/* * Copyright 2012 Advanced Micro Devices, Inc. * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE COPYRIGHT HOLDER(S) OR AUTHOR(S) BE LIABLE FOR ANY CLAIM, DAMAGES OR * OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, * ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR * OTHER DEALINGS IN THE SOFTWARE. * * Authors: Alex Deucher */ #include #include #include #include #include "drmP.h" #include "radeon.h" #include "radeon_asic.h" #include "cikd.h" #include "atom.h" #include "cik_blit_shaders.h" /* GFX */ #define CIK_PFP_UCODE_SIZE 2144 #define CIK_ME_UCODE_SIZE 2144 #define CIK_CE_UCODE_SIZE 2144 /* compute */ #define CIK_MEC_UCODE_SIZE 4192 /* interrupts */ #define BONAIRE_RLC_UCODE_SIZE 2048 #define KB_RLC_UCODE_SIZE 2560 #define KV_RLC_UCODE_SIZE 2560 /* gddr controller */ #define CIK_MC_UCODE_SIZE 7866 /* sdma */ #define CIK_SDMA_UCODE_SIZE 1050 #define CIK_SDMA_UCODE_VERSION 64 MODULE_FIRMWARE("radeon/BONAIRE_pfp.bin"); MODULE_FIRMWARE("radeon/BONAIRE_me.bin"); MODULE_FIRMWARE("radeon/BONAIRE_ce.bin"); MODULE_FIRMWARE("radeon/BONAIRE_mec.bin"); MODULE_FIRMWARE("radeon/BONAIRE_mc.bin"); MODULE_FIRMWARE("radeon/BONAIRE_rlc.bin"); MODULE_FIRMWARE("radeon/BONAIRE_sdma.bin"); MODULE_FIRMWARE("radeon/KAVERI_pfp.bin"); MODULE_FIRMWARE("radeon/KAVERI_me.bin"); MODULE_FIRMWARE("radeon/KAVERI_ce.bin"); MODULE_FIRMWARE("radeon/KAVERI_mec.bin"); MODULE_FIRMWARE("radeon/KAVERI_rlc.bin"); MODULE_FIRMWARE("radeon/KAVERI_sdma.bin"); MODULE_FIRMWARE("radeon/KABINI_pfp.bin"); MODULE_FIRMWARE("radeon/KABINI_me.bin"); MODULE_FIRMWARE("radeon/KABINI_ce.bin"); MODULE_FIRMWARE("radeon/KABINI_mec.bin"); MODULE_FIRMWARE("radeon/KABINI_rlc.bin"); MODULE_FIRMWARE("radeon/KABINI_sdma.bin"); extern int r600_ih_ring_alloc(struct radeon_device *rdev); extern void r600_ih_ring_fini(struct radeon_device *rdev); extern void evergreen_mc_stop(struct radeon_device *rdev, struct evergreen_mc_save *save); extern void evergreen_mc_resume(struct radeon_device *rdev, struct evergreen_mc_save *save); extern void si_vram_gtt_location(struct radeon_device *rdev, struct radeon_mc *mc); #define BONAIRE_IO_MC_REGS_SIZE 36 static const u32 bonaire_io_mc_regs[BONAIRE_IO_MC_REGS_SIZE][2] = { {0x00000070, 0x04400000}, {0x00000071, 0x80c01803}, {0x00000072, 0x00004004}, {0x00000073, 0x00000100}, {0x00000074, 0x00ff0000}, {0x00000075, 0x34000000}, {0x00000076, 0x08000014}, {0x00000077, 0x00cc08ec}, {0x00000078, 0x00000400}, {0x00000079, 0x00000000}, {0x0000007a, 0x04090000}, {0x0000007c, 0x00000000}, {0x0000007e, 0x4408a8e8}, {0x0000007f, 0x00000304}, {0x00000080, 0x00000000}, {0x00000082, 0x00000001}, {0x00000083, 0x00000002}, {0x00000084, 0xf3e4f400}, {0x00000085, 0x052024e3}, {0x00000087, 0x00000000}, {0x00000088, 0x01000000}, {0x0000008a, 0x1c0a0000}, {0x0000008b, 0xff010000}, {0x0000008d, 0xffffefff}, {0x0000008e, 0xfff3efff}, {0x0000008f, 0xfff3efbf}, {0x00000092, 0xf7ffffff}, {0x00000093, 0xffffff7f}, {0x00000095, 0x00101101}, {0x00000096, 0x00000fff}, {0x00000097, 0x00116fff}, {0x00000098, 0x60010000}, {0x00000099, 0x10010000}, {0x0000009a, 0x00006000}, {0x0000009b, 0x00001000}, {0x0000009f, 0x00b48000} }; /* ucode loading */ /** * ci_mc_load_microcode - load MC ucode into the hw * * @rdev: radeon_device pointer * * Load the GDDR MC ucode into the hw (CIK). * Returns 0 on success, error on failure. */ static int ci_mc_load_microcode(struct radeon_device *rdev) { const __be32 *fw_data; u32 running, blackout = 0; u32 *io_mc_regs; int i, ucode_size, regs_size; if (!rdev->mc_fw) return -EINVAL; switch (rdev->family) { case CHIP_BONAIRE: default: io_mc_regs = (u32 *)&bonaire_io_mc_regs; ucode_size = CIK_MC_UCODE_SIZE; regs_size = BONAIRE_IO_MC_REGS_SIZE; break; } running = RREG32(MC_SEQ_SUP_CNTL) & RUN_MASK; if (running == 0) { if (running) { blackout = RREG32(MC_SHARED_BLACKOUT_CNTL); WREG32(MC_SHARED_BLACKOUT_CNTL, blackout | 1); } /* reset the engine and set to writable */ WREG32(MC_SEQ_SUP_CNTL, 0x00000008); WREG32(MC_SEQ_SUP_CNTL, 0x00000010); /* load mc io regs */ for (i = 0; i < regs_size; i++) { WREG32(MC_SEQ_IO_DEBUG_INDEX, io_mc_regs[(i << 1)]); WREG32(MC_SEQ_IO_DEBUG_DATA, io_mc_regs[(i << 1) + 1]); } /* load the MC ucode */ fw_data = (const __be32 *)rdev->mc_fw->data; for (i = 0; i < ucode_size; i++) WREG32(MC_SEQ_SUP_PGM, be32_to_cpup(fw_data++)); /* put the engine back into the active state */ WREG32(MC_SEQ_SUP_CNTL, 0x00000008); WREG32(MC_SEQ_SUP_CNTL, 0x00000004); WREG32(MC_SEQ_SUP_CNTL, 0x00000001); /* wait for training to complete */ for (i = 0; i < rdev->usec_timeout; i++) { if (RREG32(MC_SEQ_TRAIN_WAKEUP_CNTL) & TRAIN_DONE_D0) break; udelay(1); } for (i = 0; i < rdev->usec_timeout; i++) { if (RREG32(MC_SEQ_TRAIN_WAKEUP_CNTL) & TRAIN_DONE_D1) break; udelay(1); } if (running) WREG32(MC_SHARED_BLACKOUT_CNTL, blackout); } return 0; } /** * cik_init_microcode - load ucode images from disk * * @rdev: radeon_device pointer * * Use the firmware interface to load the ucode images into * the driver (not loaded into hw). * Returns 0 on success, error on failure. */ static int cik_init_microcode(struct radeon_device *rdev) { struct platform_device *pdev; const char *chip_name; size_t pfp_req_size, me_req_size, ce_req_size, mec_req_size, rlc_req_size, mc_req_size, sdma_req_size; char fw_name[30]; int err; DRM_DEBUG("\n"); pdev = platform_device_register_simple("radeon_cp", 0, NULL, 0); err = IS_ERR(pdev); if (err) { printk(KERN_ERR "radeon_cp: Failed to register firmware\n"); return -EINVAL; } switch (rdev->family) { case CHIP_BONAIRE: chip_name = "BONAIRE"; pfp_req_size = CIK_PFP_UCODE_SIZE * 4; me_req_size = CIK_ME_UCODE_SIZE * 4; ce_req_size = CIK_CE_UCODE_SIZE * 4; mec_req_size = CIK_MEC_UCODE_SIZE * 4; rlc_req_size = BONAIRE_RLC_UCODE_SIZE * 4; mc_req_size = CIK_MC_UCODE_SIZE * 4; sdma_req_size = CIK_SDMA_UCODE_SIZE * 4; break; case CHIP_KAVERI: chip_name = "KAVERI"; pfp_req_size = CIK_PFP_UCODE_SIZE * 4; me_req_size = CIK_ME_UCODE_SIZE * 4; ce_req_size = CIK_CE_UCODE_SIZE * 4; mec_req_size = CIK_MEC_UCODE_SIZE * 4; rlc_req_size = KV_RLC_UCODE_SIZE * 4; sdma_req_size = CIK_SDMA_UCODE_SIZE * 4; break; case CHIP_KABINI: chip_name = "KABINI"; pfp_req_size = CIK_PFP_UCODE_SIZE * 4; me_req_size = CIK_ME_UCODE_SIZE * 4; ce_req_size = CIK_CE_UCODE_SIZE * 4; mec_req_size = CIK_MEC_UCODE_SIZE * 4; rlc_req_size = KB_RLC_UCODE_SIZE * 4; sdma_req_size = CIK_SDMA_UCODE_SIZE * 4; break; default: BUG(); } DRM_INFO("Loading %s Microcode\n", chip_name); snprintf(fw_name, sizeof(fw_name), "radeon/%s_pfp.bin", chip_name); err = request_firmware(&rdev->pfp_fw, fw_name, &pdev->dev); if (err) goto out; if (rdev->pfp_fw->size != pfp_req_size) { printk(KERN_ERR "cik_cp: Bogus length %zu in firmware \"%s\"\n", rdev->pfp_fw->size, fw_name); err = -EINVAL; goto out; } snprintf(fw_name, sizeof(fw_name), "radeon/%s_me.bin", chip_name); err = request_firmware(&rdev->me_fw, fw_name, &pdev->dev); if (err) goto out; if (rdev->me_fw->size != me_req_size) { printk(KERN_ERR "cik_cp: Bogus length %zu in firmware \"%s\"\n", rdev->me_fw->size, fw_name); err = -EINVAL; } snprintf(fw_name, sizeof(fw_name), "radeon/%s_ce.bin", chip_name); err = request_firmware(&rdev->ce_fw, fw_name, &pdev->dev); if (err) goto out; if (rdev->ce_fw->size != ce_req_size) { printk(KERN_ERR "cik_cp: Bogus length %zu in firmware \"%s\"\n", rdev->ce_fw->size, fw_name); err = -EINVAL; } snprintf(fw_name, sizeof(fw_name), "radeon/%s_mec.bin", chip_name); err = request_firmware(&rdev->mec_fw, fw_name, &pdev->dev); if (err) goto out; if (rdev->mec_fw->size != mec_req_size) { printk(KERN_ERR "cik_cp: Bogus length %zu in firmware \"%s\"\n", rdev->mec_fw->size, fw_name); err = -EINVAL; } snprintf(fw_name, sizeof(fw_name), "radeon/%s_rlc.bin", chip_name); err = request_firmware(&rdev->rlc_fw, fw_name, &pdev->dev); if (err) goto out; if (rdev->rlc_fw->size != rlc_req_size) { printk(KERN_ERR "cik_rlc: Bogus length %zu in firmware \"%s\"\n", rdev->rlc_fw->size, fw_name); err = -EINVAL; } snprintf(fw_name, sizeof(fw_name), "radeon/%s_sdma.bin", chip_name); err = request_firmware(&rdev->sdma_fw, fw_name, &pdev->dev); if (err) goto out; if (rdev->sdma_fw->size != sdma_req_size) { printk(KERN_ERR "cik_sdma: Bogus length %zu in firmware \"%s\"\n", rdev->sdma_fw->size, fw_name); err = -EINVAL; } /* No MC ucode on APUs */ if (!(rdev->flags & RADEON_IS_IGP)) { snprintf(fw_name, sizeof(fw_name), "radeon/%s_mc.bin", chip_name); err = request_firmware(&rdev->mc_fw, fw_name, &pdev->dev); if (err) goto out; if (rdev->mc_fw->size != mc_req_size) { printk(KERN_ERR "cik_mc: Bogus length %zu in firmware \"%s\"\n", rdev->mc_fw->size, fw_name); err = -EINVAL; } } out: platform_device_unregister(pdev); if (err) { if (err != -EINVAL) printk(KERN_ERR "cik_cp: Failed to load firmware \"%s\"\n", fw_name); release_firmware(rdev->pfp_fw); rdev->pfp_fw = NULL; release_firmware(rdev->me_fw); rdev->me_fw = NULL; release_firmware(rdev->ce_fw); rdev->ce_fw = NULL; release_firmware(rdev->rlc_fw); rdev->rlc_fw = NULL; release_firmware(rdev->mc_fw); rdev->mc_fw = NULL; } return err; } /* * Core functions */ /** * cik_tiling_mode_table_init - init the hw tiling table * * @rdev: radeon_device pointer * * Starting with SI, the tiling setup is done globally in a * set of 32 tiling modes. Rather than selecting each set of * parameters per surface as on older asics, we just select * which index in the tiling table we want to use, and the * surface uses those parameters (CIK). */ static void cik_tiling_mode_table_init(struct radeon_device *rdev) { const u32 num_tile_mode_states = 32; const u32 num_secondary_tile_mode_states = 16; u32 reg_offset, gb_tile_moden, split_equal_to_row_size; u32 num_pipe_configs; u32 num_rbs = rdev->config.cik.max_backends_per_se * rdev->config.cik.max_shader_engines; switch (rdev->config.cik.mem_row_size_in_kb) { case 1: split_equal_to_row_size = ADDR_SURF_TILE_SPLIT_1KB; break; case 2: default: split_equal_to_row_size = ADDR_SURF_TILE_SPLIT_2KB; break; case 4: split_equal_to_row_size = ADDR_SURF_TILE_SPLIT_4KB; break; } num_pipe_configs = rdev->config.cik.max_tile_pipes; if (num_pipe_configs > 8) num_pipe_configs = 8; /* ??? */ if (num_pipe_configs == 8) { for (reg_offset = 0; reg_offset < num_tile_mode_states; reg_offset++) { switch (reg_offset) { case 0: gb_tile_moden = (ARRAY_MODE(ARRAY_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DEPTH_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P8_32x32_16x16) | TILE_SPLIT(ADDR_SURF_TILE_SPLIT_64B)); break; case 1: gb_tile_moden = (ARRAY_MODE(ARRAY_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DEPTH_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P8_32x32_16x16) | TILE_SPLIT(ADDR_SURF_TILE_SPLIT_128B)); break; case 2: gb_tile_moden = (ARRAY_MODE(ARRAY_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DEPTH_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P8_32x32_16x16) | TILE_SPLIT(ADDR_SURF_TILE_SPLIT_256B)); break; case 3: gb_tile_moden = (ARRAY_MODE(ARRAY_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DEPTH_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P8_32x32_16x16) | TILE_SPLIT(ADDR_SURF_TILE_SPLIT_512B)); break; case 4: gb_tile_moden = (ARRAY_MODE(ARRAY_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DEPTH_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P8_32x32_16x16) | TILE_SPLIT(split_equal_to_row_size)); break; case 5: gb_tile_moden = (ARRAY_MODE(ARRAY_1D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DEPTH_MICRO_TILING)); break; case 6: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DEPTH_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P8_32x32_16x16) | TILE_SPLIT(ADDR_SURF_TILE_SPLIT_256B)); break; case 7: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DEPTH_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P8_32x32_16x16) | TILE_SPLIT(split_equal_to_row_size)); break; case 8: gb_tile_moden = (ARRAY_MODE(ARRAY_LINEAR_ALIGNED) | PIPE_CONFIG(ADDR_SURF_P8_32x32_16x16)); break; case 9: gb_tile_moden = (ARRAY_MODE(ARRAY_1D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DISPLAY_MICRO_TILING)); break; case 10: gb_tile_moden = (ARRAY_MODE(ARRAY_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DISPLAY_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P8_32x32_16x16) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; case 11: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DISPLAY_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P8_32x32_8x16) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; case 12: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DISPLAY_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P8_32x32_16x16) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; case 13: gb_tile_moden = (ARRAY_MODE(ARRAY_1D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_THIN_MICRO_TILING)); break; case 14: gb_tile_moden = (ARRAY_MODE(ARRAY_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_THIN_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P8_32x32_16x16) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; case 16: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_THIN_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P8_32x32_8x16) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; case 17: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_THIN_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P8_32x32_16x16) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; case 27: gb_tile_moden = (ARRAY_MODE(ARRAY_1D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_ROTATED_MICRO_TILING)); break; case 28: gb_tile_moden = (ARRAY_MODE(ARRAY_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_ROTATED_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P8_32x32_16x16) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; case 29: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_ROTATED_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P8_32x32_8x16) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; case 30: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_ROTATED_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P8_32x32_16x16) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; default: gb_tile_moden = 0; break; } WREG32(GB_TILE_MODE0 + (reg_offset * 4), gb_tile_moden); } for (reg_offset = 0; reg_offset < num_secondary_tile_mode_states; reg_offset++) { switch (reg_offset) { case 0: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_1) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_4) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_4) | NUM_BANKS(ADDR_SURF_16_BANK)); break; case 1: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_1) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_2) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_2) | NUM_BANKS(ADDR_SURF_16_BANK)); break; case 2: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_1) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_1) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_2) | NUM_BANKS(ADDR_SURF_16_BANK)); break; case 3: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_1) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_1) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_2) | NUM_BANKS(ADDR_SURF_16_BANK)); break; case 4: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_1) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_1) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_1) | NUM_BANKS(ADDR_SURF_8_BANK)); break; case 