VHDL Class NOtes Unit3 - Part6 by Zainalabedin Navabi

PART 6

Manual Controller Design

Controller hardware
VHDL style
Signals and resolutions
State descriptions
Complete CPU
Testing CPU

Controller.onehot

Only one hot state at a given time
Easier design,
No need for encoding states
No need for decoding control lines

Controller.hardware

Encoded state machine
Requires more output and input logic
Requires fewer flip-flops

Controller.hardware

We will use a one hot controller
Hardware surrounding a control flip-flop
A control flip-flop conditionally activates control signals

Controller.hardware

Control signals are issued by various control flip-flops
Use OR gate for oring same-name control signals
All signals activating a control flip-flop are ored

Controller.hardware

Three control states and corresponding logic
csy conditionally issued by j
csx conditionally issued by i also unconditionally issued by k

Controller.VHDL_style

ARCHITECTURE multiple_state_machine OF detector IS

SIGNAL s : ored_bit_vector (1 TO 4) REGISTER := "1000";

BEGIN

clocking : BLOCK (clk = '1' AND NOT clk'STABLE)

BEGIN

s1: BLOCK (s(1) = '1' AND GUARD)

BEGIN

s(1) <= GUARDED '1' WHEN x = '0' ELSE '0';

s(2) <= GUARDED '1' WHEN x = '1' ELSE '0';

END BLOCK s1;

s2: BLOCK (s(2) = '1' AND GUARD)

BEGIN

s(3) <= GUARDED '1' WHEN x = '0' ELSE '0';

s(2) <= GUARDED '1' WHEN x = '1' ELSE '0';

END BLOCK s2;

s3: BLOCK (s(3) = '1' AND GUARD)

BEGIN

s(1) <= GUARDED '1' WHEN x = '0' ELSE '0';

s(4) <= GUARDED '1' WHEN x = '1' ELSE '0';

END BLOCK s3;

s4: BLOCK (s(4) = '1' AND GUARD)

BEGIN

s(3) <= GUARDED '1' WHEN x = '0' ELSE '0';

s(2) <= GUARDED '1' WHEN x = '1' ELSE '0';

z <= '1' WHEN (s(4) = '1' AND x = '1') ELSE '0';

END BLOCK s4;

s <= GUARDED "0000";

END BLOCK clocking;

END multiple_state_machine;

State machine description style
A guarded block for each state

Controller.VHDL_style

sn: Block (guard on state n)
BEGIN
issue control signals
.
.
.
ck: Block (guard on clock)
issue next state;
END Block ck;
END Block sn;

Issue control signals in each state
A guarded block guards next state assignment

Controller.signals_and_resolutions

Controller issues signals used by data
Decisions made based on ir_lines

Controller.signals_and_resolutions

ARCHITECTURE dataflow OF par_control_unit IS

-- oring is implied in the following signals (oi)

SIGNAL load_ac_oi, zero_ac_oi,

load_ir_oi,

increment_pc_oi, load_page_pc_oi, load_offset_pc_oi, reset_pc_oi,

load_page_mar_oi, load_offset_mar_oi,

load_sr_oi, cm_carry_sr_oi,

pc_on_mar_page_bus_oi, ir_on_mar_page_bus_oi,

pc_on_mar_offset_bus_oi, dbus_on_mar_offset_bus_oi,

pc_offset_on_dbus_oi, obus_on_dbus_oi, databus_on_dbus_oi,

mar_on_adbus_oi,

dbus_on_databus_oi,

arith_shift_left_oi, arith_shift_right_oi,

read_mem_oi, write_mem_oi : ored_qit BUS;

SIGNAL alu_code_oi : ored_qit_vector (2 DOWNTO 0) BUS;

SIGNAL s : ored_qit_vector (9 DOWNTO 1) REGISTER := "000000001";

Use resolved signals to imply oring
Multiple assignments to oi signals are ored
Declare s as a register of 9 states

Controller.signals_and_resolutions

FUNCTION oring ( drivers : qit_vector) RETURN qit;
SUBTYPE ored_qit IS oring qit;
TYPE ored_qit_vector IS ARRAY (NATURAL RANGE <>) OF ored_qit;
(a)

FUNCTION oring ( drivers : qit_vector) RETURN qit IS
VARIABLE accumulate : qit := '0';
BEGIN
FOR i IN drivers'RANGE LOOP
accumulate := accumulate OR drivers(i);
END LOOP;
RETURN accumulate;
END oring;
(b)

Use oring resolution function
All assignments to same state are ored
All assignments to same control lines are ored

Controller.signals_and_resolutions

Ored signals control flow of data in the data section
Ored signals make appropriate state transitions
Data and control signals follow the same timing
Control signals are active from one falling edge to another
One period allows propagation through logic and buses

