#include "drmP.h" #include "drm.h" #include "nouveau_drv.h" #include "nouveau_drm.h" /* * NV20 * ----- * There are 3 families : * NV20 is 0x10de:0x020* * NV25/28 is 0x10de:0x025* / 0x10de:0x028* * NV2A is 0x10de:0x02A0 * * NV30 * ----- * There are 3 families : * NV30/31 is 0x10de:0x030* / 0x10de:0x031* * NV34 is 0x10de:0x032* * NV35/36 is 0x10de:0x033* / 0x10de:0x034* * * Not seen in the wild, no dumps (probably NV35) : * NV37 is 0x10de:0x00fc, 0x10de:0x00fd * NV38 is 0x10de:0x0333, 0x10de:0x00fe * */ #define NV20_GRCTX_SIZE (3580*4) #define NV25_GRCTX_SIZE (3529*4) #define NV2A_GRCTX_SIZE (3500*4) #define NV30_31_GRCTX_SIZE (24392) #define NV34_GRCTX_SIZE (18140) #define NV35_36_GRCTX_SIZE (22396) static void nv20_graph_context_init(struct drm_device *dev, struct nouveau_gpuobj *ctx) { struct drm_nouveau_private *dev_priv = dev->dev_private; int i; /* write32 #1 block at +0x00740adc NV_PRAMIN+0x40adc of 3369 (0xd29) elements: +0x00740adc: ffff0000 00000000 00000000 00000000 00000000 00000000 00000000 00000000 +0x00740afc: 00000000 00000000 00000000 00000000 00000000 00000000 00000000 00000000 +0x00740b1c: 00000000 00000000 00000000 00000000 00000000 00000000 00000000 00000000 +0x00740b3c: 00000000 0fff0000 0fff0000 00000000 00000000 00000000 00000000 00000000 +0x00740b5c: 00000000 00000000 00000000 00000000 00000000 00000000 00000000 00000000 +0x00740b7c: 00000000 00000000 00000000 00000000 00000000 00000000 00000000 00000000 +0x00740b9c: 00000000 00000000 00000000 00000000 00000000 00000000 00000000 00000000 +0x00740bbc: 00000000 00000000 00000000 00000000 00000000 00000000 00000000 00000000 +0x00740bdc: 00000000 00000000 00000000 00000000 00000000 00000000 00000000 00000000 +0x00740bfc: 00000000 00000000 00000000 00000000 00000000 00000000 00000000 00000000 +0x00740c1c: 00000101 00000000 00000000 00000000 00000000 00000111 00000000 00000000 +0x00740c3c: 00000000 00000000 00000000 44400000 00000000 00000000 00000000 00000000 +0x00740c5c: 00000000 00000000 00000000 00000000 00000000 00000000 00030303 00030303 +0x00740c7c: 00030303 00030303 00000000 00000000 00000000 00000000 00080000 00080000 +0x00740c9c: 00080000 00080000 00000000 00000000 01012000 01012000 01012000 01012000 +0x00740cbc: 000105b8 000105b8 000105b8 000105b8 00080008 00080008 00080008 00080008 +0x00740cdc: 00000000 00000000 00000000 00000000 00000000 00000000 00000000 00000000 +0x00740cfc: 07ff0000 07ff0000 07ff0000 07ff0000 07ff0000 07ff0000 07ff0000 07ff0000 +0x00740d1c: 07ff0000 07ff0000 07ff0000 07ff0000 07ff0000 07ff0000 07ff0000 07ff0000 +0x00740d3c: 00000000 00000000 4b7fffff 00000000 00000000 00000000 00000000 00000000 +0x00740d5c: 00000000 00000000 00000000 00000000 00000000 00000000 00000000 00000000 +0x00740d7c: 00000000 00000000 00000000 00000000 00000000 00000000 00000000 00000000 +0x00740d9c: 00000001 00000000 00004000 00000000 00000000 00000001 00000000 00040000 +0x00740dbc: 00010000 00000000 00000000 00000000 00000000 00000000 00000000 00000000 +0x00740ddc: 00000000 00000000 00000000 00000000 00000000 00000000 00000000 00000000 ... */ INSTANCE_WR(ctx, (0x33c/4)+0, 0xffff0000); INSTANCE_WR(ctx, (0x33c/4)+25, 0x0fff0000); INSTANCE_WR(ctx, (0x33c/4)+26, 0x0fff0000); INSTANCE_WR(ctx, (0x33c/4)+80, 0x00000101); INSTANCE_WR(ctx, (0x33c/4)+85, 0x00000111); INSTANCE_WR(ctx, (0x33c/4)+91, 0x44400000); for (i = 0; i < 4; ++i) INSTANCE_WR(ctx, (0x33c/4)+102+i, 0x00030303); for (i = 0; i < 4; ++i) INSTANCE_WR(ctx, (0x33c/4)+110+i, 0x00080000); for (i = 0; i < 4; ++i) INSTANCE_WR(ctx, (0x33c/4)+116+i, 0x01012000); for (i = 0; i < 4; ++i) INSTANCE_WR(ctx, (0x33c/4)+120+i, 0x000105b8); for (i = 0; i < 4; ++i) INSTANCE_WR(ctx, (0x33c/4)+124+i, 0x00080008); for (i = 0; i < 16; ++i) INSTANCE_WR(ctx, (0x33c/4)+136+i, 0x07ff0000); INSTANCE_WR(ctx, (0x33c/4)+154, 0x4b7fffff); INSTANCE_WR(ctx, (0x33c/4)+176, 0x00000001); INSTANCE_WR(ctx, (0x33c/4)+178, 0x00004000); INSTANCE_WR(ctx, (0x33c/4)+181, 0x00000001); INSTANCE_WR(ctx, (0x33c/4)+183, 0x00040000); INSTANCE_WR(ctx, (0x33c/4)+184, 0x00010000); /* ... +0x0074239c: 