
CPU Registers
The RM7065A CPU contains 32 general purpose registers (GPR), two special purpose registers for integer multiplication and division, and a program counter; there are no condition code bits. Figure 2 shows the user visible state.
Figure 2
63 0 r1 r2 * * * * r29 r30 r31 63 LO
CP0 Registers
0
General Purpose Registers Multiply/Divide Registers
63 HI 0 0
Program Counter
63 PC 0
4.2
Superscalar Dispatch
The RM7065A incorporates a superscalar dispatch unit that allows it to issue up to two instructions per cycle. For purposes of instruction issue, the RM7065A defines four classes of instructions: integer, load/store, branches, and floating-point. There are two logical pipelines, the function, or F, pipeline and the memory, or M, pipeline. Note however that the M pipe can execute integer as well as memory type instructions.
Table 1 Instruction Issue Rules F Pipe
one of: integer, branch, floating-point, integer mul, div
M Pipe
one of: integer, load/store
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RM7065ATM Microprocessor with On-Chip Secondary Cache Data Sheet Preliminary
Figure 2 is a simplification of the pipeline section and illustrates the basics of the instruction issue mechanism.
Figure 3 Instruction Issue Paradigm
Instruction Cache
Dispatch Unit F Pipe IBus M Pipe IBus
FP F Pipe
FP M Pipe
Integer F Pipe
Integer M Pipe
The figure illustrates that one F pipe instruction and one M pipe instruction can be issued concurrently but that two M pipe or two F pipe instructions cannot be issued. Table 2 specifies more completely the instructions within each class.
Table 2 Dual Issue Instruction Classes integer
add, sub, or, xor, shift, etc.
load/store
lw, sw, ld, sd, ldc1, sdc1, mov, movc, fmov, etc.
floatingpoint
fadd, fsub, fmult, fmadd, fdiv, fcmp, fsqrt, etc.
branch
beq, bne, bCzT, bCzF, j, etc.
4.3
Pipeline
The logical length of both the F and M pipelines is five stages with state committing in the register write, or W, pipe stage. The physical length of the floating-point execution pipeline is actually seven stages but this is completely transparent to the user. Figure 4 shows instruction execution within the RM7065A when instructions are issuing simultaneously down both pipelines. As illustrated in the figure, up to ten instructions can be executing simultaneously. This figure presents a somewhat simplistic view of the processors operation since the out-of-order completion of loads, stores, and long latency floating-point operations can result in there being even more instructions in process than what is shown.
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RM7065ATM Microprocessor with On-Chip Secondary Cache Data Sheet Preliminary
Figure 4 Pipeline
I0 I1 I2 I3 I4 I5 I6 I7 I8 I9 1I 1I 2I 2I 1R 1R 1I 1I 2R 2R 2I 2I 1A 1A 1R 1R 1I 1I 2A 2A 2R 2R 2I 2I 1D 1D 1A 1A 1R 1R 1I 1I 2D 2D 2A 2A 2R 2R 2I 2I 1W 1W 1D 1D 1A 1A 1R 1R 1I 1I 2W 2W 2D 2D 2A 2A 2R 2R 2I 2I 1W 1W 1D 1D 1A 1A 1R 1R 2W 2W 2D 2D 2A 2A 2R 2R 1W 1W 1D 1D 1A 1A 2W 2W 2D 2D 2A 2A 1W 1W 1D 1D 2W 2W 2D 2D 1W 1W 2W 2W
1I-1R: 2I: 2R: 1A: 1A: 1A-2A: 2A: 2A-2D: 1D: 2W:
one cycle Instruction cache access Instruction virtual to physical address translation Register file read, Bypass calculation, Instruction decode, Branch address calculation Issue or slip decision, Branch decision Data virtual address calculation Integer add, logical, shift Store Align Data cache access and load align Data virtual to physical address translation Register file write
Note that instruction dependencies, resource conflicts, and branches may result in some of the instruction slots being occupied by NOPs.
4.4
Integer Unit
The RM7065A implements the MIPS IV Instruction Set Architecture. Additionally, the RM7065A includes two implementation specific instructions not found in the baseline MIPS IV ISA, but that are useful in the embedded market place. These instructions are integer multiply-accumulate (MAD) and three-operand integer multiply (MUL). The RM7065A integer unit includes thirty-two general purpose 64-bit registers, the HI/LO result registers for two-operand integer multiply/divide operations, and the program counter, or PC. There are two separate execution units, one of which can execute function (F) type instructions and one which can execute memory (M) type instructions. Refer to Table 1 for the instruction issue rules. Note that integer multiply/divide instructions, as well as their corresponding MFHI and MFLO instructions, can only be executed in the F type execution unit. Within each execution unit the operational characteristics are the same as on previous MIPS designs with single cycle ALU operations (add, sub, logical, shift), one cycle load delay, and an autonomous multiply/divide unit.
Register File
The RM7065A has thirty-two general purpose registers with register location 0 (r0) hard wired to a zero value. These registers are used for scalar integer operations and address calculation. In order to service the two integer execution units, the register file has four read ports and two write ports and is fully bypassed both within and between the two execution units to minimize operation latency in the pipeline.
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4.5
ALU
The RM7065A has two complete integer ALUs each consisting of an integer adder/subtractor, a logic unit, and a shifter. Table 3 shows the functions performed by the ALUs for each execution unit. Each of these units is optimized to perform all operations in a single processor cycle.
Table 3 ALU Operations Unit
Adder Logic Shifter
F Pipe
add, sub
M Pipe
add, sub, data address add
logic, moves, zero shifts logic, moves, zero shifts (nop) (nop) non zero shift non zero shift, store align
4.6
Integer Multiply/Divide
The RM7065A has a single dedicated integer multiply/divide unit optimized for high-speed multiply and multiply-accumulate operations. The multiply/divide unit resides in the F type execution unit. Table 4 shows the performance of the multiply/divide unit on each operation.
Table 4 Integer Multiply/Divide Operations Opcode
MULT/U, MAD/U MUL DMULT, DMULTU DIV, DIVD DDIV, DDIVU
Operand Size
16 bit 32 bit 16 bit 32 bit any any any
Latency
4 5 4 5 9 36 68
Repeat Rate
3 4 3 4 8 36 68
Stall Cycles
0 0 2 3 0 0 0
The baseline MIPS IV ISA specifies that the results of a multiply or divide operation be placed in the Hi and Lo registers. These values can then be transferred to the general purpose register file using the Move-from-Hi and Move-from-Lo (MFHI/MFLO) instructions. In addition to the baseline MIPS IV integer multiply instructions, the RM7065A also implements the 3-operand multiply instruction, MUL. This instruction specifies that the multiply result go directly to the integer register file rather than the Lo register. The portion of the multiply that would have normally gone into the Hi register is discarded. For applications where it is known that the upper half of the multiply result is not required, using the MUL instruction eliminates the necessity of executing an explicit MFLO instruction. The multiply-add instructions, MAD and MADU, multiply two operands and add the resulting product to the current contents of the Hi and Lo registers. The multiply-accumulate operation is
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RM7065ATM Microprocessor with On-Chip Secondary Cache Data Sheet Preliminary
the core primitive of almost all signal processing algorithms. Therefore, using the RM7065A eliminates the need for a separate DSP engine in many embedded applications.
4.7
Floating-Point Coprocessor
The RM7065A incorporates a high-performance fully pipelined floating-point coprocessor which includes a floating-point register file and autonomous execution units for multiply/add/convert and divide/square root. The floating-point coprocessor is a tightly coupled execution unit, decoding and executing instructions in parallel with, and in the case of floating-point loads and stores, in cooperation with the M pipe of the integer unit. The superscalar capabilities of the RM7065A allow floating-point computation instructions to issue concurrently with integer instructions.
4.8
Floating-Point Unit
The RM7065A floating-point execution unit supports single and double precision arithmetic, as specified in the IEEE Standard 754. The execution unit is broken into a separate divide/square root unit and a pipelined multiply/add unit. Overlap of divide/square root and multiply/add is supported. The RM7065A maintains fully precise floating-point exceptions while allowing both overlapped and pipelined operations. Precise exceptions are extremely important in object-oriented programming environments and highly desirable for debugging in any environment. Floating-point operations include: * * * * * * * * * * * add subtract multiply divide square root reciprocal reciprocal square root conditional moves conversion between fixed-point and floating-point format conversion between floating-point formats floating-point compare
Table 5 gives the latencies of the floating-point instructions in internal processor cycles.
