/* hp_disclib.c: HP MAC/ICD disc controller simulator library | |
Copyright (c) 2011-2012, J. David Bryan | |
Copyright (c) 2004-2011, Robert M. Supnik | |
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 AUTHORS 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 names of the authors shall not be | |
used in advertising or otherwise to promote the sale, use or other dealings | |
in this Software without prior written authorization from the authors. | |
07-May-12 JDB Corrected end-of-track delay time logic | |
02-May-12 JDB First release | |
09-Nov-11 JDB Created disc controller common library from DS simulator | |
References: | |
- 13037 Disc Controller Technical Information Package (13037-90902, Aug-1980) | |
- HP 13365 Integrated Controller Programming Guide (13365-90901, Feb-1980) | |
- HP 1000 ICD/MAC Disc Diagnostic Reference Manual (5955-4355, Jun-1984) | |
- RTE-IVB System Manager's Manual (92068-90006, Jan-1983) | |
- DVR32 RTE Moving Head Driver source (92084-18711, Revision 5000) | |
This library provides common functions required by HP disc controllers. It | |
implements the 13037 MAC and 13365 ICD controller command sets used with the | |
7905/06/20/25 and 7906H/20H/25H disc drives. | |
The library is an adaptation of the code originally written by Bob Supnik | |
for the DS simulator. DS simulates a 13037 controller connected via a 13175 | |
disc interface to an HP 1000 computer. To create the library, the functions | |
of the controller were separated from the functions of the interface. This | |
allows the library to work with other CPU interfaces, such as the 12821A | |
HP-IB disc interface, that use substantially different communication | |
protocols. The library functions implement the controller command set for | |
the drive units. The interface functions handle the transfer of commands and | |
data to and from the CPU. | |
As a result of this separation, the library does not handle the data transfer | |
between the controller and the interface directly. Instead, data is moved | |
between the interface and a sector buffer by the interface simulator, and | |
then the buffer is passed to the disc library for reading or writing. This | |
buffer is also used to pass disc commands and parameters to the controller, | |
and to receive status information from the controller. Only one buffer is | |
needed per interface, regardless of the number of controllers or units | |
handled, as a single interface cannot perform data transfers concurrently | |
with controller commands. | |
The library provides routines to prepare, start, and end commands, service | |
units, and poll drives for Attention status. In addition, routines are | |
provided to attach and detach disc images from drive units, load and unload | |
disc heads, classify commands, and provide opcode and phase name strings for | |
debugging. | |
Autosizing is supported when attaching a disc image. If enabled, the model | |
of the drive is set to match the disc image size. For example, if a 50 MB | |
disc image is attached to a unit set for autosizing, the unit's model will be | |
set to a 7920(H). | |
The interface simulator declares a structure that contains the state | |
variables for a controller. A MAC controller may handle multiple disc units. | |
An ICD controller handles only a single disc unit, but multiple controllers | |
may be employed to support several drives on a given interface. The type of | |
the controller (MAC or ICD) is contained in the structure, which is passed to | |
the disc library routines. The minor differences in controller action | |
between the two are handled internally. A macro (CNTLR_INIT) is provided to | |
initialize the structure. | |
The interface simulator also declares the sector buffer. The buffer is an | |
array containing DL_BUFSIZE 16-bit elements. The address of the buffer is | |
stored in the controller state structure. The controller maintains the | |
current index into the buffer, as well as the length of valid data stored | |
there. Other than setting the length when the controller places data into | |
the buffer and resetting the index at the start of a sector read or write, | |
the interface simulator is free to manipulate these values as desired. | |
In general, a user of the library is free to read any of the controller state | |
variable structure fields. Writing to the fields generally will interfere | |
with controller operations, with these exceptions: | |
Field Name Description | |
=========== ============================ | |
status controller status | |
eod end of data flag | |
index data buffer index | |
length data buffer length | |
seek_time per-cylinder seek delay time | |
sector_time intersector delay time | |
cmd_time command response time | |
data_time data transfer response time | |
wait_time command wait time | |
In hardware, the controller executes in three basic states: | |
1. In the Poll Loop, which looks for commands and drive attention requests. | |
In each pass of the loop, the next CPU interface in turn is checked for a | |
command; if present, it is executed. If none are pending, all drives are | |
checked in turn until one is found with Attention status; if none are | |
found, the loop continues. If a drive is requesting attention, the | |
associated CPU interface is connected to check for a command; if present, | |
it is executed. If not, and the interface allows interrupts, an | |
interrupt request is made and the Command Wait Loop is entered. If | |
interrupts are not allowed, the Poll Loop continues. | |
2. In the Command Wait Loop, which looks for commands. | |
In each pass of the loop, the current CPU interface is checked for a | |
command; if present, it is executed. If not, the Command Wait Loop | |
continues. While in the loop, a 1.8 second timer is running. If it | |
expires before a command is received, the file mask is reset, and the | |
Poll Loop is entered. | |
3. In command execution, which processes the current command. | |
During command execution, the waits for input parameters, seek | |
completion, data transfers, and output status words are handled | |
internally. Each wait is governed by the 1.8 second timer; if it | |
expires, the command is aborted. | |
In simulation, these states are represented by the values cntlr_idle, | |
cntlr_wait, and cntlr_busy, respectively. | |
A MAC controller operates from one to eight drives, represented by an array | |
of one to eight units. When operating multiple units, a pointer to the first | |
unit of a contiguous array is passed, and the unit number present in the | |
command is used to index to the target unit. | |
A MAC controller emulation also requires an array of two contiguous auxiliary | |
units containing a controller unit and a command wait timeout unit. Commands | |
that do not access the drive, such as Address Record, are scheduled on the | |
controller unit to allow controller commands to execute while drive units are | |
seeking. The command wait timer limits the amount of time the controller | |
will wait for the interface to supply a command or parameter. A pointer to | |
the auxiliary unit array is set up during controller state variable | |
initialization. The auxiliary array may be separate or an extension of the | |
drive unit array. | |
An ICD controller manages a single unit corresponding to the drive in which | |
the controller is integrated. An interface declares a unit array | |
corresponding to the number of drives supported and passes the unit number to | |
use to the command preparation and start routines. Auxiliary units are not | |
used, and all commands are scheduled on the drive unit associated with a | |
given controller. | |
The library provides a unit service routine to handle all of the disc | |
commands. The routine is called from the interface service routine to handle | |
the common disc actions, while the interface routine handles actions specific | |
to the operation of the interface (such as data transfer). | |
The service routine schedules the unit to continue command execution under | |
these conditions: | |
1. A Seek or Recalibrate command is waiting for the seek completion. | |
2. A read or write command is waiting for the first data transfer of a | |
sector to start. | |
3. A read or write command is waiting for the next sector to start after | |
the final data transfer of the preceding sector. | |
4. A Verify command is waiting for the end of the current sector. | |
The library also provides controller and timer service routines for MAC | |
emulations. All three (unit, controller, and timer) must be called from | |
their respective interface service routines before any interface-specific | |
actions, if any, are taken. | |
On return from the library unit or controller service routines, the "wait" | |
field of the UNIT structure will be set to the activation time if the unit | |
is to be scheduled. The caller is responsible for activating the unit. If | |
the caller uses this feature, the field should be reset to zero before the | |
next service call. | |
The MAC timer unit is activated by the library, and its "wait" field is not | |
used. The timer starts when a command other than End, Seek, or Recalibrate | |
completes, or when the controller is waiting for the interface to supply or | |
accept a parameter during command execution. It stops when an End, Seek, or | |
Recalibrate command completes, a command is prepared for execution, or the | |
final parameter has been supplied or accepted by the interface during command | |
execution. | |
The controller maintains six variables in each drive's unit structure: | |
wait -- the current service activation time | |
pos -- the current byte offset into the disc image file | |
u3 (CYL) -- the current drive cylinder | |
u4 (STAT) -- the drive status (Status-2) | |
u5 (OP) -- the drive operation in process | |
u6 (PHASE) -- the current operation phase | |
These and other definitions are in the file hp_disclib.h, which must be | |
included in the interface simulator. | |
The controller library supports up to eight drives per MAC controller and one | |
drive per ICD controller. Unit numbers 0-7 represent valid drive addresses | |
for a MAC controller. The unit number field is ignored for an ICD | |
controller, and unit 0 is always implied. In simulation, MAC unit numbers | |
correspond one-for-one with device units, whereas one ICD controller is | |
associated with each of the several device units that are independently | |
addressed as unit 0. | |
The MAC controller firmware allows access to unit numbers 8-10 without | |
causing a Unit Unavailable error. Instead, the controller reports these | |
legal-but-invalid units as permanently offline. | |
Implementation notes: | |
1. The library does not simulate sector headers and trailers. Initialize | |
and Write Full Sector commands ignore the SPD bits and the supplied | |
header and trailer words. Read Full Sector fills in the header with the | |
current CHS address and sets the SPD bits to zero. The CRC and ECC words | |
in the trailer are returned as zeros. Programs that depend on drives | |
retaining the set values will fail. | |
2. The library does not simulate drive hold bits or support multiple CPU | |
interfaces connected to the same controller. CPU access to a valid drive | |
always succeeds. | |
3. The library does not simulate interface signals or function bus orders, | |
except for EOD (End of Data) and BUSY. The interface simulators must | |
decide for themselves what actions to take (e.g., interrupting the CPU) | |
on the basis of the controller state. | |
4. The command/sector buffer is an array of 16-bit elements. Byte-oriented | |
interface simulators, such as the 12821A HP-IB Disc Interface, must do | |
their own byte packing and unpacking. | |
5. The SAVE command does not save the "wait" and "pos" fields of the UNIT | |
structure automatically. To ensure that they are saved, they are | |
referenced by hidden, read-only registers. | |
*/ | |
#include <math.h> | |
#include "hp_disclib.h" | |
/* Command accessors */ | |
#define DL_V_OPCODE 8 /* bits 12- 8: general opcode */ | |
#define DL_V_HOLD 7 /* bits 7- 7: general hold flag */ | |
#define DL_V_UNIT 0 /* bits 3- 0: general unit number */ | |
#define DL_V_SPD 13 /* bits 15-13: Initialize S/P/D flags */ | |