5: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_1) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_1) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_1) | NUM_BANKS(ADDR_SURF_4_BANK)); break; case 6: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_1) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_1) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_1) | NUM_BANKS(ADDR_SURF_2_BANK)); break; case 8: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_1) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_8) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_4) | NUM_BANKS(ADDR_SURF_16_BANK)); break; case 9: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_1) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_4) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_4) | NUM_BANKS(ADDR_SURF_16_BANK)); break; case 10: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_1) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_2) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_2) | NUM_BANKS(ADDR_SURF_16_BANK)); break; case 11: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_1) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_1) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_2) | NUM_BANKS(ADDR_SURF_16_BANK)); break; case 12: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_1) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_1) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_1) | NUM_BANKS(ADDR_SURF_8_BANK)); break; case 13: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_1) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_1) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_1) | NUM_BANKS(ADDR_SURF_4_BANK)); break; case 14: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_1) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_1) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_1) | NUM_BANKS(ADDR_SURF_2_BANK)); break; default: gb_tile_moden = 0; break; } WREG32(GB_MACROTILE_MODE0 + (reg_offset * 4), gb_tile_moden); } } else if (num_pipe_configs == 4) { if (num_rbs == 4) { for (reg_offset = 0; reg_offset < num_tile_mode_states; reg_offset++) { switch (reg_offset) { case 0: gb_tile_moden = (ARRAY_MODE(ARRAY_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DEPTH_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P4_16x16) | TILE_SPLIT(ADDR_SURF_TILE_SPLIT_64B)); break; case 1: gb_tile_moden = (ARRAY_MODE(ARRAY_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DEPTH_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P4_16x16) | TILE_SPLIT(ADDR_SURF_TILE_SPLIT_128B)); break; case 2: gb_tile_moden = (ARRAY_MODE(ARRAY_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DEPTH_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P4_16x16) | TILE_SPLIT(ADDR_SURF_TILE_SPLIT_256B)); break; case 3: gb_tile_moden = (ARRAY_MODE(ARRAY_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DEPTH_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P4_16x16) | TILE_SPLIT(ADDR_SURF_TILE_SPLIT_512B)); break; case 4: gb_tile_moden = (ARRAY_MODE(ARRAY_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DEPTH_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P4_16x16) | TILE_SPLIT(split_equal_to_row_size)); break; case 5: gb_tile_moden = (ARRAY_MODE(ARRAY_1D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DEPTH_MICRO_TILING)); break; case 6: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DEPTH_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P4_16x16) | TILE_SPLIT(ADDR_SURF_TILE_SPLIT_256B)); break; case 7: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DEPTH_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P4_16x16) | TILE_SPLIT(split_equal_to_row_size)); break; case 8: gb_tile_moden = (ARRAY_MODE(ARRAY_LINEAR_ALIGNED) | PIPE_CONFIG(ADDR_SURF_P4_16x16)); break; case 9: gb_tile_moden = (ARRAY_MODE(ARRAY_1D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DISPLAY_MICRO_TILING)); break; case 10: gb_tile_moden = (ARRAY_MODE(ARRAY_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DISPLAY_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P4_16x16) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; case 11: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DISPLAY_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P4_8x16) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; case 12: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DISPLAY_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P4_16x16) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; case 13: gb_tile_moden = (ARRAY_MODE(ARRAY_1D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_THIN_MICRO_TILING)); break; case 14: gb_tile_moden = (ARRAY_MODE(ARRAY_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_THIN_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P4_16x16) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; case 16: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_THIN_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P4_8x16) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; case 17: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_THIN_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P4_16x16) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; case 27: gb_tile_moden = (ARRAY_MODE(ARRAY_1D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_ROTATED_MICRO_TILING)); break; case 28: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_ROTATED_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P4_16x16) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; case 29: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_ROTATED_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P4_8x16) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; case 30: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_ROTATED_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P4_16x16) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; default: gb_tile_moden = 0; break; } WREG32(GB_TILE_MODE0 + (reg_offset * 4), gb_tile_moden); } } else if (num_rbs < 4) { for (reg_offset = 0; reg_offset < num_tile_mode_states; reg_offset++) { switch (reg_offset) { case 0: gb_tile_moden = (ARRAY_MODE(ARRAY_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DEPTH_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P4_8x16) | TILE_SPLIT(ADDR_SURF_TILE_SPLIT_64B)); break; case 1: gb_tile_moden = (ARRAY_MODE(ARRAY_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DEPTH_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P4_8x16) | TILE_SPLIT(ADDR_SURF_TILE_SPLIT_128B)); break; case 2: gb_tile_moden = (ARRAY_MODE(ARRAY_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DEPTH_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P4_8x16) | TILE_SPLIT(ADDR_SURF_TILE_SPLIT_256B)); break; case 3: gb_tile_moden = (ARRAY_MODE(ARRAY_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DEPTH_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P4_8x16) | TILE_SPLIT(ADDR_SURF_TILE_SPLIT_512B)); break; case 4: gb_tile_moden = (ARRAY_MODE(ARRAY_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DEPTH_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P4_8x16) | TILE_SPLIT(split_equal_to_row_size)); break; case 5: gb_tile_moden = (ARRAY_MODE(ARRAY_1D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DEPTH_MICRO_TILING)); break; case 6: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DEPTH_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P4_8x16) | TILE_SPLIT(ADDR_SURF_TILE_SPLIT_256B)); break; case 7: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DEPTH_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P4_8x16) | TILE_SPLIT(split_equal_to_row_size)); break; case 8: gb_tile_moden = (ARRAY_MODE(ARRAY_LINEAR_ALIGNED) | PIPE_CONFIG(ADDR_SURF_P4_8x16)); break; case 9: gb_tile_moden = (ARRAY_MODE(ARRAY_1D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DISPLAY_MICRO_TILING)); break; case 10: gb_tile_moden = (ARRAY_MODE(ARRAY_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DISPLAY_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P4_8x16) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; case 11: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DISPLAY_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P4_8x16) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; case 12: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DISPLAY_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P4_8x16) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; case 13: gb_tile_moden = (ARRAY_MODE(ARRAY_1D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_THIN_MICRO_TILING)); break; case 14: gb_tile_moden = (ARRAY_MODE(ARRAY_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_THIN_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P4_8x16) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; case 16: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_THIN_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P4_8x16) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; case 17: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_THIN_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P4_8x16) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; case 27: gb_tile_moden = (ARRAY_MODE(ARRAY_1D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_ROTATED_MICRO_TILING)); break; case 28: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_ROTATED_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P4_8x16) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; case 29: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_ROTATED_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P4_8x16) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; case 30: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_ROTATED_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P4_8x16) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; default: gb_tile_moden = 0; break; } WREG32(GB_TILE_MODE0 + (reg_offset * 4), gb_tile_moden); } } for (reg_offset = 0; reg_offset < num_secondary_tile_mode_states; reg_offset++) { switch (reg_offset) { case 0: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_1) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_4) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_4) | NUM_BANKS(ADDR_SURF_16_BANK)); break; case 1: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_1) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_2) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_4) | NUM_BANKS(ADDR_SURF_16_BANK)); break; case 2: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_1) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_1) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_2) | NUM_BANKS(ADDR_SURF_16_BANK)); break; case 3: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_1) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_1) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_2) | NUM_BANKS(ADDR_SURF_16_BANK)); break; case 4: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_1) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_1) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_2) | NUM_BANKS(ADDR_SURF_16_BANK)); break; case 5: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_1) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_1) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_2) | NUM_BANKS(ADDR_SURF_8_BANK)); break; case 6: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_1) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_1) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_1) | NUM_BANKS(ADDR_SURF_4_BANK)); break; case 8: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_2) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_8) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_4) | NUM_BANKS(ADDR_SURF_16_BANK)); break; case 9: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_2) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_4) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_4) | NUM_BANKS(ADDR_SURF_16_BANK)); break; case 10: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_1) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_4) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_4) | NUM_BANKS(ADDR_SURF_16_BANK)); break; case 11: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_1) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_2) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_4) | NUM_BANKS(ADDR_SURF_16_BANK)); break; case 12: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_1) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_1) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_2) | NUM_BANKS(ADDR_SURF_16_BANK)); break; case 13: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_1) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_1) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_2) | NUM_BANKS(ADDR_SURF_8_BANK)); break; case 14: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_1) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_1) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_1) | NUM_BANKS(ADDR_SURF_4_BANK)); break; default: gb_tile_moden = 0; break; } WREG32(GB_MACROTILE_MODE0 + (reg_offset * 4), gb_tile_moden); } } else if (num_pipe_configs == 2) { for (reg_offset = 0; reg_offset < num_tile_mode_states; reg_offset++) { switch (reg_offset) { case 0: gb_tile_moden = (ARRAY_MODE(ARRAY_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DEPTH_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P2) | TILE_SPLIT(ADDR_SURF_TILE_SPLIT_64B)); break; case 1: gb_tile_moden = (ARRAY_MODE(ARRAY_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DEPTH_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P2) | TILE_SPLIT(ADDR_SURF_TILE_SPLIT_128B)); break; case 2: gb_tile_moden = (ARRAY_MODE(ARRAY_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DEPTH_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P2) | TILE_SPLIT(ADDR_SURF_TILE_SPLIT_256B)); break; case 3: gb_tile_moden = (ARRAY_MODE(ARRAY_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DEPTH_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P2) | TILE_SPLIT(ADDR_SURF_TILE_SPLIT_512B)); break; case 4: gb_tile_moden = (ARRAY_MODE(ARRAY_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DEPTH_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P2) | TILE_SPLIT(split_equal_to_row_size)); break; case 5: gb_tile_moden = (ARRAY_MODE(ARRAY_1D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DEPTH_MICRO_TILING)); break; case 6: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DEPTH_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P2) | TILE_SPLIT(ADDR_SURF_TILE_SPLIT_256B)); break; case 7: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DEPTH_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P2) | TILE_SPLIT(split_equal_to_row_size)); break; case 8: gb_tile_moden = ARRAY_MODE(ARRAY_LINEAR_ALIGNED); break; case 9: gb_tile_moden = (ARRAY_MODE(ARRAY_1D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DISPLAY_MICRO_TILING)); break; case 10: gb_tile_moden = (ARRAY_MODE(ARRAY_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DISPLAY_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P2) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; case 11: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DISPLAY_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P2) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; case 