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RM7065ATM Microprocessor with On-Chip Secondary Cache Data Sheet Preliminary
Table 5 Floating Point Latencies and Repeat Rates Operation
fadd fsub fmult fmadd fmsub fdiv fsqrt frecip frsqrt fcvt.s.d fcvt.s.w fcvt.s.l fcvt.d.s fcvt.d.w fcvt.d.l fcvt.w.s fcvt.w.d fcvt.l.s fcvt.l.d fcmp fmov, fmovc fabs, fneg
Latency single/double
4 4 4/5 4/5 4/5 21/36 21/36 21/36 38/68 4 6 6 4 4 4 4 4 4 4 1 1 1
Repeat Rate single/double
1 1 1/2 1/2 1/2 19/34 19/34 19/34 36/66 1 3 3 1 1 1 1 1 1 1 1 1 1
4.9
Floating-Point General Register File
The floating-point general register file (FGR) is made up of thirty-two 64-bit registers. With the floating-point load and store double instructions, LDC1 and SDC1, the floating-point unit can take advantage of the 64-bit wide data cache and issue a floating-point coprocessor load or store doubleword instruction in every cycle. The floating-point control register file contains two registers; one for determining configuration and revision information for the coprocessor, and one for control and status information. These registers are primarily used for diagnostic software, exception handling, state saving and restoring, and control of rounding modes. To support superscalar operations the FGR has four read ports and two write ports and is fully bypassed to minimize operation latency in the pipeline. Three of the read ports and one write port are used to support the combined multiply-add instruction while the fourth read and second write port allows for concurrent floating-point load or store and conditional move operations.
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4.10 System Control Coprocessor (CP0)
The system control coprocessor (CP0) is responsible for the virtual memory sub-system, the exception control system, and the diagnostics capability of the processor. For memory management support, the RM7065A CP0 is logically identical to the RM5200 Family. For interrupt exceptions and diagnostics, the RM7065A is a superset of the RM5200 Family, implementing additional features described in the following sections on Interrupts, Test/ Breakpoint registers, and Performance Counters. The memory management unit controls the virtual memory system page mapping. It consists of an instruction address translation buffer (ITLB) a data address translation buffer (DTLB), a Joint TLB (JTLB), and coprocessor registers used by the virtual memory mapping sub-system.
4.11 System Control Coprocessor Registers
The RM7065A incorporates all CP0 registers internally. These registers provide the path through which the virtual memory system's page mapping is examined and modified, exceptions are handled, and operating modes are controlled (kernel vs. user mode, interrupts enabled or disabled, cache features). In addition, the RM7065A includes registers to implement a real-time cycle counting facility, to aid in cache and system diagnostics, and to assist in data error detection. To support the non-blocking caches and enhanced interrupt handling capabilities of the RM7065A, both the data and control register spaces of CP0 are supported. In the data register space, which is accessed using the MFC0 and MTC0 instructions, the RM7065A supports the same registers as found in the RM5200 Family. In the control space, which is accessed by the previously unused CTC0 and CFC0 instructions, the RM7065A supports five new registers. The first three of these new 32-bit registers support the enhanced interrupt handling capabilities; Interrupt Control, Interrupt Priority Level Lo (IPLLO), and Interrupt Priority Level Hi (IPLHI). These registers are described further in the section on interrupt handling. Two other registers, Imprecise Error 1 and Imprecise Error 2, have been added to help diagnose bus errors that occur on non-blocking memory references. Figure 5 shows the CP0 registers.
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Figure 5 CP0 Registers
PageMask 5* EntryHi 10* 47 EntryLo0 2* EntryLo1 3* Info 7* Index 0* TLB Random 1* Wired 6* (entries protected from TLBWR) 0 LLAddr 17* TagLo 28* TagHi 29* PRId 15* Config 16* Watch2 19* ECC 26* XContext 20* CacheErr 27* ErrorEPC 30* Imp Error 2 27* Context 4* Count 9* Status 12* EPC 14* BadVAddr 8* Compare 11* Cause 13* Watch1 18* Watch Mask 24* Perf Counter 25* Perf Ctr Cntrl 22* IPLLO 18* IPLHI 19* IntControl 20* Imp Error 1 26*
Used for memory management
* Register number
Used for exception processing
Control Space Registers
4.12 Virtual to Physical Address Mapping
The RM7065A provides three modes of virtual addressing: * * * user mode kernel mode supervisor mode
These modes allow system software to provide a secure environment for user processes. Bits in the CP0 Status register determine which virtual addressing mode is used. In user mode, the RM7065A provides a single, uniform virtual address space of 256 GB (2 GB in 32-bit mode). When operating in the kernel mode, four distinct virtual address spaces, totalling 1024 GB (4 GB in 32-bit mode), are simultaneously available and are differentiated by the high-order bits of the virtual address. The RM7065A processor also supports a supervisor mode in which the virtual address space is 256.5 GB (2.5 GB in 32-bit mode), divided into three regions based on the high-order bits of the virtual address. Figure 6 shows the address space layout for 32-bit operations.
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Figure 6
Kernel Mode Virtual Addressing (32-bit)
Kernel virtual address space (kseg3) Mapped, 0.5GB Supervisor virtual address space (ksseg) Mapped, 0.5GB Uncached kernel physical address space (kseg1) Unmapped, 0.5GB Cached kernel physical address space (kseg0) Unmapped, 0.5GB User virtual address space (kuseg) Mapped, 2.0GB
0xFFFFFFFF
0xE0000000
0xDFFFFFFF
0xC0000000
0xBFFFFFFF
0xA0000000
0x9FFFFFFF
0x80000000
0x7FFFFFFF
0x00000000
When the RM7065A is configured for 64-bit addressing, the virtual address space layout is an upward compatible extension of the 32-bit virtual address space layout.
4.13 Joint TLB
For fast virtual-to-physical address translation, the RM7065A uses a large, fully associative TLB that maps virtual pages to their corresponding physical addresses. As indicated by its name, the JTLB is used for both instruction and data translations. The JTLB is organized as pairs of even/odd entries, and maps a virtual address and address space identifier (ASID) into the large, 64 GB physical address space. By default, the JTLB is configured as 48 pairs of even/odd entries. The optional 64 even/odd entry configuration is set at boot time. Two mechanisms are provided to assist in controlling the amount of mapped space and the replacement characteristics of various memory regions. First, the page size can be configured, on a per-entry basis, to use page sizes in the range of 4 KB to 16 MB (in 4x multiples). The CP0 PageMask register is loaded with the desired page size of a mapping, and that size is stored into the TLB, along with the virtual address, when a new entry is written. Thus, operating systems can
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create special purpose maps; for example, an entire frame buffer can be memory mapped using only one TLB entry. The second mechanism controls the replacement algorithm when a TLB miss occurs. The RM7065A provides a random replacement algorithm to select a TLB entry to be written with a new mapping. However, the processor also provides a mechanism whereby a system specific number of mappings can be locked into the TLB, thereby avoiding random replacement. This mechanism uses the CP0 Wired register and allows the operating system to guarantee that certain pages are always mapped for performance reasons and to avoid a deadlock condition. This mechanism also facilitates the design of real-time systems by allowing deterministic access to critical software. The JTLB also contains information that controls the cache coherency protocol for each page. Specifically, each page has attribute bits to determine whether the coherency algorithm is: * * * * * uncached write-back write-through with write-allocate write-through without write-allocate write-back with secondary bypass
Note that both of the write-through protocols bypass the secondary cache since it does not support writes of less than a complete cache line. These protocols are used for both code and data on the RM7065A with data using write-back or write-through depending on the application. The write-through modes support the same efficient frame buffer handling as the RM5200 Family.
4.14 Instruction TLB
The RM7065A uses a 4-entry instruction TLB (ITLB). The ITLB offers the following advantages; * * * * Minimizes contention for the JTLB Eliminates the critical path of translating through a large associative array Allows instruction address and data address translations to occur in parallel Saves power
Each ITLB entry maps a 4 KB page. The ITLB improves performance by allowing instruction address translation to occur in parallel with data address translation. When a miss occurs on an instruction address translation by the ITLB, the least-recently used ITLB entry is filled from the JTLB. The operation of the ITLB is completely transparent to the user.
