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Assembler directives and basic steps ALP of 8086

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Urvashi Singh

ASSEMBLER DIRECTIVES AND PROGRAMMING OF THE 8086

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B Y DR. URVASHI SINGH A S S O C I A T E P R O F E S S O R D E L H I T E C H N I C A L C A M P U S G G S I P U N I V E R S I T Y G R E A T E R N O I D A ( I N D I A ) Assembler directives and basic steps of ALP
ASSEMBLER DIRECTIVES Assembly language: low-level languages for programming computers, microprocessors, microcontrollers, and other IC Assembler Directive: a statement to give direction to the assembler to perform task of the assembly process. control the organization of the program provide necessary information to the assembler to understand ALPs and generate necessary machine codes Indicate how an operand or a section of the program is to be processed by the assembler Consists of two types of statements: instructions and directives Instructions: translated to the machine code by the assembler Directives are not translated to the machine codes
Important terms and rules SYMBOLS: to signify different components of the ALP (assembly Language Program) Symbols consist of following characters:- Upper case & lower case alphabets: A to Z; a to z Digits: 0 to 9 Special characters: $, ?, @, _ (underscore) No distinction between an uppercase and lowercase letter A hexadecimal no. starting with A to F must begin with β€œ0” (zero) ; otherwise will be taken as a symbol VARIABLE: these are symbols whose values can be varied while running a program Names of variables: should be meaningful to make program maintenance easy A variable can use: A to Z; a to z; 0 to 9; @; _ (underscore) Digit can not be used as 1st character of an Assembler variable CONSTANT: these are symbols whose values can not be varies while running a program A numeric constant may be a binary, decimal or hexadecimal number. Symbols B, D & H must be used at the end of a binary, decimal and hexadecimal number, respectively.
Important Assembler Directives of the 8086 Microprocessor Data declaration directives: DB, DW, DD, DQ, DT ASSUME END directives EQU Directive PROC ORG SEGMENT GROUP, INCLUDE, EVEN, ALIGN EXTRN, PUBLIC, TYPE, PTR, LENGTH, OFFSET NAME, LABEL, SHORT, GLOBAL
Data declaration directives 1. DB - The DB directive is used to declare a BYTE -2-BYTE variable - A BYTE is made up of 8 bits. examples: PRICES DB 49H, 98H, 29H; Declare array of 3 bytes named PRICES and initialize them with specified values TEMP DB 100 DUP (?); Set aside 100 bytes of storage in memory and give it the name TEMP. But leave the 100 bytes un-initialized 2. DW - The DW directive is used to declare a WORD type variable - A WORD occupies 16 bits or (2 BYTE). examples: WORDS DW 1234H, 3456H; Declares an array of 2 words and initialize them with the specified values 3. DD - The DD directive is used to declare a DWORD - A DWORD double word is made up of 32 bits =2 Word's or 4 BYTE. examples: ARRAY DD 25629261H; This will define a double word named ARRAY and initialize the double word with the specified value when the program is loaded into memory to be run. The low word, 9261H, will be put in memory at a lower address than the high word.
Data declaration directives (cont.) DQ (DEFINE QUADWORD) The DQ directive is used to tell the assembler to declare a variable 4 words in length or to reserve 4 words of storage in memory. Example: BIG_NUMBER DQ 243598740192A92BH; This will declare a variable named BIG_NUMBER and initialize the 4 words set aside with the specified number when the program is loaded into memory to be run. DT (DEFINE TEN BYTES) The DT directive is used to tell the assembler to declare a variable, which is 10 bytes in length or to reserve 10 bytes of storage in memory. Example: PACKED_BCD DT 11223344556677889900 This will declare an array named PACKED_BCD, which is 10 bytes in length. It will initialize the 10 bytes with the values 11, 22, 33, 44, 55, 66, 77, 88, 99, and 00 when the program is loaded into memory to be run. The statement RESULT DT 20H DUP (0) will declare an array of 20H blocks of 10 bytes each and initialize all 320 bytes to 00 when the program is loaded into memory to be run.