#define DL_V_CHEAD 6 /* bits 7- 6: Cold Load Read head number */ | |
#define DL_V_CSECT 0 /* bits 5- 0: Cold Load Read sector number */ | |
#define DL_V_FRETRY 4 /* bits 7- 4: Set File Mask retry count */ | |
#define DL_V_FDECR 3 /* bits 3- 3: Set File Mask seek decrement */ | |
#define DL_V_FSPEN 2 /* bits 2- 2: Set File Mask sparing enable */ | |
#define DL_V_FCYLM 1 /* bits 1- 1: Set File Mask cylinder mode */ | |
#define DL_V_FAUTSK 0 /* bits 0- 0: Set File Mask auto seek */ | |
#define DL_V_FMASK 0 /* bits 3- 0: Set File Mask (flags combined) */ | |
#define DL_M_OPCODE 037 /* opcode mask */ | |
#define DL_M_UNIT 017 /* unit mask */ | |
#define DL_M_SPD 007 /* S/P/D flags mask */ | |
#define DL_M_CHEAD 003 /* Cold Load Read head number mask */ | |
#define DL_M_CSECT 077 /* Cold Load Read sector number mask */ | |
#define DL_M_FRETRY 017 /* Set File Mask retry count mask */ | |
#define DL_M_FMASK 017 /* Set File Mask flags mask */ | |
#define GET_OPCODE(c) (CNTLR_OPCODE) (((c) >> DL_V_OPCODE) & DL_M_OPCODE) | |
#define GET_UNIT(c) (((c) >> DL_V_UNIT) & DL_M_UNIT) | |
#define GET_SPD(c) (((c) >> DL_V_SPD) & DL_M_SPD) | |
#define GET_CHEAD(c) (((c) >> DL_V_CHEAD) & DL_M_CHEAD) | |
#define GET_CSECT(c) (((c) >> DL_V_CSECT) & DL_M_CSECT) | |
#define GET_FRETRY(c) (((c) >> DL_V_FRETRY) & DL_M_FRETRY) | |
#define GET_FMASK(c) (((c) >> DL_V_FMASK) & DL_M_FMASK) | |
#define DL_FDECR (1 << DL_V_FDECR) | |
#define DL_FSPEN (1 << DL_V_FSPEN) | |
#define DL_FCYLM (1 << DL_V_FCYLM) | |
#define DL_FAUTSK (1 << DL_V_FAUTSK) | |
/* Parameter accessors */ | |
#define DL_V_HEAD 8 /* bits 12- 8: head number */ | |
#define DL_V_SECTOR 0 /* bits 7- 0: sector number */ | |
#define DL_M_HEAD 0017 /* head number mask */ | |
#define DL_M_SECTOR 0377 /* sector number mask */ | |
#define GET_HEAD(p) (((p) >> DL_V_HEAD) & DL_M_HEAD) | |
#define GET_SECTOR(p) (((p) >> DL_V_SECTOR) & DL_M_SECTOR) | |
#define SET_HEAD(c) (((c)->head & DL_M_HEAD) << DL_V_HEAD) | |
#define SET_SECTOR(c) (((c)->sector & DL_M_SECTOR) << DL_V_SECTOR) | |
/* Drive properties table. | |
In hardware, drives report their Drive Type numbers to the controller upon | |
receipt of a Request Status tag bus command. The drive type is used to | |
determine the legal range of head and sector addresses (the drive itself will | |
validate the cylinder address during seeks). | |
In simulation, we set up a table of drive properties and use the model ID as | |
an index into the table. The table is used to validate seek parameters and | |
to provide the mapping between CHS addresses and the linear byte addresses | |
required by the host file access routines. | |
The 7905/06(H) drives consist of removable and fixed platters, whereas the | |
7920(H)/25(H) drives have only removable multi-platter packs. As a result, | |
7905/06 drives are almost always accessed in platter mode, i.e., a given | |
logical disc area is fully contained on either the removable or fixed | |
platter, whereas the 7920/25 drives are almost always accessed in cylinder | |
mode with logical disc areas spanning some or all of the platters. | |
Disc image files are arranged as a linear set of tracks. To improve | |
locality of access, tracks in the 7905/06 images are grouped per-platter, | |
whereas tracks on the 7920 and 7925 are sequential by cylinder and head | |
number. | |
The simulator maps the tracks on the 7905/06 removable platter (heads 0 and | |
1) to the first half of the disc image, and the tracks on the fixed platter | |
(heads 2 and, for the 7906 only, 3) to the second half of the image. For the | |
7906(H), the cylinder-head order of the tracks is 0-0, 0-1, 1-0, 1-1, ..., | |
410-0, 410-1, 0-2, 0-3, 1-2, 1-3, ..., 410-2, 410-3. The 7905 order is the | |
same, except that head 3 tracks are omitted. | |
For the 7920(H)/25(H), all tracks appear in cylinder-head order, e.g., 0-0, | |
0-1, 0-2, 0-3, 0-4, 1-0, 1-1, ..., 822-2, 822-3, 822-4 for the 7920(H). | |
This variable-access geometry is accomplished by defining additional "heads | |
per cylinder" values for the fixed and removable sections of each drive that | |
indicates the number of heads that should be grouped for locality. The | |
removable values are set to 2 on the 7905 and 7906, indicating that those | |
drives typically use cylinders consisting of two heads. They are set to the | |
number of heads per drive for the 7920 and 7925, as those typically use | |
cylinders encompassing the entire pack. | |
*/ | |
#define D7905_RH 2 | |
#define D7905_FH (D7905_HEADS - D7905_RH) | |
#define D7906_RH 2 | |
#define D7906_FH (D7906_HEADS - D7906_RH) | |
#define D7920_RH D7920_HEADS | |
#define D7920_FH (D7920_HEADS - D7920_RH) | |
#define D7925_RH D7925_HEADS | |
#define D7925_FH (D7925_HEADS - D7925_RH) | |
typedef struct { | |
uint32 sectors; /* sectors per head */ | |
uint32 heads; /* heads per cylinder*/ | |
uint32 cylinders; /* cylinders per drive */ | |
uint32 words; /* words per drive */ | |
uint32 type; /* drive type */ | |
uint32 remov_heads; /* number of removable-platter heads */ | |
uint32 fixed_heads; /* number of fixed-platter heads */ | |
} DRIVE_PROPERTIES; | |
static const DRIVE_PROPERTIES drive_props [] = { | |
{ D7905_SECTS, D7905_HEADS, D7905_CYLS, D7905_WORDS, D7905_TYPE, D7905_RH, D7905_FH }, | |
{ D7906_SECTS, D7906_HEADS, D7906_CYLS, D7906_WORDS, D7906_TYPE, D7906_RH, D7906_FH }, | |
{ D7920_SECTS, D7920_HEADS, D7920_CYLS, D7920_WORDS, D7920_TYPE, D7920_RH, D7920_FH }, | |
{ D7925_SECTS, D7925_HEADS, D7925_CYLS, D7925_WORDS, D7925_TYPE, D7925_RH, D7925_FH } | |
}; | |
#define PROPS_COUNT (sizeof (drive_props) / sizeof (drive_props [0])) | |
/* Convert a CHS address to a block offset. | |
A cylinder/head/sector address is converted into a linear block address that | |
may be used to calculate a byte offset to pass to the file access routines. | |
The conversion logic is: | |
if Head < removable_heads_per_cylinder then | |
tracks := Cylinder * removable_heads_per_cylinder + Head; | |
else | |
tracks := cylinders_per_drive * removable_heads_per_cylinder + | |
Cylinder * fixed_heads_per_cylinder + (Head - removable_heads_per_cylinder); | |
block := tracks * sectors_per_track + Sector; | |
byte_offset := block * words_per_sector * bytes_per_word; | |
The byte offset is calculated in two steps to allow for future controller | |
enhancements to support the CS/80 command set and its associated linear block | |
addressing mode. | |
*/ | |
#define TO_BLOCK(cylinder,head,sector,model) \ | |
(((head) < drive_props [model].remov_heads \ | |
? (cylinder) * drive_props [model].remov_heads + (head) \ | |
: drive_props [model].cylinders * drive_props [model].remov_heads \ | |
+ ((cylinder) * drive_props [model].fixed_heads + (head) - drive_props [model].remov_heads)) \ | |
* drive_props [model].sectors + (sector)) | |
#define TO_OFFSET(block) ((block) * DL_WPSEC * sizeof (uint16)) | |
/* Estimate the current sector. | |
The sector currently passing under the disc heads is estimated from the | |
current simulator time (i.e., the count of instructions since startup) and | |
the simulated disc rotation time. The computation logic is: | |
per_sector_time := word_transfer_time * words_per_sector + intersector_time; | |
current_sector := (current_time / per_sector_time) MOD sectors_per_track; | |
*/ | |
#define GET_CURSEC(cvptr,uptr) \ | |
((uint16) fmod (sim_gtime() / (double) ((cvptr->data_time * DL_WPSEC + cvptr->sector_time)), \ | |
(double) drive_props [GET_MODEL (uptr->flags)].sectors)) | |
/* Command properties table. | |
The validity of each command for a specified controller type is checked | |
against the command properties table when it is prepared. The table also | |
includes the count of inbound and outbound properties, the class of the | |
command, and flags to indicate certain common actions that should be taken. | |
*/ | |
typedef struct { | |
uint32 params_in; /* count of input parameters */ | |
uint32 params_out; /* count of output parameters */ | |
CNTLR_CLASS classification; /* command classification */ | |
t_bool valid [type_count]; /* per-type command validity */ | |
t_bool clear_status; /* command clears the controller status */ | |
t_bool unit_field; /* command has a unit field */ | |
t_bool unit_check; /* command checks the unit number validity */ | |
t_bool unit_access; /* command accesses the drive unit */ | |
t_bool seek_wait; /* command waits for seek completion */ | |
} DS_PROPS; | |
typedef const DS_PROPS *PRPTR; | |
#define T TRUE | |
#define F FALSE | |
static const DS_PROPS cmd_props [] = { | |
/* par par opcode valid for clear unit unit unit seek */ | |
/* in out classification MAC ICD stat field check acces wait */ | |
{ 0, 0, class_read, { T, T }, T, F, T, T, F }, /* 00 = cold load read */ | |
{ 0, 0, class_control, { T, T }, T, T, T, T, T }, /* 01 = recalibrate */ | |
{ 2, 0, class_control, { T, T }, T, T, T, T, F }, /* 02 = seek */ | |
{ 0, 2, class_status, { T, T }, F, T, F, F, F }, /* 03 = request status */ | |
{ 0, 1, class_status, { T, T }, T, T, T, F, F }, /* 04 = request sector address */ | |
{ 0, 0, class_read, { T, T }, T, T, T, T, T }, /* 05 = read */ | |
{ 0, 0, class_read, { T, T }, T, T, T, T, T }, /* 06 = read full sector */ | |
{ 1, 0, class_read, { T, T }, T, T, T, T, T }, /* 07 = verify */ | |
{ 0, 0, class_write, { T, T }, T, T, T, T, T }, /* 10 = write */ | |
{ 0, 0, class_write, { T, T }, T, T, T, T, T }, /* 11 = write full sector */ | |
{ 0, 0, class_control, { T, T }, T, F, F, F, F }, /* 12 = clear */ | |
{ 0, 0, class_write, { T, T }, T, T, T, T, T }, /* 13 = initialize */ | |
{ 2, 0, class_control, { T, T }, T, F, F, F, F }, /* 14 = address record */ | |
{ 0, 7, class_status, { T, F }, F, F, F, F, F }, /* 15 = request syndrome */ | |
{ 1, 0, class_read, { T, T }, T, T, T, T, T }, /* 16 = read with offset */ | |
{ 0, 0, class_control, { T, T }, T, F, F, F, F }, /* 17 = set file mask */ | |
{ 0, 0, class_invalid, { F, F }, T, F, F, F, F }, /* 20 = invalid */ | |
{ 0, 0, class_invalid, { F, F }, T, F, F, F, F }, /* 21 = invalid */ | |
{ 0, 0, class_read, { T, T }, T, T, T, T, T }, /* 22 = read without verify */ | |
{ 1, 0, class_status, { T, F }, T, F, F, F, F }, /* 23 = load TIO register */ | |
{ 0, 2, class_status, { T, T }, F, F, F, F, F }, /* 24 = request disc address */ | |
{ 0, 0, class_control, { T, T }, T, F, F, F, F }, /* 25 = end */ | |
{ 0, 0, class_control, { T, F }, T, T, T, F, F } /* 26 = wakeup */ | |
}; | |
/* Auxiliary unit indices */ | |
typedef enum { | |
controller = 0, /* controller unit index */ | |
timer /* command wait timer index */ | |
} AUX_INDEX; | |
/* Controller opcode names */ | |
static const char invalid_name [] = "invalid"; | |
static const char *opcode_name [] = { | |
"cold load read", /* 00 */ | |
"recalibrate", /* 01 */ | |
"seek", /* 02 */ | |
"request status", /* 03 */ | |
"request sector address", /* 04 */ | |
"read", /* 05 */ | |
"read full sector", /* 06 */ | |
"verify", /* 07 */ | |
"write", /* 10 */ | |
"write full sector", /* 11 */ | |
"clear", /* 12 */ | |
"initialize", /* 13 */ | |
"address record", /* 14 */ | |
"request syndrome", /* 15 */ | |
"read with offset", /* 16 */ | |
"set file mask", /* 17 */ | |
invalid_name, /* 20 = invalid */ | |
invalid_name, /* 21 = invalid */ | |
"read without verify", /* 22 */ | |
"load TIO register", /* 23 */ | |
"request disc address", /* 24 */ | |
"end", /* 25 */ | |
"wakeup" /* 26 */ | |
}; | |
/* Controller phase names */ | |
static const char *phase_name [] = { | |
"start", | |
"data", | |
"end" | |
}; | |
/* Disc library local controller routines */ | |
static t_bool start_seek (CVPTR cvptr, UNIT *uptr, CNTLR_OPCODE next_opcode, CNTLR_PHASE next_phase); | |
static t_stat start_read (CVPTR cvptr, UNIT *uptr); | |
static void end_read (CVPTR cvptr, UNIT *uptr); | |
static void start_write (CVPTR cvptr, UNIT *uptr); | |
static t_stat end_write (CVPTR cvptr, UNIT *uptr); | |
static t_bool position_sector (CVPTR cvptr, UNIT *uptr, t_bool verify); | |
static void next_sector (CVPTR cvptr, UNIT *uptr); | |
static t_stat io_error (CVPTR cvptr, UNIT *uptr); | |
/* Disc library local utility routines */ | |
static void set_address (CVPTR cvptr, uint32 index); | |
static void set_timer (CVPTR cvptr, FLIP_FLOP action); | |
static uint16 drive_status (UNIT *uptr); | |
/* Disc library global controller routines */ | |
/* Prepare a command for execution. | |
