/* * Common HID report descriptor helpers * * Copyright 2021 RĂ©mi Bernon for CodeWeavers * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301, USA */ #if 0 #pragma makedep unix #endif #include #include #include #include "ntstatus.h" #define WIN32_NO_STATUS #include "winternl.h" #include "winioctl.h" #include "hidusage.h" #include "ddk/wdm.h" #include "ddk/hidsdi.h" #include "wine/debug.h" #include "wine/hid.h" #include "unix_private.h" WINE_DEFAULT_DEBUG_CHANNEL(hid); static BOOL hid_report_descriptor_append(struct hid_report_descriptor *desc, const BYTE *buffer, SIZE_T size) { BYTE *tmp = desc->data; if (desc->size + size > desc->max_size) { desc->max_size = max(desc->max_size * 3 / 2, desc->size + size); desc->data = realloc(tmp, desc->max_size); } if (!desc->data) { free(tmp); return FALSE; } memcpy(desc->data + desc->size, buffer, size); desc->size += size; return TRUE; } #include "psh_hid_macros.h" static BOOL hid_report_descriptor_append_usage(struct hid_report_descriptor *desc, USAGE usage) { const BYTE template[] = { USAGE(2, usage), }; return hid_report_descriptor_append(desc, template, sizeof(template)); } static BOOL hid_device_begin_collection(struct hid_report_descriptor *desc, const USAGE_AND_PAGE *usage, BYTE type) { const BYTE template[] = { USAGE_PAGE(2, usage->UsagePage), USAGE(2, usage->Usage), COLLECTION(1, type), }; return hid_report_descriptor_append(desc, template, sizeof(template)); } static BOOL hid_device_end_collection(struct hid_report_descriptor *desc) { static const BYTE template[] = { END_COLLECTION, }; return hid_report_descriptor_append(desc, template, sizeof(template)); } BOOL hid_device_begin_report_descriptor(struct unix_device *iface, const USAGE_AND_PAGE *device_usage) { struct hid_report_descriptor *desc = &iface->hid_report_descriptor; memset(desc, 0, sizeof(*desc)); return hid_device_begin_collection(desc, device_usage, Application); } BOOL hid_device_end_report_descriptor(struct unix_device *iface) { struct hid_report_descriptor *desc = &iface->hid_report_descriptor; return hid_device_end_collection(desc); } BOOL hid_device_begin_input_report(struct unix_device *iface, const USAGE_AND_PAGE *physical_usage) { struct hid_report_descriptor *desc = &iface->hid_report_descriptor; struct hid_device_state *state = &iface->hid_device_state; const BYTE report_id = ++desc->next_report_id[HidP_Input]; const BYTE template[] = { REPORT_ID(1, report_id), }; if (state->report_len) { ERR("input report already created\n"); return FALSE; } state->id = report_id; state->bit_size += 8; if (!hid_device_begin_collection(desc, physical_usage, Physical)) return FALSE; return hid_report_descriptor_append(desc, template, sizeof(template)); } BOOL hid_device_end_input_report(struct unix_device *iface) { struct hid_report_descriptor *desc = &iface->hid_report_descriptor; struct hid_device_state *state = &iface->hid_device_state; state->report_len = (state->bit_size + 7) / 8; if (!(state->report_buf = calloc(1, state->report_len))) return FALSE; if (!(state->last_report_buf = calloc(1, state->report_len))) return FALSE; state->report_buf[0] = state->id; state->last_report_buf[0] = state->id; return hid_device_end_collection(desc); } static BOOL hid_device_add_button_count(struct unix_device *iface, BYTE count) { USHORT offset = iface->hid_device_state.bit_size / 8; if ((iface->hid_device_state.bit_size % 8) && !iface->hid_device_state.button_count) ERR("buttons should start byte aligned, missing padding!