Some Embedded Processor Alternatives; Processors for this course: Introduction to Altera FPGAs
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Transcript of Some Embedded Processor Alternatives; Processors for this course: Introduction to Altera FPGAs
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Some Embedded Processor Alternatives;
Processors for this course: Introduction to Altera FPGAs
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Processor Examples
“Harvard architecture”:
--PIC processor family
“von Neumann architecture”:
--simple processor
--P 3 processor (Hamblen et al., chapter 9)
--MIPS processor (Hamblen et al., chapter 14)
--NIOS II processor core (Hamblen et al., chapters 15-17)
Control
ALUMemoryData + Instruc.
I/O
Control
ALUInstruc. I/O Data
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PIC processor family: processor is fixed, developer programs it
Reference: http://en.wikipedia.org/wiki/PIC_microcontroller
• PIC: peripheral interface controller
• Originally (~1975) for offloading I/O functions from a CPU
• Harvard architecture: data and instructions (“code”) are stored separately—thus a data item and an instruction do not need to be the same length
• Newer versions have a stack
• One accumulator (referred to as W), but memory is usually referred to as a “register file”
• Some versions allow a type of indirect addressing
• Usually referred to as a RISC machine; may have up to 70 instructions
• May be able to access external memory (newer versions)
• Many development tools & languages available
Data“Code”
(Instructions)
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power
VGA portparallel portPS2 port
+3.3VsupplyLED
on/off switchuser-definablepushbuttons
user-definable
LEDs
user-definableDIP switches
global reset
USB port
serial port
invalid input voltage LED
UP3 BOARD
http://users.ece.gatech.edu/~hamblen/UP3/ and
http://users.ece.gatech.edu/~hamblen/UP3/UP3%20Reference%20Manual.pdf
FLASH
SRAM
Altera Cyclone chip
+5VsupplyLED
LC Display Some processor architectures:
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simple processor:
•Von Neumann architecture
•Only one general purpose register (accumulator)
•Supports direct, indirect, and indexed addressing
•Small instruction set, 2 formats (000-110 or 111)
•Primitive I/O (via accumulator)
•No built-in stack / stack pointer
•No ability to do virtual storage
ALU
MMA
IR AC CF MD IA IB PC
ABUS
OBUS
BBUS
ALU OUTPUT
M: memoryMA: memory address registerMD: memory data registerIR: instruction registerAC: accumulatorCF: carry flagIA, IB: index registersPC: program counter
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P 3 processor (Hamblen et al., chapter 9)
•Similar to simple processor—von Neumann architecture, 1 accumulator
•Implementation uses < 1% of Altera Cyclone device logic
•Memory and I/O are now each components on the data bus; all info goes through MDR (fig. 9-1)
•8-bit instructions, 8-bit data in 1 16-bit word, several formats
•Only direct addressing
•Only 5 instructions given (load, store, add, jump, jneg)—can these support general-purpose computing?
•No stack pointer
•Can it do virtual storage?
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MIPS processor (Hamblen et al., chapter 14)
•Widely-used RISC architecture, 1980’s
•32-bit instructions, 3 formats
•32 general-purpose registers
•1-cycle fetch/decode/execute (employs pipelining)
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NIOS II processor core (Hamblen et al., chapters 15-17)
Hardware (IP) core—SOPC example; C/C++ compiler
•32-bit datapath
•1-6 pipeline stages
•32 general purpose registers, 6 special-purpose
•Optional instruction cache
•Optional multiply/divide instructions
•Hardware floating point unit can be added
•Hardware can be customized
•Development environment includes;
--C/C++ compiler
--Ability to customize library for the peripheral devices you need
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More about Altera devices and tools:
Generic FPGA architecture:
LOCAL BUS
GLOBAL BUS
CARRY OUT
IN OUTBUS
BUS
CLOCKRESETMEM IN
LOGIC(LOOK-UPTABLE or
LUT)
MEMORY
(1-BIT)
CARRY IN
BUS
MEM OUTFPGA (EXAMPLE)
SINGLE FPGA CELL
RAM BLOCK
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examples (Altera, Xilinx, etc.):
"cell" typically contains LUT (look-up table),memory, I/O output
ex: 3-input LUT: o
inputs: a
b
c
"device" consists of cells, local routing, globalrouting, specialized memory arrays; manufacturerprovides "families" of devices--different sizes, powerusage, operating conditions, etc.
