Current Path : /sys/amd64/compile/hs32/modules/usr/src/sys/modules/mvs/@/amd64/compile/hs32/modules/usr/src/sys/modules/geom/geom_stripe/@/dev/drm/ |
FreeBSD hs32.drive.ne.jp 9.1-RELEASE FreeBSD 9.1-RELEASE #1: Wed Jan 14 12:18:08 JST 2015 root@hs32.drive.ne.jp:/sys/amd64/compile/hs32 amd64 |
Current File : //sys/amd64/compile/hs32/modules/usr/src/sys/modules/mvs/@/amd64/compile/hs32/modules/usr/src/sys/modules/geom/geom_stripe/@/dev/drm/via_verifier.c |
/*- * Copyright 2004 The Unichrome Project. All Rights Reserved. * Copyright 2005 Thomas Hellstrom. All Rights Reserved. * * 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, sub license, * 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 (including the * next paragraph) 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 NON-INFRINGEMENT. IN NO EVENT SHALL * THE AUTHOR(S), AND/OR THE COPYRIGHT HOLDER(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. * * Author: Thomas Hellstrom 2004, 2005. * This code was written using docs obtained under NDA from VIA Inc. * * Don't run this code directly on an AGP buffer. Due to cache problems it will * be very slow. */ #include <sys/cdefs.h> __FBSDID("$FreeBSD: release/9.1.0/sys/dev/drm/via_verifier.c 203288 2010-01-31 14:30:39Z rnoland $"); #include "dev/drm/via_3d_reg.h" #include "dev/drm/drmP.h" #include "dev/drm/drm.h" #include "dev/drm/via_drm.h" #include "dev/drm/via_verifier.h" #include "dev/drm/via_drv.h" typedef enum { state_command, state_header2, state_header1, state_vheader5, state_vheader6, state_error } verifier_state_t; typedef enum { no_check = 0, check_for_header2, check_for_header1, check_for_header2_err, check_for_header1_err, check_for_fire, check_z_buffer_addr0, check_z_buffer_addr1, check_z_buffer_addr_mode, check_destination_addr0, check_destination_addr1, check_destination_addr_mode, check_for_dummy, check_for_dd, check_texture_addr0, check_texture_addr1, check_texture_addr2, check_texture_addr3, check_texture_addr4, check_texture_addr5, check_texture_addr6, check_texture_addr7, check_texture_addr8, check_texture_addr_mode, check_for_vertex_count, check_number_texunits, forbidden_command } hazard_t; /* * Associates each hazard above with a possible multi-command * sequence. For example an address that is split over multiple * commands and that needs to be checked at the first command * that does not include any part of the address. */ static drm_via_sequence_t seqs[] = { no_sequence, no_sequence, no_sequence, no_sequence, no_sequence, no_sequence, z_address, z_address, z_address, dest_address, dest_address, dest_address, no_sequence, no_sequence, tex_address, tex_address, tex_address, tex_address, tex_address, tex_address, tex_address, tex_address, tex_address, tex_address, no_sequence }; typedef struct { unsigned int code; hazard_t hz; } hz_init_t; static hz_init_t