12: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_DISPLAY_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P2) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; case 13: gb_tile_moden = (ARRAY_MODE(ARRAY_1D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_THIN_MICRO_TILING)); break; case 14: gb_tile_moden = (ARRAY_MODE(ARRAY_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_THIN_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P2) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; case 16: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_THIN_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P2) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; case 17: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_THIN_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P2) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; case 27: gb_tile_moden = (ARRAY_MODE(ARRAY_1D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_ROTATED_MICRO_TILING)); break; case 28: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_ROTATED_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P2) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; case 29: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_ROTATED_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P2) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; case 30: gb_tile_moden = (ARRAY_MODE(ARRAY_PRT_2D_TILED_THIN1) | MICRO_TILE_MODE_NEW(ADDR_SURF_ROTATED_MICRO_TILING) | PIPE_CONFIG(ADDR_SURF_P2) | SAMPLE_SPLIT(ADDR_SURF_SAMPLE_SPLIT_2)); break; default: gb_tile_moden = 0; break; } WREG32(GB_TILE_MODE0 + (reg_offset * 4), gb_tile_moden); } for (reg_offset = 0; reg_offset < num_secondary_tile_mode_states; reg_offset++) { switch (reg_offset) { case 0: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_2) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_4) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_4) | NUM_BANKS(ADDR_SURF_16_BANK)); break; case 1: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_2) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_2) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_4) | NUM_BANKS(ADDR_SURF_16_BANK)); break; case 2: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_1) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_2) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_4) | NUM_BANKS(ADDR_SURF_16_BANK)); break; case 3: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_1) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_1) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_4) | NUM_BANKS(ADDR_SURF_16_BANK)); break; case 4: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_1) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_1) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_4) | NUM_BANKS(ADDR_SURF_16_BANK)); break; case 5: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_1) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_1) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_4) | NUM_BANKS(ADDR_SURF_16_BANK)); break; case 6: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_1) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_1) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_2) | NUM_BANKS(ADDR_SURF_8_BANK)); break; case 8: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_4) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_8) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_4) | NUM_BANKS(ADDR_SURF_16_BANK)); break; case 9: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_4) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_4) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_4) | NUM_BANKS(ADDR_SURF_16_BANK)); break; case 10: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_2) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_4) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_4) | NUM_BANKS(ADDR_SURF_16_BANK)); break; case 11: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_2) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_2) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_4) | NUM_BANKS(ADDR_SURF_16_BANK)); break; case 12: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_1) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_2) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_4) | NUM_BANKS(ADDR_SURF_16_BANK)); break; case 13: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_1) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_1) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_4) | NUM_BANKS(ADDR_SURF_16_BANK)); break; case 14: gb_tile_moden = (BANK_WIDTH(ADDR_SURF_BANK_WIDTH_1) | BANK_HEIGHT(ADDR_SURF_BANK_HEIGHT_1) | MACRO_TILE_ASPECT(ADDR_SURF_MACRO_ASPECT_2) | NUM_BANKS(ADDR_SURF_8_BANK)); break; default: gb_tile_moden = 0; break; } WREG32(GB_MACROTILE_MODE0 + (reg_offset * 4), gb_tile_moden); } } else DRM_ERROR("unknown num pipe config: 0x%x\n", num_pipe_configs); } /** * cik_select_se_sh - select which SE, SH to address * * @rdev: radeon_device pointer * @se_num: shader engine to address * @sh_num: sh block to address * * Select which SE, SH combinations to address. Certain * registers are instanced per SE or SH. 0xffffffff means * broadcast to all SEs or SHs (CIK). */ static void cik_select_se_sh(struct radeon_device *rdev, u32 se_num, u32 sh_num) { u32 data = INSTANCE_BROADCAST_WRITES; if ((se_num == 0xffffffff) && (sh_num == 0xffffffff)) data = SH_BROADCAST_WRITES | SE_BROADCAST_WRITES; else if (se_num == 0xffffffff) data |= SE_BROADCAST_WRITES | SH_INDEX(sh_num); else if (sh_num == 0xffffffff) data |= SH_BROADCAST_WRITES | SE_INDEX(se_num); else data |= SH_INDEX(sh_num) | SE_INDEX(se_num); WREG32(GRBM_GFX_INDEX, data); } /** * cik_create_bitmask - create a bitmask * * @bit_width: length of the mask * * create a variable length bit mask (CIK). * Returns the bitmask. */ static u32 cik_create_bitmask(u32 bit_width) { u32 i, mask = 0; for (i = 0; i < bit_width; i++) { mask <<= 1; mask |= 1; } return mask; } /** * cik_select_se_sh - select which SE, SH to address * * @rdev: radeon_device pointer * @max_rb_num: max RBs (render backends) for the asic * @se_num: number of SEs (shader engines) for the asic * @sh_per_se: number of SH blocks per SE for the asic * * Calculates the bitmask of disabled RBs (CIK). * Returns the disabled RB bitmask. */ static u32 cik_get_rb_disabled(struct radeon_device *rdev, u32 max_rb_num, u32 se_num, u32 sh_per_se) { u32 data, mask; data = RREG32(CC_RB_BACKEND_DISABLE); if (data & 1) data &= BACKEND_DISABLE_MASK; else data = 0; data |= RREG32(GC_USER_RB_BACKEND_DISABLE); data >>= BACKEND_DISABLE_SHIFT; mask = cik_create_bitmask(max_rb_num / se_num / sh_per_se); return data & mask; } /** * cik_setup_rb - setup the RBs on the asic * * @rdev: radeon_device pointer * @se_num: number of SEs (shader engines) for the asic * @sh_per_se: number of SH blocks per SE for the asic * @max_rb_num: max RBs (render backends) for the asic * * Configures per-SE/SH RB registers (CIK). */ static void cik_setup_rb(struct radeon_device *rdev, u32 se_num, u32 sh_per_se, u32 max_rb_num) { int i, j; u32 data, mask; u32 disabled_rbs = 0; u32 enabled_rbs = 0; for (i = 0; i < se_num; i++) { for (j = 0; j < sh_per_se; j++) { cik_select_se_sh(rdev, i, j); data = cik_get_rb_disabled(rdev, max_rb_num, se_num, sh_per_se); disabled_rbs |= data << ((i * sh_per_se + j) * CIK_RB_BITMAP_WIDTH_PER_SH); } } cik_select_se_sh(rdev, 0xffffffff, 0xffffffff); mask = 1; for (i = 0; i < max_rb_num; i++) { if (!(disabled_rbs & mask)) enabled_rbs |= mask; mask <<= 1; } for (i = 0; i < se_num; i++) { cik_select_se_sh(rdev, i, 0xffffffff); data = 0; for (j = 0; j < sh_per_se; j++) { switch (enabled_rbs & 3) { case 1: data |= (RASTER_CONFIG_RB_MAP_0 << (i * sh_per_se + j) * 2); break; case 2: data |= (RASTER_CONFIG_RB_MAP_3 << (i * sh_per_se + j) * 2); break; case 3: default: data |= (RASTER_CONFIG_RB_MAP_2 << (i * sh_per_se + j) * 2); break; } enabled_rbs >>= 2; } WREG32(PA_SC_RASTER_CONFIG, data); } cik_select_se_sh(rdev, 0xffffffff, 0xffffffff); } /** * cik_gpu_init - setup the 3D engine * * @rdev: radeon_device pointer * * Configures the 3D engine and tiling configuration * registers so that the 3D engine is usable. */ static void cik_gpu_init(struct radeon_device *rdev) { u32 gb_addr_config = RREG32(GB_ADDR_CONFIG); u32 mc_shared_chmap, mc_arb_ramcfg; u32 hdp_host_path_cntl; u32 tmp; int i, j; switch (rdev->family) { case CHIP_BONAIRE: rdev->config.cik.max_shader_engines = 2; rdev->config.cik.max_tile_pipes = 4; rdev->config.cik.max_cu_per_sh = 7; rdev->config.cik.max_sh_per_se = 1; rdev->config.cik.max_backends_per_se = 2; rdev->config.cik.max_texture_channel_caches = 4; rdev->config.cik.max_gprs = 256; rdev->config.cik.max_gs_threads = 32; rdev->config.cik.max_hw_contexts = 8; rdev->config.cik.sc_prim_fifo_size_frontend = 0x20; rdev->config.cik.sc_prim_fifo_size_backend = 0x100; rdev->config.cik.sc_hiz_tile_fifo_size = 0x30; rdev->config.cik.sc_earlyz_tile_fifo_size = 0x130; gb_addr_config = BONAIRE_GB_ADDR_CONFIG_GOLDEN; break; case CHIP_KAVERI: /* TODO */ break; case CHIP_KABINI: default: rdev->config.cik.max_shader_engines = 1; rdev->config.cik.max_tile_pipes = 2; rdev->config.cik.max_cu_per_sh = 2; rdev->config.cik.max_sh_per_se = 1; rdev->config.cik.max_backends_per_se = 1; rdev->config.cik.max_texture_channel_caches = 2; rdev->config.cik.max_gprs = 256; rdev->config.cik.max_gs_threads = 16; rdev->config.cik.max_hw_contexts = 8; rdev->config.cik.sc_prim_fifo_size_frontend = 0x20; rdev->config.cik.sc_prim_fifo_size_backend = 0x100; rdev->config.cik.sc_hiz_tile_fifo_size = 0x30; rdev->config.cik.sc_earlyz_tile_fifo_size = 0x130; gb_addr_config = BONAIRE_GB_ADDR_CONFIG_GOLDEN; break; } /* Initialize HDP */ for (i = 0, j = 0; i < 32; i++, j += 0x18) { WREG32((0x2c14 + j), 0x00000000); WREG32((0x2c18 + j), 0x00000000); WREG32((0x2c1c + j), 0x00000000); WREG32((0x2c20 + j), 0x00000000); WREG32((0x2c24 + j), 0x00000000); } WREG32(GRBM_CNTL, GRBM_READ_TIMEOUT(0xff)); WREG32(BIF_FB_EN, FB_READ_EN | FB_WRITE_EN); mc_shared_chmap = RREG32(MC_SHARED_CHMAP); mc_arb_ramcfg = RREG32(MC_ARB_RAMCFG); rdev->config.cik.num_tile_pipes = rdev->config.cik.max_tile_pipes; rdev->config.cik.mem_max_burst_length_bytes = 256; tmp = (mc_arb_ramcfg & NOOFCOLS_MASK) >> NOOFCOLS_SHIFT; rdev->config.cik.mem_row_size_in_kb = (4 * (1 << (8 + tmp))) / 1024; if (rdev->config.cik.mem_row_size_in_kb > 4) rdev->config.cik.mem_row_size_in_kb = 4; /* XXX use MC settings? */ rdev->config.cik.shader_engine_tile_size = 32; rdev->config.cik.num_gpus = 1; rdev->config.cik.multi_gpu_tile_size = 64; /* fix up row size */ gb_addr_config &= ~ROW_SIZE_MASK; switch (rdev->config.cik.mem_row_size_in_kb) { case 1: default: gb_addr_config |= ROW_SIZE(0); break; case 2: gb_addr_config |= ROW_SIZE(1); break; case 4: gb_addr_config |= ROW_SIZE(2); break; } /* setup tiling info dword. gb_addr_config is not adequate since it does * not have bank info, so create a custom tiling dword. * bits 3:0 num_pipes * bits 7:4 num_banks * bits 11:8 group_size * bits 15:12 row_size */ rdev->config.cik.tile_config = 0; switch (rdev->config.cik.num_tile_pipes) { case 1: rdev->config.cik.tile_config |= (0 << 0); break; case 2: rdev->config.cik.tile_config |= (1 << 0); break; case 4: rdev->config.cik.tile_config |= (2 << 0); break; case 8: default: /* XXX what about 12? */ rdev->config.cik.tile_config |= (3 << 0); break; } if ((mc_arb_ramcfg & NOOFBANK_MASK) >> NOOFBANK_SHIFT) rdev->config.cik.tile_config |= 1 << 4; else rdev->config.cik.tile_config |= 0 << 4; rdev->config.cik.tile_config |= ((gb_addr_config & PIPE_INTERLEAVE_SIZE_MASK) >> PIPE_INTERLEAVE_SIZE_SHIFT) << 8; rdev->config.cik.tile_config |= ((gb_addr_config & ROW_SIZE_MASK) >> ROW_SIZE_SHIFT) << 12; WREG32(GB_ADDR_CONFIG, gb_addr_config); WREG32(HDP_ADDR_CONFIG, gb_addr_config); WREG32(DMIF_ADDR_CALC, gb_addr_config); WREG32(SDMA0_TILING_CONFIG + SDMA0_REGISTER_OFFSET, gb_addr_config & 0x70); WREG32(SDMA0_TILING_CONFIG + SDMA1_REGISTER_OFFSET, gb_addr_config & 0x70); cik_tiling_mode_table_init(rdev); cik_setup_rb(rdev, rdev->config.cik.max_shader_engines, rdev->config.cik.max_sh_per_se, rdev->config.cik.max_backends_per_se); /* set HW defaults for 3D engine */ WREG32(CP_MEQ_THRESHOLDS, MEQ1_START(0x30) | MEQ2_START(0x60)); WREG32(SX_DEBUG_1, 0x20); WREG32(TA_CNTL_AUX, 0x00010000); tmp = RREG32(SPI_CONFIG_CNTL); tmp |= 0x03000000; WREG32(SPI_CONFIG_CNTL, tmp); WREG32(SQ_CONFIG, 1); WREG32(DB_DEBUG, 0); tmp = RREG32(DB_DEBUG2) & ~0xf00fffff; tmp |= 0x00000400; WREG32(DB_DEBUG2, tmp); tmp = RREG32(DB_DEBUG3) & ~0x0002021c; tmp |= 0x00020200; WREG32(DB_DEBUG3, tmp); tmp = RREG32(CB_HW_CONTROL) & ~0x00010000; tmp |= 0x00018208; WREG32(CB_HW_CONTROL, tmp); WREG32(SPI_CONFIG_CNTL_1, VTX_DONE_DELAY(4)); WREG32(PA_SC_FIFO_SIZE, (SC_FRONTEND_PRIM_FIFO_SIZE(rdev->config.cik.sc_prim_fifo_size_frontend) | SC_BACKEND_PRIM_FIFO_SIZE(rdev->config.cik.sc_prim_fifo_size_backend) | SC_HIZ_TILE_FIFO_SIZE(rdev->config.cik.sc_hiz_tile_fifo_size) | SC_EARLYZ_TILE_FIFO_SIZE(rdev->config.cik.sc_earlyz_tile_fifo_size))); WREG32(VGT_NUM_INSTANCES, 1); WREG32(CP_PERFMON_CNTL, 0); WREG32(SQ_CONFIG, 0); WREG32(PA_SC_FORCE_EOV_MAX_CNTS, (FORCE_EOV_MAX_CLK_CNT(4095) | FORCE_EOV_MAX_REZ_CNT(255))); WREG32(VGT_CACHE_INVALIDATION, CACHE_INVALIDATION(VC_AND_TC) | AUTO_INVLD_EN(ES_AND_GS_AUTO)); WREG32(VGT_GS_VERTEX_REUSE, 16); WREG32(PA_SC_LINE_STIPPLE_STATE, 0); tmp = RREG32(HDP_MISC_CNTL); tmp |= HDP_FLUSH_INVALIDATE_CACHE; WREG32(HDP_MISC_CNTL, tmp); hdp_host_path_cntl = RREG32(HDP_HOST_PATH_CNTL); WREG32(HDP_HOST_PATH_CNTL, hdp_host_path_cntl); WREG32(PA_CL_ENHANCE, CLIP_VTX_REORDER_ENA | NUM_CLIP_SEQ(3)); WREG32(PA_SC_ENHANCE, ENABLE_PA_SC_OUT_OF_ORDER); udelay(50); } /* * GPU scratch registers helpers function. */ /** * cik_scratch_init - setup driver info for CP scratch regs * * @rdev: radeon_device pointer * * Set up the number and offset of the CP scratch registers. * NOTE: use of CP scratch registers is a legacy inferface and * is not used by default on newer asics (r6xx+). On newer asics, * memory buffers are used for fences rather than scratch regs. */ static void cik_scratch_init(struct radeon_device *rdev) { int i; rdev->scratch.num_reg = 7; rdev->scratch.reg_base = SCRATCH_REG0; for (i = 0; i < rdev->scratch.num_reg; i++) { rdev->scratch.free[i] = true; rdev->scratch.reg[i] = rdev->scratch.reg_base + (i * 4); } } /** * cik_ring_test - basic gfx ring test * * @rdev: radeon_device pointer * @ring: radeon_ring structure holding ring information * * Allocate a scratch register and write to it using the gfx ring (CIK). * Provides a basic gfx ring test to verify that the ring is working. * Used by cik_cp_gfx_resume(); * Returns 0 on success, error on failure. */ int cik_ring_test(struct radeon_device *rdev, struct radeon_ring *ring) { uint32_t scratch; uint32_t tmp = 0; unsigned i; int r; r = radeon_scratch_get(rdev, &scratch); if (r) { DRM_ERROR("radeon: cp failed to get scratch reg (%d).\n", r); return r; } WREG32(scratch, 0xCAFEDEAD); r = radeon_ring_lock(rdev, ring, 3); if (r) { DRM_ERROR("radeon: cp failed to lock ring %d (%d).