On entry, the first word of the controller buffer contains the command to | |
prepare, the "cvptr" parameter points at the controller state variable | |
structure, and the "units" parameter points at the first unit of the unit | |
array. For a MAC controller, the "unit limit" parameter indicates the last | |
valid unit number, and the unit to use is taken from the unit field of the | |
command word. For an ICD controller, the parameter indicates the number | |
of the unit to use directly. | |
If a valid command was prepared for execution, the routine returns TRUE and | |
sets the controller state to "busy." If the command is illegal, the routine | |
returns FALSE and sets the controller state to "waiting." In the latter | |
case, the controller status will indicate the reason for the rejection. | |
The opcode and unit number (for MAC controllers) are obtained from the buffer | |
and checked for legality. If either is illegal, the controller status is set | |
appropriately, and the routine returns FALSE. | |
For a valid command and an available unit, the controller's opcode field is | |
set from the buffer, the length field is set to the number of inbound | |
parameter words expected, and the index field is set to 1 to point at the | |
first parameter entry in the buffer. | |
*/ | |
t_bool dl_prepare_command (CVPTR cvptr, UNIT *units, uint32 unit_limit) | |
{ | |
uint32 unit; | |
PRPTR props; | |
CNTLR_OPCODE opcode; | |
set_timer (cvptr, CLEAR); /* stop the command wait timer */ | |
opcode = GET_OPCODE (cvptr->buffer [0]); /* get the opcode from the command */ | |
if (opcode > last_opcode) /* is the opcode invalid? */ | |
props = &cmd_props [invalid_opcode]; /* undefined commands clear prior status */ | |
else /* the opcode is potentially valid */ | |
props = &cmd_props [opcode]; /* get the command properties */ | |
if (cvptr->type == MAC) /* is this a MAC controller? */ | |
if (props->unit_field) /* is the unit field defined for this command? */ | |
unit = GET_UNIT (cvptr->buffer [0]); /* get the unit from the command */ | |
else /* no unit specified in the command */ | |
unit = 0; /* so the unit is always unit 0 */ | |
else /* an ICD controller */ | |
unit = unit_limit; /* uses the supplied unit number */ | |
if (props->clear_status) { /* clear the prior controller status */ | |
cvptr->status = normal_completion; /* if indicated for this command */ | |
cvptr->spd_unit = SET_S1UNIT (unit); /* save the unit number for status requests */ | |
} | |
if (cvptr->type <= last_type /* is the controller type legal, */ | |
&& props->valid [cvptr->type]) /* and the opcode defined for this controller? */ | |
if (props->unit_check && unit > DL_MAXUNIT) /* if the unit number is checked and is illegal, */ | |
dl_end_command (cvptr, unit_unavailable); /* end with a unit unavailable error */ | |
else { | |
cvptr->state = cntlr_busy; /* legal unit, so controller is now busy */ | |
cvptr->opcode = opcode; /* save the controller opcode */ | |
cvptr->length = props->params_in; /* set the inbound parameter count */ | |
cvptr->index = 1; /* point at the first parameter element (if any) */ | |
if (cvptr->type == MAC && cvptr->length) { /* is this a MAC controller with inbound parameters? */ | |
cvptr->aux [controller].OP = opcode; /* save the opcode */ | |
cvptr->aux [controller].PHASE = data_phase; /* and set the phase for parameter pickup */ | |
set_timer (cvptr, SET); /* start the timer to wait for the first parameter */ | |
} | |
return TRUE; /* the command is now prepared for execution */ | |
} | |
else /* the opcode is undefined */ | |
dl_end_command (cvptr, illegal_opcode); /* so set bad opcode status */ | |
return FALSE; /* the preparation has failed */ | |
} | |
/* Start a command. | |
On entry, the controller's opcode field contains the command to start, and | |
the buffer contains the command word in element 0 and the parameters required | |
by the command, if any, beginning in element 1. The call parameters are the | |
same as those supplied to the "prepare command" routine. | |
If the command was started successfully, the routine returns a pointer to the | |
unit to be activated and sets that unit's "wait" field to the activation | |
time. The caller should activate the unit upon return to complete or | |
continue command processing. If the command did not start, the routine | |
returns NULL. | |
If a seek is in progress on a drive when a command accessing that drive is | |
started, the unit pointer is returned but the unit's "wait" field is set to | |
zero. In this case, the unit must not be activated (as it already is). | |
Instead, the unit's opcode and phase fields will have been set to start the | |
command automatically when the seek completes. | |
For commands that return status from the controller, the buffer will contain | |
the returned value(s), the buffer index will be zero, and the buffer length | |
will be set to the number of words returned in the buffer. These words must | |
be returned to the CPU via the interface. | |
Implementation notes: | |
1. A command must have been prepared by calling dl_prepare_command first. | |
After preparation, the controller's opcode will be valid, and the unit | |
number field will be legal (but not necessarily valid) for those commands | |
that check the unit. | |
Unit numbers 0-7 represent valid drive addresses. However, the MAC | |
controller firmware allows access to unit numbers 8-10 without causing a | |
Unit Unavailable error. Instead, the controller reports these units as | |
permanently offline. | |
2. Commands that check for a valid unit do some processing before failing | |
with a Status-2 (not ready) error if the unit is invalid. For example, | |
the Seek command accepts its parameters from the CPU and sets the CHS | |
values into the controller before failing. | |
3. In hardware, read, write, and recalibrate commands wait in an internal | |
loop for a pending seek completion and clear the resulting Attention | |
status before executing. In simulation, we change a seeking drive unit's | |
opcode and phase fields from seek completion to the start of the next | |
command. This eliminates the setting of the Attention status and begins | |
command execution automatically when the seek completes. | |
If the seek completed between the command preparation and start, | |
Attention will have been set. If the unit is idle on entry, we clear the | |
Attention status unilaterally (it doesn't matter whether or not it was | |
set; Attention always is clear when commands start). | |
4. The Seek and Cold Load Read commands do not check for a seek or | |
recalibrate in progress. If the heads are moving, the drive will reject | |
a seek command with a Seek Check error. The firmware does not test | |
explicitly for Access Not Ready before executing the command, so the | |
parameters (e.g., controller CHS addresses) are still set as though the | |
command had succeeded. | |
A Seek command will return to the Poll Loop with Seek Check status set. | |
When the seek in progress completes, the controller will interrupt with | |
Drive Attention status. The controller address will differ from the | |
drive address, so it's incumbent upon the caller to issue a Request | |
Status command after the seek, which will return Status-2 Error status. | |
A Cold Load Read command issues a seek to cylinder 0 and then begins a | |
read, which first waits for seek completion. The Seek Check error will | |
abort the command at this point with Status-2 Error status. | |
In simulation, a Seek command allows the seek in progress to complete | |
normally, whereas a Cold Load Read command modifies the unit command | |
and phase from the end phase of Seek or Recalibrate to the start | |
phase of Read, which will catch the Seek Check error as in hardware. | |
5. The Cold Load Read command checks if the drive is ready before setting | |
the file mask. Therefore, we normally defer setting the file mask until | |
the unit service is called. However, if a seek is in progress, then the | |
drive must be ready, so we set the file mask here. | |
6. ECC is not simulated, so the Request Syndrome command always returns zero | |
values for the displacement and patterns. | |
7. The Request Status, Request Sector Address, and Wakeup commands reference | |
drive units but are scheduled on the controller unit because they may be | |
issued while a drive is processing a seek. | |
8. The activation time is set to the intersector time (latency) for read and | |
write commands, and to the controller processing time for all others. | |
The read/write start time cannot be shorter than 20 instructions, or | |
DVR32 will be unable to start DCPC in time to avoid an over/underrun. | |
*/ | |
UNIT *dl_start_command (CVPTR cvptr, UNIT *units, uint32 unit_limit) | |
{ | |
UNIT *uptr, *rptr; | |
uint32 unit; | |
PRPTR props; | |
t_bool is_seeking = FALSE; | |
props = &cmd_props [cvptr->opcode]; /* get the command properties */ | |
if (cvptr->type == MAC) { /* is this a MAC controller? */ | |
if (props->unit_field) /* is the unit field defined for this command? */ | |
unit = GET_UNIT (cvptr->buffer [0]); /* get the unit number from the command */ | |
else /* no unit is specified in the command */ | |
unit = 0; /* so the unit number defaults to 0 */ | |
if (unit > unit_limit) /* if the unit number is invalid, */ | |
uptr = NULL; /* it does not correspond to a unit */ | |
else if (props->unit_access) /* if the command accesses a drive, */ | |
uptr = units + unit; /* get the address of the unit */ | |
else /* the command accesses the controller only */ | |
uptr = cvptr->aux + controller; /* so use the controller unit */ | |
} | |
else { /* for an ICD controller, */ | |
unit = 0; /* the unit value is ignored */ | |
uptr = units + unit_limit; /* and we use the indicated unit */ | |
} | |
if (props->unit_check && !uptr /* if the unit number is checked and is invalid */ | |
|| props->seek_wait && (drive_status (uptr) & DL_S2STOPS)) { /* or if we're waiting for an offline drive */ | |
dl_end_command (cvptr, status_2_error); /* then the command ends with a Status-2 error */ | |
uptr = NULL; /* prevent the command from starting */ | |
} | |
else if (uptr) { /* otherwise, we have a valid unit */ | |
uptr->wait = cvptr->cmd_time; /* most commands use the command delay */ | |
if (props->unit_access) { /* does the command access the unit? */ | |
is_seeking = sim_is_active (uptr) != 0; /* see if the unit is busy */ | |
if (is_seeking) /* if a seek is in progress, */ | |
uptr->wait = 0; /* set for no unit activation */ | |
else { /* otherwise, the unit is idle */ | |
uptr->STAT &= ~DL_S2ATN; /* clear the drive Attention status */ | |
if (props->classification == class_read /* if a read command */ | |
|| props->classification == class_write) /* or a write command */ | |
uptr->wait = cvptr->sector_time; /* schedule the sector start latency */ | |
} | |
} | |
} | |
cvptr->index = 0; /* reset the buffer index */ | |
cvptr->length = props->params_out; /* set the count of outbound parameters */ | |
cvptr->eod = CLEAR; /* clear the end of data flag */ | |
switch (cvptr->opcode) { /* dispatch the command */ | |
case cold_load_read: | |
cvptr->cylinder = 0; /* set the cylinder address to 0 */ | |
cvptr->head = GET_CHEAD (cvptr->buffer [0]); /* set the head */ | |
cvptr->sector = GET_CSECT (cvptr->buffer [0]); /* and sector from the command */ | |
if (is_seeking) { /* if a seek is in progress, */ | |
uptr->STAT |= DL_S2SC; /* a Seek Check occurs */ | |
cvptr->file_mask = DL_FSPEN; /* enable sparing */ | |
uptr->OP = read; /* start the read on the seek completion */ | |
uptr->PHASE = start_phase; /* and reset the command phase */ | |
return uptr; /* to allow the seek to complete normally */ | |
} | |
else /* the drive is not seeking */ | |
uptr->wait = cvptr->cmd_time; /* the command starts with a seek, not a read */ | |
break; | |
case seek: | |
cvptr->cylinder = cvptr->buffer [1]; /* get the supplied cylinder */ | |
cvptr->head = GET_HEAD (cvptr->buffer [2]); /* and head */ | |
cvptr->sector = GET_SECTOR (cvptr->buffer [2]); /* and sector addresses */ | |
if (is_seeking) { /* if a seek is in progress, */ | |
uptr->STAT |= DL_S2SC; /* a Seek Check occurs */ | |
dl_idle_controller (cvptr); /* return the controller to the idle condition */ | |
