/* hp_disclib.c: HP MAC/ICD disc controller simulator library | |
Copyright (c) 2011-2016, 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 | |
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in this Software without prior written authorization from the authors. | |
27-Jul-15 JDB First revised release version | |
21-Feb-15 JDB Revised for new controller interface model | |
24-Dec-14 JDB Added casts for explicit downward conversions | |
27-Oct-14 JDB Corrected the relative movement calculation in start_seek | |
20-Dec-12 JDB sim_is_active() now returns t_bool | |
24-Oct-12 JDB Changed CNTLR_OPCODE to title case to avoid name clash | |
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, August 1980) | |
- HP 13365 Integrated Controller Programming Guide | |
(13365-90901, February 1980) | |
- HP 1000 ICD/MAC Disc Diagnostic Reference Manual | |
(5955-4355, June 1984) | |
- RTE-IVB System Manager's Manual | |
(92068-90006, January 1983) | |
- DVR32 RTE Moving Head Driver Source | |
(92084-18711, Revision 5000) | |
The 13037 multiple-access disc controller (MAC) connects from one to eight HP | |
7905 (15 MB), 7906 (20 MB), 7920 (50 MB), or 7925 (120 MB) disc drives to | |
interfaces installed in from one to eight HP 1000, 2000, or 3000 CPUs. The | |
drives use a common command set and present data to the controller | |
synchronously at a data rate of 468.75 kilowords per second (2.133 | |
microseconds per word). | |
The controller hardware consists of three PCAs: a 16-bit microprogrammed | |
processor constructed from 74S181 bit slices operating at 5 MHz, a device | |
controller that provides the interconnections to the drives and CPU | |
interfaces, and an error correction controller that enables the correction of | |
up to 32-bit error bursts. 1024 words of 24-bit firmware are stored in ROM | |
on the error correction PCA, and the execution time is 200 nanoseconds per | |
instruction. | |
The Integrated Controller Drive (ICD) models include the HP 7906H, 7920H, and | |
7925H. These drives are identical to the corresponding MAC drives, except | |
that they integrate a single-CPU version of the MAC controller on two PCAs | |
housed within the drive: an 8-bit microprocessor constructed from two 4-bit | |
slices operating at 3.75 MHz, and an 8-bit DMA that handles the data path | |
between the drive and CPU. Connection to the CPU is via the Hewlett-Packard | |
Interface Bus (HP-IB) -- HP's implementation of the IEEE-488 standard. | |
The ICD command set essentially is the MAC command set modified for | |
single-unit operation. The unit number and CPU hold bit fields in the opcode | |
words are unused in the ICD implementation. The Load TIO Register, Wakeup, | |
and Request Syndrome commands are removed, as Load TIO is used with the HP | |
3000, Wakeup is used in a multi-CPU environment, and the simpler ICD | |
controller does not support ECC. Controller status values 02B (Unit | |
Available) and 27B (Unit Unavailable) are dropped as the controller supports | |
only single units, 12B (I/O Program Error) is reused to indicate HP-IB | |
protocol errors, 13B (Sync Not Received) is added, and 17B (Possibly | |
Correctable Data Error) is removed as error correction is not supported. | |
Some minor redefinitions also occur. For example, status 14B (End of | |
Cylinder) is expanded to include an auto-seek beyond the drive limits, and | |
37B (Drive Attention) is restricted to just head unloads (from head loads and | |
unloads). | |
The MAC controller offers an HP-IB option: the HP 12745A Disc Controller to | |
HP-IB Adapter Kit. This card plugs into the 13037's chassis containing the | |
other three controller cards and connects to the CPU interface port of the | |
device controller PCA in place of the multi-CPU-interface cable. It allows | |
HP-IB 3000s and the HP 64000 Logic Development Station to connect to MAC disc | |
drives; the ICD drives are not supported on these systems. | |
This library provides the 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 HP2100 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. | |
The original release of this library did not handle the data transfer between | |
the controller and the interface directly. Instead, data was moved between | |
the interface and a sector buffer by the interface simulator, and then the | |
buffer was passed to the disc library for reading or writing. This buffer | |
was also used to pass disc commands and parameters to the controller, and to | |
receive status information from the controller. | |
While this approach served to allow the library to be shared between | |
dissimilar interfaces, each interface had to have intimate knowledge of the | |
internal controller state in order to schedule parameter and data transfers. | |
In particular, the unit service routine had to base its actions on specific | |
controller phase and opcode pairs and manipulate the internal state variables | |
of the controller. As such, the library could not be viewed opaquely. | |
In addition, the HP 3000 interface required channel program support that was | |
not provided by the simulation library although it was present in hardware. | |
Adapting the existing library model would have placed an even larger and more | |
intimate burden on the interface simulation. | |
As a result, the library API was rewritten to model the hardware more | |
closely and provide a more strict separation of controller and interface | |
functions. Instead of providing separate routines to prepare, start, and end | |
commands, service units, and poll drives for Attention status, the new model | |
provides a single routine that represents the hardware data, flag, and | |
function buses between the interface and controller. The interface calls | |
this routine whenever the state of the flag bus changes, and the controller | |
responds by potentially changing the data and function buses. The interface | |
merely responds to those changes without requiring any other knowledge of the | |
internal state of the controller. | |
A device interface simulator interacts with the disc controller simulator via | |
the dl_controller routine, which simulates the command, status, and data | |
interconnection between the interface and controller. Utility routines are | |
also provided to attach and detach disc image files from drive units, load or | |
unload the drive's heads, set drive model and protection status, select the | |
interface timing mode (real or fast), and enable overriding of disc command | |
status returns for diagnostics. | |
In hardware, the interface and controller are interconnected via a 16-bit | |
bidirectional data bus (IBUS), a 6-bit flag bus and one signal (CLEAR) to | |
the controller, and a 4-bit function bus (IFNBUS) and four signals (ENID, | |
ENIR, IFVLD, and IFCLK) to the interface. The interface initiates controller | |
action by changing the state of the flag bus, and the controller responds by | |
asserting a function on the function bus. For example, the interface starts | |
a disc command by asserting CMRDY on the flag bus. The controller responds | |
by placing the IFGTC (Interface Get Command) function on the function bus and | |
asserting the ENID (Enable Interface Drivers) and IFVLD (Interface Function | |
Valid) signals. The interface then replies by placing the command on the | |
data bus, where it is read by the controller. The controller then decodes | |
the command and initiates processing. | |
The controller microprogram runs continuously. However, command execution | |
pauses in various wait loops whenever the controller must suspend until an | |
external event occurs. For example, an Address Record command waits first | |
for the CPU to send the cylinder address and then waits again for the CPU to | |
send the head/sector address. The controller then saves these values in | |
registers before completing the command and then waiting for the CPU to send | |
a new command. | |
In simulation, the dl_controller routine is called with a set of flags and | |
the content of the data bus whenever the flag state changes or a service | |
event occurs. The routine returns a set of functions and the new content of | |
the data bus. To use the above example, dl_controller would be called with | |
CMRDY and the command word and would return IFGTC; the data bus return value | |
would not be used in this case. In hardware, the controller might send a | |
series of individual functions to the interface in response to a single | |
invocation. In simulation, this series would be collected into a single | |
function set for return. | |
Hardware wait loops are simulated by the dl_controller routine returning to | |
the caller until the expected external event occurs. In the Address Record | |
example, dl_controller would be called first when the command is issued by | |
the CPU. The routine would initiate command processing and then return to | |
wait for the cylinder address. When the CPU provided the address, the | |
interface simulator would call dl_controller again with the cylinder value. | |
The routine would then return to wait for the head/sector address. When it | |
was available, dl_controller would be called with the value, and the routine | |
would complete the command and return to the caller to wait for a new | |
command. So, in simulation, the controller only "runs" when it has work to | |
do. | |
A controller instance is represented by a CNTLR_VARS structure, which | |
maintains the controller's internal state. A MAC interface will have a | |
single controller instance that controls up to eight drive units, whereas an | |
ICD interface will have one controller instance per drive unit. The minor | |
differences in controller action between the two are handled internally. | |
The interface simulator must declare one unit for each disc drive to be | |
controlled by the library. For a MAC controller, eight units are required, | |
plus one additional unit for the controller itself. For an ICD controller, | |
only one unit is required. | |
The controller maintains five values in each drive's unit structure: | |
u3 (CYL) -- the current drive cylinder | |
u4 (STATUS) -- the drive status (Status-2) | |
u5 (OPCODE) -- the drive current operation in process | |
u6 (PHASE) -- the drive current operation phase | |
pos -- the current byte offset into the disc image file | |
Drives maintain their cylinder (head positioner) locations separate from the | |
cylinder location stored in the controller. This allows the controller to | |
implement sparing by positioning to one location while storing a different | |
location in the sector headers. It also allows seek retries by issuing a | |
Recalibrate (which moves the positioner to cylinder 0) followed by the | |
original read or write (which repositioned to the cylinder stored in the | |
controller). | |
The drive status field contains only a subset of the status maintained by | |
drives in hardware. Specifically, the Attention, Read-Only, First Status, | |
and Seek Check bits are stored in the status field. The other bits (Format | |
Enabled, Not Ready, and Drive Busy) are set dynamically whenever status is | |
requested (the Drive Fault bit is not simulated). | |
Per-drive opcode and phase values allow seeks to be overlapped. For example, | |
a Seek issued to unit 0 may be followed by a Read issued to unit 1. When the | |
seek completes on unit 0, its opcode and phase values will let the controller | |
set the appropriate seek completion status without disturbing the values | |
currently in-use by unit 1. | |
The simulation defines these command phases: | |
Idle -- the unit is not currently executing a command | |
Parameter -- the unit is obtaining or returning parameter values | |
Seek -- the unit is seeking to a new head position | |
Rotate -- the unit is rotating into position to access a sector | |
Data -- the unit is obtaining or returning sector data values | |
Intersector -- the unit is rotating between sectors | |
End -- the unit is completing a command | |
A value represents the current state of the unit. If a unit is active, the | |
phase will end when the unit is serviced. | |
In addition to the controller structure(s), an interface declares a data | |
buffer to be used for sector transfers. 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. Only one | |
buffer is needed per interface, regardless of the number of controllers or | |
units handled, as a single interface cannot perform data transfers on one | |
drive concurrently with a command directed to another drive. | |
An interface is also responsible for declaring a structure of type | |
DELAY_PROPS that contains the timing values for the controller when in | |
FASTTIME mode. The values are event counts for these actions: | |
- track-to-track seek time | |
- full-stroke seek time | |
- full sector rotation time | |
- per-word data transfer time | |
- intersector gap time | |
- controller execution overhead time | |
These values are typically exposed via the interface's register set and so | |
may be altered by the user. A macro, DELAY_INIT, is provided to initialize | |
the structure. | |
An interface may optionally declare an array of DIAG_ENTRY structures if it | |
wishes to use the diagnostic override capability. Diagnostic overrides are | |
used to return controller status values that otherwise are not simulated to a | |
diagnostic program. An example would be a Correctable Data Error or a | |
Head-Sector Miscompare. If this facility is to be used, a pointer to the | |
array is placed in the CNTLR_VARS structure when it is initialized, and the | |
array itself is initialized with the DL_OVEND value that indicates that no | |
overrides are currently defined. | |
If the pointer is set, then when each command is started, the cylinder, head, | |
sector, and opcode values from the current override entry are checked against | |
the corresponding current controller values. If a match occurs, then the | |
controller status and Spare/Protected/Defective values are set from the entry | |
rather than being cleared, and the pointer is moved to the next entry. These | |
values will then be returned as the completion status of the current command. | |
If the command performs address verification, then any SPD value(s) will be | |
used as the result of the verification. In particular, setting the P bit for | |
a Write will cause a Protected Track error if the FORMAT switch is not on, | |
and any status value other than Normal Completion, Correctable Data Error, or | |
Uncorrectable Data Error will cause a verification abort. | |
In hardware, the errors that may occur during verification are Cylinder | |
Miscompare, Head-Sector Miscompare, Sync Timeout, Illegal Spare Access, and | |
Defective Track; any of these errors may be simulated. In addition, an | |
Uncorrectable Data Error may occur in hardware if the controller is unable to | |
verify any of the 16 sectors starting at the sector preceding the target | |
sector, but this error cannot be simulated. | |
Specifying either a Correctable Data Error or an Uncorrectable Data Error | |
will cause an abort at the end of the first sector of a read, write, or | |
verify command. | |
Correctable Data Error and Uncorrectable Data Error may also be specified for | |
the Request Syndrome command. A table entry with the former status value is | |
always followed by an additional entry that contains the values to be | |
returned for the three syndrome words and the displacement. | |
The last defined table entry always contains a special end-of-table value. | |
The controller library provides a macro, DL_MODS, that initializes MTAB | |
entries, and two utility routines, dl_set_diag and dl_show_diag, that provide | |
a user interface for setting up a table of diagnostic overrides. See the | |
comments for these routines below for the command syntax. | |
A macro, CNTLR_INIT, is provided to initialize the controller structure from | |
the following parameters: | |
- the type of the controller (MAC or ICD) | |
- the simulation DEVICE structure on which the controller operates | |
- the data buffer array | |
- the diagnostic override array or NULL if not used | |
- the structure containing the FASTTIME values | |
A macro, DL_REGS, is also provided that initializes a set of REG structures | |
to provide a user interface to the controller structure. | |
In hardware, disc drives respond to commands issued by the controller. The | |
only unsolicited status from drives occurs when the heads are loaded or | |
unloaded by the operator. In simulation, SET <dev> UNLOAD and SET <dev> LOAD | |
commands represent these actions. The controller must be notified by calling | |
the dl_load_unload routine in response to changes in a disc drive's RUN/STOP | |
switch. | |
Finally, the controller library provides extensive tracing of its internal | |
operations via debug logging. Six debug flags are declared for use by the | |
interface simulator. When enabled, these report controller actions at | |
various levels of detail. | |
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 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. | |
4. In hardware, a command pending on an interface (CMRDY asserted) while a | |
previous command is executing will be started as soon as the current | |
command completes. In simulation, dl_controller will exit when the | |
current command completes and must be called again if CMRDY is asserted. | |
This is necessary to allow the completion status of the prior command to | |
be returned to the interface before the new command is started. | |
*/ | |
#include <math.h> | |
#include "hp_disclib.h" | |
/* Program constants */ | |
#define CNTLR_UNIT (DL_MAXDRIVE + 1) /* controller unit number */ | |
#define MAX_UNIT 10 /* last legal unit number */ | |
#define WORDS_PER_SECTOR 128 /* data words per sector */ | |
#define UNTALK_DELAY 160 /* ICD untalk delay (constant instruction count) */ | |
#define CNTLR_TIMEOUT S (1.74) /* command and parameter wait timeout (1.74 seconds) */ | |
#define NO_EVENT -1 /* do not schedule an event */ | |
#define NO_ACTION (CNTLR_IFN_IBUS) (NO_FUNCTIONS | NO_DATA) | |
/* Controller unit pointer */ | |
#define CNTLR_UPTR (cvptr->device->units + cvptr->device->numunits - 1) | |
/* Unit flags accessor */ | |
#define GET_MODEL(f) (((f) >> UNIT_MODEL_SHIFT) & UNIT_MODEL_MASK) | |
/* Controller clear types */ | |
typedef enum { | |
Hard_Clear, /* power-on/preset hard clear */ | |
Timeout_Clear, /* command or parameter timeout clear */ | |
Soft_Clear /* programmed soft clear */ | |
} CNTLR_CLEAR; | |
/* Command accessors. | |
Disc commands are passed across the data bus to the controller with the CMRDY | |
flag asserted. The commands have several forms, depending on the particular | |
opcode: | |
15| 14 13 12| 11 10 9 | 8 7 6 | 5 4 3 | 2 1 0 HP 1000 numbering | |
+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+ | |
| - - - | command opcode | - - - - - - - - | form 1 | |
+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+ | |
| - - - | command opcode | - - - - | unit number | form 2 | |
+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+ | |
| - - - | command opcode | H | - - - | unit number | form 3 | |
+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+ | |
| S | P | D | command opcode | H | - - - | unit number | form 4 | |
+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+ | |
| - - - | command opcode | retries | D | S | C | A | form 5 | |
+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+ | |
| - - - | command opcode | head | sector | form 6 | |
+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+ | |
0 | 1 2 3 | 4 5 6 | 7 8 9 |10 11 12 |13 14 15 HP 3000 numbering | |
Form 1 is used by the Address Record, Clear, End, Load TIO Register, Request | |
Disc Address, and Request Syndrome commands. | |
Form 2 is used by the Request Disc Sector and Request Status commands. | |
Form 3 is used by the Read, Read Full Sector, Read With Offset, Read Without | |
Verify, Recalibrate, Seek, Verify, Wakeup, Write, and Write Full Sector | |
commands, where: | |
H = hold the drive | |
Form 4 is used by the Initialize Command, where: | |
S = initialize the track to spare status | |