\n"); else if (iface->hid_device_state.bit_size + count > 0x80000) ERR("report size overflow, too many elements!\n"); else { if (!iface->hid_device_state.button_count) iface->hid_device_state.button_start = offset; iface->hid_device_state.button_count += count; iface->hid_device_state.bit_size += count; return TRUE; } return FALSE; } BOOL hid_device_add_buttons(struct unix_device *iface, USAGE usage_page, USAGE usage_min, USAGE usage_max) { struct hid_report_descriptor *desc = &iface->hid_report_descriptor; const USHORT count = usage_max - usage_min + 1; const BYTE template[] = { USAGE_PAGE(2, usage_page), USAGE_MINIMUM(2, usage_min), USAGE_MAXIMUM(2, usage_max), LOGICAL_MINIMUM(1, 0), LOGICAL_MAXIMUM(1, 1), REPORT_COUNT(2, count), REPORT_SIZE(1, 1), INPUT(1, Data|Var|Abs), }; const BYTE template_pad[] = { REPORT_COUNT(1, 8 - (count % 8)), REPORT_SIZE(1, 1), INPUT(1, Cnst|Var|Abs), }; if (!hid_device_add_button_count(iface, usage_max - usage_min + 1)) return FALSE; if (!hid_report_descriptor_append(desc, template, sizeof(template))) return FALSE; if ((count % 8) && !hid_report_descriptor_append(desc, template_pad, sizeof(template_pad))) return FALSE; return TRUE; } static BOOL hid_device_add_hatswitch_count(struct unix_device *iface, BYTE count) { USHORT offset = iface->hid_device_state.bit_size / 8; if (iface->hid_device_state.button_count) ERR("hatswitches should be added before buttons!\n"); else if ((iface->hid_device_state.bit_size % 8)) ERR("hatswitches should be byte aligned, missing padding!\n"); else if (iface->hid_device_state.bit_size + 8 * count > 0x80000) ERR("report size overflow, too many elements!\n"); else { if (!iface->hid_device_state.hatswitch_count) iface->hid_device_state.hatswitch_start = offset; iface->hid_device_state.hatswitch_count += count; iface->hid_device_state.bit_size += 8 * count; return TRUE; } return FALSE; } BOOL hid_device_add_hatswitch(struct unix_device *iface, INT count) { struct hid_report_descriptor *desc = &iface->hid_report_descriptor; const BYTE template[] = { USAGE_PAGE(1, HID_USAGE_PAGE_GENERIC), USAGE(1, HID_USAGE_GENERIC_HATSWITCH), LOGICAL_MINIMUM(1, 1), LOGICAL_MAXIMUM(1, 8), REPORT_SIZE(1, 8), REPORT_COUNT(4, count), UNIT(1, 0x0e /* none */), INPUT(1, Data|Var|Abs|Null), }; if (!hid_device_add_hatswitch_count(iface, count)) return FALSE; return hid_report_descriptor_append(desc, template, sizeof(template)); } static BOOL hid_device_add_axis_count(struct unix_device *iface, BOOL rel, BYTE count, USAGE usage_page, const USAGE *usages) { struct hid_device_state *state = &iface->hid_device_state; USHORT i, offset = state->bit_size / 8; if (!rel && state->rel_axis_count) ERR("absolute axes should be added before relative axes!\n"); else if (state->button_count || state->hatswitch_count) ERR("axes should be added before buttons or hatswitches!\n"); else if ((state->bit_size % 8)) ERR("axes should be byte aligned, missing padding!\n"); else if (state->bit_size + 32 * count > 0x80000) ERR("report size overflow, too many elements!\n"); else if (rel) { if (!state->rel_axis_count) state->rel_axis_start = offset; state->rel_axis_count += count; state->bit_size += 32 * count; return TRUE; } else { if (state->abs_axis_count + count > ARRAY_SIZE(state->abs_axis_usages)) { ERR("absolute axis usage overflow, too many elements!