\n", ring->idx, r); radeon_scratch_free(rdev, scratch); return r; } radeon_ring_write(ring, PACKET3(PACKET3_SET_UCONFIG_REG, 1)); radeon_ring_write(ring, ((scratch - PACKET3_SET_UCONFIG_REG_START) >> 2)); radeon_ring_write(ring, 0xDEADBEEF); radeon_ring_unlock_commit(rdev, ring); for (i = 0; i < rdev->usec_timeout; i++) { tmp = RREG32(scratch); if (tmp == 0xDEADBEEF) break; DRM_UDELAY(1); } if (i < rdev->usec_timeout) { DRM_INFO("ring test on %d succeeded in %d usecs\n", ring->idx, i); } else { DRM_ERROR("radeon: ring %d test failed (scratch(0x%04X)=0x%08X)\n", ring->idx, scratch, tmp); r = -EINVAL; } radeon_scratch_free(rdev, scratch); return r; } /** * cik_fence_ring_emit - emit a fence on the gfx ring * * @rdev: radeon_device pointer * @fence: radeon fence object * * Emits a fence sequnce number on the gfx ring and flushes * GPU caches. */ void cik_fence_ring_emit(struct radeon_device *rdev, struct radeon_fence *fence) { struct radeon_ring *ring = &rdev->ring[fence->ring]; u64 addr = rdev->fence_drv[fence->ring].gpu_addr; /* EVENT_WRITE_EOP - flush caches, send int */ radeon_ring_write(ring, PACKET3(PACKET3_EVENT_WRITE_EOP, 4)); radeon_ring_write(ring, (EOP_TCL1_ACTION_EN | EOP_TC_ACTION_EN | EVENT_TYPE(CACHE_FLUSH_AND_INV_TS_EVENT) | EVENT_INDEX(5))); radeon_ring_write(ring, addr & 0xfffffffc); radeon_ring_write(ring, (upper_32_bits(addr) & 0xffff) | DATA_SEL(1) | INT_SEL(2)); radeon_ring_write(ring, fence->seq); radeon_ring_write(ring, 0); /* HDP flush */ /* We should be using the new WAIT_REG_MEM special op packet here * but it causes the CP to hang */ radeon_ring_write(ring, PACKET3(PACKET3_WRITE_DATA, 3)); radeon_ring_write(ring, (WRITE_DATA_ENGINE_SEL(0) | WRITE_DATA_DST_SEL(0))); radeon_ring_write(ring, HDP_MEM_COHERENCY_FLUSH_CNTL >> 2); radeon_ring_write(ring, 0); radeon_ring_write(ring, 0); } void cik_semaphore_ring_emit(struct radeon_device *rdev, struct radeon_ring *ring, struct radeon_semaphore *semaphore, bool emit_wait) { uint64_t addr = semaphore->gpu_addr; unsigned sel = emit_wait ? PACKET3_SEM_SEL_WAIT : PACKET3_SEM_SEL_SIGNAL; radeon_ring_write(ring, PACKET3(PACKET3_MEM_SEMAPHORE, 1)); radeon_ring_write(ring, addr & 0xffffffff); radeon_ring_write(ring, (upper_32_bits(addr) & 0xffff) | sel); } /* * IB stuff */ /** * cik_ring_ib_execute - emit an IB (Indirect Buffer) on the gfx ring * * @rdev: radeon_device pointer * @ib: radeon indirect buffer object * * Emits an DE (drawing engine) or CE (constant engine) IB * on the gfx ring. IBs are usually generated by userspace * acceleration drivers and submitted to the kernel for * sheduling on the ring. This function schedules the IB * on the gfx ring for execution by the GPU. */ void cik_ring_ib_execute(struct radeon_device *rdev, struct radeon_ib *ib) { struct radeon_ring *ring = &rdev->ring[ib->ring]; u32 header, control = INDIRECT_BUFFER_VALID; if (ib->is_const_ib) { /* set switch buffer packet before const IB */ radeon_ring_write(ring, PACKET3(PACKET3_SWITCH_BUFFER, 0)); radeon_ring_write(ring, 0); header = PACKET3(PACKET3_INDIRECT_BUFFER_CONST, 2); } else { u32 next_rptr; if (ring->rptr_save_reg) { next_rptr = ring->wptr + 3 + 4; radeon_ring_write(ring, PACKET3(PACKET3_SET_UCONFIG_REG, 1)); radeon_ring_write(ring, ((ring->rptr_save_reg - PACKET3_SET_UCONFIG_REG_START) >> 2)); radeon_ring_write(ring, next_rptr); } else if (rdev->wb.enabled) { next_rptr = ring->wptr + 5 + 4; radeon_ring_write(ring, PACKET3(PACKET3_WRITE_DATA, 3)); radeon_ring_write(ring, WRITE_DATA_DST_SEL(1)); radeon_ring_write(ring, ring->next_rptr_gpu_addr & 0xfffffffc); radeon_ring_write(ring, upper_32_bits(ring->next_rptr_gpu_addr) & 0xffffffff); radeon_ring_write(ring, next_rptr); } header = PACKET3(PACKET3_INDIRECT_BUFFER, 2); } control |= ib->length_dw | (ib->vm ? (ib->vm->id << 24) : 0); radeon_ring_write(ring, header); radeon_ring_write(ring, #ifdef __BIG_ENDIAN (2 << 0) | #endif (ib->gpu_addr & 0xFFFFFFFC)); radeon_ring_write(ring, upper_32_bits(ib->gpu_addr) & 0xFFFF); radeon_ring_write(ring, control); } /** * cik_ib_test - basic gfx ring IB test * * @rdev: radeon_device pointer * @ring: radeon_ring structure holding ring information * * Allocate an IB and execute it on the gfx ring (CIK). * Provides a basic gfx ring test to verify that IBs are working. * Returns 0 on success, error on failure. */ int cik_ib_test(struct radeon_device *rdev, struct radeon_ring *ring) { struct radeon_ib ib; uint32_t scratch; uint32_t tmp = 0; unsigned i; int r; r = radeon_scratch_get(rdev, &scratch); if (r) { DRM_ERROR("radeon: failed to get scratch reg (%d).\n", r); return r; } WREG32(scratch, 0xCAFEDEAD); r = radeon_ib_get(rdev, ring->idx, &ib, NULL, 256); if (r) { DRM_ERROR("radeon: failed to get ib (%d).\n", r); return r; } ib.ptr[0] = PACKET3(PACKET3_SET_UCONFIG_REG, 1); ib.ptr[1] = ((scratch - PACKET3_SET_UCONFIG_REG_START) >> 2); ib.ptr[2] = 0xDEADBEEF; ib.length_dw = 3; r = radeon_ib_schedule(rdev, &ib, NULL); if (r) { radeon_scratch_free(rdev, scratch); radeon_ib_free(rdev, &ib); DRM_ERROR("radeon: failed to schedule ib (%d).\n", r); return r; } r = radeon_fence_wait(ib.fence, false); if (r) { DRM_ERROR("radeon: fence wait failed (%d).\n", r); return r; } for (i = 0; i < rdev->usec_timeout; i++) { tmp = RREG32(scratch); if (tmp == 0xDEADBEEF) break; DRM_UDELAY(1); } if (i < rdev->usec_timeout) { DRM_INFO("ib test on ring %d succeeded in %u usecs\n", ib.fence->ring, i); } else { DRM_ERROR("radeon: ib test failed (scratch(0x%04X)=0x%08X)\n", scratch, tmp); r = -EINVAL; } radeon_scratch_free(rdev, scratch); radeon_ib_free(rdev, &ib); return r; } /* * CP. * On CIK, gfx and compute now have independant command processors. * * GFX * Gfx consists of a single ring and can process both gfx jobs and * compute jobs. The gfx CP consists of three microengines (ME): * PFP - Pre-Fetch Parser * ME - Micro Engine * CE - Constant Engine * The PFP and ME make up what is considered the Drawing Engine (DE). * The CE is an asynchronous engine used for updating buffer desciptors * used by the DE so that they can be loaded into cache in parallel * while the DE is processing state update packets. * * Compute * The compute CP consists of two microengines (ME): * MEC1 - Compute MicroEngine 1 * MEC2 - Compute MicroEngine 2 * Each MEC supports 4 compute pipes and each pipe supports 8 queues. * The queues are exposed to userspace and are programmed directly * by the compute runtime. */ /** * cik_cp_gfx_enable - enable/disable the gfx CP MEs * * @rdev: radeon_device pointer * @enable: enable or disable the MEs * * Halts or unhalts the gfx MEs. */ static void cik_cp_gfx_enable(struct radeon_device *rdev, bool enable) { if (enable) WREG32(CP_ME_CNTL, 0); else { WREG32(CP_ME_CNTL, (CP_ME_HALT | CP_PFP_HALT | CP_CE_HALT)); rdev->ring[RADEON_RING_TYPE_GFX_INDEX].ready = false; } udelay(50); } /** * cik_cp_gfx_load_microcode - load the gfx CP ME ucode * * @rdev: radeon_device pointer * * Loads the gfx PFP, ME, and CE ucode. * Returns 0 for success, -EINVAL if the ucode is not available. */ static int cik_cp_gfx_load_microcode(struct radeon_device *rdev) { const __be32 *fw_data; int i; if (!rdev->me_fw || !rdev->pfp_fw || !rdev->ce_fw) return -EINVAL; cik_cp_gfx_enable(rdev, false); /* PFP */ fw_data = (const __be32 *)rdev->pfp_fw->data; WREG32(CP_PFP_UCODE_ADDR, 0); for (i = 0; i < CIK_PFP_UCODE_SIZE; i++) WREG32(CP_PFP_UCODE_DATA, be32_to_cpup(fw_data++)); WREG32(CP_PFP_UCODE_ADDR, 0); /* CE */ fw_data = (const __be32 *)rdev->ce_fw->data; WREG32(CP_CE_UCODE_ADDR, 0); for (i = 0; i < CIK_CE_UCODE_SIZE; i++) WREG32(CP_CE_UCODE_DATA, be32_to_cpup(fw_data++)); WREG32(CP_CE_UCODE_ADDR, 0); /* ME */ fw_data = (const __be32 *)rdev->me_fw->data; WREG32(CP_ME_RAM_WADDR, 0); for (i = 0; i < CIK_ME_UCODE_SIZE; i++) WREG32(CP_ME_RAM_DATA, be32_to_cpup(fw_data++)); WREG32(CP_ME_RAM_WADDR, 0); WREG32(CP_PFP_UCODE_ADDR, 0); WREG32(CP_CE_UCODE_ADDR, 0); WREG32(CP_ME_RAM_WADDR, 0); WREG32(CP_ME_RAM_RADDR, 0); return 0; } /** * cik_cp_gfx_start - start the gfx ring * * @rdev: radeon_device pointer * * Enables the ring and loads the clear state context and other * packets required to init the ring. * Returns 0 for success, error for failure. */ static int cik_cp_gfx_start(struct radeon_device *rdev) { struct radeon_ring *ring = &rdev->ring[RADEON_RING_TYPE_GFX_INDEX]; int r, i; /* init the CP */ WREG32(CP_MAX_CONTEXT, rdev->config.cik.max_hw_contexts - 1); WREG32(CP_ENDIAN_SWAP, 0); WREG32(CP_DEVICE_ID, 1); cik_cp_gfx_enable(rdev, true); r = radeon_ring_lock(rdev, ring, cik_default_size + 17); if (r) { DRM_ERROR("radeon: cp failed to lock ring (%d).\n", r); return r; } /* init the CE partitions. CE only used for gfx on CIK */ radeon_ring_write(ring, PACKET3(PACKET3_SET_BASE, 2)); radeon_ring_write(ring, PACKET3_BASE_INDEX(CE_PARTITION_BASE)); radeon_ring_write(ring, 0xc000); radeon_ring_write(ring, 0xc000); /* setup clear context state */ radeon_ring_write(ring, PACKET3(PACKET3_PREAMBLE_CNTL, 0)); radeon_ring_write(ring, PACKET3_PREAMBLE_BEGIN_CLEAR_STATE); radeon_ring_write(ring, PACKET3(PACKET3_CONTEXT_CONTROL, 1)); radeon_ring_write(ring, 0x80000000); radeon_ring_write(ring, 0x80000000); for (i = 0; i < cik_default_size; i++) radeon_ring_write(ring, cik_default_state[i]); radeon_ring_write(ring, PACKET3(PACKET3_PREAMBLE_CNTL, 0)); radeon_ring_write(ring, PACKET3_PREAMBLE_END_CLEAR_STATE); /* set clear context state */ radeon_ring_write(ring, PACKET3(PACKET3_CLEAR_STATE, 0)); radeon_ring_write(ring, 0); radeon_ring_write(ring, PACKET3(PACKET3_SET_CONTEXT_REG, 2)); radeon_ring_write(ring, 0x00000316); radeon_ring_write(ring, 0x0000000e); /* VGT_VERTEX_REUSE_BLOCK_CNTL */ radeon_ring_write(ring, 0x00000010); /* VGT_OUT_DEALLOC_CNTL */ radeon_ring_unlock_commit(rdev, ring); return 0; } /** * cik_cp_gfx_fini - stop the gfx ring * * @rdev: radeon_device pointer * * Stop the gfx ring and tear down the driver ring * info. */ static void cik_cp_gfx_fini(struct radeon_device *rdev) { cik_cp_gfx_enable(rdev, false); radeon_ring_fini(rdev, &rdev->ring[RADEON_RING_TYPE_GFX_INDEX]); } /** * cik_cp_gfx_resume - setup the gfx ring buffer registers * * @rdev: radeon_device pointer * * Program the location and size of the gfx ring buffer * and test it to make sure it's working. * Returns 0 for success, error for failure. */ static int cik_cp_gfx_resume(struct radeon_device *rdev) { struct radeon_ring *ring; u32 tmp; u32 rb_bufsz; u64 rb_addr; int r; WREG32(CP_SEM_WAIT_TIMER, 0x0); WREG32(CP_SEM_INCOMPLETE_TIMER_CNTL, 0x0); /* Set the write pointer delay */ WREG32(CP_RB_WPTR_DELAY, 0); /* set the RB to use vmid 0 */ WREG32(CP_RB_VMID, 0); WREG32(SCRATCH_ADDR, ((rdev->wb.gpu_addr + RADEON_WB_SCRATCH_OFFSET) >> 8) & 0xFFFFFFFF); /* ring 0 - compute and gfx */ /* Set ring buffer size */ ring = &rdev->ring[RADEON_RING_TYPE_GFX_INDEX]; rb_bufsz = drm_order(ring->ring_size / 8); tmp = (drm_order(RADEON_GPU_PAGE_SIZE/8) << 8) | rb_bufsz; #ifdef __BIG_ENDIAN tmp |= BUF_SWAP_32BIT; #endif WREG32(CP_RB0_CNTL, tmp); /* Initialize the ring buffer's read and write pointers */ WREG32(CP_RB0_CNTL, tmp | RB_RPTR_WR_ENA); ring->wptr = 0; WREG32(CP_RB0_WPTR, ring->wptr); /* set the wb address wether it's enabled or not */ WREG32(CP_RB0_RPTR_ADDR, (rdev->wb.gpu_addr + RADEON_WB_CP_RPTR_OFFSET) & 0xFFFFFFFC); WREG32(CP_RB0_RPTR_ADDR_HI, upper_32_bits(rdev->wb.gpu_addr + RADEON_WB_CP_RPTR_OFFSET) & 0xFF); /* scratch register shadowing is no longer supported */ WREG32(SCRATCH_UMSK, 0); if (!rdev->wb.enabled) tmp |= RB_NO_UPDATE; mdelay(1); WREG32(CP_RB0_CNTL, tmp); rb_addr = ring->gpu_addr >> 8; WREG32(CP_RB0_BASE, rb_addr); WREG32(CP_RB0_BASE_HI, upper_32_bits(rb_addr)); ring->rptr = RREG32(CP_RB0_RPTR); /* start the ring */ cik_cp_gfx_start(rdev); rdev->ring[RADEON_RING_TYPE_GFX_INDEX].ready = true; r = radeon_ring_test(rdev, RADEON_RING_TYPE_GFX_INDEX, &rdev->ring[RADEON_RING_TYPE_GFX_INDEX]); if (r) { rdev->ring[RADEON_RING_TYPE_GFX_INDEX].ready = false; return r; } return 0; } /** * cik_cp_compute_enable - enable/disable the compute CP MEs * * @rdev: radeon_device pointer * @enable: enable or disable the MEs * * Halts or unhalts the compute MEs. */ static void cik_cp_compute_enable(struct radeon_device *rdev, bool enable) { if (enable) WREG32(CP_MEC_CNTL, 0); else WREG32(CP_MEC_CNTL, (MEC_ME1_HALT | MEC_ME2_HALT)); udelay(50); } /** * cik_cp_compute_load_microcode - load the compute CP ME ucode * * @rdev: radeon_device pointer * * Loads the compute MEC1&2 ucode. * Returns 0 for success, -EINVAL if the ucode is not available. */ static int cik_cp_compute_load_microcode(struct radeon_device *rdev) { const __be32 *fw_data; int i; if (!rdev->mec_fw) return -EINVAL; cik_cp_compute_enable(rdev, false); /* MEC1 */ fw_data = (const __be32 *)rdev->mec_fw->data; WREG32(CP_MEC_ME1_UCODE_ADDR, 0); for (i = 0; i < CIK_MEC_UCODE_SIZE; i++) WREG32(CP_MEC_ME1_UCODE_DATA, be32_to_cpup(fw_data++)); WREG32(CP_MEC_ME1_UCODE_ADDR, 0); if (rdev->family == CHIP_KAVERI) { /* MEC2 */ fw_data = (const __be32 *)rdev->mec_fw->data; WREG32(CP_MEC_ME2_UCODE_ADDR, 0); for (i = 0; i < CIK_MEC_UCODE_SIZE; i++) WREG32(CP_MEC_ME2_UCODE_DATA, be32_to_cpup(fw_data++)); WREG32(CP_MEC_ME2_UCODE_ADDR, 0); } return 0; } /** * cik_cp_compute_start - start the compute queues * * @rdev: radeon_device pointer * * Enable the compute queues. * Returns 0 for success, error for failure. */ static int cik_cp_compute_start(struct radeon_device *rdev) { //todo return 0; } /** * cik_cp_compute_fini - stop the compute queues * * @rdev: radeon_device pointer * * Stop the compute queues and tear down the driver queue * info. */ static void cik_cp_compute_fini(struct radeon_device *rdev) { cik_cp_compute_enable(rdev, false); //todo } /** * cik_cp_compute_resume - setup the compute queue registers * * @rdev: radeon_device pointer * * Program the compute queues and test them to make sure they * are working. * Returns 0 for success, error for failure. */ static int cik_cp_compute_resume(struct radeon_device *rdev) { int r; //todo r = cik_cp_compute_start(rdev); if (r) return r; return 0; } /* XXX temporary wrappers to handle both compute and gfx */ /* XXX */ static void cik_cp_enable(struct radeon_device *rdev, bool enable) { cik_cp_gfx_enable(rdev, enable); cik_cp_compute_enable(rdev, enable); } /* XXX */ static int cik_cp_load_microcode(struct radeon_device *rdev) { int r; r = cik_cp_gfx_load_microcode(rdev); if (r) return r; r = cik_cp_compute_load_microcode(rdev); if (r) return r; return 0; } /* XXX */ static void cik_cp_fini(struct radeon_device *rdev) { cik_cp_gfx_fini(rdev); cik_cp_compute_fini(rdev); } /* XXX */ static int cik_cp_resume(struct radeon_device *rdev) { int r; /* Reset all cp blocks */ WREG32(GRBM_SOFT_RESET, SOFT_RESET_CP); RREG32(GRBM_SOFT_RESET); mdelay(15); WREG32(GRBM_SOFT_RESET, 0); RREG32(GRBM_SOFT_RESET); r = cik_cp_load_microcode(rdev); if (r) return r; r = cik_cp_gfx_resume(rdev); if (r) return r; r = cik_cp_compute_resume(rdev); if (r) return r; return 0; } /* * sDMA - System DMA * Starting with CIK, the GPU has new asynchronous * DMA engines. These engines are used for compute * and gfx. There are two DMA engines (SDMA0, SDMA1) * and each one supports 1 ring buffer used for gfx * and 2 queues used for compute. * * The programming model is very similar to the CP * (ring buffer, IBs, etc.), but sDMA has it's own * packet format that is different from the PM4 format * used by the CP. sDMA supports copying data, writing * embedded data, solid fills, and a number of other * things. It also has support for tiling/detiling of * buffers. */ /** * cik_sdma_ring_ib_execute - Schedule an IB on the DMA engine * * @rdev: radeon_device pointer * @ib: IB object to schedule * * Schedule an IB in the DMA ring (CIK). */ void cik_sdma_ring_ib_execute(struct radeon_device *rdev, struct radeon_ib *ib) { struct radeon_ring *ring = &rdev->ring[ib->ring]; u32 extra_bits = (ib->vm ? ib->vm->id : 0) & 0xf; if (rdev->wb.enabled) { u32 