ASSUME DIRECTIVE ASSUME Directive - The ASSUME directive is used to tell the assembler that the name of the logical segment should be used for a specified segment. The 8086 works directly with only 4 physical segments: a Code segment, a data segment, a stack segment, and an extra segment. Example: ASSUME CS:CODE ;This tells the assembler that the logical segment named CODE contains the instruction statements for the program and should be treated as a code segment. ASSUME DS:DATA ;This tells the assembler that for any instruction which refers to a data in the data segment, data will found in the logical segment DATA.
End directive END - End Program ENDP - End Procedure ENDS - End Segment END – it signifies the end of the program module The assembler will ignore any statement after an END directive ENDP - indicates the end of a procedure Syntax: Procedure_name ENDP ENDS - indicates the end of a logical segment Syntax: Segment_name ENDS
Equate (EQU) Directive EQU - This EQU directive is used to give a name to some value or to a symbol. Each time the assembler finds the name in the program, it will replace the name with the value or symbol you given to that name. Example: FACTOR EQU 03H ; you has to write this statement at the starting of your program later in the program you can use this as follows : ADD AL, FACTOR ; When it codes this instruction the assembler will code it as ADDAL, 03H ;The advantage of using EQU in this manner is, if FACTOR is used many no of times in a program and you want to change the value, all you had to do is change the EQU statement at beginning, it will changes the rest of all.
PROC (Procedure) Directive PROC - The PROC directive is used to identify the start of a procedure. The term near or far is used to specify the type of the procedure. Example: SMART PROC FAR ; This identifies that the start of a procedure named as SMART and instructs the assembler that the procedure is far . SMART ENDP ; This PROC is used with ENDP to indicate the break of the procedure.
ORG (ORIGIN) ORG Changes the starting offset address of the data in the data segment. As an assembler assembles a section of a data declarations or instruction statements, it uses a location counter to keep track of how many bytes it is from the start of a segment at any time. The location counter is automatically set to 0000 when assembler starts reading a segment. The ORG directive allows you to set the location counter to a desired value at any point in the program. Example: The statement ORG 2000H tells the assembler to set the location counter to 2000H.
SEGMENT SEGMENT directive : to indicate the start of a logical segment Syntax: Segment_name SEGMENT Additional terms are often added to a SEGMENT directive statement to indicate some special way in which we want the assembler to treat the segment. Example: CODE SEGMENT WORD ; tells the assembler that we want the content of this segment located on the next available word (even address) when segments are combined and given absolute addresses. Without this WORD addition, the segment will be located on the next available paragraph (16-byte) address, which might waste as much as 15 bytes of memory. The statement CODE SEGMENT PUBLIC tells the assembler that the segment may be put together with other segments named CODE from other assembly modules when the modules are linked together.
GROUP, INCLUDE, EVEN, ALIGN GROUP - used to group the logical segments named after the directive into one logical group segment. INCLUDE - used to insert a block of source code from the named file into the current source module. EVEN - instructs the assembler to increment the location of the counter to the next even address if it is not already in the even address. If the word is at even address 8086 can read a memory in 1 bus cycle. If the word starts at an odd address, the 8086 will take 2 bus cycles to get the data. A series of words can be read much more quickly if they are at even address. When EVEN is used the location counter will simply incremented to next address and NOP instruction is inserted in that incremented location. ALIGN: Memory array is stored in word boundaries. Example: ALIGN 2 means storing from an even address
EXTRN, PUBLIC EXTRN : used to tell the assembler that the name or labels following the directive are in some other assembly module. For example, if you want to call a procedure, which in a program module assembled at a different time from that which contains the CALL instruction, you must tell the assembler that the procedure is external. The assembler will then put this information in the object code file so that the linker can connect the two modules together. For a reference to externally named variable, you must specify the type of the variable, as in the statement EXTRN DIVISOR: WORD. The statement EXTRN DIVIDE: FAR tells the assembler that DIVIDE is a label of type FAR in another assembler module. Name or labels referred to as external in one module must be declared public with the PUBLIC directive in the module in which they are defined. PUBLIC - The PUBLIC directive is used to instruct the assembler that a specified name or label will be accessed from other modules. Example: PUBLIC DIVISOR, DIVIDEND ;these two variables are public so these are available to all modules. If an instruction in a module refers to a variable in another assembly module, we can access that module by declaring as EXTRN directive.