\n"); return FALSE; } for (i = 0; i < count; ++i) { state->abs_axis_usages[state->abs_axis_count + i].UsagePage = usage_page; state->abs_axis_usages[state->abs_axis_count + i].Usage = usages[i]; } if (!state->abs_axis_count) state->abs_axis_start = offset; state->abs_axis_count += count; state->bit_size += 32 * count; return TRUE; } return FALSE; } BOOL hid_device_add_axes(struct unix_device *iface, BYTE count, USAGE usage_page, const USAGE *usages, BOOL rel, LONG min, LONG max) { struct hid_report_descriptor *desc = &iface->hid_report_descriptor; const BYTE template_begin[] = { USAGE_PAGE(1, usage_page), COLLECTION(1, Physical), }; const BYTE template_end[] = { END_COLLECTION, }; const BYTE template[] = { LOGICAL_MINIMUM(4, min), LOGICAL_MAXIMUM(4, max), REPORT_SIZE(1, 32), REPORT_COUNT(1, count), INPUT(1, Data|Var|(rel ? Rel : Abs)), }; int i; if (!hid_device_add_axis_count(iface, rel, count, usage_page, usages)) return FALSE; if (!hid_report_descriptor_append(desc, template_begin, sizeof(template_begin))) return FALSE; for (i = 0; i < count; i++) { if (!hid_report_descriptor_append_usage(desc, usages[i])) return FALSE; } if (!hid_report_descriptor_append(desc, template, sizeof(template))) return FALSE; if (!hid_report_descriptor_append(desc, template_end, sizeof(template_end))) return FALSE; return TRUE; } #include "pshpack1.h" struct hid_haptics_waveform { UINT16 intensity; BYTE manual_trigger; BYTE repeat_count; }; #include "poppack.h" BOOL hid_device_add_haptics(struct unix_device *iface) { struct hid_report_descriptor *desc = &iface->hid_report_descriptor; const BYTE haptics_features_report = ++desc->next_report_id[HidP_Feature]; const BYTE haptics_waveform_report = ++desc->next_report_id[HidP_Output]; const BYTE haptics_template[] = { USAGE_PAGE(2, HID_USAGE_PAGE_HAPTICS), USAGE(1, HID_USAGE_HAPTICS_SIMPLE_CONTROLLER), COLLECTION(1, Logical), REPORT_ID(1, haptics_features_report), USAGE(1, HID_USAGE_HAPTICS_WAVEFORM_LIST), COLLECTION(1, NamedArray), USAGE(4, (HID_USAGE_PAGE_ORDINAL<<16)|HAPTICS_WAVEFORM_RUMBLE_ORDINAL), /* HID_USAGE_HAPTICS_WAVEFORM_RUMBLE */ USAGE(4, (HID_USAGE_PAGE_ORDINAL<<16)|HAPTICS_WAVEFORM_BUZZ_ORDINAL), /* HID_USAGE_HAPTICS_WAVEFORM_BUZZ */ REPORT_COUNT(1, 2), REPORT_SIZE(1, 16), FEATURE(1, Data|Var|Abs|Null), END_COLLECTION, USAGE(1, HID_USAGE_HAPTICS_DURATION_LIST), COLLECTION(1, NamedArray), USAGE(4, (HID_USAGE_PAGE_ORDINAL<<16)|HAPTICS_WAVEFORM_RUMBLE_ORDINAL), /* 0 (HID_USAGE_HAPTICS_WAVEFORM_RUMBLE) */ USAGE(4, (HID_USAGE_PAGE_ORDINAL<<16)|HAPTICS_WAVEFORM_BUZZ_ORDINAL), /* 0 (HID_USAGE_HAPTICS_WAVEFORM_BUZZ) */ REPORT_COUNT(1, 2), REPORT_SIZE(1, 16), FEATURE(1, Data|Var|Abs|Null), END_COLLECTION, USAGE(1, HID_USAGE_HAPTICS_WAVEFORM_CUTOFF_TIME), UNIT(2, 0x1001), /* seconds */ UNIT_EXPONENT(1, -3), /* 10^-3 */ LOGICAL_MINIMUM(4, 0x00000000), LOGICAL_MAXIMUM(4, 0x7fffffff), REPORT_SIZE(1, 32), REPORT_COUNT(1, 1), FEATURE(1, Data|Var|Abs), /* reset global items */ UNIT(1, 0), /* None */ UNIT_EXPONENT(1, 0), REPORT_ID(1, haptics_waveform_report), USAGE(1, HID_USAGE_HAPTICS_INTENSITY), LOGICAL_MINIMUM(4, 0x00000000), LOGICAL_MAXIMUM(4, 0x0000ffff), REPORT_SIZE(1, 16), REPORT_COUNT(1, 1), OUTPUT(1, Data|Var|Abs), USAGE(1, HID_USAGE_HAPTICS_MANUAL_TRIGGER), LOGICAL_MINIMUM(1, HAPTICS_WAVEFORM_NONE_ORDINAL), LOGICAL_MAXIMUM(1, HAPTICS_WAVEFORM_LAST_ORDINAL), REPORT_SIZE(1, 