The PDP-11 architecture[1] is a 16-bit CISC instruction set architecture (ISA) developed by Digital Equipment Corporation (DEC). It is implemented by central processing units (CPUs) and microprocessors used in PDP-11 minicomputers. It was in wide use during the 1970s, but was eventually overshadowed by the more powerful VAX architecture in the 1980s.

PDP-11
DesignerDigital Equipment Corporation
Bits16-bit
Introduced1970; 54 years ago (1970)
DesignCISC
TypeRegister–register
Register–memory
Memory–memory
EncodingVariable (2 to 6 bytes)
BranchingCondition code
EndiannessMixed (little-endian for 16-bit integers)
ExtensionsEIS, FIS, FPP, CIS
OpenNo
SuccessorVAX
Registers
General-purpose8 × 16-bit
Floating point6 × 64-bit floating-point registers if FPP present

Memory

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Data formats

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The smallest unit of addressable and writable memory is the 8-bit byte. Bytes can also be held in the lower half of registers R0 through R5.

16-bit words are stored little-endian with least significant bytes at the lower address. Words are always aligned to even memory addresses. Words can be held in registers R0 through R7.

32-bit double words in the Extended Instruction Set (EIS) can only be stored in register pairs with the lower word being stored in the lower-numbered register. Double words are used by the MUL, DIV, and ASHC instructions. Other 32-bit data are supported as extensions to the basic architecture: floating point in the FPU Instruction Set or long data in the Commercial Instruction Set are stored in more than one format, including an unusual middle-endian format[2][3] sometimes referred to as "PDP-endian."

A 64-bit double precision floating point format is supported by the floating point processor option (FPP) for 11/45 and most subsequent models.

Memory management

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The PDP-11's 16-bit addresses can address 64 KB. By the time the PDP-11 yielded to the VAX, 8-bit bytes and hexadecimal notation were becoming standard in the industry; however, numeric values on the PDP-11 always use octal notation, and the amount of memory attached to a PDP-11 is always stated as a number of words. The basic logical address space is 32K words, but the high 4K of physical address space (addresses 1600008 through 1777778 in the absence of memory management) are not populated because input/output registers on the bus respond to addresses in that range. So originally, a fully expanded PDP-11 had 28K words, or 56 kbytes in modern terms.

The processor reserves low memory addresses for two-word vectors that give a program counter and processor status word with which to begin a service routine. When an I/O device interrupts a program, it places the address of its vector on the bus to indicate which service routine should take control. The lowest vectors are service routines to handle various types of trap. Traps occur on some program errors, such as an attempt to execute an undefined instruction; and also when the program executes an instruction such as BPT, EMT, IOT, or TRAP to request service from the operating system.

Memory expansion

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During the life of the PDP-11, the 16-bit logical address space became an increasing limitation. Various techniques were used to work around it:

  • Later-model PDP-11 processors include memory management to support virtual addressing. The physical address space was extended to 18 or 22 bits, hence allowing up to 256 KB or 4 MB of RAM. The logical address space (that is, the address space available at any moment without changing the memory mapping table) remains limited to 16 bits.
  • Some models, beginning with the PDP-11/45, can be set to use 32K words (64 KB) as the "instruction space" for program code and a separate 32K words of "data space". Some operating systems—notably Unix since edition V7, and RSX11-M —rely on this feature.
  • Programming techniques, such as overlaying a block of stored instructions or data with another as needed, can conceal paging issues from the application programmer. For example, the Modula-2 compiler produces code under which the run-time system swaps 8 Kb pages into memory as individual procedures receive control.[4]

CPU registers

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DEC PDP-11 registers
15 14 13 12 11 10 09 08 07 06 05 04 03 02 01 00 (bit position)
Main registers
R0 Register 0
R1 Register 1
R2 Register 2
R3 Register 3
R4 Register 4
R5 Register 5
Stack pointer
R6 / SP Register 6 / Stack Pointer
Program counter
R7 / PC Register 7 / Program Counter
Status flags
  I T N Z V C Processor Status Word
    Floating Point Status Register

The CPU contains eight general-purpose 16-bit registers (R0 to R7). Register R7 is the program counter (PC). Although any register can be used as a stack pointer, R6 is the stack pointer (SP) used for hardware interrupts and traps. R5 is often used to point to the current procedure call frame. To speed up context switching, some PDP-11 models provide dual R0-R5 register sets. Kernel, Supervisor (where present), and User modes have separate memory maps, and also separate stack pointers (so that a user program cannot cause the system to malfunction by storing an invalid value in the stack pointer register).