4.15 Data TLB
The RM7065A uses a 4-entry data TLB (DTLB) for the same reasons cited above for the ITLB. Each DTLB entry maps a 4 KB page. The DTLB improves performance by allowing data address translation to occur in parallel with instruction address translation. When a miss occurs on a data address translation, the DTLB is filled from the JTLB. The DTLB refill is pseudo-LRU; the least recently used entry of the least recently used pair of entries is filled. The operation of the DTLB is completely transparent to the user.
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4.16 Cache Memory
The RM7065A contains integrated primary instruction and data caches that support single cycle access, as well as a large unified secondary cache with a three cycle miss penalty from the primary caches. Each primary cache has a 64-bit read path and a 128-bit write path. Both caches can be accessed simultaneously. The primary caches provide the integer and floating-point units with an aggregate bandwidth of 5.6 GB per second at an internal clock frequency of 350 MHz. During an instruction or data primary cache refill, the secondary cache can provide a 64-bit datum every cycle following the initial three cycle latency for a peak bandwidth of 2.8 GB per second.
4.17 Instruction Cache
The RM7065A has an integrated 16 KB, four-way set associative instruction cache that is virtually indexed and physically tagged. The effective physical index eliminates the potential for virtual aliases in the cache. The data array portion of the instruction cache is 64 bits wide and protected by word parity while the tag array holds a 24-bit physical address, 14 control bits, a valid bit, and a single parity bit. By accessing 64 bits per cycle, the instruction cache is able to supply two instructions per cycle to the superscalar dispatch unit. For signal processing, graphics, and other numerical code sequences where a floating-point load or store and a floating-point computation instruction are being issued together in a loop, the entire bandwidth available from the instruction cache is consumed by instruction issue. For typical integer code mixes, where instruction dependencies and other resource constraints restrict the level of parallelism that can be achieved, the extra instruction cache bandwidth is used to fetch both the taken and non-taken branch paths to minimize the overall penalty for branches. A 32-byte (eight instruction) line size is used to maximize the communication efficiency between the instruction cache and the secondary cache or memory system. The RM7065A supports cache locking on a per line basis. The contents of each line of the cache can be locked by setting a bit in the Tag RAM. Locking the line prevents its contents from being overwritten by a subsequent cache miss. Refills occur only into unlocked cache lines. This mechanism allows the programmer to lock critical code into the cache, thereby guaranteeing deterministic behavior for the locked code sequence.
4.18 Data Cache
The RM7065A has an integrated 16 KB, four-way set associative data cache that is virtually indexed and physically tagged. Line size is 32 bytes (8 words). The effective physical index eliminates the potential for virtual aliases in the cache. The data cache is non-blocking; that is, a miss in the data cache does not necessarily stall the processor pipeline. As long as no instruction is encountered which is dependent on the data reference which caused the miss, the pipeline continues to advance. Once there are two cache misses outstanding, the processor stalls if it encounters another load or store instruction. The data array portion of the data cache is 64 bits wide and protected by byte parity while the tag array holds a 24-bit physical address, 3 control bits, a two-bit cache state field, and two parity bits.
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The most commonly used write policy is write-back, which means that a store to a cache line does not immediately cause memory to be updated. This increases system performance by reducing bus traffic and eliminating the bottleneck of waiting for each store operation to finish before issuing a subsequent memory operation. Software can, however, select write-through on a per-page basis when appropriate, such as for frame buffers. Cache protocols supported for the data cache are as follows: 1. Uncached Reads to addresses in a memory area identified as uncached do not access the cache. Writes to such addresses are written directly to main memory without updating the cache. 2. Write-back Loads and instruction fetches first search the cache, reading the next memory hierarchy level only if the desired data is not cache resident. On data store operations, the cache is first searched to determine if the target address is cache resident. If it is resident, the cache contents are updated and the cache line is marked for later write-back. If the cache lookup misses, the target line is first brought into the cache, afterwhich the write is performed as above. 3. Write-through with write allocate Loads and instruction fetches first search the cache, reading from memory only if the desired data is not cache resident; write-through data is never cached in the secondary cache. On data store operations, the cache is first searched to determine if the target address is cache resident. If it is resident, the primary cache contents are updated and main memory is written, leaving the write-back bit of the cache line unchanged; no writes occur to the secondary cache. If the cache lookup misses, the target line is first brought into the cache, afterwhich the write is performed as above. 4. Write-through without write allocate Loads and instruction fetches first search the cache, reading from memory only if the desired data is not cache resident; write-through data is never cached in the secondary cache. On data store operations, the cache is first searched to determine if the target address is cache resident. If it is resident, the cache contents are updated and main memory is written, leaving the writeback bit of the cache line unchanged; no writes occur to the secondary cache. If the cache lookup misses, only main memory is written. 5. Fast Packet CacheTM (Write-back with secondary bypass) Loads and instruction fetches first search the primary cache, reading from memory only if the desired data is not resident; the secondary cache is not searched. On data store operations, the primary cache is first searched to determine if the target address is resident. If it is resident, the cache contents are updated, and the cache line marked for later write-back. If the cache lookup misses, the target line is first brought into the cache, afterwhich the write is performed as above. Associated with the data cache is the store buffer. When the RM7065A executes a STORE instruction, this single-entry buffer is written with the store data while the tag comparison is performed. If the tag matches, then the data is written into the data cache in the next cycle that the data cache is not accessed (the next non-load cycle). The store buffer allows the RM7065A to
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execute a store every processor cycle and to perform back-to-back stores without penalty. In the event of a store immediately followed by a load to the same address, a combined merge and cache write occurs such that no penalty is incurred.
4.19 Secondary Cache
The RM7065A has an integrated 256 KB, four-way set associative, block write-back secondary cache. The secondary cache has a 32-byte line size, a 64-bit bus width to match the system interface and primary cache bus widths, and is protected with doubleword parity. The secondary cache tag array holds a 20-bit physical address, 2 control bits, a three bit cache state field, and two parity bits. By integrating a secondary cache, the RM7065A is able to decrease the latency of a primary cache miss without significantly increasing the number of pins and the amount of power required by the processor. From a technology point of view, integrating a secondary cache leverages CMOS technology by using silicon to build the structures that are most amenable to silicon technology; building very dense, low power memory arrays rather than large power hungry I/O buffers. Further benefits of an integrated secondary cache are flexibility in the cache organization and management policies that are not practical with an external cache. Two previously mentioned examples are the 4-way associativity and write-back cache protocol. A third management policy for which integration affords flexibility is cache hierarchy management. With multiple levels of cache, it is necessary to specify a policy for dealing with cases where two cache lines at level n of the hierarchy could possibly be sharing an entry in level n+1 of the hierarchy. The RM7065A allows entries to be stored in the primary caches that do not necessarily have a corresponding entry in the secondary; the RM7065A does not force the primaries to be a subset of the secondary. For example, if primary cache line A is being filled and a cache line already exists in the secondary for primary cache line B at the location where primary A's line would reside, then that secondary entry is replaced by an entry corresponding to primary cache line A and no action occurs in the primary for cache line B. This operation creates the aforementioned scenario where the primary cache line, which initially had a corresponding secondary entry, no longer has such an entry. Such a primary line is called an orphan. In general, cache lines at level n+1 of the hierarchy are called parents of level n's children. Another RM7065A cache management optimization occurs for the case of a secondary cache line replacement where the secondary line is dirty and has a corresponding dirty line in the primary. In this case, since it is permissible to leave the dirty line in the primary, it is not necessary to write the secondary line back to main memory. Taking this scenario one step further, a final optimization occurs when the aforementioned dirty primary line is replaced by another line and must be written back. In this case it is written directly to memory, bypassing the secondary cache.
4.20 Secondary Caching Protocols
Unlike the primary data cache, the secondary cache supports only uncached and block write-back. As noted earlier, cache lines managed with either of the write-through protocols are not placed in the secondary cache. A new caching attribute, write-back with secondary bypass, allows the secondary cache to be bypassed entirely. When this attribute is selected, the secondary cache is not filled on load misses and are not written on dirty write-backs from the primary cache
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The RM7065A cache attributes for the instruction, data, internal secondary caches are summarized in Table 6.
Table 6 Cache Attributes Attribute
Size Associativity Replacement Algorithm Line size Index Tag Write policy read policy
Instruction
16KB 4-way cyclic 32 byte vAddr11..0 pAddr35..12 n.a. n.a.