8), REPORT_COUNT(1, 1), OUTPUT(1, Data|Var|Abs), USAGE(1, HID_USAGE_HAPTICS_REPEAT_COUNT), LOGICAL_MINIMUM(1, 0), LOGICAL_MAXIMUM(1, 1), REPORT_SIZE(1, 8), REPORT_COUNT(1, 1), OUTPUT(1, Data|Var|Abs), END_COLLECTION, }; iface->hid_haptics.features_report = haptics_features_report; iface->hid_haptics.waveform_report = haptics_waveform_report; iface->hid_haptics.features.waveform_list[0] = HID_USAGE_HAPTICS_WAVEFORM_RUMBLE; iface->hid_haptics.features.waveform_list[1] = HID_USAGE_HAPTICS_WAVEFORM_BUZZ; iface->hid_haptics.features.duration_list[0] = 0; iface->hid_haptics.features.duration_list[1] = 0; iface->hid_haptics.features.waveform_cutoff_time_ms = 1000; return hid_report_descriptor_append(desc, haptics_template, sizeof(haptics_template)); } #include "pshpack1.h" struct pid_device_control { BYTE control_index; }; static const USAGE pid_device_control_usages[] = { 0, /* HID nary collection indexes start at 1 */ PID_USAGE_DC_ENABLE_ACTUATORS, PID_USAGE_DC_DISABLE_ACTUATORS, PID_USAGE_DC_STOP_ALL_EFFECTS, PID_USAGE_DC_DEVICE_RESET, PID_USAGE_DC_DEVICE_PAUSE, PID_USAGE_DC_DEVICE_CONTINUE, }; struct pid_device_gain { BYTE value; }; struct pid_effect_control { BYTE index; BYTE control_index; BYTE iterations; }; static const USAGE pid_effect_control_usages[] = { 0, /* HID nary collection indexes start at 1 */ PID_USAGE_OP_EFFECT_START, PID_USAGE_OP_EFFECT_START_SOLO, PID_USAGE_OP_EFFECT_STOP, }; struct pid_effect_update { BYTE index; BYTE type_index; UINT16 duration; UINT16 trigger_repeat_interval; UINT16 sample_period; UINT16 start_delay; BYTE trigger_button; BYTE enable_bits; UINT16 direction[2]; }; struct pid_set_periodic { BYTE index; UINT16 magnitude; INT16 offset; UINT16 phase; UINT16 period; }; struct pid_set_envelope { BYTE index; UINT16 attack_level; UINT16 fade_level; UINT16 attack_time; UINT16 fade_time; }; struct pid_set_condition { BYTE index; BYTE condition_index; INT16 center_point_offset; INT16 positive_coefficient; INT16 negative_coefficient; UINT16 positive_saturation; UINT16 negative_saturation; UINT16 dead_band; }; struct pid_set_constant_force { BYTE index; INT16 magnitude; }; struct pid_set_ramp_force { BYTE index; INT16 ramp_start; INT16 ramp_end; }; struct pid_effect_state { BYTE flags; BYTE index; }; #include "poppack.h" static BOOL hid_descriptor_add_set_periodic(struct unix_device *iface) { struct hid_report_descriptor *desc = &iface->hid_report_descriptor; const BYTE report_id = ++desc->next_report_id[HidP_Output]; const BYTE template[] = { /* Periodic Report Definition */ USAGE(1, PID_USAGE_SET_PERIODIC_REPORT), COLLECTION(1, Logical), REPORT_ID(1, report_id), USAGE(1, PID_USAGE_EFFECT_BLOCK_INDEX), LOGICAL_MINIMUM(1, 0), LOGICAL_MAXIMUM(1, 0x7f), REPORT_SIZE(1, 8), REPORT_COUNT(1, 1), OUTPUT(1, Data|Var|Abs), USAGE(1, PID_USAGE_MAGNITUDE), LOGICAL_MINIMUM(1, 0), LOGICAL_MAXIMUM(2, 0x7fff), PHYSICAL_MINIMUM(1, 0), PHYSICAL_MAXIMUM(2, 10000), REPORT_SIZE(1, 16), REPORT_COUNT(1, 1), OUTPUT(1, Data|Var|Abs), PHYSICAL_MINIMUM(1, 0), PHYSICAL_MAXIMUM(1, 0), USAGE(1, PID_USAGE_OFFSET), LOGICAL_MINIMUM(2, 0x8000), LOGICAL_MAXIMUM(2, 0x7fff), PHYSICAL_MINIMUM(2, -10000), PHYSICAL_MAXIMUM(2, +10000), REPORT_SIZE(1, 16), REPORT_COUNT(1, 1), OUTPUT(1, Data|Var|Abs), PHYSICAL_MINIMUM(1, 0), PHYSICAL_MAXIMUM(1, 0), USAGE(1, PID_USAGE_PHASE), UNIT(1, 0x14), /* Eng Rot:Angular