/* hp3000_cpu.h: HP 3000 CPU declarations | |
Copyright (c) 2016, J. David Bryan | |
Permission is hereby granted, free of charge, to any person obtaining a copy | |
of this software and associated documentation files (the "Software"), to deal | |
in the Software without restriction, including without limitation the rights | |
to use, copy, modify, merge, publish, distribute, sublicense, and/or sell | |
copies of the Software, and to permit persons to whom the Software is | |
furnished to do so, subject to the following conditions: | |
The above copyright notice and this permission notice shall be included in | |
all copies or substantial portions of the Software. | |
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR | |
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, | |
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE | |
AUTHOR BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN | |
ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION | |
WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. | |
Except as contained in this notice, the name of the author shall not be used | |
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this Software without prior written authorization from the author. | |
12-Sep-16 JDB Added the PCN_SERIES_II and PCN_SERIES_III constants | |
02-Sep-16 JDB Added the POWER_STATE enumeration type, the UNIT_PFARS | |
flag, and the "cpu_power_state" external declaration | |
24-Aug-16 JDB Fixed the UNIT_CPU_MODEL test macro | |
23-Aug-16 JDB Added the MOD (module control) register | |
12-Jul-16 JDB Renamed "loading" EXEC_STATE to "waiting" | |
21-Mar-16 JDB Changed cpu_ccb_table type from uint16 to HP_WORD | |
14-Feb-16 JDB First release version | |
11-Dec-12 JDB Created | |
This file provides the declarations for interoperation between the CPU and | |
its supporting modules. It provides the symbols that allow direct | |
manipulation of the CPU registers and determination of currently installed | |
features. | |
*/ | |
#include <setjmp.h> | |
/* Architectural constants. | |
The type used to represent a main memory word value is defined. An array of | |
this type is used to simulate the CPU main memory. | |
Implementation notes: | |
1. The MEMORY_WORD type is a 16-bit unsigned type, corresponding with the | |
16-bit main memory in the HP 3000. Unlike the general data type, which | |
is a 32-bit type for speed, main memory does not benefit from the faster | |
32-bit execution on IA-32 processors, as only one instruction in the | |
cpu_read_memory and cpu_write_memory routines has an operand override | |
that invokes the slower instruction fetch path. There is a negligible | |
difference in the Memory Pattern Test diagnostic execution speeds for the | |
uint32 vs. uint16 definition, whereas the VM requirements are doubled for | |
the former. | |
*/ | |
typedef uint16 MEMORY_WORD; /* HP 16-bit memory word representation */ | |
/* Supported breakpoint switches */ | |
#define BP_EXEC (SWMASK ('E')) /* an execution breakpoint */ | |
#define BP_SUPPORTED (BP_EXEC) /* the list of supported breakpoint types */ | |
/* Unit flags and accessors */ | |
#define UNIT_MODEL_SHIFT (UNIT_V_UF + 0) /* the CPU model (1 bit) */ | |
#define UNIT_EIS_SHIFT (UNIT_V_UF + 1) /* the Extended Instruction Set firmware option */ | |
#define UNIT_CALTIME_SHIFT (UNIT_V_UF + 2) /* the process clock timing mode */ | |
#define UNIT_PFARS_SHIFT (UNIT_V_UF + 3) /* the power-fail auto-restart mode */ | |
#define UNIT_MODEL_MASK 0000001u /* model ID mask */ | |
#define UNIT_MODEL (UNIT_MODEL_MASK << UNIT_MODEL_SHIFT) | |
#define UNIT_SERIES_III (0u << UNIT_MODEL_SHIFT) /* the CPU is a Series III */ | |
#define UNIT_SERIES_II (1u << UNIT_MODEL_SHIFT) /* the CPU is a Series II */ | |
#define UNIT_EIS (1u << UNIT_EIS_SHIFT) /* the Extended Instruction Set is installed */ | |
#define UNIT_CALTIME (1u << UNIT_CALTIME_SHIFT) /* the process clock is calibrated to wall time */ | |
#define UNIT_PFARS (1u << UNIT_PFARS_SHIFT) /* the system will auto-restart after a power failure */ | |
#define UNIT_CPU_MODEL (cpu_unit [0].flags & UNIT_MODEL) | |
#define CPU_MODEL(f) ((f) >> UNIT_MODEL_SHIFT & UNIT_MODEL_MASK) | |
#define MEMSIZE (cpu_unit [0].capac) /* the current memory size in 16-bit words */ | |
/* CPU debug flags */ | |
#define DEB_MDATA (1u << 0) /* trace memory data accesses */ | |
#define DEB_INSTR (1u << 1) /* trace instruction execution */ | |
#define DEB_FETCH (1u << 2) /* trace instruction fetches */ | |
#define DEB_REG (1u << 3) /* trace register values */ | |
#define DEB_PSERV (1u << 4) /* trace PCLK service events */ | |
#define BOV_FORMAT "%02o.%06o %06o " /* bank-offset-value trace format string */ | |
/* CPU stop flags */ | |
#define SS_LOOP (1u << 0) /* stop on infinite loop */ | |
#define SS_PAUSE (1u << 1) /* stop on PAUS instruction */ | |
#define SS_UNDEF (1u << 2) /* stop on undefined instruction */ | |
#define SS_UNIMPL (1u << 3) /* stop on unimplemented instruction */ | |
#define SS_BYPASSED (1u << 31) /* stops are bypassed for this instruction */ | |
/* System power state. | |
The HP 3000 power supply uses two signals to indicate its state: PON (power | |
on) and PFW (power-fail warning). PON is asserted when the DC power levels | |
are within their operating ranges. PFW is asserted when AC power is lost. | |
When a power failure occurs, PFW will be asserted at least three milliseconds | |
before PON is denied. When power is restored, PFW denies immediately, but | |
