Chapter 1 Introduction to HCS12/MC9S12. Computer Hardware Organization What is a Computer? Software...
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Transcript of Chapter 1 Introduction to HCS12/MC9S12. Computer Hardware Organization What is a Computer? Software...
Chapter 1
Introduction to HCS12/MC9S12
Computer Hardware Organization
Control Unit
Datapath
ArithmeticLogic Unit
Registers
Processor
Common Bus (address, data, & control)
Memory
ProgramStorage
DataStorage
OutputUnits
InputUnits
Figure 1.1 Computer Organization
What is a Computer?
• Software• Hardware
The Processor
• Registers– Storage locations in the processor
• Arithmetic logic unit• Control unit
– Program counter keeps track of the address of the next instruction to be executed.
– Status register flags the instruction execution result.• The microprocessor
– A processor implemented on a very large scale integration (VLSI) chip– Peripheral chips are needed to construct a product
• The microcontroller– The processor and peripheral functions implemented on one VLSI chip
Features of the HCS12 Microcontroller
• 16-bit CPU• 64 KB memory space (also supports expanded memory up to 1
MB through a 16-KB window)• 0 KB to 4KB of EEPROM• 2 KB to 14 KB of on-chip SRAM• 32 KB to 512 KB flash memory• Sophisticated timer functions that include: input capture, output
compare, pulse accumulators, real-time interrupt, and COP timer
• Serial communication interfaces: SCI, SPI, CAN, BDLC• Background debug mode (BDM)• 10-bit A/D converter• Instructions for supporting fuzzy logic function
Semiconductor Memory (1 of 2)
• Random-access memory (RAM): same amount of time is required to access any location on the same chip– Dynamic random-access memory (DRAM): periodic refresh
is required to maintain the contents of a DRAM chip– Static random-access memory (SRAM): no periodic refresh
is required• Read-only memory (ROM): can only be read but not written by
the processor– Mask-programmed read-only memory (MROM):
programmed when being manufactured– Programmable read-only memory (PROM): is fuse-based,
can be programmed by the end user by a burner.
Semiconductor Memory (2 of 2)
• Erasable programmable ROM (EPROM) – Electrically programmable many times– Erased by ultraviolet light (through a window)– Erasable in bulk (whole chip in one erasure operation)
• Electrically erasable programmable ROM (EEPROM)– Electrically programmable many times– Electrically erasable many times– Can be erased one location, one row, or whole chip in one
operation• Flash memory
– Electrically programmable many times– Electrically erasable many times– Can only be erased in bulk or a sector at a time
Computer Software
• Computer programs are known as software.• A program is a sequence of instructions.• Machine instruction
– A sequence of binary digits which can be executed by the processor
• 0001 1000 0000 0110: A [A] + [B]• 0100 0011: A [A] + 1• 1000 0110 0000 0110: A 6
– Hard to understand, enter, debug, and maintain for human being
Assembly Language
• Defined by assembly instructions– An assembly instruction is a mnemonic representation of a
machine instruction• ABA: A [A] + [B]• DECA: A [A] – 1
– Assembly programs must be translated into machine instructions before it can be executed -- translated by an assembler
– There are two kinds of assemblers: native assembler and cross assembler.
– Programmers need to work on the program logic at a very low level and cannot achieve high productivity.
High-level Language
• Syntax of a high-level language is similar to English.• A translator is required to translate the program written in a
high-level language -- done by a compiler.– There are two types of compilers: native compiler and cross
compiler.• High-level languages allow the user to work on the program
logic at higher level and achieve higher productivity.• Source code
– A program written in assembly or high-level language• Object code
– The output of an assembler or compiler
line
1:
2:
3:
4:
5:
6:
addr.
2000
2003
2006
2009
machine code
= 00002000
B6 1000
BB 1001
BB 1002
7A 1100
source code
org $2000
ldaa $1000
adda $1001
adda $1002
staa $1100
end
7 00 7A B
15 0D
8-bit accumulator A and Bor16-bit double accumulator D
15 0X
15 0Y
Index register X
Index register Y
15 0SP Stack pointer
15 0PC Program counter
S X H I N Z V C Condition code register
CarryOverflowZero
NegativeI Interrupt maskHalf-Carry (from bit 3)X Interrupt MaskStop Disable
Figure 1.2 HCS12 CPU registers.
ContentsAddress
Figure 1.5 The components of a memory location
Table 1.1 Prefixes for number bases
base
binaryoctaldecimalhexadecimal(shorthand hex)
prefix example
%@
$
%10001010@123456712345678$5678
Memory Addressing
• Memory consists of a sequence of directly addressable locations.– A location is referred to as an information unit.– A memory location can be used to store data, instruction, and the
status of peripheral devices.– A memory location has two components: an address and its contents.
