recipes/rc2014/sdcard: use driver from blkfs

This completes the migration of all Collapse OS code into blkfs!

drv/sdc.fs

@@ -1,215 +0,0 @@
-( -- n )
-: _idle 0xff _sdcSR ;
-
-( -- n )
-( _sdcSR 0xff until the response is something else than 0xff
-  for a maximum of 20 times. Returns 0xff if no response. )
-: _wait
-    0  ( cnt )
-    BEGIN
-        _idle
-        DUP 0xff = IF DROP ELSE SWAP DROP EXIT THEN
-        1+
-    DUP 20 = UNTIL
-    DROP 0xff
-;
-
-( -- )
-( The opposite of sdcWaitResp: we wait until response is 0xff.
-  After a successful read or write operation, the card will be
-  busy for a while. We need to give it time before interacting
-  with it again. Technically, we could continue processing on
-  our side while the card it busy, and maybe we will one day,
-  but at the moment, I'm having random write errors if I don't
-  do this right after a write, so I prefer to stay cautious
-  for now. )
-: _ready BEGIN _idle 0xff = UNTIL ;
-
-( c n -- c )
-( Computes n into crc c with polynomial 0x09
-  Note that the result is "left aligned", that is, that 8th
-  bit to the "right" is insignificant (will be stop bit). )
-: _crc7
-    XOR           ( c )
-    8 0 DO
-        2 *       ( <<1 )
-        DUP 255 > IF
-            ( MSB was set, apply polynomial )
-            0xff AND
-            0x12 XOR  ( 0x09 << 1, we apply CRC on high bits )
-        THEN
-    LOOP
-;
-
-( c n -- c )
-( Computes n into crc c with polynomial 0x1021 )
-: _crc16
-    SWAP DUP 256 /    ( n c c>>8 )
-    ROT XOR           ( c x )
-    DUP 16 / XOR      ( c x^x>>4 )
-    SWAP 256 *        ( x c<<8 )
-    OVER 4096 * XOR   ( x c^x<<12 )
-    OVER 32 * XOR     ( x c^x<<5 )
-    XOR               ( c )
-;
-
-( send-and-crc7 )
-( n c -- c )
-: _s+crc SWAP DUP _sdcSR DROP _crc7 ;
-
-( cmd arg1 arg2 -- resp )
-( Sends a command to the SD card, along with arguments and
-  specified CRC fields. (CRC is only needed in initial commands
-  though).
-  This does *not* handle CS. You have to select/deselect the
-  card outside this routine. )
-: _cmd
-    _wait DROP
-    ROT            ( a1 a2 cmd )
-    0 _s+crc       ( a1 a2 crc )
-    ROT 256 /MOD   ( a2 crc h l )
-    ROT            ( a2 h l crc )
-    _s+crc         ( a2 h crc )
-    _s+crc         ( a2 crc )
-    SWAP 256 /MOD  ( crc h l )
-    ROT            ( h l crc )
-    _s+crc         ( h crc )
-    _s+crc         ( crc )
-    ( send CRC )
-    0x01 OR        ( ensure stop bit )
-    _sdcSR DROP
-    ( And now we just have to wait for a valid response... )
-    _wait
-;
-
-( cmd arg1 arg2 -- r )
-( Send a command that expects a R1 response, handling CS. )
-: SDCMDR1 _sdcSel _cmd _sdcDesel ;
-
-( cmd arg1 arg2 -- r arg1 arg2 )
-( Send a command that expects a R7 response, handling CS. A R7
-  is a R1 followed by 4 bytes. arg1 contains bytes 0:1, arg2
-  has 2:3 )
-: SDCMDR7
-    _sdcSel
-    _cmd        ( r )
-    _idle 256 * ( r h )
-    _idle +     ( r arg1 )
-    _idle 256 * ( r arg1 h )
-    _idle +     ( r arg1 arg2 )
-    _sdcDesel
-;
-
-: _err _sdcDesel ABORT" SDerr" ;
-
-( Initialize a SD card. This should be called at least 1ms
-  after the powering up of the card. )
-: SDC$
-    ( Wake the SD card up. After power up, a SD card has to
-      receive at least 74 dummy clocks with CS and DI high. We
-      send 80. )
-    10 0 DO _idle DROP LOOP
-
-    ( call cmd0 and expect a 0x01 response (card idle)
-	  this should be called multiple times. we're actually
-      expected to. let's call this for a maximum of 10 times. )
-    0  ( dummy )
-    10 0 DO  ( r )
-        DROP
-        0b01000000 0 0  ( CMD0 )
-        SDCMDR1
-        DUP 0x01 = IF LEAVE THEN
-    LOOP
-    0x01 = NOT IF _err THEN
-
-    ( Then comes the CMD8. We send it with a 0x01aa argument
-      and expect a 0x01aa argument back, along with a 0x01 R1
-      response. )
-    0b01001000 0 0x1aa  ( CMD8 )
-    SDCMDR7                     ( r arg1 arg2 )
-    0x1aa = NOT IF _err THEN    ( arg2 check )
-    0 = NOT IF _err THEN        ( arg1 check )
-    0x01 = NOT IF _err THEN     ( r check )
-
-    ( Now we need to repeatedly run CMD55+CMD41 (0x40000000)
-      until the card goes out of idle mode, that is, when
-      it stops sending us 0x01 response and send us 0x00
-      instead. Any other response means that initialization
-      failed. )
-    BEGIN
-        0b01110111 0 0  ( CMD55 )
-        SDCMDR1
-        0x01 = NOT IF _err THEN
-        0b01101001 0x4000 0x0000  ( CMD41 )
-        SDCMDR1
-        DUP 0x01 > IF _err THEN
-    NOT UNTIL
-    ( Out of idle mode! Success! )
-;
-
-( dstaddr blkno -- )
-: _sdc@
-    _sdcSel
-    0x51    ( CMD17 )
-    0 ROT   ( a cmd 0 blkno )
-    _cmd
-    IF _err THEN
-    _wait
-    0xfe = NOT IF _err THEN
-    0 SWAP           ( crc a )
-    512 0 DO         ( crc a )
-        DUP          ( crc a a )
-        _idle        ( crc a a n )
-        DUP ROT      ( crc a n n a )
-        C!           ( crc a n )
-        ROT SWAP     ( a crc n )
-        _crc16       ( a crc )
-        SWAP 1+      ( crc a+1 )
-    LOOP
-    DROP             ( crc1 )
-    _idle 256 *
-    _idle +          ( crc2 )
-    _wait DROP
-    _sdcDesel
-    = NOT IF _err THEN
-;
-
-: SDC@
-    2 * DUP BLK( SWAP    ( b a b )
-    _sdc@
-    1+ BLK( 512 + SWAP
-    _sdc@
-;
-
-( srcaddr blkno -- )
-: _sdc!
-    _sdcSel
-    0x58    ( CMD24 )
-    0 ROT   ( a cmd 0 blkno )
-    _cmd
-    IF _err THEN
-    _idle DROP
-    0xfe _sdcSR DROP
-    0 SWAP           ( crc a )
-    512 0 DO         ( crc a )
-        C@+          ( crc a+1 n )
-        ROT OVER     ( a n crc n )
-        _crc16       ( a n crc )
-        SWAP         ( a crc n )
-        _sdcSR DROP  ( a crc )
-        SWAP         ( crc a )
-    LOOP
-    DROP             ( crc )
-    256 /MOD         ( lsb msb )
-    _sdcSR DROP      ( lsb )
-    _sdcSR DROP
-    _wait DROP
-    _sdcDesel
-;
-
-: SDC!
-    2 * DUP BLK( SWAP    ( b a b )
-    _sdc!
-    1+ BLK( 512 + SWAP
-    _sdc!
-;