"address" from a,b,c output0 0 0 f00 0 1 f10 1 0 f20 1 1 f31 0 0 f41 0 1 f51 1 0 f61 1 1 f7
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Example: using a lookup table to describe a gate network:
f(A,B,C) = A'B'C + A'BC' + A'BC + ABC (001) (010) (011) (111)
Inputs: ABC out000 0001 1010 1011 1100 0101 0110 0111 1
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Example: A Generic Programmable Logic Device Architecture
(Altera):
maxplus2 "compiler":
netlist extractor
CARRY-IN GLOBAL LOCAL
BUS BUS
MEM
OUT
b. BLOCK OF PLD CELLS
IN OUT
BUS BUS
CLOCK
RESET
MEM IN
LOGIC
(LOOK-UP
TABLE)
MEMORY
(1-BIT)
LE (Logic Element)
LAB (Logic Array Block)
RAM Block
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Device families:
Example: “Cyclone”—we will use EP1C6 or EP1C2
features:
» logic elements (LE’s)
» RAM blocks
» Global clock + Phase locked loops for clock configuration
» >= 170 I/O pins
Cyclone LE—figure 3.7
Cyclone LABs and interconnects: figure 3.9
(These references and those that follow are to the reference by Hamblen et al.)
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SW Programming:
Silicon Programming:
"silicon compilation":basic idea: restrict possible physical configurations; sacrifice area / performance for "regularity" of design; use regular physical structures to enable AUTOMATION of layoutAll CAD tools will sacrifice some area/performance for automation and the ability to do "large" designs, just as software compilers sacrifice some efficiency for the ability to use a high-level language instead of assembly language; designer productivity will increase substantially, however
Write Program (HLL)
Compile Link to Libraries
Load/Execute
Write Program (HDL/Scm)
Com-pile/Link
Program Device/Execute
Fit Simu-late
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Altera Project Flow (“Rapid Prototyping”):1. (Hierarchical) DESIGNdesign entry
schematic (mydesign.gdf)Verilog (mydesign.v)other formats (VHDL, AHDL, EDIF, )IP cores
2.Compilationtranslation, optimization, synthesis (“netlist”)device fitting (placement and routing)Floorplan editor—figure 1.23Report generation
3.”Execution”Timing analysissimulation (functional / timing) device programming, hardware verificationinformation on power usage
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After we have completed our design (schematic or HDL), the compiler converts it into a design for an actual working circuit using a "technology mapping": design library technology library on the Altera boards we are using, there is one chip, from the “CYCLONE” family
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Technology: SRAM
General description:
http://en.wikipedia.org/wiki/Static_Random_Access_Memory
General information on “programmable” devices:
http://www.tutorial-reports.com/computer-science/fpga/user-programmability.php
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CYCLONE chips: http://www.altera.com/literature/hb/cyc/cyc_c51002.pdf 2900-20,000 LE’s; 10 LE’s grouped into one LAB Dedicated RAM blocks Specs: page 2-2 LE architecture: page 2-6 Embedded memory specs; page 2-18 Global clock and up to 2 PLLs (UP3 clock: 48 MHz) Device grades, operating conditions: http://www.altera.com/literature/hb/cyc/cyc_c51004.pdf
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Physical behavior of devices: operating conditions--recommended/absolute maximum
temperature gate delays pin voltage levels output loading power-supply management device programming erasure power evaluation: worksheet available at: www.altera.com/support/devices/estimator/pow-powerplay.html
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Reconfigurable computing:We can create arrays of programmable devicesProgrammability will allow us to change the
hardware capabilities "on the fly"--e.g., reprogramsome devices while others are being used forprocessing; this allows us to "reconfigure" thehardware to adapt to specific processing needs, justas we can now rewrite softwareexample: Xilinx Virtex FPGA boards
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Functional Testing: One more useful Altera option: note that the devices we have access to will allow us to produce fairly "large" designs. To adequately test these designs, we will need to input files of test vectors rather than relying solely on inputting waveforms (and we will need to do HIERARCHICAL design AND testing)A test vector file (myfile.vec) can be created in the text editor. Here is an example file to test a module with inputs A, B, RESET, and CLOCK and outputs X,Y,Z.