Addressing modes

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Most instructions allocate six bits to specify an operand. Three bits select one of eight addressing modes, and three bits select a general register.

The encoding of the six bit operand addressing mode is as follows:

5 3 2 0
Mode Register


In the following sections, each item includes an example of how the operand would be written in assembly language. Rn means one of the eight registers, written R0 through R7.

General register addressing modes

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The following eight modes can be applied to any general register. Their effects when applied to R6 (the stack pointer, SP) and R7 (the program counter, PC) are set out separately in the following sections.

Code Name Example Description
0n Register Rn The operand is in Rn
1n Register deferred (Rn) Rn contains the address of the operand
2n Autoincrement (Rn) Rn contains the address of the operand, then increment Rn
3n Autoincrement deferred @(Rn) Rn contains the address of the address of the operand, then increment Rn by 2
4n Autodecrement −(Rn) Decrement Rn, then use the result as the address of the operand
5n Autodecrement deferred @−(Rn) Decrement Rn by 2, then use the result as the address of the address of the operand
6n Index X(Rn) Rn X is the address of the operand
7n Index deferred @X(Rn) Rn X is the address of the address of the operand

In index and index deferred modes, X is a 16-bit value taken from a second word of the instruction. In double-operand instructions, both operands can use these modes. Such instructions are three words long.

Autoincrement and autodecrement operations on a register are by 1 in byte instructions, by 2 in word instructions, and by 2 whenever a deferred mode is used, since the quantity the register addresses is a (word) pointer.

Program counter addressing modes

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When R7 (the program counter) is specified, four of the addressing modes naturally yield useful effects:

Code Name Example Description
27 Immediate #n The operand is the next word of the instruction
37 Absolute @#a The address of the operand is the next word of the instruction
67 Relative a The address of the operand is the next word of the instruction added to the PC
77 Relative deferred @a The address of the address of the operand is the next word of the instruction added to PC

The only common use of absolute mode, whose syntax combines immediate and deferred mode, is to specify input/output registers, as the registers for each device have specific memory addresses. Relative mode has a simpler syntax and is more typical for referring to program variables and jump destinations. A program that uses relative mode (and relative deferred mode) exclusively for internal references is position-independent; it contains no assumptions about its own location, so it can be loaded into an arbitrary memory location, or even moved, with no need for its addresses to be adjusted to reflect its location (relocated). In computing such addresses relative to the current location, the processor performed relocation on the fly.

Immediate and absolute modes are merely autoincrement and autoincrement deferred mode, respectively, applied to PC. When the auxiliary word is "in the instruction" as the above table says, the PC for the next instruction is automatically incremented past the auxiliary word. As PC always points to words, the autoincrement operation is always by 2.

Stack addressing modes

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R6, also written SP, is used as a hardware stack for traps and interrupts. A convention enforced by the set of modes the PDP-11 provides is that a stack grows downward—toward lower addresses—as items are pushed onto it. When a mode is applied to SP, or to any register the programmer elects to use as a software stack, the addressing modes have the following effects:

Code Name Example Description
16 Deferred (SP) The operand is on the top of the stack
26 Autoincrement (SP) The operand is on the top of the stack, then pop it off
36 Autoincrement deferred @(SP) A pointer to the operand is on top of the stack; pop the pointer off
46 Autodecrement −(SP) Push a value onto the stack
66 Indexed X(SP) This refers to any item on the stack by its positive distance from the top
76 Indexed deferred @X(SP) This refers to a value to which a pointer is at the specified location on the stack

Although software stacks can contain bytes, SP is always a stack of words. Autoincrement and autodecrement operations on SP are always by 2.