init_table1[] = { {0xf2, check_for_header2_err}, {0xf0, check_for_header1_err}, {0xee, check_for_fire}, {0xcc, check_for_dummy}, {0xdd, check_for_dd}, {0x00, no_check}, {0x10, check_z_buffer_addr0}, {0x11, check_z_buffer_addr1}, {0x12, check_z_buffer_addr_mode}, {0x13, no_check}, {0x14, no_check}, {0x15, no_check}, {0x23, no_check}, {0x24, no_check}, {0x33, no_check}, {0x34, no_check}, {0x35, no_check}, {0x36, no_check}, {0x37, no_check}, {0x38, no_check}, {0x39, no_check}, {0x3A, no_check}, {0x3B, no_check}, {0x3C, no_check}, {0x3D, no_check}, {0x3E, no_check}, {0x40, check_destination_addr0}, {0x41, check_destination_addr1}, {0x42, check_destination_addr_mode}, {0x43, no_check}, {0x44, no_check}, {0x50, no_check}, {0x51, no_check}, {0x52, no_check}, {0x53, no_check}, {0x54, no_check}, {0x55, no_check}, {0x56, no_check}, {0x57, no_check}, {0x58, no_check}, {0x70, no_check}, {0x71, no_check}, {0x78, no_check}, {0x79, no_check}, {0x7A, no_check}, {0x7B, no_check}, {0x7C, no_check}, {0x7D, check_for_vertex_count} }; static hz_init_t init_table2[] = { {0xf2, check_for_header2_err}, {0xf0, check_for_header1_err}, {0xee, check_for_fire}, {0xcc, check_for_dummy}, {0x00, check_texture_addr0}, {0x01, check_texture_addr0}, {0x02, check_texture_addr0}, {0x03, check_texture_addr0}, {0x04, check_texture_addr0}, {0x05, check_texture_addr0}, {0x06, check_texture_addr0}, {0x07, check_texture_addr0}, {0x08, check_texture_addr0}, {0x09, check_texture_addr0}, {0x20, check_texture_addr1}, {0x21, check_texture_addr1}, {0x22, check_texture_addr1}, {0x23, check_texture_addr4}, {0x2B, check_texture_addr3}, {0x2C, check_texture_addr3}, {0x2D, check_texture_addr3}, {0x2E, check_texture_addr3}, {0x2F, check_texture_addr3}, {0x30, check_texture_addr3}, {0x31, check_texture_addr3}, {0x32, check_texture_addr3}, {0x33, check_texture_addr3}, {0x34, check_texture_addr3}, {0x4B, check_texture_addr5}, {0x4C, check_texture_addr6}, {0x51, check_texture_addr7}, {0x52, check_texture_addr8}, {0x77, check_texture_addr2}, {0x78, no_check}, {0x79, no_check}, {0x7A, no_check}, {0x7B, check_texture_addr_mode}, {0x7C, no_check}, {0x7D, no_check}, {0x7E, no_check}, {0x7F, no_check}, {0x80, no_check}, {0x81, no_check}, {0x82, no_check}, {0x83, no_check}, {0x85, no_check}, {0x86, no_check}, {0x87, no_check}, {0x88, no_check}, {0x89, no_check}, {0x8A, no_check}, {0x90, no_check}, {0x91, no_check}, {0x92, no_check}, {0x93, no_check} }; static hz_init_t init_table3[] = { {0xf2, check_for_header2_err}, {0xf0, check_for_header1_err}, {0xcc, check_for_dummy}, {0x00, check_number_texunits} }; static hazard_t table1[256]; static hazard_t table2[256]; static hazard_t table3[256]; static __inline__ int eat_words(const uint32_t ** buf, const uint32_t * buf_end, unsigned num_words) { if ((buf_end - *buf) >= num_words) { *buf += num_words; return 0; } DRM_ERROR("Illegal termination of DMA command buffer\n"); return 1; } /* * Partially stolen from drm_memory.h */ static __inline__ drm_local_map_t *via_drm_lookup_agp_map(drm_via_state_t *seq, unsigned long offset, unsigned long size, struct drm_device * dev) { drm_local_map_t *map = seq->map_cache; if (map && map->offset <= offset && (offset + size) <= (map->offset + map->size)) { return map; } TAILQ_FOREACH(map, &dev->maplist, link) { if (map->offset <= offset && (offset + size) <= (map->offset + map->size) && !