PON does not assert until the DC output voltages have stabilized, and the | |
machine is ready to resume execution. | |
In simulation, the four states of these two signals are modeled with | |
enumeration constants, as follows: | |
PON PFW State Simulator Action | |
--- --- --------------- ---------------------------- | |
1 0 power on executing normally | |
1 1 power failing executing with cpx1_PFINTR | |
0 1 power off will not execute | |
0 0 power returning executing with trap_Power_On | |
*/ | |
typedef enum { | |
power_on, | |
power_failing, | |
power_off, | |
power_returning | |
} POWER_STATE; | |
/* Micromachine execution state */ | |
typedef enum { | |
running, /* the micromachine is running */ | |
paused, /* a PAUS instruction has been executed */ | |
waiting, /* a cold load or dump is in progress */ | |
halted /* a programmed or front panel HALT has been executed */ | |
} EXEC_STATE; | |
/* Memory access classifications. | |
The access classification determines which bank register is used with the | |
supplied offset to access memory, and whether or not the access is bounds | |
checked. | |
Implementation notes: | |
1. The "_iop" and "_sel" classifications are identical. The only difference | |
is which device's trace flag is checked to print debugging information. | |
All of the other classifications check the CPU's trace flags. | |
*/ | |
typedef enum { | |
absolute_iop, /* absolute bank, IOP request */ | |
dma_iop, /* DMA channel bank, IOP request */ | |
absolute_sel, /* absolute bank, selector channel request */ | |
dma_sel, /* DMA channel bank, selector channel request */ | |
absolute, /* absolute bank */ | |
absolute_checked, /* absolute bank, bounds checked */ | |
fetch, /* program bank, instruction fetch */ | |
fetch_checked, /* program bank, instruction fetch, bounds checked */ | |
program, /* program bank, data access */ | |
program_checked, /* program bank, data access, bounds checked */ | |
data, /* data bank, data access */ | |
data_checked, /* data bank, data access, bounds checked */ | |
stack, /* stack bank, data access */ | |
stack_checked /* stack bank, data access, bounds checked */ | |
} ACCESS_CLASS; | |
/* CPX register flags. | |
The CPX1 register contains flags that designate the run-time interrupts. The | |
CPX2 register contains flags for halt-time interrupts. | |
Implementation notes: | |
1. These are implemented as enumeration types to allow the "gdb" debugger to | |
display the CPX register values as bit sets. | |
*/ | |
typedef enum { | |
cpx1_INTOVFL = 0100000u, /* integer overflow */ | |
cpx1_BNDVIOL = 0040000u, /* bounds violation */ | |
cpx1_ILLADDR = 0020000u, /* illegal address */ | |
cpx1_CPUTIMER = 0010000u, /* CPU timer */ | |
cpx1_SYSPAR = 0004000u, /* system parity error */ | |
cpx1_ADDRPAR = 0002000u, /* address parity error */ | |
cpx1_DATAPAR = 0001000u, /* data parity error */ | |
cpx1_MODINTR = 0000400u, /* module interrupt */ | |
cpx1_EXTINTR = 0000200u, /* external interrupt */ | |
cpx1_PFINTR = 0000100u, /* power fail interrupt */ | |
/* cpx1_UNUSED = 0000040u, unused, always 0 */ | |
cpx1_ICSFLAG = 0000020u, /* ICS flag */ | |
cpx1_DISPFLAG = 0000010u, /* dispatcher-is-active flag */ | |
cpx1_EMULATOR = 0000004u, /* emulator-in-use flag */ | |
cpx1_IOTIMER = 0000002u, /* I/O timeout */ | |
cpx1_OPTION = 0000001u /* option present */ | |
} CPX1FLAG; | |
#define CPX1_IRQ_SET (cpx1_INTOVFL | cpx1_BNDVIOL | \ | |
cpx1_ILLADDR | cpx1_CPUTIMER | \ | |
cpx1_SYSPAR | cpx1_ADDRPAR | \ | |
cpx1_DATAPAR | cpx1_MODINTR | \ | |
cpx1_EXTINTR | cpx1_PFINTR) /* the set of CPX1 interrupt requests */ | |
typedef enum { | |
cpx2_RUNSWCH = 0100000u, /* RUN switch */ | |
cpx2_DUMPSWCH = 0040000u, /* DUMP switch */ | |
cpx2_LOADSWCH = 0020000u, /* LOAD switch */ | |
cpx2_LOADREG = 0010000u, /* load register */ | |
cpx2_LOADADDR = 0004000u, /* load address */ | |
cpx2_LOADMEM = 0002000u, /* load memory */ | |
cpx2_DISPMEM = 0001000u, /* display memory */ | |
cpx2_SNGLINST = 0000400u, /* single instruction */ | |
cpx2_EXECSWCH = 0000200u, /* EXECUTE switch */ | |
cpx2_INCRADDR = 0000100u, /* increment address */ | |
cpx2_DECRADDR = 0000040u, /* decrement address */ | |
/* cpx2_UNUSED = 0000020u, unused, always 0 */ | |
/* cpx2_UNUSED = 0000010u, unused, always 0 */ | |
cpx2_INHPFARS = 0000004u, /* inhibit power-fail auto-restart */ | |
cpx2_SYSHALT = 0000002u, /* system halt */ | |
cpx2_RUN = 0000001u /* run flip-flop */ | |
} CPX2FLAG; | |
#define CPX2_IRQ_SET (cpx2_RUNSWCH | cpx2_DUMPSWCH | \ | |
cpx2_LOADSWCH | cpx2_LOADREG | \ | |
cpx2_LOADADDR | cpx2_LOADMEM | \ | |
cpx2_DISPMEM | cpx2_SNGLINST | \ | |
cpx2_EXECSWCH) /* the set of CPX2 interrupt requests */ | |
/* Interrupt classifications. | |
Interrupts are generated by setting CPX1 bits, by microcode aborts (traps), | |
or by the DISP or IXIT instructions to run the OS dispatcher or in response | |
to an external interrupt. Each interrupt source is serviced by a procedure | |
in the Segment Transfer Table of segment 1, and the classification values are | |
chosen to match the STT numbers. | |
Implementation notes: | |
1. The STT numbers are relevant only for interrupts that come from setting | |
the CPX1 bits (except for bit 8). The enumeration values for external, | |
trap, DISP, and IXIT interrupts are not significant. | |
*/ | |
typedef enum { | |
/* identifier STT Source Description */ | |
/* ----------------------- --- ------ ------------------------- */ | |
irq_Integer_Overflow = 000, /* CPX1.0 Integer Overflow */ | |