Instruction set

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The PDP-11 operates on bytes and words. Bytes are specified by a register number—identifying the register's low-order byte—or by a memory location. Words are specified by a register number or by the memory location of the low-order byte, which must be an even number. In most instructions that take operands, bit 15 is set to specify byte addressing, or clear to specify word addressing. In the lists in the following two sections, the assembly-language programmer appended B to the instruction symbol to specify a byte operation; for example, MOV became MOVB.

A few instructions, for example MARK and SOB, were not implemented on some PDP-11 models.

Double-operand instructions

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The high-order four bits specify the operation to be performed (with bit 15 generally selecting word versus byte addressing). Two groups of six bits specify the source operand addressing mode and the destination operand addressing mode, as defined above.

15 12 11 9 8 6 5 3 2 0
Opcode Src Register Dest Register
Opcode Mnemonic Operation
01 MOV Move: Dest ← Src

Note: Moving byte to a register sign-extends into bits 8-15

11 MOVB
02 CMP Compare: Set-flags(Src − Dest)
12 CMPB
03 BIT Bit test: Set-flags(Src ∧ Dest)
13 BITB
04 BIC Bit clear: Dest ← Dest ∧ Ones-complement(Src)
14 BICB
05 BIS Bit set: Dest ← Dest ∨ Src
15 BISB
06 ADD Add: Dest ← Dest Src
16 SUB Subtract: Dest ← Dest − Src

The ADD and SUB instructions use word addressing, and have no byte-oriented variations.

Some two-operand instructions utilize an addressing mode operand and an additional register operand:

15 9 8 6 5 3 2 0
Opcode Reg Src/Dest Register

Where a register pair is used (written below as "(Reg, Reg 1)", the first register contains the low-order portion of the operand and must be an even numbered register. The next higher numbered register contains the high-order portion of the operand (or the remainder). An exception is the multiply instruction; Reg may be odd, but if it is, the high 16 bits of the result are not stored.

Opcode Mnemonic Operation
070 MUL Multiply: (Reg, Reg 1) ← Reg × Src
071 DIV Divide: Compute (Reg, Reg 1) ÷ Src; Reg ← quotient; Reg 1 ← remainder
072 ASH Arithmetic shift: if Src<5:0> < 0 then Reg ← Shift-right(Reg, -Src<5:0>) else Reg ← Shift-left(Reg, Src<5:0>)
073 ASHC Arithmetic shift combined: if Src<5:0> < 0 then (Reg, Reg 1) ← Shift-right((Reg, Reg 1), -Src<5:0>) else (Reg, Reg 1) ← Shift-left((Reg, Reg 1), Src<5:0>)
074 XOR Exclusive or: Dest ← Dest ⊻ Reg

Single-operand instructions

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The high-order ten bits specify the operation to be performed, with bit 15 generally selecting byte versus word addressing. A single group of six bits specifies the operand as defined above.

15 6 5 3 2 0
Opcode Src/Dest Register
Opcode Mnemonic Operation
0001 JMP Jump: PC ← Src
0003 SWAB Swap bytes of word: Dest ← Swap-bytes(Dest)
0050 CLR Clear: Dest ← 0
1050 CLRB
0051 COM Complement: Dest ← Ones-complement(Dest)
1051 COMB
0052 INC Increment: Dest ← Dest 1
1052 INCB
0053 DEC Decrement: Dest ← Dest − 1
1053 DECB
0054 NEG Negate: Dest ← Twos-complement(Dest)
1054 NEGB
0055 ADC Add carry: Dest ← Dest C flag
1055 ADCB
0056 SBC Subtract carry: Dest ← Dest - C flag
1056 SBCB
0057 TST Test: Set-flags(Src)
1057 TSTB
0060 ROR Rotate right: Dest ← Rotate-right(Dest, 1)
1060 RORB
0061 ROL Rotate left: Dest ← Rotate-left(Dest, 1)
1061 ROLB
0062 ASR Arithmetic shift right: Dest ← Shift-right(Dest, 1)
1062 ASRB
0063 ASL Arithmetic shift left: Dest ← Shift-left(Dest, 1)
1063 ASLB
1064 MTPS Move to PSW: PSW ← Src
0065 MFPI Move from previous I space: −(SP) ← Src
1065 MFPD Move from previous D space: −(SP) ← Src
0066 MTPI Move to previous I space: Dest ← (SP)
1066 MTPD Move to previous D space: Dest ← (SP)
0067 SXT Sign extend: if N flag ≠ 0 then Dest ← -1 else Dest ← 0
1067 MFPS Move from PSW: Dest ← PSW

Branch instructions

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In most branch instructions, whether the branch is taken is based on the state of the condition codes. A branch instruction is typically preceded by a two-operand CMP (compare) or BIT (bit test) or a one-operand TST (test) instruction. Arithmetic and logic instructions also set the condition codes. In contrast to Intel processors in the x86 architecture, MOV instructions set them too, so a branch instruction could be used to branch depending on whether the value moved was zero or negative.