Data
16KB 4-way cyclic 32 byte vAddr11..0 pAddr35..12 write-back, write-through
Secondary
256KB 4-way cyclic 32 byte pAddr15..0 pAddr35..16 block writeback, bypass
non-blocking (2 non-blocking outstanding) (data only, 2 outstanding) critical word first critical word first sequential sequential first double (if n.a. waiting for data) per byte per doubleword
read order write order miss restart following: Parity
critical word first NA complete line per word
4.21 Cache Locking
The RM7065A allows critical code or data fragments to be locked into the primary and secondary caches. The user has complete control over the locking function. For instruction and data fragments in the primary caches, locking is accomplished by setting either or both of the cache lock enable bits and specifying the set in the CP0 ECC register, then executing either a load instruction for data, or a Fill_I cache operation for instructions. Only sets A and B within each cache can be locked. Locking within the secondary works identically to the primaries using a separate secondary lock enable bit and the same set selection field. As with the primaries, only sets A and B can be locked. Table 7 summarizes the cache locking capabilities.
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Table 7 Cache Locking Control Cache
Primary I Primary D Secondary
Lock Enable
ECC[27] ECC[26] ECC[25]
Set Select
ECC[28]=0A ECC[28]=1B ECC[28]=0A ECC[28]=1B ECC[28]=0A ECC[28]=1B
Activate
Fill_I Load/Store Fill_I or Load/Store
4.22 Cache Management
To improve the performance of critical data movement operations in the embedded environment, the RM7065A significantly improves the speed of operation of certain critical cache management operations. In particular, the speed of the Hit-Writeback-Invalidate and Hit-Invalidate cache operations has been improved, in some cases by an order of magnitude, over that of other MIPS processors. For example, Table 8 compares the RM7065A with the R4000 processor.
Table 8 Penalty Cycles Penalty Operation
Hit-WritebackInvalidate
Condition RM7065A
Miss Hit-Clean Hit-Dirty Miss Hit 0 3 3+n 0 2
R4000
7 12 14+n 7 9
Hit-Invalidate
For the Hit-Dirty case of Hit-Writeback-Invalidate in Table 8 above, if the writeback buffer is full from some previous cache eviction, then n is the number of cycles required to empty the writeback buffer. If the buffer is empty then n is zero. The penalty value in Table 8 is the number of processor cycles beyond the one cycle required to issue the instruction that is required to implement the operation.
4.23 Primary Write Buffer
Writes to secondary cache or external memory, whether cache miss write-backs or stores to uncached or write-through addresses, use the integrated primary write buffer. The write buffer holds up to four 64-bit address and data pairs. The entire buffer is used for a data cache write-back and allows the processor to proceed in parallel with memory update. For uncached and writethrough stores, the write buffer significantly increases performance by decoupling the SysAD bus transfers from the instruction execution stream.
4.24 System Interface
The RM7065A provides a high-performance 64-bit system interface which is compatible with the RM5200 Family. As an enhancement to the SysAD bus interface, the RM7065A allows half-
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integral clock multipliers, thereby providing greater granularity when selecting pipeline and system interface frequencies. The SysAD interface consists of a 64-bit Address/Data bus with 8 check bits and a 9-bit command bus. In addition, there are ten handshake signals and ten interrupt inputs. The interface is capable of transferring data between the processor and memory at a peak rate of 1000 MB/sec with a 125 MHz SysClock. Figure 7 shows a typical embedded system using the RM7065A. This example shows a system with a bank of DRAMs and an interface ASIC which provides DRAM control as well as an I/O port.
Figure 7 Typical Embedded System Block Diagram
DRAM Flash/ Boot ROM Address Control x x
72 8
Latch
72
SysAD Bus
72 25
RM7065A
SysCmd
Memory I/O Controller
PCI Bus
4.25 System Address/Data Bus
The 64-bit System Address Data (SysAD) bus is used to transfer addresses and data between the RM7065A and the rest of the system. It is protected with an 8-bit parity check bus, SysADC[7:0]. The system interface is configurable to allow easy interfacing to memory and I/O systems of varying frequencies. The data rate and the bus frequency at which the RM7065A transmits data to the system interface are programmable at boot time via mode control bits. In addition, the rate at which the processor receives data is fully controlled by the external device. Therefore, either a low cost interface requiring no read or write buffering, or a faster, high-performance interface can be designed to communicate with the RM7065A.
4.26 System Command Bus
The RM7065A interface has a 9-bit System Command bus, SysCmd[8:0]. The command bus indicates whether the SysAD bus carries address or data information on a per-clock basis. If the SysAD bus carries address, the SysCmd bus indicates the transaction type (for example, a read or write). If the SysAD bus carries data, then the SysCmd bus contains information about the data (for example, this is the last data word transmitted, or the data contains an error). The SysCmd bus is bidirectional to support both processor requests and external requests to the RM7065A. Processor requests are initiated by the RM7065A and responded to by an external device. External requests are issued by an external device and require the RM7065A to respond. The RM7065A supports one- to eight-byte transfers as well as 32-byte block transfers on the SysAD bus. In the case of a sub-doubleword transfer, the 3 low-order address bits give the byte address of the transfer, and the SysCmd bus indicates the number of bytes being transferred.
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4.27 Handshake Signals
There are ten handshake signals on the system interface. Two of these, RdRdy* and WrRdy*, are driven by an external device to indicate to the RM7065A whether it can accept a new read or write transaction. The RM7065A samples these signals before deasserting the address on read and write requests. ExtRqst* and Release* are used to transfer control of the SysAD and SysCmd buses from the processor to an external device. When an external device requires control of the bus, it asserts ExtRqst*. The RM7065A responds by asserting Release* to release the system interface to slave state. PRqst* and PAck* are used to transfer control of the SysAD and SysCmd buses from the external agent to the processor. These two pins have been added to the SysAD interface to support multiple outstanding reads and facilitate non-blocking caches. When the processor needs to reacquire control of the interface, it asserts PRqst*. The external device responds by asserting PAck* to return control of the interface to the processor. RspSwap* is also a new pin and is used by the external agent to indicate to the processor when it is returning data out of order. For example, when there are two outstanding reads, the external agent asserts RspSwap* when it is going to return the data for the second read before it returns the data for the first read. RdType is another new pin on the interface that indicates whether a read is an instruction read or a data read. When asserted, the reference is an instruction read. When deasserted it is a data read. RdType is only valid during valid address cycles. ValidOut* and ValidIn* are used by the RM7065A and the external device respectively to indicate that there is a valid command or data on the SysAD and SysCmd buses. The RM7065A asserts ValidOut* when it is driving these buses with a valid command or data, and the external device drives ValidIn* when it has control of the buses and is driving a valid command or data.
4.28 System Interface Operation
To support non-blocking caches and data prefetch instructions, the RM7065A allows two outstanding reads. An external device may respond to read requests in whatever order it chooses by using the response order indicator pin RspSwap*. No more than two read requests are submitted to the external device. Support for multiple outstanding reads can be enabled or disabled via a boot-time mode bit. Refer to Table 16 for a complete list of mode bits. The RM7065A can issue read and write requests to an external device, while an external device can issue null and write requests to the RM7065A. For processor reads, the RM7065A asserts ValidOut* and simultaneously drives the address and read command on the SysAD and SysCmd buses. If the system interface has RdRdy* asserted, then the processor tristates its drivers and releases the system interface to slave state by asserting Release*. The external device can then begin sending data to the RM7065A. Figure 8 shows a processor block read request and the corresponding external agent read response.