P = initialize the track to protected status | |
D = initialize the track to defective status | |
H = hold the drive | |
Form 5 is used by the Set File Mask command, where: | |
D = decremental seek | |
S = sparing enabled | |
C = cylinder mode | |
A = auto-seek enabled | |
Form 6 is used by the Cold Load Read command. | |
*/ | |
#define CM_OPCODE_MASK 0017400 /* operation code mask */ | |
#define CM_UNIT_MASK 0000017 /* unit number mask */ | |
#define CM_SPARE 0100000 /* spare track */ | |
#define CM_PROTECTED 0040000 /* protected track */ | |
#define CM_DEFECTIVE 0020000 /* defective track */ | |
#define CM_SPD_MASK (CM_SPARE | CM_PROTECTED | CM_DEFECTIVE) | |
#define CM_RETRY_MASK 0000360 /* retry count mask */ | |
#define CM_FILE_MASK_MASK 0000017 /* file mask mask */ | |
#define CM_DECR_SEEK 0000010 /* 0/1 = incremental/decremental seek */ | |
#define CM_SPARE_EN 0000004 /* sparing enabled */ | |
#define CM_CYL_MODE 0000002 /* 0/1 = surface/cylinder mode */ | |
#define CM_AUTO_SEEK_EN 0000001 /* auto-seek enabled */ | |
#define CM_HEAD_MASK 0000300 /* cold load read head mask */ | |
#define CM_SECTOR_MASK 0000077 /* cold load read sector mask */ | |
#define CM_OPCODE_SHIFT 8 | |
#define CM_UNIT_SHIFT 0 | |
#define CM_RETRY_SHIFT 4 | |
#define CM_FILE_MASK_SHIFT 0 | |
#define CM_HEAD_SHIFT 6 | |
#define CM_SECTOR_SHIFT 0 | |
#define CM_SPD(c) ((c) & CM_SPD_MASK) | |
#define CM_OPCODE(c) (((c) & CM_OPCODE_MASK) >> CM_OPCODE_SHIFT) | |
#define CM_UNIT(c) (((c) & CM_UNIT_MASK) >> CM_UNIT_SHIFT) | |
#define CM_RETRY(c) (((c) & CM_RETRY_MASK) >> CM_RETRY_SHIFT) | |
#define CM_FILE_MASK(c) (((c) & CM_FILE_MASK_MASK) >> CM_FILE_MASK_SHIFT) | |
#define CM_HEAD(c) (((c) & CM_HEAD_MASK) >> CM_HEAD_SHIFT) | |
#define CM_SECTOR(c) (((c) & CM_SECTOR_MASK) >> CM_SECTOR_SHIFT) | |
static const BITSET_NAME file_mask_names [] = { /* File mask word */ | |
"\1decremental seek\0incremental seek", /* bit 3/12 */ | |
"sparing", /* bit 2/13 */ | |
"\1cylinder mode\0surface mode", /* bit 1/14 */ | |
"autoseek" /* bit 0/15 */ | |
}; | |
static const BITSET_FORMAT file_mask_format = /* names, offset, direction, alternates, bar */ | |
{ FMT_INIT (file_mask_names, 0, msb_first, has_alt, append_bar) }; | |
/* Parameter accessors. | |
Parameters are passed across the data bus to the controller with the DTRDY | |
flag asserted. The parameters have several forms, depending on the commands | |
requesting them: | |
15| 14 13 12| 11 10 9 | 8 7 6 | 5 4 3 | 2 1 0 HP 1000 numbering | |
+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+ | |
| cylinder | form 1 (in/out) | |
+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+ | |
| 0 | head | sector | form 2 (in/out) | |
+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+ | |
| S | P | D | status code | - - - - | unit number | form 3 (out) | |
+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+ | |
| E | - - | drive type | - | A | R | F | L | S | K | N | B | form 4 (out) | |
+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+ | |
| 0 | sector | form 5 (out) | |
+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+ | |
| sector count | form 6 (in) | |
+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+ | |
| displacement | form 7 (out) | |
+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+ | |
| pattern | form 8 (out) | |
+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+ | |
| data word | form 9 (in) | |
+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+ | |
| | A | D | S | - | cyl offset magnitude | form 10 (in) | |
+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+ | |
0 | 1 2 3 | 4 5 6 | 7 8 9 |10 11 12 |13 14 15 HP 3000 numbering | |
Forms 1 and 2 are used by the Address Record, Request Disc Address, Request | |
Syndrome, and Seek commands. | |
Form 3 is used by the Request Status and Request Syndrome commands, where: | |
S = last track was a spare | |
P = last track was protected | |
D = last track was defective | |
Form 4 is used by the Request Status command, where: | |
E = error present | |
A = attention | |
R = read-only | |
F = format enabled | |
L = drive fault | |
S = first status | |
K = seek check | |
N = not ready | |
B = drive busy | |
Form 5 is used by the Request Sector Address command. | |
Form 6 is used by the Verify command. | |
Forms 7 and 8 are used by the Request Syndrome command. | |
Form 9 is used by the Load TIO Register command. | |
Form 10 is used by the Read With Offset command, where: | |
A = advance the clock (valid for 13037A only) | |
D = delay the clock (valid for 13037A only) | |
S = sign of cylinder offset | |
*/ | |
#define S1_SPARE 0100000 /* spare track */ | |
#define S1_PROTECTED 0040000 /* protected track */ | |
#define S1_DEFECTIVE 0020000 /* defective track */ | |
#define S1_STATUS_MASK 0017400 /* encoded termination status mask */ | |
#define S1_UNIT_MASK 0000017 /* unit number mask */ | |
#define S1_STATUS_SHIFT 8 | |
#define S1_UNIT_SHIFT 0 | |
#define S1_STATUS(n) ((n) << S1_STATUS_SHIFT & S1_STATUS_MASK) | |
#define S1_UNIT(n) ((n) << S1_UNIT_SHIFT & S1_UNIT_MASK) | |
#define S2_ERROR 0100000 /* any error */ | |
#define S2_DRIVE_TYPE_MASK 0017000 /* drive type mask */ | |
#define S2_ATTENTION 0000200 /* attention */ | |
#define S2_READ_ONLY 0000100 /* read-only */ | |
#define S2_FORMAT_EN 0000040 /* format enabled */ | |
#define S2_FAULT 0000020 /* drive fault */ | |
#define S2_FIRST_STATUS 0000010 /* first status */ | |
#define S2_SEEK_CHECK 0000004 /* seek check */ | |
#define S2_NOT_READY 0000002 /* not ready */ | |
#define S2_BUSY 0000001 /* drive busy */ | |
#define S2_STOPS (S2_FAULT \ | |
| S2_SEEK_CHECK \ | |
| S2_NOT_READY) /* bits that stop drive access */ | |
#define S2_ERRORS (S2_FAULT \ | |
| S2_SEEK_CHECK \ | |
| S2_NOT_READY \ | |
| S2_BUSY) /* bits that set S2_ERROR */ | |
#define S2_CPS (S2_ATTENTION \ | |
| S2_FAULT \ | |
| S2_FIRST_STATUS \ | |
| S2_SEEK_CHECK) /* bits that are cleared by Controller Preset */ | |
#define S2_DRIVE_TYPE_SHIFT 9 | |
#define S2_DRIVE_TYPE(n) ((n) << S2_DRIVE_TYPE_SHIFT & S2_DRIVE_TYPE_MASK) | |
#define S2_TO_DRIVE_TYPE(n) (((n) & S2_DRIVE_TYPE_MASK) >> S2_DRIVE_TYPE_SHIFT) | |
#define PIO_HEAD_MASK 0017400 /* head mask */ | |
#define PIO_SECTOR_MASK 0000377 /* sector mask */ | |
#define PI_ADV_CLOCK 0001000 /* advance clock */ | |
#define PI_DEL_CLOCK 0000400 /* delay clock */ | |
#define PI_NEG_OFFSET 0000200 /* 0/1 = positive/negative cylinder offset sign */ | |
#define PI_OFFSET_MASK 0000077 /* cylinder offset mask */ | |
#define PIO_HEAD_SHIFT 8 | |
#define PIO_SECTOR_SHIFT 0 | |
#define PI_OFFSET_SHIFT 0 | |
#define PI_HEAD(p) (((p) & PIO_HEAD_MASK) >> PIO_HEAD_SHIFT) | |
#define PI_SECTOR(p) (((p) & PIO_SECTOR_MASK) >> PIO_SECTOR_SHIFT) | |
#define PI_OFFSET(p) (((p) & PI_OFFSET_MASK) >> PI_OFFSET_SHIFT) | |
#define PO_HEAD(n) (((n) << PIO_HEAD_SHIFT & PIO_HEAD_MASK)) | |
#define PO_SECTOR(n) (((n) << PIO_SECTOR_SHIFT & PIO_SECTOR_MASK)) | |
static const BITSET_NAME status_1_names [] = { /* Status-1 word */ | |
"spare", /* bit 15/0 */ | |
"protected", /* bit 14/1 */ | |
"defective" /* bit 13/2 */ | |
}; | |
static const BITSET_FORMAT status_1_format = /* names, offset, direction, alternates, bar */ | |
{ FMT_INIT (status_1_names, 13, msb_first, no_alt, append_bar) }; | |
static const BITSET_FORMAT initialize_format = /* names, offset, direction, alternates, bar */ | |
{ FMT_INIT (status_1_names, 13, msb_first, no_alt, no_bar) }; | |
static const BITSET_NAME status_2_names [] = { /* Status-2 word */ | |
"attention", /* bit 7/ 8 */ | |
"read only", /* bit 6/ 9 */ | |
"format enabled", /* bit 5/10 */ | |
"fault", /* bit 4/11 */ | |
"first status", /* bit 3/12 */ | |
"seek check", /* bit 2/13 */ | |
"not ready", /* bit 1/14 */ | |
"busy" /* bit 0/15 */ | |
}; | |
static const BITSET_FORMAT status_2_format = /* names, offset, direction, alternates, bar */ | |
{ FMT_INIT (status_2_names, 0, msb_first, no_alt, no_bar) }; | |
static const BITSET_NAME offset_names [] = { /* Read With Offset parameter */ | |
"advanced clock", /* bit 9/ 6 */ | |
"delayed clock" /* bit 8/ 7 */ | |
}; | |
static const BITSET_FORMAT offset_format = /* names, offset, direction, alternates, bar */ | |
{ FMT_INIT (offset_names, 8, msb_first, no_alt, append_bar) }; | |
/* 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 a Seek command and the head/sector | |
address during an Address Record drive command). | |
In simulation, the model ID number from the unit flags is used as an index | |
into the drive properties 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 separate "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. | |
The Drive Type is reported by the controller in the second status word | |
(Status-2) returned by the Request Status command. | |
*/ | |
typedef struct { | |
char *name; /* drive name */ | |
uint32 sectors; /* sectors per head */ | |
uint32 heads; /* heads per cylinder*/ | |
uint32 cylinders; /* cylinders per drive */ | |
uint32 words; /* words per drive */ | |
uint32 remov_heads; /* number of removable-platter heads */ | |
uint32 fixed_heads; /* number of fixed-platter heads */ | |
} DRIVE_PROPS; | |
static const DRIVE_PROPS drive_props [] = { /* indexed by DRIVE_TYPE */ | |
/* drive sectors heads cylinders words remov fixed */ | |
/* name per trk per cyl per drive per drive heads heads */ | |
/* ------- ------- ------- ---------- ----------- ----- ----- */ | |
{ "7906", 48, 4, 411, WORDS_7906, 2, 2 }, /* drive type 0 */ | |
{ "7920", 48, 5, 823, WORDS_7920, 5, 0 }, /* drive type 1 */ | |
{ "7905", 48, 3, 411, WORDS_7905, 2, 1 }, /* drive type 2 */ | |
{ "7925", 64, 9, 823, WORDS_7925, 9, 0 } /* drive type 3 */ | |
}; | |
/* Delay properties table. | |
To support the realistic timing mode, the delay properties table contains | |
timing specifications for the supported disc drives. The times represent the | |
delays for mechanical and electronic operations. Delay values are in event | |
tick counts; macros are used to convert from times to ticks. | |
The drive type field differentiates between drive models available on a given | |
controller. The field is not significant for MAC and ICD controllers because | |
all of the drives supported have the same specifications. | |
The controller overhead values are estimates; they do not appear to be | |
documented for MAC and ICD controllers, although they are published for | |
various CS/80 drives. | |
*/ | |
static const DELAY_PROPS real_times [] = { | |
/* cntlr drive seek seek sector data intersector cntlr */ | |
/* type type trk-trk full rotation per word gap overhead */ | |
/* ----- -------- ------- -------- ----------- ---------- ----------- -------- */ | |
{ MAC, HP_All, mS (5), mS (45), uS (347.2), uS (2.13), uS (27.2), uS (200) }, | |
{ ICD, HP_All, mS (5), mS (45), uS (347.2), uS (2.13), uS (27.2), mS (1.5) } | |
}; | |
#define DELAY_COUNT (sizeof real_times / sizeof real_times [0]) | |
/* Estimate the current sector. | |
The sector currently passing under the disc heads is estimated from the | |
current "simulation time," which is the number of event ticks since the | |
simulation run was started, and the simulated disc rotation time. The | |
computation logic is: | |
current_sector := (simulator_time / per_sector_time) MOD sectors_per_track; | |
*/ | |
#define CURRENT_SECTOR(cvptr,uptr) \ | |
(uint32) fmod (sim_gtime () / cvptr->dlyptr->sector_full, \ | |
drive_props [GET_MODEL (uptr->flags)].sectors) | |
/* Command properties table. | |
The validity of each command for a given controller type is checked against | |
the command properties table when it is prepared for execution. The table | |
also includes the count of inbound or outbound parameters, the class of the | |
command, and flags that indicate certain common actions that are be taken. | |
Implementation notes: | |
1. The verify field of the Read_Without_Verify property record is set to | |
TRUE so that address verification will be done if a track boundary is | |
crossed. Initial verification is suppressed by setting the controller's | |
verify field to FALSE during initial Read_Without_Verify processing. | |
*/ | |
typedef struct { | |
uint32 param_count; /* count of input or output parameters */ | |
CNTLR_CLASS classification; /* command classification */ | |
t_bool valid [CNTLR_COUNT]; /* command validity, indexed by CNTLR_TYPE */ | |
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 */ | |
t_bool verify_address; /* command does address verification */ | |
t_bool idle_at_end; /* command idles the controller at completion */ | |
uint32 preamble_size; /* size of preamble in words */ | |
uint32 transfer_size; /* size of data transfer in words */ | |
uint32 postamble_size; /* size of postamble in words */ | |
} COMMAND_PROPERTIES; | |
typedef const COMMAND_PROPERTIES *PRPTR; | |
#define T TRUE | |
#define F FALSE | |
static const COMMAND_PROPERTIES cmd_props [] = { | |
/* parm opcode valid for clr unit unit unit seek addr end pre xfer post */ | |
/* I/O classification MAC ICD CS80 stat fld chk acc wait verf idle size size size */ | |
/* ---- -------------- --- --- ---- ---- ---- ---- ---- ---- ---- ---- ---- ---- ---- */ | |
{ 0, Class_Read, { T, T, F }, T, F, T, T, F, T, F, 15, 128, 7 }, /* 00 = Cold_Load_Read */ | |
{ 0, Class_Control, { T, T, F }, T, T, T, T, T, F, T, 0, 0, 0 }, /* 01 = Recalibrate */ | |
{ 2, Class_Control, { T, T, F }, T, T, T, T, F, F, T, 0, 0, 0 }, /* 02 = Seek */ | |
{ 2, Class_Status, { T, T, F }, F, T, F, F, F, F, F, 0, 0, 0 }, /* 03 = Request_Status */ | |
{ 1, Class_Status, { T, T, F }, T, T, T, T, F, F, F, 0, 0, 0 }, /* 04 = Request_Sector_Address */ | |
{ 0, Class_Read, { T, T, F }, T, T, T, T, T, T, F, 15, 128, 7 }, /* 05 = Read */ | |
{ 0, Class_Read, { T, T, F }, T, T, T, T, T, F, F, 12, 138, 0 }, /* 06 = Read_Full_Sector */ | |
{ 1, Class_Read, { T, T, F }, T, T, T, T, T, T, F, 0, 0, 0 }, /* 07 = Verify */ | |
{ 0, Class_Write, { T, T, F }, T, T, T, T, T, T, F, 15, 128, 7 }, /* 10 = Write */ | |
{ 0, Class_Write, { T, T, F }, T, T, T, T, T, F, F, 12, 138, 0 }, /* 11 = Write_Full_Sector */ | |
{ 0, Class_Control, { T, T, F }, T, F, F, F, F, F, F, 0, 0, 0 }, /* 12 = Clear */ | |
{ 0, Class_Write, { T, T, F }, T, T, T, T, T, F, F, 15, 128, 7 }, /* 13 = Initialize */ | |
{ 2, Class_Control, { T, T, F }, T, F, F, F, F, F, F, 0, 0, 0 }, /* 14 = Address_Record */ | |
{ 7, Class_Status, { T, F, F }, T, F, F, F, F, F, F, 0, 0, 0 }, /* 15 = Request_Syndrome */ | |
{ 1, Class_Read, { T, T, F }, T, T, T, T, T, T, F, 15, 128, 7 }, /* 16 = Read_With_Offset */ | |
{ 0, Class_Control, { T, T, F }, T, F, F, F, F, F, F, 0, 0, 0 }, /* 17 = Set_File_Mask */ | |
{ 0, Class_Invalid, { F, F, F }, T, F, F, F, F, F, F, 0, 0, 0 }, /* 20 = Invalid_Opcode */ | |
{ 0, Class_Invalid, { F, F, F }, T, F, F, F, F, F, F, 0, 0, 0 }, /* 21 = Invalid_Opcode */ | |
{ 0, Class_Read, { T, T, F }, T, T, T, T, T, T, F, 15, 128, 7 }, /* 22 = Read_Without_Verify */ | |
{ 1, Class_Status, { T, F, F }, T, F, F, F, F, F, F, 0, 0, 0 }, /* 23 = Load_TIO_Register */ | |
{ 2, Class_Status, { T, T, F }, F, F, F, F, F, F, F, 0, 0, 0 }, /* 24 = Request_Disc_Address */ | |
{ 0, Class_Control, { T, T, F }, T, F, F, F, F, F, T, 0, 0, 0 }, /* 25 = End */ | |
{ 0, Class_Control, { T, F, F }, T, T, T, F, F, F, F, 0, 0, 0 } /* 26 = Wakeup */ | |
}; | |
/* Command functions table. | |
At each phase of command execution, the controller may return zero or more | |
functions for the interface to perform. The functions control the transfer | |
of parameters and data to and from the CPU. Note that commands do not | |
necessarily use all available phases. | |
Implementation notes: | |
1. Commands usually return BUSY and IFGTC functions to begin. However, the | |
Clear and Set File Mask commands delay the IFGTC function, which requests | |
channel service, to the End Phase to ensure that the WRTIO function | |
completes before the channel program continues. This ensures that an End | |
I/O order will pick up the correct status value from the interface. | |
2. Invalid commands have WRTIO in their Idle_Phase entries because the | |
diagnostic expects to see Illegal_Opcode status immediately after the SIO | |
program ends. | |
*/ | |
typedef CNTLR_IFN IFN_ARRAY [7]; | |
static const IFN_ARRAY cmd_functions [] = { /* indexed by CNTLR_OPCODE */ | |
/* 00 = Cold_Load_Read */ | |
{ BUSY | SRTRY | IFGTC, /* Idle Phase */ | |
0, /* Parameter Phase */ | |
0, /* Seek Phase */ | |
0, /* Rotate Phase */ | |
IFIN, /* Data Phase */ | |
0, /* Intersector Phase */ | |
STDFL | WRTIO | RQSRV | FREE }, /* End Phase */ | |
/* 01 = Recalibrate */ | |
{ BUSY | IFGTC, /* Idle Phase */ | |
0, /* Parameter Phase */ | |
0, /* Seek Phase */ | |
0, /* Rotate Phase */ | |
0, /* Data Phase */ | |
0, /* Intersector Phase */ | |
WRTIO | FREE }, /* End Phase */ | |
/* 02 = Seek */ | |
{ BUSY | IFGTC | STDFL, /* Idle Phase */ | |
IFOUT | STDFL, /* Parameter Phase */ | |
0, /* Seek Phase */ | |
0, /* Rotate Phase */ | |
0, /* Data Phase */ | |
0, /* Intersector Phase */ | |
IFOUT | WRTIO | RQSRV | FREE }, /* End Phase */ | |
/* 03 = Request_Status */ | |
{ BUSY | IFGTC, /* Idle Phase */ | |
IFIN | STDFL, /* Parameter Phase */ | |
0, /* Seek Phase */ | |
0, /* Rotate Phase */ | |
0, /* Data Phase */ | |
0, /* Intersector Phase */ | |
WRTIO | FREE | RQSRV }, /* End Phase */ | |
/* 04 = Request_Sector_Address */ | |
{ BUSY | IFGTC, /* Idle Phase */ | |
IFIN | STDFL, /* Parameter Phase */ | |
0, /* Seek Phase */ | |
0, /* Rotate Phase */ | |
0, /* Data Phase */ | |
0, /* Intersector Phase */ | |
WRTIO | RQSRV | FREE }, /* End Phase */ | |
/* 05 = Read */ | |
{ BUSY | IFGTC, /* Idle Phase */ | |
0, /* Parameter Phase */ | |
0, /* Seek Phase */ | |
0, /* Rotate Phase */ | |
IFIN, /* Data Phase */ | |
0, /* Intersector Phase */ | |
STDFL | WRTIO | RQSRV | FREE }, /* End Phase */ | |
/* 06 = Read_Full_Sector */ | |
{ BUSY | IFGTC, /* Idle Phase */ | |
0, /* Parameter Phase */ | |
0, /* Seek Phase */ | |
0, /* Rotate Phase */ | |
IFIN, /* Data Phase */ | |
0, /* Intersector Phase */ | |
STDFL | WRTIO | RQSRV | FREE }, /* End Phase */ | |
/* 07 = Verify */ | |
{ BUSY | IFGTC | STDFL, /* Idle Phase */ | |
IFOUT, /* Parameter Phase */ | |
0, /* Seek Phase */ | |
0, /* Rotate Phase */ | |
0, /* Data Phase */ | |
0, /* Intersector Phase */ | |
STDFL | WRTIO | RQSRV | FREE }, /* End Phase */ | |
/* 10 = Write */ | |
{ BUSY | IFGTC, /* Idle Phase */ | |
0, /* Parameter Phase */ | |
0, /* Seek Phase */ | |
0, /* Rotate Phase */ | |
IFOUT, /* Data Phase */ | |
0, /* Intersector Phase */ | |
STDFL | WRTIO | RQSRV | FREE }, /* End Phase */ | |
/* 11 = Write_Full_Sector */ | |
{ BUSY | IFGTC, /* Idle Phase */ | |
0, /* Parameter Phase */ | |
0, /* Seek Phase */ | |
0, /* Rotate Phase */ | |
IFOUT, /* Data Phase */ | |
0, /* Intersector Phase */ | |
STDFL | WRTIO | RQSRV | FREE }, /* End Phase */ | |
/* 12 = Clear */ | |
{ BUSY, /* Idle Phase */ | |
0, /* Parameter Phase */ | |
0, /* Seek Phase */ | |
0, /* Rotate Phase */ | |
0, /* Data Phase */ | |
0, /* Intersector Phase */ | |
IFGTC | WRTIO | STDFL | FREE }, /* End Phase */ | |
/* 13 = Initialize */ | |
{ BUSY | IFGTC, /* Idle Phase */ | |
0, /* Parameter Phase */ | |
0, /* Seek Phase */ | |
0, /* Rotate Phase */ | |
IFOUT, /* Data Phase */ | |
0, /* Intersector Phase */ | |
STDFL | WRTIO | RQSRV | FREE }, /* End Phase */ | |
/* 14 = Address_Record */ | |
{ BUSY | IFGTC | STDFL, /* Idle Phase */ | |
IFOUT | STDFL, /* Parameter Phase */ | |
0, /* Seek Phase */ | |
0, /* Rotate Phase */ | |
0, /* Data Phase */ | |
0, /* Intersector Phase */ | |
IFOUT | WRTIO | RQSRV | FREE }, /* End Phase */ | |
/* 15 = Request_Syndrome */ | |
{ BUSY | IFGTC, /* Idle Phase */ | |
IFIN | STDFL, /* Parameter Phase */ | |
0, /* Seek Phase */ | |
0, /* Rotate Phase */ | |
0, /* Data Phase */ | |
0, /* Intersector Phase */ | |
WRTIO | RQSRV | FREE }, /* End Phase */ | |
/* 16 = Read_With_Offset */ | |
{ BUSY | IFGTC | STDFL, /* Idle Phase */ | |
IFOUT, /* Parameter Phase */ | |
RQSRV | STDFL, /* Seek Phase */ | |
0, /* Rotate Phase */ | |
IFIN, /* Data Phase */ | |
0, /* Intersector Phase */ | |
STDFL | WRTIO | RQSRV | FREE }, /* End Phase */ | |
/* 17 = Set_File_Mask */ | |
{ BUSY | SRTRY, /* Idle Phase */ | |
0, /* Parameter Phase */ | |