The high-order byte of the instruction specifies the operation. Bits 9 through 15 are the op-code, and bit 8 is the value of the condition code calculation which results in the branch being taken. The low-order byte is a signed word offset relative to the current location of the program counter. This allows for forward and reverse branches in code.

15 9 8 7 0
Opcode C Offset
Opcode C Mnemonic Condition or Operation
000 1 BR Branch always PC ← PC 2 × Sign-extend(Offset)
001 0 BNE Branch if not equal Z = 0
001 1 BEQ Branch if equal Z = 1
002 0 BGE Branch if greater than or equal (N ⊻ V) = 0
002 1 BLT Branch if less than (N ⊻ V) = 1
003 0 BGT Branch if greater than (Z ∨ (N ⊻ V)) = 0
003 1 BLE Branch if less than or equal (Z ∨ (N ⊻ V)) = 1
100 0 BPL Branch if plus N = 0
100 1 BMI Branch if minus N = 1
101 0 BHI Branch if higher (C ∨ Z) = 0
101 1 BLOS Branch if lower or same (C ∨ Z) = 1
102 0 BVC Branch if overflow clear V = 0
102 1 BVS Branch if overflow set V = 1
103 0 BCC or BHIS Branch if carry clear, or Branch if higher or same C = 0
103 1 BCS or BLO Branch if carry set, or Branch if lower C = 1

The limited range of the branch instructions meant that, as code grew, the target addresses of some branches would become unreachable. The programmer would change the one-word BR to the two-word JMP instruction from the next group. As JMP has no conditional forms, the programmer would change BEQ to a BNE that branched around a JMP.

SOB (Subtract One and Branch) is another conditional branch instruction. The specified register is decremented by 1, and if the result is not zero, a reverse branch is taken based on the 6 bit word offset.

15 9 8 6 5 0
Opcode Reg Offset
Opcode Mnemonic Operation
077 SOB Subtract One and Branch: Reg ← Reg - 1; if Reg ≠ 0 then PC ← PC - 2 × Offset

Subroutine instructions

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JSR calls a subroutine. A group of six bits specifies the addressing mode. The JSR instruction can save any register on the stack and load that register with the return address. Programs that do not need this feature specify PC as the register (JSR PC, address) and the routine returns using RTS PC.

If a routine is called with, for instance, JSR R4, address, then the old value of R4 is pushed on the top of the stack and the address just after JSR (ordinarily, the return address) is placed in R4. However, the routine can gain access to values coded in-line by specifying (R4) , or to in-line pointers by specifying @(R4) . The autoincrementation moves past these data, to the point at which the caller's code resumes. In either case, such a routine specifies RTS R4 to return to its caller.

The JSR PC,@(SP) form, which exchanges the contents of PC with the top element of the stack, can be used to implement coroutines. Once a routine places the entry address of the coroutine on the stack, executing JSR PC,@(SP) saves PC on the stack and jumps to the coroutine. Both coroutines can then use additional JSR PC,@(SP) instructions to jump to the other coroutine wherever it left off. This lets the two routines swap control and resume one another at the point of the previous swap.

15 9 8 6 5 3 2 0
Opcode Reg Src Register
Opcode Mnemonic Operation
004 JSR Jump to subroutine: -(SP) ← Reg; Reg ← PC; PC ← Src

The value of PC moved to Reg is the address after the JSR instruction.