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Figure 8 Processor Block Read
SysClock
SysAD
Addr Read
Data0
Data1 NData
Data2 NData
Data3 NEOD
SysCmd ValidOut* ValidIn*
NData
RdRdy* WrRdy*
Release*
In Figure 8 the read latency is 4 cycles (ValidOut* to ValidIn*), and the response data pattern is DDxxDD. Figure 9 shows a processor block write where the processor was programmed with write-back data rate boot code 2, or DDxxDDxx. Finally, Figure 10 shows a typical sequence resulting in two outstanding reads, as explained in the following sequence. 1. The processor issues a read. 2. The external agent takes control of the bus in preparation for returning data to the processor. 3. The processor encounters another internal cache miss and therefore asserts PRqst* in order to regain control of the bus. 4. The external agent pulses PAck*, returning control of the bus to the processor. 5. The processor issues a read for the second miss. 6. The RspSwap* pin is asserted to denote the out of order response. Not shown in the figure is the completion of the data transfer for the second miss, or any of the data transfer for the first miss. 7. The external agent retakes control of the bus and begins returning data (out of order) for the second miss to the processor
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Figure 9 Processor Block Write
SysClock Addr Write Data0 NData Data1 NData Data2 NData Data3 NEOD
SysAD
SysCmd ValidOut* ValidIn*
RdRdy* WrRdy*
Release*
Figure 10 Multiple Outstanding Reads
Master SysClock SysAD SysCmd RspSwap* ValidOut* Addr1 Read1 Data0 Data1 Addr2 Read2 Data0 Data1 Data02 NData Data12 NData Processor Processor System Processor Processor System
2
5
6
7
ValidIn* Release* PRqst*
3 4
PAck*
4.29 Data Prefetch
The RM7065A is the first PMC-Sierra design to support the MIPS IV integer data prefetch (PREF) and floating-point data prefetch (PREFX) instructions. These instructions are used by the compiler or by an assembly language programmer when it is known or suspected that an upcoming data reference is going to miss in the cache. By appropriately placing a prefetch instruction, the memory latency can be hidden under the execution of other instructions. In cases where the execution of a prefetch instruction would cause a memory management or address error exception the prefetch is treated as a NOP. The "Hint" field of the data prefetch instruction is used to specify the action taken by the instruction. The instruction can operate normally (that is, fetching data as if for a load operation) or it can allocate and fill a cache line with zeroes on a primary data cache miss.
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4.30 Enhanced Write Modes
The RM7065A implements two enhancements to the original R4000 write mechanism: Write Reissue and Pipeline Writes. The original R4000 allowed a write on the SysAD bus every four SysClock cycles. Hence for a non-block write, this meant that two out of every four cycles were wait states. Pipelined write mode eliminates these two wait states by allowing the processor to drive a new write address onto the bus immediately after the previous data cycle. This allows for higher SysAD bus utilization. However, at high frequencies the processor may drive a subsequent write onto the bus prior to the time the external agent deasserts WrRdy*, indicating that it can not accept another write cycle. This can cause the cycle to be aborted. Write reissue mode is an enhancement to pipelined write mode and allows the processor to reissue aborted write cycles. If WrRdy* is deasserted during the issue phase of a write operation, the cycle is aborted by the processor and reissued at a later time. In write reissue mode, a rate of one write every two bus cycles can be achieved. Pipelined writes have the same two bus cycle write repeat rate, but can issue one additional write following the deassertion of WrRdy*.
4.31 External Requests
The RM7065A can respond to certain requests issued by an external device. These requests take one of two forms: Write requests and Null requests. An external device executes a write request when it wishes to update one of the processors writable resources such as the internal interrupt register. A null request is executed when the external device wishes the processor to reassert ownership of the processor external interface. Once the external device has acquired control of the processor interface via ExtRqst*, it can execute a null request after completing an independent transaction between itself and system memory in a system where memory is connected directly to the SysAD bus. Normally this transaction would be a DMA read or write from the I/O system.
4.32 Test/Breakpoint Registers
To facilitate hardware and software debugging, the RM7065A incorporates a pair of Test/Breakpoint, or Watch registers, called Watch1 and Watch2. Each Watch register can be separately enabled to watch for a load address, a store address, or an instruction address. All address comparisons are done on physical addresses. An associated register, Watch Mask, has also been added so that either or both of the Watch registers can compare against an address range rather than a specific address. The range granularity is limited to a power of two. When enabled, a match of either Watch register results in an exception. If the Watch is enabled for a load or store address then the exception is the Watch exception as defined for the R4000 by Cause exception code twenty-three. If the Watch is enabled for instruction addresses then a newly defined Instruction Watch exception is taken and the Cause code is sixteen. The Watch register which caused the exception is indicated by Cause bits 25:24. Table 9 summarizes a Watch operation.
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Table 9 Watch Control Register Register
Watch1, 2 Watch Mask
Bit Field/Function
63 Store 62 Load 31:2 Mask 61 Instr 60:36 0 35:2 Addr 1 1:0 0 0
Mask Mask Watch Watch 2 1
Note that the W1 and W2 bits of the Cause register indicate which Watch register caused a particular Watch exception.
4.33 Performance Counters
To facilitate system tuning, the RM7065A implements a performance counter using two new CP0 registers, PerfCount and PerfControl. The PerfCount register is a 32-bit writable counter which causes an interrupt when bit 31 is set. The PerfControl register is a 32-bit register containing a 5bit field which selects one of twenty-two event types as well as a handful of bits which control the overall counting function. Note that only one event type can be counted at a time and that counting can occur for user code, kernel code, or both. The event types and control bits are listed in Table 10.
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Table 10 Performance Counter Control PerfControl Field
4:0
Description
Event Type
00: 01: 02: 03: 04: 05: 06: 07: 08: 09: 0A: 0B: 0C: 0D: 0E: 0F: 10: 11: 12: 13: 14: 15: 16: 17: 18: 19: 1A: 1B: 1C: 1D: 1E: Clock cycles Total instructions issued Floating-point instructions issued Integer instructions issued Load instructions issued Store instructions issued Dual issued pairs Branch prefetches External Cache Misses Stall cycles Secondary cache misses Instruction cache misses Data cache misses Data TLB misses Instruction TLB misses Joint TLB instruction misses Joint TLB data misses Branches taken Branches issued Secondary cache writebacks Primary cache writebacks Dcache miss stall cycles (cycles where both cache miss tokens taken and a third address is requested) Cache misses FP possible exception cycles Slip Cycles due to multiplier busy Coprocessor 0 slip cycles Slip cycles doe to pending non-blocking loads Write buffer full stall cycles Cache instruction stall cycles Multiplier stall cycles Stall cycles due to pending non-blocking loads - stall start of exception
7:5 8
Reserved (must be zero) Count in Kernel Mode
0: 1: Disable Enable
9
Count in User Mode
0: 1: Disable Enable
10
Count Enable
0: 1: Disable Enable
31:11
Reserved (must be zero)
The performance counter interrupt only occurs when interrupts are enabled in the Status register, IE=1, and the Interrupt Mask bit 13 (IM[13]) of the coprocessor 0 interrupt control register is set.
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Since the performance counter can be set up to count clock cycles, it can be used as either a second timer, or a watchdog interrupt. A watchdog interrupt can be used as an aid in debugging system or software "hangs." Typically the software is setup to periodically update the count so that no interrupt occurs. When a hang occurs the interrupt ultimately triggers, thereby breaking free from the hang-up.
4.34 Interrupt Handling
In order to provide better real time interrupt handling, the RM7065A provides an extended set of hardware interrupts, each of which can be separately prioritized and separately vectored. In addition to the standard six external interrupt pins, the RM7065A provides four more interrupt pins for a total of ten external interrupts. As described above, the performance counter is also a hardware interrupt source using Int[13]. Historically in the MIPS architecture, interrupt 7 (Int[7]) was used as the timer interrupt. The RM7065A provides a separate interrupt, Int[12], for this purpose, thereby releasing Int[7] for use as a pure external interrupt. All interrupts (Int[13:0]), the Performance Counter, and the Timer, have corresponding interrupt mask bits, IM[13..0], and interrupt pending bits, IP[13..0], in the Status, Interrupt Control, and Cause registers. The bit assignments for the Interrupt Control and Cause registers are shown in Table 11 and Table 12. The Status register has not changed from the RM5200 Family and is not shown. The IV bit in the Cause register is the global enable bit for the enhanced interrupt features. If this bit is clear then interrupt operation is compatible with the RM5200 Family. In the Interrupt Control register, the interrupt vector spacing is controlled by the Spacing field as described below. The Interrupt Mask field (IM[15:8]) contains the interrupt mask for interrupts eight through thirteen. IM[15:14] are reserved for future use. The Timer Enable (TE) bit is used to gate the Timer Interrupt to the Cause register. If TE is set to "0", the Timer Interrupt is not gated to IP[12]. If TE is set to "1", the Timer Interrupt is gated to IP[12]. The setting for Mode Bit 11 is used to determine if the Timer Interrupt replaces the External Interrupt (Int[5]*) as an input to IP[7] in the Cause register. If Mode Bit 11 is set to "0", Int[5]* is gated to IP[7]. If Mode Bit 11 is set to "1", the Timer Interrupt is gated to IP[7]. In order to utilize both Int[5]* and the internal Timer Interrupt, Mode Bit 11 must be set to "0" and TE must be set to "1". In this case, the Timer Interrupt will use IP[12], and Int[5]* will use IP[7]. Refer to the logic diagram in the RM7000 User Manual for more information on the interrupt signals. The Interrupt Control register uses IM13 to enable the Performance Counter Control. Priority of the interrupts is set via two new coprocessor 0 registers called Interrupt Priority Level Lo (IPLLO) and Interrupt Priority Level Hi (IPLHI).