irq_Bounds_Violation = 001, /* CPX1.1 Bounds Violation */ | |
irq_Illegal_Address = 002, /* CPX1.2 Illegal Memory Address */ | |
irq_Timeout = 003, /* CPX1.3 Non-Responding Module */ | |
irq_System_Parity = 004, /* CPX1.4 System Parity Error */ | |
irq_Address_Parity = 005, /* CPX1.5 Address Parity Error */ | |
irq_Data_Parity = 006, /* CPX1.6 Data Parity Error */ | |
irq_Module = 007, /* CPX1.7 Module Interrupt */ | |
irq_External = 010, /* CPX1.8 External Interrupt */ | |
irq_Power_Fail = 011, /* CPX1.9 Power Fail Interrupt */ | |
irq_Trap = 012, /* uABORT System or user trap */ | |
irq_Dispatch = 013, /* DISP Run the dispatcher */ | |
irq_IXIT = 014 /* IXIT External interrupt */ | |
} IRQ_CLASS; | |
/* Trap classifications. | |
Except for the power-on trap, all traps result from microcode aborts. In | |
hardware, these result in microcode jumps to the appropriate trap handlers. | |
In simulation, a MICRO_ABORT executes a "longjmp" to the trap handler just | |
before the main instruction loop. As with interrupts, each trap is serviced | |
by a procedure in the Segment Transfer Table of segment 1, and the | |
classification values are chosen to match the STT numbers. | |
Traps are invoked by the MICRO_ABORT macro, which takes as its parameter a | |
trap classification value. Some traps require an additional parameter and | |
must be invoked by the MICRO_ABORTP macro, which takes a trap classification | |
value and a trap-specific value as parameters. | |
Accessors are provided to separate the TRAP_CLASS and the parameter from the | |
combined longjmp value. | |
Implementation notes: | |
1. Trap classifications must be > 0 for longjmp compatibility. | |
2. A System Halt trap does not call an OS procedure but instead stops the | |
simulator. The parameter number indicates the reason for the halt. | |
3. The User trap is subdivided into traps for a number of arithmetic | |
conditions. These are indicated by their corresponding parameter numbers | |
in the upper words of the longjmp values. | |
*/ | |
typedef enum { | |
/* identifier STT Source Description */ | |
/* ------------------------ --- ------ ------------------------- */ | |
trap_None = 000, /* -- (none) */ | |
trap_Bounds_Violation = 001, /* ucode Bounds Violation */ | |
trap_Unimplemented = 020, /* ucode Unimplemented Instruction */ | |
trap_STT_Violation = 021, /* ucode STT Violation */ | |
trap_CST_Violation = 022, /* ucode CST Violation */ | |
trap_DST_Violation = 023, /* ucode DST Violation */ | |
trap_Stack_Underflow = 024, /* ucode Stack Underflow */ | |
trap_Privilege_Violation = 025, /* ucode Privileged Mode Violation */ | |
trap_Stack_Overflow = 030, /* ucode Stack Overflow */ | |
trap_User = 031, /* ucode User Trap */ | |
trap_CS_Absent = 037, /* ucode Absent Code Segment */ | |
trap_Trace = 040, /* ucode Trace */ | |
trap_Uncallable = 041, /* ucode STT Entry Uncallable */ | |
trap_DS_Absent = 042, /* ucode Absent Data Segment */ | |
trap_Power_On = 043, /* hdwe Power On */ | |
trap_Cold_Load = 044, /* ucode Cold Load */ | |
trap_System_Halt = 045 /* ucode System Halt */ | |
} TRAP_CLASS; | |
#define trap_Integer_Overflow TO_DWORD (001, trap_User) | |
#define trap_Float_Overflow TO_DWORD (002, trap_User) | |
#define trap_Float_Underflow TO_DWORD (003, trap_User) | |
#define trap_Integer_Zero_Divide TO_DWORD (004, trap_User) | |
#define trap_Float_Zero_Divide TO_DWORD (005, trap_User) | |
#define trap_Ext_Float_Overflow TO_DWORD (010, trap_User) | |
#define trap_Ext_Float_Underflow TO_DWORD (011, trap_User) | |
#define trap_Ext_Float_Zero_Divide TO_DWORD (012, trap_User) | |
#define trap_Decimal_Overflow TO_DWORD (013, trap_User) | |
#define trap_Invalid_ASCII_Digit TO_DWORD (014, trap_User) | |
#define trap_Invalid_Decimal_Digit TO_DWORD (015, trap_User) | |
#define trap_Invalid_Word_Count TO_DWORD (016, trap_User) | |
#define trap_Word_Count_Overflow TO_DWORD (017, trap_User) | |
#define trap_Decimal_Zero_Divide TO_DWORD (020, trap_User) | |
#define trap_SysHalt_STTV_1 TO_DWORD ( 1, trap_System_Halt) | |
#define trap_SysHalt_Absent_ICS TO_DWORD ( 2, trap_System_Halt) | |
#define trap_SysHalt_Absent_1 TO_DWORD ( 3, trap_System_Halt) | |
#define trap_SysHalt_Overflow_ICS TO_DWORD ( 4, trap_System_Halt) | |
#define trap_SysHalt_IO_Timeout TO_DWORD ( 6, trap_System_Halt) | |
#define trap_SysHalt_PSEB_Enabled TO_DWORD ( 9, trap_System_Halt) | |
#define trap_SysHalt_CSTV_1 TO_DWORD (13, trap_System_Halt) | |
#define trap_SysHalt_LOCK_EI TO_DWORD (23, trap_System_Halt) | |
#define trap_SysHalt_Trace_1 TO_DWORD (33, trap_System_Halt) | |
#define PARAM(i) (uint32) UPPER_WORD (i) | |
#define TRAP(i) (TRAP_CLASS) LOWER_WORD (i) | |
#define MICRO_ABORT(t) longjmp (cpu_save_env, (t)) | |
#define MICRO_ABORTP(t,p) longjmp (cpu_save_env, TO_DWORD ((p),(t))) | |
/* Central Data Bus module definitions */ | |
#define MODULE_MEMORY_LOWER 0 /* lower memory MCL address */ | |
#define MODULE_MEMORY_UPPER 2 /* upper memory MCL address */ | |
#define MODULE_MEMORY 3 /* upper bound of MCL addresses */ | |
#define MODULE_PORT_CNTLR 4 /* selector channel port controller address */ | |
#define MODULE_CPU 5 /* CPU MCU address */ | |
#define MODULE_UNDEFINED 6 /* addresses 6-7 are unused */ | |
#define MOP_NOP 0 /* module operation 00 = no operation */ | |
#define MOP_WRITE 1 /* module operation 01 = write */ | |
#define MOP_READ 2 /* module operation 10 = read */ | |
#define MOP_READ_WRITE_ONES 3 /* module operation 11 = read/write ones */ | |
/* Module control register accessors. | |