TYPE, PTR(POINTER) TYPE - instructs the assembler to determine the type of a variable and determines the number of bytes specified to that variable. Example: Byte type variable – assembler will give a value 1 Word type variable – assembler will give a value 2 Double word type variable – assembler will give a value 4 ADD BX, TYPE WORD_ ARRAY ; hear we want to increment BX to point to next word in an array of words. PTR (POINTER) : used to assign a specific type to a variable or a label. It is necessary to do this in any instruction where the type of the operand is not clear. Example: INC [BX]; It will not know whether to increment the byte pointed to by BX. We use the PTR operator to clarify how we want the assembler to code the instruction. INC BYTE PTR [BX] ; This statement tells the assembler that we want to increment the byte pointed to by BX. INC WORD PTR [BX] ; This statement tells the assembler that we want to increment the word pointed to by BX. The PTR operator assigns the type specified before PTR to the variable specified after PTR.
LENGTH, OFFSET LENGTH : tells the assembler to determine the number of elements in some named data item, such as a string or an array. Example: MOV CX, LENGTH STRING1; This will determine the number of elements in STRING1 and load it into CX. If the string was declared as a string of bytes, LENGTH will produce the number of bytes in the string. If the string was declared as a word string, LENGTH will produce the number of words in the string. OFFSET : tells the assembler to determine the offset or displacement of a named data item (variable), a procedure from the start of the segment, which contains it. Example: MOV BX, OFFSET PRICES; It will determine the offset of the variable PRICES from the start of the segment in which PRICES is defined and will load this value into BX.
NAME, LABEL, SHORT, GLOBAL NAME : used to give a specific name to each assembly module when programs consisting of several modules are written. LABEL : As an assembler assembles a section of a data declarations or instruction statements, it uses a location counter to be keep track of how many bytes it is from the start of a segment at any time. If the label is going to be used as the destination for a jump or a call, then the label must be specified as type near or type far. SHORT The SHORT operator is used to tell the assembler that only a 1 byte displacement is needed to code a jump instruction in the program. The destination must in the range of – 128 bytes to +127 bytes from the address of the instruction after the jump. Example: JMP SHORT NEARBY_LABEL GLOBAL (DECLARE SYMBOLS AS PUBLIC OR EXTRN) : can be used in place of a PUBLIC directive or in place of an EXTRN directive. For a name or symbol defined in the current assembly module, the GLOBAL directive is used to make the symbol available to other modules. Example: GLOBAL DIVISOR This statement makes the variable DIVISOR public so that it can be accessed from other assembly modules.
