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1 26 hellwig
 
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FPGA Implementations of ECO32
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=============================
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eco32-00
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--------
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This is essentially the same as the solution of assigment 9 of the
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course "Hardware for Embedded Systems", i.e., an implementation of
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ECO32e. The differences are:
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a) The reset circuit is moved to a subdirectory of its own. The
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   duration of the reset pulse is reduced to 2^24/50MHz = 0.3 sec,
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   a quarter of the original duration.
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b) The reset circuit is connected to the pushbutton on the carrier
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   board, which has been designated for reset by the manufacturer.
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c) The bus controller is moved to a subdirectory of its own.
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d) The top-level description is transformed from a schematic into
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   plain text. This in turn eliminates the need for top-level
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   symbols of the Reset/ROM/RAM/Busctrl/CPU/DSP/KBD circuits.
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21
 
22
eco32-01
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--------
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25
We have a new module, "ser", which represents the circuit for a
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serial interface (8 bit data, no parity, 1 stop bit, 38400 baud).
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The data is buffered twice in both directions. The module is
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instanciated once; the data in/out lines are connected to the
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RS232 interface on the carrier board. The bus controller got
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the necessary additional connections to drive the module.
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32
 
33
eco32-02
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--------
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The fake RAM module is replaced by a preliminary implementation of
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real RAM. It uses the block RAM of the FPGA (instead of the SDRAM
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mounted as an extra chip on the board that the final implementation
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will use). It is therefore very small in size: 4 blocks of 16K bits
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each yield a total size of 2 KWords (8K bytes).
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42
 
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eco32-03
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--------
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This revision corrects an error which should have been corrected
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a long time ago: the instructions ldb and ldh never sign-extended
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their loaded data. On top of that, the instructions ldbu and ldhu
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never placed zeroes into the bit positions 31 to 8 and 31 to 16,
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respectively. This went undetected so far, because the implementation
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of the bus did this already, although it is not explicitly requested.
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54
eco32-04
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--------
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57
This version got a shift unit. It is connected in parallel to the
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ALU, feeding its output into an expanded multiplexer. Because
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arithmetic right shifts are slow, shifting needs an extra cycle
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to complete. Even then it was necessary to request the place and
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route effort level "high" to get by with a clock period of 20 nsec.
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63
 
64
eco32-05
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--------
66
 
67
Again there was an error to correct: I tried to scroll the display
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by copying the display memory contents and discovered that reading
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the memory needs an additional bus cycle (because the memory is
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clocked). A simple state machine had to be written, which in turn
71
needed the reset signal. I changed the top-level description of
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the display from a schematic to plain text.
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74
 
75
eco32-06
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--------
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78
An easy job: I implemented the "jalr" instruction.
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80
 
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eco32-07
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--------
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84
This is the first step in getting the real memory to work:
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I integrated the clock/reset module from my SDRAM controller
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experiments. I also corrected the naming of the flash ROM
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signals; all active-low signals are now consistently named
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with a trailing "_n".
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90
 
91
eco32-08
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--------
93
 
94
We now have a working SDRAM controller!
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96
 
97
eco32-09
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--------
99
 
100
Second serial interface added.
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102
 
103
eco32-10
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--------
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106
Branches based on signed comparisons added.
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108
 
109
eco32-11
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--------
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112
Timer added.
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115
eco32-12
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--------
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118
Multiply, divide, and remainder instructions done.
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120
 
121
eco32-13
122
--------
123
 
124
A first attempt to introduce virtual addressing: a totally
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minimalistic MMU consisting of two AND gates which suppress
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the two MSBs of the virtual address if they are set. If
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they are not, too bad - the virtual address is then mapped
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to physical address 0.
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130
 