next_rptr = ring->wptr + 5; while ((next_rptr & 7) != 4) next_rptr++; next_rptr += 4; radeon_ring_write(ring, SDMA_PACKET(SDMA_OPCODE_WRITE, SDMA_WRITE_SUB_OPCODE_LINEAR, 0)); radeon_ring_write(ring, ring->next_rptr_gpu_addr & 0xfffffffc); radeon_ring_write(ring, upper_32_bits(ring->next_rptr_gpu_addr) & 0xffffffff); radeon_ring_write(ring, 1); /* number of DWs to follow */ radeon_ring_write(ring, next_rptr); } /* IB packet must end on a 8 DW boundary */ while ((ring->wptr & 7) != 4) radeon_ring_write(ring, SDMA_PACKET(SDMA_OPCODE_NOP, 0, 0)); radeon_ring_write(ring, SDMA_PACKET(SDMA_OPCODE_INDIRECT_BUFFER, 0, extra_bits)); radeon_ring_write(ring, ib->gpu_addr & 0xffffffe0); /* base must be 32 byte aligned */ radeon_ring_write(ring, upper_32_bits(ib->gpu_addr) & 0xffffffff); radeon_ring_write(ring, ib->length_dw); } /** * cik_sdma_fence_ring_emit - emit a fence on the DMA ring * * @rdev: radeon_device pointer * @fence: radeon fence object * * Add a DMA fence packet to the ring to write * the fence seq number and DMA trap packet to generate * an interrupt if needed (CIK). */ void cik_sdma_fence_ring_emit(struct radeon_device *rdev, struct radeon_fence *fence) { struct radeon_ring *ring = &rdev->ring[fence->ring]; u64 addr = rdev->fence_drv[fence->ring].gpu_addr; u32 extra_bits = (SDMA_POLL_REG_MEM_EXTRA_OP(1) | SDMA_POLL_REG_MEM_EXTRA_FUNC(3)); /* == */ u32 ref_and_mask; if (fence->ring == R600_RING_TYPE_DMA_INDEX) ref_and_mask = SDMA0; else ref_and_mask = SDMA1; /* write the fence */ radeon_ring_write(ring, SDMA_PACKET(SDMA_OPCODE_FENCE, 0, 0)); radeon_ring_write(ring, addr & 0xffffffff); radeon_ring_write(ring, upper_32_bits(addr) & 0xffffffff); radeon_ring_write(ring, fence->seq); /* generate an interrupt */ radeon_ring_write(ring, SDMA_PACKET(SDMA_OPCODE_TRAP, 0, 0)); /* flush HDP */ radeon_ring_write(ring, SDMA_PACKET(SDMA_OPCODE_POLL_REG_MEM, 0, extra_bits)); radeon_ring_write(ring, GPU_HDP_FLUSH_DONE); radeon_ring_write(ring, GPU_HDP_FLUSH_REQ); radeon_ring_write(ring, ref_and_mask); /* REFERENCE */ radeon_ring_write(ring, ref_and_mask); /* MASK */ radeon_ring_write(ring, (4 << 16) | 10); /* RETRY_COUNT, POLL_INTERVAL */ } /** * cik_sdma_semaphore_ring_emit - emit a semaphore on the dma ring * * @rdev: radeon_device pointer * @ring: radeon_ring structure holding ring information * @semaphore: radeon semaphore object * @emit_wait: wait or signal semaphore * * Add a DMA semaphore packet to the ring wait on or signal * other rings (CIK). */ void cik_sdma_semaphore_ring_emit(struct radeon_device *rdev, struct radeon_ring *ring, struct radeon_semaphore *semaphore, bool emit_wait) { u64 addr = semaphore->gpu_addr; u32 extra_bits = emit_wait ? 0 : SDMA_SEMAPHORE_EXTRA_S; radeon_ring_write(ring, SDMA_PACKET(SDMA_OPCODE_SEMAPHORE, 0, extra_bits)); radeon_ring_write(ring, addr & 0xfffffff8); radeon_ring_write(ring, upper_32_bits(addr) & 0xffffffff); } /** * cik_sdma_gfx_stop - stop the gfx async dma engines * * @rdev: radeon_device pointer * * Stop the gfx async dma ring buffers (CIK). */ static void cik_sdma_gfx_stop(struct radeon_device *rdev) { u32 rb_cntl, reg_offset; int i; radeon_ttm_set_active_vram_size(rdev, rdev->mc.visible_vram_size); for (i = 0; i < 2; i++) { if (i == 0) reg_offset = SDMA0_REGISTER_OFFSET; else reg_offset = SDMA1_REGISTER_OFFSET; rb_cntl = RREG32(SDMA0_GFX_RB_CNTL + reg_offset); rb_cntl &= ~SDMA_RB_ENABLE; WREG32(SDMA0_GFX_RB_CNTL + reg_offset, rb_cntl); WREG32(SDMA0_GFX_IB_CNTL + reg_offset, 0); } } /** * cik_sdma_rlc_stop - stop the compute async dma engines * * @rdev: radeon_device pointer * * Stop the compute async dma queues (CIK). */ static void cik_sdma_rlc_stop(struct radeon_device *rdev) { /* XXX todo */ } /** * cik_sdma_enable - stop the async dma engines * * @rdev: radeon_device pointer * @enable: enable/disable the DMA MEs. * * Halt or unhalt the async dma engines (CIK). */ static void cik_sdma_enable(struct radeon_device *rdev, bool enable) { u32 me_cntl, reg_offset; int i; for (i = 0; i < 2; i++) { if (i == 0) reg_offset = SDMA0_REGISTER_OFFSET; else reg_offset = SDMA1_REGISTER_OFFSET; me_cntl = RREG32(SDMA0_ME_CNTL + reg_offset); if (enable) me_cntl &= ~SDMA_HALT; else me_cntl |= SDMA_HALT; WREG32(SDMA0_ME_CNTL + reg_offset, me_cntl); } } /** * cik_sdma_gfx_resume - setup and start the async dma engines * * @rdev: radeon_device pointer * * Set up the gfx DMA ring buffers and enable them (CIK). * Returns 0 for success, error for failure. */ static int cik_sdma_gfx_resume(struct radeon_device *rdev) { struct radeon_ring *ring; u32 rb_cntl, ib_cntl; u32 rb_bufsz; u32 reg_offset, wb_offset; int i, r; for (i = 0; i < 2; i++) { if (i == 0) { ring = &rdev->ring[R600_RING_TYPE_DMA_INDEX]; reg_offset = SDMA0_REGISTER_OFFSET; wb_offset = R600_WB_DMA_RPTR_OFFSET; } else { ring = &rdev->ring[CAYMAN_RING_TYPE_DMA1_INDEX]; reg_offset = SDMA1_REGISTER_OFFSET; wb_offset = CAYMAN_WB_DMA1_RPTR_OFFSET; } WREG32(SDMA0_SEM_INCOMPLETE_TIMER_CNTL + reg_offset, 0); WREG32(SDMA0_SEM_WAIT_FAIL_TIMER_CNTL + reg_offset, 0); /* Set ring buffer size in dwords */ rb_bufsz = drm_order(ring->ring_size / 4); rb_cntl = rb_bufsz << 1; #ifdef __BIG_ENDIAN rb_cntl |= SDMA_RB_SWAP_ENABLE | SDMA_RPTR_WRITEBACK_SWAP_ENABLE; #endif WREG32(SDMA0_GFX_RB_CNTL + reg_offset, rb_cntl); /* Initialize the ring buffer's read and write pointers */ WREG32(SDMA0_GFX_RB_RPTR + reg_offset, 0); WREG32(SDMA0_GFX_RB_WPTR + reg_offset, 0); /* set the wb address whether it's enabled or not */ WREG32(SDMA0_GFX_RB_RPTR_ADDR_HI + reg_offset, upper_32_bits(rdev->wb.gpu_addr + wb_offset) & 0xFFFFFFFF); WREG32(SDMA0_GFX_RB_RPTR_ADDR_LO + reg_offset, ((rdev->wb.gpu_addr + wb_offset) & 0xFFFFFFFC)); if (rdev->wb.enabled) rb_cntl |= SDMA_RPTR_WRITEBACK_ENABLE; WREG32(SDMA0_GFX_RB_BASE + reg_offset, ring->gpu_addr >> 8); WREG32(SDMA0_GFX_RB_BASE_HI + reg_offset, ring->gpu_addr >> 40); ring->wptr = 0; WREG32(SDMA0_GFX_RB_WPTR + reg_offset, ring->wptr << 2); ring->rptr = RREG32(SDMA0_GFX_RB_RPTR + reg_offset) >> 2; /* enable DMA RB */ WREG32(SDMA0_GFX_RB_CNTL + reg_offset, rb_cntl | SDMA_RB_ENABLE); ib_cntl = SDMA_IB_ENABLE; #ifdef __BIG_ENDIAN ib_cntl |= SDMA_IB_SWAP_ENABLE; #endif /* enable DMA IBs */ WREG32(SDMA0_GFX_IB_CNTL + reg_offset, ib_cntl); ring->ready = true; r = radeon_ring_test(rdev, ring->idx, ring); if (r) { ring->ready = false; return r; } } radeon_ttm_set_active_vram_size(rdev, rdev->mc.real_vram_size); return 0; } /** * cik_sdma_rlc_resume - setup and start the async dma engines * * @rdev: radeon_device pointer * * Set up the compute DMA queues and enable them (CIK). * Returns 0 for success, error for failure. */ static int cik_sdma_rlc_resume(struct radeon_device *rdev) { /* XXX todo */ return 0; } /** * cik_sdma_load_microcode - load the sDMA ME ucode * * @rdev: radeon_device pointer * * Loads the sDMA0/1 ucode. * Returns 0 for success, -EINVAL if the ucode is not available. */ static int cik_sdma_load_microcode(struct radeon_device *rdev) { const __be32 *fw_data; int i; if (!rdev->sdma_fw) return -EINVAL; /* stop the gfx rings and rlc compute queues */ cik_sdma_gfx_stop(rdev); cik_sdma_rlc_stop(rdev); /* halt the MEs */ cik_sdma_enable(rdev, false); /* sdma0 */ fw_data = (const __be32 *)rdev->sdma_fw->data; WREG32(SDMA0_UCODE_ADDR + SDMA0_REGISTER_OFFSET, 0); for (i = 0; i < CIK_SDMA_UCODE_SIZE; i++) WREG32(SDMA0_UCODE_DATA + SDMA0_REGISTER_OFFSET, be32_to_cpup(fw_data++)); WREG32(SDMA0_UCODE_DATA + SDMA0_REGISTER_OFFSET, CIK_SDMA_UCODE_VERSION); /* sdma1 */ fw_data = (const __be32 *)rdev->sdma_fw->data; WREG32(SDMA0_UCODE_ADDR + SDMA1_REGISTER_OFFSET, 0); for (i = 0; i < CIK_SDMA_UCODE_SIZE; i++) WREG32(SDMA0_UCODE_DATA + SDMA1_REGISTER_OFFSET, be32_to_cpup(fw_data++)); WREG32(SDMA0_UCODE_DATA + SDMA1_REGISTER_OFFSET, CIK_SDMA_UCODE_VERSION); WREG32(SDMA0_UCODE_ADDR + SDMA0_REGISTER_OFFSET, 0); WREG32(SDMA0_UCODE_ADDR + SDMA1_REGISTER_OFFSET, 0); return 0; } /** * cik_sdma_resume - setup and start the async dma engines * * @rdev: radeon_device pointer * * Set up the DMA engines and enable them (CIK). * Returns 0 for success, error for failure. */ static int cik_sdma_resume(struct radeon_device *rdev) { int r; /* Reset dma */ WREG32(SRBM_SOFT_RESET, SOFT_RESET_SDMA | SOFT_RESET_SDMA1); RREG32(SRBM_SOFT_RESET); udelay(50); WREG32(SRBM_SOFT_RESET, 0); RREG32(SRBM_SOFT_RESET); r = cik_sdma_load_microcode(rdev); if (r) return r; /* unhalt the MEs */ cik_sdma_enable(rdev, true); /* start the gfx rings and rlc compute queues */ r = cik_sdma_gfx_resume(rdev); if (r) return r; r = cik_sdma_rlc_resume(rdev); if (r) return r; return 0; } /** * cik_sdma_fini - tear down the async dma engines * * @rdev: radeon_device pointer * * Stop the async dma engines and free the rings (CIK). */ static void cik_sdma_fini(struct radeon_device *rdev) { /* stop the gfx rings and rlc compute queues */ cik_sdma_gfx_stop(rdev); cik_sdma_rlc_stop(rdev); /* halt the MEs */ cik_sdma_enable(rdev, false); radeon_ring_fini(rdev, &rdev->ring[R600_RING_TYPE_DMA_INDEX]); radeon_ring_fini(rdev, &rdev->ring[CAYMAN_RING_TYPE_DMA1_INDEX]); /* XXX - compute dma queue tear down */ } /** * cik_copy_dma - copy pages using the DMA engine * * @rdev: radeon_device pointer * @src_offset: src GPU address * @dst_offset: dst GPU address * @num_gpu_pages: number of GPU pages to xfer * @fence: radeon fence object * * Copy GPU paging using the DMA engine (CIK). * Used by the radeon ttm implementation to move pages if * registered as the asic copy callback. */ int cik_copy_dma(struct radeon_device *rdev, uint64_t src_offset, uint64_t dst_offset, unsigned num_gpu_pages, struct radeon_fence **fence) { struct radeon_semaphore *sem = NULL; int ring_index = rdev->asic->copy.dma_ring_index; struct radeon_ring *ring = &rdev->ring[ring_index]; u32 size_in_bytes, cur_size_in_bytes; int i, num_loops; int r = 0; r = radeon_semaphore_create(rdev, &sem); if (r) { DRM_ERROR("radeon: moving bo (%d).\n", r); return r; } size_in_bytes = (num_gpu_pages << RADEON_GPU_PAGE_SHIFT); num_loops = DIV_ROUND_UP(size_in_bytes, 0x1fffff); r = radeon_ring_lock(rdev, ring, num_loops * 7 + 14); if (r) { DRM_ERROR("radeon: moving bo (%d).\n", r); radeon_semaphore_free(rdev, &sem, NULL); return r; } if (radeon_fence_need_sync(*fence, ring->idx)) { radeon_semaphore_sync_rings(rdev, sem, (*fence)->ring, ring->idx); radeon_fence_note_sync(*fence, ring->idx); } else { radeon_semaphore_free(rdev, &sem, NULL); } for (i = 0; i < num_loops; i++) { cur_size_in_bytes = size_in_bytes; if (cur_size_in_bytes > 0x1fffff) cur_size_in_bytes = 0x1fffff; size_in_bytes -= cur_size_in_bytes; radeon_ring_write(ring, SDMA_PACKET(SDMA_OPCODE_COPY, SDMA_COPY_SUB_OPCODE_LINEAR, 0)); radeon_ring_write(ring, cur_size_in_bytes); radeon_ring_write(ring, 0); /* src/dst endian swap */ radeon_ring_write(ring, src_offset & 0xffffffff); radeon_ring_write(ring, upper_32_bits(src_offset) & 0xffffffff); radeon_ring_write(ring, dst_offset & 0xfffffffc); radeon_ring_write(ring, upper_32_bits(dst_offset) & 0xffffffff); src_offset += cur_size_in_bytes; dst_offset += cur_size_in_bytes; } r = radeon_fence_emit(rdev, fence, ring->idx); if (r) { radeon_ring_unlock_undo(rdev, ring); return r; } radeon_ring_unlock_commit(rdev, ring); radeon_semaphore_free(rdev, &sem, *fence); return r; } /** * cik_sdma_ring_test - simple async dma engine test * * @rdev: radeon_device pointer * @ring: radeon_ring structure holding ring information * * Test the DMA engine by writing using it to write an * value to memory. (CIK). * Returns 0 for success, error for failure. */ int cik_sdma_ring_test(struct radeon_device *rdev, struct radeon_ring *ring) { unsigned i; int r; void __iomem *ptr = (void *)rdev->vram_scratch.ptr; u32 tmp; if (!ptr) { DRM_ERROR("invalid vram scratch pointer\n"); return -EINVAL; } tmp = 0xCAFEDEAD; writel(tmp, ptr); r = radeon_ring_lock(rdev, ring, 4); if (r) { DRM_ERROR("radeon: dma failed to lock ring %d (%d).\n", ring->idx, r); return r; } radeon_ring_write(ring, SDMA_PACKET(SDMA_OPCODE_WRITE, SDMA_WRITE_SUB_OPCODE_LINEAR, 0)); radeon_ring_write(ring, rdev->vram_scratch.gpu_addr & 0xfffffffc); radeon_ring_write(ring, upper_32_bits(rdev->vram_scratch.gpu_addr) & 0xffffffff); radeon_ring_write(ring, 1); /* number of DWs to follow */ radeon_ring_write(ring, 0xDEADBEEF); radeon_ring_unlock_commit(rdev, ring); for (i = 0; i < rdev->usec_timeout; i++) { tmp = readl(ptr); if (tmp == 0xDEADBEEF) break; DRM_UDELAY(1); } if (i < rdev->usec_timeout) { DRM_INFO("ring test on %d succeeded in %d usecs\n", ring->idx, i); } else { DRM_ERROR("radeon: ring %d test failed (0x%08X)\n", ring->idx, tmp); r = -EINVAL; } return r; } /** * cik_sdma_ib_test - test an IB on the DMA engine * * @rdev: radeon_device pointer * @ring: radeon_ring structure holding ring information * * Test a simple IB in the DMA ring (CIK). * Returns 0 on success, error on failure. */ int cik_sdma_ib_test(struct radeon_device *rdev, struct radeon_ring *ring) { struct radeon_ib ib; unsigned i; int r; void __iomem *ptr = (void *)rdev->vram_scratch.ptr; u32 tmp = 0; if (!ptr) { DRM_ERROR("invalid vram scratch pointer\n"); return -EINVAL; } tmp = 0xCAFEDEAD; writel(tmp, ptr); r = radeon_ib_get(rdev, ring->idx, &ib, NULL, 256); if (r) { DRM_ERROR("radeon: failed to get ib (%d).\n", r); return r; } ib.ptr[0] = SDMA_PACKET(SDMA_OPCODE_WRITE, SDMA_WRITE_SUB_OPCODE_LINEAR, 0); ib.ptr[1] = rdev->vram_scratch.gpu_addr & 0xfffffffc; ib.ptr[2] = upper_32_bits(rdev->vram_scratch.gpu_addr) & 0xffffffff; ib.ptr[3] = 1; ib.ptr[4] = 0xDEADBEEF; ib.length_dw = 5; r = radeon_ib_schedule(rdev, &ib, NULL); if (r) { radeon_ib_free(rdev, &ib); DRM_ERROR("radeon: failed to schedule ib (%d).\n", r); return r; } r = radeon_fence_wait(ib.fence, false); if (r) { DRM_ERROR("radeon: fence wait failed (%d).\n", r); return r; } for (i = 0; i < rdev->usec_timeout; i++) { tmp = readl(ptr); if (tmp == 0xDEADBEEF) break; DRM_UDELAY(1); } if (i < rdev->usec_timeout) { DRM_INFO("ib test on ring %d succeeded in %u usecs\n", ib.fence->ring, i); } else { DRM_ERROR("radeon: ib test failed (0x%08X)\n", tmp); r = -EINVAL; } radeon_ib_free(rdev, &ib); return r; } /** * cik_gpu_is_lockup - check if the 3D engine is locked up * * @rdev: radeon_device pointer * @ring: radeon_ring structure holding ring information * * Check if the 3D engine is locked up (CIK). * Returns true if the engine is locked, false if not. */ bool cik_gpu_is_lockup(struct radeon_device *rdev, struct radeon_ring *ring) { u32 srbm_status, srbm_status2; u32 grbm_status, grbm_status2; u32 grbm_status_se0, grbm_status_se1, grbm_status_se2, grbm_status_se3; srbm_status = RREG32(SRBM_STATUS); srbm_status2 = RREG32(SRBM_STATUS2); grbm_status = RREG32(GRBM_STATUS); grbm_status2 = RREG32(GRBM_STATUS2); grbm_status_se0 = RREG32(GRBM_STATUS_SE0); grbm_status_se1 = RREG32(GRBM_STATUS_SE1); grbm_status_se2 = RREG32(GRBM_STATUS_SE2); grbm_status_se3 = RREG32(GRBM_STATUS_SE3); if (!(grbm_status & GUI_ACTIVE)) { radeon_ring_lockup_update(ring); return false; } /* force CP activities */ radeon_ring_force_activity(rdev, ring); return radeon_ring_test_lockup(rdev, ring); } /** * cik_gfx_gpu_soft_reset - soft reset the 3D engine and CPG * * @rdev: radeon_device pointer * * Soft reset the GFX engine and CPG blocks (CIK). * XXX: deal with reseting RLC and CPF * Returns 0 for success. */ static int cik_gfx_gpu_soft_reset(struct radeon_device *rdev) { struct evergreen_mc_save save; u32 grbm_reset = 0; if (!