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Table 11 Cause Register 31
BD
30
0
29,28
CE
27
0
26
W2
25
W1
24
IV
23..8
IP[15..0]
7
0
6..2
EXC
0,1
0
Table 12 Interrupt Control Register 31..16
0
15..8
IM[15..8]
7
TE
6..5
0
4..0
Spacing
Table 13 IPLLO Register 31..28
IPL7
27..24
IPL6
23..20
IPL5
19..16
IPL4
15..12
IPL3
11..8
IPL2
7..4
IPL1
3..0
IPL0
Table 14 IPLHI Register 31..28
0
27..24
0
23..20
IPL13
19..16
IPL12
15..12
IPL11
11..8
IPL10
7..4
IPL9
3..0
IPL8
In the IPLLO and IPLHI registers, each interrupt is represented by a four-bit field, thereby allowing each interrupt to be programmed with a priority level from 0 to 13 inclusive. The priorities can be set in any manner, including having all the priorities set exactly the same. Priority 0 is the highest level and priority 15 the lowest. The format of the priority level registers is shown in Table 13 and Table 14 above. The priority level registers are located in the coprocessor 0 control register space. In addition to programmable priority levels, the RM7065A also permits the spacing between interrupt vectors to be programmed. For example, the minimum spacing between two adjacent vectors is 0x20 while the maximum is 0x200. This programmability allows the user to either set up the vectors as jumps to the actual interrupt routines or, if interrupt latency is paramount, to include the entire interrupt routine at one vector. Table 15 illustrates the complete set of vector spacing selections along with the coding as required in the Interrupt Control register bits 4:0. In general, the active interrupt priority, combined with the spacing setting, generates a vector offset which is then added to the interrupt base address of 0x200 to generate the interrupt exception offset. This offset is then added to the exception base to produce the final interrupt vector address.
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RM7065ATM Microprocessor with On-Chip Secondary Cache Data Sheet Preliminary
Table 15 Interrupt Vector Spacing ICR[4..0]
0x0 0x1 0x2 0x4 0x8 0x10 others
Spacing
0x000 0x020 0x040 0x080 0x100 0x200 reserved
4.35 Standby Mode
The RM7065A provides a means to reduce the amount of power consumed by the internal core when the CPU is not performing any useful operations. This state is known as Standby Mode. Executing the WAIT instruction enables interrupts and causes the processor to enter Standby Mode. If the SysAD bus is currently idle when the WAIT instruction completes the W pipe stage, the internal processor clock stops, thereby freezing the pipeline. The phase lock loop, or PLL, internal timer/counter, and the "wake up" input pins: IP[9.0]*, NMI*, ExtReq*, Reset*, and ColdReset* continue to operate in their normal fashion. If the SysAD bus is not idle when the WAIT instruction completes the W pipe stage, then the WAIT is treated as a NOP until the bus operation is completed. Once the processor is in Standby, any interrupt, including the internally generated timer interrupt, causes the processor to exit Standby and resume operation where it left off. The WAIT instruction is typically inserted in the idle loop of the operating system or real time executive.
4.36 JTAG Interface
The RM7065A interface supports JTAG boundary scan in conformance with IEEE 1149.1. The JTAG interface is useful for checking the integrity of the processor's pin connections.
4.37 Boot-Time Options
The RM7065A operating modes are initialized at power-up by the boot-time mode control interface. The serial boot-time mode control interface operates at a very low frequency (SysClock divided by 256), allowing the initialization information to be kept in a low cost EPROM or system interface ASIC.
4.38 Boot-Time Modes
The boot-time serial mode stream is defined in Table 16. Bit 0 is presented to the processor as the first bit in the stream when VccOK is de-asserted. Bit 255 is the last bit transferred.
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RM7065ATM Microprocessor with On-Chip Secondary Cache Data Sheet Preliminary
Table 16 Boot Time Mode Stream Mode bit Description
0 4:1 Reserved: must be zero Write-back data rate
0: 1: 2: 3: 4: 5: 6: 7: 8: 9-15: DDDD DDxDDx DDxxDDxx DxDxDxDx DDxxxDDxxx DDxxxxDDxxxx DxxDxxDxxDxx DDxxxxxxDDxxxxxx DxxxDxxxDxxxDxxx reserved
Mode bit Description
17:16 19:18 System configuration identifiers - software visible in processor Config[21..20] register Reserved: Must be zero
7:5
SysClock to Pclock Multiplier Mode bit 20 = 0 / Mode bit 20 = 1
0: 1: 2: 3: 4: 5: 6: 7: Multiply by 2/x Multiply by 3/x Multiply by 4/x Multiply by 5/2.5 Multiply by 6/x Multiply by 7/3.5 Multiply by 8/x Multiply by 9/4.5
20
Pclock to SysClock multipliers.
0: 1: Integer multipliers (2,3,4,5,6,7,8,9) Half integer multipliers (2.5,3.5,4.5)
8
Specifies byte ordering. Logically ORed with BigEndian input signal.
0: 1: Little endian Big endian
23:21
Reserved: Must be zero
10:9
Non-Block Write Control
00: 01: 10: 11: R4000 compatible non-block writes reserved pipelined non-block writes non-block write re-issue
24
JTLB Size.
0: 1: 48 dual-entry 64 dual-entry
11
Timer Interrupt Enable/Disable
0: 1: External Int[5]* gated to IP[7] Internal Timer Interrupt gated to IP[7]
25
On-chip secondary cache control.
0: 1: Disable Enable
12
Reserved: Must be zero
26
Enable two outstanding reads with out-oforder return
0: 1: Disable Enable
14:13
Output driver strength - 100% = fastest
00: 01: 10: 11: 67% strength 50% strength 100% strength 83% strength
255:27
Reserved: Must be zero
15
Reserved: Must be zero
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RM7065ATM Microprocessor with On-Chip Secondary Cache Data Sheet Preliminary
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Pin Descriptions
The following is a list of control, data, clock, interrupt, and miscellaneous pins of the RM7065A.
Table 17 System Interface Pin Name
ExtRqst* Release*
Type
Input Output
Description
External request Signals that the system interface is submitting an external request. Release interface Signals that the processor is releasing the system interface to slave state Read Ready Signals that an external agent can now accept a processor read. Write Ready Signals that an external agent can now accept a processor write request. Valid Input Signals that an external agent is now driving a valid address or data on the SysAD bus and a valid command or data identifier on the SysCmd bus. Valid output Signals that the processor is now driving a valid address or data on the SysAD bus and a valid command or data identifier on the SysCmd bus. Processor Request When asserted this signal requests that control of the system interface be returned to the processor. This is enabled by Mode Bit 26. Processor Acknowledge When asserted, in response to PRqst*, this signal indicates to the processor that it has been granted control of the system interface. Response Swap RspSwap* is used by the external agent to signal the processor when it is about to return a memory reference out of order; i.e., of two outstanding memory references, the data for the second reference is being returned ahead of the data for the first reference. Note that this signal works as a toggle; i.e., for each cycle that it is held asserted the order of return is reversed. By default, anytime the processor issues a second read it is assumed that the reads will be returned in order; i.e., no action is required if the reads are indeed returned in order. This is enabled by Mode Bit 26. Read Type During the address cycle of a read request, RdType indicates whether the read request is an instruction read or a data read. System address/data bus A 64-bit address and data bus for communication between the processor and an external agent.