15 3 2 0
Opcode Reg
Opcode Mnemonic Operation
00020 RTS Return from subroutine: PC ← Reg; Reg ← (SP)
15 6 5 0
Opcode nn
Opcode Mnemonic Operation
0064 MARK Return from subroutine, discard stack entries: SP ← SP (2 x nn), PC ← R5, R5 ← (SP)

MARK is used to delete parameters on the stack when exiting a subroutine. MARK is unusual in that it is placed on the return stack by the caller for later execution directly on the stack by the return routine. First, the caller pushes R5 on the stack. Next, up to 63 word arguments may be placed on the stack. The caller then adds the number of arguments to the MARK opcode and pushes that result on the stack. The value of SP is copied to R5. Finally, a JSR PC,address is executed to call the subroutine. After executing its code, the subroutine terminates with an RTS R5. This loads the value in R5 (pointing to MARK instruction on stack) into the PC and pops the caller's return address into R5. The MARK instruction is executed. MARK multiplies the number of arguments by 2, adds that to SP, deleting the arguments, and then returns to caller with the equivalent of an RTS R5. The MARK instruction is rarely used as its convoluted operation can be replaced by an ADD to SP.[5]

Trap instructions

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15 9 8 7 0
Opcode S Operation Code
Opcode S Mnemonic Operation
104 0 EMT Emulator trap: -(SP) ← PS; -(SP) ← PC; PC ← (30); PS ← (32)
104 1 TRAP General trap: -(SP) ← PS; -(SP) ← PC; PC ← (34); PS ← (36)
15 0
Opcode
Opcode Mnemonic Operation
000002 RTI Return from interrupt: PC ← (SP) ; PS ← (SP)
000003 BPT Breakpoint trap: -(SP) ← PS; -(SP) ← PC; PC ← (14); PS ← (16)
000004 IOT I/O trap: -(SP) ← PS; -(SP) ← PC; PC ← (20); PS ← (22)
000006 RTT Return from trap: PC ← (SP) ; PS ← (SP)

Trap and Exception Vector Address Assignments

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Vector Condition
000000 (Reserved)
000004 Illegal instruction, bus error, stack limit
000010 Reserved instruction
000014 BPT instruction, trace trap
000020 IOT instruction
000024 Power fail
000030 EMT instruction
000034 TRAP instruction
000114 Parity error
000244 Floating point exception
000250 Memory management fault

Miscellaneous instructions

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15 0
Opcode
Opcode Mnemonic Operation
000000 HALT Halt processor: Halt execution before next instruction
000001 WAIT Wait for interrupt: Halt execution before next instruction; Resume execution at next interrupt handler
000005 RESET Reset UNIBUS: Assert INIT on UNIBUS for 10 ms; All other devices reset to power up state
000240 NOP Do nothing

Condition-code operations

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15 6 5 4 3 2 1 0
Opcode 1 S N Z V C
Opcode S Mnemonic Operation
0002 0 Ccc Clear condition codes: Clear codes according to N, Z, V, C bits
0002 1 Scc Set condition codes: Set codes according to N, Z, V, C bits

The four condition codes in the processor status word (PSW) are

  • N indicating a negative value
  • Z indicating a zero (equal) condition
  • V indicating an overflow condition, and
  • C indicating a carry condition.

Instructions in this group were what Digital called "micro-programmed": A single bit in the instruction word referenced a single condition code. The assembler did not define syntax to specify every combination, but the symbols SCC and CCC assembled an instruction that set or cleared, respectively, all four condition codes.

Clearing or setting none of the condition codes (opcodes 000240 and 000260, respectively) could effectively be considered as no-operation instructions. In fact, the NOP mnemonic assembled into 000240.

Inconsistent instructions

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Over the life of the PDP-11, subtle differences arose in the implementation of instructions and combinations of addressing modes, though no implementation was regarded as correct. The inconsistencies did not affect ordinary use of the PDP-11.

Optional instruction sets

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Extended Instruction Set (EIS)

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The EIS is an option for the 11/35/40 and 11/03, and was supplied as standard on newer processors.

  • MUL, DIV multiply and divide integer operand to register pair
  • ASH, ASHC arithmetic - shift a register or a register pair. For a positive number it will shift left, and right for a negative one.