0, /* Seek Phase */ | |
0, /* Rotate Phase */ | |
0, /* Data Phase */ | |
0, /* Intersector Phase */ | |
IFGTC | WRTIO | STDFL | FREE }, /* End Phase */ | |
/* 20 = Invalid_Opcode */ | |
{ BUSY | IFGTC | WRTIO, /* Idle Phase */ | |
0, /* Parameter Phase */ | |
0, /* Seek Phase */ | |
0, /* Rotate Phase */ | |
0, /* Data Phase */ | |
0, /* Intersector Phase */ | |
FREE }, /* End Phase */ | |
/* 21 = Invalid_Opcode */ | |
{ BUSY | IFGTC | WRTIO, /* Idle Phase */ | |
0, /* Parameter Phase */ | |
0, /* Seek Phase */ | |
0, /* Rotate Phase */ | |
0, /* Data Phase */ | |
0, /* Intersector Phase */ | |
FREE }, /* End Phase */ | |
/* 22 = Read_Without_Verify */ | |
{ BUSY | IFGTC, /* Idle Phase */ | |
0, /* Parameter Phase */ | |
0, /* Seek Phase */ | |
0, /* Rotate Phase */ | |
IFIN, /* Data Phase */ | |
0, /* Intersector Phase */ | |
STDFL | WRTIO | RQSRV | FREE }, /* End Phase */ | |
/* 23 = Load_TIO_Register */ | |
{ BUSY | IFGTC | STDFL, /* Idle Phase */ | |
0, /* Parameter Phase */ | |
0, /* Seek Phase */ | |
0, /* Rotate Phase */ | |
0, /* Data Phase */ | |
0, /* Intersector Phase */ | |
IFOUT | WRTIO | RQSRV | FREE }, /* End Phase */ | |
/* 24 = Request_Disc_Address */ | |
{ BUSY | IFGTC, /* Idle Phase */ | |
IFIN | STDFL, /* Parameter Phase */ | |
0, /* Seek Phase */ | |
0, /* Rotate Phase */ | |
0, /* Data Phase */ | |
0, /* Intersector Phase */ | |
WRTIO | RQSRV | FREE }, /* End Phase */ | |
/* 25 = End */ | |
{ IFGTC, /* Idle Phase */ | |
0, /* Parameter Phase */ | |
0, /* Seek Phase */ | |
0, /* Rotate Phase */ | |
0, /* Data Phase */ | |
0, /* Intersector Phase */ | |
0 }, /* End Phase */ | |
/* 26 = Wakeup */ | |
{ BUSY | IFGTC, /* Idle Phase */ | |
0, /* Parameter Phase */ | |
0, /* Seek Phase */ | |
0, /* Rotate Phase */ | |
0, /* Data Phase */ | |
0, /* Intersector Phase */ | |
WRTIO | STDFL | FREE } /* End Phase */ | |
}; | |
/* Status functions table. | |
The End Phase functions above are proper for commands that complete normally. | |
Commands that return an error status return additional functions that depend | |
on the particular status code. An entry in this table is ORed with the End | |
Phase function to produce the final function set that is returned to the | |
interface. | |
*/ | |
static const CNTLR_IFN status_functions [] = { /* indexed by CNTLR_STATUS */ | |
0, /* 000 = Normal Completion */ | |
STINT | WRTIO | FREE, /* 001 = Illegal Opcode */ | |
STDFL | WRTIO | FREE, /* 002 = Unit Available */ | |
STINT | WRTIO | FREE, /* 003 = Illegal Drive Type */ | |
0, /* 004 = (undefined) */ | |
0, /* 005 = (undefined) */ | |
0, /* 006 = (undefined) */ | |
STINT | WRTIO | FREE, /* 007 = Cylinder Miscompare */ | |
DVEND | RQSRV | WRTIO | FREE, /* 010 = Uncorrectable Data Error */ | |
STINT | WRTIO | FREE, /* 011 = Head-Sector Miscompare */ | |
STINT | WRTIO | FREE, /* 012 = I/O Program Error */ | |
DVEND | RQSRV | WRTIO | FREE, /* 013 = Sync Timeout */ | |
STINT | WRTIO | FREE, /* 014 = End of Cylinder */ | |
0, /* 015 = (undefined) */ | |
DVEND | RQSRV | WRTIO | FREE, /* 016 = Data Overrun */ | |
DVEND | RQSRV | WRTIO | FREE, /* 017 = Correctable Data Error */ | |
STINT | WRTIO | FREE, /* 020 = Illegal Spare Access */ | |
STINT | WRTIO | FREE, /* 021 = Defective Track */ | |
STINT | WRTIO | FREE, /* 022 = Access Not Ready */ | |
STINT | WRTIO | FREE, /* 023 = Status-2 Error */ | |
0, /* 024 = (undefined) */ | |
0, /* 025 = (undefined) */ | |
STINT | WRTIO | FREE, /* 026 = Protected Track */ | |
STINT | WRTIO | FREE, /* 027 = Unit Unavailable */ | |
0, /* 030 = (undefined) */ | |
0, /* 031 = (undefined) */ | |
0, /* 032 = (undefined) */ | |
0, /* 033 = (undefined) */ | |
0, /* 034 = (undefined) */ | |
0, /* 035 = (undefined) */ | |
0, /* 036 = (undefined) */ | |
STINT | WRTIO | FREE /* 037 = Drive Attention */ | |
}; | |
/* Controller operation names */ | |
static const BITSET_NAME flag_names [] = { /* controller flag names, in CNTLR_FLAG order */ | |
"CLEAR", /* 000001 */ | |
"CMRDY", /* 000002 */ | |
"DTRDY", /* 000004 */ | |
"EOD", /* 000010 */ | |
"INTOK", /* 000020 */ | |
"OVRUN", /* 000040 */ | |
"XFRNG" /* 000100 */ | |
}; | |
static const BITSET_FORMAT flag_format = /* names, offset, direction, alternates, bar */ | |
{ FMT_INIT (flag_names, 0, lsb_first, no_alt, no_bar) }; | |
static const BITSET_NAME function_names [] = { /* interface function names, in CNTLR_IFN order */ | |
"BUSY", /* 000000200000 */ | |
"DSCIF", /* 000000400000 */ | |
"SELIF", /* 000001000000 */ | |
"IFIN", /* 000002000000 */ | |
"IFOUT", /* 000004000000 */ | |
"IFGTC", /* 000010000000 */ | |
"IFPRF", /* 000020000000 */ | |
"RQSRV", /* 000040000000 */ | |
"DVEND", /* 000100000000 */ | |
"SRTRY", /* 000200000000 */ | |
"STDFL", /* 000400000000 */ | |
"STINT", /* 001000000000 */ | |
"WRTIO", /* 002000000000 */ | |
"FREE" /* 004000000000 */ | |
}; | |
static const BITSET_FORMAT function_format = /* names, offset, direction, alternates, bar */ | |
{ FMT_INIT (function_names, 16, lsb_first, no_alt, no_bar) }; | |
static const char invalid_name [] = "Invalid"; | |
static const char *opcode_name [] = { /* command opcode names, in CNTLR_OPCODE order */ | |
"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 */ | |
}; | |
#define OPCODE_LENGTH 22 /* length of the longest opcode name */ | |
static const char *const status_name [] = { /* command status names, in CNTLR_STATUS order */ | |
"Normal Completion", /* 000 */ | |
"Illegal Opcode", /* 001 */ | |
"Unit Available", /* 002 */ | |
"Illegal Drive Type", /* 003 */ | |
NULL, /* 004 */ | |
NULL, /* 005 */ | |
NULL, /* 006 */ | |
"Cylinder Miscompare", /* 007 */ | |
"Uncorrectable Data Error", /* 010 */ | |
"Head-Sector Miscompare", /* 011 */ | |
"I/O Program Error", /* 012 */ | |
"Sync Timeout", /* 013 */ | |
"End of Cylinder", /* 014 */ | |
NULL, /* 015 */ | |
"Data Overrun", /* 016 */ | |
"Correctable Data Error", /* 017 */ | |
"Illegal Spare Access", /* 020 */ | |
"Defective Track", /* 021 */ | |
"Access Not Ready", /* 022 */ | |
"Status-2 Error", /* 023 */ | |
NULL, /* 024 */ | |
NULL, /* 025 */ | |
"Protected Track", /* 026 */ | |
"Unit Unavailable", /* 027 */ | |
NULL, /* 030 */ | |
NULL, /* 031 */ | |
NULL, /* 032 */ | |
NULL, /* 033 */ | |
NULL, /* 034 */ | |
NULL, /* 035 */ | |
NULL, /* 036 */ | |
"Drive Attention" /* 037 */ | |
}; | |
#define STATUS_LENGTH 24 /* length of the longest status name */ | |
static const char *state_name [] = { /* controller state names, in CNTLR_STATE order */ | |
"idle", | |
"wait", | |
"busy" | |
}; | |
static const char *phase_name [] = { /* unit state names, in CNTLR_PHASE order */ | |
"idle", | |
"parameter", | |
"seek", | |
"rotate", | |
"data", | |
"intersector", | |
"end" | |
}; | |
/* Disc library local controller routines */ | |
static CNTLR_IFN_IBUS start_command (CVPTR cvptr, CNTLR_FLAG_SET flags, CNTLR_IBUS data); | |
static CNTLR_IFN_IBUS continue_command (CVPTR cvptr, UNIT *uptr, CNTLR_FLAG_SET flags, CNTLR_IBUS data); | |
static CNTLR_IFN_IBUS poll_drives (CVPTR cvptr); | |
static void end_command (CVPTR cvptr, UNIT *uptr, CNTLR_STATUS status); | |
static t_bool start_seek (CVPTR cvptr, UNIT *uptr); | |
static t_bool start_read (CVPTR cvptr, UNIT *uptr, CNTLR_FLAG_SET flags); | |
static void end_read (CVPTR cvptr, UNIT *uptr, CNTLR_FLAG_SET flags); | |
static t_bool start_write (CVPTR cvptr, UNIT *uptr); | |
static void end_write (CVPTR cvptr, UNIT *uptr, CNTLR_FLAG_SET flags); | |
static t_bool position_sector (CVPTR cvptr, UNIT *uptr); | |
static void next_sector (CVPTR cvptr, UNIT *uptr); | |
static void io_error (CVPTR cvptr, UNIT *uptr); | |
static void set_completion (CVPTR cvptr, UNIT *uptr, CNTLR_STATUS status); | |
static void clear_controller (CVPTR cvptr, CNTLR_CLEAR clear_type); | |
static void idle_controller (CVPTR cvptr); | |
/* Disc library local utility routines */ | |
static void set_address (CVPTR cvptr, uint32 index); | |
static void wait_timer (CVPTR cvptr, FLIP_FLOP action); | |
static uint16 drive_status (UNIT *uptr); | |
static t_stat activate_unit (CVPTR cvptr, UNIT *uptr); | |
static void set_rotation (CVPTR cvptr, UNIT *uptr); | |
static void set_file_pos (CVPTR cvptr, UNIT *uptr, uint32 model); | |
/* Disc library global controller routines */ | |
/* Disc controller interface. | |
This routine simulates the hardware interconnection between the disc | |
controller and the CPU interface. This routine is called whenever the flag | |
state changes. This would be when a new command is to be started, when | |
command parameters are supplied or status words are retrieved, and when | |
sector data is read or written. It must also be called when the unit service | |
routine is entered. The caller passes in the set of interface flags and the | |
contents of the data buffer. The routine returns a set of functions and, if | |
IFIN is included in set, the new content of the data buffer. | |
In hardware, the controller microcode executes in one of three 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 selected and | |
checked for a command; if present, it is executed. If not, the | |
interface is disconnected, and then 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 selected 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 | |
interface is disconnected, and the Poll Loop continues. | |
2. In the Command Wait Loop, which looks for commands. | |
In each pass of the loop, the currently selected CPU interface is checked | |
for a command; if present, it is executed. If not, the Command Wait Loop | |
continues. While in the loop, a 1.74 second timer is running. If it | |
expires before a command is received, the file mask is reset, the current | |
interface is disconnected, and the Poll Loop is entered. | |
3. In command execution, which processes the current command. | |
While a command is executing, any waits for input parameters, seek | |
completion, data transfers, or output status words are handled | |
internally. Each wait is governed by the 1.74 second timer; if it | |
expires, the command is aborted, the file mask is reset, the current | |
interface is disconnected, and the Poll Loop is reentered. | |
In simulation, these states are represented by the CNTLR_STATE values | |
Idle_State, Wait_State, and Busy_State, respectively. | |
A MAC controller operates from one to eight drives, represented by an array | |
of one to eight UNITs. The unit number present in the command is used to | |
index to the target unit via the "units" pointer in the DEVICE structure. | |
One additional unit that represents the controller is required, separate from | |
the individual drive units. 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 is | |
also scheduled on the controller unit to limit the amount of time the | |
controller will wait for the interface to supply a command or parameter. | |
An ICD simulation manages a single unit corresponding to the drive in which | |
the controller is integrated. A device interface declares a UNIT array | |
corresponding to the number of drives supported and passes the unit number to | |
use during controller initialization. A controller unit is not used, as all | |
commands are scheduled on the drive unit associated with a given controller. | |
On entry, the flags and controller state are examined to determine if a new | |
controller command should be initiated or the current command should be | |
continued. If this routine is being called as a result of an event service, | |
"uptr" will point at the unit being serviced. Otherwise, "uptr" will be NULL | |
(for example, when starting a new controller command). | |
If the CLEARF flag is asserted, then perform a hard clear on the controller. | |
Otherwise, if a 3000 channel error has occurred, then terminate any command | |
in progress and return I/O Program Error status. Otherwise, if the | |
controller is currently busy with a command, or if this is an event service | |
entry, then process the next step of the command. Otherwise, if the CMRDY | |
flag is asserted, then start a new command. If none of these cases pertain, | |
or if the controller is now idle, poll the drives for attention. | |
In all cases, return a combined function set and outbound data word to the | |
caller. | |
Implementation notes: | |
1. This routine will be entered when the drive unit event service occurs | |
for seek completion, and Seek_Phase processing in continue_command will | |
set the drive's Attention bit. The drives must then be polled and the | |
return functions and TIO value set to generate a CPU interrupt. | |
A seek command started on one drive while a second drive already has its | |
Attention bit set would seem to overwrite the first drive's Seek | |
completion status with the second drive's Attention status. However, | |
this won't occur because INTOK will not be set until the first drive's | |
channel program completes, and so the drive poll is inhibited until then. | |
*/ | |
CNTLR_IFN_IBUS dl_controller (CVPTR cvptr, UNIT *uptr, CNTLR_FLAG_SET flags, CNTLR_IBUS data) | |
{ | |
CNTLR_IFN_IBUS outbound; | |
dpprintf (cvptr->device, DL_DEB_IOB, "Controller (%s) received data %06o with flags %s\n", | |
state_name [cvptr->state], data, fmt_bitset (flags, flag_format)); | |
if (flags & CLEARF) { /* if the CLEAR flag is asserted */ | |
clear_controller (cvptr, Hard_Clear); /* then perform a hard clear on the controller */ | |
outbound = NO_ACTION; /* and take no other action on return */ | |
dpprintf (cvptr->device, DL_DEB_CMD, "Hard clear\n"); | |
} | |
else if (flags & XFRNG) { /* otherwise if a channel error has occurred */ | |
end_command (cvptr, uptr, IO_Program_Error); /* then terminate the command with error status */ | |
cvptr->spd_unit = 0; /* and clear the SPD and unit parts of the status */ | |
outbound = status_functions [IO_Program_Error] /* set the Status-1 value for WRTIO */ | |
| S1_STATUS (IO_Program_Error); | |
} | |
else if (uptr || cvptr->state == Busy_State) /* otherwise if a command is in process */ | |
outbound = continue_command (cvptr, uptr, flags, data); /* then continue with command processing */ | |
else if (flags & CMRDY) /* otherwise if a new command is ready */ | |
outbound = start_command (cvptr, flags, data); /* then begin command execution */ | |
else /* otherwise there's nothing to do */ | |
outbound = NO_ACTION; /* except possibly poll for attention */ | |
if (cvptr->state == Idle_State /* if the controller is idle */ | |
&& cvptr->type == MAC /* and it's a MAC controller */ | |
&& flags & INTOK) /* and interrupts are allowed */ | |
outbound = poll_drives (cvptr); /* then poll the drives for attention */ | |
dpprintf (cvptr->device, DL_DEB_IOB, "Controller (%s) returned data %06o with functions %s\n", | |
state_name [cvptr->state], DLIBUS (outbound), | |
fmt_bitset (DLIFN (outbound), function_format)); | |
return outbound; | |
} | |
/* Start a new command. | |
This routine simulates the controller microcode entry into the command | |
executor corresponding to the command presented by the CPU interface. It's | |
called when the controller is waiting for a command and the interface asserts | |
CMRDY to indicate that a new command is available. It returns a set of | |
action functions and a data word to the caller. For a good command, it also | |
sets up the next phase of operation on the controller and/or drive unit and | |
schedules the unit(s) as appropriate. | |
On entry, the command word is supplied in the "inbound_data" parameter; this | |
simulates the microcode issuing an IFPRF (Interface Prefetch) to obtain the | |
command. The opcode is isolated from the command word and checked for | |
validity. If it's OK, it's used as an index into the command properties | |
table. If the command contains a unit number field, it is extracted, checked | |
for validity, and used to derive a pointer to the corresponding UNIT | |
structure. If the command does not access the drive, or if the unit number | |
is invalid, the unit pointer is set to NULL. A pointer to the controller | |
unit is also set up; for ICD controllers, the controller and drive unit are | |
the same. | |
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. | |
If a diagnostic override is defined, and the cylinder, head, sector, and | |
opcode values from the current override entry match their corresponding | |
controller values, then the status and SPD values are set from the entry | |
rather than being cleared, and the pointer is moved to the next entry. The | |
controller is then set to the busy state, and the validity of the opcode and | |
unit are checked. If any errors are detected, the appropriate status is set, | |
and the controller unit is scheduled for the End_Phase to simulate the | |
controller processing overhead. | |
If the command and unit are valid, then if the command accesses a drive unit, | |
the unit's OPCODE field is set, and any pending Attention status is cleared. | |
If the command takes or returns parameters, then the Parameter_Phase is set | |
up on the controller unit and the wait timer is started. Commands that | |
return parameters temporarily store their parameter values in the sector | |
buffer at this time for return as the CPU interface requests them. The Cold | |
Load Read and Recalibrate commands start their respective seeks at this time, | |
and commands that complete immediately, e.g., Set File Mask, Wakeup, etc., | |
schedule the End_Phase on the controller unit and set up the status value for | |
return if they end with the WRTIO function. | |
Finally, the controller and/or drive units are activated if they were | |
scheduled. If a seek is in progress on a drive when a command that | |
waits for seek completion is started, the unit is not rescheduled. Instead, | |
the unit is left in the Seek_Phase, but the unit's OPCODE field is changed to | |
reflect the new command so that the command will start automatically when the | |
seek completes. | |
Implementation notes: | |
1. A command is started only if the controller is not busy. Therefore, the | |
target unit can be only in either the Seek_Phase or the Idle_Phase, as | |
all other phases will have the controller in the Busy_State. | |
2. Commands that access units and take parameters (e.g., Verify) set up the | |
parameter access on the controller unit but perform the rest of the | |
operation on the drive unit. The controller must be used so that | |
parameters may be read for the next command for a unit that is currently | |
seeking (stacked commands wait for seek completion after parameters have | |
been read). | |
3. Drive Attention may be still set on a drive that has completed a seek but | |
has not been able to interrupt the CPU before a new command is started. | |
Therefore, Attention is always cleared when a command starts. | |
4. In hardware, the Recalibrate command waits for a seek-in-progress to | |
complete before the RCL tag is sent to the drive. In simulation, | |
repositioning the heads to cylinder 0 is started immediately, but any | |
remaining time from a seek-in-progress is added to the time required for | |
repositioning. The effect is that recalibration completes in the time it | |
would have taken for the seek-in-progress to complete followed by | |
repositioning from that location. | |
5. The Cold Load Read command does not check for Access Not Ready before | |
issuing the seek to cylinder 0, so if a seek or recalibrate is in | |
progress, the drive will reject it with a Seek Check error. However, the | |
command continues, and when the seek in progress completes and the read | |
begins, the Seek Check error will abort the command at this point with a | |
Status-2 Error. | |
6. ECC is not simulated, so the Request Syndrome command always returns zero | |
values for the displacement and patterns and Uncorrectable Data Error for | |
the status, unless a diagnostic override is in effect. | |
7. The Wakeup command references a drive unit but is scheduled on the | |
controller unit because it may be issued while the drive is seeking. | |
*/ | |
static CNTLR_IFN_IBUS start_command (CVPTR cvptr, CNTLR_FLAG_SET inbound_flags, CNTLR_IBUS inbound_data) | |
{ | |
UNIT *cuptr, *duptr, *rptr; | |
uint32 unit; | |
int32 seek_wait_time; | |
PRPTR props; | |
CNTLR_IFN_IBUS outbound; | |