RdRdy* WrRdy*
Input Input
ValidIn*
Input
ValidOut*
Output
PRqst*
Output
PAck*
Input
RspSwap*
Input
RdType
Output
SysAD(63:0)
Input/Output
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RM7065ATM Microprocessor with On-Chip Secondary Cache Data Sheet Preliminary
Pin Name
SysADC(7:0)
Type
Input/Output
Description
System address/data check bus An 8-bit bus containing parity check bits for the SysAD bus during data cycles. System command/data identifier bus A 9-bit bus for command and data identifier transmission between the processor and an external agent. System Command/Data Identifier Bus Parity For the RM7065A, unused on input and zero on output.
SysCmd(8:0)
Input/Output
SysCmdP
Input/Output
Table 18 Clock/Control Interface Pin Name
SysClock
Type
Input
Description
System clock Master clock input used as the system interface reference clock. All output timings are relative to this input clock. Pipeline operation frequency is derived by multiplying this clock up by the factor selected during boot initialization Vcc for PLL Quiet VccInt for the internal phase locked loop. Must be connected to VccInt through a filter circuit. Vss for PLL Quiet Vss for the internal phase locked loop. Must be connected to VssInt through a filter circuit.
VccP
Input
VssP
Input
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RM7065ATM Microprocessor with On-Chip Secondary Cache Data Sheet Preliminary
Table 19 Interrupt Interface Pin Name
IP*(9:0)
Type
Input
Description
Interrupt Ten general processor interrupts, bit-wise ORed with bits 9:0 of the interrupt register. Non-maskable interrupt Non-maskable interrupt, ORed with bit 15 of the interrupt register (bit 6 in R5000 compatibility mode).
NMI*
Input
Table 20 JTAG Interface Pin Name
JTDI JTCK JTDO JTMS
Type
Input Input Output Input
Description
JTAG data in JTAG serial data in. JTAG clock input JTAG serial clock input. JTAG data out JTAG serial data out. JTAG command JTAG command signal, signals that the incoming serial data is command data.
Table 21 Initialization Interface Pin Name
BigEndian
Type
Input
Description
Big Endian / Little Endian Control Allows the system to change the processor addressing mode without rewriting the mode ROM. Vcc is OK When asserted, this signal indicates to the RM7065A that the VccInt power supply has been above the recommended value for more than 100 milliseconds and will remain stable. The assertion of VccOK initiates the reading of the boot-time mode control serial stream. Cold Reset This signal must be asserted for a power on reset or a cold reset. ColdReset must be de-asserted synchronously with SysClock. Reset This signal must be asserted for any reset sequence. It may be asserted synchronously or asynchronously for a cold reset, or synchronously to initiate a warm reset. Reset must be de-asserted synchronously with SysClock. Boot Mode Clock Serial boot-mode data clock output at the system clock frequency divided by two hundred and fifty six. Boot Mode Data In Serial boot-mode data input.
VccOK
Input
ColdReset*
Input
Reset*
Input
ModeClock
Output
ModeIn
Input
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Absolute Maximum Ratings1
Symbol
VTERM TCASE TSTG IIN IOUT Notes 1. Stresses greater than those listed under ABSOLUTE MAXIMUM RATINGS may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect reliability. VIN minimum = -2.0 V for pulse width less than 15 ns. VIN should not exceed 3.9 Volts. When VIN < 0V or VIN > VccIO Not more than one output should be shorted at a time. Duration of the short should not exceed 30 seconds.
Rating
Terminal Voltage with respect to VSS Operating Temperature Storage Temperature DC Input Current3 DC Output Current4
Limits
-0.52 to +3.9 0 to +85 -55 to +125 20 20
Unit
V C C mA mA
2. 3. 4.
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RM7065ATM Microprocessor with On-Chip Secondary Cache Data Sheet Preliminary
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Recommended Operating Conditions
CPU Speed
300 - 350 MHz
Temperature
0C to +85C (Case)
Vss
0V
VccInt
1.65V 50 mV
VccIO
3.3 V 150 mV or 2.5 V 200 mV
VccP
1.65V 50 mV
Notes 1. 2. 3. 4. VccIO should not exceed VccInt by greater than 2.0 V during the power-up sequence. Applying a logic high state to any I/O pin before VccInt becomes stable is not recommended. As specified in IEEE 1149.1 (JTAG), the JTMS pin must be held high during reset to avoid entering JTAG test mode. Refer to the RM7065A Family Users Manual, Appendix E. VccP must be connected to VccInt through a passive filter circuit. See RM7000 Family User's Manual for recommended circuit.
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RM7065ATM Microprocessor with On-Chip Secondary Cache Data Sheet Preliminary
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DC Electrical Characteristics
(VccIO = 3.15V - 3.45V)
Parameter
VOL VOH VOL VOH VIL VIH IIN 2.4V -0.3V 2.0V 0.8V VccIO + 0.3V 15 A 15 A VIN = 0 VIN = VccIO VccIO - 0.2V 0.4V |IOUT| = 2 mA
Minimum
Maximum
0.2V
Conditions
|IOUT|= 100 A
(VccIO = 2.3V - 2.7V)
Parameter
VOL VOH VOL VOH VOL VOH VIL VIH IIN 1.7 -0.3V 1.7V 0.7V VccIO + 0.3V 15 A 15 A VIN = 0 VIN = VccIO 2.0 0.7V |IOUT| = 2 mA 2.1V 0.4V |IOUT| = 1 mA
Minimum
Maximum
0.2V
Conditions
|IOUT|= 100 A
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RM7065ATM Microprocessor with On-Chip Secondary Cache Data Sheet Preliminary
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Power Consumption
CPU Speed 300 MHz 350 MHz TBD MHz Parameter
standby VccInt Power (mWatts) Notes 1. 2. 3. Worst case supply voltage (maximum VccInt) with worst case temperature (maximum TCase). Dhrystone 2.1 instruction mix. I/O supply power is application dependant, but typically <20% of VccInt. Maximum with no FPU active operation2
Conditions
Max1
TBD TBD TBD
Max1
TBD TBD TBD
Max1
TBD TBD TBD
Maximum worst case instruction mix
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RM7065ATM Microprocessor with On-Chip Secondary Cache Data Sheet Preliminary
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AC Electrical Characteristics
Parameter
Load Derate
10.1 Capacitive Load Deration
Symbol
CLD
Min
Max
2
Units
ns/25pF
10.2 Clock Parameters
CPU Speed Test Parameter
SysClock High SysClock Low SysClock Frequency SysClock Period Clock Jitter for SysClock SysClock Rise Time SysClock Fall Time ModeClock Period JTAG Clock Period Note 1. Operation of the RM7065A is only guaranteed with the Phase Lock Loop Enabled. tSCP tJitterIn tSCRise tSCFall tModeCKP tJTAGCKP 4
300 MHz Min
3 3 33.3 10 100 30 150 2 2 256
350 MHz Min
3 3 33.3 8.5 117 30 150 2 2 256 4
TBD MHz Min Max Units
ns ns MHz ns ps ns ns tSCP tSCP
Symbol
tSCHigh tSCLow
Conditions
Transition 5ns Transition 5ns
Max
Max
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RM7065ATM Microprocessor with On-Chip Secondary Cache Data Sheet Preliminary
10.3 System Interface Parameters
CPU Speed 300 MHz Parameter
1
350 MHz
TBD TBD TBD TBD TBD TBD
TBD MHz Max Units
TBD ns TBD ns ns ns TBD TBD TBD TBD
Symbol Test Conditions
mode14..13 = 10 (fastest)
5,6
Min
1.0 1.0 2.5 1.0
Max Min
TBD TBD
Max Min
Data Output2,3
tDO
mode14..13 = 015,6 (slowest) trise = see above table tfall = see above table
Data Setup4 Data Hold4 Notes 1. 2. 3. 4. 5. 6.
tDS6 tDH
Timings are measured from 0.425 x VccIO of clock to 0.425 x VccIO of signal for 3.3 V I/O. Timings are measured from 0.48 x VccIO of clock to 0.48 x VccIO of signal for 2.5 V I/O. Capacitive load for all output timings is 50 pF. Data Output timing applies to all signal pins whether tristate I/O or output only. Setup and Hold parameters apply to all signal pins whether tristate I/O or input only. Only mode 14:13 = 10 is tested and guaranteed. Data shown is for 3.3 V I/O. For 2.5 V I/O derate all times by 0.5 nS.