CPU
Address bus lines
Data bus lines
Memory
Figure 1.6 Transferring data between CPU and memory
• Data transfers between the CPU and the memory are done over the common buses: address bus and data bus.
• Notations: m[addr] represents the contents of a memory location, [reg] refers to the contents of a register. – For example, [$20] refers to the contents of memory location
at $20.– [A] refers to the contents of accumulator A.
Addressing Modes
• A HCS12 instruction consists of one or two bytes of opcode and zero to five bytes of operand addressing information.– Opcode bytes specify the operation to be performed by
the CPU. – The first byte of a two-byte opcode is always $18.
• Addressing modes specify the operand to be operated on.
• The addressing mode may specify a value, a register, or a memory location to be used as an operand.
Table 1.2P M68HC12 addressing mode summary
Addressing mode Source format Abbre. Description
Inherent
Immediate
Direct
ExtendedRelative
Indexed(5-bit offset)Indexed(pre-decrement)Indexed(pre-increment)Indexed(post-decrement)Indexed(post-increment)Indexed(accumulator offset)Indexed(9-bit offset)Indexed(16-bit offset)Indexed-Indirect(16-bit offset)Indexed-Indirect(D accumulatoroffset)
INST(no externallysupplied operands)INST #opr8iorINST #opr16iINST opr8a
INST opr16aINST rel8orINST rel16INST oprx5,xysp
INST oprx3,-xys
INST oprx3,+xys
INST oprx3,xys-
INST oprx3,xys+
INST abd,xysp
INST oprx9,xysp
INST oprx16,xysp
INST [oprx16,xysp]
INST [D,xysp]
INH
IMM
DIR
EXT
REL
IDX
IDX
IDX
IDX
IDX
IDX
IDX1
IDX2
[IDX2]
[D,IDX]
Operands (if any) are in CPU registers
Operand is included in instruction stream. 8- or16-bit size implied by context
Operand is the lower 8 bits of an address in therange $0000-$00FFOperand is a 16-bit addressAn 8-bit or 16-bit relative offset from the currentPC is supplied in the instruction
5-bit signed constant offset from x,y,sp, or pc
Auto pre-decrement x, y, or sp by 1 ~ 8
Auto pre-increment x, y, or sp by 1 ~ 8
Auto post-decrement x, y, or sp by 1 ~ 8
Auto post-increment x, y, or sp by 1 ~ 8
Indexed with 8-bit (A or B) or 16-bit (D)accumulator offset from x, y, sp, or pc9-bit signed constant offset from x, y, sp, or pc(lower 8-bits of offset in one extension byte)16-bit constant offset from x, y, sp, or pc (16-bitoffset in two extension bytes)Pointer to operand is found at 16-bit constantoffset from (x, y, sp, or pc)Pointer to operand is found at x, y, sp, or pc plusthe vlaue in D
Inherent Mode
• Instructions that use this mode do not use extra bytes to specify operands because the instructions either do not need operands or all operands are CPU registers.– Operands are implied by the opcode.– Examples
• NOP
• INX
• DECA
Immediate Mode
• Operands for instructions that use immediate mode are included in the instruction.
• CPU does not access memory for operands.• Example
– LDAA #$55– LDX #$1000
Direct Mode
• This mode can only specify memory locations in the range of 0 - 255.
• This mode uses only one byte to specify the operand address.
• Example– LDAA $20– LDAB $40
Extended Mode
• In this mode, the full 16-bit address is provided in the instruction.
• For example,– LDAA $4000– LDX $FE60
Relative Mode (1 of 2)• Used only by branch instructions• Short and long conditional branch instructions use exclusively
relative mode. • BRCLR and BRSET instructions can also use relative mode to
specify branch target.– A short branch instructions consists of an 8-bit opcode and a
signed 8-bit offset. – The short relative mode can specify a range of -128 ~ +127.– A long branch instruction consists of an 8-bit opcode and a
signed 16-bit offset. – The range of the long relative mode is from -32768 ~
+32767.• A programmer uses a symbol to specify the branch target and
the assembler will figure out the actual branch offset (distance) from the instruction that follows branch instruction.
Relative Mode (2 of 2)
• For example,
minus
…
…
bmi minus
…
Indexed Mode
• This mode uses the sum of an index register (X, Y, PC, or SP) and an offset to specify the address of an operand.– The offset can be a 5-bit, 9-bit, and 16-bit signed value
or the value in accumulator A, B, or D. – Automatic pre- or post-increment or pre- or post-
decrement by -8 to +8 are options.– PC can be used as the index register for all but auto-
increment or auto-decrement mode.– Indirect indexing with 16-bit offset or accumulator D as
the offset is supported. • A summary of indexed addressing modes is given in
Table 1.3.