(map->flags & _DRM_RESTRICTED) && (map->type == _DRM_AGP)) { seq->map_cache = map; return map; } } return NULL; } /* * Require that all AGP texture levels reside in the same AGP map which should * be mappable by the client. This is not a big restriction. * FIXME: To actually enforce this security policy strictly, drm_rmmap * would have to wait for dma quiescent before removing an AGP map. * The via_drm_lookup_agp_map call in reality seems to take * very little CPU time. */ static __inline__ int finish_current_sequence(drm_via_state_t * cur_seq) { switch (cur_seq->unfinished) { case z_address: DRM_DEBUG("Z Buffer start address is 0x%x\n", cur_seq->z_addr); break; case dest_address: DRM_DEBUG("Destination start address is 0x%x\n", cur_seq->d_addr); break; case tex_address: if (cur_seq->agp_texture) { unsigned start = cur_seq->tex_level_lo[cur_seq->texture]; unsigned end = cur_seq->tex_level_hi[cur_seq->texture]; unsigned long lo = ~0, hi = 0, tmp; uint32_t *addr, *pitch, *height, tex; unsigned i; int npot; if (end > 9) end = 9; if (start > 9) start = 9; addr = &(cur_seq->t_addr[tex = cur_seq->texture][start]); pitch = &(cur_seq->pitch[tex][start]); height = &(cur_seq->height[tex][start]); npot = cur_seq->tex_npot[tex]; for (i = start; i <= end; ++i) { tmp = *addr++; if (tmp < lo) lo = tmp; if (i == 0 && npot) tmp += (*height++ * *pitch++); else tmp += (*height++ << *pitch++); if (tmp > hi) hi = tmp; } if (!via_drm_lookup_agp_map (cur_seq, lo, hi - lo, cur_seq->dev)) { DRM_ERROR ("AGP texture is not in allowed map\n"); return 2; } } break; default: break; } cur_seq->unfinished = no_sequence; return 0; } static __inline__ int investigate_hazard(uint32_t cmd, hazard_t hz, drm_via_state_t * cur_seq) { register uint32_t tmp, *tmp_addr; if (cur_seq->unfinished && (cur_seq->unfinished != seqs[hz])) { int ret; if ((ret = finish_current_sequence(cur_seq))) return ret; } switch (hz) { case check_for_header2: if (cmd == HALCYON_HEADER2) return 1; return 0; case check_for_header1: if ((cmd & HALCYON_HEADER1MASK) == HALCYON_HEADER1) return 1; return 0; case check_for_header2_err: if (cmd == HALCYON_HEADER2) return 1; DRM_ERROR("Illegal DMA HALCYON_HEADER2 command\n"); break; case check_for_header1_err: if ((cmd & HALCYON_HEADER1MASK) == HALCYON_HEADER1) return 1; DRM_ERROR("Illegal DMA HALCYON_HEADER1 command\n"); break; case check_for_fire: if ((cmd & HALCYON_FIREMASK) == HALCYON_FIRECMD) return 1; DRM_ERROR("Illegal DMA HALCYON_FIRECMD command\n"); break; case check_for_dummy: if (HC_DUMMY == cmd) return 0; DRM_ERROR("Illegal DMA HC_DUMMY command\n"); break; case check_for_dd: if (0xdddddddd == cmd) return 0; DRM_ERROR("Illegal DMA 0xdddddddd command\n"); break; case check_z_buffer_addr0: cur_seq->unfinished = z_address; cur_seq->z_addr = (cur_seq->z_addr & 0xFF000000) | (cmd & 0x00FFFFFF); return 0; case check_z_buffer_addr1: cur_seq->unfinished = z_address; cur_seq->z_addr = (cur_seq->z_addr & 0x00FFFFFF) | ((cmd & 0xFF) << 24); return 0; case check_z_buffer_addr_mode: cur_seq->unfinished = z_address; if ((cmd & 0x0000C000) == 0) return 0; DRM_ERROR("Attempt to place Z buffer in system memory\n"); return 2; case check_destination_addr0: cur_seq->unfinished = dest_address; cur_seq->d_addr = (cur_seq->d_addr & 0xFF000000) | (cmd & 0x00FFFFFF); return 0; case check_destination_addr1: cur_seq->unfinished = dest_address; cur_seq->d_addr = (cur_seq->d_addr & 0x00FFFFFF) | ((cmd & 0xFF) << 24); return 0; case check_destination_addr_mode: cur_seq->unfinished = dest_address; if ((cmd & 0x0000C000) == 0) return 0; DRM_ERROR ("Attempt to place 3D drawing buffer in system memory\n"); return 2; case check_texture_addr0: cur_seq->unfinished = tex_address; tmp = (cmd >> 24); tmp_addr = &cur_seq->t_addr[cur_seq->texture][tmp]; *tmp_addr = (*tmp_addr & 0xFF000000) | (cmd & 0x00FFFFFF); return 0; case check_texture_addr1: cur_seq->unfinished = tex_address; tmp = ((cmd >> 24) - 0x20); tmp += tmp << 1; tmp_addr = &cur_seq->t_addr[cur_seq->texture][tmp]; *tmp_addr = (*tmp_addr & 0x00FFFFFF) | ((cmd & 0xFF) << 24); tmp_addr++; *tmp_addr = (*tmp_addr & 0x00FFFFFF) | ((cmd & 0xFF00) << 16); tmp_addr++; *tmp_addr = (*tmp_addr & 0x00FFFFFF) | ((cmd & 0xFF0000) << 8); return 0; case check_texture_addr2: cur_seq->unfinished = tex_address; cur_seq->tex_level_lo[tmp = cur_seq->texture] = cmd & 0x3F; cur_seq->tex_level_hi[tmp] = (cmd & 0xFC0) >> 6; return 0; case check_texture_addr3: cur_seq->unfinished = tex_address; tmp = ((cmd >> 24) - HC_SubA_HTXnL0Pit); if (tmp == 0 && (cmd & HC_HTXnEnPit_MASK)) { cur_seq->pitch[cur_seq->texture][tmp] = (cmd & HC_HTXnLnPit_MASK); cur_seq->tex_npot[cur_seq->texture] = 1; } else { cur_seq->pitch[cur_seq->texture][tmp] = (cmd & HC_HTXnLnPitE_MASK) >> HC_HTXnLnPitE_SHIFT; cur_seq->tex_npot[cur_seq->texture] = 0; if (cmd & 0x000FFFFF) { DRM_ERROR ("Unimplemented texture level 0 pitch mode.\n"); return 2; } } return 0; case check_texture_addr4: cur_seq->unfinished = tex_address; tmp_addr = &cur_seq->t_addr[cur_seq->texture][9]; *tmp_addr = (*tmp_addr & 0x00FFFFFF) | ((cmd & 0xFF) << 24); return 0; case check_texture_addr5: case check_texture_addr6: cur_seq->unfinished = tex_address; /* * Texture width. We don't care since we have the pitch. */ return 0; case check_texture_addr7: cur_seq->unfinished = tex_address; tmp_addr = &(cur_seq->height[cur_seq->texture][0]); tmp_addr[5] = 1 << ((cmd & 0x00F00000) >> 20); tmp_addr[4] = 1 << ((cmd & 0x000F0000) >> 16); tmp_addr[3] = 1 << ((cmd & 0x0000F000) >> 12); tmp_addr[2] = 1 << ((cmd & 0x00000F00) >> 8); tmp_addr[1] = 1 << ((cmd & 0x000000F0) >> 4); tmp_addr[0] = 1 << (cmd & 0x0000000F); return 0; case check_texture_addr8: cur_seq->unfinished = tex_address; tmp_addr = &(cur_seq->height[cur_seq->texture][0]); tmp_addr[9] = 1 << ((cmd & 0x0000F000) >> 12); tmp_addr[8] = 1 << ((cmd & 0x00000F00) >> 8); tmp_addr[7] = 1 << ((cmd & 0x000000F0) >> 4); tmp_addr[6] = 1 << (cmd & 0x0000000F); return 0; case check_texture_addr_mode: cur_seq->unfinished = tex_address; if (2 == (tmp = cmd & 0x00000003)) { DRM_ERROR ("Attempt to fetch texture from system memory.\n"); return 2; } cur_seq->agp_texture = (tmp == 3); cur_seq->tex_palette_size[cur_seq->texture] = (cmd >> 16) & 0x000000007; return 0; case check_for_vertex_count: cur_seq->vertex_count = cmd & 0x0000FFFF; return 0; case check_number_texunits: cur_seq->multitex = (cmd >> 3) & 1; return 0; default: DRM_ERROR("Illegal DMA data: 0x%x\n", cmd); return 2; } return 2; } static __inline__ int via_check_prim_list(uint32_t const **buffer, const uint32_t * buf_end, drm_via_state_t * cur_seq) { drm_via_private_t *dev_priv = (drm_via_private_t *) cur_seq->dev->dev_private; uint32_t a_fire, bcmd, dw_count; int ret = 0; int have_fire; const uint32_t *buf = *buffer; while (buf < buf_end) { have_fire = 0; if ((buf_end - buf) < 2) { DRM_ERROR ("Unexpected termination of primitive list.