return uptr; /* to allow the seek to complete normally */ | |
} | |
break; | |
case request_status: | |
cvptr->buffer [0] = /* set the Status-1 value */ | |
cvptr->spd_unit | SET_S1STAT (cvptr->status); /* into the buffer */ | |
if (cvptr->type == MAC) /* is this a MAC controller? */ | |
if (unit > unit_limit) /* if the unit number is invalid */ | |
rptr = NULL; /* it does not correspond to a unit */ | |
else /* otherwise, the unit is valid */ | |
rptr = &units [unit]; /* so get the address of the referenced unit */ | |
else /* if not a MAC controller */ | |
rptr = uptr; /* then the referenced unit is the current unit */ | |
cvptr->buffer [1] = drive_status (rptr); /* set the Status-2 value */ | |
if (rptr) /* if the unit is valid */ | |
rptr->STAT &= ~DL_S2FS; /* clear the First Status bit */ | |
cvptr->spd_unit = SET_S1UNIT (unit); /* save the unit number */ | |
if (unit > DL_MAXUNIT) /* if the unit number is illegal, */ | |
cvptr->status = unit_unavailable; /* the next status will be Unit Unavailable */ | |
else /* a legal unit */ | |
cvptr->status = normal_completion; /* clears the controller status */ | |
break; | |
case request_disc_address: | |
set_address (cvptr, 0); /* return the CHS values in buffer 0-1 */ | |
break; | |
case request_sector_address: | |
if (unit > unit_limit) /* if the unit number is invalid */ | |
rptr = NULL; /* it does not correspond to a unit */ | |
else /* otherwise, the unit is valid */ | |
rptr = &units [unit]; /* so get the address of the referenced unit */ | |
if (drive_status (rptr) & DL_S2NR) /* if the drive is not ready, */ | |
dl_end_command (cvptr, status_2_error); /* terminate with not ready status */ | |
else /* otherwise, the drive is ready */ | |
cvptr->buffer [0] = GET_CURSEC (cvptr, rptr); /* so calculate the current sector address */ | |
break; | |
case request_syndrome: | |
cvptr->buffer [0] = /* return the Status-1 value in buffer 0 */ | |
cvptr->spd_unit | SET_S1STAT (cvptr->status); | |
set_address (cvptr, 1); /* return the CHS values in buffer 1-2 */ | |
cvptr->buffer [3] = 0; /* the displacement is always zero */ | |
cvptr->buffer [4] = 0; /* the syndrome is always zero */ | |
cvptr->buffer [5] = 0; | |
cvptr->buffer [6] = 0; | |
break; | |
case address_record: | |
cvptr->cylinder = cvptr->buffer [1]; /* get the supplied cylinder */ | |
cvptr->head = GET_HEAD (cvptr->buffer [2]); /* and head */ | |
cvptr->sector = GET_SECTOR (cvptr->buffer [2]); /* and sector addresses */ | |
cvptr->eoc = CLEAR; /* clear the end-of-cylinder flag */ | |
break; | |
case set_file_mask: | |
cvptr->file_mask = GET_FMASK (cvptr->buffer [0]); /* get the supplied file mask */ | |
if (cvptr->type == MAC) /* if this is a MAC controller, */ | |
cvptr->retry = GET_FRETRY (cvptr->buffer [0]); /* the retry count is supplied too */ | |
break; | |
case initialize: | |
if (uptr) /* if the unit is valid, */ | |
cvptr->spd_unit |= /* merge the SPD flags */ | |
SET_S1SPD (GET_SPD (cvptr->buffer [0])); /* from the command word */ | |
break; | |
case verify: | |
cvptr->verify_count = cvptr->buffer [1]; /* get the supplied sector count */ | |
break; | |
default: /* the remaining commands */ | |
break; /* are handled by the service routines */ | |
} | |
if (uptr) { /* if the command accesses a valid unit */ | |
uptr->OP = cvptr->opcode; /* save the opcode in the unit */ | |
if (cvptr->length) /* if the command has outbound parameters, */ | |
uptr->PHASE = data_phase; /* set up the data phase for the transfer */ | |
else /* if there are no parameters, */ | |
uptr->PHASE = start_phase; /* set up the command phase for execution */ | |
return uptr; /* return a pointer to the scheduled unit */ | |
} | |
else | |
return NULL; /* the command did not start */ | |
} | |
/* Complete a command. | |
The current command is completed with the indicated status. The command | |
result status is set, the controller enters the command wait state, and the | |
CPU timer is restarted. | |
*/ | |
void dl_end_command (CVPTR cvptr, CNTLR_STATUS status) | |
{ | |
cvptr->status = status; /* set the command result status */ | |
cvptr->state = cntlr_wait; /* set the controller state to waiting */ | |
set_timer (cvptr, SET); /* start the command wait timer */ | |
return; | |
} | |
/* Poll the drives for Attention status. | |
If interrupts are enabled on the interface, this routine is called to check | |
if any drive is requesting attention. The routine returns TRUE if a drive is | |
requesting attention and FALSE if not. | |
Starting with the last unit requesting attention, each drive is checked in | |
sequence. If a drive has its Attention status set, the controller saves its | |
unit number, sets the result status to Drive Attention, and enters the | |
command wait state. The routine returns TRUE to indicate that an interrupt | |
should be generated. The next time the routine is called, the poll begins | |
with the last unit that requested attention, so that each unit is given an | |
equal chance to respond. | |
If no unit is requesting attention, the routine returns FALSE to indicate | |
that no interrupt should be generated. | |
*/ | |
t_bool dl_poll_drives (CVPTR cvptr, UNIT *units, uint32 unit_limit) | |
{ | |
uint32 unit; | |
for (unit = 0; unit <= unit_limit; unit++) { /* check each unit in turn */ | |
cvptr->poll_unit = /* start with the last unit checked */ | |
(cvptr->poll_unit + 1) % (unit_limit + 1); /* and cycle back to unit 0 */ | |
if (units [cvptr->poll_unit].STAT & DL_S2ATN) { /* if the unit is requesting attention, */ | |
units [cvptr->poll_unit].STAT &= ~DL_S2ATN; /* clear the Attention status */ | |
cvptr->spd_unit = SET_S1UNIT (cvptr->poll_unit); /* set the controller's unit number */ | |
cvptr->status = drive_attention; /* and status */ | |
cvptr->state = cntlr_wait; /* and wait for a command */ | |
return TRUE; /* tell the caller to interrupt */ | |
} | |
} | |
return FALSE; /* no requests, so do not generate an interrupt */ | |
} | |
/* Service the disc drive unit. | |
The unit service routine is called to execute scheduled controller commands | |
for the specified unit. The actions to be taken depend on the current state | |
of the controller and the unit. | |
In addition to the controller state variables supplied in the call, the | |
service routine accesses these six variables in the UNIT structure: | |
wait -- the current service activation time | |
pos -- the current byte offset into the disc image file | |
u3 (CYL) -- the current drive cylinder | |
u4 (STAT) -- the drive status (Status-2) | |
u5 (OP) -- the drive operation in process | |
u6 (PHASE) -- the current operation phase | |
The activation time is set non-zero if the service should be rescheduled. | |
The caller is responsible upon return for activating the unit. The file | |
offset indicates the byte position in the disc image file for the next read | |
or write operation. | |
The drive cylinder gives the current location of the head positioner. This | |
may differ from the cylinder value in the controller if the Address Record | |
command has been used. The drive status maintains various per-drive | |
conditions (e.g., the state of the read-only and format switches, drive | |
ready, first status). The operation in process and operation phase define | |
the action to be taken by this service routine. | |
Initially, the operation in process is set to the opcode field of the command | |
when it is started. However, the operation in process may change during | |
execution (the controller opcode never does). This is to aid code reuse in | |
the service routine. For example, a Cold Load Read command is changed to a | |
Read command once the seek portion is complete, and a Read Without Verify | |
command is changed to a normal Read command after a track boundary is | |
crossed. | |
The operation phase provides different substates for those commands that | |
transfer data or that have different starting and ending actions. Three | |
phases are defined: start, data, and end. Commands that do not transfer data | |
to or from the CPU interface do not have data phases, and commands that | |
complete upon first service do not have end phases. The service routine | |
validates phase assignments and returns SCPE_IERR (Internal Error) if entry | |
is made with an illegal operation phase or a phase that is not valid for a | |
given operation. | |
An operation in the data phase is in the process of transferring data between | |
the CPU and sector buffer. Because this process is interface-specific, the | |
service routine does nothing (other than validate) in this phase. It is up | |
to the caller to transition from the data phase to the end phase when the | |
transfer is complete. | |
If an operation is completed, or an error has occurred, the controller state | |
on return will be either idle or waiting, instead of busy. The caller should | |
check the controller status to determine if normal completion or error | |
recovery is appropriate. | |
If the command is continuing, the service activation time will be set | |
appropriately. The caller should then call sim_activate to schedule the next | |
service and clear the "wait" field in preparation for the next service call. | |
Implementation notes: | |
1. The Cold Load Read and Seek commands check only the drive's Not Ready | |
status because seeking clears a Seek Check. The other commands that | |
access the unit (e.g., Read and Write) have already checked in the | |
command start routine for Not Ready, Seek Check, or Fault status and | |
terminated with a Status-2 error. | |
2. Several commands (e.g., Set File Mask, Address Record) are executed | |
completely within the dl_start_command routine, so all we do here is | |
finish the command with the expected status. The service routine is | |
called only to provide the proper command execution delay. | |
3. If a host file system error occurs, the service routine returns SCPE_IERR | |
to stop simulation. If simulation is resumed, the controller will behave | |
as though an uncorrectable data error had occurred. | |
*/ | |
t_stat dl_service_drive (CVPTR cvptr, UNIT *uptr) | |
{ | |
t_stat result = SCPE_OK; | |
const CNTLR_OPCODE opcode = (CNTLR_OPCODE) uptr->OP; | |
switch ((CNTLR_PHASE) uptr->PHASE) { /* dispatch the phase */ | |
case start_phase: | |
switch (opcode) { /* dispatch the current operation */ | |
case recalibrate: | |
case seek: | |
if (start_seek (cvptr, uptr, opcode, end_phase) /* start the seek; if it succeeded, */ | |
&& (cvptr->type == MAC)) /* and this a MAC controller, */ | |
dl_idle_controller (cvptr); /* then go idle until it completes */ | |
break; | |
case cold_load_read: | |
if (start_seek (cvptr, uptr, read, start_phase)) /* start the seek; did it succeed? */ | |
cvptr->file_mask = DL_FSPEN; /* set sparing enabled now */ | |
break; | |
case read: | |
case read_with_offset: | |
case read_without_verify: | |
cvptr->length = DL_WPSEC; /* transfer just the data */ | |
result = start_read (cvptr, uptr); /* start the sector read */ | |
break; | |
case read_full_sector: | |
cvptr->length = DL_WPFSEC; /* transfer the header/data/trailer */ | |
result = start_read (cvptr, uptr); /* start the sector read */ | |
break; | |
case verify: | |
cvptr->length = 0; /* no data transfer needed */ | |
result = start_read (cvptr, uptr); /* start the sector read */ | |
if (uptr->PHASE == data_phase) { /* did the read start successfully? */ | |
uptr->PHASE = end_phase; /* skip the data phase */ | |
uptr->wait = cvptr->sector_time /* reschedule for the intersector time */ | |
+ cvptr->data_time * DL_WPSEC; /* plus the data read time */ | |
} | |
break; | |
case write: | |
case initialize: | |
cvptr->length = DL_WPSEC; /* transfer just the data */ | |
start_write (cvptr, uptr); /* start the sector write */ | |
break; | |
case write_full_sector: | |
cvptr->length = DL_WPFSEC; /* transfer the header/data/trailer */ | |
start_write (cvptr, uptr); /* start the sector write */ | |
break; | |
case request_status: | |
case request_sector_address: | |
case clear: | |
case address_record: | |
case request_syndrome: | |
case set_file_mask: | |
case load_tio_register: | |
case request_disc_address: | |
case end: | |
case wakeup: | |
dl_service_controller (cvptr, uptr); /* the controller service handles these */ | |
break; | |
default: /* we were entered with an invalid state */ | |
