4cade/src/okvs.a
2019-09-23 17:09:07 -07:00

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;license:MIT
;(c) 2018-9 by 4am
;
; Ordered key/value store (6502 compatible)
;
; Public functions
; - okvs_init(address) reset (required)
; - okvs_len(address) get number of keys
; - okvs_append(address, key, value, max_len) add new key/value pair
; - okvs_update(address, key, value) update key/value pair
; - okvs_get(address, key) get value by key lookup
; - okvs_nth(address, n) get key by numeric index
; - okvs_next(address, n) get next key by numeric index
; - okvs_iter(address, callback) iterate through keys
; - okvs_iter_values(address, callback) iterate through values
;
; Call init() once. Call it again to reset the store to 0 keys.
;
; Keys are maintained in a singly linked list, so most functions are O(n).
; len() and append() are O(1) though.
;
; Key count is stored as a byte, so a store can hold a maximum of 255 keys.
;
; Keys and values are length-prefixed strings (Pascal style), so max length
; of any single key or value is 255 bytes.
;
; Keys are case-sensitive. Lookups are an exact byte-for-byte comparison.
;
; append() has a max_len argument to reserve more space for the value, in case
; you want to update it later. max_len is the total space to reserve, not the
; additional space. One exception: max_len can be 0, and it will be treated as
; length(value) at append time. update() always modifies the value in place.
; There is no range checking because this is assembly.
; All functions take the starting address of the store's data buffer in
; memory, so there can be multiple independent stores at one time. append()
; will happily extend the store's data buffer without limit. There is no
; overflow protection because this is assembly.
;
; There is no sort() function.
;
; There is no delete() function.
;
; Keys can be duplicated, but get() will always return the one that was
; append()ed first.
;
; Structures:
;
; Store
; +0 length (byte)
; +1 free space pointer after last record (word)
; +3 Record
; ...Record...
; ...Record...
;
; Record
; +0 next-record pointer (word)
; +2 key length
; +3 key
; +K+2 value length (actual length, not max length)
; +K+3 value
; ... filler bytes up to value max length (set at append() time)
;------------------------------------------------------------------------------
; okvs_init
;
; in: A/Y = handle to storage space
; out: $00/$01 clobbered
; $02/$03 clobbered
; all registers clobbered
;------------------------------------------------------------------------------
okvs_init
jsr GetStoreAddressFromAY
; PTR -> store
; Y = 0
tya
sta (PTR),y ; set number of keys in store to 0
iny ; set next-free-space pointer to store + 3
ldx PTR+1
lda PTR
clc
adc #$03
bcc +
inx
+ sta (PTR),y
iny
txa
sta (PTR),y
rts
;------------------------------------------------------------------------------
; okvs_len
;
; in: A/Y = handle to storage space
; out: A contains number of keys in this store
; X preserved
; Y clobbered
; $00/$01 clobbered
; $02/$03 clobbered
;------------------------------------------------------------------------------
okvs_len
jsr GetStoreAddressFromAY
; PTR -> store
; Y = 0
lda (PTR),y ; A = number of keys in store
rts
;------------------------------------------------------------------------------
; okvs_append
;
; in: stack contains 7 bytes of parameters:
; +1 [word] handle to storage space
; +3 [word] address of key
; +5 [word] address of value
; +7 [byte] maximum length of value (or 0 to fit)
