5th Generation Standard PID Creation
Wild pokemon and stationary legendaries without a shiny check have their PIDs created in the same way. It involves using the TID and SID to evaluate the seed being used for the PID and whether or not it should be OR-ed with 0x80000000 on creation.
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standard 0x8 decision pid generation(btw, r6 is sidtid for basically this entire thing)
020056FC F096ECB6 blx #0209C06C //switch to ARM, to 0209C06C
(rng.64bit.multiply())
-return to 02005700
02005700 6922 ldr r2,[r4,#0x10] // load value at 2216254 into r2(00269EC3)
02005702 6963 ldr r3,[r4,#0x14] // load 02216258 into r3(aka, zero-out r3)
02005704 1810 add r0,r2,r0 // add together r0 and r2, finish l32 advancement
02005706 414B adc r3,r1 // new upper seed
02005708 6020 str r0,[r4] // store the lower half-rng back to the state offset
0200570A 6063 str r3,[r4,#0x4] // store the upper half-rng back to the state offset
0200570C 2D00 cmp r5, #0x0 // this is 0 for pid creation only
0200570E D101 bne #0x2005714 // false, no branch
02005714 6860 ldr r0,[r4,#0x4] // load the value of the upper half of the rng state into r0
02005716 2100 mov r1, #0x0 // set r1 to 00000000
02005718 2300 mov r3, #0x0 // set r3 to 00000000
0200571A 1C2A mov r2, r5 // move contents r5(0x0) to r2
0200571C F096ECA6 blx #0209C06C // no branch
02005720 1C08 mov r0,r1 //save that u32
02005722 BD38 pop {r3-r5,r15} //jump to 20186F8
020186F8 1C04 mov r4,r0 //save the seed to compare
020186FA E024 b #0x2018746
02018746 9807 ldr r0,[sp,#0x1C] // value @ 2FE3604(0x2)
02018748 2800 cmp r0,#0x0
0201874A D019 beq #0x2018780 (pkm global struct?)
0201874C 2801 cmp r0,#0x1
0201874E D002 beq #0x2018756
02018750 2802 cmp r0,#0x2
02018752 D01E beq #0x2018792 ;true
02018792 2001 mov r0,#0x1
02018794 9906 ldr r1,[sp,#0x18]
02018796 0400 lsl r0,r0,#0x10 //prepping for base 0x00010000 xor
02018798 1C22 mov r2,r4
0201879A 4002 and r2,r0 //not understanding why it ANDs u32 by 10000, but r2 now == 0
0201879C 0409 lsl r1,r1,#0x10
0201879E 428A cmp r2,r1 // same as with the legendaries, 10000 vs. 20000, not equal
020187A0 D000 beq #0x20187A4 // false, no advancement
020187A2 4044 eor r4,r0 // base xor by 00010000
020187A4 1C20 mov r0,r4 // store this half-ready pid to r0 and save it...
020187A6 BDF8 pop {r3-r7,r15}
021A9DB2 79A1 ldrb r1,[r4,#0x6] //2FE36C4
021A9DB4 2902 cmp r1,#0x2 // r1 == 0
021A9DB6 D012 beq #0x21A9DDE // false, no branch
021A9DB8 6A2C ldr r4,[r5,#0x20] //load sidtid to r4
021A9DBA 0401 lsl r1,r0,#0x10 //set the lower half of the temp pid to r1(u16 of r1, need to fix)
021A9DBC 0C0B lsr r3,r1,#0x10 // move the lower half temp-pid to the lower half of r3 to prep
021A9DBE 0421 lsl r1,r4,#0x10 // separate tid and sid; this is tid
021A9DC0 0C22 lsr r2,r4,#0x10 // sid is ready
021A9DC2 0C09 lsr r1,r1,#0x10 // tid is ready
021A9DC4 4051 eor r1,r2 // tid ^ sid
021A9DC6 1C1A mov r2,r3 // move lower 16 of pid to r2, get ready for next step
021A9DC8 404A eor r2,r1 l16 pid ^ (tid ^ sid)
021A9DCA 2101 mov r1,#0x1 // r1 == 1
021A9DCC 4211 tst r1,r2 // (tid ^ sid ^ l16 pid) & 1 (== 0 in my case)
021A9DCE D004 beq #0x21A9DDA // resolve to 0, skip this
021A9DD0 2102 mov r1,#0x2 // set up 0x8 xor
021A9DD2 0789 lsl r1,r1,#0x1E // r1 == 80000000
021A9DD4 B002 add sp,#0x8
021A9DD6 4308 orr r0,r1 // this is an OR, not XOR
021A9DD8 BD70 pop {r4-r6,r15} //return
021A9DDA 4902 ldr r1,=#0x7FFFFFFF // set up to finish the pid
021A9DDC 4008 and r0,r1 // this kind of doesn't need to happen
021A9DDE B002 add sp,#0x8
021A9DE0 BD70 pop {r4-r6,r15} // return