8086 Programming using Assembler Directives Basic structure of a program: Name_data segment SEGMENT Data declaration statement 1 : : Data declaration statement n DATA ENDS Name_codeseg SEGMENT ASSUME CS:CODE, DS:DATA, ES:EXTRA, SS: STACK START: Program line 1 : : Program line n Name_codeseg ENDS END START
example Program to multiply 2 16-bit words in memory locations called MULTIPLICAND and MULTIPLIER. Result is stored in memory location PRODUCT. DATA SEGMENT MULTIPLICAND DW 204A H; 1ST Word MULTIPLIER DW 3B2A H; 2nd word PRODUCT DW 2 DUP(0); sets aside storage for 2 words in memory and gives starting address of 1st word the name PRODUCT. The DUP(0) part of the statement tells assembler to initialize 2 words to all zeros. DATA ENDS CODE SEGMENT ASSUMER CS:CODE, DS:DATA; START: MOV AX, DATA MOV DS, AX MOV AX, MULTIPLICAND; MUL MULTIPLIER; MOV PRODUCT, AX; MOV PRODUCT+2, DX; INT3 CODE ENDS END START
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Assembler directives and basic steps ALP of 8086

  • 1. B Y DR. URVASHI SINGH A S S O C I A T E P R O F E S S O R D E L H I T E C H N I C A L C A M P U S G G S I P U N I V E R S I T Y G R E A T E R N O I D A ( I N D I A ) Assembler directives and basic steps of ALP
  • 2. ASSEMBLER DIRECTIVES Assembly language: low-level languages for programming computers, microprocessors, microcontrollers, and other IC Assembler Directive: a statement to give direction to the assembler to perform task of the assembly process. control the organization of the program provide necessary information to the assembler to understand ALPs and generate necessary machine codes Indicate how an operand or a section of the program is to be processed by the assembler Consists of two types of statements: instructions and directives Instructions: translated to the machine code by the assembler Directives are not translated to the machine codes
  • 3. Important terms and rules SYMBOLS: to signify different components of the ALP (assembly Language Program) Symbols consist of following characters:- Upper case & lower case alphabets: A to Z; a to z Digits: 0 to 9 Special characters: $, ?, @, _ (underscore) No distinction between an uppercase and lowercase letter A hexadecimal no. starting with A to F must begin with β€œ0” (zero) ; otherwise will be taken as a symbol VARIABLE: these are symbols whose values can be varied while running a program Names of variables: should be meaningful to make program maintenance easy A variable can use: A to Z; a to z; 0 to 9; @; _ (underscore) Digit can not be used as 1st character of an Assembler variable CONSTANT: these are symbols whose values can not be varies while running a program A numeric constant may be a binary, decimal or hexadecimal number. Symbols B, D & H must be used at the end of a binary, decimal and hexadecimal number, respectively.
  • 4. Important Assembler Directives of the 8086 Microprocessor Data declaration directives: DB, DW, DD, DQ, DT ASSUME END directives EQU Directive PROC ORG SEGMENT GROUP, INCLUDE, EVEN, ALIGN EXTRN, PUBLIC, TYPE, PTR, LENGTH, OFFSET NAME, LABEL, SHORT, GLOBAL
  • 5. Data declaration directives 1. DB - The DB directive is used to declare a BYTE -2-BYTE variable - A BYTE is made up of 8 bits. examples: PRICES DB 49H, 98H, 29H; Declare array of 3 bytes named PRICES and initialize them with specified values TEMP DB 100 DUP (?); Set aside 100 bytes of storage in memory and give it the name TEMP. But leave the 100 bytes un-initialized 2. DW - The DW directive is used to declare a WORD type variable - A WORD occupies 16 bits or (2 BYTE). examples: WORDS DW 1234H, 3456H; Declares an array of 2 words and initialize them with the specified values 3. DD - The DD directive is used to declare a DWORD - A DWORD double word is made up of 32 bits =2 Word's or 4 BYTE. examples: ARRAY DD 25629261H; This will define a double word named ARRAY and initialize the double word with the specified value when the program is loaded into memory to be run. The low word, 9261H, will be put in memory at a lower address than the high word.
  • 6. Data declaration directives (cont.) DQ (DEFINE QUADWORD) The DQ directive is used to tell the assembler to declare a variable 4 words in length or to reserve 4 words of storage in memory. Example: BIG_NUMBER DQ 243598740192A92BH; This will declare a variable named BIG_NUMBER and initialize the 4 words set aside with the specified number when the program is loaded into memory to be run. DT (DEFINE TEN BYTES) The DT directive is used to tell the assembler to declare a variable, which is 10 bytes in length or to reserve 10 bytes of storage in memory. Example: PACKED_BCD DT 11223344556677889900 This will declare an array named PACKED_BCD, which is 10 bytes in length. It will initialize the 10 bytes with the values 11, 22, 33, 44, 55, 66, 77, 88, 99, and 00 when the program is loaded into memory to be run. The statement RESULT DT 20H DUP (0) will declare an array of 20H blocks of 10 bytes each and initialize all 320 bytes to 00 when the program is loaded into memory to be run.