10.4 Boot-Time Interface Parameters
Parameter
Mode Data Setup Mode Data Hold
Symbol
tDS tDH
Min
4 0
Max
Units
SysClock cycles SysClock cycles
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RM7065ATM Microprocessor with On-Chip Secondary Cache Data Sheet Preliminary
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Timing Diagrams
Figure 11 Clock Timing
SysClock tRise tFall tHigh tLow tJitterIn
11.1 Clock Timing
System Interface Timing (SysAD, SysCmd, ValidIn*, ValidOut*, etc.)
Figure 12 Input Timing
SysClock tDS Data Data tDH
Figure 13
Output Timing
SysClock tDOmax Data tDOmin Data Data
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RM7065ATM Microprocessor with On-Chip Secondary Cache Data Sheet Preliminary
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Packaging Information
Figure 14 Mechanical Diagram
D
e 20 18 16 14 12 10 8 6 4 2 19 17 15 13 11 9 7 5 3 1 A C E G J L B D F H K M P T V Y
E
J
N R U W
I DETAIL Y
e
TOP VIEW
BOTTOM VIEW
c
24.13 SIDE VIEW
DETAIL X
4
0.30 M C A B
b
A A1
bbb
-C-
C
DETAIL Y
aaa
DETAIL X
C
5
SEATING PLANE
Symbol
A
8
Min.
-- 0.50 -- -- 1.435 REF. 1.435 REF.
Nom.
-- 0.60 27.00 27.00
Max.
1.70 0.70 -- --
A1 D E I J M aaa bbb b c e Notes 1. 2.
20 0.20 0.25 0.60 0.80 1.27 TYP. 0.75 0.90 0.90 1.00
Package Dimensions conform to JEDEC Registration MO-149(BG-2X). "e" represents the basic solder ball grid pitch.
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RM7065ATM Microprocessor with On-Chip Secondary Cache Data Sheet Preliminary
3. 4. 5. 6. 7. 8. 9.
"M" represents the maximum solder ball matrix size. "Dimension "b" is measured at the maximum solder ball diameter parallel to the primary datum "c". The Primary datum "c" and the seating plane are defined by the spherical crowns of the solder balls. All dimensions are in millimeters. Dimensioning and tolerancing per ASME Y14.5M-1994. After surface mount assembly, solder ball will have 0.15 mm (TYP) collapse in "A" dimension. Substrate base material is copper.
10. Package top surface color shall be black. 11. Cavity depth maximum is 0.50 mm.
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RM7065ATM Microprocessor with On-Chip Secondary Cache Data Sheet Preliminary
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RM7065A Pinout
Pin
A1 A5 A9 A13 A17 B1 B5 B9 B13 B17 C1 C5 C9 C13 C17 D1 D5 D9 D13 D17 E1 E17 F1 F17 G1 G17 H1 H17 J1 J17 K1 K17 L1 L17 M1 M17 N1 N17
Function
VccIO SysAD[35] VSS SysADC[2] Do Not Connect VSS Do Not Connect SysADC[5] Do Not Connect VSS VSS Do Not Connect SysAD[0] SysAD[31] Do Not Connect Do not Connect VccIO VccIO SysAD[63] VccIO SysAD[5] VccIO VSS VccInt SysAD[38] VccInt SysAD[7] SysAD[24] VSS VccIO SysAD[41] SysAD[53] SysAD[43] VccInt VSS VccIO SysAD[14] VccInt
Pin
A2 A6 A10 A14 A18 B2 B6 B10 B14 B18 C2 C6 C10 C14 C18 D2 D6 D10 D14 D18 E2 E18 F2 F18 G2 G18 H2 H18 J2 J18 K2 K18 L2 L18 M2 M18 N2 N18
Function
VSS VSS SysADC[1] SysAD[62] VSS VccIO SysAD[3] SysADC[0] SysAD[30] VSS VSS Do Not Connect SysADC[4] SysAD[61] VccIO VSS Do Not Connect VccInt VccInt Do Not Connect Do Not Connect Do Not Connect SysAD[36] SysAD[27] SysAD[6] SysAD[26] SysAD[39] SysAD[56] SysAD[9] SysAD[54] SysAD[10] SysAD[21] SysAD[44] SysAD[51] SysAD[13] SysAD[18] SysAD[46] SysAD[48]
Pin
A3 A7 A11 A15 A19 B3 B7 B11 B15 B19 C3 C7 C11 C15 C19 D3 D7 D11 D15 D19 E3 E19 F3 F19 G3 G19 H3 H19 J3 J19 K3 K19 L3 L19 M3 M19 N3 N19
Function
VSS SysAD[33] Do Not Connect VSS VSS VSS SysAD[2] SysADC[3] SysAD[29] VccIO VccIO SysAD[34] SysADC[7] VccInt VSS Do not Connect VccInt VccInt SysAD[28] VSS VccInt Do Not Connect SysAD[4] SysAD[58] SysAD[37] SysAD[57] SysAD[40] SysAD[55] VccInt SysAD[22] SysAD[42] SysAD[52] SysAD[12] SysAD[19] SysAD[45] SysAD[49] VccInt SysAD[16]
Pin
A4 A8 A12 A16 A20 B4 B8 B12 B16 B20 C4 C8 C12 C16 C20 D4 D8 D12 D16 D20 E4 E20 F4 F20 G4 G20 H4 H20 J4 J20 K4 K20 L4 L20 M4 M20 N4 N20
Function
Do Not Connect SysAD[32] VSS SysAD[60] VccIO VSS SysAD[1] SysADC[6] Do Not Connect VSS Do Not Connect VccInt VccInt Do Not Connect VSS VccIO VccInt VccIO VccIO Do Not Connect VccIO SysAD[59] VccInt VSS VccInt SysAD[25] SysAD[8] SysAD[23] VccIO VSS SysAD[11] SysAD[20] VccInt SysAD[50] VccIO VSS SysAD[47] SysAD[17] 50
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RM7065ATM Microprocessor with On-Chip Secondary Cache Data Sheet Preliminary
Pin
P1 P17 R1 R17 T1 T17 U1 U5 U9 U13 U17 V1 V5 V9 V13 V17 W1 W5 W9 W13 W17 Y1 Y5 Y9 Y13 Y17
Function
SysAD[15] ColdResetB VSS VccInt PRQSTB VccIO ModeClock VccIO VccIO SysCmd[7] VccIO VSS RDRDYB Do Not Connect SysCmd[6] Int[4]* VSS WRRDYB Do Not Connect SysCmd[5] VSS VccIO ValidOutB VSS SysCmd[4] Int[0]*
Pin
P2 P18 R2 R18 T2 T18 U2 U6 U10 U14 U18 V2 V6 V10 V14 V18 W2 W6 W10 W14 W18 Y2 Y6 Y10 Y14 Y18
Function
RSPSWAPB VccOK Do Not Connect ExtrQSTB JTDO VccInt VSS ValidInB VccInt VccInt Int[6]* VSS VccP Do Not Connect VccInt VccIO VccIO ReleaseB Do Not Connect SysCmdP VSS VSS VSS Do Not Connect SysCmd[8] VSS
Pin
P3 P19 R3 R19 T3 T19 U3 U7 U11 U15 U19 V3 V7 V11 V15 V19 W3 W7 W11 W15 W19 Y3 Y7 Y11 Y15 Y19
Function
PACKB BigEndian JTDI NMIB VccIO Int[9]* JTMS VSSP VccInt Int[3]* VSS VccIO Do Not Connect VccInt Int[2]* VSS VSS SysClk SysCmd[1] VccInt VccIO VSS VccP SysCmd[0] VSS VSS
Pin
P4 P20 R4 R20 T4 T20 U4 U8 U12 U16 U20 V4 V8 V12 V16 V20 W4 W8 W12 W16 W20 Y4 Y8 Y12 Y16 Y20
Function
VccInt ResetB JTCK VSS
VccIO
Int[8]* VccIO VccInt VccIO VccIO Int[7]* RDType VccInt SysCmd[3] Int[5]* VSS VSS VccInt SysCmd[2] Int[1]* VSS ModeIn Do Not Connect VSS Do Not Connect
VccIO
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RM7065ATM Microprocessor with On-Chip Secondary Cache Data Sheet Preliminary
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Ordering Information
RM7065A -123 T I Temperature Grade: (blank) = commercial Package Type: T = TBGA
Device Maximum Speed Device Type A = 0.18 micron process geometry
Valid Combinations
RM7065A-300T RM7065A-350T
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