\n"); ret = 1; break; } if ((*buf & HC_ACMD_MASK) != HC_ACMD_HCmdB) break; bcmd = *buf++; if ((*buf & HC_ACMD_MASK) != HC_ACMD_HCmdA) { DRM_ERROR("Expected Vertex List A command, got 0x%x\n", *buf); ret = 1; break; } a_fire = *buf++ | HC_HPLEND_MASK | HC_HPMValidN_MASK | HC_HE3Fire_MASK; /* * How many dwords per vertex ? */ if (cur_seq->agp && ((bcmd & (0xF << 11)) == 0)) { DRM_ERROR("Illegal B command vertex data for AGP.\n"); ret = 1; break; } dw_count = 0; if (bcmd & (1 << 7)) dw_count += (cur_seq->multitex) ? 2 : 1; if (bcmd & (1 << 8)) dw_count += (cur_seq->multitex) ? 2 : 1; if (bcmd & (1 << 9)) dw_count++; if (bcmd & (1 << 10)) dw_count++; if (bcmd & (1 << 11)) dw_count++; if (bcmd & (1 << 12)) dw_count++; if (bcmd & (1 << 13)) dw_count++; if (bcmd & (1 << 14)) dw_count++; while (buf < buf_end) { if (*buf == a_fire) { if (dev_priv->num_fire_offsets >= VIA_FIRE_BUF_SIZE) { DRM_ERROR("Fire offset buffer full.\n"); ret = 1; break; } dev_priv->fire_offsets[dev_priv-> num_fire_offsets++] = buf; have_fire = 1; buf++; if (buf < buf_end && *buf == a_fire) buf++; break; } if ((*buf == HALCYON_HEADER2) || ((*buf & HALCYON_FIREMASK) == HALCYON_FIRECMD)) { DRM_ERROR("Missing Vertex Fire command, " "Stray Vertex Fire command or verifier " "lost sync.\n"); ret = 1; break; } if ((ret = eat_words(&buf, buf_end, dw_count))) break; } if (buf >= buf_end && !have_fire) { DRM_ERROR("Missing Vertex Fire command or verifier " "lost sync.\n"); ret = 1; break; } if (cur_seq->agp && ((buf - cur_seq->buf_start) & 0x01)) { DRM_ERROR("AGP Primitive list end misaligned.\n"); ret = 1; break; } } *buffer = buf; return ret; } static __inline__ verifier_state_t via_check_header2(uint32_t const **buffer, const uint32_t * buf_end, drm_via_state_t * hc_state) { uint32_t cmd; int hz_mode; hazard_t hz; const uint32_t *buf = *buffer; const hazard_t *hz_table; if ((buf_end - buf) < 2) { DRM_ERROR ("Illegal termination of DMA HALCYON_HEADER2 sequence.\n"); return state_error; } buf++; cmd = (*buf++ & 0xFFFF0000) >> 16; switch (cmd) { case HC_ParaType_CmdVdata: if (via_check_prim_list(&buf, buf_end, hc_state)) return state_error; *buffer = buf; return state_command; case HC_ParaType_NotTex: hz_table = table1; break; case HC_ParaType_Tex: hc_state->texture = 0; hz_table = table2; break; case (HC_ParaType_Tex | (HC_SubType_Tex1 << 8)): hc_state->texture = 1; hz_table = table2; break; case (HC_ParaType_Tex | (HC_SubType_TexGeneral << 8)): hz_table = table3; break; case HC_ParaType_Auto: if (eat_words(&buf, buf_end, 2)) return state_error; *buffer = buf; return state_command; case (HC_ParaType_Palette | (HC_SubType_Stipple << 8)): if (eat_words(&buf, buf_end, 32)) return state_error; *buffer = buf; return state_command; case (HC_ParaType_Palette | (HC_SubType_TexPalette0 << 8)): case (HC_ParaType_Palette | (HC_SubType_TexPalette1 << 8)): DRM_ERROR("Texture palettes are rejected because of " "lack of info how to determine their size.\n"); return state_error; case (HC_ParaType_Palette | (HC_SubType_FogTable << 8)): DRM_ERROR("Fog factor palettes are rejected because of " "lack of info how to determine their size.