Floating Instruction Set (FIS)

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FIS is an option for the PDP-11/35/40 and 11/03. Single-precision floats are operated on a stack addressed by a register operand. The high-order 13 bits specify the operation to be performed. A three bit field specifies which register is used as the floating point operand stack pointer. Each float is two words and each floating point instruction operates on two floats, returning one float as a result. The selected stack pointer is incremented by a stride of 4 after each operation.

15 3 2 0
Opcode Reg
Opcode Mnemonic Operation
07500 FADD Floating add: 4(Rn) ← 4(Rn) (Rn), Rn ← Rn 4
07501 FSUB Floating subtract: 4(Rn) ← 4(Rn) - (Rn), Rn ← Rn 4
07502 FMUL Floating Multiply: 4(Rn) ← 4(Rn) × (Rn), Rn ← Rn 4
07503 FDIV Floating Divide: 4(Rn) ← 4(Rn) ÷ (Rn), Rn ← Rn 4

Floating Point Processor (FPP)

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This was the optional floating point processor option for 11/45 and most subsequent models.

  • full floating point operations on single- or double-precision operands, selected by single/double bit in Floating Point Status Register
  • single-precision floating point data format predecessor of IEEE 754 format: sign bit, 8-bit exponent, 23-bit mantissa with hidden bit 24

Commercial Instruction Set (CIS)

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The Commercial Instruction Set, known as CIS or CIS11, adds string and binary coded decimal (BCD) instructions used by COBOL and DIBOL. It was implemented by optional microcode in the 11/23/24, and by an add-in module in the 11/44 and one version of the 11/74.[6]

Strings are represented by two 16-bit integers stored in any two of the general-purpose registers, or as two 16-bit values in subsequent locations in memory. One is designated "n", which is the length up to 64 kB, and the other "A", which is a pointer to the start of the character data in memory. Together, an n/A pair indicates the location and length of the string. The basic operations are MOVEC, MOVTC and MOVRC, which move the character data in memory from the location indicated in one n/A pair to the location in a second n/A, both in registers. MOVECI, MOVTCI and MOVRCI did the same but with the locations indicated by n/A pairs in memory instead of registers. In all of the move instructions, if the source is shorter than the destination, the destination is padded, if the source is longer, it is truncated. If either occurs, the processor status flags are used to indicate this.[6]

MOVEC/MOVECI simply copies the data from one location to another. MOVRC/MOVRCI reverses the original string into the destination. MOVTC/MOVTCI translates characters during copy using a 256-byte lookup table held in a third n/A pair, with the A pointing to the start of the table and the lower eight bits of n being a value used to fill the destination string if the source string is shorter. Translations use the source string's character values as index numbers and copy the value in the translation table at that index into the destination string. This can be used for EBCDIC to ASCII conversions by placing the corresponding ASCII character code for the mapped EBCDIC codes in the table. The character "E" is character 69 in ASCII and 197 in EBCDIC, so to convert EBCDIC to ASCII one would make a table of 256 bytes with a 69 in location 197. When MOVTC is called and sees a 197 in the original string, it will output 97 in the new string, performing the conversion.[6]

String comparisons are handled by CMPC, which sets the processor condition codes based on the results of comparing two strings. LOCC finds the first occurrence of a character in a string, while SKPC searches for the first character that does not match, used for trimming blanks at the start of strings, for instance. SCANC and SPANC are similar to LOCC and SKPC, but match any character in a masked character set. This can be used, for instance, to find the next occurrence of any line-breaking character like VT, LF or CR. Character sets are a table of 256 bytes, split into subsets.[a] These are similar to the translation tables with the lower eight bits of the first word forming a mask, and the second word pointing to the start of the table. The mask selects which of the subsets, up to eight, are part of the character set during comparisons. Using this system, one can define character sets like uppercase, lowercase, digits, etc. and then easily make a union via the mask, for instance, selecting the upper and lowercase subsets to produce the complete set of letters.[6]