recipes/rc2014/sdcard/README.md

@@ -19,7 +19,7 @@ design.
 ## Gathering parts
 
 * A RC2014 Classic
-* `stage3.bin` from the base recipe
+* `stage2.bin` from the base recipe
 * A MicroSD breakout board. I use Adafruit's.
 * A proto board + header pins with 39 positions so we can make a RC2014 card.
 * Diodes, resistors and stuff
@@ -69,20 +69,20 @@ matter. However, it *does* matter for the `SELECT` line, so I don't follow my
 own schematic with regards to the `M1` and `A2` lines and use two inverters
 instead.
 
-## Building your stage 4
+## Building your stage 3
 
-Using the same technique as you used for building your stage 3, you can append
-required words to your boot binary. Required units are `forth/blk.fs` and
-`drv/sdc.fs`. You also need `drv/sdc.z80` but to save you the troubles of
-rebuilding from stage 1 for this recipe, we took the liberty of already having
-included it in the base recipe.
+Using the same technique as you used in the `eeprom` recipe, you can append
+required words to your boot binary. Required units `blk` (B464) and the SD Card
+driver (B370). You only need the Forth part. You of course actually need
+Z80 SDC words but to save you the troubles of rebuilding from stage 1 for this
+recipe, we took the liberty of already having included it in the base recipe.
 
 ## Testing in the emulator
 
 The RC2014 emulator includes SDC emulation. You can attach a SD card image to
 it by invoking it with a second argument:
 
-    ../../../emul/hw/rc2014/classic stage4.bin ../../../emul/blkfs
+    ../../../emul/hw/rc2014/classic stage3.bin ../../../emul/blkfs
 
 You will then run with a SD card having the contents from `/blk`.