\n"); return state_error; default: /* * There are some unimplemented HC_ParaTypes here, that * need to be implemented if the Mesa driver is extended. */ DRM_ERROR("Invalid or unimplemented HALCYON_HEADER2 " "DMA subcommand: 0x%x. Previous dword: 0x%x\n", cmd, *(buf - 2)); *buffer = buf; return state_error; } while (buf < buf_end) { cmd = *buf++; if ((hz = hz_table[cmd >> 24])) { if ((hz_mode = investigate_hazard(cmd, hz, hc_state))) { if (hz_mode == 1) { buf--; break; } return state_error; } } else if (hc_state->unfinished && finish_current_sequence(hc_state)) { return state_error; } } if (hc_state->unfinished && finish_current_sequence(hc_state)) { return state_error; } *buffer = buf; return state_command; } static __inline__ verifier_state_t via_parse_header2(drm_via_private_t * dev_priv, uint32_t const **buffer, const uint32_t * buf_end, int *fire_count) { uint32_t cmd; const uint32_t *buf = *buffer; const uint32_t *next_fire; int burst = 0; next_fire = dev_priv->fire_offsets[*fire_count]; buf++; cmd = (*buf & 0xFFFF0000) >> 16; VIA_WRITE(HC_REG_TRANS_SET + HC_REG_BASE, *buf++); switch (cmd) { case HC_ParaType_CmdVdata: while ((buf < buf_end) && (*fire_count < dev_priv->num_fire_offsets) && (*buf & HC_ACMD_MASK) == HC_ACMD_HCmdB) { while (buf <= next_fire) { VIA_WRITE(HC_REG_TRANS_SPACE + HC_REG_BASE + (burst & 63), *buf++); burst += 4; } if ((buf < buf_end) && ((*buf & HALCYON_FIREMASK) == HALCYON_FIRECMD)) buf++; if (++(*fire_count) < dev_priv->num_fire_offsets) next_fire = dev_priv->fire_offsets[*fire_count]; } break; default: while (buf < buf_end) { if (*buf == HC_HEADER2 || (*buf & HALCYON_HEADER1MASK) == HALCYON_HEADER1 || (*buf & VIA_VIDEOMASK) == VIA_VIDEO_HEADER5 || (*buf & VIA_VIDEOMASK) == VIA_VIDEO_HEADER6) break; VIA_WRITE(HC_REG_TRANS_SPACE + HC_REG_BASE + (burst & 63), *buf++); burst += 4; } } *buffer = buf; return state_command; } static __inline__ int verify_mmio_address(uint32_t address) { if ((address > 0x3FF) && (address < 0xC00)) { DRM_ERROR("Invalid VIDEO DMA command. " "Attempt to access 3D- or command burst area.\n"); return 1; } else if ((address > 0xCFF) && (address < 0x1300)) { DRM_ERROR("Invalid VIDEO DMA command. " "Attempt to access PCI DMA area.\n"); return 1; } else if (address > 0x13FF) { DRM_ERROR("Invalid VIDEO DMA command. " "Attempt to access VGA registers.\n"); return 1; } return 0; } static __inline__ int verify_video_tail(uint32_t const **buffer, const uint32_t * buf_end, uint32_t dwords) { const uint32_t *buf = *buffer; if (buf_end - buf < dwords) { DRM_ERROR("Illegal termination of video command.\n"); return 1; } while (dwords--) { if (*buf++) { DRM_ERROR("Illegal video command tail.\n"); return 1; } } *buffer = buf; return 0; } static __inline__ verifier_state_t via_check_header1(uint32_t const **buffer, const uint32_t * buf_end) { uint32_t cmd; const uint32_t *buf = *buffer; verifier_state_t ret = state_command; while (buf < buf_end) { cmd = *buf; if ((cmd > ((0x3FF >> 2) | HALCYON_HEADER1)) && (cmd < ((0xC00 >> 2) | HALCYON_HEADER1))) { if ((cmd & HALCYON_HEADER1MASK) != HALCYON_HEADER1) break; DRM_ERROR("Invalid HALCYON_HEADER1 command. " "Attempt to access 3D- or command burst area.