NAME
microseq — ppbus microsequencer developer’s guide
SYNOPSIS
#include <sys/types.h>
#include <dev/ppbus/ppbconf.h>
#include <dev/ppbus/ppb_msq.h>
DESCRIPTION
See ppbus(4) for ppbus description and general info about the microsequencer.
The purpose of this document is to encourage developers to use the microsequencer mechanism in order to have:
1.
a uniform programming model
2.
efficient code
Before using microsequences, you are encouraged to look at ppc(4) microsequencer implementation and an example of how using it in vpo(4).
PPBUS register model
Background
The parallel port model chosen for ppbus is the PC parallel
port model. Thus, any register described later has the same
semantic than its counterpart in a PC parallel port. For
more info about ISA/ECP programming, get the Microsoft
standard referenced as "Extended Capabilities Port
Protocol and ISA interface Standard". Registers
described later are standard parallel port registers.
Mask macros are defined in the standard ppbus include files for each valid bit of parallel port registers.
Data
register
In compatible or nibble mode, writing to this register will
drive data to the parallel port data lines. In any other
mode, drivers may be tri-stated by setting the direction bit
(PCD) in the control register. Reads to this register return
the value on the data lines.
Device status
register
This read-only register reflects the inputs on the parallel
port interface.
Bit Name
Description
7 nBUSY inverted version of parallel port Busy signal
6 nACK version of parallel port nAck signal
5 PERROR version of parallel port PERROR signal
4 SELECT version of parallel port Select signal
3 nFAULT version of parallel port nFault signal
Others are reserved and return undefined result when read.
Device
control register
This register directly controls several output signals as
well as enabling some functions.
Bit Name
Description
5 PCD direction bit in extended modes
4 IRQENABLE 1 enables an interrupt on the rising edge of
nAck
3 SELECTIN inverted and driven as parallel port nSelectin
signal
2 nINIT driven as parallel port nInit signal
1 AUTOFEED inverted and driven as parallel port nAutoFd
signal
0 STROBE inverted and driven as parallel port nStrobe
signal
MICROINSTRUCTIONS
Description
Microinstructions are either parallel port accesses,
program iterations, submicrosequence or C calls. The
parallel port must be considered as the logical model
described in ppbus(4).
Available microinstructions are:
#define MS_OP_GET 0 /* get <ptr>, <len> */
#define MS_OP_PUT 1 |
/* put <ptr>, <len> |
*/ | |||||||
#define MS_OP_RFETCH |
2 |
/* rfetch <reg>, <mask>, <ptr> |
*/ | ||||||
#define MS_OP_RSET |
3 |
/* rset <reg>, <mask>, <mask> |
*/ | ||||||
#define MS_OP_RASSERT |
4 |
/* rassert <reg>, <mask> |
*/ | ||||||
#define MS_OP_DELAY 5 |
/* delay <val> |
*/ | |||||||
#define MS_OP_SET 6 |
/* set <val> |
*/ | |||||||
#define MS_OP_DBRA 7 |
/* dbra <offset> |
*/ | |||||||
#define MS_OP_BRSET 8 |
/* brset <mask>, <offset> |
*/ | |||||||
#define MS_OP_BRCLEAR 9 |
/* brclear <mask>, <offset> |
*/ | |||||||
#define MS_OP_RET 10 |
/* ret <retcode> |
*/ | |||||||
#define MS_OP_C_CALL |
11 |
/* c_call <function>, <parameter> |
*/ | ||||||
#define MS_OP_PTR |
12 |
/* ptr <pointer> |
*/ | ||||||
#define MS_OP_ADELAY |
13 |
/* adelay <val> |
*/ | ||||||
#define MS_OP_BRSTAT |
14 |
/* brstat <mask>, <mask>, <offset> |
*/ | ||||||
#define MS_OP_SUBRET |
15 |
/* subret <code> |
*/ | ||||||
#define MS_OP_CALL |
16 |
/* call <microsequence> |
*/ | ||||||
#define MS_OP_RASSERT_P |
17 |
/* rassert_p <iter>, <reg> |
*/ | ||||||
#define MS_OP_RFETCH_P |
18 |
/* rfetch_p <iter>, <reg>, <mask> |
*/ | ||||||
#define MS_OP_TRIG |
19 |
/* trigger <reg>, <len>, <array> |
*/ |
Execution
context
The execution context of microinstructions is:
•
the program counter which points to the next microinstruction to execute either in the main microsequence or in a subcall
•
the current value of ptr which points to the next char to send/receive
•
the current value of the internal branch register
This data is modified by some of the microinstructions, not all.