A X
B Y
RESET Z
CLOCK
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%test vector file for above module%% units default to ns %START 0 ; % time to start simulation%STOP 1000 ; % time to end (in ns)%INTERVAL 100 ;INPUTS CLOCK ;PATTERN0 1 ; % pattern of clock values % % CLOCK ticks every 100 ns %INPUTS A B ;PATTERN % test every combination of % % A and B %0> 0 0220> 1 0320> 1 1 % change A,B at given times %570> 0 1720> 1 1;
INPUTS RESET ;PATTERN0> 1100> 0;OUTPUTS X Y Z ;PATTERN % check output at every Clock pulse --these are expected values%= X X X= 0 0 0 % relative time vector values %= 0 0 0= 1 0 0= 0 0 1= 0 0 1= 0 1 1= 0 1 1= 1 1 1= 1 1 1= 1 1 1= 1 1 1 ;
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using the .vec file: open the simulator; then on the "File" menu choose inputs/outputs; then choose your .vec file; you must do this BEFORE opening a .scf file
Note: results of the simulation cannot be saved as a .vec file. To save your results, save them as either a waveform (.vwf) or a table output (.tbl) file.
Alternative: compile separately in Verilog on Sun workstations, compiler, use a testbench; then import into Altera environment; this is the standard HDl methodology
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Useful Altera functions:
•The UP3 core library
•input and output for the Altera board
•random number generation
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We will be covering material from chapters 4,5,10,11 on I/O I/O is the "hardest" type of module to build, since it requires transition between electrical domain and other energy domains (e.g., mechanical, light) We will also discuss a way to generate pseudo random numbers (Appendix A) Both I/O and random number generation will probably be useful for your projects.
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UP3 functions: an IP (intellectual property) core described in chapter 5 of Hamblen et al. can be used with schematics, Verilog, or VHDL
8 modules--perform I/O “housekeeping” functions modules must be “visible” in your path or included in your design in some way (directly, package, etc.)