result = SCPE_IERR; /* return an internal (programming) error */ | |
break; | |
} /* end of operation dispatch */ | |
break; /* end of start phase handlers */ | |
case data_phase: | |
switch (opcode) { /* dispatch the current operation */ | |
case read: | |
case read_full_sector: | |
case read_with_offset: | |
case read_without_verify: | |
case write: | |
case write_full_sector: | |
case initialize: | |
break; /* data transfers are handled by the caller */ | |
default: /* entered with an invalid state */ | |
result = SCPE_IERR; /* return an internal (programming) error */ | |
break; | |
} /* end of operation dispatch */ | |
break; /* end of data phase handlers */ | |
case end_phase: | |
switch (opcode) { /* dispatch the operation command */ | |
case recalibrate: | |
case seek: | |
if (cvptr->type == ICD) /* is this an ICD controller? */ | |
dl_end_command (cvptr, drive_attention); /* seeks end with Drive Attention status */ | |
else /* if not an ICD controller, */ | |
uptr->STAT |= DL_S2ATN; /* set Attention in the unit status */ | |
break; | |
case read: | |
case read_full_sector: | |
case read_with_offset: | |
end_read (cvptr, uptr); /* end the sector read */ | |
break; | |
case read_without_verify: | |
if (cvptr->sector == 0) /* have we reached the end of the track? */ | |
uptr->OP = read; /* begin verifying the next time */ | |
end_read (cvptr, uptr); /* end the sector read */ | |
break; | |
case verify: | |
cvptr->verify_count = /* decrement the count */ | |
(cvptr->verify_count - 1) & DMASK; /* modulo 65536 */ | |
if (cvptr->verify_count == 0) /* are there more sectors to verify? */ | |
cvptr->eod = SET; /* no, so terminate the command cleanly */ | |
end_read (cvptr, uptr); /* end the sector read */ | |
break; | |
case write: | |
case write_full_sector: | |
case initialize: | |
result = end_write (cvptr, uptr); /* end the sector write */ | |
break; | |
case request_status: | |
case request_sector_address: | |
case request_disc_address: | |
dl_service_controller (cvptr, uptr); /* the controller service handles these */ | |
break; | |
default: /* we were entered with an invalid state */ | |
result = SCPE_IERR; /* return an internal (programming) error */ | |
break; | |
} /* end of operation dispatch */ | |
break; /* end of end phase handlers */ | |
} /* end of phase dispatch */ | |
return result; /* return the result of the service */ | |
} | |
/* Service the controller unit. | |
The controller service routine is called to execute scheduled controller | |
commands that do not access drive units. It is also called to obtain command | |
parameters from the interface and to return command result values to the | |
interface. The actions to be taken depend on the current state of the | |
controller. | |
Controller commands are scheduled on a separate unit to allow concurrent | |
processing while seeks are in progress. For example, a seek may be started | |
on unit 0. While the seek is in progress, the CPU may request status from | |
the controller. In between returning the first and second status words to | |
the CPU, the seek may complete. Separating the controller unit allows seek | |
completion to be handled while the controller is "busy" waiting for the CPU | |
to indicate that it is ready for the second word. | |
For ICD controllers, the controller unit is not used, and all commands are | |
scheduled on the drive unit. This is possible because ICD controllers always | |
wait for seeks to complete before executing additional commands. To reduce | |
code duplication, however, the drive unit service calls the controller | |
service directly to handle controller commands. | |
The service routine validates phase assignments and returns SCPE_IERR | |
(Internal Error) if entry is made with an illegal operation phase or a phase | |
that is not valid for a given operation. | |
Implementation notes: | |
1. While the interface simulator is responsible for data phase transfers, | |
the controller service routine is responsible for (re)starting and | |
stopping the command wait timer for each parameter sent to and received | |
from the interface. | |
*/ | |
t_stat dl_service_controller (CVPTR cvptr, UNIT *uptr) | |
{ | |
t_stat result = SCPE_OK; | |
const CNTLR_OPCODE opcode = (CNTLR_OPCODE) uptr->OP; | |
switch ((CNTLR_PHASE) uptr->PHASE) { /* dispatch the phase */ | |
case start_phase: | |
case end_phase: | |
switch (opcode) { /* dispatch the current operation */ | |
case request_status: | |
dl_end_command (cvptr, cvptr->status); /* the command completes with no status change */ | |
break; | |
case clear: | |
dl_clear_controller (cvptr, uptr, soft_clear); /* clear the controller */ | |
dl_end_command (cvptr, normal_completion); /* the command is complete */ | |
break; | |
case request_sector_address: | |
case address_record: | |
case request_syndrome: | |
case set_file_mask: | |
case load_tio_register: | |
case request_disc_address: | |
dl_end_command (cvptr, normal_completion); /* the command is complete */ | |
break; | |
case end: | |
dl_idle_controller (cvptr); /* the command completes with the controller idle */ | |
break; | |
case wakeup: | |
dl_end_command (cvptr, unit_available); /* the command completes with Unit Available status */ | |
break; | |
default: /* we were entered with an invalid state */ | |
result = SCPE_IERR; /* return an internal (programming) error */ | |
break; | |
} /* end of operation dispatch */ | |
break; /* end of start and end phase handlers */ | |
case data_phase: | |
switch (opcode) { /* dispatch the current operation */ | |
case seek: | |
case verify: | |
case address_record: | |
case read_with_offset: | |
case load_tio_register: | |
if (cvptr->length > 1) /* at least one more parameter to input? */ | |
set_timer (cvptr, SET); /* restart the timer for the next parameter */ | |
else /* this is the last one */ | |
set_timer (cvptr, CLEAR); /* so stop the command wait timer */ | |
break; | |
case request_status: | |
case request_sector_address: | |
case request_syndrome: | |
case request_disc_address: | |
if (cvptr->length > 0) /* at least one more to parameter output? */ | |
set_timer (cvptr, SET); /* restart the timer for the next parameter */ | |
else /* this is the last one */ | |
set_timer (cvptr, CLEAR); /* so stop the command wait timer */ | |
break; | |
default: /* we were entered with an invalid state */ | |
result = SCPE_IERR; /* return an internal (programming) error */ | |
break; | |
} /* end of operation dispatch */ | |
break; /* end of data phase handlers */ | |
} /* end of phase dispatch */ | |
return result; /* return the result of the service */ | |
} | |
/* Service the command wait timer unit. | |
The command wait timer service routine is called if the command wait timer | |
expires. This indicates that the CPU did not respond to a parameter transfer | |
or did not issue a new command within the ~1.8 second timeout period. The | |
timer is used with the MAC controller to ensure that a hung CPU does not tie | |
up the controller, preventing it from servicing other CPUs or drives. ICD | |
controllers do not use the command wait timer; they will wait forever, as | |
each controller is dedicated to a single interface. | |
When a timeout occurs, the controller unit is cancelled in case the cause was | |
a parameter timeout. Then the file mask is reset, and the controller is | |
idled. | |
The interface is responsible for polling for a new command and for drive | |
attention when a timeout occurs. | |
Implementation notes: | |
1. Only the controller unit may be active when the command wait timer | |
expires. A unit is never active because the timer is cancelled when | |
commands are executing and is restarted after the command completes. | |
*/ | |
t_stat dl_service_timer (CVPTR cvptr, UNIT *uptr) | |
{ | |
sim_cancel (cvptr->aux); /* cancel any controller activation */ | |
dl_idle_controller (cvptr); /* idle the controller */ | |
cvptr->file_mask = 0; /* clear the file mask */ | |
return SCPE_OK; | |
} | |
/* Clear the controller. | |
The controller connected to the specified unit is cleared as directed. A MAC | |
controller is connected to several units, so the unit is used to find the | |
associated device and thereby the unit array. An ICD controller is connected | |
only to the specified unit. | |
In hardware, four conditions clear the 13037 controller: | |
- an initial application of power | |
- an assertion of the CLEAR signal by the CPU interface | |
- a timeout of the command wait timer | |
- a programmed Clear command | |
The first two conditions, called "hard clears," are equivalent and cause a | |
firmware restart with the PWRON flag set. The 13175 interface for the HP | |
1000 asserts the CLEAR signal in response to the backplane CRS signal if the | |
PRESET ENABLE jumper is not installed (which is the usual case). The third | |
condition also causes a firmware restart but with the PWRON flag clear. The | |
last condition is executed in the command handler and therefore returns to | |
the Command Wait Loop instead of the Poll Loop. | |
For a hard clear, the 13037 controller will: | |
- disconnect the CPU interface | |
- zero the controller RAM (no drives held, last polled unit number reset) | |
- issue a Controller Preset to clear all connected drives | |
- clear the clock offset | |
- clear the file mask | |
- enter the Poll Loop (which clears the controller status) | |
For a timeout clear, the 13037 controller will: | |
- disconnect the CPU interface | |
- clear the hold bits of any drives held by the interface that timed out | |
- clear the clock offset | |
- clear the file mask | |
- enter the Poll Loop (which clears the controller status) | |
For a programmed "soft" clear, the 13037 controller will: | |
- clear the controller status | |
- issue a Controller Preset to clear all connected drives | |
- enter the Command Wait Loop | |
Controller Preset is a tag bus command that is sent to all drives connected | |
to the controller. Each drive will: | |
- disconnect from the controller | |
- clear its internal drive faults | |
- clear its head and sector registers | |
- clear its illegal head and sector flip-flops | |
- reset its seek check, first status, drive fault, and attention status | |
In simulation, a hard clear occurs when a RESET -P or RESET command is | |
issued, or a programmed CLC 0 instruction is executed. A soft clear occurs | |
when a programmed Clear command is started. A timeout clear occurs when the | |
command wait timer unit is serviced, but this action is handled in the timer | |
unit service. | |
Because the controller execution state is implemented by scheduling command | |
phases for the target or controller unit, a simulated firmware restart must | |
abort any in-process activation. However, a firmware restart does not affect | |
seeks in progress, so these must be allowed to continue to completion so that | |
their Attention requests will be honored. | |
Implementation notes: | |
1. The specific 13365 controller actions on hard or soft clears are not | |
documented. Therefore, an ICD controller clear is handled as a MAC | |
controller clear, except that only the current drive is preset (as an ICD | |
controller manages only a single drive). | |
2. Neither hard nor soft clears affect the controller flags (e.g., EOC) or | |
registers (e.g., cylinder address). | |
3. In simulation, an internal seek, such as an auto-seek during a Read | |
command or the initial seek during a Cold Load Read command, will be | |
aborted for a hard or timeout clear, whereas in hardware it would | |
complete normally. This is OK, however, because an internal seek always | |
clears the drive's Attention status on completion, so aborting the | |
simulated seek is equivalent to an immediate seek completion. | |
4. In simulation, a Controller Preset only resets the specified status bits, | |
as the remainder of the hardware actions are not implemented. | |
*/ | |
t_stat dl_clear_controller (CVPTR cvptr, UNIT *uptr, CNTLR_CLEAR clear_type) | |
{ | |
uint32 unit, unit_count; | |
DEVICE *dptr = NULL; | |
if (clear_type == hard_clear) { /* is this a hard clear? */ | |
dl_idle_controller (cvptr); /* idle the controller */ | |
cvptr->file_mask = 0; /* clear the file mask */ | |
cvptr->poll_unit = 0; /* clear the last unit polled */ | |
} | |
if (cvptr->type == ICD) /* is this an ICD controller? */ | |