The module control register, MOD, has this format: | |
0 | 1 2 3 | 4 5 6 | 7 8 9 |10 11 12 |13 14 15 | |
+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+ | |
| 0 0 | MOP | 0 | FROM | 0 0 0 0 | B | A | 0 0 | | |
+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+ | |
Where: | |
MOP = module operation | |
FROM = source module address | |
B = this CPU is CPU #2 | |
A = this CPU is CPU #1 | |
*/ | |
#define MOD_MOP_MASK 0030000u /* MOD register MOP field mask */ | |
#define MOD_FROM_MASK 0003400u /* MOD register FROM field mask */ | |
#define MOD_CPU_2 0000010u /* CPU number 2 MCU */ | |
#define MOD_CPU_1 0000004u /* CPU number 1 MCU */ | |
#define MOD_MOP_SHIFT 12 /* MOD register MOP field alignment shift */ | |
#define MOD_FROM_SHIFT 8 /* MOD register FROM field alignment shift */ | |
#define TO_MOD_MOP(v) ((v) << MOD_MOP_SHIFT & MOD_MOP_MASK) | |
#define TO_MOD_FROM(v) ((v) << MOD_FROM_SHIFT & MOD_FROM_MASK) | |
/* Status register accessors. | |
The CPU status register, STA, has this format: | |
0 | 1 2 3 | 4 5 6 | 7 8 9 |10 11 12 |13 14 15 | |
+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+ | |
| M | I | T | R | O | C | ccode | current code segment number | | |
+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+ | |
Where: | |
M = user mode/protected mode (0/1) | |
I = external interrupts are enabled | |
T = user traps are enabled | |
R = right-hand stack operation executes next | |
O = arithmetic overflow has occurred | |
C = arithmetic carry has occurred | |
Condition Code: | |
00 = CCL (less than) | |
01 = CCE (equal to) | |
10 = CCG (greater than) | |
11 = invalid | |
*/ | |
#define STATUS_M 0100000u /* mode flag */ | |
#define STATUS_I 0040000u /* interrupt flag */ | |
#define STATUS_T 0020000u /* trap flag */ | |
#define STATUS_R 0010000u /* right-hand stack op flag */ | |
#define STATUS_O 0004000u /* overflow flag */ | |
#define STATUS_C 0002000u /* carry flag */ | |
#define STATUS_CCG 0000000u /* condition code greater than */ | |
#define STATUS_CCL 0000400u /* condition code less than */ | |
#define STATUS_CCE 0001000u /* condition code equal to */ | |
#define STATUS_CC_MASK 0001400u /* condition code mask */ | |
#define STATUS_CC_SHIFT 8 /* condition code alignment */ | |
#define STATUS_CS_MASK 0000377u /* code segment mask */ | |
#define STATUS_CS_WIDTH 8 /* code segment mask width */ | |
#define STATUS_OVTRAP (STATUS_T | STATUS_O) | |
#define STATUS_NPRV (STATUS_T | STATUS_O | STATUS_C | STATUS_CC_MASK) | |
#define TO_CCN(s) (((s) & STATUS_CC_MASK) >> STATUS_CC_SHIFT) | |
/* Status register mode tests */ | |
#define PRIV (STA & STATUS_M) /* current mode is privileged */ | |
#define NPRV (!PRIV) /* current mode is non-privileged */ | |
/* Condition code flags. | |
Several instructions define "condition code flags" that specify condition | |
code tests to be performed. These flags are ANDed with the condition code | |
from the status register to establish whether the test passes. CCE and CCL | |
are encoded in the status register by bits 6 and 7, respectively, but CCG is | |
encoded as 00, causing a direct AND to fail. This is resolved in microcode | |
by the "CC" S-bus micro-order, which copies bits 6 and 7 to bits 8 and 9 of | |
the S-bus register and also sets bit 7 if bits 8 and 9 are zero (CCG). The | |
result is a single bit set for each condition code that may be ANDed with the | |
CCF field of the instruction. | |
The MVBW (Move Bytes While) instruction moves bytes from the source to the | |
destination while the bytes are alphabetic, numeric, or either, depending on | |
the A and N bits in the instruction. The CCB classification table is used to | |
determine the type of each byte moved. If both A and N bits are set, then a | |
table entry of either CCG or CCE will succeed. Matching via a single AND | |
operation is possible only if the encoding of all three conditions is | |
disjoint. | |
We implement this scheme without the two-bit right-shift, so that ANDing a | |
CCF with STATUS_CC_MASK will produce the correctly aligned status register | |
value. The TO_CCF macro converts the current condition code in the status | |
register to a condition code flag. | |
*/ | |
#define CFL 0000400u /* condition code flag less than */ | |
#define CFE 0001000u /* condition code flag equal to */ | |
#define CFG 0002000u /* condition code flag greater than */ | |
#define TO_CCF(s) ((s) & STATUS_CC_MASK ? (s) & STATUS_CC_MASK : CFG) | |
/* Condition code patterns. | |
Machine instructions typically set the condition code field of the status | |
register to reflect the values of their operands, which may be on the top of | |
the stack, in the X register, or in memory. Each instruction that affects | |
the condition code field commonly uses one of the following patterns to set | |
the field: | |
CCA (arithmetic) sets CC to: | |
- CCG (00) if the operand is > 0 | |
- CCL (01) if the operand is < 0 | |
- CCE (10) if the operand is = 0 | |
CCB (byte) sets CC to: | |
- CCG (00) if the operand is numeric (byte value is 060-071) | |
- CCL (01) if the operand is any other character | |
- CCE (10) if the operand is alphabetic (0101-0132 or 0141-0172) | |
CCC (comparison) sets CC to: | |
- CCG (00) if operand 1 is > operand 2 | |
- CCL (01) if operand 1 is < operand 2 | |
- CCE (10) if operand 1 is = operand 2 | |
CCD (direct I/O) sets CC to: | |
- CCG (00) if the device is not ready | |
- CCL (01) if the device controller is not responding | |
- CCE (10) if the device is ready and controller is responding | |