Controller.signals_and_resolutions

BEGIN

-- implied or assignments to output signals

load_ac <= load_ac_oi;

zero_ac <= zero_ac_oi;

load_ir <= load_ir_oi;

increment_pc <= increment_pc_oi;

load_page_pc <= load_page_pc_oi;

load_offset_pc <= load_offset_pc_oi;

reset_pc <= reset_pc_oi;

load_page_mar <= load_page_mar_oi;

load_offset_mar <= load_offset_mar_oi;

load_sr <= load_sr_oi;

cm_carry_sr <= cm_carry_sr_oi;

pc_on_mar_page_bus <= pc_on_mar_page_bus_oi;

ir_on_mar_page_bus <= ir_on_mar_page_bus_oi;

pc_on_mar_offset_bus <= pc_on_mar_offset_bus_oi;

dbus_on_mar_offset_bus <= dbus_on_mar_offset_bus_oi;

pc_offset_on_dbus <= pc_offset_on_dbus_oi;

obus_on_dbus <= obus_on_dbus_oi;

databus_on_dbus <= databus_on_dbus_oi;

mar_on_adbus <= mar_on_adbus_oi;

dbus_on_databus <= dbus_on_databus_oi;

arith_shift_left <= arith_shift_left_oi;

arith_shift_right <= arith_shift_right_oi;

read_mem <= read_mem_oi;

write_mem <= write_mem_oi;

alu_code <= qit_vector (alu_code_oi);

Make assignments to do type conversion

Controller.state_descriptions

s1: BLOCK (s(1) = '1')

BEGIN -- start of fetch

-- pc to mar

pc_on_mar_page_bus_oi <= GUARDED '1';

pc_on_mar_offset_bus_oi <= GUARDED '1';

load_page_mar_oi <= GUARDED '1';

load_offset_mar_oi <= GUARDED '1';

-- reset pc if interrupt

reset_pc_oi <= GUARDED '1' WHEN interrupt = '1' ELSE '0';

-- goto 2 if interrupt is off

ck: BLOCK ( (clk = '0' AND NOT clk'STABLE) AND GUARD )

BEGIN

s(1) <= GUARDED '1' WHEN interrupt = '1' ELSE '0';

s(2) <= GUARDED '1' WHEN interrupt /= '1' ELSE '0';

END BLOCK ck;

END BLOCK s1;

Start to fetch in state 1
Transfer pc to mar via mar_bus
Stay in state 1 if interrupted

Controller.state_descriptions

s2: BLOCK (s(2) = '1')

BEGIN -- fetching continues

-- read memory into ir

mar_on_adbus_oi <= GUARDED '1';

read_mem_oi <= GUARDED '1' AFTER read_delay;

databus_on_dbus_oi <= GUARDED '1';

alu_code_oi <= GUARDED ored_qit_vector (a_input);

load_ir_oi <= GUARDED '1';

-- increment pc

increment_pc_oi <= GUARDED '1';

-- goto 3

ck: BLOCK ( (clk = '0' AND NOT clk'STABLE) AND GUARD )

BEGIN

s(3) <= GUARDED '1';

END BLOCK ck;

END BLOCK s2;

Continue to fetch instruction
Read memory into ir

Controller.state_descriptions

s3: BLOCK (s(3) = '1')

BEGIN

-- pc to mar, for next read

pc_on_mar_page_bus_oi <= GUARDED '1';

pc_on_mar_offset_bus_oi <= GUARDED '1';

load_page_mar_oi <= GUARDED '1';

load_offset_mar_oi <= GUARDED '1';

-- goto 4 if not single byte instruction

ck: BLOCK ( (clk = '0' AND NOT clk'STABLE) AND GUARD )

BEGIN

s(4) <= GUARDED '1' WHEN ir_lines (7 DOWNTO 4) /= "1110" ELSE '0';

END BLOCK ck;

-- perform single byte instructions

sb: BLOCK ( (ir_lines (7 DOWNTO 4) = "1110") AND GUARD)

BEGIN

alu_code_oi <= GUARDED

ored_qit_vector (b_compl) WHEN ir_lines (1) = '1' ELSE

ored_qit_vector (b_input);

arith_shift_left_oi <= GUARDED

'1' WHEN ir_lines (3 DOWNTO 0) = "1000" ELSE '0';

arith_shift_right_oi <= GUARDED

'1' WHEN ir_lines (3 DOWNTO 0) = "1001" ELSE '0';

load_sr_oi <= GUARDED

'1' WHEN ( ir_lines (3) = '1' OR ir_lines (1) = '1' ) ELSE '0';

cm_carry_sr_oi <= GUARDED '1' WHEN ir_lines (2) = '1' ELSE '0';

load_ac_oi <= GUARDED

'1' WHEN ( ir_lines (3) = '1' OR ir_lines (1) = '1' ) ELSE '0';

zero_ac_oi <= GUARDED

'1' WHEN ( ir_lines (3) = '0' AND ir_lines (0) = '1' ) ELSE '0';

ck: BLOCK ( (clk = '0' AND NOT clk'STABLE) AND GUARD )

BEGIN

s(2) <= GUARDED '1';

END BLOCK ck;

END BLOCK sb;

END BLOCK s3;

For two byte instructions:

Prepare for address fetch, goto state 4

For single byte instructions:

Prepare for next instruction fetch, complete current instruction

Controller.state_descriptions

Hardware for state3
Logic block is enabled to do single_byte instructions
pc to mar transfer takes place