MS_OP_GET and
MS_OP_PUT
are microinstructions used to do either predefined standard
IEEE1284-1994 transfers or programmed non-standard io.
MS_OP_RFETCH
- Register FETCH
is used to retrieve the current value of a parallel port
register, apply a mask and save it in a buffer.
Parameters:
1.
register
2.
character mask
3.
pointer to the buffer
Predefined macro: MS_RFETCH(reg,mask,ptr)
MS_OP_RSET -
Register SET
is used to assert/clear some bits of a particular parallel
port register, two masks are applied.
Parameters:
1.
register
2.
mask of bits to assert
3.
mask of bits to clear
Predefined macro: MS_RSET(reg,assert,clear)
MS_OP_RASSERT
- Register ASSERT
is used to assert all bits of a particular parallel port
register.
Parameters:
1.
register
2.
byte to assert
Predefined macro: MS_RASSERT(reg,byte)
MS_OP_DELAY -
microsecond DELAY
is used to delay the execution of the microsequence.
Parameter:
1.
delay in microseconds
Predefined macro: MS_DELAY(delay)
MS_OP_SET -
SET internal branch register
is used to set the value of the internal branch
register.
Parameter:
1.
integer value
Predefined macro: MS_SET(accum)
MS_OP_DBRA -
Do BRAnch
is used to branch if internal branch register decremented by
one result value is positive.
Parameter:
1.
integer offset in the current executed (sub)microsequence. Offset is added to the index of the next microinstruction to execute.
Predefined macro: MS_DBRA(offset)
MS_OP_BRSET -
BRanch on SET
is used to branch if some of the status register bits of the
parallel port are set.
Parameter:
1.
bits of the status register
2.
integer offset in the current executed (sub)microsequence. Offset is added to the index of the next microinstruction to execute.
Predefined macro: MS_BRSET(mask,offset)
MS_OP_BRCLEAR
- BRanch on CLEAR
is used to branch if some of the status register bits of the
parallel port are cleared.
Parameter:
1.
bits of the status register
2.
integer offset in the current executed (sub)microsequence. Offset is added to the index of the next microinstruction to execute.
Predefined macro: MS_BRCLEAR(mask,offset)
MS_OP_RET -
RETurn
is used to return from a microsequence. This instruction is
mandatory. This is the only way for the microsequencer to
detect the end of the microsequence. The return code is
returned in the integer pointed by the (int *) parameter of
the ppb_MS_microseq().
Parameter:
1.
integer return code
Predefined macro: MS_RET(code)
MS_OP_C_CALL
- C function CALL
is used to call C functions from microsequence execution.
This may be useful when a non-standard i/o is performed to
retrieve a data character from the parallel port.
Parameter:
1.
the C function to call
2.
the parameter to pass to the function call
The C function shall be declared as a int(*)(void *p, char *ptr). The ptr parameter is the current position in the buffer currently scanned.
Predefined macro: MS_C_CALL(func,param)
MS_OP_PTR -
initialize internal PTR
is used to initialize the internal pointer to the currently
scanned buffer. This pointer is passed to any C call (see
above).
Parameter:
1.
pointer to the buffer that shall be accessed by xxx_P() microsequence calls. Note that this pointer is automatically incremented during xxx_P() calls
Predefined macro: MS_PTR(ptr)
MS_OP_ADELAY
- do an Asynchronous DELAY
is used to make a tsleep() during microsequence execution.
The tsleep is executed at PPBPRI level.
Parameter:
1.
delay in ms
Predefined macro: MS_ADELAY(delay)
MS_OP_BRSTAT
- BRanch on STATe
is used to branch on status register state condition.
Parameter:
1.
mask of asserted bits. Bits that shall be asserted in the status register are set in the mask
2.
mask of cleared bits. Bits that shall be cleared in the status register are set in the mask
3.
integer offset in the current executed (sub)microsequence. Offset is added to the index of the next microinstruction to execute.