The operand(s) may be a byte, word, double word, triple word, or quadruple | |
word, and may be signed (integer) or unsigned (logical). | |
Statement macros are provided to set the condition code explicitly, as well | |
as to set the code using patterns CCA, CCB, or CCC. The CCA macro takes two | |
parameters: an upper word and a lower word. The CCB macro takes a single | |
byte parameter. The CCC macro takes four parameters: an upper and lower word | |
for each of the two operands. | |
No macro is provided for pattern CCD, as that pattern reflects the | |
operational status of the target device and interface, rather than the | |
condition of an operand. The I/O instructions use the explicit macros to set | |
the codes for pattern D. | |
*/ | |
#define SET_CCG STA = STA & ~STATUS_CC_MASK | STATUS_CCG | |
#define SET_CCL STA = STA & ~STATUS_CC_MASK | STATUS_CCL | |
#define SET_CCE STA = STA & ~STATUS_CC_MASK | STATUS_CCE | |
/* Condition code pattern CCA (arithmetic). | |
Semantics: | |
if operand > 0 | |
then CCG | |
else if operand < 0 | |
then CCL | |
else | |
CCE | |
Macro: | |
SET_CCA (upper, lower) | |
Implementation: | |
if upper = 0 or lower = 0 | |
then CCE | |
else if upper.sign = 1 | |
then CCL | |
else CCG | |
Usage: | |
SET_CCA (RA, 0) -- a 16-bit integer value | |
SET_CCA (0, RA) -- a 16-bit logical value | |
SET_CCA (RB, RA) -- a 32-bit integer value | |
SET_CCA (0, RB | RA) -- a 32-bit logical value | |
SET_CCA (RC, RB | RA) -- a 48-bit integer value | |
SET_CCA (RD, RC | RB | RA) -- a 64-bit integer value | |
Implementation notes: | |
1. When either "upper" or "lower" is 0, the corresponding test is optimized | |
away. | |
*/ | |
#define SET_CCA(u,l) STA = STA & ~STATUS_CC_MASK | \ | |
(((u) | (l)) == 0 \ | |
? STATUS_CCE \ | |
: (u) & D16_SIGN \ | |
? STATUS_CCL \ | |
: STATUS_CCG) | |
/* Condition code pattern CCB (byte). | |
Semantics: | |
if operand in 060 .. 071 | |
then CCG | |
else if operand in 0101 .. 0132 or operand in 0141 .. 0172 | |
then CCE | |
else | |
CCL | |
Macro: | |
SET_CCB (byte) | |
Implementation: | |
CCx = ccb_lookup_table [byte] | |
Usage: | |
SET_CCB (RA) | |
Implementation notes: | |
1. The byte parameter is not masked before being used as an array index, so | |
the caller must ensure that the value is between 0 and 255. | |
2. The table value must be masked if it is to be stored in the status | |
register because CCG is returned as 100 (base 2) to ensure that all | |
values are disjoint for the MVBW and Bcc instructions. | |
*/ | |
#define SET_CCB(b) STA = STA & ~STATUS_CC_MASK | \ | |
cpu_ccb_table [(b)] & STATUS_CC_MASK | |
/* Condition code pattern CCC (conditional). | |
Semantics: | |
if operand_1 > operand_2 | |
then CCG | |
else if operand_1 < operand_2 | |
then CCL | |
else | |
CCE | |
Macro: | |
SET_CCC (upper_1, lower_1, upper_2, lower_2) | |
Implementation: | |
if upper_1 = upper_2 | |
then | |
if lower_1 = lower_2 | |
then CCE | |
else if lower_1 < lower_2 | |
then CCL | |
else CCG | |
else if |upper_1| < |upper_2| | |
then CCL | |
else CCG | |
Usage: | |
SET_CCC (RA, 0, RB, 0) -- 16-bit integer comparison | |
SET_CCC ( 0, RA, 0, RB) -- 16-bit logical comparison | |
SET_CCC (RB, RA, RD, RC) -- 32-bit integer comparison | |
Implementation notes: | |
1. When any of the parameters are 0, the corresponding tests are optimized | |
away. | |
2. Complementing the signs of the upper words allows an unsigned comparison | |
to substitute for a signed comparison. | |
*/ | |
#define SET_CCC(u1,l1,u2,l2) STA = STA & ~STATUS_CC_MASK | \ | |
((u1) == (u2) \ | |
? ((l1) == (l2) \ | |
? STATUS_CCE \ | |
: ((l1) < (l2) \ | |
? STATUS_CCL \ | |
: STATUS_CCG)) \ | |
: (((u1) ^ D16_SIGN) < ((u2) ^ D16_SIGN) \ | |
? STATUS_CCL \ | |
: STATUS_CCG)) | |
/* Set carry and overflow. | |
These macros are used by arithmetic operations to set the carry and overflow | |
bits in the status register. In addition to setting the overflow bit, if | |
user traps are enabled, the Integer Overflow bit in the CPX1 register is set, | |
which will cause an interrupt | |
*/ | |
#define SET_CARRY(b) STA = ((b) ? STA | STATUS_C : STA & ~STATUS_C) | |
#define SET_OVERFLOW(b) if (b) { \ | |
STA |= STATUS_O; \ | |
if (STA & STATUS_T) \ | |
CPX1 |= cpx1_INTOVFL; \ | |
} \ | |
else \ | |
STA &= ~STATUS_O | |
/* SR preadjust. | |
The PREADJUST_SR macro is called to ensure that the correct number of TOS | |
registers are valid prior to instruction execution. | |
*/ | |
#define PREADJUST_SR(n) if (SR < (n)) \ | |
cpu_adjust_sr (n) | |
/* Machine instruction bit-field accessors */ | |
#define BITS_0_3_MASK 0170000u /* bits 0-3 mask */ | |
#define BITS_0_3_SHIFT 12 /* bits 0-3 alignment shift */ | |
#define BITS_0_3(v) (((v) & BITS_0_3_MASK) >> BITS_0_3_SHIFT) | |
#define BITS_4_5_MASK 0006000u /* bits 4-5 mask */ | |
#define BITS_4_5_SHIFT 10 /* bits 4-5 alignment shift */ | |
#define BITS_4_5(v) (((v) & BITS_4_5_MASK) >> BITS_4_5_SHIFT) | |
#define BITS_4_7_MASK 0007400u /* bits 4-7 mask */ | |
#define BITS_4_7_SHIFT 8 /* bits 4-7 alignment shift */ | |
#define BITS_4_7(v) (((v) & BITS_4_7_MASK) >> BITS_4_7_SHIFT) | |
#define BITS_4_9_MASK 0007700u /* bits 4-9 mask */ | |
#define BITS_4_9_SHIFT 6 /* bits 4-9 alignment shift */ | |
#define BITS_4_9(v) (((v) & BITS_4_9_MASK) >> BITS_4_9_SHIFT) | |
#define BITS_5_9_MASK 0003700u /* bits 5-9 mask */ | |
#define BITS_5_9_SHIFT 6 /* bits 5-9 alignment shift */ | |
#define BITS_5_9(v) (((v) & BITS_5_9_MASK) >> BITS_5_9_SHIFT) | |