Table 1.3 Summary of indexed operations
Postbytecode (xb)
source codesyntax
Commentsrr: 00 = X, 01 = Y, 10 = SP, 11 = PC
rr0nnnnn
111rr0zs
111rr011
rr1pnnnn
111rr1aa
111rr111
rn,r-n,rn,r-n,r
[n,r]
n,-rn,+rn,r-n,r+
A,rB,rD,r
[D,r]
5-bit constant offset n = -16 to +15r can be X, Y, SP, or PC
Constant offset (9- or 16-bit signed)z: 0 = 9-bit with sign in LSB of postbyte (s) -256< n < 255 1 = 16-bit 0 < n < 65535if z = s = 1, 16-bit offset indexed-indirect (see below)r can be X, Y, SP, or PC16-bit offset indexed-indirect 0 < n < 65536rr can be X, Y, SP, or PCAuto pre-decrement/increment or auto post-decrement/increment;p = pre-(0) or post-(1), n = -8 to -1 or +1 to +8r can be X, Y, or SP (PC not a valid choice)
+8 = 0111...+1 = 0000-1 = 1111....-8 = 1000
Accumulator offset (unsigned 8-bit 0r 16-bit)aa: 00 = A
01 = B10 = D (16-bit)11 = see accumulator D offset indexed-indirect
r can be X, Y, SP, or PCAccumulator D offset indexed-indirectr can be X, Y, SP, or PC
Indexed Addressing (1 of 2)
• 5-bit Constant Offset Indexed Addressing– The base index register can be X, Y, SP, or PC.– The range of the offset is from -16 to +15.– Examples
• ldaa 0,X• stab -8,0
• 9-bit Constant Offset Indexed Addressing– The base index register can be X, Y, SP, or PC.– The range of the offset is from -256 to +255.– Examples
• ldaa $FF,X• ldab -20,Y
Indexed Addressing (2 of 2)
• 16-bit Constant Offset Indexed Addressing – The base index register can be X, Y, SP, or PC.– This mode allows access any location in the 64-KB range.– Examples
• ldaa 2000,X• staa 4000,Y
• 16-bit Constant Indirect Indexed Addressing– A 16-bit offset is added to the base index register to form the
address of a memory location that contains a pointer to the memory location affected by the instruction.
– The square brackets distinguish this addressing mode from the 16-bit constant offset indexing.
• Example,– ldaa [10,X]– staa [20,Y]
Auto Pre/Post Decrement/Increment Indexed Addressing
• The base index register can be X, Y, or SP.• The index register can be incremented or decremented by an
integer value either before or after indexing taking place.• The index register retains the changed value after indexing.• The value to be incremented or decremented is in the ranges -8
thru -1 or 1 thru 8.• The value needs to be related to the size of the operand or the
current instruction.• Examples
– staa 1,-SP– staa 1,SP-– ldx 2,+SP– ldx 2,SP+
Accumulator Offset Indexed Addressing
• The effective address of the operand is the sum of the accumulator and the base index register.– The base register can be X, Y, SP, or PC.– The accumulator can be the 8-bit A or B or the
16-bit accumulator D.– Example
• ldaa B,X
• stab B,Y
The value in D is added to the value in the base index register to form the address of the memory location that contains the address to the memory location affected by the instruction.
The square brackets distinguish this addressing mode from accumulator D offset indexing.
Example
jmp [D,PC]
go1 dc.w target1
go2 dc.w target2
go3 dc.w target3
…
target1 …
.
target2 …
.
target3 …
Accumulator D Indirect Indexed Addressing
HCS12 Instruction Examples
• The LOAD and STORE instructions– The LOAD instruction copies the contents of a memory location or
places an immediate value into an accumulator or a CPU register.– STORE instructions save the contents of a CPU register into a memory
location.– N and Z flags of the CCR register are automatically updated and the V
flag is cleared.• All except for the relative mode can be used to select the memory
location or value to be loaded into an accumulator or CPU register.• All except for the relative and immediate modes can be used to select
memory location to store contents of the CPU register. For example,– ldaa 0,X– staa $20– stx $8000– ldd #100
Table 1.4 Load and store instructions
Mnemonic
LDAALDABLDDLDSLDXLDYLEASLEAXLEAY
STAASTABSTDSTSSTXSTY
Store Instructions
Mnemonic
Function
Load ALoad BLoad DLoad SPLoad index register XLoad index register YLoad effective address into SPLoad effective address into XLoad efective address into Y
Operation
(M) A(M) B(M:M+1) (A:B)(M:M+1) SP(M:M+1) X(M:M+1) XEffective address SPEffective address XEffective address Y
Function Operation
Store AStore BStore DStore SPStore XStore Y
(A) M(B) M(A) M, (B) M+1(SP) M, M+1(X) M:M+1(Y) M:M+1
Transfer and Exchange Instructions (1 of 2)
• Transfer instructions copy the contents of a CPU register or accumulator into another CPU register or accumulator.