unit_count = 1; /* there is only one unit per controller */ | |
else { /* a MAC controller clears all units */ | |
dptr = find_dev_from_unit (uptr); /* find the associated device */ | |
if (dptr == NULL) /* the device doesn't exist?!? */ | |
return SCPE_IERR; /* this is an impossible condition! */ | |
else /* the device was found */ | |
unit_count = dptr->numunits; /* so get the number of units */ | |
} | |
for (unit = 0; unit < unit_count; unit++) { /* loop through the unit(s) */ | |
if (dptr) /* pick up the unit from the device? */ | |
uptr = dptr->units + unit; /* yes, so get the next unit */ | |
if (!(uptr->flags & UNIT_DIS)) { /* is the unit enabled? */ | |
if (clear_type == hard_clear /* a hard clear cancels */ | |
&& uptr->OP != seek /* only if not seeking */ | |
&& uptr->OP != recalibrate) /* or recalibrating */ | |
sim_cancel (uptr); /* cancel the service */ | |
uptr->STAT &= ~DL_S2CPS; /* do "Controller Preset" for the unit */ | |
} | |
} | |
return SCPE_OK; | |
} | |
/* Idle the controller. | |
The command wait timer is turned off, the status is reset, and the controller | |
is returned to the idle state (Poll Loop). | |
*/ | |
void dl_idle_controller (CVPTR cvptr) | |
{ | |
cvptr->state = cntlr_idle; /* idle the controller */ | |
cvptr->status = normal_completion; /* the Poll Loop clears the status */ | |
set_timer (cvptr, CLEAR); /* stop the command wait timer */ | |
return; | |
} | |
/* Load or unload the drive heads. | |
In hardware, a drive's heads are loaded when a disc pack is installed and the | |
RUN/STOP switch is set to RUN. The drive reports First Status when the heads | |
load to indicate that the pack has potentially changed. Setting the switch | |
to STOP unloads the heads. When the heads are unloaded, the drive reports | |
Not Ready and Drive Busy status. | |
In simulation, the unit must be attached before the heads may be unloaded or | |
loaded. As the heads should be automatically loaded when a unit is attached | |
and unloaded when a unit is detached, this routine must be called after | |
attaching and before detaching. | |
Implementation notes: | |
1. The drive sets its Attention status bit when the heads load or unload. | |
However, the ICD controller reports Attention only for head unloading. | |
2. Loading or unloading the heads clears Fault and Seek Check status. | |
3. If we are called during a RESTORE command, the unit's flags are not | |
changed to avoid upsetting the state that was SAVEd. | |
*/ | |
t_stat dl_load_unload (CVPTR cvptr, UNIT *uptr, t_bool load) | |
{ | |
if ((uptr->flags & UNIT_ATT) == 0) /* the unit must be attached to [un]load */ | |
return SCPE_UNATT; /* return "Unit not attached" if not */ | |
else if (!(sim_switches & SIM_SW_REST)) /* modify the flags only if not restoring */ | |
if (load) { /* are we loading the heads? */ | |
uptr->flags = uptr->flags & ~UNIT_UNLOAD; /* clear the unload flag */ | |
uptr->STAT = DL_S2FS; /* and set First Status */ | |
if (cvptr->type != ICD) /* if this is not an ICD controller */ | |
uptr->STAT |= DL_S2ATN; /* set Attention status also */ | |
} | |
else { /* we are unloading the heads */ | |
uptr->flags = uptr->flags | UNIT_UNLOAD; /* set the unload flag */ | |
uptr->STAT = DL_S2ATN; /* and Attention status */ | |
} | |
return SCPE_OK; | |
} | |
/* Disc library global utility routines */ | |
/* Classify the current controller opcode. | |
The controller opcode is classified as a read, write, control, or status | |
command, and the classification is returned to the caller. If the opcode is | |
illegal or undefined for the indicated controller, the classification is | |
marked as invalid. | |
*/ | |
CNTLR_CLASS dl_classify (CNTLR_VARS cntlr) | |
{ | |
if (cntlr.type <= last_type /* if the controller type is legal */ | |
&& cntlr.opcode <= last_opcode /* and the opcode is legal */ | |
&& cmd_props [cntlr.opcode].valid [cntlr.type]) /* and is defined for this controller, */ | |
return cmd_props [cntlr.opcode].classification; /* then return the command classification */ | |
else /* the type or opcode is illegal */ | |
return class_invalid; /* so return an invalid classification */ | |
} | |
/* Return the name of an opcode. | |
A string representing the supplied controller opcode is returned to the | |
caller. If the opcode is illegal or undefined for the indicated controller, | |
the string "invalid" is returned. | |
*/ | |
const char *dl_opcode_name (CNTLR_TYPE controller, CNTLR_OPCODE opcode) | |
{ | |
if (controller <= last_type /* if the controller type is legal */ | |
&& opcode <= last_opcode /* and the opcode is legal */ | |
&& cmd_props [opcode].valid [controller]) /* and is defined for this controller, */ | |
return opcode_name [opcode]; /* then return the opcode name */ | |
else /* the type or opcode is illegal, */ | |
return invalid_name; /* so return an error indication */ | |
} | |
/* Return the name of a command phase. | |
A string representing the supplied phase is returned to the caller. If the | |
phase is illegal, the string "invalid" is returned. | |
*/ | |
const char *dl_phase_name (CNTLR_PHASE phase) | |
{ | |
if (phase <= last_phase) /* if the phase is legal, */ | |
return phase_name [phase]; /* return the phase name */ | |
else /* the phase is illegal, */ | |
return invalid_name; /* so return an error indication */ | |
} | |
/* Disc library global VM routines */ | |
/* Attach a disc image file to a unit. | |
The file specified by the supplied filename is attached to the indicated | |
unit. If the attach was successful, the heads are loaded on the drive. | |
If the drive is set to autosize, the size of the image file is compared to | |
the table of drive capacities to determine which model of drive was used to | |
create it. If the image file is new, then the previous drive model is | |
retained. | |
*/ | |
t_stat dl_attach (CVPTR cvptr, UNIT *uptr, char *cptr) | |
{ | |
uint32 id, size; | |
t_stat result; | |
result = attach_unit (uptr, cptr); /* attach the unit */ | |
if (result != SCPE_OK) /* did the attach fail? */ | |
return result; /* yes, so return the error status */ | |
dl_load_unload (cvptr, uptr, TRUE); /* if the attach succeeded, load the heads */ | |
if (uptr->flags & UNIT_AUTO) { /* is autosizing enabled? */ | |
size = sim_fsize (uptr->fileref) / sizeof (uint16); /* get the file size in words */ | |
if (size > 0) /* a new file retains the current drive model */ | |
for (id = 0; id < PROPS_COUNT; id++) /* find the best fit to the drive models */ | |
if (size <= drive_props [id].words /* if the file size fits the drive capacity */ | |
|| id == PROPS_COUNT - 1) { /* or this is the largest available drive */ | |
uptr->capac = drive_props [id].words; /* then set the capacity */ | |
uptr->flags = (uptr->flags & ~UNIT_MODEL) /* and the model */ | |
| SET_MODEL (id); | |
break; | |
} | |
} | |
return SCPE_OK; /* the unit was successfully attached */ | |
} | |
/* Detach a disc image file from a unit. | |
The heads are unloaded on the drive, and the attached file, if any, is | |
detached. | |
*/ | |
t_stat dl_detach (CVPTR cvptr, UNIT *uptr) | |
{ | |
dl_load_unload (cvptr, uptr, FALSE); /* unload the heads if attached */ | |
return detach_unit (uptr); /* and detach the unit */ | |
} | |
/* Set the drive model. | |
This validation routine is called to set the model of disc drive associated | |
with the specified unit. The "value" parameter indicates the model ID, and | |
the unit capacity is set to the size indicated. | |
*/ | |
t_stat dl_set_model (UNIT *uptr, int32 value, char *cptr, void *desc) | |
{ | |
if (uptr->flags & UNIT_ATT) /* we cannot alter the disc model */ | |
return SCPE_ALATT; /* if the unit is attached */ | |
if (value != UNIT_AUTO) /* if we are not autosizing */ | |
uptr->capac = drive_props [GET_MODEL (value)].words; /* set the capacity to the new value */ | |
return SCPE_OK; | |
} | |
/* Disc library local controller routines */ | |
/* Start a read operation on the current sector. | |
The current sector indicated by the controller address is read from the disc | |
image file into the sector buffer in preparation for data transfer to the | |
CPU. If the end of the track had been reached, and the file mask permits, | |
an auto-seek is scheduled instead to allow the read to continue. | |
On entry, the end-of-data flag is checked. If it is set, the current read is | |
completed. Otherwise, the buffer data offset and verify options are set up. | |
For a Read Full Sector, the sync word is set from the controller type, and | |
dummy cylinder and head-sector words are generated from the current location | |
(as would be the case in the absence of track sparing). | |
The image file is positioned to the correct sector in preparation for | |
reading. If the positioning requires a permitted seek, it is scheduled, and | |
the routine returns with the operation phase unchanged to wait for seek | |
completion before resuming the read (when the seek completes, the service | |
routine will be entered, and we will be called again; this time, the | |
end-of-cylinder flag will be clear and positioning will succeed). If | |
positioning resulted in an error, the current read is terminated with the | |
error status set. | |
If positioning succeeded within the same cylinder, the sector image is read | |
into the buffer at an offset determined by the operation (Read Full Sector | |
leaves room at the start of the buffer for the sector header). If the image | |
file read did not return a full sector, the remainder of the buffer is padded | |
with zeros. If the image read failed with a file system error, SCPE_IOERR is | |
returned from the service routine to cause a simulation stop; resumption is | |
handled as an Uncorrectable Data Error. | |
If the image was read correctly, the next sector address is updated, the | |
operation phase is set for the data transfer, and the index of the first word | |
to transfer is set. | |
Implementation notes: | |
1. The length of the transfer required (cvptr->length) must be set before | |
entry. | |
2. Entry while executing a Read Without Verify or Read Full Sector command | |
inhibits address verification. The unit opcode is tested instead of the | |
controller opcode because a Read Without Verify is changed to a Read to | |
begin verifying after a track switch occurs. | |
*/ | |
static t_stat start_read (CVPTR cvptr, UNIT *uptr) | |
{ | |
uint32 count, offset; | |
t_bool verify; | |
const CNTLR_OPCODE opcode = (CNTLR_OPCODE) uptr->OP; | |
if (cvptr->eod == SET) { /* is the end of data indicated? */ | |
dl_end_command (cvptr, normal_completion); /* complete the command */ | |
return SCPE_OK; | |
} | |
if (opcode == read_full_sector) { /* are we starting a Read Full Sector command? */ | |
if (cvptr->type == ICD) /* is this an ICD controller? */ | |
cvptr->buffer [0] = 0100377; /* ICD does not support ECC */ | |
else | |
cvptr->buffer [0] = 0100376; /* MAC does support ECC */ | |
set_address (cvptr, 1); /* set the current address into buffer 1-2 */ | |
offset = 3; /* start the data after the header */ | |
verify = FALSE; /* set for no address verification */ | |
} | |
else { /* it's another read command */ | |
offset = 0; /* data starts at the beginning */ | |
verify = (opcode != read_without_verify); /* set for address verification unless it's a RWV */ | |
} | |
if (! position_sector (cvptr, uptr, verify)) /* position the sector */ | |
return SCPE_OK; /* a seek is in progress or an error occurred */ | |
count = sim_fread (cvptr->buffer + offset, /* read the sector from the image */ | |
sizeof (uint16), DL_WPSEC, /* into the sector buffer */ | |
uptr->fileref); | |
for (count = count + offset; count < cvptr->length; count++) /* pad the sector as needed */ | |
cvptr->buffer [count] = 0; /* e.g., if reading from a new file */ | |
if (ferror (uptr->fileref)) /* did a host file system error occur? */ | |
return io_error (cvptr, uptr); /* set up the data error status and stop the simulation */ | |
next_sector (cvptr, uptr); /* address the next sector */ | |
uptr->PHASE = data_phase; /* set up the data transfer phase */ | |
cvptr->index = 0; /* reset the data index */ | |
return SCPE_OK; /* the read was successfully started */ | |
} | |
/* Finish a read operation on the current sector. | |
On entry, the end-of-data flag is checked. If it is set, the current read is | |