char s1_buffer [256], s2_buffer [256]; /* formatted bitset buffers for trace logging */ | |
wait_timer (cvptr, CLEAR); /* stop the command wait timer */ | |
cvptr->opcode = CM_OPCODE (inbound_data); /* get the opcode from the command */ | |
if (cvptr->opcode > LAST_OPCODE /* if the opcode is undefined */ | |
|| cvptr->type > LAST_CNTLR /* or the controller type is undefined */ | |
|| cmd_props [cvptr->opcode].valid [cvptr->type] == FALSE) /* or the opcode is not valid for this controller */ | |
cvptr->opcode = Invalid_Opcode; /* then replace it with the invalid opcode */ | |
props = &cmd_props [cvptr->opcode]; /* get the properties associated with the opcode */ | |
if (cvptr->type == MAC) { /* if this a MAC controller */ | |
if (props->unit_field) /* then if the unit field is defined */ | |
unit = CM_UNIT (inbound_data); /* then get it from the command */ | |
else /* otherwise the unit is not specified in the command */ | |
unit = 0; /* so the unit is always unit 0 */ | |
cuptr = CNTLR_UPTR; /* set the controller unit pointer */ | |
if (unit > DL_MAXDRIVE /* if the unit number is invalid */ | |
|| props->unit_access == FALSE) /* or the command accesses the controller only */ | |
duptr = NULL; /* then the drive pointer does not correspond to a unit */ | |
else /* otherwise the command accesses a valid drive unit */ | |
duptr = cvptr->device->units + unit; /* so set the drive pointer to the unit */ | |
} | |
else { /* otherwise this is an ICD or CS/80 controller */ | |
unit = 0; /* so the unit value isn't used */ | |
cuptr = duptr = /* and the unit number was predefined */ | |
cvptr->device->units + cvptr->poll_unit; /* when the controller structure was initialized */ | |
} | |
dpprintf (cvptr->device, DL_DEB_INCO, "Unit %d %s command started\n", | |
unit, opcode_name [cvptr->opcode]); | |
if (cvptr->dop /* if the diagnostic override table is defined */ | |
&& cvptr->dop->cylinder == cvptr->cylinder /* and the cylinder, */ | |
&& cvptr->dop->head == cvptr->head /* head, */ | |
&& cvptr->dop->sector == cvptr->sector /* sector, */ | |
&& cvptr->dop->opcode == cvptr->opcode) { /* and opcode values match the current values */ | |
cvptr->spd_unit = cvptr->dop->spd | unit; /* then override the Spare/Protected/Defective */ | |
cvptr->status = cvptr->dop->status; /* and status values from the override entry */ | |
cvptr->dop++; /* point at the next table entry */ | |
dpprintf (cvptr->device, DL_DEB_INCO, "Unit %d cylinder %d head %d sector %d diagnostic override\n", | |
unit, cvptr->cylinder, cvptr->head, cvptr->sector); | |
} | |
else if (props->clear_status) { /* otherwise if this command clears prior status */ | |
cvptr->status = Normal_Completion; /* then do it */ | |
cvptr->spd_unit = unit; /* and save the unit number for status requests */ | |
} | |
cvptr->state = Busy_State; /* the controller is now busy */ | |
cvptr->index = 0; /* reset the buffer index */ | |
cvptr->count = 0; /* and the sector/word count */ | |
cvptr->verify = props->verify_address; /* set the address verification flag */ | |
cuptr->OPCODE = cvptr->opcode; /* set the controller unit opcode */ | |
cuptr->wait = NO_EVENT; /* and assume no controller scheduling */ | |
outbound = cmd_functions [cvptr->opcode] [Idle_Phase]; /* set up the initial function set and zero data */ | |
if (cvptr->opcode == Invalid_Opcode) /* if the opcode is invalid */ | |
set_completion (cvptr, cuptr, Illegal_Opcode); /* then finish with an illegal opcode error */ | |
else if (props->unit_check && unit > MAX_UNIT) /* otherwise if the unit number is checked and is illegal */ | |
set_completion (cvptr, cuptr, Unit_Unavailable); /* then finish with a unit unavailable error */ | |
else if (props->unit_check && unit > DL_MAXDRIVE /* otherwise if the unit number is checked and is invalid */ | |
|| props->seek_wait && (drive_status (duptr) & S2_STOPS)) /* or if we're waiting for an offline drive */ | |
set_completion (cvptr, cuptr, Status_2_Error); /* then finish with a Status-2 error */ | |
else { /* otherwise the command and unit are valid */ | |
if (duptr) { /* if the drive unit is accessed */ | |
duptr->OPCODE = cvptr->opcode; /* then set the drive opcode for later reference */ | |
duptr->wait = NO_EVENT; /* assume no drive scheduling */ | |
duptr->STATUS &= ~S2_ATTENTION; /* clear any pending Attention status */ | |
} | |
if (props->param_count != 0) { /* if the command takes or returns parameters */ | |
cvptr->length = props->param_count; /* then set the parameter count */ | |
cuptr->PHASE = Parameter_Phase; /* set up the parameter transfer on the controller */ | |
wait_timer (cvptr, SET); /* and start the timer to wait for the first parameter */ | |
} | |
switch (cvptr->opcode) { /* dispatch the command for initiation */ | |
case Cold_Load_Read: | |
cvptr->cylinder = 0; /* set the cylinder address to 0 */ | |
cvptr->head = CM_HEAD (inbound_data); /* set the head and */ | |
cvptr->sector = CM_SECTOR (inbound_data); /* sector addresses from the command */ | |
if (start_seek (cvptr, duptr) == FALSE) /* start the seek; if it failed */ | |
set_completion (cvptr, cuptr, Status_2_Error); /* then set up the completion status */ | |
dpprintf (cvptr->device, DL_DEB_CMD, "Unit %d %s from cylinder %d head %d sector %d\n", | |
unit, opcode_name [Cold_Load_Read], cvptr->cylinder, cvptr->head, cvptr->sector); | |
break; /* wait for seek completion */ | |
case Recalibrate: | |
dpprintf (cvptr->device, DL_DEB_CMD, "Unit %d %s to cylinder 0\n", | |
unit, opcode_name [Recalibrate]); | |
if (duptr->PHASE == Seek_Phase) { /* if the unit is currently seeking */ | |
seek_wait_time = sim_activate_time (duptr); /* then get the remaining event time */ | |
sim_cancel (duptr); /* cancel the event to allow rescheduling */ | |
duptr->PHASE = Idle_Phase; /* and idle the drive so that the seek succeeds */ | |
dpprintf (cvptr->device, DL_DEB_INCO, "Unit %d %s command waiting for seek completion\n", | |
unit, opcode_name [Recalibrate]); | |
} | |
else /* otherwise the drive is idle */ | |
seek_wait_time = 0; /* so there's no seek wait time */ | |
if (start_seek (cvptr, duptr) == FALSE) /* start the seek; if it failed */ | |
set_completion (cvptr, cuptr, Status_2_Error); /* then set up the completion status */ | |
else if (cvptr->type == MAC) /* otherwise if this a MAC controller */ | |
set_completion (cvptr, cuptr, Normal_Completion); /* then schedule seek completion */ | |
duptr->wait = duptr->wait + seek_wait_time; /* increase the delay by any remaining seek time */ | |
break; /* and wait for the recalibrate to complete */ | |
case Request_Status: | |
cvptr->buffer [0] = (uint16) (cvptr->spd_unit /* set the Status-1 value */ | |
| S1_STATUS (cvptr->status)); /* into the buffer */ | |
if (cvptr->type == MAC) /* if this a MAC controller */ | |
if (unit > DL_MAXDRIVE) /* then if the unit number is invalid */ | |
rptr = NULL; /* then it does not correspond to a unit */ | |
else /* otherwise the unit is valid */ | |
rptr = cvptr->device->units + unit; /* so get the address of the referenced unit */ | |
else /* otherwise it is not a MAC controller */ | |
rptr = duptr; /* so the referenced unit is the current unit */ | |
cvptr->buffer [1] = drive_status (rptr); /* set the Status-2 value into the buffer */ | |
dpprintf (cvptr->device, DL_DEB_CMD, "Unit %d %s returns %sunit %d | %s and %s%s | %s\n", | |
unit, opcode_name [Request_Status], | |
strcpy (s1_buffer, fmt_bitset (cvptr->spd_unit, status_1_format)), | |
CM_UNIT (cvptr->spd_unit), dl_status_name (cvptr->status), | |
(cvptr->buffer [1] & S2_ERROR ? "error | " : ""), | |
drive_props [S2_TO_DRIVE_TYPE (cvptr->buffer [1])].name, | |
strcpy (s2_buffer, fmt_bitset (cvptr->buffer [1], status_2_format))); | |
if (rptr) /* if the referenced unit is valid */ | |
rptr->STATUS &= ~S2_FIRST_STATUS; /* then clear the First Status bit */ | |
cvptr->spd_unit = S1_UNIT (unit); /* save the unit number referenced in the command */ | |
if (unit > MAX_UNIT) /* if the unit number is illegal */ | |
cvptr->status = Unit_Unavailable; /* then the next status will be Unit Unavailable */ | |
else /* otherwise a legal unit */ | |
cvptr->status = Normal_Completion; /* clears the controller status */ | |
break; | |
case Request_Sector_Address: | |
if (drive_status (duptr) & S2_NOT_READY) /* if the drive is not ready */ | |
set_completion (cvptr, cuptr, Status_2_Error); /* then finish with Not Ready status */ | |
else /* otherwise the drive is ready */ | |
cvptr->buffer [0] = /* so calculate the current sector address */ | |
(uint16) CURRENT_SECTOR (cvptr, duptr); | |
dpprintf (cvptr->device, DL_DEB_CMD, "Unit %d %s returns sector %d\n", | |
unit, opcode_name [Request_Sector_Address], cvptr->buffer [0]); | |
break; | |
case Clear: | |
clear_controller (cvptr, Soft_Clear); /* clear the controller */ | |
set_completion (cvptr, cuptr, Normal_Completion); /* and schedule the command completion */ | |
dpprintf (cvptr->device, DL_DEB_CMD, "%s\n", opcode_name [Clear]); | |
break; | |
case Request_Syndrome: | |
if (cvptr->status == Correctable_Data_Error) { /* if we've been called with a correction override */ | |
cvptr->buffer [3] = (uint16) cvptr->dop->spd; /* then load the displacement */ | |
cvptr->buffer [4] = (uint16) cvptr->dop->cylinder; /* and three */ | |
cvptr->buffer [5] = (uint16) cvptr->dop->head; /* syndrome words */ | |
cvptr->buffer [6] = (uint16) cvptr->dop->sector; /* from the override entry */ | |
cvptr->dop++; /* point at the next entry */ | |
} | |
else { /* otherwise no correction data was supplied */ | |
cvptr->buffer [3] = 0; /* so the displacement is always zero */ | |
cvptr->buffer [4] = 0; /* as are */ | |
cvptr->buffer [5] = 0; /* the three */ | |
cvptr->buffer [6] = 0; /* syndrome words */ | |
if (cvptr->status == Normal_Completion) /* if we've been called without an override */ | |
cvptr->status = Uncorrectable_Data_Error; /* then presume that an uncorrectable error occurred */ | |
} | |
cvptr->buffer [0] = (uint16) (cvptr->spd_unit /* save the Status-1 value */ | |
| S1_STATUS (cvptr->status)); /* in the buffer */ | |
set_address (cvptr, 1); /* save the CHS values in the buffer */ | |
dpprintf (cvptr->device, DL_DEB_CMD, "%s returns %sunit %d | %s | cylinder %d head %d sector %d | " | |
"syndrome %06o %06o %06o %06o\n", | |
opcode_name [Request_Syndrome], fmt_bitset (cvptr->spd_unit, status_1_format), | |
CM_UNIT (cvptr->spd_unit), dl_status_name (cvptr->status), | |
cvptr->cylinder, cvptr->head, cvptr->sector, | |
cvptr->buffer [3], cvptr->buffer [4], cvptr->buffer [5], cvptr->buffer [6]); | |
next_sector (cvptr, cvptr->device->units /* address the next sector of the last unit used */ | |
+ S1_UNIT (cvptr->spd_unit)); | |
break; | |
case Set_File_Mask: | |
cvptr->file_mask = CM_FILE_MASK (inbound_data); /* save the supplied file mask */ | |
outbound |= CM_RETRY (inbound_data); /* return the retry count */ | |
set_completion (cvptr, cuptr, Normal_Completion); /* schedule the command completion */ | |
dpprintf (cvptr->device, DL_DEB_CMD, "%s to %sretries %d\n", | |
opcode_name [Set_File_Mask], fmt_bitset (cvptr->file_mask, file_mask_format), | |
CM_RETRY (inbound_data)); | |
break; | |
case Request_Disc_Address: | |
set_address (cvptr, 0); /* set the controller's CHS values into the buffer */ | |
dpprintf (cvptr->device, DL_DEB_CMD, "Unit %d %s returns cylinder %d head %d sector %d\n", | |
unit, opcode_name [Request_Disc_Address], cvptr->cylinder, cvptr->head, cvptr->sector); | |
break; | |
case End: | |
dpprintf (cvptr->device, DL_DEB_CMD, "%s\n", opcode_name [End]); | |
end_command (cvptr, NULL, Normal_Completion); /* end the command and idle the controller */ | |
break; | |
case Wakeup: | |
set_completion (cvptr, cuptr, Unit_Available); /* schedule the command completion */ | |
dpprintf (cvptr->device, DL_DEB_CMD, "Unit %d %s\n", | |
unit, opcode_name [Wakeup]); | |
break; | |
/* these commands wait for seek completion before starting */ | |
case Read_Without_Verify: | |
cvptr->verify = FALSE; /* do not verify until a track is crossed */ | |
inbound_data &= ~CM_SPD_MASK; /* clear the SPD bits to avoid changing the state */ | |
/* fall into the Initialize case */ | |
case Initialize: | |
cvptr->spd_unit |= CM_SPD (inbound_data); /* merge the SPD flags with the unit */ | |
/* fall into the read/write cases */ | |
case Read: | |
case Read_Full_Sector: | |
case Write: | |
case Write_Full_Sector: | |
if (duptr->PHASE == Seek_Phase) /* if the unit is currently seeking */ | |
dpprintf (cvptr->device, DL_DEB_INCO, "Unit %d %s command waiting for seek completion\n", | |
unit, opcode_name [cvptr->opcode]); | |
else /* otherwise the unit is idle */ | |
set_rotation (cvptr, duptr); /* so set up the rotation phase and latency */ | |
break; | |
/* these commands take parameters but otherwise require no preliminary work */ | |
case Seek: | |
case Verify: | |
case Address_Record: | |
case Read_With_Offset: | |
case Load_TIO_Register: | |
break; | |
case Invalid_Opcode: /* for completeness; invalid commands are not dispatched */ | |
break; | |
} | |
} | |
if (cvptr->state == Busy_State) { /* if the command has not completed immediately */ | |
if (cuptr->wait != NO_EVENT && cvptr->type == MAC) /* then if the controller unit is scheduled */ | |
activate_unit (cvptr, cuptr); /* then activate it */ | |
if (duptr && duptr->wait != NO_EVENT) /* and if the drive unit is valid and scheduled */ | |
activate_unit (cvptr, duptr); /* then activate it as well */ | |
} | |
if (outbound & WRTIO) /* if status is expected immediately */ | |
outbound |= S1_STATUS (cvptr->status) | cvptr->spd_unit; /* then return the Status-1 value */ | |
return outbound; /* return the data word and function set */ | |
} | |
/* Continue the current command. | |
This routine simulates continuing execution of the controller microcode for | |
the current command. It's called whenever the controller has had to wait for | |
action from the CPU interface or the drive unit, and that action has now | |
occurred. Typically, this would be whenever the interface flag status | |
changes, or a unit's event service has been entered. It returns a set of | |
action functions and a data word to the caller. It also sets up the next | |
phase of operation on the controller and/or drive unit and schedules the | |
unit(s) as appropriate. | |
On entry, the "uptr" parameter is set to NULL if the controller was called | |
for a CPU interface action, or it points to the unit whose event service was | |
just called; this may be either the controller unit or a drive unit. The | |
"inbound_flags" and "inbound_data" parameters contain the CPU interface flags | |
and data buffer values. | |
If the entry is for a unit service, the unit number of the drive requesting | |
service is determined. If the entry is for the CPU interface, the controller | |
is checked; if it's idle, the routine returns because no command is in | |
progress. | |
While a unit is activated, the current phase indicates the reason for the | |
activation, i.e., what the simulated drive is "doing" at the moment, as | |
follows: | |
Idle_Phase -- waiting for the next command to be issued (note that | |
this phase, which indicates that the unit is not | |
scheduled, is distinct from the controller Idle_State, | |
which indicates that the controller itself is idle) | |
Parameter_Phase -- waiting for a parameter to be transferred to or from | |
the interface | |
Seek_Phase -- waiting for a seek to complete (explicit or automatic) | |
Rotate_Phase -- waiting for the target sector to arrive under the head | |
Data_Phase -- waiting for the interface to accept or return the next | |
data word to be transferred to or from the drive | |
Intersector_Phase -- waiting for the controller to finish executing the | |
end-of-sector microcode | |
End_Phase -- waiting for the controller to finish executing the | |
microcode corresponding to the current command | |
Depending on the current command opcode and phase, a number of actions may be | |
taken: | |
Idle_Phase -- If the controller unit is being serviced, then the 1.74 | |
second command wait timer has expired while waiting for a new command. | |
Reset the file mask and idle the controller. | |
Parameter_Phase -- If the controller unit is being serviced, then the 1.74 | |
second command wait timer has expired while waiting for a parameter from | |
the CPU. Reset the file mask and idle the controller. Otherwise, for | |
outbound parameters, return the next word from the sector buffer and | |
restart the timer; if the last word has been sent, end the command. For | |
inbound parameters, store the next word in the appropriate controller state | |
variable; if the last word has been received, end the command or set up the | |
next operation phase (seek, rotate, etc.). | |
Seek_Phase -- If a Seek or Recalibrate has completed, set Drive Attention | |
status. All other commands have been waiting for seek completion before | |
starting, so set up the rotate phase to begin the command. | |
Rotate_Phase -- Set up the read or write of the current sector. For all | |
commands except Verify, proceed to the data phase to begin the data | |
transfer. For Verify, skip the data phase and proceed directly to the | |
end-of-sector processing, but schedule that event as though the full sector | |
rotation time had elapsed. | |
Data_Phase -- For read transfers, return the next word from the sector | |
buffer, or for write transfers, store the next word into the sector buffer, | |
and schedule the next data phase transfer if the CPU has not indicated an | |
end-of-data condition. If it has, or if the last word of the sector has | |
been transmitted, schedule the intersector phase. | |
Intersector_Phase -- Complete the read or write of the current sector. If | |
the CPU has indicated an end-of-data condition, end the command. | |
Otherwise, address the next sector and schedule the rotate phase. | |
End_Phase -- End the command. The end phase is used to provide a | |
controller delay when an operation has no other command phases. | |
At the completion of the current phase, the next phase is scheduled, if | |
required, before returning the appropriate function set and data word to the | |
caller. | |
The commands employ the various phases as follows: | |
Inter | |
Command Param Seek Rotate Data sector End | |
+------------------------+-------+------+--------+------+--------+-----+ | |
| Cold Load Read | - | D | D | D | D | - | | |
| Recalibrate | - | D | - | - | - | - | | |
| Seek | c | D | - | - | - | - | | |
| Request Status | c | - | - | - | - | - | | |
| Request Sector Address | c | - | - | - | - | - | | |
| Read | - | - | D | D | D | - | | |
| Read Full Sector | - | - | D | D | D | - | | |
| Verify | c | - | D | - | D | - | | |
| Write | - | - | D | D | D | - | | |
| Write Full Sector | - | - | D | D | D | - | | |
| Clear | - | - | - | - | - | C | | |
| Initialize | - | - | D | D | D | - | | |
| Address Record | c | - | - | - | - | - | | |
| Request Syndrome | c | - | - | - | - | - | | |
| Read With Offset | c | - | D | D | D | - | | |
| Set File Mask | - | - | - | - | - | C | | |
| Invalid Opcode | - | - | - | - | - | C | | |
| Read Without Verify | - | - | D | D | D | - | | |
| Load TIO Register | c | - | - | - | - | - | | |
| Request Disc Address | c | - | - | - | - | - | | |
| End | - | - | - | - | - | - | | |
| Wakeup | - | - | - | - | - | C | | |
+------------------------+-------+------+--------+------+--------+-----+ | |
Key: | |
C = controller unit is scheduled | |
c = controller is called directly by the CPU interface | |
D = drive unit is scheduled | |
- = the phase is not used | |
Implementation notes: | |
1. The "%.0d" print specification in the trace call absorbs the zero "unit" | |
value parameter without printing when the controller unit is specified. | |
2. The Seek command does not check for Access Not Ready before issuing the | |
seek, so if a prior seek is in progress, the drive will reject it with a | |
Seek Check error. However, 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. | |
3. The set of interface functions to assert on command completion is | |
normally specified by the End_Phase entry in the cmd_functions table, | |
regardless of whether or not a command has an end phase. However, the | |
Request Syndrome command returns either Correctable Data Error or | |