#define BITS_8_11_MASK 0000360u /* bits 8-11 mask */ | |
#define BITS_8_11_SHIFT 4 /* bits 8-11 alignment shift */ | |
#define BITS_8_11(v) (((v) & BITS_8_11_MASK) >> BITS_8_11_SHIFT) | |
#define BITS_8_12_MASK 0000370u /* bits 8-12 mask */ | |
#define BITS_8_12_SHIFT 3 /* bits 8-12 alignment shift */ | |
#define BITS_8_12(v) (((v) & BITS_8_12_MASK) >> BITS_8_12_SHIFT) | |
#define BITS_10_15_MASK 0000077u /* bits 10-15 mask */ | |
#define BITS_10_15_SHIFT 0 /* bits 10-15 alignment shift */ | |
#define BITS_10_15(v) (((v) & BITS_10_15_MASK) >> BITS_10_15_SHIFT) | |
#define BITS_12_15_MASK 0000017u /* bits 12-15 mask */ | |
#define BITS_12_15_SHIFT 0 /* bits 12-15 alignment shift */ | |
#define BITS_12_15(v) (((v) & BITS_12_15_MASK) >> BITS_12_15_SHIFT) | |
/* Instruction-class accessors */ | |
#define SUBOP_MASK BITS_0_3_MASK /* subopcode mask */ | |
#define SUBOP_SHIFT BITS_0_3_SHIFT /* subopcode alignment shift */ | |
#define SUBOP(v) BITS_0_3(v) /* subopcode accessor */ | |
#define STACKOP_A_MASK BITS_4_9_MASK /* stack operation A mask */ | |
#define STACKOP_A_SHIFT BITS_4_9_SHIFT /* stack operation A alignment shift */ | |
#define STACKOP_A(v) BITS_4_9(v) /* stack operation A accessor */ | |
#define STACKOP_B_MASK BITS_10_15_MASK /* stack operation B mask */ | |
#define STACKOP_B_SHIFT BITS_10_15_SHIFT /* stack operation B alignment shift */ | |
#define STACKOP_B(v) BITS_10_15(v) /* stack operation B accessor */ | |
#define SBBOP_MASK BITS_5_9_MASK /* shift/branch/bit operation mask */ | |
#define SBBOP_SHIFT BITS_5_9_SHIFT /* shift/branch/bit operation alignment shift */ | |
#define SBBOP(v) BITS_5_9(v) /* shift/branch/bit operation accessor */ | |
#define MSFIFROP_MASK BITS_4_7_MASK /* move/special/firmware/immediate/field/register operation mask */ | |
#define MSFIFROP_SHIFT BITS_4_7_SHIFT /* move/special/firmware/immediate/field/register operation alignment shift */ | |
#define MSFIFROP(v) BITS_4_7(v) /* move/special/firmware/immediate/field/register operation accessor */ | |
#define MSSUBOP_MASK BITS_8_12_MASK /* move/special suboperation mask */ | |
#define MSSUBOP_SHIFT BITS_8_12_SHIFT /* move/special suboperation alignment shift */ | |
#define MSSUBOP(v) BITS_8_12(v) /* move/special suboperation accessor */ | |
#define SPECOP_MASK BITS_12_15_MASK /* special operation mask */ | |
#define SPECOP_SHIFT BITS_12_15_SHIFT /* special operation alignment shift */ | |
#define SPECOP(v) BITS_12_15(v) /* special operation accessor */ | |
#define IOCPIMOP_MASK BITS_4_7_MASK /* I-O/control/program/immediate/memory operation mask */ | |
#define IOCPIMOP_SHIFT BITS_4_7_SHIFT /* I-O/control/program/immediate/memory operation alignment shift */ | |
#define IOCPIMOP(v) BITS_4_7(v) /* I-O/control/program/immediate/memory operation accessor */ | |
#define IOCSUBOP_MASK BITS_8_11_MASK /* I-O/control suboperation mask */ | |
#define IOCSUBOP_SHIFT BITS_8_11_SHIFT /* I-O/control suboperation alignment shift */ | |
#define IOCSUBOP(v) BITS_8_11(v) /* I-O/control suboperation accessor */ | |
#define CNTLOP_MASK BITS_12_15_MASK /* control operation mask */ | |
#define CNTLOP_SHIFT BITS_12_15_SHIFT /* control operation alignment shift */ | |
#define CNTLOP(v) BITS_12_15(v) /* control operation accessor */ | |
#define MLBOP_MASK BITS_0_3_MASK /* memory/loop/branch operation mask */ | |
#define MLBOP_SHIFT BITS_0_3_SHIFT /* memory/loop/branch operation alignment shift */ | |
#define MLBOP(v) BITS_0_3(v) /* memory/loop/branch operation accessor */ | |
#define FIRMEXTOP_MASK BITS_8_11_MASK /* firmware extension operation mask */ | |
#define FIRMEXTOP_SHIFT BITS_8_11_SHIFT /* firmware extension operation alignment shift */ | |
#define FIRMEXTOP(v) BITS_8_11(v) /* firmware extension operation accessor */ | |
#define FMEXSUBOP_MASK BITS_12_15_MASK /* firmware extension suboperation mask */ | |
#define FMEXSUBOP_SHIFT BITS_12_15_SHIFT /* firmware extension suboperation alignment shift */ | |
#define FMEXSUBOP(v) BITS_12_15(v) /* firmware extension suboperation accessor */ | |
/* Specific instruction accessors */ | |
#define IOOP_K_MASK 0000017u /* I/O K-field mask */ | |
#define IOOP_K_SHIFT 0000000u /* I/O K-field alignment shift */ | |
#define IO_K(v) (((v) & IOOP_K_MASK) >> IOOP_K_SHIFT) | |
#define X_FLAG 0004000u /* index flag in bit 4 */ | |
#define I_FLAG_BIT_4 0004000u /* indirect flag in bit 4 */ | |
#define I_FLAG_BIT_5 0002000u /* indirect flag in bit 5 */ | |
#define M_FLAG 0001000u /* memory subop flag in bit 6 */ | |
#define START_BIT_MASK 0000360u /* start bit mask for bit field instructions */ | |
#define START_BIT_SHIFT 4 /* start bit alignment shift */ | |
#define START_BIT(v) (((v) & START_BIT_MASK) >> START_BIT_SHIFT) | |
#define BIT_COUNT_MASK 0000017u /* bit count mask for bit field instructions */ | |
#define BIT_COUNT_SHIFT 0 /* bit count alignment shift */ | |
#define BIT_COUNT(v) (((v) & BIT_COUNT_MASK) >> BIT_COUNT_SHIFT) | |
#define BIT_POSITION_MASK 0000077u /* bit position mask for bit test instructions */ | |
#define BIT_POSITION_SHIFT 0 /* bit position alignment shift */ | |
#define BIT_POSITION(v) (((v) & BIT_POSITION_MASK) >> BIT_POSITION_SHIFT) | |
#define SHIFT_COUNT_MASK 0000077u /* shift count mask for shift instructions */ | |
#define SHIFT_COUNT_SHIFT 0 /* shift count alignment shift */ | |
#define SHIFT_COUNT(v) (((v) & SHIFT_COUNT_MASK) >> SHIFT_COUNT_SHIFT) | |
#define SHIFT_RIGHT_FLAG 0000100u /* shift instructions left/right (0/1) flag */ | |
#define MODE_DISP_MASK 0001777u /* memory-reference mode and displacement mask */ | |