  • 7. ASSUME DIRECTIVE ASSUME Directive - The ASSUME directive is used to tell the assembler that the name of the logical segment should be used for a specified segment. The 8086 works directly with only 4 physical segments: a Code segment, a data segment, a stack segment, and an extra segment. Example: ASSUME CS:CODE ;This tells the assembler that the logical segment named CODE contains the instruction statements for the program and should be treated as a code segment. ASSUME DS:DATA ;This tells the assembler that for any instruction which refers to a data in the data segment, data will found in the logical segment DATA.
  • 8. End directive END - End Program ENDP - End Procedure ENDS - End Segment END – it signifies the end of the program module The assembler will ignore any statement after an END directive ENDP - indicates the end of a procedure Syntax: Procedure_name ENDP ENDS - indicates the end of a logical segment Syntax: Segment_name ENDS
  • 9. Equate (EQU) Directive EQU - This EQU directive is used to give a name to some value or to a symbol. Each time the assembler finds the name in the program, it will replace the name with the value or symbol you given to that name. Example: FACTOR EQU 03H ; you has to write this statement at the starting of your program later in the program you can use this as follows : ADD AL, FACTOR ; When it codes this instruction the assembler will code it as ADDAL, 03H ;The advantage of using EQU in this manner is, if FACTOR is used many no of times in a program and you want to change the value, all you had to do is change the EQU statement at beginning, it will changes the rest of all.
  • 10. PROC (Procedure) Directive PROC - The PROC directive is used to identify the start of a procedure. The term near or far is used to specify the type of the procedure. Example: SMART PROC FAR ; This identifies that the start of a procedure named as SMART and instructs the assembler that the procedure is far . SMART ENDP ; This PROC is used with ENDP to indicate the break of the procedure.
  • 11. ORG (ORIGIN) ORG Changes the starting offset address of the data in the data segment. As an assembler assembles a section of a data declarations or instruction statements, it uses a location counter to keep track of how many bytes it is from the start of a segment at any time. The location counter is automatically set to 0000 when assembler starts reading a segment. The ORG directive allows you to set the location counter to a desired value at any point in the program. Example: The statement ORG 2000H tells the assembler to set the location counter to 2000H.
  • 12. SEGMENT SEGMENT directive : to indicate the start of a logical segment Syntax: Segment_name SEGMENT Additional terms are often added to a SEGMENT directive statement to indicate some special way in which we want the assembler to treat the segment. Example: CODE SEGMENT WORD ; tells the assembler that we want the content of this segment located on the next available word (even address) when segments are combined and given absolute addresses. Without this WORD addition, the segment will be located on the next available paragraph (16-byte) address, which might waste as much as 15 bytes of memory. The statement CODE SEGMENT PUBLIC tells the assembler that the segment may be put together with other segments named CODE from other assembly modules when the modules are linked together.
  • 13. GROUP, INCLUDE, EVEN, ALIGN GROUP - used to group the logical segments named after the directive into one logical group segment. INCLUDE - used to insert a block of source code from the named file into the current source module. EVEN - instructs the assembler to increment the location of the counter to the next even address if it is not already in the even address. If the word is at even address 8086 can read a memory in 1 bus cycle. If the word starts at an odd address, the 8086 will take 2 bus cycles to get the data. A series of words can be read much more quickly if they are at even address. When EVEN is used the location counter will simply incremented to next address and NOP instruction is inserted in that incremented location. ALIGN: Memory array is stored in word boundaries. Example: ALIGN 2 means storing from an even address
  • 14. EXTRN, PUBLIC EXTRN : used to tell the assembler that the name or labels following the directive are in some other assembly module. For example, if you want to call a procedure, which in a program module assembled at a different time from that which contains the CALL instruction, you must tell the assembler that the procedure is external. The assembler will then put this information in the object code file so that the linker can connect the two modules together. For a reference to externally named variable, you must specify the type of the variable, as in the statement EXTRN DIVISOR: WORD. The statement EXTRN DIVIDE: FAR tells the assembler that DIVIDE is a label of type FAR in another assembler module. Name or labels referred to as external in one module must be declared public with the PUBLIC directive in the module in which they are defined. PUBLIC - The PUBLIC directive is used to instruct the assembler that a specified name or label will be accessed from other modules. Example: PUBLIC DIVISOR, DIVIDEND ;these two variables are public so these are available to all modules. If an instruction in a module refers to a variable in another assembly module, we can access that module by declaring as EXTRN directive.