CIS also includes a set of data types and instructions for manipulating BCD numbers. This data is also represented by two 16-bit registers or memory locations, with the second number being the A identical to the string case. The first word now contains four fields which describe the string representation of the data, which include packed and unpacked digits, handling the sign, and the length of the string, from 0 to 16 bytes. DEC referred to unpacked data, with one digit per byte, as "numeric strings". Using packed data, with two BCD digits per byte, a 16-byte string held BCD numbers up to 32 digits long. Instructions included ADDP/ADDN for packed and unpacked data, SUBP/SUBN, ASHP/ASHN (arithmetic shift) and CMPP/CMPN (compare). Available for packed data only are MULP and DIVP. CIS also includes a set of six instructions (CVT) to convert BCD numbers between packed and unpacked formats, as well as to and from binary values.[6]

A final set of instructions is provided to load two or three 2-word string descriptors to the internal registers, avoiding the need for multiple MOVs.[6]

Access to Processor Status Word (PSW)

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The PSW is mapped to memory address 177 776, and can thus be processed like any data. Instructions found on all but the earliest PDP-11s give programs more direct access to the register.

  • SPL (set priority level)
  • MTPS (move to Processor Status)
  • MFPS (move from Processor Status)

Access to other memory spaces

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On PDP-11s that provide multiple instruction spaces and data spaces, a set of non-orthogonal Move instructions give access to other spaces. For example, routines in the operating system that handle run-time service calls use these instructions to exchange information with the caller.

  • MTPD (move to previous data space)
  • MTPI (move to previous instruction space)
  • MFPD (move from previous data space)
  • MFPI (move from previous instruction space)

Example code

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The following PDP-11 assembly source code is for a subroutine named TOUPPER that converts a null-terminated ASCIIZ character string to upper case.









000000
000000  010046
000002  010146
000004  016600 000006

000010  112001
000012  001414
000014  120127 000172       
000020  003373
000022  120127 000141
000026  002776
000030  142740 000040
000034  000766

000036  012601
000040  012600
000042  000207
; TOUPPER:
; Scan a null-terminated ASCII string, converting
; all alphabetic characters to upper case.
;
; Entry stack parameters,
;      [SP 2] = Address of target string
;      [SP 0] = Return address
;
TOUPPER:
       MOV    R0,-(SP)         ; Save some registers
	   MOV    R1,-(SP)
	   MOV 	  6(SP),R0         ; Get address of string

LOOP:  MOVB	  (R0) ,R1         ; Get a character
	   BEQ	  DONE             ; If zero, then done
	   CMPB	  R1, #’z          ; Is it between a and z?
	   BGT	  LOOP             ; If not, get next char
	   CMPB	  R1, #’a
	   BLT	  LOOP
	   BICB	  #40,-(R0)        ; If a-z, then make it A-Z
	   BR	  LOOP

DONE:  MOV	  (SP) ,R1         ; restore registers
	   MOV	  (SP) ,R0
	   RTS	  PC               ; Return from subroutine

The following PDP-11 assembly source code demonstrates how the PDP-11's addressing modes can be used to write the same routine with no general registers at all.









000000
000000  105776 000002
000004  001416
000006  127627 000002 000172
000014  003008
000016  127627 000002 000141
000024  002403
000026  142776 000040 000002
000034  005266 000002
000040  000757

000042  000207
; TOUPPER2:
; Scan a null-terminated ASCII string, converting
; all alphabetic characters to upper case.
;
; Entry stack parameters,
;      [SP 2] = Address of target string
;      [SP 0] = Return address
;
TOUPPER2:
       TSTB	  @2(SP)           ; Test char at address on stack
	   BEQ	  DONE             ; If zero, then done
	   CMPB	  @2(SP), #’z      ; Is it between a and z?
	   BGT	  NEXTC            ; If not, point to next char
	   CMPB	  @2(SP), #’a
	   BLT	  NEXTC
	   BICB	  #40,@2(SP)       ; If a-z, then make it A-Z
NEXTC: INC	  2(SP)            ; Inc address of next char on stack
	   BR	  TOUPPER2

DONE:  RTS	  PC

Speed

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PDP-11 processor speed varies by model, memory configuration, op code, and addressing modes. Instruction timings have up to three components, fetch/execute of the instruction itself and access time for the source and the destination. The last two components depend on the addressing mode. For example, on the PDP-11/70 (circa 1975), an instruction of the form ADD x(Rm),y(Rn) had a fetch/execute time of 1.35 microseconds plus source and destination times of 0.6 microseconds each, for a total instruction time of 2.55 microseconds. Any case where addressed memory is not in the cache adds 1.02 microseconds. The register-to-register ADD Rm,Rn can execute from the cache in 0.3 microseconds. Floating point is even more complex, since there is some overlap between the CPU and the floating-point processor, but in general, floating point is significantly slower. A single-precision floating add instruction ranges from 2.4 to 5.5 microseconds plus time to fetch the operands.[7]

Interrupts

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The PDP-11 operates at a priority level from 0 through 7, specified by three bits in the Processor Status Word (PSW), and high-end models can operate in a choice of modes, Kernel (privileged), User (application), and sometimes Supervisor, according to two bits in the PSW.