Uncorrectable Data Error for normal command completion. These status | |
returns would normally include DVEND to indicate that the command should | |
be retried, but that's wrong for Request Syndrome, so we explicitly | |
override the function set for this command. | |
4. Command completion must be detected by the controller state changing to | |
"not busy" rather than simply being "not busy" at the end of the routine. | |
Otherwise, a seek that completes while the controller is waiting for a | |
command would re-issue the end phase functions. | |
5. The disc is a synchronous device, so overrun or underrun can occur if the | |
interface is not ready when the controller must transfer data. There are | |
four conditions that lead to an overrun or underrun: | |
a. The controller is ready with a disc read word (IFCLK * IFIN), but | |
the interface buffer is full (DTRDY). | |
b. The controller needs a disc write word (IFCLK * IFOUT), but the | |
interface buffer is empty (~DTRDY). | |
c. The CPU attempts to read a word, but the interface buffer is empty | |
(~DTRDY). | |
d. The CPU attempts to write a word, but the interface buffer is full | |
(DTRDY). | |
The 13037 controller ORs the interface-supplied OVRUN signal with an | |
internal overrun latch that sets on condition 2 above (write underrun). | |
However, both the 13175A HP 1000 interface and the 30229B HP 3000 | |
interface assert OVRUN for all four conditions, so the latch is not | |
simulated. | |
6. Not all changes of CPU interface flag status are significant. If the | |
routine is called when it isn't needed, the routine simply returns with | |
no action. | |
*/ | |
static CNTLR_IFN_IBUS continue_command (CVPTR cvptr, UNIT *uptr, CNTLR_FLAG_SET inbound_flags, CNTLR_IBUS inbound_data) | |
{ | |
const t_bool service_entry = (uptr != NULL); /* set TRUE if entered via unit service */ | |
CNTLR_OPCODE opcode; | |
CNTLR_PHASE phase; | |
CNTLR_IFN_IBUS outbound; | |
t_bool controller_service, controller_was_busy; | |
uint32 unit, sector_count; | |
if (service_entry) { /* if this is an event service entry */ | |
unit = uptr - cvptr->device->units; /* then get the unit number */ | |
controller_service = (uptr == CNTLR_UPTR /* set TRUE if the controller is being serviced */ | |
&& cvptr->type == MAC); | |
} | |
else if (CNTLR_UPTR->PHASE == Idle_Phase) /* otherwise if this interface entry isn't needed */ | |
return NO_ACTION; /* then quit as there's nothing to do */ | |
else { /* otherwise the controller is expecting the entry */ | |
uptr = CNTLR_UPTR; /* set up to use the controller unit */ | |
unit = CNTLR_UNIT; /* and unit number */ | |
controller_service = FALSE; /* but note that this isn't a service entry */ | |
} | |
opcode = (CNTLR_OPCODE) uptr->OPCODE; /* get the current opcode */ | |
phase = (CNTLR_PHASE) uptr->PHASE; /* and command phase */ | |
if (controller_service == FALSE || phase == End_Phase) | |
dpprintf (cvptr->device, DL_DEB_STATE, (unit == CNTLR_UNIT | |
? "Controller unit%.0d %s %s phase entered from %s\n" | |
: "Unit %d %s %s phase entered from %s\n"), | |
(unit == CNTLR_UNIT ? 0 : unit), opcode_name [opcode], phase_name [phase], | |
(service_entry ? "service" : "interface")); | |
controller_was_busy = (cvptr->state == Busy_State); /* set TRUE if the controller was busy on entry */ | |
outbound = cmd_functions [opcode] [phase]; /* set up the initial function return set */ | |
switch (phase) { /* dispatch the phase */ | |
case Idle_Phase: /* the command wait timer has expired */ | |
clear_controller (cvptr, Timeout_Clear); /* so idle the controller and clear the file mask */ | |
outbound = NO_FUNCTIONS; /* clear the function set for an idle return */ | |
dpprintf (cvptr->device, DL_DEB_INCO, "Controller command wait timed out\n"); | |
break; | |
case Parameter_Phase: | |
if (controller_service) { /* if the parameter wait timer has expired */ | |
clear_controller (cvptr, Timeout_Clear); /* then idle the controller and clear the file mask */ | |
outbound = NO_FUNCTIONS; /* clear the function set for an idle return */ | |
dpprintf (cvptr->device, DL_DEB_INCO, "Unit %d %s command aborted with parameter wait timeout\n", | |
CM_UNIT (cvptr->spd_unit), opcode_name [opcode]); | |
} | |
else switch (opcode) { /* otherwise dispatch the command */ | |
case Request_Status: /* these commands */ | |
case Request_Disc_Address: /* return parameters */ | |
case Request_Sector_Address: /* to the interface */ | |
case Request_Syndrome: | |
if (cvptr->length == 0) /* if the last parameter has been sent */ | |
end_command (cvptr, uptr, cvptr->status); /* then terminate the command with the preset status */ | |
else { /* otherwise there are more to send */ | |
outbound |= cvptr->buffer [cvptr->index++]; /* so return the next value from the buffer */ | |
cvptr->length = cvptr->length - 1; /* and drop the parameter count */ | |
wait_timer (cvptr, SET); /* restart the parameter timer */ | |
} | |
break; | |
case Seek: /* these commands receive parameters */ | |
case Address_Record: /* from the interface */ | |
cvptr->buffer [cvptr->index++] = inbound_data; /* save the current one in the buffer */ | |
cvptr->length = cvptr->length - 1; /* and drop the parameter count */ | |
if (cvptr->length > 0) /* if another parameter is expected */ | |
wait_timer (cvptr, SET); /* then restart the parameter timer */ | |
else { /* otherwise all parameters are in */ | |
cvptr->cylinder = cvptr->buffer [0]; /* so fill in the supplied cylinder */ | |
cvptr->head = PI_HEAD (cvptr->buffer [1]); /* and head */ | |
cvptr->sector = PI_SECTOR (cvptr->buffer [1]); /* and sector addresses */ | |
if (opcode == Address_Record) { /* if this is an Address Record command */ | |
cvptr->eoc = CLEAR; /* then clear the end-of-cylinder flag */ | |
dpprintf (cvptr->device, DL_DEB_CMD, "%s to cylinder %d head %d sector %d\n", | |
opcode_name [Address_Record], | |
cvptr->cylinder, cvptr->head, cvptr->sector); | |
end_command (cvptr, uptr, /* the command is now complete */ | |
Normal_Completion); | |
} | |
else { /* otherwise it's a Seek command */ | |
dpprintf (cvptr->device, DL_DEB_CMD, "Unit %d %s to cylinder %d head %d sector %d\n", | |
CM_UNIT (cvptr->spd_unit), opcode_name [Seek], | |
cvptr->cylinder, cvptr->head, cvptr->sector); | |
uptr = cvptr->device->units /* get the target unit */ | |
+ CM_UNIT (cvptr->spd_unit); | |
if (start_seek (cvptr, uptr) == FALSE) /* start the seek; if it failed, */ | |
end_command (cvptr, uptr, /* then report the error */ | |
Status_2_Error); | |
else if (cvptr->type == MAC) /* otherwise if this a MAC controller */ | |
end_command (cvptr, uptr, /* then complete the command and idle the controller */ | |
Normal_Completion); | |
} /* otherwise an ICD command ends when the seek completes */ | |
} | |
break; | |
case Verify: | |
if (inbound_data == 0) /* if the sector count is zero */ | |
sector_count = 65536; /* then use the rollover count */ | |
else /* otherwise */ | |
sector_count = inbound_data; /* use the count as is */ | |
cvptr->count = sector_count * WORDS_PER_SECTOR; /* convert to the number of words to verify */ | |
dpprintf (cvptr->device, DL_DEB_CMD, "Unit %d %s %d sector%s\n", | |
CM_UNIT (cvptr->spd_unit), opcode_name [Verify], | |
sector_count, (sector_count == 1 ? "" : "s")); | |
wait_timer (cvptr, CLEAR); /* stop the parameter timer */ | |
uptr = cvptr->device->units /* get the target unit */ | |
+ CM_UNIT (cvptr->spd_unit); | |
if (uptr->PHASE == Seek_Phase) { /* if a seek is in progress, */ | |
uptr->wait = NO_EVENT; /* then wait for it to complete */ | |
dpprintf (cvptr->device, DL_DEB_INCO, "Unit %d %s command waiting for seek completion\n", | |
CM_UNIT (cvptr->spd_unit), opcode_name [Verify]); | |
} | |
else /* otherwise the unit is idle */ | |
set_rotation (cvptr, uptr); /* so set up the rotation phase and latency */ | |
break; | |
case Read_With_Offset: | |
dpprintf (cvptr->device, DL_DEB_CMD, "Unit %d %s using %soffset %+d\n", | |
CM_UNIT (cvptr->spd_unit), opcode_name [Read_With_Offset], | |
fmt_bitset (inbound_data, offset_format), | |
(inbound_data & PI_NEG_OFFSET ? - (int) PI_OFFSET (inbound_data) | |
: PI_OFFSET (inbound_data))); | |
wait_timer (cvptr, CLEAR); /* stop the parameter timer */ | |
uptr = cvptr->device->units /* get the target unit */ | |
+ CM_UNIT (cvptr->spd_unit); | |
if (uptr->PHASE == Seek_Phase) { /* if a seek is in progress, */ | |
uptr->wait = NO_EVENT; /* then wait for it to complete */ | |
dpprintf (cvptr->device, DL_DEB_INCO, "Unit %d %s command waiting for seek completion\n", | |
CM_UNIT (cvptr->spd_unit), opcode_name [Read_With_Offset]); | |
} | |
else { /* otherwise the unit is idle */ | |
uptr->PHASE = Seek_Phase; /* so schedule the seek phase */ | |
uptr->wait = cvptr->dlyptr->seek_one; /* with the offset positioning delay */ | |
} | |
break; | |
case Load_TIO_Register: | |
wait_timer (cvptr, CLEAR); /* stop the parameter timer */ | |
dpprintf (cvptr->device, DL_DEB_CMD, "%s with %06o\n", | |
opcode_name [Load_TIO_Register], inbound_data); | |
end_command (cvptr, uptr, Normal_Completion); /* complete the command */ | |
return inbound_data /* return the supplied TIO value */ | |
| cmd_functions [Load_TIO_Register] [End_Phase]; | |
break; | |
default: /* the remaining commands */ | |
break; /* do not have a parameter phase */ | |
} | |
break; | |
case Seek_Phase: | |
switch (opcode) { /* dispatch the command */ | |
case Recalibrate: | |
case Seek: | |
if (cvptr->type == MAC) { /* if this a MAC controller */ | |
uptr->STATUS |= S2_ATTENTION; /* set Attention in the unit status */ | |
uptr->PHASE = Idle_Phase; /* and idle the drive */ | |
} | |
else /* otherwise this is an ICD or CS/80 drive */ | |
end_command (cvptr, uptr, Drive_Attention); /* so seeks end with Drive Attention status */ | |
break; | |
case Cold_Load_Read: | |
cvptr->file_mask = CM_SPARE_EN; /* enable sparing in surface mode without auto-seek */ | |
/* fall into the default case */ | |
default: /* a command was waiting on seek completion */ | |
set_rotation (cvptr, uptr); /* so set up the rotation phase and latency */ | |
break; | |
} | |
break; | |
case Rotate_Phase: | |
switch (opcode) { /* dispatch the command */ | |
case Write: | |
case Write_Full_Sector: | |
case Initialize: | |
start_write (cvptr, uptr); /* start the sector write */ | |
break; | |
case Read: | |
case Read_Full_Sector: | |
case Read_With_Offset: | |
case Read_Without_Verify: | |
case Cold_Load_Read: | |
start_read (cvptr, uptr, inbound_flags); /* start the sector read */ | |
break; | |
case Verify: | |
inbound_flags &= ~EOD; /* EOD is not relevant for Verify */ | |
if (start_read (cvptr, uptr, inbound_flags)) { /* if the sector read was set up successfully */ | |
uptr->PHASE = Intersector_Phase; /* then skip the data phase */ | |
uptr->wait = cvptr->dlyptr->sector_full; /* and reschedule for the sector read time */ | |
} | |
break; | |
default: /* the remaining commands */ | |
break; /* do not have a rotate phase */ | |
} | |
break; | |
case Data_Phase: | |
if (inbound_flags & EOD) /* if the transfer has ended */ | |
outbound = NO_FUNCTIONS; /* then don't assert IFIN/IFOUT on return */ | |
switch (opcode) { /* dispatch the command */ | |
case Read: | |
case Read_With_Offset: | |
case Read_Without_Verify: | |
case Read_Full_Sector: | |
case Cold_Load_Read: | |
if ((inbound_flags & EOD) == NO_FLAGS) { /* if the transfer continues */ | |
outbound |= cvptr->buffer [cvptr->index++]; /* then get the next word from the buffer */ | |
cvptr->count = cvptr->count + 1; /* count the */ | |
cvptr->length = cvptr->length - 1; /* transfer */ | |
dpprintf (cvptr->device, DL_DEB_XFER, "Unit %d %s word %d is %06o\n", | |
unit, opcode_name [opcode], | |
cvptr->count, DLIBUS (outbound)); | |
} | |
uptr->wait = cvptr->dlyptr->data_xfer; /* set the transfer delay */ | |
if (cvptr->length == 0 || inbound_flags & EOD) { /* if the buffer is empty or the transfer is done */ | |
uptr->PHASE = Intersector_Phase; /* then set up the intersector phase */ | |
if (cvptr->device->flags & DEV_REALTIME) /* if we're in realistic timing mode */ | |
uptr->wait = uptr->wait /* then account for the actual delay */ | |
* (cvptr->length + cmd_props [opcode].postamble_size); | |
} | |
break; | |
case Write: | |
case Write_Full_Sector: | |
case Initialize: | |
if ((inbound_flags & EOD) == NO_FLAGS) { /* if the transfer continues */ | |
cvptr->buffer [cvptr->index++] = inbound_data; /* then store the next word in the buffer */ | |
cvptr->count = cvptr->count + 1; /* count the */ | |
cvptr->length = cvptr->length - 1; /* transfer */ | |
dpprintf (cvptr->device, DL_DEB_XFER, "Unit %d %s word %d is %06o\n", | |
unit, opcode_name [opcode], | |
cvptr->count, inbound_data); | |
} | |
uptr->wait = cvptr->dlyptr->data_xfer; /* set the transfer delay */ | |
if (cvptr->length == 0 || inbound_flags & EOD) { /* if the buffer is empty or the transfer is done */ | |
uptr->PHASE = Intersector_Phase; /* then set up the intersector phase */ | |
if (cvptr->device->flags & DEV_REALTIME) /* if we're in realistic timing mode */ | |
uptr->wait = uptr->wait /* then account for the actual delay */ | |
* (cvptr->length + cmd_props [opcode].postamble_size); | |
} | |
break; | |
default: /* the remaining commands */ | |
break; /* do not have a data phase */ | |
} | |
break; | |
case Intersector_Phase: | |
switch (opcode) { /* dispatch the command */ | |
case Read: | |
case Read_With_Offset: | |
case Read_Without_Verify: | |
case Read_Full_Sector: | |
case Cold_Load_Read: | |
end_read (cvptr, uptr, inbound_flags); /* end the sector read */ | |
break; | |
case Write: | |
case Write_Full_Sector: | |
case Initialize: | |
end_write (cvptr, uptr, inbound_flags); /* end the sector write */ | |
break; | |
case Verify: | |
cvptr->count = cvptr->count - WORDS_PER_SECTOR; /* decrement the word count */ | |
if (cvptr->count > 0) /* if there more sectors to verify */ | |
inbound_flags &= ~EOD; /* then this is not the end of data */ | |
else /* otherwise the command is complete */ | |
inbound_flags |= EOD; /* and this is the end of data */ | |
end_read (cvptr, uptr, inbound_flags); /* end the sector read */ | |
break; | |
default: /* the remaining commands */ | |
break; /* do not have an intersector phase */ | |
} | |
break; | |
case End_Phase: | |
end_command (cvptr, uptr, cvptr->status); /* complete the command with the preset status */ | |
break; | |
} | |
if (uptr->wait != NO_EVENT) /* if the unit has been scheduled */ | |
activate_unit (cvptr, uptr); /* then activate it */ | |
if (controller_was_busy && cvptr->state != Busy_State) { /* if the command has just completed */ | |
if (cvptr->status == Normal_Completion /* then if the command completed normally */ | |
|| opcode == Request_Syndrome) /* or it was a Request Syndrome command */ | |
outbound = cmd_functions [opcode] [End_Phase]; /* then use the normal exit function set */ | |
else /* otherwise */ | |
outbound = status_functions [cvptr->status]; /* the function set depends on the status */ | |
if (outbound & WRTIO) /* if the TIO register will be written */ | |
outbound |= S1_STATUS (cvptr->status) | cvptr->spd_unit; /* then include the Status-1 value */ | |
} | |
return outbound; /* return the data word and function set */ | |
} | |
/* Poll the drives for Attention status. | |
MAC controllers complete their Seek and Recalibrate commands when the seeks | |
are initiated, so that other drives may be serviced during the waits. A | |
drive will set its Attention status when its seek completes, and the | |
controller must poll the drives for attention requests when it is idle and | |
interrupts are allowed by the CPU interface. | |
Starting with the last unit that had previously requested 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 a function set that | |
indicates 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 an empty function set | |
to indicate that no interrupt should be generated. | |
ICD controllers do not call this routine, because each controller waits for | |
seek completion on its dedicated drive before completing the associated Seek | |
or Recalibrate command. | |
*/ | |
static CNTLR_IFN_IBUS poll_drives (CVPTR cvptr) | |
{ | |
uint32 unit; | |
UNIT *units = cvptr->device->units; | |
dpprintf (cvptr->device, DL_DEB_INCO, "Controller polled drives for attention\n"); | |
for (unit = 0; unit <= DL_MAXDRIVE; unit++) { /* check each unit in turn */ | |
cvptr->poll_unit = /* start with the last unit checked */ | |
(cvptr->poll_unit + 1) % (DL_MAXDRIVE + 1); /* and cycle back to unit 0 */ | |
if (units [cvptr->poll_unit].STATUS & S2_ATTENTION) { /* if the unit is requesting attention, */ | |
units [cvptr->poll_unit].STATUS &= ~S2_ATTENTION; /* clear the Attention status */ | |
cvptr->spd_unit = cvptr->poll_unit; /* set the controller's unit number */ | |
cvptr->status = Drive_Attention; /* and status */ | |
cvptr->state = Wait_State; /* set the controller state to waiting */ | |
wait_timer (cvptr, SET); /* start the command wait timer */ | |
return status_functions [Drive_Attention] /* tell the caller to interrupt */ | |
| S1_STATUS (cvptr->status) | cvptr->spd_unit; /* and include the Status-1 value */ | |
} | |
} | |
return NO_ACTION; /* no drives have attention set */ | |
} | |
/* Clear the controller. | |
A "hard", "timeout", or "soft" clear is performed on the indicated controller | |
as specified by the "clear_type" parameter. | |
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 jumper is installed in the enabled position (which is the usual case). | |
The 30229B interface for the HP 3000 asserts CLEAR in response to an IORESET | |
signal or a programmed Master Reset if the PRESET DISABLE jumper is installed | |
in the enabled position. | |
The third condition, a "timeout clear", also causes a firmware restart but | |
with the PWRON flag clear. The last condition, a "soft clear" 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) | |
- clear the clock offset | |
- clear the file mask | |
- issue a Controller Preset to clear all connected drives | |
- 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 | |
On a 7905 or 7906 drive, clearing the head register will change Read-Only | |
status to reflect the position of the PROTECT LOWER DISC switch. | |
In simulation, a hard clear occurs when an SCP RESET command is entered, or a | |
programmed CLC 0 instruction or Master Clear is executed. A timeout clear | |
occurs when the command or parameter wait timer expires. A soft clear occurs | |
when a programmed Clear command is issued. | |
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 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. If a drive unit is disabled, it is still cleared. A unit cannot be | |
disabled while it is active, so it must be in the idle state while | |
disabled. Clearing the status keeps it consistent in case it is | |
reenabled later. | |
5. A soft clear does not abort commands in progress on a drive unit. | |
However, a soft clear is a result of a programmed command that can only | |
be issued when the prior command has completed (except for Seek and | |
Recalibrate commands, which are never aborted). | |
6. In simulation, a Controller Preset only resets the specified status bits, | |
as the remainder of the hardware actions are not implemented. | |
*/ | |
static void clear_controller (CVPTR cvptr, CNTLR_CLEAR clear_type) | |
{ | |
uint32 unit_count; | |
UNIT *uptr; | |
if (clear_type == Timeout_Clear) { /* if this is a timeout clear */ | |
cvptr->file_mask = 0; /* then clear the file mask */ | |
idle_controller (cvptr); /* and idle the controller */ | |
} | |
else { /* otherwise */ | |
if (clear_type == Hard_Clear) { /* if this a hard clear */ | |
cvptr->file_mask = 0; /* then clear the file mask */ | |
if (cvptr->type == MAC) /* if this is a MAC controller */ | |
cvptr->poll_unit = 0; /* then clear the last unit polled too */ | |
idle_controller (cvptr); /* idle the controller */ | |
} | |
else /* otherwise it's a soft clear */ | |
cvptr->status = Normal_Completion; /* so clear the status explicitly */ | |
if (cvptr->type == MAC) { /* if this a MAC controller */ | |
uptr = cvptr->device->units; /* then preset all units */ | |
unit_count = cvptr->device->numunits - 1; /* except the controller unit */ | |