Pos */ UNIT_EXPONENT(1, -2), LOGICAL_MINIMUM(1, 0), LOGICAL_MAXIMUM(4, 36000), REPORT_SIZE(1, 16), REPORT_COUNT(1, 1), OUTPUT(1, Data|Var|Abs), USAGE(1, PID_USAGE_PERIOD), UNIT(2, 0x1003), /* Eng Lin:Time */ UNIT_EXPONENT(1, -3), /* 10^-3 */ LOGICAL_MINIMUM(1, 0), LOGICAL_MAXIMUM(2, 0x7fff), REPORT_SIZE(1, 16), REPORT_COUNT(1, 1), OUTPUT(1, Data|Var|Abs), UNIT_EXPONENT(1, 0), UNIT(1, 0), /* None */ END_COLLECTION, }; iface->hid_physical.set_periodic_report = report_id; return hid_report_descriptor_append(desc, template, sizeof(template)); } static BOOL hid_descriptor_add_set_envelope(struct unix_device *iface) { struct hid_report_descriptor *desc = &iface->hid_report_descriptor; const BYTE report_id = ++desc->next_report_id[HidP_Output]; const BYTE template[] = { /* Envelope Report Definition */ USAGE(1, PID_USAGE_SET_ENVELOPE_REPORT), COLLECTION(1, Logical), REPORT_ID(1, report_id), USAGE(1, PID_USAGE_EFFECT_BLOCK_INDEX), LOGICAL_MINIMUM(1, 0), LOGICAL_MAXIMUM(1, 0x7f), REPORT_SIZE(1, 8), REPORT_COUNT(1, 1), OUTPUT(1, Data|Var|Abs), USAGE(1, PID_USAGE_ATTACK_LEVEL), USAGE(1, PID_USAGE_FADE_LEVEL), LOGICAL_MINIMUM(1, 0), LOGICAL_MAXIMUM(2, 0x7fff), PHYSICAL_MINIMUM(1, 0), PHYSICAL_MAXIMUM(2, 10000), REPORT_SIZE(1, 16), REPORT_COUNT(1, 2), OUTPUT(1, Data|Var|Abs), PHYSICAL_MINIMUM(1, 0), PHYSICAL_MAXIMUM(1, 0), USAGE(1, PID_USAGE_ATTACK_TIME), USAGE(1, PID_USAGE_FADE_TIME), UNIT(2, 0x1003), /* Eng Lin:Time */ UNIT_EXPONENT(1, -3), LOGICAL_MINIMUM(1, 0), LOGICAL_MAXIMUM(2, 0x7fff), REPORT_SIZE(1, 16), REPORT_COUNT(1, 2), OUTPUT(1, Data|Var|Abs), PHYSICAL_MAXIMUM(1, 0), UNIT_EXPONENT(1, 0), UNIT(1, 0), END_COLLECTION, }; iface->hid_physical.set_envelope_report = report_id; return hid_report_descriptor_append(desc, template, sizeof(template)); } static BOOL hid_descriptor_add_set_condition(struct unix_device *iface) { struct hid_report_descriptor *desc = &iface->hid_report_descriptor; const BYTE report_id = ++desc->next_report_id[HidP_Output]; const BYTE template[] = { /* Condition Report Definition */ USAGE(1, PID_USAGE_SET_CONDITION_REPORT), COLLECTION(1, Logical), REPORT_ID(1, report_id), USAGE(1, PID_USAGE_EFFECT_BLOCK_INDEX), LOGICAL_MINIMUM(1, 0), LOGICAL_MAXIMUM(1, 0x7f), REPORT_SIZE(1, 8), REPORT_COUNT(1, 1), OUTPUT(1, Data|Var|Abs), USAGE(1, PID_USAGE_PARAMETER_BLOCK_OFFSET), LOGICAL_MINIMUM(1, 0x00), LOGICAL_MAXIMUM(1, 0x01), REPORT_SIZE(1, 8), REPORT_COUNT(1, 1), OUTPUT(1, Data|Var|Abs), USAGE(1, PID_USAGE_CP_OFFSET), USAGE(1, PID_USAGE_POSITIVE_COEFFICIENT), USAGE(1, PID_USAGE_NEGATIVE_COEFFICIENT), LOGICAL_MINIMUM(2, 0x8000), LOGICAL_MAXIMUM(2, 0x7fff), PHYSICAL_MINIMUM(2, -10000), PHYSICAL_MAXIMUM(2, +10000), REPORT_SIZE(1, 16), REPORT_COUNT(1, 3), OUTPUT(1, Data|Var|Abs), PHYSICAL_MINIMUM(1, 0), PHYSICAL_MAXIMUM(1, 0), USAGE(1, PID_USAGE_POSITIVE_SATURATION), USAGE(1, PID_USAGE_NEGATIVE_SATURATION), USAGE(1, PID_USAGE_DEAD_BAND), LOGICAL_MINIMUM(1, 0), LOGICAL_MAXIMUM(4, 0xffff), PHYSICAL_MINIMUM(1, 0), PHYSICAL_MAXIMUM(2, +10000), REPORT_SIZE(1, 16), REPORT_COUNT(1, 3), OUTPUT(1, Data|Var|Abs), PHYSICAL_MINIMUM(1, 0), PHYSICAL_MAXIMUM(1, 0), END_COLLECTION, }; iface->hid_physical.set_condition_report = report_id; return hid_report_descriptor_append(desc, template, sizeof(template)); } static BOOL hid_descriptor_add_set_constant_force(struct unix_device *iface) { struct hid_report_descriptor *desc = &iface->hid_report_descriptor; const BYTE report_id = ++desc->next_report_id[HidP_Output]; const BYTE template[] = { /* Constant Force Report Definition */ USAGE(1, PID_USAGE_SET_CONSTANT_FORCE_REPORT), COLLECTION(1, Logical), REPORT_ID(1, report_id), USAGE(1, PID_USAGE_EFFECT_BLOCK_INDEX), LOGICAL_MINIMUM(1, 0), LOGICAL_MAXIMUM(1, 0x7f), REPORT_SIZE(1, 8), REPORT_COUNT(1, 1), OUTPUT(1, Data|Var|Abs), USAGE(1, PID_USAGE_MAGNITUDE), LOGICAL_MINIMUM(2, 0x8000), LOGICAL_MAXIMUM(2, 0x7fff), PHYSICAL_MINIMUM(2, -10000), PHYSICAL_MAXIMUM(2, +10000), REPORT_SIZE(1, 16), REPORT_COUNT(1, 1), OUTPUT(1, Data|Var|Abs), PHYSICAL_MINIMUM(1, 0), PHYSICAL_MAXIMUM(1, 0), END_COLLECTION, }; iface->hid_physical.set_constant_force_report = report_id; return hid_report_descriptor_append(desc, template, sizeof(template)); } static BOOL hid_descriptor_add_set_ramp_force(struct unix_device *iface) { struct hid_report_descriptor *desc = &iface->hid_report_descriptor; const BYTE report_id = ++desc->next_report_id[HidP_Output]; const BYTE template[] = { /* Ramp Force Report Definition */ USAGE(1, PID_USAGE_SET_RAMP_FORCE_REPORT), COLLECTION(1, Logical), REPORT_ID(1, report_id), USAGE(1, PID_USAGE_EFFECT_BLOCK_INDEX), LOGICAL_MINIMUM(1, 0), LOGICAL_MAXIMUM(1, 0x7f), REPORT_SIZE(1, 8), REPORT_COUNT(1, 1), OUTPUT(1, Data|Var|Abs), USAGE(1, PID_USAGE_RAMP_START), USAGE(1, PID_USAGE_RAMP_END), LOGICAL_MINIMUM(2, 0x8000), LOGICAL_MAXIMUM(2, 0x7fff), PHYSICAL_MINIMUM(2, -10000), PHYSICAL_MAXIMUM(2, +10000), REPORT_SIZE(1, 16), REPORT_COUNT(1, 2), OUTPUT(1, Data|Var|Abs), PHYSICAL_MINIMUM(1, 0), PHYSICAL_MAXIMUM(1, 0), END_COLLECTION, }; iface->hid_physical.set_ramp_force_report = report_id; return hid_report_descriptor_append(desc, template, sizeof(template)); } BOOL hid_device_add_physical(struct unix_device *iface, USAGE *usages, USHORT count) { struct hid_report_descriptor *desc = &iface->hid_report_descriptor; const BYTE device_control_report = ++desc->next_report_id[HidP_Output]; struct hid_device_state *state = &iface->hid_device_state; const BYTE device_control_header[] = { USAGE_PAGE(1, HID_USAGE_PAGE_PID), USAGE(1, PID_USAGE_DEVICE_CONTROL_REPORT), COLLECTION(1, Logical), REPORT_ID(1, device_control_report), USAGE(1, PID_USAGE_DEVICE_CONTROL), COLLECTION(1, Logical), }; const BYTE device_control_footer[] = { LOGICAL_MINIMUM(1, 1), LOGICAL_MAXIMUM(1, 6), REPORT_SIZE(1, 8), REPORT_COUNT(1, 1), OUTPUT(1, Data|Ary|Abs), END_COLLECTION, END_COLLECTION, }; const BYTE device_gain_report = ++desc->next_report_id[HidP_Output]; const BYTE device_gain[] = { USAGE_PAGE(1, HID_USAGE_PAGE_PID), USAGE(1, PID_USAGE_DEVICE_GAIN_REPORT), COLLECTION(1, Logical), REPORT_ID(1, device_gain_report), USAGE(1, PID_USAGE_DEVICE_GAIN), LOGICAL_MINIMUM(1, 0), LOGICAL_MAXIMUM(1, 100), PHYSICAL_MINIMUM(1, 0), PHYSICAL_MAXIMUM(2, 10000), REPORT_SIZE(1, 8), REPORT_COUNT(1, 1), OUTPUT(1, Data|Var|Abs), PHYSICAL_MINIMUM(1, 0), PHYSICAL_MAXIMUM(1, 0), END_COLLECTION, }; const BYTE effect_control_report = ++desc->next_report_id[HidP_Output]; const BYTE effect_control_header[] = { /* Control effect state */ USAGE(1, PID_USAGE_EFFECT_OPERATION_REPORT), COLLECTION(1, Logical), REPORT_ID(1, effect_control_report), USAGE(1, PID_USAGE_EFFECT_BLOCK_INDEX), LOGICAL_MINIMUM(1, 0), LOGICAL_MAXIMUM(1, 0x7f), REPORT_SIZE(1, 8), REPORT_COUNT(1, 1), OUTPUT(1, Data|Var|Abs), USAGE(1, PID_USAGE_EFFECT_OPERATION), COLLECTION(1, Logical), }; const