• TFR is the universal transfer instruction, but other mnemonics are accepted for compatibility with the 68HC11.
• The TAB and TBA instructions affect the N, Z, and V condition code bits.
• The TFR instruction does not affect any condition code bits. For example,– TFR D,X ; [D] X– TFR A,B ; [A] B– TFR A,X ; 0:[A] X ; upper 8-bit of X is cleared
to 0– TFR X,A ; X[7:0] A ; lower 8 bits copied to A
• The EXG instruction exchanges the contents of a pair of registers or accumulators. For example,
exg A, B exg D,X
exg A,X ; A X[7:0], X $00:[A]exg X,B ; X $00:[B], B X[7:0]
• The SEX instruction sign-extend an 8-bit two’s complement number into a 16-bit number so that it can be used in 16-bit signed operations. For example,
SEX A,X
Transfer and Exchange Instructions (2 of 2)
Move Instructions
• These instructions move data bytes or words from a source to a destination in memory.
• Six combinations of immediate, extended, and index addressing modes are allowed to specify the source and destination addresses:– IMM EXT, IMM IDX, EXT EXT, EXT IDX, IDX
EXT, IDX IDX
– For example,• movb $100,$800• movw 0,X, 0,Y
Transfer Instructions
Table 1.6 Move instructions
Mnemonic
MOVBMOVW
Function
Move byte (8-bit)Move word (16-bit)
Operation
(M1) M2(M:M+11) M:M+12
Add and Subtract Instructions• These instructions perform fundamental arithmetic operations.• The destinations of these instructions are always a CPU register
or accumulator.• There are two-operand and three-operand versions of these
instructions.• Three-operand ADD or SUB instructions always include the C
flag as one of the operand. • Three-operand ADD or SUB instructions are used to perform
multi-precision addition or subtraction.• Example• adda $1000 ; A [A] + [$1000]• adca $1000 ; A [A] + [$1000] + C• suba $1002 ; A [A] + [$1002]• sbca $1000 ; A [A] - [$1000] - C
Add Instructions
Table 1.7 Add and subtract instructions
Mnemonic
ABAABXABY
ADCAADCBADDAADDBADDD
Function
Add B to AAdd B to XAdd B to YAdd with carry to AAdd with carry to BAdd without carry to AAdd without carry to BAdd without carry to D
Operation
(A) + (B) A(B) + (X) X(B) + (Y) Y(A) + (M) + C A(B) + (M) + C B(A) + (M) A(B) + (M) B(A:B) + (M:M+1) A:B
Subtract Instructions
Mnemonic Function
SBASBCASBCBSUBASUBBSUBD
Subtract B from ASubtract with borrow from ASubtract with borrow from BSubtract memory from ASubtract memory from BSubtract memory from D
(A) - (B) A(A) - (M) - C A(B) - (M) - C B(A) - (M) A(B) - (M) B(D) - (M:M+1) D
Operation
• Instruction Execution Cycle– One or more read cycles to fetch instruction opcode bytes
and addressing information– One or more read cycles to fetch the memory operand (s)
(optional)– Perform the operation specified by the opcode– One or more write cycles to write back the result to either a
register or a memory location (optional)• Instruction Queue
– The HCS12 executes one instruction at a time and many instructions take several clock cycles to complete.
– When the CPU is performing the operation, it does not need to access memory.
• The HCS12 prefetches instructions when the CPU is not accessing memory to speedup the instruction execution process.
• There are two 16-bit queue stages and one 16-bit buffer. Unless buffering is required, program information is first queued in stage 1, and then advanced to stage 2 for execution.
Embedded SystemAny product that uses a microprocessor or microcontroller as its controller.Functionality is the focus not the processor itself.
Weather Station
RFreceiver RF
transmitter
outdoormodule
Indoormodule
temperatu
re
hum
idity
light in
tensity
temperature
humidity
display
time-of-dayinput
Figure 1.6 Block diagram of a weather station
alarm
Other Examples of Embedded System
• Cell phone: making the phone call, accepting incoming call, accessing Internet, displaying
• Web page: handling input/output, keeping track of time, taking picture, and playing game
• Home security system: sensing external temperature, smoke, humidity, and intruders; taking appropriate actions according to the detected events
• Automobile: monitoring speed, gas level, temperature, distance, direction, and so on; controlling display, full injection, air bag deployment, cruising, and so on; giving warnings
• Network router: responsible for message routing, congestion and traffic control, and so on