\n"); ret = state_error; break; } else if (cmd > ((0xCFF >> 2) | HALCYON_HEADER1)) { if ((cmd & HALCYON_HEADER1MASK) != HALCYON_HEADER1) break; DRM_ERROR("Invalid HALCYON_HEADER1 command. " "Attempt to access VGA registers.\n"); ret = state_error; break; } else { buf += 2; } } *buffer = buf; return ret; } static __inline__ verifier_state_t via_parse_header1(drm_via_private_t * dev_priv, uint32_t const **buffer, const uint32_t * buf_end) { register uint32_t cmd; const uint32_t *buf = *buffer; while (buf < buf_end) { cmd = *buf; if ((cmd & HALCYON_HEADER1MASK) != HALCYON_HEADER1) break; VIA_WRITE((cmd & ~HALCYON_HEADER1MASK) << 2, *++buf); buf++; } *buffer = buf; return state_command; } static __inline__ verifier_state_t via_check_vheader5(uint32_t const **buffer, const uint32_t * buf_end) { uint32_t data; const uint32_t *buf = *buffer; if (buf_end - buf < 4) { DRM_ERROR("Illegal termination of video header5 command\n"); return state_error; } data = *buf++ & ~VIA_VIDEOMASK; if (verify_mmio_address(data)) return state_error; data = *buf++; if (*buf++ != 0x00F50000) { DRM_ERROR("Illegal header5 header data\n"); return state_error; } if (*buf++ != 0x00000000) { DRM_ERROR("Illegal header5 header data\n"); return state_error; } if (eat_words(&buf, buf_end, data)) return state_error; if ((data & 3) && verify_video_tail(&buf, buf_end, 4 - (data & 3))) return state_error; *buffer = buf; return state_command; } static __inline__ verifier_state_t via_parse_vheader5(drm_via_private_t * dev_priv, uint32_t const **buffer, const uint32_t * buf_end) { uint32_t addr, count, i; const uint32_t *buf = *buffer; addr = *buf++ & ~VIA_VIDEOMASK; i = count = *buf; buf += 3; while (i--) { VIA_WRITE(addr, *buf++); } if (count & 3) buf += 4 - (count & 3); *buffer = buf; return state_command; } static __inline__ verifier_state_t via_check_vheader6(uint32_t const **buffer, const uint32_t * buf_end) { uint32_t data; const uint32_t *buf = *buffer; uint32_t i; if (buf_end - buf < 4) { DRM_ERROR("Illegal termination of video header6 command\n"); return state_error; } buf++; data = *buf++; if (*buf++ != 0x00F60000) { DRM_ERROR("Illegal header6 header data\n"); return state_error; } if (*buf++ != 0x00000000) { DRM_ERROR("Illegal header6 header data\n"); return state_error; } if ((buf_end - buf) < (data << 1)) { DRM_ERROR("Illegal termination of video header6 command\n"); return state_error; } for (i = 0; i < data; ++i) { if (verify_mmio_address(*buf++)) return state_error; buf++; } data <<= 1; if ((data & 3) && verify_video_tail(&buf, buf_end, 4 - (data & 3))) return state_error; *buffer = buf; return state_command; } static __inline__ verifier_state_t via_parse_vheader6(drm_via_private_t * dev_priv, uint32_t const **buffer, const uint32_t * buf_end) { uint32_t addr, count, i; const uint32_t *buf = *buffer; i = count = *++buf; buf += 3; while (i--) { addr = *buf++; VIA_WRITE(addr, *buf++); } count <<= 1; if (count & 3) buf += 4 - (count & 3); *buffer = buf; return state_command; } int via_verify_command_stream(const uint32_t * buf, unsigned int size, struct drm_device * dev, int agp) { drm_via_private_t *dev_priv = (drm_via_private_t *) dev->dev_private; drm_via_state_t *hc_state = &dev_priv->hc_state; drm_via_state_t saved_state = *hc_state; uint32_t cmd; const uint32_t *buf_end = buf + (size >> 2); verifier_state_t state = state_command; int cme_video; int supported_3d; cme_video = (dev_priv->chipset == VIA_PRO_GROUP_A || dev_priv->chipset == VIA_DX9_0); supported_3d = dev_priv->chipset != VIA_DX9_0; hc_state->dev = dev; hc_state->unfinished = no_sequence; hc_state->map_cache = NULL; hc_state->agp = agp; hc_state->buf_start = buf; dev_priv->num_fire_offsets = 0; while (buf < buf_end) { switch (state) { case state_header2: state = via_check_header2(&buf, buf_end, hc_state); break; case state_header1: state = via_check_header1(&buf, buf_end); break; case state_vheader5: state = via_check_vheader5(&buf, buf_end); break; case state_vheader6: state = via_check_vheader6(&buf, buf_end); break; case state_command: if ((HALCYON_HEADER2 == (cmd = *buf)) && supported_3d) state = state_header2; else if ((cmd & HALCYON_HEADER1MASK) == HALCYON_HEADER1) state = state_header1; else if (cme_video && (cmd & VIA_VIDEOMASK) == VIA_VIDEO_HEADER5) state = state_vheader5; else if (cme_video && (cmd & VIA_VIDEOMASK) == VIA_VIDEO_HEADER6) state = state_vheader6; else if ((cmd == HALCYON_HEADER2) && !supported_3d) { DRM_ERROR("Accelerated 3D is not supported on this chipset yet.\n"); state = state_error; } else { DRM_ERROR ("Invalid / Unimplemented DMA HEADER command. 0x%x\n", cmd); state = state_error; } break; case state_error: default: *hc_state = saved_state; return -EINVAL; } } if (state == state_error) { *hc_state = saved_state; return -EINVAL; } return 0; } int via_parse_command_stream(struct drm_device * dev, const uint32_t * buf, unsigned int size) { drm_via_private_t *dev_priv = (drm_via_private_t *) dev->dev_private; uint32_t cmd; const uint32_t *buf_end = buf + (size >> 2); verifier_state_t state = state_command; int fire_count = 0; while (buf < buf_end) { switch (state) { case state_header2: state = via_parse_header2(dev_priv, &buf, buf_end, &fire_count); break; case state_header1: state = via_parse_header1(dev_priv, &buf, buf_end); break; case state_vheader5: state = via_parse_vheader5(dev_priv, &buf, buf_end); break; case state_vheader6: state = via_parse_vheader6(dev_priv, &buf, buf_end); break; case state_command: if (HALCYON_HEADER2 == (cmd = *buf)) state = state_header2; else if ((cmd & HALCYON_HEADER1MASK) == HALCYON_HEADER1) state = state_header1; else if ((cmd & VIA_VIDEOMASK) == VIA_VIDEO_HEADER5) state = state_vheader5; else if ((cmd & VIA_VIDEOMASK) == VIA_VIDEO_HEADER6) state = state_vheader6; else { DRM_ERROR ("Invalid / Unimplemented DMA HEADER command. 0x%x\n", cmd); state = state_error; } break; case state_error: default: return -EINVAL; } } if (state == state_error) { return -EINVAL; } return 0; } static void setup_hazard_table(hz_init_t init_table[], hazard_t table[], int size) { int i; for (i = 0; i < 256; ++i) { table[i] = forbidden_command; } for (i = 0; i < size; ++i) { table[init_table[i].code] = init_table[i].hz; } } void via_init_command_verifier(void) { setup_hazard_table(init_table1, table1, sizeof(init_table1) / sizeof(hz_init_t)); setup_hazard_table(init_table2, table2, sizeof(init_table2) / sizeof(hz_init_t)); setup_hazard_table(init_table3, table3, sizeof(init_table3) / sizeof(hz_init_t)); }