From: Ayaz A Siddiqui <ayaz.siddiqui@xxxxxxxxx> Xe-HP and latest devices support Flat CCS which reserved a portion of the device memory to store compression metadata, during the clearing of device memory buffer object we also need to clear the associated CCS buffer. Flat CCS memory can not be directly accessed by S/W. Address of CCS buffer associated main BO is automatically calculated by device itself. KMD/UMD can only access this buffer indirectly using XY_CTRL_SURF_COPY_BLT cmd via the address of device memory buffer. v2: Fixed issues with platform naming [Lucas] v3: Rebased [Ram] Used the round_up funcs [Bob] v4: Fixed ccs blk calculation [Ram] Added Kdoc on flat-ccs. Cc: CQ Tang <cq.tang@xxxxxxxxx> Signed-off-by: Ayaz A Siddiqui <ayaz.siddiqui@xxxxxxxxx> Signed-off-by: Ramalingam C <ramalingam.c@xxxxxxxxx> --- drivers/gpu/drm/i915/gt/intel_gpu_commands.h | 15 ++ drivers/gpu/drm/i915/gt/intel_migrate.c | 145 ++++++++++++++++++- 2 files changed, 156 insertions(+), 4 deletions(-) diff --git a/drivers/gpu/drm/i915/gt/intel_gpu_commands.h b/drivers/gpu/drm/i915/gt/intel_gpu_commands.h index f8253012d166..166de5436c4a 100644 --- a/drivers/gpu/drm/i915/gt/intel_gpu_commands.h +++ b/drivers/gpu/drm/i915/gt/intel_gpu_commands.h @@ -203,6 +203,21 @@ #define GFX_OP_DRAWRECT_INFO ((0x3<<29)|(0x1d<<24)|(0x80<<16)|(0x3)) #define GFX_OP_DRAWRECT_INFO_I965 ((0x7900<<16)|0x2) +#define XY_CTRL_SURF_INSTR_SIZE 5 +#define MI_FLUSH_DW_SIZE 3 +#define XY_CTRL_SURF_COPY_BLT ((2 << 29) | (0x48 << 22) | 3) +#define SRC_ACCESS_TYPE_SHIFT 21 +#define DST_ACCESS_TYPE_SHIFT 20 +#define CCS_SIZE_SHIFT 8 +#define XY_CTRL_SURF_MOCS_SHIFT 25 +#define NUM_CCS_BYTES_PER_BLOCK 256 +#define NUM_BYTES_PER_CCS_BYTE 256 +#define NUM_CCS_BLKS_PER_XFER 1024 +#define INDIRECT_ACCESS 0 +#define DIRECT_ACCESS 1 +#define MI_FLUSH_LLC BIT(9) +#define MI_FLUSH_CCS BIT(16) + #define COLOR_BLT_CMD (2 << 29 | 0x40 << 22 | (5 - 2)) #define XY_COLOR_BLT_CMD (2 << 29 | 0x50 << 22) #define SRC_COPY_BLT_CMD (2 << 29 | 0x43 << 22) diff --git a/drivers/gpu/drm/i915/gt/intel_migrate.c b/drivers/gpu/drm/i915/gt/intel_migrate.c index 20444d6ceb3c..9f9cd2649377 100644 --- a/drivers/gpu/drm/i915/gt/intel_migrate.c +++ b/drivers/gpu/drm/i915/gt/intel_migrate.c @@ -16,6 +16,8 @@ struct insert_pte_data { }; #define CHUNK_SZ SZ_8M /* ~1ms at 8GiB/s preemption delay */ +#define GET_CCS_BYTES(i915, size) (HAS_FLAT_CCS(i915) ? \ + DIV_ROUND_UP(size, NUM_BYTES_PER_CCS_BYTE) : 0) static bool engine_supports_migration(struct intel_engine_cs *engine) { @@ -467,6 +469,113 @@ static bool wa_1209644611_applies(int ver, u32 size) return height % 4 == 3 && height <= 8; } +/** + * DOC: Flat-CCS - Memory compression for Local memory + * + * On Xe-HP and later devices, we use dedicated compression control state (CCS) + * stored in local memory for each surface, to support the 3D and media + * compression formats. + * + * The memory required for the CCS of the entire local memory is 1/256 of the + * local memory size. So before the kernel boot, the required memory is reserved + * for the CCS data and a secure register will be programmed with the CCS base + * address. + * + * Flat CCS data needs to be cleared when a lmem object is allocated. + * And CCS data can be copied in and out of CCS region through + * XY_CTRL_SURF_COPY_BLT. CPU can't access the CCS data directly. + * + * When we exaust the lmem, if the object's placements support smem, then we can + * directly decompress the compressed lmem object into smem and start using it + * from smem itself. + * + * But when we need to swapout the compressed lmem object into a smem region + * though objects' placement doesn't support smem, then we copy the lmem content + * as it is into smem region along with ccs data (using XY_CTRL_SURF_COPY_BLT). + * When the object is referred, lmem content will be swaped in along with + * restoration of the CCS data (using XY_CTRL_SURF_COPY_BLT) at corresponding + * location. + */ + +static inline u32 *i915_flush_dw(u32 *cmd, u64 dst, u32 flags) +{ + /* Mask the 3 LSB to use the PPGTT address space */ + *cmd++ = MI_FLUSH_DW | flags; + *cmd++ = lower_32_bits(dst); + *cmd++ = upper_32_bits(dst); + + return cmd; +} + +static u32 calc_ctrl_surf_instr_size(struct drm_i915_private *i915, int size) +{ + u32 num_cmds, num_blks, total_size; + + if (!GET_CCS_BYTES(i915, size)) + return 0; + + /* + * XY_CTRL_SURF_COPY_BLT transfers CCS in 256 byte + * blocks. one XY_CTRL_SURF_COPY_BLT command can + * trnasfer upto 1024 blocks. + */ + num_blks = DIV_ROUND_UP(GET_CCS_BYTES(i915, size), + NUM_CCS_BYTES_PER_BLOCK); + num_cmds = DIV_ROUND_UP(num_blks, NUM_CCS_BLKS_PER_XFER); + total_size = (XY_CTRL_SURF_INSTR_SIZE) * num_cmds; + + /* + * We need to add a flush before and after + * XY_CTRL_SURF_COPY_BLT + */ + total_size += 2 * MI_FLUSH_DW_SIZE; + return total_size; +} + +static u32 *_i915_ctrl_surf_copy_blt(u32 *cmd, u64 src_addr, u64 dst_addr, + u8 src_mem_access, u8 dst_mem_access, + int src_mocs, int dst_mocs, + u16 num_ccs_blocks) +{ + int i = num_ccs_blocks; + + /* + * The XY_CTRL_SURF_COPY_BLT instruction is used to copy the CCS + * data in and out of the CCS region. + * + * We can copy at most 1024 blocks of 256 bytes using one + * XY_CTRL_SURF_COPY_BLT instruction. + * + * In case we need to copy more than 1024 blocks, we need to add + * another instruction to the same batch buffer. + * + * 1024 blocks of 256 bytes of CCS represent a total 256KB of CCS. + * + * 256 KB of CCS represents 256 * 256 KB = 64 MB of LMEM. + */ + do { + /* + * We use logical AND with 1023 since the size field + * takes values which is in the range of 0 - 1023 + */ + *cmd++ = ((XY_CTRL_SURF_COPY_BLT) | + (src_mem_access << SRC_ACCESS_TYPE_SHIFT) | + (dst_mem_access << DST_ACCESS_TYPE_SHIFT) | + (((i - 1) & 1023) << CCS_SIZE_SHIFT)); + *cmd++ = lower_32_bits(src_addr); + *cmd++ = ((upper_32_bits(src_addr) & 0xFFFF) | + (src_mocs << XY_CTRL_SURF_MOCS_SHIFT)); + *cmd++ = lower_32_bits(dst_addr); + *cmd++ = ((upper_32_bits(dst_addr) & 0xFFFF) | + (dst_mocs << XY_CTRL_SURF_MOCS_SHIFT)); + src_addr += SZ_64M; + dst_addr += SZ_64M; + i -= NUM_CCS_BLKS_PER_XFER; + } while (i > 0); + + return cmd; +} + static int emit_copy(struct i915_request *rq, u32 dst_offset, u32 src_offset, int size) { @@ -614,16 +723,23 @@ intel_context_migrate_copy(struct intel_context *ce, return err; } -static int emit_clear(struct i915_request *rq, u64 offset, int size, u32 value) +static int emit_clear(struct i915_request *rq, u64 offset, int size, + u32 value, bool is_lmem) { - const int ver = GRAPHICS_VER(rq->engine->i915); + struct drm_i915_private *i915 = rq->engine->i915; + const int ver = GRAPHICS_VER(i915); + u32 num_ccs_blks, ccs_ring_size; u32 *cs; GEM_BUG_ON(size >> PAGE_SHIFT > S16_MAX); offset += (u64)rq->engine->instance << 32; - cs = intel_ring_begin(rq, ver >= 8 ? 8 : 6); + /* Clear flat css only when value is 0 */ + ccs_ring_size = (is_lmem && !value) ? + calc_ctrl_surf_instr_size(i915, size) : 0; + + cs = intel_ring_begin(rq, round_up(ver >= 8 ? 8 + ccs_ring_size : 6, 2)); if (IS_ERR(cs)) return PTR_ERR(cs); @@ -646,6 +762,27 @@ static int emit_clear(struct i915_request *rq, u64 offset, int size, u32 value) *cs++ = value; } + if (is_lmem && HAS_FLAT_CCS(i915) && !value) { + num_ccs_blks = DIV_ROUND_UP(GET_CCS_BYTES(i915, size), + NUM_CCS_BYTES_PER_BLOCK); + + /* + * Flat CCS surface can only be accessed via + * XY_CTRL_SURF_COPY_BLT CMD and using indirect + * mapping of associated LMEM. + * We can clear ccs surface by writing all 0s, + * so we will flush the previously cleared buffer + * and use it as a source. + */ + cs = i915_flush_dw(cs, offset, MI_FLUSH_LLC | MI_FLUSH_CCS); + cs = _i915_ctrl_surf_copy_blt(cs, offset, offset, + DIRECT_ACCESS, INDIRECT_ACCESS, + 1, 1, num_ccs_blks); + cs = i915_flush_dw(cs, offset, MI_FLUSH_LLC | MI_FLUSH_CCS); + + if (ccs_ring_size & 1) + *cs++ = MI_NOOP; + } intel_ring_advance(rq, cs); return 0; } @@ -711,7 +848,7 @@ intel_context_migrate_clear(struct intel_context *ce, if (err) goto out_rq; - err = emit_clear(rq, offset, len, value); + err = emit_clear(rq, offset, len, value, is_lmem); /* Arbitration is re-enabled between requests. */ out_rq: -- 2.20.1