00000000 00000000 00000000 00000000 00000000 00000000 00000000 00000000 +0x007423bc: 10700ff9 0436086c 000c001b 00000000 10700ff9 0436086c 000c001b 00000000 +0x007423dc: 10700ff9 0436086c 000c001b 00000000 10700ff9 0436086c 000c001b 00000000 +0x007423fc: 10700ff9 0436086c 000c001b 00000000 10700ff9 0436086c 000c001b 00000000 ... +0x00742bdc: 10700ff9 0436086c 000c001b 00000000 10700ff9 0436086c 000c001b 00000000 +0x00742bfc: 10700ff9 0436086c 000c001b 00000000 10700ff9 0436086c 000c001b 00000000 +0x00742c1c: 10700ff9 0436086c 000c001b 00000000 10700ff9 0436086c 000c001b 00000000 +0x00742c3c: 00000000 00000000 00000000 00000000 00000000 00000000 00000000 00000000 ... */ for (i = 0; i < 0x880; i += 0x10) { INSTANCE_WR(ctx, ((0x1c1c + i)/4)+0, 0x10700ff9); INSTANCE_WR(ctx, ((0x1c1c + i)/4)+1, 0x0436086c); INSTANCE_WR(ctx, ((0x1c1c + i)/4)+2, 0x000c001b); } /* write32 #1 block at +0x00742fbc NV_PRAMIN+0x42fbc of 4 (0x4) elements: +0x00742fbc: 3f800000 00000000 00000000 00000000 */ INSTANCE_WR(ctx, (0x281c/4), 0x3f800000); /* write32 #1 block at +0x00742ffc NV_PRAMIN+0x42ffc of 12 (0xc) elements: +0x00742ffc: 40000000 3f800000 3f000000 00000000 40000000 3f800000 00000000 bf800000 +0x0074301c: 00000000 bf800000 00000000 00000000 */ INSTANCE_WR(ctx, (0x285c/4)+0, 0x40000000); INSTANCE_WR(ctx, (0x285c/4)+1, 0x3f800000); INSTANCE_WR(ctx, (0x285c/4)+2, 0x3f000000); INSTANCE_WR(ctx, (0x285c/4)+4, 0x40000000); INSTANCE_WR(ctx, (0x285c/4)+5, 0x3f800000); INSTANCE_WR(ctx, (0x285c/4)+7, 0xbf800000); INSTANCE_WR(ctx, (0x285c/4)+9, 0xbf800000); /* write32 #1 block at +0x00742fcc NV_PRAMIN+0x42fcc of 4 (0x4) elements: +0x00742fcc: 00000000 3f800000 00000000 00000000 */ INSTANCE_WR(ctx, (0x282c/4)+1, 0x3f800000); /* write32 #1 block at +0x0074302c NV_PRAMIN+0x4302c of 4 (0x4) elements: +0x0074302c: 00000000 00000000 00000000 00000000 write32 #1 block at +0x00743c9c NV_PRAMIN+0x43c9c of 4 (0x4) elements: +0x00743c9c: 00000000 00000000 00000000 00000000 write32 #1 block at +0x00743c3c NV_PRAMIN+0x43c3c of 8 (0x8) elements: +0x00743c3c: 00000000 00000000 000fe000 00000000 00000000 00000000 00000000 00000000 */ INSTANCE_WR(ctx, (0x349c/4)+2, 0x000fe000); /* write32 #1 block at +0x00743c6c NV_PRAMIN+0x43c6c of 4 (0x4) elements: +0x00743c6c: 00000000 00000000 00000000 00000000 write32 #1 block at +0x00743ccc NV_PRAMIN+0x43ccc of 4 (0x4) elements: +0x00743ccc: 00000000 000003f8 00000000 00000000 */ INSTANCE_WR(ctx, (0x352c/4)+1, 0x000003f8); /* write32 #1 NV_PRAMIN+0x43ce0 <- 0x002fe000 */ INSTANCE_WR(ctx, 0x3540/4, 0x002fe000); /* write32 #1 block at +0x00743cfc NV_PRAMIN+0x43cfc of 8 (0x8) elements: +0x00743cfc: 001c527c 001c527c 001c527c 001c527c 001c527c 001c527c 001c527c 001c527c */ for (i = 0; i < 8; ++i) INSTANCE_WR(ctx, (0x355c/4)+i, 0x001c527c); } static void nv2a_graph_context_init(struct drm_device *dev, struct nouveau_gpuobj *ctx) { struct drm_nouveau_private *dev_priv = dev->dev_private; int i; INSTANCE_WR(ctx, 0x33c/4, 0xffff0000); for(i = 0x3a0; i< 0x3a8; i += 4) INSTANCE_WR(ctx, i/4, 0x0fff0000); INSTANCE_WR(ctx, 0x47c/4, 0x00000101); INSTANCE_WR(ctx, 0x490/4, 0x00000111); INSTANCE_WR(ctx, 0x4a8/4, 0x44400000); for(i = 0x4d4; i< 0x4e4; i += 4) INSTANCE_WR(ctx, i/4, 0x00030303); for(i = 0x4f4; i< 0x504; i += 4) INSTANCE_WR(ctx, i/4, 0x00080000); for(i = 0x50c; i< 0x51c; i += 4) INSTANCE_WR(ctx, i/4, 0x01012000); for(i = 0x51c; i< 0x52c; i += 4) INSTANCE_WR(ctx, i/4, 0x000105b8); for(i = 0x52c; i< 0x53c; i += 4) INSTANCE_WR(ctx, i/4, 0x00080008); for(i = 0x55c; i< 0x59c; i += 4) INSTANCE_WR(ctx, i/4, 0x07ff0000); INSTANCE_WR(ctx, 0x5a4/4, 0x4b7fffff); INSTANCE_WR(ctx, 0x5fc/4, 0x00000001); INSTANCE_WR(ctx, 0x604/4, 0x00004000); INSTANCE_WR(ctx, 0x610/4, 0x00000001); INSTANCE_WR(ctx, 0x618/4, 0x00040000); INSTANCE_WR(ctx, 0x61c/4, 0x00010000); for (i=0x1a9c; i <= 0x22fc/4; i += 32) { INSTANCE_WR(ctx, i/4 , 0x10700ff9); INSTANCE_WR(ctx, i/4 + 1, 0x0436086c); INSTANCE_WR(ctx, i/4 + 2, 0x000c001b); } INSTANCE_WR(ctx, 0x269c/4, 0x3f800000); INSTANCE_WR(ctx, 0x26b0/4, 