} | |
else { /* otherwise preset */ | |
uptr = cvptr->device->units + cvptr->poll_unit; /* only the single unit */ | |
unit_count = 1; /* dedicated to the controller */ | |
} | |
while (unit_count > 0) { /* preset each drive in turn */ | |
if (uptr->PHASE != Idle_Phase /* if the unit is active */ | |
&& uptr->OPCODE != Seek /* but not seeking */ | |
&& uptr->OPCODE != Recalibrate) { /* or recalibrating */ | |
sim_cancel (uptr); /* then cancel the unit event */ | |
uptr->PHASE = Idle_Phase; /* and idle it */ | |
} | |
uptr->STATUS &= ~(S2_CPS | S2_READ_ONLY); /* do a "Controller Preset" on the unit */ | |
if (uptr->flags & UNIT_PROT_U) /* if the (upper) heads are protected */ | |
uptr->STATUS |= S2_READ_ONLY; /* then set read-only status */ | |
uptr++; /* point at the next unit */ | |
unit_count = unit_count - 1; /* and count the unit just cleared */ | |
} | |
} | |
return; | |
} | |
/* Disc library global utility routines */ | |
/* 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_CNTLR /* 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 /* otherwise the type or opcode is illegal */ | |
return invalid_name; /* so return an error indication */ | |
} | |
/* Return the name of a command result status. | |
A string representing the supplied command result status is returned to the | |
caller. If the status is illegal or undefined, the string "Invalid" is | |
returned. | |
*/ | |
const char *dl_status_name (CNTLR_STATUS status) | |
{ | |
if (status <= Drive_Attention && status_name [status]) /* if the status is legal */ | |
return status_name [status]; /* then return the status name */ | |
else /* otherwise the status is illegal */ | |
return invalid_name; /* so return an error indication */ | |
} | |
/* Disc library global SCP support 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. | |
*/ | |
t_stat dl_attach (CVPTR cvptr, UNIT *uptr, char *cptr) | |
{ | |
t_stat result; | |
result = attach_unit (uptr, cptr); /* attach the unit */ | |
if (result == SCPE_OK) /* if the attach succeeded */ | |
result = dl_load_unload (cvptr, uptr, TRUE); /* then load the heads */ | |
return result; /* return the command result status */ | |
} | |
/* 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) | |
{ | |
t_stat unload, detach; | |
unload = dl_load_unload (cvptr, uptr, FALSE); /* unload the heads */ | |
if (unload == SCPE_OK || unload == SCPE_INCOMP) { /* if the unload succeeded */ | |
detach = detach_unit (uptr); /* then detach the unit */ | |
if (detach == SCPE_OK) /* if the detach succeeded as well */ | |
return unload; /* then return the unload status */ | |
else /* otherwise */ | |
return detach; /* return the detach failure status */ | |
} | |
else /* otherwise the unload failed */ | |
return unload; /* so return the failure status */ | |
} | |
/* 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 both cases, the drive reports Attention | |
status to the controller. A MAC controller will clear a drive's Attention | |
status and will interrupt the CPU when the drives are polled in the Idle | |
Loop. An ICD controller also clears the drive's Attention status but will | |
assert a Parallel Poll Response only when the heads unload. | |
In simulation, the unit must be attached, corresponding to having a disc pack | |
installed in the drive, before the heads may be unloaded or loaded. If it | |
isn't, the routine returns SCPE_UNATT. Otherwise, the UNIT_UNLOAD flag and | |
the drive status are set accordingly. | |
If the (MAC) controller is idle, the routine returns SCPE_INCOMP to indicate | |
that the caller must then call the controller to poll for drive attention to | |
complete the command. Otherwise, it returns SCPE_OK, and the drives will be | |
polled automatically when the current command or command wait completes and | |
the controller is idled. | |
Implementation notes: | |
1. Loading or unloading the heads clears Fault and Seek Check status. | |
2. If we are called during a RESTORE command, the unit's flags are not | |
changed to avoid upsetting the state that was SAVEd. | |
3. Unloading an active unit does not cancel the event. This ensures that | |
the controller will not hang during a transfer but instead will see the | |
unloaded unit and fail the transfer with Access_Not_Ready status. | |
*/ | |
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; /* so return "Unit not attached" if it is not */ | |
else if ((sim_switches & SIM_SW_REST) == 0) { /* if we are not being called during a RESTORE command */ | |
uptr->STATUS &= ~S2_CPS; /* then do a "Controller Preset" on the unit */ | |
if (load) { /* if we are loading the heads */ | |
uptr->flags &= ~UNIT_UNLOAD; /* then clear the unload flag */ | |
uptr->STATUS |= S2_FIRST_STATUS; /* and set First Status */ | |
if (cvptr->type != ICD) /* if this is not an ICD controller */ | |
uptr->STATUS |= S2_ATTENTION; /* then set Attention status also */ | |
} | |
else { /* otherwise we are unloading the heads */ | |
uptr->flags |= UNIT_UNLOAD; /* so set the unload flag */ | |
uptr->STATUS |= S2_ATTENTION; /* and Attention status */ | |
} | |
dpprintf (cvptr->device, DL_DEB_CMD, "RUN/STOP switch set to %s\n", | |
(load ? "RUN" : "STOP")); | |
if (cvptr->type == MAC && cvptr->state == Idle_State) /* if this is a MAC controller, and it's idle */ | |
return SCPE_INCOMP; /* then the controller must be called to poll the drives */ | |
} /* otherwise indicate that the command is complete */ | |
return SCPE_OK; /* return normal completion status to the caller */ | |
} | |
/* Set the drive model. | |
This validation routine is called to set the model of the disc drive | |
associated with the specified unit. The "value" parameter indicates the | |
model ID, and the unit capacity is set to the size indicated. | |
Implementation notes: | |
1. If the drive is changed from a 7905 or 7906, which has separate head | |
protect switches, to a 7920 or 7925, which has a single protect switch, | |
ensure that both protect bits are set so that all heads are protected. | |
*/ | |
t_stat dl_set_model (UNIT *uptr, int32 value, char *cptr, void *desc) | |
{ | |
if (uptr->flags & UNIT_ATT) /* if the unit is currently attached */ | |
return SCPE_ALATT; /* then the disc model cannot be changed */ | |
uptr->capac = drive_props [GET_MODEL (value)].words; /* set the capacity to the new value */ | |
if (uptr->flags & UNIT_PROT /* if either protect bit is set */ | |
&& (value == UNIT_7920 || value == UNIT_7925)) /* and the new drive is a 7920 or 7925 */ | |
uptr->flags |= UNIT_PROT; /* then ensure that both bits are set */ | |
return SCPE_OK; | |
} | |
/* Set or clear the write protection status. | |
This validation routine is called to set the write protection status of the | |
disc drive associated with the specified unit. The "value" parameter | |
indicates whether the drive is to be protected (1) or unprotected (0). | |
In hardware, the 7920 and 7925 drives have a READ ONLY switch that write- | |
protects all heads in the drive, and Read-Only status directly reflects the | |
position of the switch. The switch is simulated by the SET <unit> PROTECT | |
and SET <unit> UNPROTECT commands. | |
The 7905 and 7906 drives have separate PROTECT UPPER DISC and PROTECT LOWER | |
DISC switches that protect heads 0-1 and 2 (7905) or 2-3 (7906), | |
respectively, and Read-Only status reflects the position of the switch | |
associated with the head currently addressed by the drive's Head Register. | |
The Head Register is loaded by the controller as part of a Seek or Cold Load | |
Read command, or during an auto-seek or spare track seek, if permitted by the | |
file mask. A Controller Preset command sent to a drive clears the Head | |
Register, so Read-Only status reflects the PROTECT UPPER DISC switch setting. | |
The SET <unit> PROTECT=(UPPER | LOWER) and SET <unit> UNPROTECT=(UPPER | | |
LOWER) simulation commands are provided to protect or unprotect the upper or | |
lower heads individually. If the option values are omitted, e.g., SET <unit> | |
PROTECT, then both upper and lower heads are (un)protected. | |
*/ | |
t_stat dl_set_protect (UNIT *uptr, int32 value, char *cptr, void *desc) | |
{ | |
const uint32 model = uptr->flags & UNIT_MODEL; | |
char gbuf [CBUFSIZE]; | |
if (cptr == NULL) /* if there are no arguments */ | |
if (value) /* then if setting the protection status */ | |
uptr->flags |= UNIT_PROT; /* then protect all heads */ | |
else /* otherwise */ | |
uptr->flags &= ~UNIT_PROT; /* unprotect all heads */ | |
else if (*cptr == '\0') /* otherwise if the argument is empty */ | |
return SCPE_MISVAL; /* then reject the command */ | |
else if (model == UNIT_7920 || model == UNIT_7925) /* otherwise if this is a 7920 or 7925 */ | |
return SCPE_ARG; /* then the heads cannot be protected separately */ | |
else { /* otherwise a 7905/06 argument is present */ | |
cptr = get_glyph (cptr, gbuf, ';'); /* get the argument */ | |
if (strcmp ("LOWER", gbuf) == 0) /* if the LOWER option was specified */ | |
if (value) /* then if setting the protection status */ | |
uptr->flags |= UNIT_PROT_L; /* then set the protect lower disc flag */ | |
else /* otherwise */ | |
uptr->flags &= ~UNIT_PROT_L; /* clear the protect lower disc flag */ | |
else if (strcmp ("UPPER", gbuf) == 0) /* otherwise if the UPPER option was specified */ | |
if (value) /* then if setting the protection status */ | |
uptr->flags |= UNIT_PROT_U; /* then set the protect upper disc flag */ | |
else /* otherwise */ | |
uptr->flags &= ~UNIT_PROT_U; /* clear the protect upper disc flag */ | |
else /* otherwise some other argument was given */ | |
return SCPE_ARG; /* so report the error */ | |
} | |
return SCPE_OK; | |
} | |
/* Show the write protection status. | |
This display routine is called to show the write protection status of the | |
disc drive associated with the specified unit. The "value" and "desc" | |
parameters are unused. | |
The unit flags contain two bits that indicate write protection for heads 0-1 | |
and heads 2-n. If both bits are clear, the drive is unprotected. A 7905 or | |
7906 drive may have one or the other or both bits set, indicating that the | |
upper, lower, or both platters are protected. A 7920 or 7925 will have both | |
bits set, indicating that the entire drive is protected. | |
*/ | |
t_stat dl_show_protect (FILE *st, UNIT *uptr, int32 value, void *desc) | |
{ | |
const uint32 model = uptr->flags & UNIT_MODEL; | |
if ((uptr->flags & UNIT_PROT) == 0) /* if the protection flags are clear */ | |
fputs ("unprotected", st); /* then report the disc as unprotected */ | |
else if (model == UNIT_7905 || model == UNIT_7906) /* otherwise if this is a 7905/06 */ | |
if ((uptr->flags & UNIT_PROT) == UNIT_PROT_L) /* then if only the lower disc protect flag is set */ | |
fputs ("lower protected", st); /* then report it */ | |
else if ((uptr->flags & UNIT_PROT) == UNIT_PROT_U) /* otherwise if only the upper disc protect flag is set */ | |
fputs ("upper protected", st); /* then report it */ | |
else /* otherwise both flags are set */ | |
fputs ("lower/upper protected", st); /* so report them */ | |
else /* otherwise it's a 7920/25 */ | |
fputs ("protected", st); /* so either flag set indicates a protected disc */ | |
return SCPE_OK; | |
} | |
/* Set or clear the diagnostic override table. | |
This validation routine is called to set or clear the diagnostic override | |
table associated with the specified unit. The "value" parameter is either | |
the positive maximum table entry count if an entry is to be added, or zero if | |
the table is to be cleared, and "desc" is a pointer to the controller. | |
If the CPU interface declares a diagnostic override table, it will specify | |
the table when initializing the controller variables structure with the | |
CNTLR_INIT macro. This sets the "dop_base" pointer in the structure to point | |
at the table. If the interface does not declare a table, the pointer will be | |
NULL. | |
If the table is present, new entries may be added with this command: | |
SET <dev> DIAG=<cylinder>;<head>;<sector>;<opcode>;<spd>;<status> | |
The cylinder, head, and sector values are entered as decimal numbers, the | |
opcode and status values are entered as octal numbers, and the SPD value is | |
specified as any combination of the letters "S", "P", or "D". | |
If a command specifies the opcode value as Request Syndrome (15) and the | |
status value as Correctable Data Error (17), then four additional values must | |
be specified as part of the command line above: | |
;<displacement>;<syndrome 1>;<syndrome 2>;<syndrome 3> | |
The displacement value is entered as a decimal number, and the three syndrome | |
values are entered as octal numbers. | |
Entering SET <dev> DIAG by itself resets the current entry pointer to the | |
first table entry. Entering SET <dev> NODIAG clears the table. | |
If the override table was not declared by the CPU interface, the routine | |
returns "Command not allowed." If SET NODIAG was entered, the "value" | |
parameter will be -1, and the table will be cleared by storing the special | |
value DL_OVEND into the first table entry. Otherwise, if SET DIAG is | |
entered, the table pointer is reset. However, if the table is already empty, | |
the routine returns "Missing value" to indicate that the table must be | |
populated first. | |
If a new entry is to be added, the "value" parameter will indicate the size | |
of the table in entries. If no free entry exists, the routine returns | |
"Memory exhausted". Otherwise, the supplied parameters are parsed and | |
entered into the table. An array of maximum allowed values and radixes are | |
used during parsing to validate each parameter. The non-numeric SPD | |
parameter is parsed separately. If, after parsing the first six parameters, | |
the opcode and status are Request Syndrome and Correctable Data Error, | |
respectively, then four more parameters are sought. These are stored into | |
the following table entry. | |
Implementation notes: | |
1. Each maximum array element value limits the absolute value of its | |
corresponding numeric parameter. Negative values may be specified for | |
unsigned values; no error is returned, and these simply will never match | |
their intended controller values. | |
2. Each radix array element value is used to parse its corresponding | |
parameter. A radix of 0 is used to indicate the S/P/D parameter, which | |
is parsed alphabetically rather than numerically. | |
3. One table entry is always reserved for the end-of-table value, so the | |
number of configurable entries is one less than the defined table size. | |
*/ | |
t_stat dl_set_diag (UNIT *uptr, int32 value, char *cptr, void *desc) | |
{ | |
typedef struct { | |
t_value max; /* maximum allowed value */ | |
uint32 radix; /* numeric parsing radix */ | |
} PARSER_PROP; | |
static const PARSER_PROP param [] = { | |
/* maximum value radix */ | |
/* ------------- ----- */ | |
{ 822, 10 }, /* cylinder */ | |
{ 8, 10 }, /* head */ | |
{ 63, 10 }, /* sector */ | |
{ LAST_OPCODE, 8 }, /* opcode */ | |
{ 0, 0 }, /* SPD */ | |
{ LAST_STATUS, 8 }, /* status */ | |
{ 135, 10 }, /* displacement */ | |
{ D16_UMAX, 8 }, /* syndrome 1 */ | |
{ D16_UMAX, 8 }, /* syndrome 2 */ | |
{ D16_UMAX, 8 } /* syndrome 3 */ | |
}; | |
const CVPTR cvptr = (CVPTR) desc; | |
DIAG_ENTRY *entry; | |
uint32 pidx, params [10]; | |
t_stat status; | |
char gbuf [CBUFSIZE]; | |
if (cvptr->dop_base == NULL) /* if the override array is not present */ | |
return SCPE_NOFNC; /* then the command is not allowed */ | |
else if (value == 0) /* otherwise if this is a NODIAG call */ | |
if (cptr != NULL) /* then if something follows the keyword */ | |
return SCPE_2MARG; /* then report an error */ | |
else { /* otherwise the command is valid */ | |
cvptr->dop = NULL; /* so clear the current entry pointer */ | |
cvptr->dop_base->cylinder = DL_OVEND; /* and mark the first entry as the end */ | |
} | |
else if (cptr == NULL) /* otherwise if DIAG is by itself */ | |
if (cvptr->dop_base->cylinder == DL_OVEND) /* then if there are no entries in the table */ | |
return SCPE_MISVAL; /* then one must be entered first */ | |
else /* otherwise */ | |
cvptr->dop = cvptr->dop_base; /* reset the current pointer to the first entry */ | |
else if (*cptr == '\0') /* otherwise if there are no parameters */ | |
return SCPE_MISVAL; /* then report a missing value */ | |
else { /* otherwise at least one parameter is present */ | |
for (entry = cvptr->dop_base; /* find the */ | |
entry->cylinder != DL_OVEND && value > 0; /* last entry */ | |
entry++, value--); /* in the current table */ | |
if (value <= 1) /* if there's not enough room to add a new entry */ | |
return SCPE_MEM; /* then report the error to the user */ | |
else { /* otherwise there's at least one free entry */ | |
for (pidx = 0; pidx < 10; pidx++) { /* so assume a full set of arguments are present */ | |
if (*cptr == '\0') /* if the next argument is not there */ | |
return SCPE_2FARG; /* then report it missing */ | |
if (param [pidx].radix == 0) { /* if this is the SPD argument */ | |
params [pidx] = 0; /* then parse it specially */ | |
while (*cptr != ';' && *cptr != '\0') { /* look for multiple arguments */ | |
if (*cptr == 'S') /* if it's an S */ | |
params [pidx] |= CM_SPARE; /* then set the spare bit */ | |
else if (*cptr == 'P') /* or if it's a P */ | |
params [pidx] |= CM_PROTECTED; /* then set the protected bit */ | |
else if (*cptr == 'D') /* or if it's a D */ | |
params [pidx] |= CM_DEFECTIVE; /* then set the defective bit */ | |
else /* any other character */ | |
return SCPE_ARG; /* results in an invalid argument error */ | |
cptr++; /* point at the next character and continue */ | |
} /* until a separator or terminator is seen */ | |
if (*cptr == ';') /* if a separator was seen */ | |
cptr++; /* then move past it */ | |
status = SCPE_OK; /* reassure the compiler that status is not uninitialized */ | |
} | |
else { /* otherwise parse a numeric argument */ | |
cptr = get_glyph (cptr, gbuf, ';'); /* get the argument */ | |
if (gbuf [0] == '-') { /* if the argument is negative */ | |
gbuf [0] = ' '; /* then clear the sign */ | |
params [pidx] = /* and negate the resulting value */ | |
(uint32) NEG16 (get_uint (gbuf, param [pidx].radix, | |
param [pidx].max, &status)); | |
} | |
else /* otherwise the argument is unsigned */ | |
params [pidx] = /* so use the value as is */ | |
(uint32) get_uint (gbuf, param [pidx].radix, | |
param [pidx].max, &status); | |
} | |
if (status != SCPE_OK) /* if an error occurred */ | |
return status; /* then return the parsing status */ | |
if (pidx == 5 /* if we have parsed the status */ | |
&& (params [3] != Request_Syndrome /* and this is not a Request Syndrome entry */ | |
|| params [5] != Correctable_Data_Error)) /* with Correctable Data Error status */ | |
break; /* then no more parameters are expected */ | |
} | |
if (*cptr != '\0') /* if more characters are present */ | |
return SCPE_2MARG; /* then report the excess */ | |
else if (pidx == 10 && value <= 2) /* otherwise if we have syndrome values but no space */ | |
return SCPE_MEM; /* the report that we can't store them */ | |
entry->cylinder = params [0]; /* store the */ | |
entry->head = params [1]; /* first set */ | |
entry->sector = params [2]; /* of parameter values */ | |
entry->opcode = (CNTLR_OPCODE) params [3]; /* in the */ | |
entry->spd = params [4]; /* first available */ | |
entry->status = (CNTLR_STATUS) params [5]; /* empty entry */ | |
if (pidx == 10) { /* if syndrome values were present */ | |
entry++; /* then store them in the next available entry */ | |
entry->spd = params [6]; /* save the displacement */ | |
entry->cylinder = params [7]; /* and the */ | |
entry->head = params [8]; /* three syndrome */ | |
entry->sector = params [9]; /* values */ | |
entry->opcode = Request_Syndrome; /* identify the entry */ | |
entry->status = Correctable_Data_Error; /* by opcode and status */ | |
} | |
entry++; /* point at the next available entry */ | |
entry->cylinder = DL_OVEND; /* and mark it as the end of the list */ | |
cvptr->dop = cvptr->dop_base; /* reset the current pointer to the start of the list */ | |
} | |
} | |
return SCPE_OK; | |
} | |
/* Show the diagnostic override table. | |