To request an interrupt, a bus device asserts one of four common bus lines, BR4 through BR7, until the processor responds. Higher numbers indicated greater urgency, perhaps that data might be lost or a desired sector might rotate out of contact with the read/write heads unless the processor responds quickly. The printer's readiness for another character is the lowest priority (BR4), as it can remain ready indefinitely. If the processor is operating at level 5, then BR6 and BR7 would be in order. If the processor is operating at 3 or lower, it will grant any interrupt; if at 7, it will grant none. Bus requests that are not granted are not lost but merely deferred. The device needing service continues to assert its bus request.

Whenever an interrupt exceeds the processor's priority level, the processor asserts the corresponding bus grant, BG4 through BG7. The bus-grant lines are not common lines but are a daisy chain: The input of each gate is the output of the previous gate in the chain. A gate is on each bus device, and a device physically closer to the processor is earlier in the daisy chain. If the device has made a request, then on sensing its bus-grant input, it concludes it is in control of the bus, and does not pass the grant signal to the next device on the bus. If the device has not made a request, it propagates its bus-grant input to its bus-grant output, giving the next closest device the chance to reply. (If devices do not occupy adjacent slots to the processor board, "grant continuity cards" inserted into the empty slots propagate the bus-grant line.)

Once in control of the bus, the device drops its bus request and places on the bus the memory address of its two-word vector. The processor saves the program counter (PC) and PSW, enters Kernel mode, and loads new values from the specified vector. For a device at BR6, the new PSW in its vector typically specifies 6 as the new processor priority, so the processor will honor more urgent requests (BR7) during the service routine, but defer requests of the same or lower priority. With the new PC, the processor jumps to the service routine for the interrupting device. That routine operates the device, at least removing the condition that caused the interrupt. The routine ends with the RTI (ReTurn from Interrupt) instruction, which restores PC and PSW as of just before the processor granted the interrupt.

If a bus request is made in error and no device responds to the bus grant, the processor times out and performs a trap that suggests bad hardware.

MACRO-11 assembly language

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Punched tape used for PDP-11

MACRO-11 is the assembly language for the PDP-11. It is the successor to PAL-11 (Program Assembler Loader), an earlier version of the PDP-11 assembly language without macro facilities. MACRO-11 is supported on all DEC PDP-11 operating systems. PDP-11 Unix systems also include an assembler (called "as"), structurally similar to MACRO-11, but with different syntax and fewer features.

See also

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  • WD16, an extension of the PDP-11 ISA

Notes

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  1. ^ The one-byte mask would imply there are eight subsets of 32 characters each, but this is not clearly stated in the documentation.

References

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  1. ^ pdp11 processor handbook pdp11/04/34a/44/60/70 (PDF). DEC. 1979. Retrieved 13 November 2015.
  2. ^ "Chapter 7". processor handbook pdp11/05/10/35/40 (PDF). DEC. 1973.
  3. ^ pdp11 processor handbook pdp11/04/34a/44/60/70 (PDF). DEC. 1979. p. 421.
  4. ^ Dotzel, Günter (1986). "On LSI-11, RT-11, Megabytes of Memory and Modula-2/VRS" (PDF).
  5. ^ "The PDP11/40 Processor Handbook". Digital Equipment Corporation. Retrieved 16 July 2024.
  6. ^ a b c d e f "Commercial Instruction Set". pdp11 processor handbook pdp11/04/34a/44/60/70 (PDF). DEC. 1979.
  7. ^ DEC PDP-11/70 Processor Handbook, 1975, Appendix C, Instruction Timing

Further reading

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