131
eco32-14
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--------
133
 
134
A couple of steps to make interrupts available:
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a) The CPU gets an input vector of 16 interrupt request lines which
137
   are all tied to 0 in the top-level design external to the CPU.
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139
b) The timer circuit's control register gets an interrupt enable bit,
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   which gates the 'timer expired' status bit onto an additional
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   output line, the timer's interrupt request line. This line is
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   connected to the CPU's irq line 14.
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144
c) Inside the CPU there must be a set of 4 special registers. They
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   are implemented in a separate module. Two instructions (mvfs and
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   mvts) transfer data between the standard and the special register
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   sets. The data input of the special register set is connected to
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   the standard register data output 2; the write enable signal for
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   the special register set is controlled by the CPU's state machine.
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   The data output of the special register set is connected to the
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   data input 2 multiplexer of the standard register set, which has
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   to be widened by one input (and by one control line also). The
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   register number which selects the special register from/to which
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   reading/writing should take place comes from the instruction
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   register's immediate constant. The two new instructions get one
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   extra state each in the CPU's state machine.
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158
d) For interrupts and exceptions to take place there must be four
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   additional values available which can be loaded into the PC:
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   0xE0000004   general interrupts (V-bit of the PSW off)
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   0xC0000004   general interrupts (V-bit of the PSW on)
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   0xE0000008   user TLB miss (V-bit of the PSW off)
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   0xC0000008   user TLB miss (V-bit of the PSW on)
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   The contents of the special register 0 (the PSW) are needed at
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   several places in the description of the CPU's state machine.
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   They have to be set also, independently of the mvts instruction.
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   Therefore an extra data path from/to the special register set
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   is established, together with a separate write signal for the
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   PSW. The state machine gets two new states, one to acknowledge
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   interrupts and another one to implement the rfx instruction.
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   Each instruction tests a specific 'interrupt trigger line'
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   before returning to state 1 (instruction fetch). If it is set,
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   the state machine branches to the 'interrupt' state. In this
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   way we don't need a separate state before the 'instruction
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   fetch' state to check for interrupts (and also avoid the
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   unpleasant alternative: to merge interrupt detection into
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   the fetch state - think of the already-incremented pc, for
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   example). The trigger signal is set if there is any interrupt
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   request present, its mask is open, and the global interrupt
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   enable (in the PSW) is set. The ECO32 architecture defines
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   5 bits in the PSW to be the priority of the last acknowledged
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   interrupt. Therefore a priority encoder takes the vector of
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   interrupt requests (possibly modified by closed mask bits)
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   and determines the highest unmasked interrupt from that. The
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   two additional states in the state machine also handle the
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   two stacks (each three positions deep) for the 'interrupt
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   enable' and 'user mode' flags within the PSW.
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189
e) Since its construction, the ALU had two unused function encodings;
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   they had been assigned to add and subtract, but were never used.
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   They now deliver either the first or the second operand of the ALU
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   to the output, unchanged. This simplifies three instructions (ldhi,
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   jr, rfx) as well as the interrupt state in the CPU's state machine.
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195
 
196
eco32-15
197
--------
198
 
199
We now have the 'trap' instruction. This is an important first
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example of an exception.
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202
 
203
eco32-16
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--------
205
 
206
This version accepts the four TLB instructions as valid instructions
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(but treats them as no-ops).
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209
 
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eco32-17
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--------
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A couple of steps to make exceptions work:
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a) There are only 16 interrupts, so irq_priority is only [3:0] wide.
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   The leading bit of the interrupt/exception priority in the PSW is
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   explicitly set to 0 in state 15 (interrupt).
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219
b) Generally, states returning to state 1 (instruction fetch) check
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   the signal irq_trigger for pending interrupts and branch to state
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   15 (interrupt) if it is set. This should NOT be done if the current
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   state could possibly set the PSW to disable interrupts. So states
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   15 (interrupt), 22 (mvts), 23 (rfx), and 24 (trap) don't do this
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   check any longer. On the other hand, delaying the acceptance of
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   a pending interrupt for a whole instruction would come as a hard
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   surprise for an unsuspecting system programmer. It would in fact
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   be possible to write an instruction sequence which never accepts
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   any interrupts, although interrupts are expected to be enabled for
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   one instruction:
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       mvts $5,PSW    ; disable interrupts
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   label:
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       mvts $4,PSW    ; enable interrupts
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       mvts $5,PSW    ; disable interrupts
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       j label
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   This cannot be tolerated. Therefore an additional state is inserted,
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   just to check irq_trigger, computed from the new value of the PSW.
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   This certainly makes no sense for interrupt and trap, because the new
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   value of the interrupt enable flag in the PSW is known to be 0. So
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   the new state is only reached from states 22 (mvts) and 23 (rfx).
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   First, I did some renumbering of states:
241
   Renamed state 25 to 26 (TLB instruction).
242
   Renamed state 24 to 25 (trap).
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   Then the additional state is called state 24.
244
 