Predefined macro: MS_BRSTAT(asserted_bits,clear_bits,offset)
MS_OP_SUBRET
- SUBmicrosequence RETurn
is used to return from the submicrosequence call. This
action is mandatory before a RET call. Some
microinstructions (PUT, GET) may not be callable within a
submicrosequence.
No parameter.
Predefined macro: MS_SUBRET()
MS_OP_CALL -
submicrosequence CALL
is used to call a submicrosequence. A submicrosequence is a
microsequence with a SUBRET call. Parameter:
1.
the submicrosequence to execute
Predefined macro: MS_CALL(microseq)
MS_OP_RASSERT_P
- Register ASSERT from internal PTR
is used to assert a register with data currently pointed by
the internal PTR pointer. Parameter:
1.
amount of data to write to the register
2.
register
Predefined macro: MS_RASSERT_P(iter,reg)
MS_OP_RFETCH_P
- Register FETCH to internal PTR
is used to fetch data from a register. Data is stored in the
buffer currently pointed by the internal PTR pointer.
Parameter:
1.
amount of data to read from the register
2.
register
3.
mask applied to fetched data
Predefined macro: MS_RFETCH_P(iter,reg,mask)
MS_OP_TRIG -
TRIG register
is used to trigger the parallel port. This microinstruction
is intended to provide a very efficient control of the
parallel port. Triggering a register is writing data, wait a
while, write data, wait a while... This allows to write
magic sequences to the port. Parameter:
1.
amount of data to read from the register
2.
register
3.
size of the array
4.
array of unsigned chars. Each couple of u_chars define the data to write to the register and the delay in us to wait. The delay is limited to 255 us to simplify and reduce the size of the array.
Predefined macro: MS_TRIG(reg,len,array)
MICROSEQUENCES
C structures
union ppb_insarg {
int i;
char c;
void *p;
int (* f)(void *, char *);
};
struct
ppb_microseq {
int opcode; /* microins. opcode */
union ppb_insarg arg[PPB_MS_MAXARGS]; /* arguments */
};
Using
microsequences
To instantiate a microsequence, just declare an array of
ppb_microseq structures and initialize it as needed. You may
either use predefined macros or code directly your
microinstructions according to the ppb_microseq definition.
For example,
struct ppb_microseq select_microseq[] = {
/* parameter list |
||
*/ |
||
#define SELECT_TARGET MS_PARAM(0, 1, MS_TYP_INT) |
||
#define SELECT_INITIATOR MS_PARAM(3, 1, MS_TYP_INT) |
||
/* send the select command to the drive */ |
||
MS_DASS(MS_UNKNOWN), |
||
MS_CASS(H_nAUTO | H_nSELIN | H_INIT | H_STROBE), |
||
MS_CASS( H_AUTO | H_nSELIN | H_INIT | H_STROBE), |
||
MS_DASS(MS_UNKNOWN), |
||
MS_CASS( H_AUTO | H_nSELIN | H_nINIT | H_STROBE), |
||
/* now, wait until the drive is ready */ |
||
MS_SET(VP0_SELTMO), |
/* loop: */ MS_BRSET(H_ACK, 2 /* ready */),
MS_DBRA(-2 /* loop */), |
/* error: */ MS_RET(1),
/* ready: */ MS_RET(0)
};
Here, some parameters are undefined and must be filled before executing the microsequence. In order to initialize each microsequence, one should use the ppb_MS_init_msq() function like this:
ppb_MS_init_msq(select_microseq, 2,
SELECT_TARGET, 1 << target, |
|||
SELECT_INITIATOR, 1 << initiator); |
and then execute the microsequence.
The
microsequencer
The microsequencer is executed either at ppbus or adapter
level (see ppbus(4) for info about ppbus system layers).
Most of the microsequencer is executed at ppc level to avoid
ppbus to adapter function call overhead. But some actions
like deciding whereas the transfer is IEEE1284-1994
compliant are executed at ppbus layer.
SEE ALSO
HISTORY
The microseq manual page first appeared in FreeBSD 3.0.
AUTHORS
This manual page was written by Nicolas Souchu.
BUGS
Only one level of submicrosequences is allowed.
When triggering the port, maximum delay allowed is 255 us.
BSD June 6, 1998 BSD