0x3f800000); INSTANCE_WR(ctx, 0x26dc/4, 0x40000000); INSTANCE_WR(ctx, 0x26e0/4, 0x3f800000); INSTANCE_WR(ctx, 0x26e4/4, 0x3f000000); INSTANCE_WR(ctx, 0x26ec/4, 0x40000000); INSTANCE_WR(ctx, 0x26f0/4, 0x3f800000); INSTANCE_WR(ctx, 0x26f8/4, 0xbf800000); INSTANCE_WR(ctx, 0x2700/4, 0xbf800000); INSTANCE_WR(ctx, 0x3024/4, 0x000fe000); INSTANCE_WR(ctx, 0x30a0/4, 0x000003f8); INSTANCE_WR(ctx, 0x33fc/4, 0x002fe000); for(i = 0x341c; i< 0x343c; i += 4) INSTANCE_WR(ctx, i/4, 0x001c527c); } static void nv25_graph_context_init(struct drm_device *dev, struct nouveau_gpuobj *ctx) { struct drm_nouveau_private *dev_priv = dev->dev_private; int i; /* write32 #1 block at +0x00740a7c NV_PRAMIN.GRCTX0+0x35c of 173 (0xad) elements: +0x00740a7c: ffff0000 00000000 00000000 00000000 00000000 00000000 00000000 00000000 +0x00740a9c: 00000000 00000000 00000000 00000000 00000000 00000000 00000000 00000000 +0x00740abc: 00000000 00000000 00000000 00000000 00000000 00000000 00000000 00000000 +0x00740adc: 00000000 0fff0000 0fff0000 00000000 00000000 00000000 00000000 00000000 +0x00740afc: 00000000 00000000 00000000 00000000 00000000 00000000 00000000 00000000 +0x00740b1c: 00000000 00000000 00000000 00000000 00000000 00000000 00000000 00000000 +0x00740b3c: 00000000 00000000 00000000 00000000 00000000 00000000 00000000 00000000 +0x00740b5c: 00000000 00000000 00000000 00000000 00000000 00000000 00000000 00000000 +0x00740b7c: 00000000 00000000 00000000 00000000 00000000 00000000 00000000 00000000 +0x00740b9c: 00000000 00000000 00000000 00000000 00000000 00000000 00000000 00000000 +0x00740bbc: 00000101 00000000 00000000 00000000 00000000 00000111 00000000 00000000 +0x00740bdc: 00000000 00000000 00000000 00000080 ffff0000 00000001 00000000 00000000 +0x00740bfc: 00000000 00000000 44400000 00000000 00000000 00000000 00000000 00000000 +0x00740c1c: 4b800000 00000000 00000000 00000000 00000000 00030303 00030303 00030303 +0x00740c3c: 00030303 00000000 00000000 00000000 00000000 00080000 00080000 00080000 +0x00740c5c: 00080000 00000000 00000000 01012000 01012000 01012000 01012000 000105b8 +0x00740c7c: 000105b8 000105b8 000105b8 00080008 00080008 00080008 00080008 00000000 +0x00740c9c: 00000000 00000000 00000000 00000000 00000000 00000000 00000000 07ff0000 +0x00740cbc: 07ff0000 07ff0000 07ff0000 07ff0000 07ff0000 07ff0000 07ff0000 07ff0000 +0x00740cdc: 07ff0000 07ff0000 07ff0000 07ff0000 07ff0000 07ff0000 07ff0000 00000000 +0x00740cfc: 00000000 4b7fffff 00000000 00000000 00000000 00000000 00000000 00000000 +0x00740d1c: 00000000 00000000 00000000 00000000 00000000 */ INSTANCE_WR(ctx, (0x35c/4)+0, 0xffff0000); INSTANCE_WR(ctx, (0x35c/4)+25, 0x0fff0000); INSTANCE_WR(ctx, (0x35c/4)+26, 0x0fff0000); INSTANCE_WR(ctx, (0x35c/4)+80, 0x00000101); INSTANCE_WR(ctx, (0x35c/4)+85, 0x00000111); INSTANCE_WR(ctx, (0x35c/4)+91, 0x00000080); INSTANCE_WR(ctx, (0x35c/4)+92, 0xffff0000); INSTANCE_WR(ctx, (0x35c/4)+93, 0x00000001); INSTANCE_WR(ctx, (0x35c/4)+98, 0x44400000); INSTANCE_WR(ctx, (0x35c/4)+104, 0x4b800000); INSTANCE_WR(ctx, (0x35c/4)+109, 0x00030303); INSTANCE_WR(ctx, (0x35c/4)+110, 0x00030303); INSTANCE_WR(ctx, (0x35c/4)+111, 0x00030303); INSTANCE_WR(ctx, (0x35c/4)+112, 0x00030303); INSTANCE_WR(ctx, (0x35c/4)+117, 0x00080000); INSTANCE_WR(ctx, (0x35c/4)+118, 0x00080000); INSTANCE_WR(ctx, (0x35c/4)+119, 0x00080000); INSTANCE_WR(ctx, (0x35c/4)+120, 0x00080000); INSTANCE_WR(ctx, (0x35c/4)+123, 0x01012000); INSTANCE_WR(ctx, (0x35c/4)+124, 0x01012000); INSTANCE_WR(ctx, (0x35c/4)+125, 0x01012000); INSTANCE_WR(ctx, (0x35c/4)+126, 0x01012000); INSTANCE_WR(ctx, (0x35c/4)+127, 0x000105b8); INSTANCE_WR(ctx, (0x35c/4)+128, 0x000105b8); INSTANCE_WR(ctx, (0x35c/4)+129, 0x000105b8); INSTANCE_WR(ctx, (0x35c/4)+130, 0x000105b8); INSTANCE_WR(ctx, (0x35c/4)+131, 0x00080008); INSTANCE_WR(ctx, (0x35c/4)+132, 0x00080008); INSTANCE_WR(ctx, (0x35c/4)+133, 0x00080008); INSTANCE_WR(ctx, (0x35c/4)+134, 0x00080008); for (i=0; i<16; ++i) INSTANCE_WR(ctx, (0x35c/4)+143+i, 0x07ff0000); INSTANCE_WR(ctx, (0x35c/4)+161, 0x4b7fffff); /* write32 #1 block at +0x00740d34 