completed. Otherwise, the command phase is reset to start the next sector, | |
and the disc service is set to allow for the intersector delay. | |
Implementation notes: | |
1. The CPU indicates the end of a read data transfer to an ICD controller by | |
untalking the drive. The untalk is done by the driver as soon as the | |
DCPC completion interrupt is processed. However, the time from the final | |
DCPC transfer through driver entry to the point where the untalk is | |
asserted on the bus varies from 80 instructions (RTE-6/VM with OS | |
microcode and the buffer in the system map) to 152 instructions (RTE-IVB | |
with the buffer in the user map). The untalk must occur before the start | |
of the next sector, or the drive will begin the data transfer. | |
Normally, this is not a problem, as the driver clears the FIFO of any | |
received data after DCPC completion. However, if the read terminates | |
after the last sector of a track, and accessing the next sector would | |
require an intervening seek, and the file mask disables auto-seeking or | |
an enabled seek would move the positioner beyond the drive limits, then | |
the controller will indicate an End of Cylinder error if the untalk does | |
not arrive before the seek is initiated. | |
The RTE driver (DVA32) and various utilities that manage the disc | |
directly (e.g., SWTCH) do not appear to account for these bogus errors, | |
so the ICD controller hardware must avoid them in some unknown manner. | |
We work around the issue by extending the intersector delay to allow time | |
for a potential untalk whenever the next access would otherwise fail. | |
Note that this issue does not occur with writes because DCPC completion | |
asserts EOI concurrently with the final data byte to terminate the | |
command. | |
*/ | |
static void end_read (CVPTR cvptr, UNIT *uptr) | |
{ | |
uint32 limit; | |
if (cvptr->eod == SET) /* is the end of data indicated? */ | |
dl_end_command (cvptr, normal_completion); /* complete the command */ | |
else { /* reading continues */ | |
uptr->PHASE = start_phase; /* reset to the start phase */ | |
uptr->wait = cvptr->sector_time; /* delay for the intersector time */ | |
if (cvptr->eoc == SET && cvptr->type == ICD) { /* seek will be required and controller is ICD? */ | |
if (!(cvptr->file_mask & DL_FAUTSK)) /* if auto-seek is disabled */ | |
limit = cvptr->cylinder; /* then the limit is the current cylinder */ | |
else if (cvptr->file_mask & DL_FDECR) /* else if enabled and decremental seek */ | |
limit = 0; /* then the limit is cylinder 0 */ | |
else /* else the enabled limit is the last cylinder */ | |
limit = drive_props [GET_MODEL (uptr->flags)].cylinders; | |
if (cvptr->cylinder == limit) /* is positioner at the limit? */ | |
uptr->wait = cvptr->eot_time; /* seek will fail; delay to allow CPU to untalk */ | |
} | |
} | |
return; | |
} | |
/* Start a write operation on the current sector. | |
The current sector indicated by the controller address is positioned for | |
writing from the sector buffer to the disc image file after data transfer | |
from the CPU. If the end of the track had been reached, and the file mask | |
permits, an auto-seek is scheduled instead to allow the write to continue. | |
On entry, if writing is not permitted, or formatting is required but not | |
enabled, the command is terminated with an error. Otherwise, the disc image | |
file is positioned to the correct sector in preparation for writing. | |
If the positioning requires a permitted seek, it is scheduled, and the | |
routine returns with the operation phase unchanged to wait for seek | |
completion before resuming the write (when the seek completes, the service | |
routine will be entered, and we will be called again; this time, the | |
end-of-cylinder flag will be clear and positioning will succeed). If | |
positioning resulted in an error, the current write is terminated with the | |
error status set. | |
If positioning succeeded within the same cylinder, the operation phase is set | |
for the data transfer, and the index of the first word to transfer is set. | |
Implementation notes: | |
1. Entry while executing a Write Full Sector or Initialize command inhibits | |
address verification. In addition, the drive's FORMAT switch must be set | |
to the enabled position for these commands to succeed. | |
*/ | |
static void start_write (CVPTR cvptr, UNIT *uptr) | |
{ | |
const t_bool verify = (CNTLR_OPCODE) uptr->OP == write; /* only Write verifies the sector address */ | |
if ((uptr->flags & UNIT_WPROT) /* is the unit write protected, */ | |
|| !verify && !(uptr->flags & UNIT_FMT)) /* or is formatting required but not enabled? */ | |
dl_end_command (cvptr, status_2_error); /* terminate the write with an error */ | |
else if (position_sector (cvptr, uptr, verify)) { /* writing is permitted; position the sector */ | |
uptr->PHASE = data_phase; /* positioning succeeded; set up data transfer phase */ | |
cvptr->index = 0; /* reset the data index */ | |
} | |
return; | |
} | |
/* Finish a write operation on the current sector. | |
The current sector is written from the sector buffer to the disc image file | |
at the current file position. The next sector address is then updated to | |
allow writing to continue. | |
On entry, the drive is checked to ensure that it is ready for the write. | |
Then the sector buffer is padded appropriately if a full sector of data was | |
not transferred. The buffer is written to the disc image file at the | |
position corresponding to the controller address as set when the sector was | |
started. The write begins at a buffer offset determined by the command (a | |
Write Full Sector has header words at the start of the buffer that are not | |
written to the disc image). | |
If the image write failed with a file system error, SCPE_IOERR is returned | |
from the service routine to cause a simulation stop; resumption is handled as | |
an Uncorrectable Data Error. If the image was written correctly, the next | |
sector address is updated. If the end-of-data flag is set, the current write | |
is completed. Otherwise, the command phase is reset to start the next | |
sector, and the disc service is scheduled to allow for the intersector delay. | |
Implementation notes: | |
1. A partial sector is filled with 177777B words (ICD) or copies of the last | |
word (MAC) per page 7-10 of the ICD/MAC Disc Diagnostic manual. | |
*/ | |
static t_stat end_write (CVPTR cvptr, UNIT *uptr) | |
{ | |
uint32 count; | |
uint16 pad; | |
const CNTLR_OPCODE opcode = (CNTLR_OPCODE) uptr->OP; | |
const uint32 offset = (opcode == write_full_sector ? 3 : 0); | |
if (uptr->flags & UNIT_UNLOAD) { /* if the drive is not ready, */ | |
dl_end_command (cvptr, access_not_ready); /* terminate the command with an error */ | |
return SCPE_OK; | |
} | |
if (cvptr->index < DL_WPSEC + offset) { /* was a partial sector transferred? */ | |
if (cvptr->type == ICD) /* an ICD controller */ | |
pad = DMASK; /* pads the sector with -1 */ | |
else /* a MAC controller */ | |
pad = cvptr->buffer [cvptr->index - 1]; /* pads with the last word written */ | |
for (count = cvptr->index; count < DL_WPSEC + offset; count++) | |
cvptr->buffer [count] = pad; /* pad the sector buffer as needed */ | |
} | |
sim_fwrite (cvptr->buffer + offset, sizeof (uint16), /* write the sector to the file */ | |
DL_WPSEC, uptr->fileref); | |
if (ferror (uptr->fileref)) /* did a host file system error occur? */ | |
return io_error (cvptr, uptr); /* set up the data error status and stop the simulation */ | |
next_sector (cvptr, uptr); /* address the next sector */ | |
if (cvptr->eod == SET) /* is the end of data indicated? */ | |
dl_end_command (cvptr, normal_completion); /* complete the command */ | |
else { /* writing continues */ | |
uptr->PHASE = start_phase; /* reset to the start phase */ | |
uptr->wait = cvptr->sector_time; /* delay for the intersector time */ | |
} | |
return SCPE_OK; | |
} | |
/* Position the disc image file at the current sector. | |
The image file is positioned at the byte address corresponding to the drive's | |
current cylinder and the controller's current head and sector addresses. | |
Positioning may involve an auto-seek if a prior read or write addressed the | |
final sector of a cylinder. If a seek is initiated or an error is detected, | |
the routine returns FALSE to indicate that the positioning was not performed. | |
If the file was positioned, the routine returns TRUE. | |
On entry, if the controller's end-of-cylinder flag is set, a prior read or | |
write addressed the final sector in the current cylinder. If the file mask | |
does not permit auto-seeking, the current command is terminated with an End | |
of Cylinder error. Otherwise, the cylinder is incremented or decremented as | |
directed by the file mask, and a seek to the new cylinder is started. | |
If the increment or decrement resulted in an out-of-bounds value, the seek | |
will return Seek Check status, and the command is terminated with an error. | |
If the seek is legal, the routine returns with the disc service scheduled for | |
seek completion and the command state unchanged. When the service is | |
reentered, the read or write will continue on the new cylinder. | |
If the EOC flag was not set, the drive's position is checked against the | |
controller's position if address verification is requested. If they are | |
different (as may occur with an Address Record command that specified a | |
different location than the last Seek command), a seek is started to the | |
correct cylinder, and the routine returns with the disc service scheduled for | |
seek completion as above. | |
If the drive and controller positions agree or verification is not requested, | |
the CHS addresses are validated against the drive limits. If they are | |
invalid, Seek Check status is set, and the command is terminated with an | |
error. | |
If the addresses are valid, the drive is checked to ensure that it is ready | |
for positioning. If it is, the the byte offset in the image file is | |
calculated from the CHS address, and the file is positioned. The disc | |
service is scheduled to begin the data transfer, and the routine returns TRUE | |
to indicate that the file position was set. | |
Implementation notes: | |
1. The ICD controller returns an End of Cylinder error if an auto-seek | |
results in a position beyond the drive limits. The MAC controller | |
returns a Status-2 error. Both controllers set the Seek Check bit in the | |
drive status word. | |
*/ | |
static t_bool position_sector (CVPTR cvptr, UNIT *uptr, t_bool verify) | |
{ | |
uint32 block; | |
uint32 model = GET_MODEL (uptr->flags); | |
if (cvptr->eoc == SET) /* are we at the end of a cylinder? */ | |
if (cvptr->file_mask & DL_FAUTSK) { /* is an auto-seek allowed? */ | |
if (cvptr->file_mask & DL_FDECR) /* is a decremental seek requested? */ | |
cvptr->cylinder = (cvptr->cylinder - 1) & DMASK; /* decrease the cylinder address with wraparound */ | |
else /* an incremental seek is requested */ | |
cvptr->cylinder = (cvptr->cylinder + 1) & DMASK; /* increase the cylinder address with wraparound */ | |
start_seek (cvptr, uptr, /* start the auto-seek */ | |
(CNTLR_OPCODE) uptr->OP, /* with the current operation */ | |
(CNTLR_PHASE) uptr->PHASE); /* and phase unchanged */ | |
if (uptr->STAT & DL_S2SC) /* did a seek check occur? */ | |
if (cvptr->type == ICD) /* is this ICD controller? */ | |
dl_end_command (cvptr, end_of_cylinder); /* report it as an End of Cylinder error */ | |
else /* it is a MAC controller */ | |
dl_end_command (cvptr, status_2_error); /* report it as a Status-2 error */ | |
} | |
else /* the file mask does not permit an auto-seek */ | |
dl_end_command (cvptr, end_of_cylinder); /* so terminate with an EOC error */ | |
else if (verify && (uint32) uptr->CYL != cvptr->cylinder) { /* is the positioner on the wrong cylinder? */ | |
start_seek (cvptr, uptr, /* start a seek to the correct cylinder */ | |
(CNTLR_OPCODE) uptr->OP, /* with the current operation */ | |
(CNTLR_PHASE) uptr->PHASE); /* and phase unchanged */ | |
if (uptr->STAT & DL_S2SC) /* did a seek check occur? */ | |
dl_end_command (cvptr, status_2_error); /* report a Status-2 error */ | |
} | |
else if (((uint32) uptr->CYL >= drive_props [model].cylinders) /* is the cylinder out of bounds? */ | |
|| (cvptr->head >= drive_props [model].heads) /* or the head? */ | |