This display routine is called to show the contents of the diagnostic | |
override table. The "value" parameter is either the positive maximum table | |
entry count if the routine was invoked by a SHOW <dev> DIAG command, or -1 if | |
the routine was invoked by a SHOW <dev> command. The "desc" parameter is a | |
pointer to the controller. | |
If the override table was not declared by the CPU interface, the routine | |
returns "Command not allowed." Otherwise, if the table is empty, the routine | |
prints "override disabled". If the table is populated, then the routine | |
prints "override enabled" if it was invoked as part of a general SHOW for the | |
device, or it prints the individual table entries if it was invoked as SHOW | |
<dev> DIAG. | |
Entries are printed in tabular form with the columns corresponding to the SET | |
DIAG parameters, except that the opcode and status fields are decoded. A | |
Request Syndrome command entry with Correctable Data Error status is followed | |
by an indented second line containing the displacement and syndrome values. | |
Numeric values are printed in the same radix as is used to enter them. | |
Implementation notes: | |
1. The Request Syndrome displacement parameter is a 16-bit signed value | |
contained in a 32-bit unsigned array element. To print it properly, we | |
convert the latter to a 16-bit signed value and then sign-extend to "int" | |
size for fprintf. | |
*/ | |
t_stat dl_show_diag (FILE *st, UNIT *uptr, int32 value, void *desc) | |
{ | |
const CVPTR cvptr = (CVPTR) desc; | |
DIAG_ENTRY *entry; | |
if (cvptr->dop_base == NULL) /* if the table isn't defined */ | |
return SCPE_NOFNC; /* then the command is illegal */ | |
else if (cvptr->dop == NULL) { /* otherwise if overrides are currently disabled */ | |
fputs ("override disabled", st); /* then report it */ | |
if (value > 0) /* if we were invoked by a SHOW DIAG command */ | |
fputc ('\n', st); /* then we must add the line terminator */ | |
} | |
else if (value < 0) /* otherwise if we were invoked by a SHOW <dev> command */ | |
fputs ("override enabled", st); /* then print the table status instead of the details */ | |
else for (entry = cvptr->dop_base; /* otherwise print each table entry */ | |
entry->cylinder != DL_OVEND && value > 0; /* until the end-of-table marker or count exhaustion */ | |
entry++, value--) { | |
fprintf (st, "%3d %1d %2d %*s %c%c%c %*s\n", /* print the entry */ | |
entry->cylinder, entry->head, entry->sector, | |
- OPCODE_LENGTH, dl_opcode_name (cvptr->type, entry->opcode), | |
(entry->spd & CM_SPARE ? 'S' : ' '), | |
(entry->spd & CM_PROTECTED ? 'P' : ' '), | |
(entry->spd & CM_DEFECTIVE ? 'D' : ' '), | |
- STATUS_LENGTH, dl_status_name (entry->status)); | |
if (entry->opcode == Request_Syndrome /* if the current entry is a syndrome request */ | |
&& entry->status == Correctable_Data_Error) { /* for a correctable data error */ | |
entry++; /* then the next entry contains the values */ | |
value = value - 1; /* drop the entry count to account for it */ | |
fprintf (st, " %3d %06o %06o %06o\n", /* print the displacement and syndrome values */ | |
(int) INT16 (entry->spd), | |
entry->cylinder, entry->head, entry->sector); | |
} | |
} | |
return SCPE_OK; | |
} | |
/* Set the controller timing mode. | |
This validation routine is called to set the timing mode for the disc | |
subsystem. As this is an extended MTAB call, the "uptr" parameter points to | |
the unit array of the device. The "value" parameter is set to 1 to use | |
realistic timing and 0 to use fast timing. For a MAC controller, the "desc" | |
parameter is a pointer to the controller. For ICD controllers, the "desc" | |
parameter is a pointer to the first element of the controller array. There | |
must be one controller for each unit defined by the device associated with | |
the controllers. | |
If fast timing is selected, the controller's timing pointer is set to the | |
fast timing pointer supplied by the interface when the controller was | |
initialized. If real timing is selected, the table of real times is searched | |
for an entry whose controller type matches the supplied controller. MAC and | |
ICD controllers support several drive models with identical timing | |
characteristics. However, CS/80 controllers allow mixing drives with | |
different timing on a single CPU interface. For these, the drive type must | |
match as well. If a match is found, the controller's timing pointer is set | |
to the associated real-time entry. Otherwise, the routine returns SCPE_IERR. | |
Non-MAC controllers are dedicated per-drive, so "desc" points not at a single | |
controller instance but at an array of controller instances. The timing mode | |
is common to every controller in the array. | |
*/ | |
t_stat dl_set_timing (UNIT *uptr, int32 value, char *cptr, void *desc) | |
{ | |
CVPTR cvptr = (CVPTR) desc; /* the controller pointer is supplied */ | |
const DELAY_PROPS *dpptr; | |
int32 model; | |
uint32 delay, cntlr_count; | |
if (cvptr->type == MAC) /* if this is a MAC controller */ | |
cntlr_count = 1; /* then there is one controller for all units */ | |
else /* otherwise */ | |
cntlr_count = cvptr->device->numunits; /* there is one controller per unit */ | |
while (cntlr_count--) { /* set each controller's timing mode */ | |
if (value) { /* if realistic timing is requested */ | |
model = GET_MODEL (uptr->flags); /* then get the drive model from the current unit */ | |
dpptr = real_times; /* and reset the real-time delay table pointer */ | |
for (delay = 0; delay < DELAY_COUNT; delay++) /* search for the correct set of times */ | |
if (dpptr->type == cvptr->type /* if the controller types match */ | |
&& (dpptr->drive == HP_All /* and the drive times are identical */ | |
|| dpptr->drive == model)) { /* or the drive types match as well */ | |
cvptr->dlyptr = dpptr; /* then use this set of times */ | |
break; | |
} | |
else /* otherwise */ | |
dpptr++; /* point at the next array element */ | |
if (delay == DELAY_COUNT) /* if the model was not found in the table */ | |
return SCPE_IERR; /* then report an internal (impossible) error */ | |
else /* otherwise */ | |
cvptr->device->flags |= DEV_REALTIME; /* set the real time flag */ | |
} | |
else { /* otherwise fast timing is requested */ | |
cvptr->device->flags &= ~DEV_REALTIME; /* so clear the real time flag */ | |
cvptr->dlyptr = cvptr->fastptr; /* and set the delays to the FASTTIME settings */ | |
} | |
cvptr++; /* point at the next controller */ | |
uptr++; /* and corresponding unit for non-MAC controllers */ | |
} | |
return SCPE_OK; | |
} | |
/* Show the controller timing mode | |
This display routine is called to show the timing mode for the disc | |
subsystem. The "value" parameter is unused; the "desc" parameter is a | |
pointer to the controller. | |
*/ | |
t_stat dl_show_timing (FILE *st, UNIT *uptr, int32 value, void *desc) | |
{ | |
CVPTR const cvptr = (CVPTR) desc; /* the controller pointer is supplied */ | |
if (cvptr->device->flags & DEV_REALTIME) /* if the real time flag is set */ | |
fputs ("realistic timing", st); /* then we're using realistic timing */ | |
else /* otherwise */ | |
fputs ("fast timing", st); /* we're using optimized timing */ | |
return SCPE_OK; | |
} | |
/* Disc library local controller routines */ | |
/* Start or stop the command/parameter wait timer. | |
A MAC controller uses a 1.74 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 additional controller unit that is activated when the | |
command or parameter wait timer is started and cancelled when the timer is | |
stopped. | |
ICD interfaces do not use the wait timer or supply an additional unit. | |
Implementation notes: | |
1. Absolute activation is used because the timer is restarted between | |
parameter word transfers. | |
*/ | |
static void wait_timer (CVPTR cvptr, FLIP_FLOP action) | |
{ | |
if (cvptr->type == MAC) /* if this a MAC controller */ | |
if (action == SET) /* then if the timer is to be set */ | |
sim_activate_abs (CNTLR_UPTR, CNTLR_TIMEOUT); /* then activate the controller unit */ | |
else { /* otherwise the timer is to be stopped */ | |
sim_cancel (CNTLR_UPTR); /* so cancel the unit */ | |
CNTLR_UPTR->PHASE = Idle_Phase; /* and idle the controller unit */ | |
} | |
return; | |
} | |
/* 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). | |
*/ | |
static void idle_controller (CVPTR cvptr) | |
{ | |
wait_timer (cvptr, CLEAR); /* stop the command wait timer */ | |
cvptr->status = Normal_Completion; /* the Poll Loop clears the status */ | |
cvptr->state = Idle_State; /* idle the controller */ | |
return; | |
} | |
/* End the current command. | |
The currently executing command is completed with the supplied status. If | |
the command completed normally, and it returns to the Poll Loop, the | |
controller is idled, and the wait timer is cancelled. Otherwise, the | |
controller enters the Wait Loop, and the wait timer is started. If the | |
command had accessed a drive unit, the unit is idled. Also, for a MAC | |
controller, the controller unit is idled as well. | |
*/ | |
static void end_command (CVPTR cvptr, UNIT *uptr, CNTLR_STATUS status) | |
{ | |
cvptr->status = status; /* set the command result status */ | |
if (status == Normal_Completion /* if the command completed normally */ | |
&& cmd_props [cvptr->opcode].idle_at_end) { /* and this command idles the controller */ | |
cvptr->state = Idle_State; /* then set idle status */ | |
wait_timer (cvptr, CLEAR); /* and stop the command wait timer */ | |
} | |
else { /* otherwise */ | |
cvptr->state = Wait_State; /* the controller waits for a new command */ | |
wait_timer (cvptr, SET); /* so start the command wait timer */ | |
if (uptr) /* if the command accessed a drive */ | |
uptr->PHASE = Idle_Phase; /* then idle it */ | |
if (cvptr->type == MAC) /* if this is a MAC controller */ | |
CNTLR_UPTR->PHASE = Idle_Phase; /* then idle the controller unit as well */ | |
} | |
if (cmd_props [cvptr->opcode].transfer_size > 0) | |
dpprintf (cvptr->device, DL_DEB_CMD, (cvptr->opcode == Initialize | |
? "Unit %d Initialize %s for %d words (%d sector%s)\n" | |
: "Unit %d %s for %d words (%d sector%s)\n"), | |
CM_UNIT (cvptr->spd_unit), | |
(cvptr->opcode == Initialize | |
? fmt_bitset (cvptr->spd_unit, initialize_format) | |
: opcode_name [cvptr->opcode]), | |
cvptr->count, | |
cvptr->count / cmd_props [cvptr->opcode].transfer_size + (cvptr->length > 0), | |
(cvptr->count <= cmd_props [cvptr->opcode].transfer_size ? "" : "s")); | |
dpprintf (cvptr->device, DL_DEB_INCO, "Unit %d %s command completed with %s status\n", | |
CM_UNIT (cvptr->spd_unit), opcode_name [cvptr->opcode], | |
dl_status_name (cvptr->status)); | |
return; | |
} | |
/* Start a read operation on the current sector. | |
This routine is called at the end of the rotate phase to begin a read | |
operation. The current sector given 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. | |
The routine returns TRUE if the data is ready to be transferred and FALSE if | |
it is not (due to command completion, an error, or an auto-seek that must | |
complete first). | |
On entry, the end-of-data flag is checked. If it is set, the current read | |
command 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 Seek_Phase set 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 track, 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 read | |
failed with a host file system error, it is reported to the simulation | |
console and the read ends with an Uncorrectable Data Error. If it succeeded | |
but did not return a full sector, the remainder of the buffer is padded with | |
zeros. | |
If the image was read correctly, the operation phase is set for the data | |
transfer, the index of the first word to transfer is set, and the routine | |
returns TRUE to begin the data transfer. | |
Implementation notes: | |
1. This routine changes the unit phase state as follows: | |
Rotate_Phase => Idle_Phase if EOD or error (returns FALSE) | |
Rotate_Phase => Seek_Phase if auto-seek (returns FALSE) | |
Rotate_Phase => Data_Phase otherwise (returns TRUE) | |
2. The position_sector routine sets up the data phase if it succeeds or the | |
seek phase if a seek is required. | |
*/ | |
static t_bool start_read (CVPTR cvptr, UNIT *uptr, CNTLR_FLAG_SET flags) | |
{ | |
uint32 count, offset; | |
const CNTLR_OPCODE opcode = (CNTLR_OPCODE) uptr->OPCODE; | |
if (flags & EOD) { /* if the end of data is indicated */ | |
end_command (cvptr, uptr, Normal_Completion); /* then complete the command */ | |
return FALSE; /* and end the current operation */ | |
} | |
if (opcode == Read_Full_Sector) { /* if we are starting a Read Full Sector command */ | |
if (cvptr->type == MAC) /* then if this is a MAC controller */ | |
cvptr->buffer [0] = 0100376; /* indicate that ECC support is valid */ | |
else /* otherwise */ | |
cvptr->buffer [0] = 0100377; /* indicate that ECC support is not available */ | |
set_address (cvptr, 1); /* set the current address into buffer words 1-2 */ | |
offset = 3; /* and start the data after the header */ | |
} | |
else /* otherwise it's a normal read command */ | |
offset = 0; /* so data starts at the beginning of the buffer */ | |
if (position_sector (cvptr, uptr) == FALSE) /* position the sector; if it was not */ | |
return FALSE; /* then a seek is in progress or an error occurred */ | |
dpprintf (cvptr->device, DL_DEB_INCO, "Unit %d %s from cylinder %d head %d sector %d\n", | |
uptr - cvptr->device->units, opcode_name [opcode], | |
uptr->CYL, cvptr->head, cvptr->sector); | |
count = sim_fread (cvptr->buffer + offset, /* read the sector from the image */ | |
sizeof (uint16), WORDS_PER_SECTOR, /* into the sector buffer */ | |
uptr->fileref); | |
if (ferror (uptr->fileref)) { /* if a host file system error occurred */ | |
io_error (cvptr, uptr); /* then report it to the simulation console */ | |
return FALSE; /* and terminate with Uncorrectable Data Error status */ | |
} | |
cvptr->length = cmd_props [opcode].transfer_size; /* set the appropriate transfer length */ | |
cvptr->index = 0; /* and reset the data index */ | |
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 */ | |
return TRUE; /* the read was successfully started */ | |
} | |
/* Finish a read operation on the current sector. | |
This routine is called at the end of the intersector phase to finish a read | |
operation. Command termination conditions are checked, and the next sector | |
is addressed in preparation for the read to continue. | |
On entry, the diagnostic override status is checked. If it is set, then the | |
read is terminated with the indicated status. Otherwise, the data overrun | |
flag is checked. If it is set, the read is terminated with an error. | |
Otherwise, the next sector is addressed. | |
If the end-of-data flag is set, the current read is completed. Otherwise,the | |
rotate phase is set up in preparation for the next sector read. | |
Implementation notes: | |
1. This routine changes the unit phase state as follows: | |
Intersector_Phase => Idle_Phase if EOD or error | |
Intersector_Phase => Rotate_Phase otherwise | |
2. The HP 1000 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 explicitly. | |
Note also that the delay is a fixed number of instructions, regardless of | |
timing mode, to ensure that the CPU makes it through the driver code to | |
output the untalk command. | |
*/ | |
static void end_read (CVPTR cvptr, UNIT *uptr, CNTLR_FLAG_SET flags) | |
{ | |
uint32 bound; | |
if (cvptr->status != Normal_Completion) /* if a diagnostic override is present */ | |
end_command (cvptr, uptr, cvptr->status); /* then report the indicated status */ | |
else if (flags & OVRUN) /* otherwise if a read overrun occurred */ | |
end_command (cvptr, uptr, Data_Overrun); /* then terminate the command with an error */ | |
else { /* otherwise the read succeeded */ | |
next_sector (cvptr, uptr); /* so address the next sector */ | |
if (flags & EOD) /* if the end of data is indicated */ | |
end_command (cvptr, uptr, Normal_Completion); /* then complete the command */ | |
else { /* otherwise reading continues */ | |
uptr->PHASE = Rotate_Phase; /* so set up the unit for the rotate phase */ | |
uptr->wait = cvptr->dlyptr->intersector_gap; /* with a delay for the intersector time */ | |
if (cvptr->eoc == SET && cvptr->type == ICD) { /* if a seek will be required on an ICD controller */ | |
if ((cvptr->file_mask & CM_AUTO_SEEK_EN) == 0) /* then if auto-seek is disabled */ | |
bound = cvptr->cylinder; /* then the bound is the current cylinder */ | |
else if (cvptr->file_mask & CM_DECR_SEEK) /* otherwise if a decremental seek is enabled */ | |
bound = 0; /* then the bound is cylinder 0 */ | |
else /* otherwise the enabled bound is the last cylinder */ | |
bound = drive_props [GET_MODEL (uptr->flags)].cylinders - 1; | |
if (cvptr->cylinder == bound) /* if the positioner is already at the bound */ | |
uptr->wait = UNTALK_DELAY; /* then the seek will fail; delay to allow CPU to untalk */ | |
} | |
} | |
} | |
return; | |
} | |
/* Start a write operation on the current sector. | |
This routine is called at the end of the rotate phase to begin a write | |
operation. 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. The routine returns TRUE if the data is ready to be | |
transferred and FALSE if it is not (due to an error or an auto-seek that must | |
complete first). | |
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 Seek_Phase set 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 track, the operation phase is set | |
for the data transfer, the index of the first word to transfer is set, and | |
the routine returns TRUE to begin the data transfer. | |
Implementation notes: | |
1. This routine changes the unit phase state as follows: | |
Rotate_Phase => Idle_Phase if write protected or error (returns FALSE) | |
Rotate_Phase => Seek_Phase if auto-seek (returns FALSE) | |
Rotate_Phase => Data_Phase otherwise (returns TRUE) | |
2. The position_sector routine sets up the data phase if it succeeds or the | |
seek phase if a seek is required. | |
*/ | |
static t_bool start_write (CVPTR cvptr, UNIT *uptr) | |
{ | |
const CNTLR_OPCODE opcode = (CNTLR_OPCODE) uptr->OPCODE; | |
if (opcode == Write /* if this is a Write command */ | |
&& cvptr->spd_unit & CM_PROTECTED /* and the track is protected */ | |
&& (uptr->flags & UNIT_FMT) == 0) /* but the FORMAT switch is not set */ | |
end_command (cvptr, uptr, Protected_Track); /* then fail with a protection error */ | |
else if (uptr->STATUS & S2_READ_ONLY /* otherwise if the unit is write protected */ | |
|| opcode != Write && (uptr->flags & UNIT_FMT) == 0) /* or the FORMAT switch must be set but is not */ | |
end_command (cvptr, uptr, Status_2_Error); /* then fail with a status error */ | |
else if (position_sector (cvptr, uptr) == TRUE) { /* otherwise if positioning the sector succeeded */ | |
cvptr->length = cmd_props [opcode].transfer_size; /* then set the appropriate transfer length */ | |
cvptr->index = 0; /* and reset the data index */ | |
dpprintf (cvptr->device, DL_DEB_INCO, "Unit %d %s to cylinder %d head %d sector %d\n", | |
uptr - cvptr->device->units, opcode_name [opcode], | |
uptr->CYL, cvptr->head, cvptr->sector); | |
return TRUE; /* the write was successfully started */ | |
} | |
return FALSE; /* otherwise an error occurred or a seek is required */ | |
} | |
/* Finish a write operation on the current sector. | |
This routine is called at the end of the intersector phase to finish a write | |
operation. 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 three header words at the start of the buffer that are | |
not written to the disc image). | |
If the image write failed with a host file system error, it is reported to | |
the simulation console and the write ends with an Uncorrectable Data Error. | |
If it succeeded, the diagnostic override status is checked. If it is set, | |
then the write is terminated with the indicated status. Otherwise, the data | |
overrun flag is checked. If it is set, the write is terminated with an | |
error. Otherwise, the next sector is addressed. If the end-of-data flag is | |
set, the current write is completed. Otherwise,the rotate phase is set up in | |
preparation for the next sector write. | |
Implementation notes: | |