NV_PRAMIN.GRCTX0+0x614 of 3136 (0xc40) elements: +0x00740d34: 00000000 00000000 00000000 00000080 30201000 70605040 b0a09080 f0e0d0c0 +0x00740d54: 00000000 00000000 00000000 00000000 00000000 00000000 00000000 00000000 +0x00740d74: 00000000 00000000 00000000 00000000 00000001 00000000 00004000 00000000 +0x00740d94: 00000000 00000001 00000000 00040000 00010000 00000000 00000000 00000000 +0x00740db4: 00000000 00000000 00000000 00000000 00000000 00000000 00000000 00000000 ... +0x00742214: 00000000 00000000 00000000 00000000 10700ff9 0436086c 000c001b 00000000 +0x00742234: 10700ff9 0436086c 000c001b 00000000 10700ff9 0436086c 000c001b 00000000 +0x00742254: 10700ff9 0436086c 000c001b 00000000 10700ff9 0436086c 000c001b 00000000 +0x00742274: 10700ff9 0436086c 000c001b 00000000 10700ff9 0436086c 000c001b 00000000 ... +0x00742a34: 10700ff9 0436086c 000c001b 00000000 10700ff9 0436086c 000c001b 00000000 +0x00742a54: 10700ff9 0436086c 000c001b 00000000 10700ff9 0436086c 000c001b 00000000 +0x00742a74: 10700ff9 0436086c 000c001b 00000000 10700ff9 0436086c 000c001b 00000000 +0x00742a94: 10700ff9 0436086c 000c001b 00000000 00000000 00000000 00000000 00000000 +0x00742ab4: 00000000 00000000 00000000 00000000 00000000 00000000 00000000 00000000 +0x00742ad4: 00000000 00000000 00000000 00000000 00000000 00000000 00000000 00000000 */ INSTANCE_WR(ctx, (0x614/4)+3, 0x00000080); INSTANCE_WR(ctx, (0x614/4)+4, 0x30201000); INSTANCE_WR(ctx, (0x614/4)+5, 0x70605040); INSTANCE_WR(ctx, (0x614/4)+6, 0xb0a09080); INSTANCE_WR(ctx, (0x614/4)+7, 0xf0e0d0c0); INSTANCE_WR(ctx, (0x614/4)+20, 0x00000001); INSTANCE_WR(ctx, (0x614/4)+22, 0x00004000); INSTANCE_WR(ctx, (0x614/4)+25, 0x00000001); INSTANCE_WR(ctx, (0x614/4)+27, 0x00040000); INSTANCE_WR(ctx, (0x614/4)+28, 0x00010000); for (i=0; i < 0x880/4; i+=4) { INSTANCE_WR(ctx, (0x1b04/4)+i+0, 0x10700ff9); INSTANCE_WR(ctx, (0x1b04/4)+i+1, 0x0436086c); INSTANCE_WR(ctx, (0x1b04/4)+i+2, 0x000c001b); } /* write32 #1 block at +0x00742e24 NV_PRAMIN.GRCTX0+0x2704 of 4 (0x4) elements: +0x00742e24: 3f800000 00000000 00000000 00000000 */ INSTANCE_WR(ctx, (0x2704/4), 0x3f800000); /* write32 #1 block at +0x00742e64 NV_PRAMIN.GRCTX0+0x2744 of 12 (0xc) elements: +0x00742e64: 40000000 3f800000 3f000000 00000000 40000000 3f800000 00000000 bf800000 +0x00742e84: 00000000 bf800000 00000000 00000000 */ INSTANCE_WR(ctx, (0x2744/4)+0, 0x40000000); INSTANCE_WR(ctx, (0x2744/4)+1, 0x3f800000); INSTANCE_WR(ctx, (0x2744/4)+2, 0x3f000000); INSTANCE_WR(ctx, (0x2744/4)+4, 0x40000000); INSTANCE_WR(ctx, (0x2744/4)+5, 0x3f800000); INSTANCE_WR(ctx, (0x2744/4)+7, 0xbf800000); INSTANCE_WR(ctx, (0x2744/4)+9, 0xbf800000); /* write32 #1 block at +0x00742e34 NV_PRAMIN.GRCTX0+0x2714 of 4 (0x4) elements: +0x00742e34: 00000000 3f800000 00000000 00000000 */ INSTANCE_WR(ctx, (0x2714/4)+1, 0x3f800000); /* write32 #1 block at +0x00742e94 NV_PRAMIN.GRCTX0+0x2774 of 4 (0x4) elements: +0x00742e94: 00000000 00000000 00000000 00000000 write32 #1 block at +0x00743804 NV_PRAMIN.GRCTX0+0x30e4 of 4 (0x4) elements: +0x00743804: 00000000 00000000 00000000 00000000 write32 #1 block at +0x007437a4 NV_PRAMIN.GRCTX0+0x3084 of 8 (0x8) elements: +0x007437a4: 00000000 00000000 000fe000 00000000 00000000 00000000 00000000 00000000 */ INSTANCE_WR(ctx, (0x3084/4)+2, 0x000fe000); /* write32 #1 block at +0x007437d4 NV_PRAMIN.GRCTX0+0x30b4 of 4 (0x4) elements: +0x007437d4: 00000000 00000000 00000000 00000000 write32 #1 block at +0x00743824 NV_PRAMIN.GRCTX0+0x3104 of 4 (0x4) elements: +0x00743824: 00000000 000003f8 00000000 00000000 */ INSTANCE_WR(ctx, (0x3104/4)+1, 0x000003f8); /* write32 #1 NV_PRAMIN.GRCTX0+0x3468 <- 0x002fe000 */ INSTANCE_WR(ctx, 0x3468/4, 0x002fe000); /* write32 #1 block at +0x00743ba4 NV_PRAMIN.GRCTX0+0x3484 of 8 (0x8) elements: +0x00743ba4: 001c527c 001c527c 001c527c 001c527c 001c527c 001c527c 001c527c 001c527c */ for (i=0; i<8; ++i) INSTANCE_WR(ctx, (0x3484/4)+i, 0x001c527c); } static void nv30_31_graph_context_init(struct drm_device *dev, struct nouveau_gpuobj *ctx) { struct drm_nouveau_private *dev_priv = dev->dev_private; int i; INSTANCE_WR(ctx, 0x410/4, 0x00000101); INSTANCE_WR(ctx, 0x424/4, 0x00000111); INSTANCE_WR(ctx, 0x428/4, 0x00000060); INSTANCE_WR(ctx, 0x444/4, 0x00000080); INSTANCE_WR(ctx, 0x448/4, 0xffff0000); INSTANCE_WR(ctx, 0x44c/4, 0x00000001); INSTANCE_WR(ctx, 0x460/4, 0x44400000); INSTANCE_WR(ctx, 0x48c/4, 0xffff0000); for(i = 0x4e0; i< 0x4e8; i += 4) INSTANCE_WR(ctx, i/4, 0x0fff0000); INSTANCE_WR(ctx, 0x4ec/4, 0x00011100); for(i = 0x508; i< 0x548; i += 4) INSTANCE_WR(ctx, i/4, 0x07ff0000); INSTANCE_WR(ctx, 0x550/4, 0x4b7fffff); INSTANCE_WR(ctx, 0x58c/4, 0x00000080); INSTANCE_WR(ctx, 0x590/4, 0x30201000); INSTANCE_WR(ctx, 0x594/4, 0x70605040); INSTANCE_WR(ctx, 0x598/4, 0xb8a89888); INSTANCE_WR(ctx, 0x59c/4, 0xf8e8d8c8); INSTANCE_WR(ctx, 0x5b0/4, 0xb0000000); for(i = 0x600; i< 0x640; i += 4) INSTANCE_WR(ctx, i/4, 0x00010588); for(i = 0x640; i< 0x680; i += 4) INSTANCE_WR(ctx, i/4, 0x00030303); for(i = 0x6c0; i< 0x700; i += 4) INSTANCE_WR(ctx, i/4, 0x0008aae4); for(i = 0x700; i< 0x740; i += 4) INSTANCE_WR(ctx, i/4, 0x01012000); for(i = 0x740; i< 0x780; i += 4) INSTANCE_WR(ctx, i/4, 0x00080008); INSTANCE_WR(ctx, 0x85c/4, 0x00040000); INSTANCE_WR(ctx, 0x860/4, 0x00010000); for(i = 0x864; i< 0x874; i += 4) INSTANCE_WR(ctx, i/4, 0x00040004); for(i = 0x1f18; i<= 0x3088 ; i+= 16) { INSTANCE_WR(ctx, i/4 + 0, 0x10700ff9); INSTANCE_WR(ctx, i/4 + 1, 0x0436086c); INSTANCE_WR(ctx, i/4 + 2, 0x000c001b); } for(i = 0x30b8; i< 0x30c8; i += 4) INSTANCE_WR(ctx, i/4, 0x0000ffff); INSTANCE_WR(ctx, 0x344c/4, 0x3f800000); INSTANCE_WR(ctx, 0x3808/4, 0x3f800000); INSTANCE_WR(ctx, 0x381c/4, 0x3f800000); INSTANCE_WR(ctx, 0x3848/4, 0x40000000); INSTANCE_WR(ctx, 0x384c/4, 0x3f800000); INSTANCE_WR(ctx, 0x3850/4, 0x3f000000); INSTANCE_WR(ctx, 0x3858/4, 0x40000000); INSTANCE_WR(ctx, 0x385c/4, 0x3f800000); INSTANCE_WR(ctx, 0x3864/4, 0xbf800000); INSTANCE_WR(ctx, 0x386c/4, 0xbf800000); } static void nv34_graph_context_init(struct drm_device *dev, struct nouveau_gpuobj *ctx) { struct drm_nouveau_private *dev_priv = dev->dev_private; int i; INSTANCE_WR(ctx, 0x40c/4, 0x01000101); INSTANCE_WR(ctx, 0x420/4, 0x00000111); INSTANCE_WR(ctx, 0x424/4, 0x00000060); INSTANCE_WR(ctx, 0x440/4, 0x00000080); INSTANCE_WR(ctx, 0x444/4, 0xffff0000); INSTANCE_WR(ctx, 0x448/4, 0x00000001); INSTANCE_WR(ctx, 0x45c/4, 0x44400000); INSTANCE_WR(ctx, 0x480/4, 0xffff0000); for(i = 0x4d4; i< 0x4dc; i += 4) INSTANCE_WR(ctx, i/4, 0x0fff0000); INSTANCE_WR(ctx, 0x4e0/4, 0x00011100); for(i = 0x4fc; i< 0x53c; i += 4) INSTANCE_WR(ctx, i/4, 0x07ff0000); INSTANCE_WR(ctx, 0x544/4, 0x4b7fffff); INSTANCE_WR(ctx, 0x57c/4, 0x00000080); INSTANCE_WR(ctx, 0x580/4, 0x30201000); INSTANCE_WR(ctx, 0x584/4, 0x70605040); INSTANCE_WR(ctx, 0x588/4, 0xb8a89888); INSTANCE_WR(ctx, 0x58c/4, 0xf8e8d8c8); INSTANCE_WR(ctx, 0x5a0/4, 0xb0000000); for(i = 0x5f0; i< 0x630; i += 4) INSTANCE_WR(ctx, i/4, 0x00010588); for(i = 0x630; i< 0x670; i += 4) INSTANCE_WR(ctx, i/4, 0x00030303); for(i = 0x6b0; i< 0x6f0; i += 4) INSTANCE_WR(ctx, i/4, 0x0008aae4); for(i = 0x6f0; i< 0x730; i += 4) INSTANCE_WR(ctx, i/4, 0x01012000); for(i = 0x730; i< 0x770; i += 4) INSTANCE_WR(ctx, i/4, 0x00080008); INSTANCE_WR(ctx, 0x850/4, 0x00040000); INSTANCE_WR(ctx, 0x854/4, 0x00010000); for(i = 0x858; i< 0x868; i += 4) INSTANCE_WR(ctx, i/4, 0x00040004); for(i = 0x15ac; i<= 0x271c ; i+= 16) { INSTANCE_WR(ctx, i/4 + 0, 0x10700ff9); INSTANCE_WR(ctx, i/4 + 1, 0x0436086c); INSTANCE_WR(ctx, i/4 + 2, 0x000c001b); } for(i = 0x274c; i< 0x275c; i += 4) INSTANCE_WR(ctx, i/4, 0x0000ffff); INSTANCE_WR(ctx, 0x2ae0/4, 0x3f800000); INSTANCE_WR(ctx, 0x2e9c/4, 0x3f800000); INSTANCE_WR(ctx, 0x2eb0/4, 0x3f800000); INSTANCE_WR(ctx, 0x2edc/4, 0x40000000); INSTANCE_WR(ctx, 0x2ee0/4, 0x3f800000); INSTANCE_WR(ctx, 0x2ee4/4, 0x3f000000); INSTANCE_WR(ctx, 0x2eec/4, 0x40000000); INSTANCE_WR(ctx, 0x2ef0/4, 0x3f800000); INSTANCE_WR(ctx, 0x2ef8/4, 0xbf800000); INSTANCE_WR(ctx, 0x2f00/4, 0xbf800000); } static void nv35_36_graph_context_init(struct drm_device *dev, struct nouveau_gpuobj *ctx) { struct drm_nouveau_private *dev_priv = dev->dev_private; int i; INSTANCE_WR(ctx, 0x40c/4, 0x00000101); INSTANCE_WR(ctx, 0x420/4, 0x00000111); INSTANCE_WR(ctx, 0x424/4, 0x00000060); INSTANCE_WR(ctx, 0x440/4, 0x00000080); INSTANCE_WR(ctx, 0x444/4, 0xffff0000); INSTANCE_WR(ctx, 0x448/4, 0x00000001); INSTANCE_WR(ctx, 0x45c/4, 0x44400000); INSTANCE_WR(ctx, 0x488/4, 0xffff0000); for(i = 0x4dc; i< 0x4e4; i += 4) INSTANCE_WR(ctx, i/4, 0x0fff0000); INSTANCE_WR(ctx, 0x4e8/4, 0x00011100); for(i = 0x504; i< 0x544; i += 4) INSTANCE_WR(ctx, i/4, 0x07ff0000); INSTANCE_WR(ctx, 0x54c/4, 0x4b7fffff); INSTANCE_WR(ctx, 0x588/4, 0x00000080); INSTANCE_WR(ctx, 0x58c/4, 0x30201000); INSTANCE_WR(ctx, 0x590/4, 0x70605040); INSTANCE_WR(ctx, 0x594/4, 0xb8a89888); INSTANCE_WR(ctx, 0x598/4, 0xf8e8d8c8); INSTANCE_WR(ctx, 0x5ac/4, 0xb0000000); for(i = 0x604; i< 0x644; i += 4) INSTANCE_WR(ctx, i/4, 0x00010588); for(i = 0x644; i< 0x684; i += 4) INSTANCE_WR(ctx, i/4, 0x00030303); for(i = 0x6c4; i< 0x704; i += 4) INSTANCE_WR(ctx, i/4, 0x0008aae4); for(i = 0x704; i< 0x744; i += 4) INSTANCE_WR(ctx, i/4, 0x01012000); for(i = 0x744; i< 0x784; i += 4) INSTANCE_WR(ctx, i/4, 0x00080008); INSTANCE_WR(ctx, 0x860/4, 0x00040000); INSTANCE_WR(ctx, 0x864/4, 0x00010000); for(i = 0x868; i< 0x878; i += 4) INSTANCE_WR(ctx, i/4, 0x00040004); for(i = 0x1f1c; i<= 0x308c ; i+= 16) { INSTANCE_WR(ctx, i/4 + 0, 0x10700ff9); INSTANCE_WR(ctx, i/4 + 1, 0x0436086c); INSTANCE_WR(ctx, i/4 + 2, 0x000c001b); } for(i = 0x30bc; i< 0x30cc; i += 4) INSTANCE_WR(ctx, i/4, 0x0000ffff); INSTANCE_WR(ctx, 0x3450/4, 0x3f800000); INSTANCE_WR(ctx, 0x380c/4, 0x3f800000); INSTANCE_WR(ctx, 0x3820/4, 0x3f800000); INSTANCE_WR(ctx, 0x384c/4, 0x40000000); INSTANCE_WR(ctx, 0x3850/4, 0x3f800000); INSTANCE_WR(ctx, 0x3854/4, 0x3f000000); INSTANCE_WR(ctx, 0x385c/4, 0x40000000); INSTANCE_WR(ctx, 0x3860/4, 0x3f800000); INSTANCE_WR(ctx, 0x3868/4, 0xbf800000); INSTANCE_WR(ctx, 0x3870/4, 0xbf800000); } int nv20_graph_create_context(struct nouveau_channel *chan) { struct drm_device *dev = chan->dev; struct drm_nouveau_private *dev_priv = dev->dev_private; void (*ctx_init)(struct drm_device *, struct nouveau_gpuobj *); unsigned int ctx_size; unsigned int idoffs = 0x28/4; int ret; switch (dev_priv->chipset) { case 0x20: ctx_size = NV20_GRCTX_SIZE; ctx_init = nv20_graph_context_init; idoffs = 0; break; case 0x25: case 0x28: ctx_size = NV25_GRCTX_SIZE; ctx_init = nv25_graph_context_init; break; case 0x2a: ctx_size = NV2A_GRCTX_SIZE; ctx_init = nv2a_graph_context_init; idoffs = 0; break; case 0x30: case 0x31: ctx_size = NV30_31_GRCTX_SIZE; ctx_init = nv30_31_graph_context_init; break; case 0x34: ctx_size = NV34_GRCTX_SIZE; ctx_init = nv34_graph_context_init; break; case 0x35: case 0x36: ctx_size = NV35_36_GRCTX_SIZE; ctx_init = nv35_36_graph_context_init; break; default: ctx_size = 0; ctx_init = nv35_36_graph_context_init; DRM_ERROR("Please contact the devs if you want your NV%x" " card to work\n", dev_priv->chipset); return -ENOSYS; break; } if ((ret = nouveau_gpuobj_new_ref(dev, chan, NULL, 0, ctx_size, 16, NVOBJ_FLAG_ZERO_ALLOC, &chan->ramin_grctx))) return ret; /* Initialise default context values */ ctx_init(dev, chan->ramin_grctx->gpuobj); /* nv20: INSTANCE_WR(chan->ramin_grctx->gpuobj, 10, chan->id<<24); */ INSTANCE_WR(chan->ramin_grctx->gpuobj, idoffs, (chan->id<<24)|0x1); /* CTX_USER */ INSTANCE_WR(dev_priv->ctx_table->gpuobj, chan->id, chan->ramin_grctx->instance >> 4); return 0; } void nv20_graph_destroy_context(struct nouveau_channel *chan) { struct drm_device *dev = chan->dev; struct drm_nouveau_private *dev_priv = dev->dev_private; if (chan->ramin_grctx) nouveau_gpuobj_ref_del(dev, &chan->ramin_grctx); INSTANCE_WR(dev_priv->ctx_table->gpuobj, chan->id, 0); } int nv20_graph_load_context(struct nouveau_channel *chan) { struct drm_device *dev = chan->dev; struct drm_nouveau_private *dev_priv = dev->dev_private; uint32_t inst; if (!chan->ramin_grctx) return -EINVAL; inst = chan->ramin_grctx->instance >> 4; NV_WRITE(NV20_PGRAPH_CHANNEL_CTX_POINTER, inst); NV_WRITE(NV20_PGRAPH_CHANNEL_CTX_XFER, NV20_PGRAPH_CHANNEL_CTX_XFER_LOAD); NV_WRITE(NV10_PGRAPH_CTX_CONTROL, 