(RREG32(GRBM_STATUS) & GUI_ACTIVE)) return 0; dev_info(rdev->dev, "GPU GFX softreset \n"); dev_info(rdev->dev, " GRBM_STATUS=0x%08X\n", RREG32(GRBM_STATUS)); dev_info(rdev->dev, " GRBM_STATUS2=0x%08X\n", RREG32(GRBM_STATUS2)); dev_info(rdev->dev, " GRBM_STATUS_SE0=0x%08X\n", RREG32(GRBM_STATUS_SE0)); dev_info(rdev->dev, " GRBM_STATUS_SE1=0x%08X\n", RREG32(GRBM_STATUS_SE1)); dev_info(rdev->dev, " GRBM_STATUS_SE2=0x%08X\n", RREG32(GRBM_STATUS_SE2)); dev_info(rdev->dev, " GRBM_STATUS_SE3=0x%08X\n", RREG32(GRBM_STATUS_SE3)); dev_info(rdev->dev, " SRBM_STATUS=0x%08X\n", RREG32(SRBM_STATUS)); dev_info(rdev->dev, " SRBM_STATUS2=0x%08X\n", RREG32(SRBM_STATUS2)); evergreen_mc_stop(rdev, &save); if (radeon_mc_wait_for_idle(rdev)) { dev_warn(rdev->dev, "Wait for MC idle timedout !\n"); } /* Disable CP parsing/prefetching */ WREG32(CP_ME_CNTL, CP_ME_HALT | CP_PFP_HALT | CP_CE_HALT); /* reset all the gfx block and all CPG blocks */ grbm_reset = SOFT_RESET_CPG | SOFT_RESET_GFX; dev_info(rdev->dev, " GRBM_SOFT_RESET=0x%08X\n", grbm_reset); WREG32(GRBM_SOFT_RESET, grbm_reset); (void)RREG32(GRBM_SOFT_RESET); udelay(50); WREG32(GRBM_SOFT_RESET, 0); (void)RREG32(GRBM_SOFT_RESET); /* Wait a little for things to settle down */ udelay(50); dev_info(rdev->dev, " GRBM_STATUS=0x%08X\n", RREG32(GRBM_STATUS)); dev_info(rdev->dev, " GRBM_STATUS2=0x%08X\n", RREG32(GRBM_STATUS2)); dev_info(rdev->dev, " GRBM_STATUS_SE0=0x%08X\n", RREG32(GRBM_STATUS_SE0)); dev_info(rdev->dev, " GRBM_STATUS_SE1=0x%08X\n", RREG32(GRBM_STATUS_SE1)); dev_info(rdev->dev, " GRBM_STATUS_SE2=0x%08X\n", RREG32(GRBM_STATUS_SE2)); dev_info(rdev->dev, " GRBM_STATUS_SE3=0x%08X\n", RREG32(GRBM_STATUS_SE3)); dev_info(rdev->dev, " SRBM_STATUS=0x%08X\n", RREG32(SRBM_STATUS)); dev_info(rdev->dev, " SRBM_STATUS2=0x%08X\n", RREG32(SRBM_STATUS2)); evergreen_mc_resume(rdev, &save); return 0; } /** * cik_compute_gpu_soft_reset - soft reset CPC * * @rdev: radeon_device pointer * * Soft reset the CPC blocks (CIK). * XXX: deal with reseting RLC and CPF * Returns 0 for success. */ static int cik_compute_gpu_soft_reset(struct radeon_device *rdev) { struct evergreen_mc_save save; u32 grbm_reset = 0; dev_info(rdev->dev, "GPU compute softreset \n"); dev_info(rdev->dev, " GRBM_STATUS=0x%08X\n", RREG32(GRBM_STATUS)); dev_info(rdev->dev, " GRBM_STATUS2=0x%08X\n", RREG32(GRBM_STATUS2)); dev_info(rdev->dev, " GRBM_STATUS_SE0=0x%08X\n", RREG32(GRBM_STATUS_SE0)); dev_info(rdev->dev, " GRBM_STATUS_SE1=0x%08X\n", RREG32(GRBM_STATUS_SE1)); dev_info(rdev->dev, " GRBM_STATUS_SE2=0x%08X\n", RREG32(GRBM_STATUS_SE2)); dev_info(rdev->dev, " GRBM_STATUS_SE3=0x%08X\n", RREG32(GRBM_STATUS_SE3)); dev_info(rdev->dev, " SRBM_STATUS=0x%08X\n", RREG32(SRBM_STATUS)); dev_info(rdev->dev, " SRBM_STATUS2=0x%08X\n", RREG32(SRBM_STATUS2)); evergreen_mc_stop(rdev, &save); if (radeon_mc_wait_for_idle(rdev)) { dev_warn(rdev->dev, "Wait for MC idle timedout !\n"); } /* Disable CP parsing/prefetching */ WREG32(CP_MEC_CNTL, MEC_ME1_HALT | MEC_ME2_HALT); /* reset all the CPC blocks */ grbm_reset = SOFT_RESET_CPG; dev_info(rdev->dev, " GRBM_SOFT_RESET=0x%08X\n", grbm_reset); WREG32(GRBM_SOFT_RESET, grbm_reset); (void)RREG32(GRBM_SOFT_RESET); udelay(50); WREG32(GRBM_SOFT_RESET, 0); (void)RREG32(GRBM_SOFT_RESET); /* Wait a little for things to settle down */ udelay(50); dev_info(rdev->dev, " GRBM_STATUS=0x%08X\n", RREG32(GRBM_STATUS)); dev_info(rdev->dev, " GRBM_STATUS2=0x%08X\n", RREG32(GRBM_STATUS2)); dev_info(rdev->dev, " GRBM_STATUS_SE0=0x%08X\n", RREG32(GRBM_STATUS_SE0)); dev_info(rdev->dev, " GRBM_STATUS_SE1=0x%08X\n", RREG32(GRBM_STATUS_SE1)); dev_info(rdev->dev, " GRBM_STATUS_SE2=0x%08X\n", RREG32(GRBM_STATUS_SE2)); dev_info(rdev->dev, " GRBM_STATUS_SE3=0x%08X\n", RREG32(GRBM_STATUS_SE3)); dev_info(rdev->dev, " SRBM_STATUS=0x%08X\n", RREG32(SRBM_STATUS)); dev_info(rdev->dev, " SRBM_STATUS2=0x%08X\n", RREG32(SRBM_STATUS2)); evergreen_mc_resume(rdev, &save); return 0; } /** * cik_asic_reset - soft reset compute and gfx * * @rdev: radeon_device pointer * * Soft reset the CPC blocks (CIK). * XXX: make this more fine grained and only reset * what is necessary. * Returns 0 for success. */ int cik_asic_reset(struct radeon_device *rdev) { int r; r = cik_compute_gpu_soft_reset(rdev); if (r) dev_info(rdev->dev, "Compute reset failed!\n"); return cik_gfx_gpu_soft_reset(rdev); } /** * cik_sdma_is_lockup - Check if the DMA engine is locked up * * @rdev: radeon_device pointer * @ring: radeon_ring structure holding ring information * * Check if the async DMA engine is locked up (CIK). * Returns true if the engine appears to be locked up, false if not. */ bool cik_sdma_is_lockup(struct radeon_device *rdev, struct radeon_ring *ring) { u32 dma_status_reg; if (ring->idx == R600_RING_TYPE_DMA_INDEX) dma_status_reg = RREG32(SDMA0_STATUS_REG + SDMA0_REGISTER_OFFSET); else dma_status_reg = RREG32(SDMA0_STATUS_REG + SDMA1_REGISTER_OFFSET); if (dma_status_reg & SDMA_IDLE) { radeon_ring_lockup_update(ring); return false; } /* force ring activities */ radeon_ring_force_activity(rdev, ring); return radeon_ring_test_lockup(rdev, ring); } /* MC */ /** * cik_mc_program - program the GPU memory controller * * @rdev: radeon_device pointer * * Set the location of vram, gart, and AGP in the GPU's * physical address space (CIK). */ static void cik_mc_program(struct radeon_device *rdev) { struct evergreen_mc_save save; u32 tmp; int i, j; /* Initialize HDP */ for (i = 0, j = 0; i < 32; i++, j += 0x18) { WREG32((0x2c14 + j), 0x00000000); WREG32((0x2c18 + j), 0x00000000); WREG32((0x2c1c + j), 0x00000000); WREG32((0x2c20 + j), 0x00000000); WREG32((0x2c24 + j), 0x00000000); } WREG32(HDP_REG_COHERENCY_FLUSH_CNTL, 0); evergreen_mc_stop(rdev, &save); if (radeon_mc_wait_for_idle(rdev)) { dev_warn(rdev->dev, "Wait for MC idle timedout !\n"); } /* Lockout access through VGA aperture*/ WREG32(VGA_HDP_CONTROL, VGA_MEMORY_DISABLE); /* Update configuration */ WREG32(MC_VM_SYSTEM_APERTURE_LOW_ADDR, rdev->mc.vram_start >> 12); WREG32(MC_VM_SYSTEM_APERTURE_HIGH_ADDR, rdev->mc.vram_end >> 12); WREG32(MC_VM_SYSTEM_APERTURE_DEFAULT_ADDR, rdev->vram_scratch.gpu_addr >> 12); tmp = ((rdev->mc.vram_end >> 24) & 0xFFFF) << 16; tmp |= ((rdev->mc.vram_start >> 24) & 0xFFFF); WREG32(MC_VM_FB_LOCATION, tmp); /* XXX double check these! */ WREG32(HDP_NONSURFACE_BASE, (rdev->mc.vram_start >> 8)); WREG32(HDP_NONSURFACE_INFO, (2 << 7) | (1 << 30)); WREG32(HDP_NONSURFACE_SIZE, 0x3FFFFFFF); WREG32(MC_VM_AGP_BASE, 0); WREG32(MC_VM_AGP_TOP, 0x0FFFFFFF); WREG32(MC_VM_AGP_BOT, 0x0FFFFFFF); if (radeon_mc_wait_for_idle(rdev)) { dev_warn(rdev->dev, "Wait for MC idle timedout !\n"); } evergreen_mc_resume(rdev, &save); /* we need to own VRAM, so turn off the VGA renderer here * to stop it overwriting our objects */ rv515_vga_render_disable(rdev); } /** * cik_mc_init - initialize the memory controller driver params * * @rdev: radeon_device pointer * * Look up the amount of vram, vram width, and decide how to place * vram and gart within the GPU's physical address space (CIK). * Returns 0 for success. */ static int cik_mc_init(struct radeon_device *rdev) { u32 tmp; int chansize, numchan; /* Get VRAM informations */ rdev->mc.vram_is_ddr = true; tmp = RREG32(MC_ARB_RAMCFG); if (tmp & CHANSIZE_MASK) { chansize = 64; } else { chansize = 32; } tmp = RREG32(MC_SHARED_CHMAP); switch ((tmp & NOOFCHAN_MASK) >> NOOFCHAN_SHIFT) { case 0: default: numchan = 1; break; case 1: numchan = 2; break; case 2: numchan = 4; break; case 3: numchan = 8; break; case 4: numchan = 3; break; case 5: numchan = 6; break; case 6: numchan = 10; break; case 7: numchan = 12; break; case 8: numchan = 16; break; } rdev->mc.vram_width = numchan * chansize; /* Could aper size report 0 ? */ rdev->mc.aper_base = pci_resource_start(rdev->pdev, 0); rdev->mc.aper_size = pci_resource_len(rdev->pdev, 0); /* size in MB on si */ rdev->mc.mc_vram_size = RREG32(CONFIG_MEMSIZE) * 1024 * 1024; rdev->mc.real_vram_size = RREG32(CONFIG_MEMSIZE) * 1024 * 1024; rdev->mc.visible_vram_size = rdev->mc.aper_size; si_vram_gtt_location(rdev, &rdev->mc); radeon_update_bandwidth_info(rdev); return 0; } /* * GART * VMID 0 is the physical GPU addresses as used by the kernel. * VMIDs 1-15 are used for userspace clients and are handled * by the radeon vm/hsa code. */ /** * cik_pcie_gart_tlb_flush - gart tlb flush callback * * @rdev: radeon_device pointer * * Flush the TLB for the VMID 0 page table (CIK). */ void cik_pcie_gart_tlb_flush(struct radeon_device *rdev) { /* flush hdp cache */ WREG32(HDP_MEM_COHERENCY_FLUSH_CNTL, 0); /* bits 0-15 are the VM contexts0-15 */ WREG32(VM_INVALIDATE_REQUEST, 0x1); } /** * cik_pcie_gart_enable - gart enable * * @rdev: radeon_device pointer * * This sets up the TLBs, programs the page tables for VMID0, * sets up the hw for VMIDs 1-15 which are allocated on * demand, and sets up the global locations for the LDS, GDS, * and GPUVM for FSA64 clients (CIK). * Returns 0 for success, errors for failure. */ static int cik_pcie_gart_enable(struct radeon_device *rdev) { int r, i; if (rdev->gart.robj == NULL) { dev_err(rdev->dev, "No VRAM object for PCIE GART.\n"); return -EINVAL; } r = radeon_gart_table_vram_pin(rdev); if (r) return r; radeon_gart_restore(rdev); /* Setup TLB control */ WREG32(MC_VM_MX_L1_TLB_CNTL, (0xA << 7) | ENABLE_L1_TLB | SYSTEM_ACCESS_MODE_NOT_IN_SYS | ENABLE_ADVANCED_DRIVER_MODEL | SYSTEM_APERTURE_UNMAPPED_ACCESS_PASS_THRU); /* Setup L2 cache */ WREG32(VM_L2_CNTL, ENABLE_L2_CACHE | ENABLE_L2_FRAGMENT_PROCESSING | ENABLE_L2_PTE_CACHE_LRU_UPDATE_BY_WRITE | ENABLE_L2_PDE0_CACHE_LRU_UPDATE_BY_WRITE | EFFECTIVE_L2_QUEUE_SIZE(7) | CONTEXT1_IDENTITY_ACCESS_MODE(1)); WREG32(VM_L2_CNTL2, INVALIDATE_ALL_L1_TLBS | INVALIDATE_L2_CACHE); WREG32(VM_L2_CNTL3, L2_CACHE_BIGK_ASSOCIATIVITY | L2_CACHE_BIGK_FRAGMENT_SIZE(6)); /* setup context0 */ WREG32(VM_CONTEXT0_PAGE_TABLE_START_ADDR, rdev->mc.gtt_start >> 12); WREG32(VM_CONTEXT0_PAGE_TABLE_END_ADDR, rdev->mc.gtt_end >> 12); WREG32(VM_CONTEXT0_PAGE_TABLE_BASE_ADDR, rdev->gart.table_addr >> 12); WREG32(VM_CONTEXT0_PROTECTION_FAULT_DEFAULT_ADDR, (u32)(rdev->dummy_page.addr >> 12)); WREG32(VM_CONTEXT0_CNTL2, 0); WREG32(VM_CONTEXT0_CNTL, (ENABLE_CONTEXT | PAGE_TABLE_DEPTH(0) | RANGE_PROTECTION_FAULT_ENABLE_DEFAULT)); WREG32(0x15D4, 0); WREG32(0x15D8, 0); WREG32(0x15DC, 0); /* empty context1-15 */ /* FIXME start with 4G, once using 2 level pt switch to full * vm size space */ /* set vm size, must be a multiple of 4 */ WREG32(VM_CONTEXT1_PAGE_TABLE_START_ADDR, 0); WREG32(VM_CONTEXT1_PAGE_TABLE_END_ADDR, rdev->vm_manager.max_pfn); for (i = 1; i < 16; i++) { if (i < 8) WREG32(VM_CONTEXT0_PAGE_TABLE_BASE_ADDR + (i << 2), rdev->gart.table_addr >> 12); else WREG32(VM_CONTEXT8_PAGE_TABLE_BASE_ADDR + ((i - 8) << 2), rdev->gart.table_addr >> 12); } /* enable context1-15 */ WREG32(VM_CONTEXT1_PROTECTION_FAULT_DEFAULT_ADDR, (u32)(rdev->dummy_page.addr >> 12)); WREG32(VM_CONTEXT1_CNTL2, 4); WREG32(VM_CONTEXT1_CNTL, ENABLE_CONTEXT | PAGE_TABLE_DEPTH(1) | RANGE_PROTECTION_FAULT_ENABLE_INTERRUPT | RANGE_PROTECTION_FAULT_ENABLE_DEFAULT | DUMMY_PAGE_PROTECTION_FAULT_ENABLE_INTERRUPT | DUMMY_PAGE_PROTECTION_FAULT_ENABLE_DEFAULT | PDE0_PROTECTION_FAULT_ENABLE_INTERRUPT | PDE0_PROTECTION_FAULT_ENABLE_DEFAULT | VALID_PROTECTION_FAULT_ENABLE_INTERRUPT | VALID_PROTECTION_FAULT_ENABLE_DEFAULT | READ_PROTECTION_FAULT_ENABLE_INTERRUPT | READ_PROTECTION_FAULT_ENABLE_DEFAULT | WRITE_PROTECTION_FAULT_ENABLE_INTERRUPT | WRITE_PROTECTION_FAULT_ENABLE_DEFAULT); /* TC cache setup ??? */ WREG32(TC_CFG_L1_LOAD_POLICY0, 0); WREG32(TC_CFG_L1_LOAD_POLICY1, 0); WREG32(TC_CFG_L1_STORE_POLICY, 0); WREG32(TC_CFG_L2_LOAD_POLICY0, 0); WREG32(TC_CFG_L2_LOAD_POLICY1, 0); WREG32(TC_CFG_L2_STORE_POLICY0, 0); WREG32(TC_CFG_L2_STORE_POLICY1, 0); WREG32(TC_CFG_L2_ATOMIC_POLICY, 0); WREG32(TC_CFG_L1_VOLATILE, 0); WREG32(TC_CFG_L2_VOLATILE, 0); if (rdev->family == CHIP_KAVERI) { u32 tmp = RREG32(CHUB_CONTROL); tmp &= ~BYPASS_VM; WREG32(CHUB_CONTROL, tmp); } /* XXX SH_MEM regs */ /* where to put LDS, scratch, GPUVM in FSA64 space */ for (i = 0; i < 16; i++) { WREG32(SRBM_GFX_CNTL, VMID(i)); /* CP and shaders */ WREG32(SH_MEM_CONFIG, 0); WREG32(SH_MEM_APE1_BASE, 1); WREG32(SH_MEM_APE1_LIMIT, 0); WREG32(SH_MEM_BASES, 0); /* SDMA GFX */ WREG32(SDMA0_GFX_VIRTUAL_ADDR + SDMA0_REGISTER_OFFSET, 0); WREG32(SDMA0_GFX_APE1_CNTL + SDMA0_REGISTER_OFFSET, 0); WREG32(SDMA0_GFX_VIRTUAL_ADDR + SDMA1_REGISTER_OFFSET, 0); WREG32(SDMA0_GFX_APE1_CNTL + SDMA1_REGISTER_OFFSET, 0); /* XXX SDMA RLC - todo */ } WREG32(SRBM_GFX_CNTL, 0); cik_pcie_gart_tlb_flush(rdev); DRM_INFO("PCIE GART of %uM enabled (table at 0x%016llX).\n", (unsigned)(rdev->mc.gtt_size >> 20), (unsigned long long)rdev->gart.table_addr); rdev->gart.ready = true; return 0; } /** * cik_pcie_gart_disable - gart disable * * @rdev: radeon_device pointer * * This disables all VM page table (CIK). */ static void cik_pcie_gart_disable(struct radeon_device *rdev) { /* Disable all tables */ WREG32(VM_CONTEXT0_CNTL, 0); WREG32(VM_CONTEXT1_CNTL, 0); /* Setup TLB control */ WREG32(MC_VM_MX_L1_TLB_CNTL, SYSTEM_ACCESS_MODE_NOT_IN_SYS | SYSTEM_APERTURE_UNMAPPED_ACCESS_PASS_THRU); /* Setup L2 cache */ WREG32(VM_L2_CNTL, ENABLE_L2_FRAGMENT_PROCESSING | ENABLE_L2_PTE_CACHE_LRU_UPDATE_BY_WRITE | ENABLE_L2_PDE0_CACHE_LRU_UPDATE_BY_WRITE | EFFECTIVE_L2_QUEUE_SIZE(7) | CONTEXT1_IDENTITY_ACCESS_MODE(1)); WREG32(VM_L2_CNTL2, 0); WREG32(VM_L2_CNTL3, L2_CACHE_BIGK_ASSOCIATIVITY | L2_CACHE_BIGK_FRAGMENT_SIZE(6)); radeon_gart_table_vram_unpin(rdev); } /** * cik_pcie_gart_fini - vm fini callback * * @rdev: radeon_device pointer * * Tears down the driver GART/VM setup (CIK). */ static void cik_pcie_gart_fini(struct radeon_device *rdev) { cik_pcie_gart_disable(rdev); radeon_gart_table_vram_free(rdev); radeon_gart_fini(rdev); } /* vm parser */ /** * cik_ib_parse - vm ib_parse callback * * @rdev: radeon_device pointer * @ib: indirect buffer pointer * * CIK uses hw IB checking so this is a nop (CIK). */ int cik_ib_parse(struct radeon_device *rdev, struct radeon_ib *ib) { return 0; } /* * vm * VMID 0 is the physical GPU addresses as used by the kernel. * VMIDs 1-15 are used for userspace clients and are handled * by the radeon vm/hsa code. */ /** * cik_vm_init - cik vm init callback * * @rdev: radeon_device pointer * * Inits cik specific vm parameters (number of VMs, base of vram for * VMIDs 1-15) (CIK). * Returns 0 for success. */ int cik_vm_init(struct radeon_device *rdev) { /* number of VMs */ rdev->vm_manager.nvm = 16; /* base offset of vram pages */ if (rdev->flags & RADEON_IS_IGP) { u64 tmp = RREG32(MC_VM_FB_OFFSET); tmp <<= 22; rdev->vm_manager.vram_base_offset = tmp; } else rdev->vm_manager.vram_base_offset = 0; return 0; } /** * cik_vm_fini - cik vm fini callback * * @rdev: radeon_device pointer * * Tear down any asic specific VM setup (CIK). */ void cik_vm_fini(struct radeon_device *rdev) { } /** * cik_vm_flush - cik vm flush using the CP * * @rdev: radeon_device pointer * * Update the page table base and flush the VM TLB * using the CP (CIK). */ void cik_vm_flush(struct radeon_device *rdev, int ridx, struct radeon_vm *vm) { struct radeon_ring *ring = &rdev->ring[ridx]; if (vm == NULL) return; radeon_ring_write(ring, PACKET3(PACKET3_WRITE_DATA, 3)); radeon_ring_write(ring, (WRITE_DATA_ENGINE_SEL(0) | WRITE_DATA_DST_SEL(0))); if (vm->id < 8) { radeon_ring_write(ring, (VM_CONTEXT0_PAGE_TABLE_BASE_ADDR + (vm->id << 2)) >> 2); } else { radeon_ring_write(ring, (VM_CONTEXT8_PAGE_TABLE_BASE_ADDR + ((vm->id - 8) << 2)) >> 2); } radeon_ring_write(ring, 0); radeon_ring_write(ring, vm->pd_gpu_addr >> 12); /* update SH_MEM_* regs */ radeon_ring_write(ring, PACKET3(PACKET3_WRITE_DATA, 3)); radeon_ring_write(ring, (WRITE_DATA_ENGINE_SEL(0) | WRITE_DATA_DST_SEL(0))); radeon_ring_write(ring, SRBM_GFX_CNTL >> 2); radeon_ring_write(ring, 0); radeon_ring_write(ring, VMID(vm->id)); radeon_ring_write(ring, PACKET3(PACKET3_WRITE_DATA, 6)); radeon_ring_write(ring, (WRITE_DATA_ENGINE_SEL(0) | WRITE_DATA_DST_SEL(0))); radeon_ring_write(ring, SH_MEM_BASES >> 2); radeon_ring_write(ring, 0); radeon_ring_write(ring, 0); /* SH_MEM_BASES */ radeon_ring_write(ring, 0); /* SH_MEM_CONFIG */ radeon_ring_write(ring, 1); /* SH_MEM_APE1_BASE */ radeon_ring_write(ring, 0); /* SH_MEM_APE1_LIMIT */ radeon_ring_write(ring, PACKET3(PACKET3_WRITE_DATA, 3)); radeon_ring_write(ring, (WRITE_DATA_ENGINE_SEL(0) | WRITE_DATA_DST_SEL(0))); radeon_ring_write(ring, SRBM_GFX_CNTL >> 2); radeon_ring_write(ring, 0); radeon_ring_write(ring, VMID(0)); /* HDP flush */ /* We should be using the WAIT_REG_MEM packet here like in * cik_fence_ring_emit(), but it causes the CP to hang in this * context... */ radeon_ring_write(ring, PACKET3(PACKET3_WRITE_DATA, 3)); radeon_ring_write(ring, (WRITE_DATA_ENGINE_SEL(0) | WRITE_DATA_DST_SEL(0))); radeon_ring_write(ring, HDP_MEM_COHERENCY_FLUSH_CNTL >> 2); radeon_ring_write(ring, 0); radeon_ring_write(ring, 0); /* bits 0-15 are the VM contexts0-15 */ radeon_ring_write(ring, PACKET3(PACKET3_WRITE_DATA, 3)); radeon_ring_write(ring, (WRITE_DATA_ENGINE_SEL(0) | WRITE_DATA_DST_SEL(0))); radeon_ring_write(ring, VM_INVALIDATE_REQUEST >> 2); radeon_ring_write(ring, 0); radeon_ring_write(ring, 1 << vm->id); /* sync PFP to ME, otherwise we might get invalid PFP reads */ radeon_ring_write(ring, PACKET3(PACKET3_PFP_SYNC_ME, 0)); radeon_ring_write(ring, 0x0); } /* * RLC * The RLC is a multi-purpose microengine that handles a * variety of functions, the most important of which is * the interrupt controller. */ /** * cik_rlc_stop - stop the RLC ME * * @rdev: radeon_device pointer * * Halt the RLC ME (MicroEngine) (CIK). */ static void cik_rlc_stop(struct radeon_device *rdev) { int i, j, k; u32 mask, tmp; tmp = RREG32(CP_INT_CNTL_RING0); tmp &= ~(CNTX_BUSY_INT_ENABLE | CNTX_EMPTY_INT_ENABLE); WREG32(CP_INT_CNTL_RING0, tmp); RREG32(CB_CGTT_SCLK_CTRL); RREG32(CB_CGTT_SCLK_CTRL); RREG32(CB_CGTT_SCLK_CTRL); RREG32(CB_CGTT_SCLK_CTRL); tmp = RREG32(RLC_CGCG_CGLS_CTRL) & 0xfffffffc; WREG32(RLC_CGCG_CGLS_CTRL, tmp); WREG32(RLC_CNTL, 0); for (i = 0; i < rdev->config.cik.max_shader_engines; i++) { for (j = 0; j < rdev->config.cik.max_sh_per_se; j++) { cik_select_se_sh(rdev, i, j); for (k = 0; k < rdev->usec_timeout; k++) { if (RREG32(RLC_SERDES_CU_MASTER_BUSY) == 0) break; udelay(1); } } } cik_select_se_sh(rdev, 0xffffffff, 0xffffffff); mask = SE_MASTER_BUSY_MASK | GC_MASTER_BUSY | TC0_MASTER_BUSY | TC1_MASTER_BUSY; for (k = 0; k < rdev->usec_timeout; k++) { if ((RREG32(RLC_SERDES_NONCU_MASTER_BUSY) & mask) == 0) break; udelay(1); } } /** * cik_rlc_start - start the RLC ME * * @rdev: radeon_device pointer * * Unhalt the RLC ME (MicroEngine) (CIK). */ static void cik_rlc_start(struct radeon_device *rdev) { u32 tmp; WREG32(RLC_CNTL, RLC_ENABLE); tmp = RREG32(CP_INT_CNTL_RING0); tmp |= (CNTX_BUSY_INT_ENABLE | CNTX_EMPTY_INT_ENABLE); WREG32(CP_INT_CNTL_RING0, tmp); udelay(50); } /** * cik_rlc_resume - setup the RLC hw * * @rdev: radeon_device pointer * * Initialize the RLC registers, load the ucode, * and start the RLC (CIK). * Returns 0 for success, -EINVAL if the ucode is not available. */ static int cik_rlc_resume(struct radeon_device *rdev) { u32 i, size; u32 clear_state_info[3]; const __be32 *fw_data; if (!rdev->rlc_fw) return -EINVAL; switch (rdev->family) { case CHIP_BONAIRE: default: size = BONAIRE_RLC_UCODE_SIZE; break; case CHIP_KAVERI: size = KV_RLC_UCODE_SIZE; break; case CHIP_KABINI: size = KB_RLC_UCODE_SIZE; break; } cik_rlc_stop(rdev); WREG32(GRBM_SOFT_RESET, SOFT_RESET_RLC); RREG32(GRBM_SOFT_RESET); udelay(50); WREG32(GRBM_SOFT_RESET, 0); RREG32(GRBM_SOFT_RESET); udelay(50); WREG32(RLC_LB_CNTR_INIT, 0); WREG32(RLC_LB_CNTR_MAX, 0x00008000); cik_select_se_sh(rdev, 0xffffffff, 0xffffffff); WREG32(RLC_LB_INIT_CU_MASK, 0xffffffff); WREG32(RLC_LB_PARAMS, 0x00600408); WREG32(RLC_LB_CNTL, 0x80000004); WREG32(RLC_MC_CNTL, 0); WREG32(RLC_UCODE_CNTL, 0); fw_data = (const __be32 *)rdev->rlc_fw->data; WREG32(RLC_GPM_UCODE_ADDR, 0); for (i = 0; i < size; i++) WREG32(RLC_GPM_UCODE_DATA, be32_to_cpup(fw_data++)); WREG32(RLC_GPM_UCODE_ADDR, 0); /* XXX */ clear_state_info[0] = 0;//upper_32_bits(rdev->rlc.save_restore_gpu_addr); clear_state_info[1] = 0;//rdev->rlc.save_restore_gpu_addr; clear_state_info[2] = 0;//cik_default_size; WREG32(RLC_GPM_SCRATCH_ADDR, 0x3d); for (i = 0; i < 3; i++) WREG32(RLC_GPM_SCRATCH_DATA, clear_state_info[i]); WREG32(RLC_DRIVER_DMA_STATUS, 0); cik_rlc_start(rdev); return 0; } /* * Interrupts * Starting with r6xx, interrupts are handled via a ring buffer. * Ring buffers are areas of GPU accessible memory that the GPU * writes interrupt vectors into and the host reads vectors out of. * There is a rptr (read pointer) that determines where the * host is currently reading, and a wptr (write pointer) * which determines where the GPU has written. When the * pointers are equal, the ring is idle. When the GPU * writes vectors to the ring buffer, it increments the * wptr. When there is an interrupt, the host then starts * fetching commands and processing them until the pointers are * equal again at which point it updates the rptr. */ /** * cik_enable_interrupts - Enable the interrupt ring buffer * * @rdev: radeon_device pointer * * Enable the interrupt ring buffer (CIK). */ static void cik_enable_interrupts(struct radeon_device *rdev) { u32 ih_cntl = RREG32(IH_CNTL); u32 ih_rb_cntl = RREG32(IH_RB_CNTL); ih_cntl |= ENABLE_INTR; ih_rb_cntl |= IH_RB_ENABLE; WREG32(IH_CNTL, ih_cntl); WREG32(IH_RB_CNTL, ih_rb_cntl); rdev->ih.enabled = true; } /** * cik_disable_interrupts - Disable the interrupt ring buffer * * @rdev: radeon_device pointer * * Disable the interrupt ring buffer (CIK). */ static void cik_disable_interrupts(struct radeon_device *rdev) { u32 ih_rb_cntl = RREG32(IH_RB_CNTL); u32 ih_cntl = RREG32(IH_CNTL); ih_rb_cntl &= ~IH_RB_ENABLE; ih_cntl &= ~ENABLE_INTR; WREG32(IH_RB_CNTL, ih_rb_cntl); WREG32(IH_CNTL, ih_cntl); /* set rptr, wptr to 0 */ WREG32(IH_RB_RPTR, 0); WREG32(IH_RB_WPTR, 0); rdev->ih.enabled = false; rdev->ih.rptr = 0; } /** * cik_disable_interrupt_state - Disable all interrupt sources * * @rdev: radeon_device pointer * * Clear all interrupt enable bits used by the driver (CIK). */ static void cik_disable_interrupt_state(struct radeon_device *rdev) { u32 tmp; /* gfx ring */ WREG32(CP_INT_CNTL_RING0, CNTX_BUSY_INT_ENABLE | CNTX_EMPTY_INT_ENABLE); /* sdma */ tmp = RREG32(SDMA0_CNTL + SDMA0_REGISTER_OFFSET) & ~TRAP_ENABLE; WREG32(SDMA0_CNTL + SDMA0_REGISTER_OFFSET, tmp); tmp = RREG32(SDMA0_CNTL + SDMA1_REGISTER_OFFSET) & ~TRAP_ENABLE; WREG32(SDMA0_CNTL + SDMA1_REGISTER_OFFSET, tmp); /* compute queues */ WREG32(CP_ME1_PIPE0_INT_CNTL, 0); WREG32(CP_ME1_PIPE1_INT_CNTL, 0); WREG32(CP_ME1_PIPE2_INT_CNTL, 0); WREG32(CP_ME1_PIPE3_INT_CNTL, 0); WREG32(CP_ME2_PIPE0_INT_CNTL, 0); WREG32(CP_ME2_PIPE1_INT_CNTL, 0); WREG32(CP_ME2_PIPE2_INT_CNTL, 0); WREG32(CP_ME2_PIPE3_INT_CNTL, 0); /* grbm */ WREG32(GRBM_INT_CNTL, 0); /* vline/vblank, etc. */ WREG32(LB_INTERRUPT_MASK + EVERGREEN_CRTC0_REGISTER_OFFSET, 0); WREG32(LB_INTERRUPT_MASK + EVERGREEN_CRTC1_REGISTER_OFFSET, 0); if (rdev->num_crtc >= 4) { WREG32(LB_INTERRUPT_MASK + EVERGREEN_CRTC2_REGISTER_OFFSET, 0); WREG32(LB_INTERRUPT_MASK + EVERGREEN_CRTC3_REGISTER_OFFSET, 0); } if (rdev->num_crtc >= 6) { WREG32(LB_INTERRUPT_MASK + EVERGREEN_CRTC4_REGISTER_OFFSET, 0); WREG32(LB_INTERRUPT_MASK + EVERGREEN_CRTC5_REGISTER_OFFSET, 0); } /* dac hotplug */ WREG32(DAC_AUTODETECT_INT_CONTROL, 0); /* digital hotplug */ tmp = RREG32(DC_HPD1_INT_CONTROL) & DC_HPDx_INT_POLARITY; WREG32(DC_HPD1_INT_CONTROL, tmp); tmp = RREG32(DC_HPD2_INT_CONTROL) & DC_HPDx_INT_POLARITY; WREG32(DC_HPD2_INT_CONTROL, tmp); tmp = RREG32(DC_HPD3_INT_CONTROL) & DC_HPDx_INT_POLARITY; WREG32(DC_HPD3_INT_CONTROL, tmp); tmp = RREG32(DC_HPD4_INT_CONTROL) & DC_HPDx_INT_POLARITY; WREG32(DC_HPD4_INT_CONTROL, tmp); tmp = RREG32(DC_HPD5_INT_CONTROL) & DC_HPDx_INT_POLARITY; WREG32(DC_HPD5_INT_CONTROL, tmp); tmp = RREG32(DC_HPD6_INT_CONTROL) & DC_HPDx_INT_POLARITY; WREG32(DC_HPD6_INT_CONTROL, tmp); } /** * cik_irq_init - init and enable the interrupt ring * * @rdev: radeon_device pointer * * Allocate a ring buffer for the interrupt controller, * enable the RLC, disable interrupts, enable the IH * ring buffer and enable it (CIK). * Called at device load and reume. * Returns 0 for success, errors for failure. */ static int cik_irq_init(struct radeon_device *rdev) { int ret = 0; int rb_bufsz; u32 interrupt_cntl, ih_cntl, ih_rb_cntl; /* allocate ring */ ret = r600_ih_ring_alloc(rdev); if (ret) return ret; /* disable irqs */ cik_disable_interrupts(rdev); /* init rlc */ ret = cik_rlc_resume(rdev); if (ret) { r600_ih_ring_fini(rdev); return ret; } /* setup interrupt control */ /* XXX this should actually be a bus address, not an MC address. same on older asics */ WREG32(INTERRUPT_CNTL2, rdev->ih.gpu_addr >> 8); interrupt_cntl = RREG32(INTERRUPT_CNTL); /* IH_DUMMY_RD_OVERRIDE=0 - dummy read disabled with msi, enabled without msi * IH_DUMMY_RD_OVERRIDE=1 - dummy read controlled by IH_DUMMY_RD_EN */ interrupt_cntl &= ~IH_DUMMY_RD_OVERRIDE; /* IH_REQ_NONSNOOP_EN=1 if ring is in non-cacheable memory, e.g., vram */ interrupt_cntl &= ~IH_REQ_NONSNOOP_EN; WREG32(INTERRUPT_CNTL, interrupt_cntl); WREG32(IH_RB_BASE, rdev->ih.gpu_addr >> 8); rb_bufsz = drm_order(rdev->ih.ring_size / 4); ih_rb_cntl = (IH_WPTR_OVERFLOW_ENABLE | IH_WPTR_OVERFLOW_CLEAR | (rb_bufsz << 1)); if (rdev->wb.enabled) ih_rb_cntl |= IH_WPTR_WRITEBACK_ENABLE; /* set the writeback address whether it's enabled or not */ WREG32(IH_RB_WPTR_ADDR_LO, (rdev->wb.gpu_addr + R600_WB_IH_WPTR_OFFSET) & 0xFFFFFFFC); WREG32(IH_RB_WPTR_ADDR_HI, upper_32_bits(rdev->wb.gpu_addr + R600_WB_IH_WPTR_OFFSET) & 0xFF); WREG32(IH_RB_CNTL, ih_rb_cntl); /* set rptr, wptr to 0 */ WREG32(IH_RB_RPTR, 0); WREG32(IH_RB_WPTR, 0); /* Default settings for IH_CNTL (disabled at first) */ ih_cntl = MC_WRREQ_CREDIT(0x10) | MC_WR_CLEAN_CNT(0x10) | MC_VMID(0); /* RPTR_REARM only works if msi's are enabled */ if (rdev->msi_enabled) ih_cntl |= RPTR_REARM; WREG32(IH_CNTL, ih_cntl); /* force the active interrupt state to all disabled */ cik_disable_interrupt_state(rdev); pci_set_master(rdev->pdev); /* enable irqs */ cik_enable_interrupts(rdev); return ret; } /** * cik_irq_set - enable/disable interrupt sources * * @rdev: radeon_device pointer * * Enable interrupt sources on the GPU (vblanks, hpd, * etc.) (CIK). * Returns 0 for success, errors for failure. */ int cik_irq_set(struct radeon_device *rdev) { u32 cp_int_cntl = CNTX_BUSY_INT_ENABLE | CNTX_EMPTY_INT_ENABLE | PRIV_INSTR_INT_ENABLE | PRIV_REG_INT_ENABLE; u32 crtc1 = 0, crtc2 = 0, crtc3 = 0, crtc4 = 0, crtc5 = 0, crtc6 = 0; u32 hpd1, hpd2, hpd3, hpd4, hpd5, hpd6; u32 grbm_int_cntl = 0; u32 dma_cntl, dma_cntl1; if (!rdev->irq.installed) { WARN(1, "Can't enable IRQ/MSI because no handler is installed\n"); return -EINVAL; } /* don't enable anything if the ih is disabled */ if (!rdev->ih.enabled) { cik_disable_interrupts(rdev); /* force the active interrupt state to all disabled */ cik_disable_interrupt_state(rdev); return 0; } hpd1 = RREG32(DC_HPD1_INT_CONTROL) & ~DC_HPDx_INT_EN; hpd2 = RREG32(DC_HPD2_INT_CONTROL) & ~DC_HPDx_INT_EN; hpd3 = RREG32(DC_HPD3_INT_CONTROL) & ~DC_HPDx_INT_EN; hpd4 = RREG32(DC_HPD4_INT_CONTROL) & ~DC_HPDx_INT_EN; hpd5 = RREG32(DC_HPD5_INT_CONTROL) & ~DC_HPDx_INT_EN; hpd6 = RREG32(DC_HPD6_INT_CONTROL) & ~DC_HPDx_INT_EN; dma_cntl = RREG32(SDMA0_CNTL + SDMA0_REGISTER_OFFSET) & ~TRAP_ENABLE; dma_cntl1 = RREG32(SDMA0_CNTL + SDMA1_REGISTER_OFFSET) & ~TRAP_ENABLE; /* enable CP interrupts on all rings */ if (atomic_read(&rdev->irq.ring_int[RADEON_RING_TYPE_GFX_INDEX])) { DRM_DEBUG("cik_irq_set: sw int gfx\n"); cp_int_cntl |= TIME_STAMP_INT_ENABLE; } /* TODO: compute queues! */ /* CP_ME[1-2]_PIPE[0-3]_INT_CNTL */ if (atomic_read(&rdev->irq.ring_int[R600_RING_TYPE_DMA_INDEX])) { DRM_DEBUG("cik_irq_set: sw int dma\n"); dma_cntl |= TRAP_ENABLE; } if (atomic_read(&rdev->irq.ring_int[CAYMAN_RING_TYPE_DMA1_INDEX])) { DRM_DEBUG("cik_irq_set: sw int dma1\n"); dma_cntl1 |= TRAP_ENABLE; } if (rdev->irq.crtc_vblank_int[0] || atomic_read(&rdev->irq.pflip[0])) { DRM_DEBUG("cik_irq_set: vblank 0\n"); crtc1 |= VBLANK_INTERRUPT_MASK; } if (rdev->irq.crtc_vblank_int[1] || atomic_read(&rdev->irq.pflip[1])) { DRM_DEBUG("cik_irq_set: vblank 1\n"); crtc2 |= VBLANK_INTERRUPT_MASK; } if (rdev->irq.crtc_vblank_int[2] || atomic_read(&rdev->irq.pflip[2])) { DRM_DEBUG("cik_irq_set: vblank 2\n"); crtc3 |= VBLANK_INTERRUPT_MASK; } if (rdev->irq.crtc_vblank_int[3] || atomic_read(&rdev->irq.pflip[3])) { DRM_DEBUG("cik_irq_set: vblank 3\n"); crtc4 |= VBLANK_INTERRUPT_MASK; } if (rdev->irq.crtc_vblank_int[4] || atomic_read(&rdev->irq.pflip[4])) { DRM_DEBUG("cik_irq_set: vblank 4\n"); crtc5 |= VBLANK_INTERRUPT_MASK; } if (rdev->irq.crtc_vblank_int[5] || atomic_read(&rdev->irq.pflip[5])) { DRM_DEBUG("cik_irq_set: vblank 5\n"); crtc6 |= VBLANK_INTERRUPT_MASK; } if (rdev->irq.hpd[0]) { DRM_DEBUG("cik_irq_set: hpd 1\n"); hpd1 |= DC_HPDx_INT_EN; } if (rdev->irq.hpd[1]) { DRM_DEBUG("cik_irq_set: hpd 2\n"); hpd2 |= DC_HPDx_INT_EN; } if (rdev->irq.hpd[2]) { DRM_DEBUG("cik_irq_set: hpd 3\n"); hpd3 |= DC_HPDx_INT_EN; } if (rdev->irq.hpd[3]) { DRM_DEBUG("cik_irq_set: hpd 4\n"); hpd4 |= DC_HPDx_INT_EN; } if (rdev->irq.hpd[4]) { DRM_DEBUG("cik_irq_set: hpd 5\n"); hpd5 |= DC_HPDx_INT_EN; } if (rdev->irq.hpd[5]) { DRM_DEBUG("cik_irq_set: hpd 6\n"); hpd6 |= DC_HPDx_INT_EN; } WREG32(CP_INT_CNTL_RING0, cp_int_cntl); WREG32(SDMA0_CNTL + SDMA0_REGISTER_OFFSET, dma_cntl); WREG32(SDMA0_CNTL + SDMA1_REGISTER_OFFSET, dma_cntl1); WREG32(GRBM_INT_CNTL, grbm_int_cntl); WREG32(LB_INTERRUPT_MASK + EVERGREEN_CRTC0_REGISTER_OFFSET, crtc1); WREG32(LB_INTERRUPT_MASK + EVERGREEN_CRTC1_REGISTER_OFFSET, crtc2); if (rdev->num_crtc >= 4) { WREG32(LB_INTERRUPT_MASK + EVERGREEN_CRTC2_REGISTER_OFFSET, crtc3); WREG32(LB_INTERRUPT_MASK + EVERGREEN_CRTC3_REGISTER_OFFSET, crtc4); } if (rdev->num_crtc >= 6) { WREG32(LB_INTERRUPT_MASK + EVERGREEN_CRTC4_REGISTER_OFFSET, crtc5); WREG32(LB_INTERRUPT_MASK + EVERGREEN_CRTC5_REGISTER_OFFSET, crtc6); } WREG32(DC_HPD1_INT_CONTROL, hpd1); WREG32(DC_HPD2_INT_CONTROL, hpd2); WREG32(DC_HPD3_INT_CONTROL, hpd3); WREG32(DC_HPD4_INT_CONTROL, hpd4); WREG32(DC_HPD5_INT_CONTROL, hpd5); WREG32(DC_HPD6_INT_CONTROL, hpd6); return 0; } /** * cik_irq_ack - ack interrupt sources * * @rdev: radeon_device pointer * * Ack interrupt sources on the GPU (vblanks, hpd, * etc.) (CIK). Certain interrupts sources are sw * generated and do not require an explicit ack. */ static inline void cik_irq_ack(struct radeon_device *rdev) { u32 tmp; rdev->irq.stat_regs.cik.disp_int = RREG32(DISP_INTERRUPT_STATUS); rdev->irq.stat_regs.cik.disp_int_cont = RREG32(DISP_INTERRUPT_STATUS_CONTINUE); rdev->irq.stat_regs.cik.disp_int_cont2 = RREG32(DISP_INTERRUPT_STATUS_CONTINUE2); rdev->irq.stat_regs.cik.disp_int_cont3 = RREG32(DISP_INTERRUPT_STATUS_CONTINUE3); rdev->irq.stat_regs.cik.disp_int_cont4 = RREG32(DISP_INTERRUPT_STATUS_CONTINUE4); rdev->irq.stat_regs.cik.disp_int_cont5 = RREG32(DISP_INTERRUPT_STATUS_CONTINUE5); rdev->irq.stat_regs.cik.disp_int_cont6 = RREG32(DISP_INTERRUPT_STATUS_CONTINUE6); if (rdev->irq.stat_regs.cik.disp_int & LB_D1_VBLANK_INTERRUPT) WREG32(LB_VBLANK_STATUS + EVERGREEN_CRTC0_REGISTER_OFFSET, VBLANK_ACK); if (rdev->irq.stat_regs.cik.disp_int & LB_D1_VLINE_INTERRUPT) WREG32(LB_VLINE_STATUS + EVERGREEN_CRTC0_REGISTER_OFFSET, VLINE_ACK); if (rdev->irq.stat_regs.cik.disp_int_cont & LB_D2_VBLANK_INTERRUPT) WREG32(LB_VBLANK_STATUS + EVERGREEN_CRTC1_REGISTER_OFFSET, VBLANK_ACK); if (rdev->irq.stat_regs.cik.disp_int_cont & LB_D2_VLINE_INTERRUPT) WREG32(LB_VLINE_STATUS + EVERGREEN_CRTC1_REGISTER_OFFSET, VLINE_ACK); if (rdev->num_crtc >= 4) { if (rdev->irq.stat_regs.cik.disp_int_cont2 & LB_D3_VBLANK_INTERRUPT) WREG32(LB_VBLANK_STATUS + EVERGREEN_CRTC2_REGISTER_OFFSET, VBLANK_ACK); if (rdev->irq.stat_regs.cik.disp_int_cont2 & LB_D3_VLINE_INTERRUPT) WREG32(LB_VLINE_STATUS + EVERGREEN_CRTC2_REGISTER_OFFSET, VLINE_ACK); if (rdev->irq.stat_regs.cik.disp_int_cont3 & LB_D4_VBLANK_INTERRUPT) WREG32(LB_VBLANK_STATUS + EVERGREEN_CRTC3_REGISTER_OFFSET, VBLANK_ACK); if (rdev->irq.stat_regs.cik.disp_int_cont3 & LB_D4_VLINE_INTERRUPT) WREG32(LB_VLINE_STATUS + EVERGREEN_CRTC3_REGISTER_OFFSET, VLINE_ACK); } if (rdev->num_crtc >= 6) { if (rdev->irq.stat_regs.cik.disp_int_cont4 & LB_D5_VBLANK_INTERRUPT) WREG32(LB_VBLANK_STATUS + EVERGREEN_CRTC4_REGISTER_OFFSET, VBLANK_ACK); if (rdev->irq.stat_regs.cik.disp_int_cont4 & LB_D5_VLINE_INTERRUPT) WREG32(LB_VLINE_STATUS + EVERGREEN_CRTC4_REGISTER_OFFSET, VLINE_ACK); if (rdev->irq.stat_regs.cik.disp_int_cont5 & LB_D6_VBLANK_INTERRUPT) WREG32(LB_VBLANK_STATUS + EVERGREEN_CRTC5_REGISTER_OFFSET, VBLANK_ACK); if (rdev->irq.stat_regs.cik.disp_int_cont5 & LB_D6_VLINE_INTERRUPT) WREG32(LB_VLINE_STATUS + EVERGREEN_CRTC5_REGISTER_OFFSET, VLINE_ACK); } if (rdev->irq.stat_regs.cik.disp_int & DC_HPD1_INTERRUPT) { tmp = RREG32(DC_HPD1_INT_CONTROL); tmp |= DC_HPDx_INT_ACK; WREG32(DC_HPD1_INT_CONTROL, tmp); } if (rdev->irq.stat_regs.cik.disp_int_cont & DC_HPD2_INTERRUPT) { tmp = RREG32(DC_HPD2_INT_CONTROL); tmp |= DC_HPDx_INT_ACK; WREG32(DC_HPD2_INT_CONTROL, tmp); } if (rdev->irq.stat_regs.cik.disp_int_cont2 & DC_HPD3_INTERRUPT) { tmp = RREG32(DC_HPD3_INT_CONTROL); tmp |= DC_HPDx_INT_ACK; WREG32(DC_HPD3_INT_CONTROL, tmp); } if (rdev->irq.stat_regs.cik.disp_int_cont3 & DC_HPD4_INTERRUPT) { tmp = RREG32(DC_HPD4_INT_CONTROL); tmp |= DC_HPDx_INT_ACK; WREG32(DC_HPD4_INT_CONTROL, tmp); } if (rdev->irq.stat_regs.cik.disp_int_cont4 & DC_HPD5_INTERRUPT) { tmp = RREG32(DC_HPD5_INT_CONTROL); tmp |= DC_HPDx_INT_ACK; WREG32(DC_HPD5_INT_CONTROL, tmp); } if (rdev->irq.stat_regs.cik.disp_int_cont5 & DC_HPD6_INTERRUPT) { tmp = RREG32(DC_HPD5_INT_CONTROL); tmp |= DC_HPDx_INT_ACK; WREG32(DC_HPD6_INT_CONTROL, tmp); } } /** * cik_irq_disable - disable interrupts * * @rdev: radeon_device pointer * * Disable interrupts on the hw (CIK). */ static void cik_irq_disable(struct radeon_device *rdev) { cik_disable_interrupts(rdev); /* Wait and acknowledge irq */ mdelay(1); cik_irq_ack(rdev); cik_disable_interrupt_state(rdev); } /** * cik_irq_disable - disable interrupts for suspend * * @rdev: radeon_device pointer * * Disable interrupts and stop the RLC (CIK). * Used for suspend. */ static void cik_irq_suspend(struct radeon_device *rdev) { cik_irq_disable(rdev); cik_rlc_stop(rdev); } /** * cik_irq_fini - tear down interrupt support * * @rdev: radeon_device pointer * * Disable interrupts on the hw and free the IH ring * buffer (CIK). * Used for driver unload. */ static void cik_irq_fini(struct radeon_device *rdev) { cik_irq_suspend(rdev); r600_ih_ring_fini(rdev); } /** * cik_get_ih_wptr - get the IH ring buffer wptr * * @rdev: radeon_device pointer * * Get the IH ring buffer wptr from either the register * or the writeback memory buffer (CIK). Also check for * ring buffer overflow and deal with it. * Used by cik_irq_process(). * Returns the value of the wptr. */ static inline u32 cik_get_ih_wptr(struct radeon_device *rdev) { u32 wptr, tmp; if (rdev->wb.enabled) wptr = le32_to_cpu(rdev->wb.wb[R600_WB_IH_WPTR_OFFSET/4]); else wptr = RREG32(IH_RB_WPTR); if (wptr & RB_OVERFLOW) { /* When a ring buffer overflow happen start parsing interrupt * from the last not overwritten vector (wptr + 16). Hopefully * this should allow us to catchup. */ dev_warn(rdev->dev, "IH ring buffer overflow (0x%08X, %d, %d)\n", wptr, rdev->ih.rptr, (wptr + 16) + rdev->ih.ptr_mask); rdev->ih.rptr = (wptr + 16) & rdev->ih.ptr_mask; tmp = RREG32(IH_RB_CNTL); tmp |= IH_WPTR_OVERFLOW_CLEAR; WREG32(IH_RB_CNTL, tmp); } return (wptr & rdev->ih.ptr_mask); } /* CIK IV Ring * Each IV ring entry is 128 bits: * [7:0] - interrupt source id * [31:8] - reserved * [59:32] - interrupt source data * [63:60] - reserved * [71:64] - RINGID * CP: * ME_ID [1:0], PIPE_ID[1:0], QUEUE_ID[2:0] * QUEUE_ID - for compute, which of the 8 queues owned by the dispatcher * - for gfx, hw shader state (0=PS...5=LS, 6=CS) * ME_ID - 0 = gfx, 1 = first 4 CS pipes, 2 = second 4 CS pipes * PIPE_ID - ME0 0=3D * - ME1&2 compute dispatcher (4 pipes each) * SDMA: * INSTANCE_ID [1:0], QUEUE_ID[1:0] * INSTANCE_ID - 0 = sdma0, 1 = sdma1 * QUEUE_ID - 0 = gfx, 1 = rlc0, 2 = rlc1 * [79:72] - VMID * [95:80] - PASID * [127:96] - reserved */ /** * cik_irq_process - interrupt handler * * @rdev: radeon_device pointer * * Interrupt hander (CIK). Walk the IH ring, * ack interrupts and schedule work to handle * interrupt events. * Returns irq process return code. */ int cik_irq_process(struct radeon_device *rdev) { u32 wptr; u32 rptr; u32 src_id, src_data, ring_id; u8 me_id, pipe_id, queue_id; u32 ring_index; bool queue_hotplug = false; bool queue_reset = false; if (!rdev->ih.enabled || rdev->shutdown) return IRQ_NONE; wptr = cik_get_ih_wptr(rdev); restart_ih: /* is somebody else already processing irqs? */ if (atomic_xchg(&rdev->ih.lock, 1)) return IRQ_NONE; rptr = rdev->ih.rptr; DRM_DEBUG("cik_irq_process start: rptr %d, wptr %d\n", rptr, wptr); /* Order reading of wptr vs. reading of IH ring data */ rmb(); /* display interrupts */ cik_irq_ack(rdev); while (rptr != wptr) { /* wptr/rptr are in bytes! */ ring_index = rptr / 4; src_id = le32_to_cpu(rdev->ih.ring[ring_index]) & 0xff; src_data = le32_to_cpu(rdev->ih.ring[ring_index + 1]) & 0xfffffff; ring_id = le32_to_cpu(rdev->ih.ring[ring_index + 2]) & 0xff; switch (src_id) { case 1: /* D1 vblank/vline */ switch (src_data) { case 0: /* D1 vblank */ if (rdev->irq.stat_regs.cik.disp_int & LB_D1_VBLANK_INTERRUPT) { if (rdev->irq.crtc_vblank_int[0]) { drm_handle_vblank(rdev->ddev, 0); rdev->pm.vblank_sync = true; wake_up(&rdev->irq.vblank_queue); } if (atomic_read(&rdev->irq.pflip[0])) radeon_crtc_handle_flip(rdev, 0); rdev->irq.stat_regs.cik.disp_int &= ~LB_D1_VBLANK_INTERRUPT; DRM_DEBUG("IH: D1 vblank\n"); } break; case 1: /* D1 vline */ if (rdev->irq.stat_regs.cik.disp_int & LB_D1_VLINE_INTERRUPT) { rdev->irq.stat_regs.cik.disp_int &= ~LB_D1_VLINE_INTERRUPT; DRM_DEBUG("IH: D1 vline\n"); } break; default: DRM_DEBUG("Unhandled interrupt: %d %d\n", src_id, src_data); break; } break; case 2: /* D2 vblank/vline */ switch (src_data) { case 0: /* D2 vblank */ if (rdev->irq.stat_regs.cik.disp_int_cont & LB_D2_VBLANK_INTERRUPT) { if (rdev->irq.crtc_vblank_int[1]) { drm_handle_vblank(rdev->ddev, 1); rdev->pm.vblank_sync = true; wake_up(&rdev->irq.vblank_queue); } if (atomic_read(&rdev->irq.pflip[1])) radeon_crtc_handle_flip(rdev, 1); rdev->irq.stat_regs.cik.disp_int_cont &= ~LB_D2_VBLANK_INTERRUPT; DRM_DEBUG("IH: D2 vblank\n"); } break; case 1: /* D2 vline */ if (rdev->irq.stat_regs.cik.disp_int_cont & LB_D2_VLINE_INTERRUPT) { rdev->irq.stat_regs.cik.disp_int_cont &= ~LB_D2_VLINE_INTERRUPT; DRM_DEBUG("IH: D2 vline\n"); } break; default: DRM_DEBUG("Unhandled interrupt: %d %d\n", src_id, src_data); break; } break; case 3: /* D3 vblank/vline */ switch (src_data) { case 0: /* D3 vblank */ if (rdev->irq.stat_regs.cik.disp_int_cont2 & LB_D3_VBLANK_INTERRUPT) { if (rdev->irq.crtc_vblank_int[2]) { drm_handle_vblank(rdev->ddev, 2); rdev->pm.vblank_sync = true; wake_up(&rdev->irq.vblank_queue); } if (atomic_read(&rdev->irq.pflip[2])) radeon_crtc_handle_flip(rdev, 2); rdev->irq.stat_regs.cik.disp_int_cont2 &= ~LB_D3_VBLANK_INTERRUPT; DRM_DEBUG("IH: D3 vblank\n"); } break; case 1: /* D3 vline */ if (rdev->irq.stat_regs.cik.disp_int_cont2 & LB_D3_VLINE_INTERRUPT) { rdev->irq.stat_regs.cik.disp_int_cont2 &= ~LB_D3_VLINE_INTERRUPT; DRM_DEBUG("IH: D3 vline\n"); } break; default: DRM_DEBUG("Unhandled interrupt: %d %d\n", src_id, src_data); break; } break; case 4: /* D4 vblank/vline */ switch (src_data) { case 0: /* D4 vblank */ if (rdev->irq.stat_regs.cik.disp_int_cont3 & LB_D4_VBLANK_INTERRUPT) { if (rdev->irq.crtc_vblank_int[3]) { drm_handle_vblank(rdev->ddev, 3); rdev->pm.vblank_sync = true; wake_up(&rdev->irq.vblank_queue); } if (atomic_read(&rdev->irq.pflip[3])) radeon_crtc_handle_flip(rdev, 3); rdev->irq.stat_regs.cik.disp_int_cont3 &= ~LB_D4_VBLANK_INTERRUPT; DRM_DEBUG("IH: D4 vblank\n"); } break; case 1: /* D4 vline */ if (rdev->irq.stat_regs.cik.disp_int_cont3 & LB_D4_VLINE_INTERRUPT) { rdev->irq.stat_regs.cik.disp_int_cont3 &= ~LB_D4_VLINE_INTERRUPT; DRM_DEBUG("IH: D4 vline\n"); } break; default: DRM_DEBUG("Unhandled interrupt: %d %d\n", src_id, src_data); break; } break; case 5: /* D5 vblank/vline */ switch (src_data) { case 0: /* D5 vblank */ if (rdev->irq.stat_regs.cik.disp_int_cont4 & LB_D5_VBLANK_INTERRUPT) { if (rdev->irq.crtc_vblank_int[4]) { drm_handle_vblank(rdev->ddev, 4); rdev->pm.vblank_sync = true; wake_up(&rdev->irq.vblank_queue); } if (atomic_read(&rdev->irq.pflip[4])) radeon_crtc_handle_flip(rdev, 4); rdev->irq.stat_regs.cik.disp_int_cont4 &= ~LB_D5_VBLANK_INTERRUPT; DRM_DEBUG("IH: D5 vblank\n"); } break; case 1: /* D5 vline */ if (rdev->irq.stat_regs.cik.disp_int_cont4 & LB_D5_VLINE_INTERRUPT) { rdev->irq.stat_regs.cik.disp_int_cont4 &= ~LB_D5_VLINE_INTERRUPT; DRM_DEBUG("IH: D5 vline\n"); } break; default: DRM_DEBUG("Unhandled interrupt: %d %d\n", src_id, src_data); break; } break; case 6: /* D6 vblank/vline */ switch (src_data) { case 0: /* D6 vblank */ if (rdev->irq.stat_regs.cik.disp_int_cont5 & LB_D6_VBLANK_INTERRUPT) { if (rdev->irq.crtc_vblank_int[5]) { drm_handle_vblank(rdev->ddev, 5); rdev->pm.vblank_sync = true; wake_up(&rdev->irq.vblank_queue); } if (atomic_read(&rdev->irq.pflip[5])) radeon_crtc_handle_flip(rdev, 5); rdev->irq.stat_regs.cik.disp_int_cont5 &= ~LB_D6_VBLANK_INTERRUPT; DRM_DEBUG("IH: D6 vblank\n"); } break; case 1: /* D6 vline */ if (rdev->irq.stat_regs.cik.disp_int_cont5 & LB_D6_VLINE_INTERRUPT) { rdev->irq.stat_regs.cik.disp_int_cont5 &= ~LB_D6_VLINE_INTERRUPT; DRM_DEBUG("IH: D6 vline\n"); } break; default: DRM_DEBUG("Unhandled interrupt: %d %d\n", src_id, src_data); break; } break; case 42: /* HPD hotplug */ switch (src_data) { case 0: if (rdev->irq.stat_regs.cik.disp_int & DC_HPD1_INTERRUPT) { rdev->irq.stat_regs.cik.disp_int &= ~DC_HPD1_INTERRUPT; queue_hotplug = true; DRM_DEBUG("IH: HPD1\n"); } break; case 1: if (rdev->irq.stat_regs.cik.disp_int_cont & DC_HPD2_INTERRUPT) { rdev->irq.stat_regs.cik.disp_int_cont &= ~DC_HPD2_INTERRUPT; queue_hotplug = true; DRM_DEBUG("IH: HPD2\n"); } break; case 2: if (rdev->irq.stat_regs.cik.disp_int_cont2 & DC_HPD3_INTERRUPT) { rdev->irq.stat_regs.cik.disp_int_cont2 &= ~DC_HPD3_INTERRUPT; queue_hotplug = true; DRM_DEBUG("IH: HPD3\n"); } break; case 3: if (rdev->irq.stat_regs.cik.disp_int_cont3 & DC_HPD4_INTERRUPT) { rdev->irq.stat_regs.cik.disp_int_cont3 &= ~DC_HPD4_INTERRUPT; queue_hotplug = true; DRM_DEBUG("IH: HPD4\n"); } break; case 4: if (rdev->irq.stat_regs.cik.disp_int_cont4 & DC_HPD5_INTERRUPT) { rdev->irq.stat_regs.cik.disp_int_cont4 &= ~DC_HPD5_INTERRUPT; queue_hotplug = true; DRM_DEBUG("IH: HPD5\n"); } break; case 5: if (rdev->irq.stat_regs.cik.disp_int_cont5 & DC_HPD6_INTERRUPT) { rdev->irq.stat_regs.cik.disp_int_cont5 &= ~DC_HPD6_INTERRUPT; queue_hotplug = true; DRM_DEBUG("IH: HPD6\n"); } break; default: DRM_DEBUG("Unhandled interrupt: %d %d\n", src_id, src_data); break; } break; case 146: case 147: dev_err(rdev->dev, "GPU fault detected: %d 0x%08x\n", src_id, src_data); dev_err(rdev->dev, " VM_CONTEXT1_PROTECTION_FAULT_ADDR 0x%08X\n", RREG32(VM_CONTEXT1_PROTECTION_FAULT_ADDR)); dev_err(rdev->dev, " VM_CONTEXT1_PROTECTION_FAULT_STATUS 0x%08X\n", RREG32(VM_CONTEXT1_PROTECTION_FAULT_STATUS)); /* reset addr and status */ WREG32_P(VM_CONTEXT1_CNTL2, 1, ~1); break; case 176: /* GFX RB CP_INT */ case 177: /* GFX IB CP_INT */ radeon_fence_process(rdev, RADEON_RING_TYPE_GFX_INDEX); break; case 181: /* CP EOP event */ DRM_DEBUG("IH: CP EOP\n"); /* XXX check the bitfield order! */ me_id = (ring_id & 0x60) >> 5; pipe_id = (ring_id & 0x18) >> 3; queue_id = (ring_id & 0x7) >> 0; switch (me_id) { case 0: radeon_fence_process(rdev, RADEON_RING_TYPE_GFX_INDEX); break; case 1: /* XXX compute */ break; case 2: /* XXX compute */ break; } break; case 184: /* CP Privileged reg access */ DRM_ERROR("Illegal register access in command stream\n"); /* XXX check the bitfield order! */ me_id = (ring_id & 0x60) >> 5; pipe_id = (ring_id & 0x18) >> 3; queue_id = (ring_id & 0x7) >> 0; switch (me_id) { case 0: /* This results in a full GPU reset, but all we need to do is soft * reset the CP for gfx */ queue_reset = true; break; case 1: /* XXX compute */ break; case 2: /* XXX compute */ break; } break; case 185: /* CP Privileged inst */ DRM_ERROR("Illegal instruction in command stream\n"); /* XXX check the bitfield order! */ me_id = (ring_id & 0x60) >> 5; pipe_id = (ring_id & 0x18) >> 3; queue_id = (ring_id & 0x7) >> 0; switch (me_id) { case 0: /* This results in a full GPU reset, but all we need to do is soft * reset the CP for gfx */ queue_reset = true; break; case 1: /* XXX compute */ break; case 2: /* XXX compute */ break; } break; case 224: /* SDMA trap event */ /* XXX check the bitfield order! */ me_id = (ring_id & 0x3) >> 0; queue_id = (ring_id & 0xc) >> 2; DRM_DEBUG("IH: SDMA trap\n"); switch (me_id) { case 0: switch (queue_id) { case 0: radeon_fence_process(rdev, R600_RING_TYPE_DMA_INDEX); break; case 1: /* XXX compute */ break; case 2: /* XXX compute */ break; } break; case 1: switch (queue_id) { case 0: radeon_fence_process(rdev, CAYMAN_RING_TYPE_DMA1_INDEX); break; case 1: /* XXX compute */ break; case 2: /* XXX compute */ break; } break; } break; case 241: /* SDMA Privileged inst */ case 247: /* SDMA Privileged inst */ DRM_ERROR("Illegal instruction in SDMA command stream\n"); /* XXX check the bitfield order! */ me_id = (ring_id & 0x3) >> 0; queue_id = (ring_id & 0xc) >> 2; switch (me_id) { case 0: switch (queue_id) { case 0: queue_reset = true; break; case 1: /* XXX compute */ queue_reset = true; break; case 2: /* XXX compute */ queue_reset = true; break; } break; case 1: switch (queue_id) { case 0: queue_reset = true; break; case 1: /* XXX compute */ queue_reset = true; break; case 2: /* XXX compute */ queue_reset = true; break; } break; } break; case 233: /* GUI IDLE */ DRM_DEBUG("IH: GUI idle\n"); break; default: DRM_DEBUG("Unhandled interrupt: %d %d\n", src_id, src_data); break; } /* wptr/rptr are in bytes! */ rptr += 16; rptr &= rdev->ih.ptr_mask; } if (queue_hotplug) schedule_work(&rdev->hotplug_work); if (queue_reset) schedule_work(&rdev->reset_work); rdev->ih.rptr = rptr; WREG32(IH_RB_RPTR, rdev->ih.rptr); atomic_set(&rdev->ih.lock, 0); /* make sure wptr hasn't changed while processing */ wptr = cik_get_ih_wptr(rdev); if (wptr != rptr) goto restart_ih; return IRQ_HANDLED; }