; out: X = new number of records (same as calling okvs_len after okvs_append)
; A/Y clobbered
; $00/$01 clobbered
; $02/$03 clobbered
; $04/$05 has the address of the next available byte after the new record
; $08/$09 clobbered
;------------------------------------------------------------------------------
okvs_append
+PARAMS_ON_STACK 7
jsr GetStoreAddress
; PTR -> store
; Y = 0
lda (PTR),y ; A = number of keys in store
clc
adc #1
pha ; will return this later
sta (PTR),y ; increment number of keys
iny
lda (PTR),y ; get address of next free space
tax
iny
lda (PTR),y
sta PTR+1
sta SAVE+1
stx PTR
stx SAVE
; PTR -> new record
; SAVE -> new record
jsr incptr2
; PTR -> space for new key
+LDPARAM 3
+STAY SRC ; SRC -> new key to copy
ldy #0
lda (SRC),y
tay
iny
sty KEYLEN
- dey ; copy new key
lda (SRC),y
sta (PTR),y
cpy #$FF
bne -
lda PTR ; update PTR to byte after copied key
clc
adc KEYLEN
sta PTR
bcc +
inc PTR+1
+ ; PTR -> space for new value
+LDPARAM 5
+STAY SRC ; SRC -> new value to copy
ldy #7
lda (PARAM),y ; get max length of value
tay
bne +
lda (SRC),y ; no max, use actual length instead
tay
iny
+ sty VALUELEN
- dey
lda (SRC),y
sta (PTR),y
cpy #$FF
bne -
lda PTR
clc
adc VALUELEN
sta SRC
bcc +
inc PTR+1
+ lda PTR+1
sta SRC+1 ; SRC -> byte after this record
+LDAY SAVE
+STAY PTR ; PTR -> this record again
ldy #0
lda SRC ; update next-record pointer
sta (PTR),y
iny
lda SRC+1
sta (PTR),y
pla
tax ; X = new OKVS length
jsr GetStoreAddress
; PTR -> store
ldy #2
- lda SRC-1,y
sta (PTR),y ; update next-free-space pointer in head
dey
bne -
rts
;------------------------------------------------------------------------------
; okvs_get
;
; in: stack contains 4 bytes of parameters:
; +1 [word] handle to storage space
; +3 [word] address of key
; out: if C clear, key was found
; A/Y = lo/hi address of value
; X = numeric index of key
; if C set, key was not found and all registers are clobbered
; all other flags clobbered
; $00/$01 clobbered
; $02/$03 clobbered
; $04/$05 clobbered
;------------------------------------------------------------------------------
okvs_get
+PARAMS_ON_STACK 4
jsr GetStoreAddress
; PTR -> store
; Y = 0
lda (PTR),y ; A = number of keys in store
beq @fail ; no keys, fail immediately
sta MAX
jsr incptr3
; PTR -> first record
ldx #0
+LDPARAM 3
+STAY SRC ; SRC -> key we want to find
ldy #0
lda (SRC),y
tay
iny
sty KEYLEN
@matchRecordLoop
lda PTR+1
sta DEST+1
lda PTR
clc
adc #2
sta DEST
bcc +
inc DEST+1 ; DEST -> key of this record
+ ldy #0
@matchKeyLoop
lda (SRC),y
cmp (DEST),y
bne @next
iny
cpy KEYLEN
bne @matchKeyLoop
+LDAY PTR
clc
adc KEYLEN
bcc +
iny
+ clc
adc #2
sta PTR
bcc +
iny
clc
+ rts
@next jsr derefptr ; PTR -> next record
inx
cpx MAX
bne @matchRecordLoop
@fail sec
rts
okvs_get_current
+STAY PTR
ldy #0
lda (PTR),y
clc
adc PTR
sta PTR
bcc +
inc PTR+1
+ jmp incptr
;------------------------------------------------------------------------------
; okvs_next
; get (N+1)th key, with wraparound
;
; in: A/Y = handle to storage space
; X = record index
; out: A/Y = lo/hi address of (X+1)th key, or first key if X was the last record
; X = next record index
; SAVE clobbered
; see okvs_nth for other exit conditions
;------------------------------------------------------------------------------
okvs_next
+STAY PARAM
inx
stx SAVE
jsr okvs_len
eor SAVE
bne +
tax
+
+LDAY PARAM
; execution falls through here
;------------------------------------------------------------------------------
; okvs_nth