1. This routine changes the unit phase state as follows: | |
Intersector_Phase => Idle_Phase if EOD or error | |
Intersector_Phase => Rotate_Phase otherwise | |
2. A partial sector is filled either with octal 177777 words (ICD) or copies | |
of the last word (MAC), per page 7-10 of the ICD/MAC Disc Diagnostic | |
manual. | |
*/ | |
static void end_write (CVPTR cvptr, UNIT *uptr, CNTLR_FLAG_SET flags) | |
{ | |
uint32 count; | |
uint16 pad; | |
const CNTLR_OPCODE opcode = (CNTLR_OPCODE) uptr->OPCODE; | |
const uint32 offset = (opcode == Write_Full_Sector ? 3 : 0); | |
if (uptr->flags & UNIT_UNLOAD) { /* if the drive is not ready */ | |
end_command (cvptr, uptr, Access_Not_Ready); /* then terminate the command */ | |
return; /* with an access error */ | |
} | |
if (cvptr->index < WORDS_PER_SECTOR + offset) { /* if a partial sector was transferred */ | |
if (cvptr->type == ICD) /* then an ICD controller */ | |
pad = D16_UMAX; /* pads the sector with -1 words */ | |
else /* whereas a MAC controller */ | |
pad = cvptr->buffer [cvptr->index - 1]; /* pads with the last word written */ | |
for (count = cvptr->index; count < WORDS_PER_SECTOR + 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 */ | |
WORDS_PER_SECTOR, uptr->fileref); | |
if (ferror (uptr->fileref)) /* if a host file system error occurred, then report it */ | |
io_error (cvptr, uptr); /* and terminate with Uncorrectable Data Error status */ | |
else if (cvptr->status != Normal_Completion) /* otherwise if a diagnostic override is present */ | |
end_command (cvptr, uptr, cvptr->status); /* then report the indicated status */ | |
else if (flags & OVRUN) /* otherwise if a write overrun occurred */ | |
end_command (cvptr, uptr, Data_Overrun); /* then terminate the command with an error */ | |
else { /* otherwise the write succeeded */ | |
next_sector (cvptr, uptr); /* so address the next sector */ | |
if (flags & EOD) /* if the end of data is indicated */ | |
end_command (cvptr, uptr, Normal_Completion); /* then complete the command */ | |
else { /* otherwise writing continues */ | |
uptr->PHASE = Rotate_Phase; /* so set up the unit for the rotate phase */ | |
uptr->wait = cvptr->dlyptr->intersector_gap; /* with a delay for the intersector time */ | |
} | |
} | |
return; | |
} | |
/* 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, the diagnostic override status is checked. If it is set to | |
anything other than a data error, then positioning is terminated with the | |
indicated status to simulate an address verification failure. Otherwise, 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 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. | |
Otherwise, the seek is legal, and the routine returns with the seek phase set | |
to wait for seek completion before resuming the current read or 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 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 unit set to the seek phase | |
to wait for seek completion as above. | |
If the drive and controller positions agree or address 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 file is positioned to a byte offset in the | |
image file that is calculated from the CHS address. The data phase is set up | |
to begin the data transfer, and the routine returns TRUE to indicate that the | |
file position is 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) | |
{ | |
const uint32 model = GET_MODEL (uptr->flags); /* get the drive model */ | |
if (cvptr->status != Normal_Completion /* if a diagnostic override is present */ | |
&& cvptr->status != Uncorrectable_Data_Error /* and it's not */ | |
&& cvptr->status != Correctable_Data_Error) /* a data error */ | |
end_command (cvptr, uptr, cvptr->status); /* then report it */ | |
else if (cvptr->eoc == SET) /* otherwise if we are at the end of a cylinder */ | |
if (cvptr->file_mask & CM_AUTO_SEEK_EN) { /* then if an auto-seek is allowed */ | |
if (cvptr->file_mask & CM_DECR_SEEK) /* then if a decremental seek is requested */ | |
cvptr->cylinder = cvptr->cylinder - 1 & D16_MASK; /* then decrease the address with wraparound */ | |
else /* otherwise an incremental seek is requested */ | |
cvptr->cylinder = cvptr->cylinder + 1 & D16_MASK; /* so increase the address with wraparound */ | |
start_seek (cvptr, uptr); /* start the auto-seek */ | |
dpprintf (cvptr->device, DL_DEB_INCO, "Unit %d %s%s autoseek to cylinder %d head %d sector %d\n", | |
uptr - cvptr->device->units, opcode_name [uptr->OPCODE], | |
(uptr->STATUS & S2_SEEK_CHECK ? " seek check on" : ""), | |
cvptr->cylinder, cvptr->head, cvptr->sector); | |
if (uptr->STATUS & S2_SEEK_CHECK) /* if a seek check occurred */ | |
if (cvptr->type == ICD) /* then if this is an ICD controller */ | |
end_command (cvptr, uptr, End_of_Cylinder); /* then report it as an End of Cylinder error */ | |
else /* otherwise */ | |
end_command (cvptr, uptr, Status_2_Error); /* report it as a Status-2 error */ | |
} | |
else /* otherwise the file mask does not permit an auto-seek */ | |
end_command (cvptr, uptr, End_of_Cylinder); /* so terminate with an EOC error */ | |
else if (cvptr->verify /* if address verification is enabled */ | |
&& (uint32) uptr->CYL != cvptr->cylinder) { /* and the positioner is on the wrong cylinder */ | |
start_seek (cvptr, uptr); /* then start a seek to the correct cylinder */ | |
dpprintf (cvptr->device, DL_DEB_INCO, "Unit %d %s%s reseek to cylinder %d head %d sector %d\n", | |
uptr - cvptr->device->units, opcode_name [uptr->OPCODE], | |
(uptr->STATUS & S2_SEEK_CHECK ? " seek check on" : ""), | |
cvptr->cylinder, cvptr->head, cvptr->sector); | |
if (uptr->STATUS & S2_SEEK_CHECK) /* if a seek check occurred */ | |
end_command (cvptr, uptr, Status_2_Error); /* then report a Status-2 error */ | |
} | |
else if (((uint32) uptr->CYL >= drive_props [model].cylinders) /* otherwise the heads are positioned correctly */ | |
|| (cvptr->head >= drive_props [model].heads) /* but if the cylinder */ | |
|| (cvptr->sector >= drive_props [model].sectors)) { /* or head or sector is out of bounds */ | |
uptr->STATUS |= S2_SEEK_CHECK; /* then set Seek Check status */ | |
end_command (cvptr, uptr, Status_2_Error); /* and terminate with an error */ | |
} | |
else if (uptr->flags & UNIT_UNLOAD) /* otherwise if the drive is not ready for positioning */ | |
end_command (cvptr, uptr, Access_Not_Ready); /* then terminate with an access error */ | |
else { /* otherwise we are ready to move the heads */ | |
set_file_pos (cvptr, uptr, model); /* so calculate the new position */ | |
sim_fseek (uptr->fileref, uptr->pos, SEEK_SET); /* set the image file position */ | |
uptr->PHASE = Data_Phase; /* set up the data transfer phase */ | |
if (cvptr->device->flags & DEV_REALTIME) /* if the real time mode is enabled */ | |
uptr->wait = cvptr->dlyptr->data_xfer /* then base the delay on the sector preamble size */ | |
* cmd_props [uptr->OPCODE].preamble_size; | |
else /* otherwise */ | |
uptr->wait = cvptr->dlyptr->data_xfer; /* start the transfer with a nominal delay */ | |
return TRUE; /* report that positioning was accomplished */ | |
} | |
return FALSE; /* positioning failed or was deferred */ | |
} | |
/* Address the next sector. | |
This routine is called after a sector has been successfully read or written | |
in preparation for continuing the transfer. It is also called after the | |
Request Syndrome command returns the correction status for a sector in error. | |
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 and the address verification state is reset to | |
enable it for a Read_Without_Verify command. 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) /* if we at not the end of the track */ | |
return; /* then the next sector value is OK */ | |
cvptr->sector = 0; /* otherwise wrap the sector number */ | |
cvptr->verify = cmd_props [uptr->OPCODE].verify_address; /* and set the address verification flag */ | |
if (cvptr->file_mask & CM_CYL_MODE) { /* if the controller is in cylinder mode */ | |
cvptr->head = cvptr->head + 1; /* then increment the head */ | |
if (cvptr->head < drive_props [model].heads) /* if we are not at the end of the cylinder */ | |
return; /* then the next head value is OK */ | |
cvptr->head = 0; /* otherwise wrap the head number */ | |
} | |
cvptr->eoc = SET; /* set the end-of-cylinder flag */ | |
return; /* to 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. The routine returns TRUE if the unit is seeking and FALSE if | |
the seek failed to start. | |
If the drive is not ready, the seek fails immediately with a Status-2 error. | |
If the drive is already seeking, Seek Check status will occur, and the | |
routine will return TRUE to allow the current seek to complete normally. | |
Otherwise, a seek is initiated to cylinder 0 if the current command is | |
Recalibrate or to the cylinder value stored in the controller if it is not. | |
EOC is reset for a seek but not for recalibrate, so that a reseek will return | |
to the same location as was current when the recalibration was done. | |
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. | |
In hardware, the controller issues tag bus SEEK and ADR (address record) | |
commands to the drive to load the drive's cylinder, head, and sector | |
registers. On the 7905 and 7906 drives, loading the head register | |
establishes the drive's Read-Only status in conjunction with the PROTECT | |
UPPER/LOWER DISC switch settings. | |
A seek check for either the cylinder, head, or sector 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 unit is set to the seek phase, and the scheduling delay is | |
calculated by the distance the heads traversed (in real time mode), or | |
it is set to a fixed delay (in fast time mode). | |
Implementation notes: | |
1. For ICD drives, a seek check will terminate the command immediately with | |
a Status-2 error. A seek-in-progress seek check cannot occur on an ICD | |
drive, however, because the second seek command will not be started until | |
the first seek completes. | |
2. 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. | |
3. The head register contents does not affect Read-Only status on the 7920 | |
or 7925, which is established solely by the switch setting. However, we | |
set the drive status here anyway as a convenience. | |
*/ | |
static t_bool start_seek (CVPTR cvptr, UNIT *uptr) | |
{ | |
int32 delta; | |
uint32 target_cylinder; | |
const uint32 model = GET_MODEL (uptr->flags); /* get the drive model */ | |
if (uptr->flags & UNIT_UNLOAD) /* if the heads are unloaded */ | |
return FALSE; /* then the seek fails as the drive was not ready */ | |
else if (uptr->PHASE == Seek_Phase) { /* otherwise if a seek is in progress */ | |
uptr->STATUS |= S2_SEEK_CHECK; /* then set Seek Check status */ | |
return TRUE; /* and return to let the seek complete */ | |
} | |
else if (uptr->OPCODE == Recalibrate) /* otherwise if the unit is recalibrating */ | |
target_cylinder = 0; /* then seek to cylinder 0 and don't reset the EOC flag */ | |
else { /* otherwise it's a Seek command or an auto-seek request */ | |
target_cylinder = cvptr->cylinder; /* so seek to the controller cylinder */ | |
cvptr->eoc = CLEAR; /* and clear the end-of-cylinder flag */ | |
} | |
if (target_cylinder >= drive_props [model].cylinders) { /* if the cylinder is out of bounds */ | |
delta = 0; /* then don't change the positioner */ | |
uptr->STATUS |= S2_SEEK_CHECK; /* and set Seek Check status */ | |
} | |
else { /* otherwise the cylinder value is OK */ | |
delta = abs (uptr->CYL - (int32) 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->STATUS |= S2_SEEK_CHECK; /* then set Seek Check status */ | |
else { /* otherwise the head and sector are OK */ | |
uptr->STATUS &= ~S2_SEEK_CHECK; /* so clear Seek Check status */ | |
if (uptr->flags & /* if the selected head is protected */ | |
(cvptr->head > 1 ? UNIT_PROT_L : UNIT_PROT_U)) | |
uptr->STATUS |= S2_READ_ONLY; /* then set read-only status */ | |
else /* otherwise */ | |
uptr->STATUS &= ~S2_READ_ONLY; /* clear it */ | |
} | |
} | |
if (uptr->STATUS & S2_SEEK_CHECK && cvptr->type == ICD) /* if a seek check occurred on an ICD controller */ | |
return FALSE; /* then the command fails immediately */ | |
else { /* otherwise the seek was OK or this is a MAC controller */ | |
uptr->PHASE = Seek_Phase; /* so set the unit to the seek phase */ | |
uptr->wait = cvptr->dlyptr->seek_one /* set the seek delay, based on the relative movement */ | |
+ delta * (cvptr->dlyptr->seek_full - cvptr->dlyptr->seek_one) | |
/ drive_props [model].cylinders; | |
} | |
return TRUE; /* the seek is underway */ | |
} | |
/* Report an I/O error. | |
Errors indicated by the host file system are printed on the simulation | |
console, and the current command is terminated with an Uncorrectable Data | |
Error indication from the controller. The target OS will retry the | |
operation; if it continues to fail, the OS will handle it appropriately. | |
*/ | |
static void io_error (CVPTR cvptr, UNIT *uptr) | |
{ | |
cprintf ("%s simulator disc library I/O error: %s\n", /* report the error to the console */ | |
sim_name, strerror (errno)); | |
clearerr (uptr->fileref); /* clear the error */ | |
end_command (cvptr, uptr, Uncorrectable_Data_Error); /* terminate the command with a bad data error */ | |
return; | |
} | |
/* Set up the controller completion. | |
This routine performs a scheduled "end_command" to complete a command after a | |
short delay. It is called for commands that execute to completion with no | |
drive or CPU interface interaction. An otherwise unused "end phase" is | |
scheduled just so that the command does not appear to complete | |
instantaneously. | |
*/ | |
static void set_completion (CVPTR cvptr, UNIT *uptr, CNTLR_STATUS status) | |
{ | |
cvptr->status = status; /* save the supplied status */ | |
uptr->PHASE = End_Phase; /* schedule the end phase */ | |
uptr->wait = cvptr->dlyptr->overhead / 2; /* with a short delay */ | |
return; | |
} | |
/* 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] = /* update the cylinder if EOC is set */ | |
(uint16) cvptr->cylinder + (cvptr->eoc == SET ? 1 : 0); | |
cvptr->buffer [index + 1] = /* merge the head and sector */ | |
(uint16) (PO_HEAD (cvptr->head) | PO_SECTOR (cvptr->sector)); | |
return; | |
} | |
/* Return the drive status (Status-2). | |
This routine returns the formatted unit status for the indicated drive unit. | |
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, Read-Only, First Status, and Seek Check bits are stored | |
in the unit status field. The other status bits are determined | |
dynamically (the Drive Fault bit is not simulated). | |
2. The Drive Busy bit is set if the unit is in the seek phase. In hardware, | |
this bit indicates that the heads are not positioned over a track, i.e., | |
that a seek is in progress. A Request Status command is accepted only | |
when the controller is waiting for seek completion or for a new command. | |
Therefore, the unit will be either in the seek phase or the idle phase, | |
respectively, when status is returned. | |
*/ | |
static uint16 drive_status (UNIT *uptr) | |
{ | |
uint16 status; | |
if (uptr == NULL) /* if the unit is invalid */ | |
return S2_ERROR | S2_NOT_READY; /* then it does not respond */ | |
status = /* start with the drive type and unit status */ | |
(uint16) (S2_DRIVE_TYPE (GET_MODEL (uptr->flags)) | uptr->STATUS); | |
if (uptr->flags & UNIT_FMT) /* if the format switch is enabled */ | |
status |= S2_FORMAT_EN; /* then set the Format status bit */ | |
if (uptr->flags & UNIT_DIS) /* if the unit does not exist */ | |
status |= S2_NOT_READY; /* then set the Not Ready bit */ | |
else if (uptr->flags & UNIT_UNLOAD) /* if the heads are unloaded */ | |
status |= S2_NOT_READY | S2_BUSY; /* then set the Not Ready and Drive Busy bits */ | |
if (uptr->PHASE == Seek_Phase) /* if a seek is in progress */ | |
status |= S2_BUSY; /* then set the Drive Busy bit */ | |
if (status & S2_ERRORS) /* if there any Status-2 errors */ | |
status |= S2_ERROR; /* then set the Error summary bit */ | |
return status; /* return the unit status */ | |
} | |
/* Activate the unit. | |
The specified unit is activated using the unit's "wait" time. If tracing | |
is enabled, the activation is logged to the debug file. | |
Implementation notes: | |
1. The "%.0d" print specification in the trace call absorbs the zero "unit" | |
value parameter without printing when the controller unit is specified. | |
*/ | |
static t_stat activate_unit (CVPTR cvptr, UNIT *uptr) | |
{ | |
t_stat result; | |
uint32 unit = uptr - cvptr->device->units; | |
dpprintf (cvptr->device, DL_DEB_SERV, (unit == CNTLR_UNIT | |
? "Controller unit%.0d %s %s phase delay %d service scheduled\n" | |
: "Unit %d %s %s phase delay %d service scheduled\n"), | |
(unit == CNTLR_UNIT ? 0 : unit), opcode_name [uptr->OPCODE], | |
phase_name [uptr->PHASE], uptr->wait); | |
result = sim_activate (uptr, uptr->wait); /* activate the unit */ | |
uptr->wait = NO_EVENT; /* and reset the activation time */ | |
return result; /* return the activation status */ | |
} | |
/* Set up the rotation phase. | |
The supplied unit is set to the rotate phase at the start of a read or write | |
command. In real time mode, the rotational latency is determined by the | |
distance between the "current" sector location and the target sector | |
location. The former is estimated from the current "simulation time," which | |
is the number of event ticks since the simulation run was started, and the | |
simulated disc rotation time, as follows: | |
(simulation_time / per_sector_time) MOD sectors_per_track | |
The distance is then: | |
(sectors_per_track + target_sector - current_sector) MOD sectors_per_track | |
...and the latency is then: | |
distance * per_sector_time | |
In fast time mode, the latency is fixed at the specified per-sector time. | |
*/ | |
static void set_rotation (CVPTR cvptr, UNIT *uptr) | |
{ | |
uint32 sectors_per_track; | |
double distance; | |
uptr->PHASE = Rotate_Phase; /* set the phase */ | |
if (cvptr->device->flags & DEV_REALTIME) { /* if the mode is real time */ | |
sectors_per_track = /* then calculate the latency as above */ | |
drive_props [GET_MODEL (uptr->flags)].sectors; | |
distance = | |
fmod (sectors_per_track + cvptr->sector - CURRENT_SECTOR (cvptr, uptr), | |
sectors_per_track); | |
uptr->wait = (int32) (cvptr->dlyptr->sector_full * distance); | |
} | |
else /* otherwise the mode is fast time */ | |
uptr->wait = cvptr->dlyptr->sector_full; /* so use the specified time directly */ | |
} | |
/* Set the image file position. | |
A cylinder/head/sector address is converted into a byte offset to pass to the | |
host file I/O routines. The cylinder is supplied by the drive unit, and the | |
head and sector addresses are supplied by the controller. The disc image | |
file is laid out in one or two pieces, depending on whether a fixed platter | |
is present in the drive. If it is, then the area corresponding to the | |
removable platter precedes the area corresponding to the fixed platter. If | |
not, then the file contains a single area encompassing all of the (removable) | |
heads. | |
In either case, the target track within the area is: | |
cylinder * heads_per_cylinder + head | |
...and the target byte position in the file is: | |
(target_track * sectors_per_track + sector) * bytes_per_sector | |
*/ | |
static void set_file_pos (CVPTR cvptr, UNIT *uptr, uint32 model) | |
{ | |
uint32 track; | |
if (cvptr->head < drive_props [model].remov_heads) /* if the head is on a removable platter */ | |
track = uptr->CYL * drive_props [model].remov_heads /* then the tracks in the file are contiguous */ | |
+ cvptr->head; | |
else /* otherwise the head is on a fixed platter */ | |
track = drive_props [model].cylinders /* so the target track is located */ | |
* drive_props [model].remov_heads /* in the second area */ | |
+ uptr->CYL * drive_props [model].fixed_heads /* that is offset from the first */ | |
+ cvptr->head - drive_props [model].remov_heads; /* by the size of the removable platter */ | |
uptr->pos = (track * drive_props [model].sectors + cvptr->sector) /* set the byte offset in the file */ | |
* WORDS_PER_SECTOR * sizeof (uint16); /* of the CHS target sector */ | |
return; | |
} |