0x10010100); nouveau_wait_for_idle(dev); return 0; } int nv20_graph_save_context(struct nouveau_channel *chan) { struct drm_device *dev = chan->dev; struct drm_nouveau_private *dev_priv = dev->dev_private; uint32_t inst; if (!chan->ramin_grctx) return -EINVAL; inst = chan->ramin_grctx->instance >> 4; NV_WRITE(NV20_PGRAPH_CHANNEL_CTX_POINTER, inst); NV_WRITE(NV20_PGRAPH_CHANNEL_CTX_XFER, NV20_PGRAPH_CHANNEL_CTX_XFER_SAVE); nouveau_wait_for_idle(dev); return 0; } static void nv20_graph_rdi(struct drm_device *dev) { struct drm_nouveau_private *dev_priv = dev->dev_private; int i, writecount = 32; uint32_t rdi_index = 0x2c80000; if (dev_priv->chipset == 0x20) { rdi_index = 0x3d0000; writecount = 15; } NV_WRITE(NV10_PGRAPH_RDI_INDEX, rdi_index); for (i = 0; i < writecount; i++) NV_WRITE(NV10_PGRAPH_RDI_DATA, 0); nouveau_wait_for_idle(dev); } int nv20_graph_init(struct drm_device *dev) { struct drm_nouveau_private *dev_priv = (struct drm_nouveau_private *)dev->dev_private; uint32_t tmp, vramsz; int ret, i; NV_WRITE(NV03_PMC_ENABLE, NV_READ(NV03_PMC_ENABLE) & ~NV_PMC_ENABLE_PGRAPH); NV_WRITE(NV03_PMC_ENABLE, NV_READ(NV03_PMC_ENABLE) | NV_PMC_ENABLE_PGRAPH); if (!dev_priv->ctx_table) { /* Create Context Pointer Table */ dev_priv->ctx_table_size = 32 * 4; if ((ret = nouveau_gpuobj_new_ref(dev, NULL, NULL, 0, dev_priv->ctx_table_size, 16, NVOBJ_FLAG_ZERO_ALLOC, &dev_priv->ctx_table))) return ret; } NV_WRITE(NV20_PGRAPH_CHANNEL_CTX_TABLE, dev_priv->ctx_table->instance >> 4); nv20_graph_rdi(dev); NV_WRITE(NV03_PGRAPH_INTR , 0xFFFFFFFF); NV_WRITE(NV03_PGRAPH_INTR_EN, 0xFFFFFFFF); NV_WRITE(NV04_PGRAPH_DEBUG_0, 0xFFFFFFFF); NV_WRITE(NV04_PGRAPH_DEBUG_0, 0x00000000); NV_WRITE(NV04_PGRAPH_DEBUG_1, 0x00118700); NV_WRITE(NV04_PGRAPH_DEBUG_3, 0xF3CE0475); /* 0x4 = auto ctx switch */ NV_WRITE(NV10_PGRAPH_DEBUG_4, 0x00000000); NV_WRITE(0x40009C , 0x00000040); if (dev_priv->chipset >= 0x25) { NV_WRITE(0x400890, 0x00080000); NV_WRITE(0x400610, 0x304B1FB6); NV_WRITE(0x400B80, 0x18B82880); NV_WRITE(0x400B84, 0x44000000); NV_WRITE(0x400098, 0x40000080); NV_WRITE(0x400B88, 0x000000ff); } else { NV_WRITE(0x400880, 0x00080000); /* 0x0008c7df */ NV_WRITE(0x400094, 0x00000005); NV_WRITE(0x400B80, 0x45CAA208); /* 0x45eae20e */ NV_WRITE(0x400B84, 0x24000000); NV_WRITE(0x400098, 0x00000040); NV_WRITE(NV10_PGRAPH_RDI_INDEX, 0x00E00038); NV_WRITE(NV10_PGRAPH_RDI_DATA , 0x00000030); NV_WRITE(NV10_PGRAPH_RDI_INDEX, 0x00E10038); NV_WRITE(NV10_PGRAPH_RDI_DATA , 0x00000030); } /* copy tile info from PFB */ for (i = 0; i < NV10_PFB_TILE__SIZE; i++) { NV_WRITE(0x00400904 + i*0x10, NV_READ(NV10_PFB_TLIMIT(i))); /* which is NV40_PGRAPH_TLIMIT0(i) ?? */ NV_WRITE(NV10_PGRAPH_RDI_INDEX, 0x00EA0030+i*4); NV_WRITE(NV10_PGRAPH_RDI_DATA, NV_READ(NV10_PFB_TLIMIT(i))); NV_WRITE(0x00400908 + i*0x10, NV_READ(NV10_PFB_TSIZE(i))); /* which is NV40_PGRAPH_TSIZE0(i) ?? */ NV_WRITE(NV10_PGRAPH_RDI_INDEX, 0x00EA0050+i*4); NV_WRITE(NV10_PGRAPH_RDI_DATA, NV_READ(NV10_PFB_TSIZE(i))); NV_WRITE(0x00400900 + i*0x10, NV_READ(NV10_PFB_TILE(i))); /* which is NV40_PGRAPH_TILE0(i) ?? */ NV_WRITE(NV10_PGRAPH_RDI_INDEX, 0x00EA0010+i*4); NV_WRITE(NV10_PGRAPH_RDI_DATA, NV_READ(NV10_PFB_TILE(i))); } for (i = 0; i < 8; i++) { NV_WRITE(0x400980+i*4, NV_READ(0x100300+i*4)); NV_WRITE(NV10_PGRAPH_RDI_INDEX, 0x00EA0090+i*4); NV_WRITE(NV10_PGRAPH_RDI_DATA, NV_READ(0x100300+i*4)); } NV_WRITE(0x4009a0, NV_READ(0x100324)); NV_WRITE(NV10_PGRAPH_RDI_INDEX, 0x00EA000C); NV_WRITE(NV10_PGRAPH_RDI_DATA, NV_READ(0x100324)); NV_WRITE(NV10_PGRAPH_CTX_CONTROL, 0x10000100); NV_WRITE(NV10_PGRAPH_STATE , 0xFFFFFFFF); NV_WRITE(NV04_PGRAPH_FIFO , 0x00000001); tmp = NV_READ(NV10_PGRAPH_SURFACE) & 0x0007ff00; NV_WRITE(NV10_PGRAPH_SURFACE, tmp); tmp = NV_READ(NV10_PGRAPH_SURFACE) | 0x00020100; NV_WRITE(NV10_PGRAPH_SURFACE, tmp); /* begin RAM config */ vramsz = drm_get_resource_len(dev, 0) - 1; NV_WRITE(0x4009A4, NV_READ(NV04_PFB_CFG0)); NV_WRITE(0x4009A8, NV_READ(NV04_PFB_CFG1)); NV_WRITE(NV10_PGRAPH_RDI_INDEX, 