; get (N)th key
;
; in: A/Y = handle to storage space
; X = record index
; out: A/Y = lo/hi address of nth key
; X preserved
; Z = 0
; all other flags clobbered
; PTR clobbered
;------------------------------------------------------------------------------
okvs_nth
jsr GetStoreAddressFromAY
; PTR -> store
jsr incptr3
; PTR -> first record
txa
beq @found
pha
- jsr derefptr
dex
bne -
pla
tax
@found jsr incptr2
+LDAY PTR
rts
;------------------------------------------------------------------------------
; okvs_update
;
; in: stack contains 6 bytes of parameters:
; +1 [word] handle to storage space
; +3 [word] address of key
; +5 [word] address of new value
; out: if C clear, key was found and value was updated
; if C set, key was not found
; all registers are clobbered
; all other flags clobbered
; $00/$01 clobbered
; $02/$03 clobbered
; $04/$05 clobbered
;------------------------------------------------------------------------------
okvs_update
+PARAMS_ON_STACK 6
ldy #6
lda (PARAM),y
sta SAVE+1
dey
lda (PARAM),y
sta SAVE
dey
- lda (PARAM),y
sta @getparams,y
dey
bne -
jsr okvs_get
@getparams=*-1
!word $FDFD ; SMC
!word $FDFD ; SMC
bcs @exit
+STAY DEST
ldy #0
lda (SAVE),y
tay
- lda (SAVE),y
sta (DEST),y
dey
cpy #$FF
bne -
clc
@exit rts
;------------------------------------------------------------------------------
; okvs_iter / okvs_iter_values
;
; in: stack contains 4 bytes of parameters:
; +1 [word] handle to storage space
; +3 [word] address of callback
; out: <callback> will be called for each record in the store, in order, with
; X = numeric index of record
; A/Y = address of key or value (depends on which entry point you call)
; all registers are clobbered
; all flags clobbered
; PARAM clobbered
; PTR clobbered
;------------------------------------------------------------------------------
okvs_iter
lda #$D0 ; 'BNE' opcode
+HIDE_NEXT_2_BYTES
okvs_iter_values
lda #$24 ; 'BIT' opcode
sta @branch
+PARAMS_ON_STACK 4
jsr GetStoreAddress
; PTR -> store
; Y = 0
lda (PTR),y ; A = number of keys in store
beq @exit ; no keys, exit immediately
sta @max
+LDPARAM 3
+STAY @callback
jsr incptr3
; PTR -> first record
ldx #0
@loop
lda #2 ; for iter, skip length = 2
@branch bne + ; SMC (iter_values puts a BIT here, so no branch)
; for iter_values, skip length = length(key) + 2 + 1
ldy #2
lda (PTR),y ; A = length of key
clc
adc #3 ; skip over pointer to next record (2 bytes) + key length (1 byte)
+ sta @skiplen
txa
pha ; save X on stack
lda PTR+1
tay
pha
lda PTR
pha ; save PTR on stack (in case callback clobbers it)
clc
@skiplen=*+1
adc #$FD ; SMC skip over pointer (and possibly key)
bcc +
iny ; A/Y -> value
+
@callback=*+1
jsr $FDFD ; SMC
pla
sta PTR
pla
sta PTR+1 ; restore PTR from stack
pla
tax ; restore X from stack
jsr derefptr ; PTR -> next record
inx
@max=*+1
cpx #$FD ; SMC
bne @loop
@exit rts
;------------------------------------------------------------------------------
; internal functions
incptr3 jsr incptr
incptr2 jsr incptr
incptr
; preserves A, X, and Y
inc PTR
bne +
inc PTR+1
+ rts
GetStoreAddressFromAY
+STAY PTR
jmp derefptr
GetStoreAddress
; in: PARAM = address of stack params (any PARAMS_ON_STACK macro will do this)
; out: PTR = address of store (always the first parameter on stack)
; preserves X
ldy #1
lda (PARAM),y
sta PTR
iny
lda (PARAM),y
sta PTR+1 ; PTR -> first parameter on stack
; execution falls through here
derefptr
; out: Y = 0
; preserves X
ldy #1
lda (PTR),y
pha
dey
lda (PTR),y
sta PTR
pla
sta PTR+1
rts