245
c) Because the trap instruction is merely one of several possible causes
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   for an exception, its execution state (25, see step b) above) can be
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   used to implement exceptions. The exception number must be communicated
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   to this state. We therefore have a 4-bit register named 'exc_priority'
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   which must be set by any state transition to state 25. Its contents
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   are appended to a leading 1 and then represent the exception priority
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   which is found in the PSW.
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253
d) The following exceptions are implemented:
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     trap instruction exception
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     illegal instruction exception
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     divide instruction exception
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258
e) The 'bus timeout exception' is implemented with the help of a counter
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   which is activated if the bus is enabled and its wait line active.
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   When the counter expires, the exception execution state is entered.
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   There is a catch: if the bus timeout occurs during instruction fetch,
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   the PC has yet its old value, i.e., it must not get decremented while
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   handling the exception. This could be handled best by just another
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   state (renaming state 26 to 27, and using the new state 26 for
265
   exception handling without decrementing the PC).
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267
f) The 'privileged instruction exception' isn't difficult to implement
268
   but can only be tested if a TLB is present (because the test program
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   must enter user mode in order to trigger the exception - and in user
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   mode, instructions cannot be executed at addresses which have their
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   MSB set without triggering a 'privileged address exception').
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273
 
274
eco32-18
275
--------
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277
This intermediate version got a new bus controller which does no longer
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mirror RAM and ROM in their respective upper address spaces but signals
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a bus timeout instead.
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281
 
282
eco32-19
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--------
284
 
285
This version implements the MMU with a TLB (first of two parts).
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a) Add the TLB module. It consists of an "input section" (32 comparators
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   working in parallel, and a priority encoder which computes the binary
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   representation of the number of one of the matching comparators), and
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   an "output section" which merely delivers the previously stored frame
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   number and permission bits of the frame. The output section's memory
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   is addressed by the output of the priority encoder. The two sections
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   together implement a fully associative address translation cache.
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295
b) Change the MMU from a purely combinational circuit to one which needs
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   a single clock cycle to compute its output. This is necessary because
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   the RAM which stores frame numbers in the TLB output section also needs
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   one cycle to read its contents.
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300
c) In the controller of the CPU add one state before each bus cycle state
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   (i.e., three states: fetch, load, and store). These additional states
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   perform the address translation from a virtual to a physical address.
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   I added three new states (28..30) which now implement the bus cycles
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   and reassigned the old state numbers (1, 12, 14) to the states which
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   do address translations.
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d) The MMU must implement several functions:
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     no operation, hold output
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     map virtual to physical address
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     execute tbs
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     execute tbwr
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     execute tbri
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     execute tbwi
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   The controller instructs the MMU which function is to be executed.
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316
e) The tbwr instruction needs a "random" index. This can be generated
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   by a counter which counts down at every clock pulse, instruction
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   fetch, or address mapping request. There is a catch: if the counter
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   would count on every clock pulse and each instruction would need a
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   multiple of 2 clock pulses to complete, then only half the entries
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   of the TLB would be used. Thus counting instructions is safer, and
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   furthermore counting address mappings is cheaper than that (because
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   address mapping is already one of the functions of the MMU and
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   therefore easily detectable).
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f) The values of the special registers 1 (TLB Index), 2 (TLB EntryHi),
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   and 3 (TLB EntryLo) are needed within the MMU. The MMU also must
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   write new values to these registers under certain circumstances.
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   Three dedicated signals for each of these special registers (old
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   value, write enable, new value) enable the MMU to do so.
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g) In principle, the tbri instruction needs two clock cycles to do
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   its work: one cycle to read the TLB and another one to write the
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   data to special register 3. This can be reduced to a single clock
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   cycle (write to special register 3) if the RAM's contents are read
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   out by default within every clock cycle.
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338
 