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module names: Debounce pushbuttons OnePulse
LCD_Display—LCD panel character display
Clk_Div--gives slower clock speeds
VGA_Sync—video sync generation Char_ROM--codes for display characters
Keyboard--keyboard connector
Mouse--mouse connector
output
input
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power
VGA portparallel portPS2 port
+3.3VsupplyLED
on/off switchuser-definablepushbuttons
user-definable
LEDs
user-definableDIP switches
global reset
USB port
serial port
invalid input voltage LED
UP3 BOARD
http://users.ece.gatech.edu/~hamblen/UP3/ and
http://users.ece.gatech.edu/~hamblen/UP3/UP3%20Reference%20Manual.pdf
FLASH
SRAM
Cyclone chip
+5VsupplyLED
LC Display
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COMPONENT LCD_DisplayPORT (Hex_Display_Data: IN STD_LOGIC_VECTOR (Num_Hex_Digists*4)-1 DOWNTO 0; reset, clock_48MHz: IN std_logic; LCD_RS, LCD_E: OUT STD_LOGIC; DATA_BUS: INOUT STD_LOGIC_VECTOR (7 DOWNTO 0);END COMPONENT;
input 4 bits hex digit signal values to convert to ASCII hex digits and send to LED display (note: Appendix D contains ASCII to hex table)Num_Hex_Digits is a Generic parameter which can be given a value in a VHDL file or in a schematic (16 characters, 2 lines available)
Outputs PIN (important!)LCD_RS 108LCD_E 50LCD_RW 73DATA_BUS (7 DOWNTO 0): 113, 106, 104, 102, 100, 98, 96, 94
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COMPONENT DebouncePORT (pb, clk_100Hz:IN STD_LOGIC;
pb_debounced:OUT STD_LOGIC);END COMPONENT;
pb is the input from a pushbutton (see I/O pins, chapter 2)
since pushbuttons have a mechanical “bounce”, this component samples the input over several clock cycles and filters out the bounces; it will register the pushbutton input only when several sequential samples of the input agree
the clock input is used by the bounce filter (see example below)
when “push” is registered, output goes low: it remains low until button is released
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COMPONENT OnePulsePORT (PB_debounced, clock:IN STD_LOGIC;
PB_single_pulse:OUT STD_LOGIC);END COMPONENT;
after the push button signal is “debounced”, this component can be used to ensure that the output read from the pushbutton is high for only one clock cycle, no matter how long the pushbutton is held down
this is useful for building finite state machines--an edge-triggered flip-flop can be used to build a state and each input will be active for only one clock cycle
the “clock” input is the clock signal being used to drive the state machine
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COMPONENT Clk_DivPORT ( clock_48MHz: IN STD_LOGIC;
clock_1MHz, clock_100KHz, clock_10KHz, clock_1KHz, clock_100Hz, clock_10Hz, clock_1Hz:OUT STD_LOGIC)
END COMPONENT;
the input is from the (48MHz) on-board clock (pin 29 for the Cyclone chip); JP3 jumper must be set to select the 48MHz USB—this the default setting
the outputs are clock signals of various frequencies which can be used in designs
Note: actual frequency will be (listed frequency)*(1.007 +/- .005%)
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Example:
Debounce
Clock (pin 29)
OnePulsefsm
Clk_Div
Clock_100Hz
Clock_1MHz
pushbutton
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COMPONENT MousePORT ( clock_48Mhz,reset: IN STD_LOGIC;
mouse_data, mouse_clk:INOUT STD_LOGIC; left_button,right_button: OUT STD_LOGIC; mouse_cursor_row,mouse_cursor_column:
OUT STD_LOGIC_VECTOR(9 DOWNTO 0);END COMPONENT;
the input is from the (48MHz) on-board clock (pin 29 for the Cyclone chip);
mouse_data is pin 13, mouse_clk is pin 12: BIDIRECTIONAL (also used for keyboard)
cursor outputs give postion in 640 x 480 pixel screen (VGA); cursor is initialized to the middle of the screen
button outputs are high when the corresponding button is pushed
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COMPONENT KeyboardPORT ( keyboard_clk,keyboard_data, clock_48Mhz,
reset, read: IN STD_LOGIC; scan_code: OUT STD_LOGIC_VECTOR(7 DOWNTO 0); scan_ready: OUT STD_LOGIC);
END COMPONENT;
Reads PS/2 keyboard scan code; converts serial data from keyboard to parallel clock input is from the (48MHz) on-board clock (pin 29 for the Cyclone chip);
keyboard_data is pin 13, keyboard_clk is pin 12: INPUTS(also used for mouse)
read clears the scan_ready signal; reset clears flip-flops for serial-to-parallel conversion