|| (cvptr->sector >= drive_props [model].sectors)) { /* or the sector? */ | |
uptr->STAT = uptr->STAT | DL_S2SC; /* set Seek Check status */ | |
dl_end_command (cvptr, status_2_error); /* and terminate with an error */ | |
} | |
else if (uptr->flags & UNIT_UNLOAD) /* is the drive ready for positioning? */ | |
dl_end_command (cvptr, access_not_ready); /* terminate the command with an access error */ | |
else { /* we are ready to position the image file */ | |
block = TO_BLOCK (uptr->CYL, cvptr->head, /* calculate the new block position */ | |
cvptr->sector, model); /* (for inspection only) */ | |
uptr->pos = TO_OFFSET (block); /* and then convert to a byte offset */ | |
sim_fseek (uptr->fileref, uptr->pos, SEEK_SET); /* set the image file position */ | |
uptr->wait = cvptr->data_time; /* delay for the data access time */ | |
return TRUE; /* and report that positioning was accomplished */ | |
} | |
return FALSE; /* report that positioning failed or was deferred */ | |
} | |
/* Address the next sector. | |
The controller's CHS address is incremented to point at the next sector. If | |
the next sector number is valid, the routine returns. Otherwise, the sector | |
number is reset to sector 0. If the file mask is set for cylinder mode, the | |
head is incremented, and if the new head number is valid, the routine | |
returns. If the head number is invalid, it is reset to head 0, and the | |
end-of-cylinder flag is set. The EOC flag is also set if the file mask is | |
set for surface mode. | |
The new cylinder address is not set here, because cylinder validation must | |
only occur when the next sector is actually accessed. Otherwise, reading or | |
writing the last sector on a track or cylinder with auto-seek disabled would | |
cause an End of Cylinder error, even if the transfer ended with that sector. | |
Instead, we set the EOC flag to indicate that a cylinder update is pending. | |
As a result of this deferred update method, the state of the EOC flag must be | |
considered when returning the disc address to the CPU. | |
*/ | |
static void next_sector (CVPTR cvptr, UNIT *uptr) | |
{ | |
const uint32 model = GET_MODEL (uptr->flags); /* get the disc model */ | |
cvptr->sector = cvptr->sector + 1; /* increment the sector number */ | |
if (cvptr->sector < drive_props [model].sectors) /* are we at the end of the track? */ | |
return; /* no, so the next sector value is OK */ | |
cvptr->sector = 0; /* wrap the sector number */ | |
if (cvptr->file_mask & DL_FCYLM) { /* are we in cylinder mode? */ | |
cvptr->head = cvptr->head + 1; /* yes, so increment the head */ | |
if (cvptr->head < drive_props [model].heads) /* are we at the end of the cylinder? */ | |
return; /* no, so the next head value is OK */ | |
cvptr->head = 0; /* wrap the head number */ | |
} | |
cvptr->eoc = SET; /* set the end-of-cylinder flag to */ | |
return; /* indicate that an update is required */ | |
} | |
/* Start a seek. | |
A seek is initiated on the indicated unit if the drive is ready and the | |
cylinder, head, and sector values in the controller are valid for the current | |
drive model. If the current operation is a recalibrate, a seek is initiated | |
to cylinder 0 instead of the cylinder value stored in the controller. The | |
routine returns TRUE if the drive was ready for the seek and FALSE if it was | |
not. | |
If the controller cylinder is beyond the drive's limit, Seek Check status is | |
set in the unit, and the heads are not moved. Otherwise, the relative | |
cylinder position change is calculated, and the heads are moved to the new | |
position. | |
If the controller head or sector is beyond the drive's limit, Seek Check | |
status is set in the unit. Otherwise, Seek Check status is cleared, and the | |
new file offset is calculated. | |
A seek check terminates the current command for an ICD controller. For a MAC | |
controller, the seek check is noted in the drive status, but processing will | |
continue until the drive sets Attention status. | |
Finally, the drive operation and phase are set to the supplied values before | |
returning. | |
Implementation notes: | |
1. EOC is not reset for recalibrate so that a reseek will return to the same | |
location as was current when the recalibrate was done. | |
2. Calculation of the file offset is performed here simply to keep the unit | |
position register available for inspection. The actual file positioning | |
is done in position_sector. | |
3. In hardware, a seek to the current location will set Drive Busy status | |
for 1.3 milliseconds (the head settling time). In simulation, disc | |
service is scheduled as though a one-cylinder seek was requested. | |
*/ | |
static t_bool start_seek (CVPTR cvptr, UNIT *uptr, CNTLR_OPCODE next_opcode, CNTLR_PHASE next_phase) | |
{ | |
int32 delta; | |
uint32 block, target_cylinder; | |
const uint32 model = GET_MODEL (uptr->flags); /* get the drive model */ | |
if (uptr->flags & UNIT_UNLOAD) { /* are the heads unloaded? */ | |
dl_end_command (cvptr, status_2_error); /* the seek ends with Status-2 error */ | |
return FALSE; /* as the drive was not ready */ | |
} | |
if ((CNTLR_OPCODE) uptr->OP == recalibrate) /* is the unit recalibrating? */ | |
target_cylinder = 0; /* seek to cylinder 0 and don't reset the EOC flag */ | |
else { /* it's a Seek command or an auto-seek request */ | |
target_cylinder = cvptr->cylinder; /* seek to the controller cylinder */ | |
cvptr->eoc = CLEAR; /* clear the end-of-cylinder flag */ | |
} | |
if (target_cylinder >= drive_props [model].cylinders) { /* is the cylinder out of bounds? */ | |
delta = 0; /* don't change the positioner */ | |
uptr->STAT = uptr->STAT | DL_S2SC; /* and set Seek Check status */ | |
} | |
else { /* the cylinder value is OK */ | |
delta = abs (uptr->CYL - target_cylinder); /* calculate the relative movement */ | |
uptr->CYL = target_cylinder; /* and move the positioner */ | |
if ((cvptr->head >= drive_props [model].heads) /* if the head */ | |
|| (cvptr->sector >= drive_props [model].sectors)) /* or the sector is out of bounds, */ | |
uptr->STAT = uptr->STAT | DL_S2SC; /* set Seek Check status */ | |
else { /* the head and sector are OK */ | |
uptr->STAT = uptr->STAT & ~DL_S2SC; /* clear Seek Check status */ | |
block = TO_BLOCK (uptr->CYL, cvptr->head, /* set up the new block position */ | |
cvptr->sector, model); /* (for inspection only) */ | |
uptr->pos = TO_OFFSET (block); /* and then convert to a byte offset */ | |
} | |
} | |
if ((uptr->STAT & DL_S2SC) && cvptr->type == ICD) /* did a Seek Check occur for an ICD controller? */ | |
dl_end_command (cvptr, status_2_error); /* the command ends with a Status-2 error */ | |
else { /* the seek was OK or this is a MAC controller */ | |
if (delta == 0) /* if the seek is to the same cylinder, */ | |
delta = 1; /* then schedule as a one-cylinder seek */ | |
uptr->wait = cvptr->seek_time * delta; /* the seek delay is based on the relative movement */ | |
} | |
uptr->OP = next_opcode; /* set the next operation */ | |
uptr->PHASE = next_phase; /* and command phase */ | |
return TRUE; /* and report that the drive was ready */ | |
} | |
/* Report an I/O error. | |
Errors indicated by the host file system are reported to the console, and | |
simulation is stopped with an "I/O error" message. If the simulation is | |
continued, the CPU will receive an Uncorrectable Data Error indication from | |
the controller. | |
*/ | |
static t_stat io_error (CVPTR cvptr, UNIT *uptr) | |
{ | |
dl_end_command (cvptr, uncorrectable_data_error); /* terminate the command with an error */ | |
perror ("DiscLib I/O error"); /* report the error to the console */ | |
clearerr (uptr->fileref); /* and clear the error in case we resume */ | |
return SCPE_IOERR; /* return an I/O error to stop the simulator */ | |
} | |
/* Disc library local utility routines */ | |
/* Set the current controller address into the buffer. | |
The controller's current cylinder, head, and sector are packed into two words | |
and stored in the sector buffer, starting at the index specified. If the | |
end-of-cylinder flag is set, the cylinder is incremented to reflect the | |
auto-seek that will be attempted when the next sequential access is made. | |
Implementation notes: | |
1. The 13037 firmware always increments the cylinder number if the EOC flag | |
is set, rather than checking cylinder increment/decrement bit in the file | |
mask. | |
*/ | |
static void set_address (CVPTR cvptr, uint32 index) | |
{ | |
cvptr->buffer [index] = cvptr->cylinder + (cvptr->eoc == SET ? 1 : 0); /* update the cylinder if EOC is set */ | |
cvptr->buffer [index + 1] = SET_HEAD (cvptr) | SET_SECTOR (cvptr); /* merge the head and sector */ | |
return; | |
} | |
/* Start or stop the command wait timer. | |
A MAC controller uses a 1.8 second timer to ensure that it does not wait | |
forever for a non-responding disc drive or CPU interface. In simulation, MAC | |
interfaces supply an auxiliary timer unit that is activated when the command | |
wait timer is started and cancelled when the timer is stopped. | |
ICD interfaces do not use the command wait timer or supply an auxiliary unit. | |
Implementation notes: | |
1. Absolute activation is used because the timer is restarted between | |
parameter word transfers. | |
*/ | |
static void set_timer (CVPTR cvptr, FLIP_FLOP action) | |
{ | |
if (cvptr->type == MAC) /* is this a MAC controller? */ | |
if (action == SET) /* should we start the timer? */ | |
sim_activate_abs (cvptr->aux + timer, /* activate the auxiliary unit */ | |
cvptr->wait_time); | |
else /* we stop the timer */ | |
sim_cancel (cvptr->aux + timer); /* by canceling the unit */ | |
return; | |
} | |
/* Return the drive status (status word 2). | |
In hardware, the controller outputs the Address Unit command on the drive tag | |
bus and the unit number on the drive control bus. The addressed drive then | |
responds by setting its internal "selected" flag. The controller then | |
outputs the Request Status command on the tag bug, and the selected drive | |
returns its status on the control bus. If a drive is selected but the heads | |
are unloaded, the drive returns Not Ready and Busy status. If no drive is | |
selected, the control bus floats inactive. This is interpreted by the | |
controller as Not Ready status (because the drive returns an inactive Ready | |
status). | |
In simulation, an enabled but detached unit corresponds to "selected but | |
heads unloaded," and a disabled unit corresponds to a non-existent unit. | |
Implementation notes: | |
1. The Attention, Drive Fault, First Status, and Seek Check bits are stored | |
in the unit status word. The other status bits are determined | |
dynamically. | |
2. The Drive Busy bit is set if the unit service is scheduled. In hardware, | |
this bit indicates that the heads are not positioned over a track, i.e., | |
that a seek is in progress. In simulation, the only time a Request | |
Status command is allowed is either when the controller is waiting for | |
seek completion or for a new command. In the latter case, unit service | |
will not be scheduled, so activation can only be for seek completion. | |
*/ | |
static uint16 drive_status (UNIT *uptr) | |
{ | |
uint16 status; | |
uint32 model; | |
if (uptr == NULL) /* if the unit is invalid */ | |
return DL_S2ERR | DL_S2NR; /* then it does not respond */ | |
model = GET_MODEL (uptr->flags); /* get the drive model */ | |
status = drive_props [model].type | uptr->STAT; /* start with the drive type and unit status */ | |
if (uptr->flags & UNIT_WPROT) /* is the write protect switch set? */ | |
status |= DL_S2RO; /* set the Protected status bit */ | |
if (uptr->flags & UNIT_FMT) /* is the format switch enabled? */ | |
status |= DL_S2FMT; /* set the Format status bit */ | |
if (uptr->flags & UNIT_DIS) /* is the unit non-existent? */ | |
status |= DL_S2NR; /* set the Not Ready bit */ | |
else if (uptr->flags & UNIT_UNLOAD) /* are the heads unloaded? */ | |
status |= DL_S2NR | DL_S2BUSY; /* set the Not Ready and Drive Busy bits */ | |
if (sim_is_active (uptr)) /* is the drive positioner moving? */ | |
status |= DL_S2BUSY; /* set the Drive Busy bit */ | |
if (status & DL_S2ERRORS) /* are there any Status-2 errors? */ | |
status |= DL_S2ERR; /* set the Error bit */ | |
return status; /* return the unit status */ | |
} |