  • 15. TYPE, PTR(POINTER) TYPE - instructs the assembler to determine the type of a variable and determines the number of bytes specified to that variable. Example: Byte type variable – assembler will give a value 1 Word type variable – assembler will give a value 2 Double word type variable – assembler will give a value 4 ADD BX, TYPE WORD_ ARRAY ; hear we want to increment BX to point to next word in an array of words. PTR (POINTER) : used to assign a specific type to a variable or a label. It is necessary to do this in any instruction where the type of the operand is not clear. Example: INC [BX]; It will not know whether to increment the byte pointed to by BX. We use the PTR operator to clarify how we want the assembler to code the instruction. INC BYTE PTR [BX] ; This statement tells the assembler that we want to increment the byte pointed to by BX. INC WORD PTR [BX] ; This statement tells the assembler that we want to increment the word pointed to by BX. The PTR operator assigns the type specified before PTR to the variable specified after PTR.
  • 16. LENGTH, OFFSET LENGTH : tells the assembler to determine the number of elements in some named data item, such as a string or an array. Example: MOV CX, LENGTH STRING1; This will determine the number of elements in STRING1 and load it into CX. If the string was declared as a string of bytes, LENGTH will produce the number of bytes in the string. If the string was declared as a word string, LENGTH will produce the number of words in the string. OFFSET : tells the assembler to determine the offset or displacement of a named data item (variable), a procedure from the start of the segment, which contains it. Example: MOV BX, OFFSET PRICES; It will determine the offset of the variable PRICES from the start of the segment in which PRICES is defined and will load this value into BX.
  • 17. NAME, LABEL, SHORT, GLOBAL NAME : used to give a specific name to each assembly module when programs consisting of several modules are written. LABEL : As an assembler assembles a section of a data declarations or instruction statements, it uses a location counter to be keep track of how many bytes it is from the start of a segment at any time. If the label is going to be used as the destination for a jump or a call, then the label must be specified as type near or type far. SHORT The SHORT operator is used to tell the assembler that only a 1 byte displacement is needed to code a jump instruction in the program. The destination must in the range of – 128 bytes to +127 bytes from the address of the instruction after the jump. Example: JMP SHORT NEARBY_LABEL GLOBAL (DECLARE SYMBOLS AS PUBLIC OR EXTRN) : can be used in place of a PUBLIC directive or in place of an EXTRN directive. For a name or symbol defined in the current assembly module, the GLOBAL directive is used to make the symbol available to other modules. Example: GLOBAL DIVISOR This statement makes the variable DIVISOR public so that it can be accessed from other assembly modules.
  • 18. 8086 Programming using Assembler Directives Basic structure of a program: Name_data segment SEGMENT Data declaration statement 1 : : Data declaration statement n DATA ENDS Name_codeseg SEGMENT ASSUME CS:CODE, DS:DATA, ES:EXTRA, SS: STACK START: Program line 1 : : Program line n Name_codeseg ENDS END START
  • 19. example Program to multiply 2 16-bit words in memory locations called MULTIPLICAND and MULTIPLIER. Result is stored in memory location PRODUCT. DATA SEGMENT MULTIPLICAND DW 204A H; 1ST Word MULTIPLIER DW 3B2A H; 2nd word PRODUCT DW 2 DUP(0); sets aside storage for 2 words in memory and gives starting address of 1st word the name PRODUCT. The DUP(0) part of the statement tells assembler to initialize 2 words to all zeros. DATA ENDS CODE SEGMENT ASSUMER CS:CODE, DS:DATA; START: MOV AX, DATA MOV DS, AX MOV AX, MULTIPLICAND; MUL MULTIPLIER; MOV PRODUCT, AX; MOV PRODUCT+2, DX; INT3 CODE ENDS END START