Controller.state_descriptions

s4: BLOCK (s(4) = '1')

BEGIN -- page from ir, and offset from next memory makeup 12-bit address

-- read memory into mar offset

mar_on_adbus_oi <= GUARDED '1';

read_mem_oi <= GUARDED '1' AFTER read_delay;

databus_on_dbus_oi <= GUARDED '1';

dbus_on_mar_offset_bus_oi <= GUARDED '1';

load_offset_mar_oi <= GUARDED '1'; -- completed operand (dir/indir) address

-- page from ir if not branch or jsr

pg: BLOCK ( (ir_lines (7 DOWNTO 6) /= "11") AND GUARD)

BEGIN

ir_on_mar_page_bus_oi <= GUARDED '1';

load_page_mar_oi <= GUARDED '1';

-- goto 5 for indirect, 6 for direct

ck: BLOCK ( (clk = '0' AND NOT clk'STABLE) AND GUARD )

BEGIN

s(5) <= GUARDED '1' WHEN ir_lines (4) = '1' ELSE '0'; -- indir

s(6) <= GUARDED '1' WHEN ir_lines (4) = '0' ELSE '0'; -- direct

END BLOCK ck;

END BLOCK pg;

-- keep page in mar_page if jms or bra (same-page instructions)

sp: BLOCK ( (ir_lines (7 DOWNTO 6) = "11") AND GUARD)

BEGIN

-- fot 7 for jsr, 9 for bra

ck: BLOCK ( (clk = '0' AND NOT clk'STABLE) AND GUARD )

BEGIN

s(7) <= GUARDED '1' WHEN ir_lines (5) = '0' ELSE '0'; -- jsr

s(9) <= GUARDED '1' WHEN ir_lines (5) = '1' ELSE '0'; -- bra

END BLOCK ck;

END BLOCK sp;

-- increment pc

increment_pc_oi <= GUARDED '1';

END BLOCK s4;

Get operand for page and full instructions
For full address : use page from ir, offset from mar
For page address: keep mar page unchanged

Controller.state_descriptions

Hardware for state 4
ir to mar occurs only when ir(7:6)=11

Controller.state_descriptions

s5: BLOCK (s(5) = '1')

BEGIN -- indirect addressing

-- read actual operand from memory into mar offset

mar_on_adbus_oi <= GUARDED '1';

read_mem_oi <= GUARDED '1' AFTER read_delay;

databus_on_dbus_oi <= GUARDED '1';

dbus_on_mar_offset_bus_oi <= GUARDED '1';

load_offset_mar_oi <= GUARDED '1';

-- goto 6

ck: BLOCK ( (clk = '0' AND NOT clk'STABLE) AND GUARD )

BEGIN

s(6) <= GUARDED '1';

END BLOCK ck;

END BLOCK s5;

Access memory with full address for indirect
Load byte from memory to mar offset

Controller.state_descriptions

s6: BLOCK (s(6) = '1')

BEGIN

jm : BLOCK ( (ir_lines (7 DOWNTO 5) = "100" ) AND GUARD

BEGIN

... perform jmp

END BLOCK jm;

st: BLOCK ( (ir_lines (7 DOWNTO 5) = "101") AND GUARD)

BEGIN

... perform sta

END BLOCK st;

rd: BLOCK ( (ir_lines (7) = '0') AND GUARD)

BEGIN

... perform lda, and, add, sub

END BLOCK rd;

END BLOCK s6;

Full address instructions are handled here
Three separate blocks for

1) jmp
2) sta
3) lda, and, add, sub

Controller.state_descriptions

s6: BLOCK (s(6) = '1') BEGIN
jm: BLOCK ( (ir_lines (7 DOWNTO 5) = "100") AND GUARD)
BEGIN
load_page_pc_oi <= GUARDED '1';
load_offset_pc_oi <= GUARDED '1';
-- goto 2
ck: BLOCK ( (clk = '0' AND NOT clk'STABLE) AND GUARD )
BEGIN
s(2) <= GUARDED '1';
END BLOCK ck;
END BLOCK jm;
. . .
. . .
Load pc with mar for jmp

Controller.state_descriptions

s6: BLOCK (s(6) = '1') BEGIN
. . .
st: BLOCK ( (ir_lines (7 DOWNTO 5) = "101") AND GUARD)
BEGIN
-- mar on adbus, ac on databus, write to memory
mar_on_adbus_oi <= GUARDED '1';
alu_code_oi <= GUARDED ored_qit_vector (b_input);
obus_on_dbus_oi <= GUARDED '1';
dbus_on_databus_oi <= GUARDED '1';
write_mem_oi <= GUARDED '1' AFTER write_delay;
-- goto 1
ck: BLOCK ( (clk = '0' AND NOT clk'STABLE) AND GUARD )
BEGIN
s(1) <= GUARDED '1';
END BLOCK ck;
END BLOCK st;
. . .
For sta, write ac to memory via alu
Assume writing is completed in one clock

Controller.state_descriptions

s6: BLO