#define MODE_MASK 0001700u /* memory-reference mode mask */ | |
#define MODE_SHIFT 6 /* memory-reference mode alignment shift */ | |
#define DISPL_31_SIGN 0000040u /* sign bit for 0-31 displacements */ | |
#define DISPL_255_SIGN 0000400u /* sign bit for 0-255 displacements */ | |
#define DISPL_31_MASK 0000037u /* mask for 0-31 displacements */ | |
#define DISPL_63_MASK 0000077u /* mask for 0-63 displacements */ | |
#define DISPL_127_MASK 0000177u /* mask for 0-127 displacements */ | |
#define DISPL_255_MASK 0000377u /* mask for 0-255 displacements */ | |
#define DISPL_P_FLAG 0001000u /* P-relative displacement flag */ | |
#define DISPL_DB_FLAG 0000400u /* DB-relative displacement flag */ | |
#define DISPL_QPOS_FLAG 0000200u /* positive Q-relative displacement flag */ | |
#define DISPL_QNEG_FLAG 0000100u /* negative Q-relative displacement flag */ | |
#define IMMED_MASK 0000377u /* mask for immediate values */ | |
#define SDEC2_MASK 0000003u /* two-bit S-decrement mask for move instructions */ | |
#define SDEC3_MASK 0000007u /* three-bit S-decrement mask for move instructions */ | |
#define SDEC_SHIFT 0 /* S-decrement alignment shift */ | |
#define SDEC2(v) (((v) & SDEC2_MASK) >> SDEC_SHIFT) | |
#define SDEC3(v) (((v) & SDEC3_MASK) >> SDEC_SHIFT) | |
#define DB_FLAG 0000020u /* PB/DB base flag */ | |
#define MVBW_CCF 0000030u /* MVBW condition code flags */ | |
#define MVBW_N_FLAG 0000020u /* MVBW numeric flag */ | |
#define MVBW_A_FLAG 0000010u /* MVBW alphabetic flag */ | |
#define MVBW_S_FLAG 0000004u /* MVBW upshift flag */ | |
#define MVBW_CCF_SHIFT 6 /* CCF alignment in MVBW instruction */ | |
#define NABS_FLAG 0000100u /* CVDA negative absolute value flag */ | |
#define ABS_FLAG 0000040u /* CVDA absolute value flag */ | |
#define EIS_SDEC_SHIFT 4 /* EIS S-decrement alignment shift */ | |
/* Explicit instruction opcodes and accessors */ | |
#define NOP 0000000u /* no operation */ | |
#define QASR 0015700u /* quadruple arithmetic right shift */ | |
#define DMUL 0020570u /* double integer multiply */ | |
#define DDIV 0020571u /* double integer divide */ | |
#define SED_1 0030041u /* set enable interrupt */ | |
#define HALT_10 0030370u /* halt 10 */ | |
#define MTFDS_MASK 0177730u /* move to/from data segment mask */ | |
#define MTFDS 0020130u /* move to/from data segment */ | |
#define EXIT_MASK 0177400u /* exit procedure mask */ | |
#define EXIT 0031400u /* exit procedure */ | |
#define PAUS_MASK 0177760u /* pause mask */ | |
#define PAUS 0030020u /* pause */ | |
#define BR_MASK 0173000u /* conditional and unconditional branch mask */ | |
#define BR_DBQS_I 0143000u /* branch unconditionally DB/Q/S-relative indirect */ | |
#define BCC 0141000u /* branch conditionally */ | |
#define BCC_CCF_SHIFT 2 /* CCF alignment in BCC instruction */ | |
#define LSDX_MASK 0175000u /* load/store double-word indexed mask */ | |
#define LDD_X 0155000u /* load double-word indexed */ | |
#define STD_X 0165000u /* store double-word indexed */ | |
#define TBR_MASK 0177000u /* test and branch mask */ | |
#define TBA 0050000u /* test and branch, limit in A */ | |
#define MTBA 0052000u /* modify, test and branch, limit in A */ | |
#define TBX 0054000u /* test and branch, limit in X */ | |
#define MTBX 0056000u /* modify, test and branch, limit in X */ | |
#define CMD_TO_MASK 0000007u /* CMD command word TO field mask */ | |
#define CMD_MOP_MASK 0000060u /* CMD command word MOP field mask */ | |
#define CMD_TO_SHIFT 0 /* CMD command word TO field alignment shift */ | |
#define CMD_MOP_SHIFT 4 /* CMD command word MOP field alignment shift */ | |
#define CMD_TO(v) (((v) & CMD_TO_MASK) >> CMD_TO_SHIFT) | |
#define CMD_MOP(v) (((v) & CMD_MOP_MASK) >> CMD_MOP_SHIFT) | |
/* PSHR/SETR instruction accessors */ | |
#define PSR_RL_MASK 0000001u /* PSHR/SETR register right-to-left mask */ | |
#define PSR_LR_MASK 0000200u /* PSHR/SETR register left-to-right mask */ | |
#define PSR_SBANK 0000200u /* Stack bank register */ | |
#define PSR_DB_DBANK 0000100u /* Data base and data bank registers */ | |
#define PSR_DL 0000040u /* Data limit register */ | |
#define PSR_Z 0000020u /* Stack limit register */ | |
#define PSR_STA 0000010u /* Status register */ | |
#define PSR_X 0000004u /* Index register */ | |
#define PSR_Q 0000002u /* Frame pointer */ | |
#define PSR_S 0000001u /* Stack pointer */ | |
#define PSR_PRIV (PSR_SBANK | PSR_DB_DBANK | PSR_DL | PSR_Z) | |
/* PCN instruction result values */ | |
#define PCN_SERIES_II 1 /* CPU number for the Series II */ | |
#define PCN_SERIES_III 2 /* CPU number for the Series III */ | |
/* Reserved memory addresses */ | |
#define CSTB_POINTER 0000000u /* code segment table base pointer */ | |
#define CSTX_POINTER 0000001u /* code segment table extension pointer */ | |
#define DST_POINTER 0000002u /* data segment table pointer */ | |
#define ICS_Q 0000005u /* interrupt control stack marker pointer (QI) */ | |
#define ICS_Z 0000006u /* interrupt control stack limit (ZI) */ | |
#define INTERRUPT_MASK 0000007u /* interrupt mask */ | |
#define SGT_POINTER 0001000u /* system global tables pointer */ | |
/* Code Segment Table accessors */ | |
#define CST_A_BIT 0100000u /* code segment is absent */ | |
#define CST_M_BIT 0040000u /* code segment is privileged */ | |
#define CST_R_BIT 0020000u /* code segment has been referenced flag */ | |
#define CST_T_BIT 0010000u /* code segment is to be traced */ | |
#define CST_SEGLEN_MASK 0007777u /* code segment length mask */ | |
#define CST_BANK_MASK 0000017u /* code segment bank mask */ | |