0x00EA0000); NV_WRITE(NV10_PGRAPH_RDI_DATA , NV_READ(NV04_PFB_CFG0)); NV_WRITE(NV10_PGRAPH_RDI_INDEX, 0x00EA0004); NV_WRITE(NV10_PGRAPH_RDI_DATA , NV_READ(NV04_PFB_CFG1)); NV_WRITE(0x400820, 0); NV_WRITE(0x400824, 0); NV_WRITE(0x400864, vramsz-1); NV_WRITE(0x400868, vramsz-1); /* interesting.. the below overwrites some of the tile setup above.. */ NV_WRITE(0x400B20, 0x00000000); NV_WRITE(0x400B04, 0xFFFFFFFF); NV_WRITE(NV03_PGRAPH_ABS_UCLIP_XMIN, 0); NV_WRITE(NV03_PGRAPH_ABS_UCLIP_YMIN, 0); NV_WRITE(NV03_PGRAPH_ABS_UCLIP_XMAX, 0x7fff); NV_WRITE(NV03_PGRAPH_ABS_UCLIP_YMAX, 0x7fff); return 0; } void nv20_graph_takedown(struct drm_device *dev) { struct drm_nouveau_private *dev_priv = dev->dev_private; nouveau_gpuobj_ref_del(dev, &dev_priv->ctx_table); } int nv30_graph_init(struct drm_device *dev) { struct drm_nouveau_private *dev_priv = dev->dev_private; // uint32_t vramsz, tmp; int ret, i; NV_WRITE(NV03_PMC_ENABLE, NV_READ(NV03_PMC_ENABLE) & ~NV_PMC_ENABLE_PGRAPH); NV_WRITE(NV03_PMC_ENABLE, NV_READ(NV03_PMC_ENABLE) | NV_PMC_ENABLE_PGRAPH); if (!dev_priv->ctx_table) { /* Create Context Pointer Table */ dev_priv->ctx_table_size = 32 * 4; if ((ret = nouveau_gpuobj_new_ref(dev, NULL, NULL, 0, dev_priv->ctx_table_size, 16, NVOBJ_FLAG_ZERO_ALLOC, &dev_priv->ctx_table))) return ret; } NV_WRITE(NV20_PGRAPH_CHANNEL_CTX_TABLE, dev_priv->ctx_table->instance >> 4); NV_WRITE(NV03_PGRAPH_INTR , 0xFFFFFFFF); NV_WRITE(NV03_PGRAPH_INTR_EN, 0xFFFFFFFF); NV_WRITE(NV04_PGRAPH_DEBUG_0, 0xFFFFFFFF); NV_WRITE(NV04_PGRAPH_DEBUG_0, 0x00000000); NV_WRITE(NV04_PGRAPH_DEBUG_1, 0x401287c0); NV_WRITE(0x400890, 0x01b463ff); NV_WRITE(NV04_PGRAPH_DEBUG_3, 0xf2de0475); NV_WRITE(NV10_PGRAPH_DEBUG_4, 0x00008000); NV_WRITE(NV04_PGRAPH_LIMIT_VIOL_PIX, 0xf04bdff6); NV_WRITE(0x400B80, 0x1003d888); NV_WRITE(0x400B84, 0x0c000000); NV_WRITE(0x400098, 0x00000000); NV_WRITE(0x40009C, 0x0005ad00); NV_WRITE(0x400B88, 0x62ff00ff); // suspiciously like PGRAPH_DEBUG_2 NV_WRITE(0x4000a0, 0x00000000); NV_WRITE(0x4000a4, 0x00000008); NV_WRITE(0x4008a8, 0xb784a400); NV_WRITE(0x400ba0, 0x002f8685); NV_WRITE(0x400ba4, 0x00231f3f); NV_WRITE(0x4008a4, 0x40000020); if (dev_priv->chipset == 0x34) { NV_WRITE(NV10_PGRAPH_RDI_INDEX, 0x00EA0004); NV_WRITE(NV10_PGRAPH_RDI_DATA , 0x00200201); NV_WRITE(NV10_PGRAPH_RDI_INDEX, 0x00EA0008); NV_WRITE(NV10_PGRAPH_RDI_DATA , 0x00000008); NV_WRITE(NV10_PGRAPH_RDI_INDEX, 0x00EA0000); NV_WRITE(NV10_PGRAPH_RDI_DATA , 0x00000032); NV_WRITE(NV10_PGRAPH_RDI_INDEX, 0x00E00004); NV_WRITE(NV10_PGRAPH_RDI_DATA , 0x00000002); } NV_WRITE(0x4000c0, 0x00000016); /* copy tile info from PFB */ for (i = 0; i < NV10_PFB_TILE__SIZE; i++) { NV_WRITE(0x00400904 + i*0x10, NV_READ(NV10_PFB_TLIMIT(i))); /* which is NV40_PGRAPH_TLIMIT0(i) ?? */ NV_WRITE(0x00400908 + i*0x10, NV_READ(NV10_PFB_TSIZE(i))); /* which is NV40_PGRAPH_TSIZE0(i) ?? */ NV_WRITE(0x00400900 + i*0x10, NV_READ(NV10_PFB_TILE(i))); /* which is NV40_PGRAPH_TILE0(i) ?? */ } NV_WRITE(NV10_PGRAPH_CTX_CONTROL, 0x10000100); NV_WRITE(NV10_PGRAPH_STATE , 0xFFFFFFFF); NV_WRITE(0x0040075c , 0x00000001); NV_WRITE(NV04_PGRAPH_FIFO , 0x00000001); /* begin RAM config */ // vramsz = drm_get_resource_len(dev, 0) - 1; NV_WRITE(0x4009A4, NV_READ(NV04_PFB_CFG0)); NV_WRITE(0x4009A8, NV_READ(NV04_PFB_CFG1)); if (dev_priv->chipset != 0x34) { NV_WRITE(0x400750, 0x00EA0000); NV_WRITE(0x400754, NV_READ(NV04_PFB_CFG0)); NV_WRITE(0x400750, 0x00EA0004); NV_WRITE(0x400754, NV_READ(NV04_PFB_CFG1)); } #if 0 NV_WRITE(0x400820, 0); NV_WRITE(0x400824, 0); NV_WRITE(0x400864, vramsz-1); NV_WRITE(0x400868, vramsz-1); NV_WRITE(0x400B20, 0x00000000); NV_WRITE(0x400B04, 0xFFFFFFFF); /* per-context state, doesn't belong here */ tmp = NV_READ(NV10_PGRAPH_SURFACE) & 0x0007ff00; NV_WRITE(NV10_PGRAPH_SURFACE, tmp); tmp = NV_READ(NV10_PGRAPH_SURFACE) | 0x00020100; NV_WRITE(NV10_PGRAPH_SURFACE, tmp); NV_WRITE(NV03_PGRAPH_ABS_UCLIP_XMIN, 0); NV_WRITE(NV03_PGRAPH_ABS_UCLIP_YMIN, 0); NV_WRITE(NV03_PGRAPH_ABS_UCLIP_XMAX, 0x7fff); NV_WRITE(NV03_PGRAPH_ABS_UCLIP_YMAX, 0x7fff); #endif return 0; }