339
eco32-20
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--------
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This version implements the MMU with a TLB (second of two parts).
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344
a) Detect privileged and illegal address exceptions within the state
345
   machine. In order to do so, virtual address bits 31, 1, and 0 must
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   be available there. The exceptions are detected in the address
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   translation states (1, 12, 14). Control is transferred to state
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   25 (or 26 in case of violation during instruction fetch) with
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   exc_priority set accordingly. Although not yet needed for the bus,
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   the bus size lines must be set to the intended transfer width
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   already in the translation states in order to detect illegal
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   addresses there (before the bus is actually accessed). Last but
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   not least the MMU must not try to map an address if that triggered
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   one of the two exceptions.
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356
b) The TLB supplies three control signals (tlb_missed, tlb_invalid,
357
   and tlb_wrtprot) which are needed to detect the three exceptions
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   "TLB miss", "TLB entry invalid", and "page frame write protected".
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   The first of these, tlb_missed, is generated in the "input section"
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   of the TLB and has to be delayed for one clock cycle so that it
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   appears at the TLB output at the same time the other two signals do.
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   The three signals are routed to the CPU's state machine. Because
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   they are valid only after the address translation took place (the
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   valid and write bits are stored together with the frame number),
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   the error conditions can only be detected in the bus cycle states.
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   The actual bus cycle however must suppress its bus enable signal,
367
   if any exception has been detected.
368
   Attention: the three control signals must be de-asserted if the
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   address in question is directly mapped (i.e., has its two MSBs set).
370
 
371
c) The tlb_missed signal has in fact to be splitted into two signals:
372
   tlb_kmissed (MSB of address is 1) and tlb_umissed (MSB is 0). This
373
   must be done in order to route "user TLB misses" to another start
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   address. Furthermore, the V bit in the PSW has to be considered and
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   the ISR start address modified accordingly.
376
 
377
d) The three write enable signals for the three special TLB registers
378
   are best produced within the main CPU state machine, because they
379
   are dependent on the opcode if one of the TLB instructions is
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   executed. They must also be asserted according to any exception
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   which das been detected.
382
 
383
 
384
eco32-21
385
--------
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387
I changed the display description from a schematic to plain Verilog.
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389
 
390
eco32-22
391
--------
392
 
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The display has got character attributes: one attribute byte per
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character stored in the display memory. The bits in the attribute
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byte are loosely imitating those from the good old CGA adapter in
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text mode.
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  Bit 7:  blinking foreground
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  Bit 6:  background red
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  Bit 5:  background green
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  Bit 4:  background blue
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  Bit 3:  intensified foreground
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  Bit 2:  foreground red
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  Bit 1:  foreground green
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  Bit 0:  foreground blue
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406
 
407
eco32-23
408
--------
409
 
410
Now the keyboard can interrupt the CPU.
411
 
412
 
413
eco32-24
414
--------
415
 
416
Project re-organized. All source files are now located under a single
417
directory "src". Now it is easier to clean up a project after editing
418
or testing: simply remove all files and directories except "src" and
419
the project manager's control file "eco32.npl".
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421
 
422
eco32-25
423
--------
424
 
425
The reset circuit had the following problem: although an externally
426
applied reset signal (produced by pressing the "reset" pushbutton)
427
was internally recognized for initializing the CPU, it did not work
428
the other way around, which is important when re-loading the FPGA.
429
In this case, the CPU was reset, but the external devices, especially
430
the disk drive, did not get a reset signal. So the drive could get
431
out of sync with its controller. The reset circuit now actively drives
432
the external bidirectional reset line when performing a reset, as well
433
as observing this line when not actively driving it.
434
 
435
 
436
eco32-26
437
--------
438
 
439
This is the first version with a real IDE disk attached! Thanks to
440
Martin Geisse, who did a very nice job.
441
 
442
 
443
eco32-27
444
--------
445
 
446
The two serial interfaces are now able to generate interrupt requests.
447
As far as I can see, the implementation is now functionally complete.
448
 
449
 
450
eco32-28
451
--------
452
 
453
The IDE disk interface had a small problem with reading/writing a block
454
of 8 sectors in a single operation. Fixed.
455
 
456
 
457
eco32-29
458
--------
459
 
460
Same as eco32-28, but with an ISE Version 11 project file. Because
461
it is now possible to develop exclusively under Linux (including
462
download to the FPGA board), all source files were converted to
463
newline-only line endings.
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