#define CST_RESERVED 0000300u /* number of CST entries reserved for the system */ | |
/* Data Segment Table accessors */ | |
#define DST_A_BIT 0100000u /* data segment is absent */ | |
#define DST_C_BIT 0040000u /* data segment is clean (not modified) */ | |
#define DST_R_BIT 0020000u /* data segment has been referenced */ | |
#define DST_SEGLEN_MASK 0017777u /* data segment length mask */ | |
#define DST_BANK_MASK 0000017u /* data segment bank mask */ | |
/* Segment Transfer Table accessors */ | |
#define STT_LENGTH_MASK 0000377u /* STT length mask */ | |
#define STT_LENGTH_SHIFT 0 /* STT length alignment shift */ | |
#define STT_LENGTH(l) (((l) & STT_LENGTH_MASK) >> STT_LENGTH_SHIFT) | |
/* Program label accessors */ | |
#define LABEL_EXTERNAL 0100000u /* external program label flag */ | |
#define LABEL_STTN_MASK 0077400u /* external program label STT number mask */ | |
#define LABEL_SEGMENT_MASK 0000377u /* external program label segment mask */ | |
#define LABEL_STTN_SHIFT 8 /* STT number alignment shift */ | |
#define LABEL_SEGMENT_SHIFT 0 /* segment number alignment shift */ | |
#define LABEL_UNCALLABLE 0040000u /* local program label uncallable flag */ | |
#define LABEL_ADDRESS_MASK 0037777u /* local program label address mask */ | |
#define STT_NUMBER(l) (((l) & LABEL_STTN_MASK) >> LABEL_STTN_SHIFT) | |
#define STT_SEGMENT(l) (((l) & LABEL_SEGMENT_MASK) >> LABEL_SEGMENT_SHIFT) | |
#define ISR_SEGMENT 1 /* segment number containing interrupt service routines */ | |
#define LABEL_IRQ (LABEL_EXTERNAL | ISR_SEGMENT) /* label for interrupt requests */ | |
#define LABEL_STTN_MAX (LABEL_STTN_MASK >> LABEL_STTN_SHIFT) /* STT number maximum value */ | |
#define TO_LABEL(s,n) ((s) | (n) << LABEL_STTN_SHIFT) | |
/* Stack marker accessors */ | |
#define STMK_D 0100000u /* dispatcher flag */ | |
#define STMK_T 0100000u /* trace flag */ | |
#define STMK_M 0040000u /* mapped flag */ | |
#define STMK_RTN_ADDR 0037777u /* PB-relative return address */ | |
/* CPU registers */ | |
extern HP_WORD CIR; /* Current Instruction Register */ | |
extern HP_WORD NIR; /* Next Instruction Register */ | |
extern HP_WORD PB; /* Program Base Register */ | |
extern HP_WORD P; /* Program Counter */ | |
extern HP_WORD PL; /* Program Limit Register */ | |
extern HP_WORD PBANK; /* Program Segment Bank Register */ | |
extern HP_WORD DL; /* Data Limit Register */ | |
extern HP_WORD DB; /* Data Base Register */ | |
extern HP_WORD DBANK; /* Data Segment Bank Register */ | |
extern HP_WORD Q; /* Stack Marker Register */ | |
extern HP_WORD SM; /* Stack Memory Register */ | |
extern HP_WORD SR; /* Stack Register Counter */ | |
extern HP_WORD Z; /* Stack Limit Register */ | |
extern HP_WORD SBANK; /* Stack Segment Bank Register */ | |
extern HP_WORD TR [4]; /* Top of Stack Registers */ | |
extern HP_WORD X; /* Index Register */ | |
extern HP_WORD STA; /* Status Register */ | |
extern HP_WORD SWCH; /* Switch Register */ | |
extern HP_WORD CPX1; /* Run-Mode Interrupt Flags Register */ | |
extern HP_WORD CPX2; /* Halt-Mode Interrupt Flags Register */ | |
extern HP_WORD MOD; /* Module Control Register */ | |
extern HP_WORD PCLK; /* Process Clock Register */ | |
extern HP_WORD CNTR; /* Microcode Counter */ | |
/* Top of stack register names */ | |
#define RA TR [0] | |
#define RB TR [1] | |
#define RC TR [2] | |
#define RD TR [3] | |
/* CPU state */ | |
extern jmp_buf cpu_save_env; /* saved environment for microcode aborts */ | |
extern POWER_STATE cpu_power_state; /* power supply state */ | |
extern EXEC_STATE cpu_micro_state; /* micromachine execution state */ | |
extern uint32 cpu_stop_flags; /* set of simulation stop flags */ | |
extern t_bool cpu_base_changed; /* TRUE if any base register has been changed */ | |
extern UNIT cpu_unit []; /* CPU unit array (needed for memory size) */ | |
/* Condition Code B mapping table */ | |
extern const HP_WORD cpu_ccb_table [256]; /* byte-value to condition-code map */ | |
/* Global CPU functions */ | |
extern void cpu_push (void); | |
extern void cpu_pop (void); | |
extern void cpu_queue_up (void); | |
extern void cpu_queue_down (void); | |
extern void cpu_flush (void); | |
extern void cpu_adjust_sr (uint32 target); | |
extern void cpu_mark_stack (void); | |
extern void cpu_ea (HP_WORD mode_disp, ACCESS_CLASS *classification, HP_WORD *offset, BYTE_SELECTOR *selector); | |
extern void cpu_setup_irq_handler (IRQ_CLASS class, HP_WORD parameter); | |
extern void cpu_setup_ics_irq (IRQ_CLASS class, TRAP_CLASS trap); | |
extern void cpu_run_mode_interrupt (HP_WORD device_number); | |
extern void cpu_setup_code_segment (HP_WORD label, HP_WORD* status, HP_WORD *entry_0); | |
extern void cpu_setup_data_segment (HP_WORD segment_number, HP_WORD *bank, HP_WORD *address); | |
extern void cpu_call_procedure (HP_WORD label); | |
extern void cpu_exit_procedure (HP_WORD new_q, HP_WORD new_sm, HP_WORD parameter); | |
extern void cpu_start_dispatcher (void); | |
extern void cpu_update_pclk (void); | |
/* Global CPU instruction execution routines */ | |
extern t_stat cpu_branch_short (t_bool check_loop); | |
extern HP_WORD cpu_add_16 (HP_WORD augend, HP_WORD addend); | |
extern HP_WORD cpu_sub_16 (HP_WORD minuend, HP_WORD subtrahend); | |
extern HP_WORD cpu_mpy_16 (HP_WORD multiplicand, HP_WORD multiplier); | |
extern t_stat cpu_stack_op (void); | |
extern t_stat cpu_shift_branch_bit_op (void); | |
extern t_stat cpu_move_spec_fw_imm_field_reg_op (void); | |
extern t_stat cpu_io_cntl_prog_imm_mem_op (void); |