scan_code: table of values in Table 11.3;--”make” code: key is hit; “break” code: key is releasedex: ‘A’ make = 1C, break = F01C: ‘shift’ make = 12, break = F012 (if key is held down, several makes will be sent before a break)
scan_ready goes high when new scan code is sent and can be used to make sure each scan code is read only once
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COMPONENT VGA_Sync PORT (clock_48MHz, red, green, blue: IN STD_LOGIC; red_out, green_out, blue_out, horiz_sync_out, vert_sync_out: OUT STD_LOGIC; pixel_row, pixel_column: OUT STD_LOGIC_VECTOR(9 DOWNTO 0));END COMPONENT;
clock_48MHz signal must come from pin 29 (Cyclone chip)
user logic generates the input “color” (red, green, blue)
Cyclone chip: horiz_sync --> pin 226, vert_sync --> pin 227red_out --> pin 228, green_out --> pin 122, blue_out --> pin 170
pixel_row and pixel_column give the pixel address
how many colors are available? how many pixels?(“dithering”: one color on odd cycles, different on even twice as many colors example: pattern sent (even/odd cycles) pattern observed
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COMPONENT Char_ROM PORT (clock: IN STD-logic;
character_address: IN STD_LOGIC_VECTOR (5 DOWNTO 0);font_row, font_col: IN STD_LOGIC_VECTOR (2 DOWNTO 0);
row_mux_output: OUT STD_LOGIC); END COMPONENT;
generates text for a video display--each character requires an 8 x 8 pixel pattern (see codes, table 9.1--a memory initialization file, tcgrom.mif, is provided; the font data can be stored in one M4K memory block)
character_address addresses the character to be displayed
font_row and font_col step through the 64 pixels (8x8) needed to display one character
Clock loads the address register and should be tied to the video pixel_clock
row_mux_output is the pixel value to be output for this character at this position and can be used to generate the correct RGB pixel color
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How does output occur (examples: chapter 10):
monitor contains CRT (cathode ray tube)
screen consists of pixels, 640 in a row and 480 in a column (VGA format)
“refresh rate”: how quickly these pixels are scanned
standard rate is 60 times / second (60 Hz)
(human eye can detect “flicker” below 30Hz)
if there are 640 X 480 pixels, with a 60Hz refresh rate, how much time is available to scan one pixel?
What clock speed is therefore required?
What is the onboard clock speed?
(note: UP3 has PLL which can be used to obtain faster refresh rates)
Sync signals tell when to start a new row or column
640
480
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random number generation (Appendix A):
actually generates “pseudorandom” numbers
Q: what is the difference?
Method: example: n = 32--will give 32-bit pseudorandom sequence of bits
from table, read “XOR from bits 32,22,2,1” (bits are 32--1, not 31--0)
build a 32-bit shift register that shifts left one bit per cycle
next bit to be input into lsb should be the XOR of bits 32,22,2,1
this will generate a sequence in “pseudorandom order”
initial value in the register is the “seed”; 0 should not be used (why?)
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Example: random number generator for n = 8:
8-bit shift register (shifts left)
Load with SEED which is any nonzero number
shift in XOR of the specified bits (8, 6, 5, 4 for n = 8)
Generate all 255 (28 – 1) nonzero numbers in “random” order, e.g.:
SEED=10101000 gives 10101000, 01010001, 10100011, 01000110, …
Bit 8 Bit 1
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Example: n = 3--table gives bits 3,2
step pattern (bit 3) xor (bit 2)
0 111 01 110 02 100 13 001 04 010 15 101 16 011 17 111 0---from here, the sequence will repeat
we have a sequence of the numbers 1-7: 7,6,4,1,2,5,3
this is the longest nonrepeating sequence we can haveorder will always be the same, seed only determines where we start(We MUST XOR specified bits for given value of n; it can be proved using facts about polynomials over the field with elements 0,1 and addition = XOR these bits will generate all nonzero values
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How good are the random numbers generated?Reference: Shruthi Narayanan, M.S. 2005, ATI TechnologiesHardware implementation of genetic algorithm modules for intelligent systems:
Random numbers generated by one shift register
Random numbers generated by multiple shift registers