BYTE effect_control_footer[] = { LOGICAL_MINIMUM(1, 1), LOGICAL_MAXIMUM(1, 3), REPORT_SIZE(1, 8), REPORT_COUNT(1, 1), OUTPUT(1, Data|Ary|Abs), END_COLLECTION, USAGE(1, PID_USAGE_LOOP_COUNT), LOGICAL_MINIMUM(1, 0), LOGICAL_MAXIMUM(2, 0x00ff), REPORT_SIZE(1, 8), REPORT_COUNT(1, 1), OUTPUT(1, Data|Var|Abs), END_COLLECTION, }; const BYTE effect_update_report = ++desc->next_report_id[HidP_Output]; const BYTE effect_update_header[] = { /* Set effect properties */ USAGE(1, PID_USAGE_SET_EFFECT_REPORT), COLLECTION(1, Logical), REPORT_ID(1, effect_update_report), USAGE(1, PID_USAGE_EFFECT_BLOCK_INDEX), LOGICAL_MINIMUM(1, 0), LOGICAL_MAXIMUM(1, 0x7f), REPORT_SIZE(1, 8), REPORT_COUNT(1, 1), OUTPUT(1, Data|Var|Abs), USAGE(1, PID_USAGE_EFFECT_TYPE), COLLECTION(1, Logical), }; const BYTE effect_update_footer[] = { LOGICAL_MINIMUM(1, 1), LOGICAL_MAXIMUM(1, count), REPORT_SIZE(1, 8), OUTPUT(1, Data|Ary|Abs), END_COLLECTION, USAGE(1, PID_USAGE_DURATION), USAGE(1, PID_USAGE_TRIGGER_REPEAT_INTERVAL), USAGE(1, PID_USAGE_SAMPLE_PERIOD), USAGE(1, PID_USAGE_START_DELAY), UNIT(2, 0x1003), /* Eng Lin:Time */ UNIT_EXPONENT(1, -3), /* 10^-3 */ LOGICAL_MINIMUM(1, 0), LOGICAL_MAXIMUM(2, 0x7fff), REPORT_SIZE(1, 16), REPORT_COUNT(1, 4), OUTPUT(1, Data|Var|Abs), UNIT_EXPONENT(1, 0), UNIT(1, 0), /* None */ USAGE(1, PID_USAGE_TRIGGER_BUTTON), LOGICAL_MINIMUM(1, 0), LOGICAL_MAXIMUM(2, state->button_count), REPORT_SIZE(1, 8), REPORT_COUNT(1, 1), OUTPUT(1, Data|Var|Abs|Null), USAGE(1, PID_USAGE_AXES_ENABLE), COLLECTION(1, Logical), USAGE(4, (state->abs_axis_usages[0].UsagePage<<16)|state->abs_axis_usages[0].Usage), USAGE(4, (state->abs_axis_usages[1].UsagePage<<16)|state->abs_axis_usages[1].Usage), LOGICAL_MINIMUM(1, 0), LOGICAL_MAXIMUM(1, 1), REPORT_SIZE(1, 1), REPORT_COUNT(1, 2), OUTPUT(1, Data|Var|Abs), END_COLLECTION, USAGE(1, PID_USAGE_DIRECTION_ENABLE), REPORT_COUNT(1, 1), OUTPUT(1, Data|Var|Abs), REPORT_COUNT(1, 5), OUTPUT(1, Cnst|Var|Abs), /* 5-bit pad */ USAGE(1, PID_USAGE_DIRECTION), COLLECTION(1, Logical), USAGE(4, (HID_USAGE_PAGE_ORDINAL<<16)|1), USAGE(4, (HID_USAGE_PAGE_ORDINAL<<16)|2), UNIT(1, 0x14), /* Eng Rot:Angular Pos */ UNIT_EXPONENT(1, -2), LOGICAL_MINIMUM(1, 0), LOGICAL_MAXIMUM(4, 36000), REPORT_SIZE(1, 16), REPORT_COUNT(1, 2), OUTPUT(1, Data|Var|Abs), END_COLLECTION, UNIT_EXPONENT(1, 0), UNIT(1, 0), /* None */ END_COLLECTION, }; const BYTE effect_state_report = ++desc->next_report_id[HidP_Input]; const BYTE effect_state_template[] = { /* Report effect state */ USAGE(1, PID_USAGE_STATE_REPORT), COLLECTION(1, Logical), REPORT_ID(1, effect_state_report), USAGE(1, PID_USAGE_DEVICE_PAUSED), USAGE(1, PID_USAGE_ACTUATORS_ENABLED), USAGE(1, PID_USAGE_EFFECT_PLAYING), LOGICAL_MINIMUM(1, 0), LOGICAL_MAXIMUM(1, 1), REPORT_SIZE(1, 1), REPORT_COUNT(1, 8), INPUT(1, Data|Var|Abs), USAGE(1, PID_USAGE_EFFECT_BLOCK_INDEX), LOGICAL_MINIMUM(1, 0), LOGICAL_MAXIMUM(1, 0x7f), REPORT_SIZE(1, 8), REPORT_COUNT(1, 1), INPUT(1, Data|Var|Abs), END_COLLECTION, }; struct hid_effect_state *effect_state = &iface->hid_physical.effect_state; BOOL periodic = FALSE; BOOL envelope = FALSE; BOOL condition = FALSE; BOOL constant_force = FALSE; BOOL ramp_force = FALSE; ULONG i; if (!hid_report_descriptor_append(desc, device_control_header, sizeof(device_control_header))) return FALSE; for (i = 1; i < ARRAY_SIZE(pid_device_control_usages); ++i) { if (!hid_report_descriptor_append_usage(desc, pid_device_control_usages[i])) return FALSE; } if (!hid_report_descriptor_append(desc, device_control_footer, sizeof(device_control_footer))) return FALSE; if (!hid_report_descriptor_append(desc, device_gain, sizeof(device_gain))) return FALSE; if (!hid_report_descriptor_append(desc, effect_control_header, sizeof(effect_control_header))) return FALSE; for (i = 1; i < ARRAY_SIZE(pid_effect_control_usages); ++i) { if (!hid_report_descriptor_append_usage(desc, pid_effect_control_usages[i])) return FALSE; } if (!hid_report_descriptor_append(desc, effect_control_footer, sizeof(effect_control_footer))) return FALSE; if (!hid_report_descriptor_append(desc, effect_update_header, sizeof(effect_update_header))) return FALSE; for (i = 0; i < count; ++i) { if (!hid_report_descriptor_append_usage(desc, usages[i])) return FALSE; } if (!hid_report_descriptor_append(desc, effect_update_footer, sizeof(effect_update_footer))) return FALSE; for (i = 0; i < count; ++i) { if (usages[i] == PID_USAGE_ET_SINE || usages[i] == PID_USAGE_ET_SQUARE || usages[i] == PID_USAGE_ET_TRIANGLE || usages[i] == PID_USAGE_ET_SAWTOOTH_UP || usages[i] == PID_USAGE_ET_SAWTOOTH_DOWN) periodic = envelope = TRUE; if (usages[i] == PID_USAGE_ET_SPRING || usages[i] == PID_USAGE_ET_DAMPER || usages[i] == PID_USAGE_ET_INERTIA || usages[i] == PID_USAGE_ET_FRICTION) condition = TRUE; if (usages[i] == PID_USAGE_ET_CONSTANT_FORCE) envelope = constant_force = TRUE; if (usages[i] == PID_USAGE_ET_RAMP) envelope = ramp_force = TRUE; } if (periodic && !hid_descriptor_add_set_periodic(iface)) return FALSE; if (envelope && !hid_descriptor_add_set_envelope(iface)) return FALSE; if (condition && !hid_descriptor_add_set_condition(iface)) return FALSE; if (constant_force && !hid_descriptor_add_set_constant_force(iface)) return FALSE; if (ramp_force && !hid_descriptor_add_set_ramp_force(iface)) return FALSE; if (!hid_report_descriptor_append(desc, effect_state_template, sizeof(effect_state_template))) return FALSE; /* HID nary collection indexes start at 1 */ memcpy(iface->hid_physical.effect_types + 1, usages, count * sizeof(*usages)); iface->hid_physical.device_control_report = device_control_report; iface->hid_physical.device_gain_report = device_gain_report; iface->hid_physical.effect_control_report = effect_control_report; iface->hid_physical.effect_update_report = effect_update_report; effect_state->id = effect_state_report; effect_state->report_len = sizeof(struct pid_effect_state) + 1; if (!(effect_state->report_buf = calloc(1, effect_state->report_len))) return FALSE; effect_state->report_buf[0] = effect_state->id; return TRUE; } #include "pop_hid_macros.h" static void hid_device_destroy(struct unix_device *iface) { iface->hid_vtbl->destroy(iface); free(iface->hid_report_descriptor.data); free(iface->hid_device_state.report_buf); free(iface->hid_device_state.last_report_buf); } static NTSTATUS hid_device_start(struct unix_device *iface) { return iface->hid_vtbl->start(iface); } static void hid_device_stop(struct unix_device *iface) { iface->hid_vtbl->stop(iface); } static NTSTATUS hid_device_get_report_descriptor(struct unix_device *iface, BYTE *buffer, UINT length, UINT *out_length) { *out_length = iface->hid_report_descriptor.size; if (length < iface->hid_report_descriptor.size) return STATUS_BUFFER_TOO_SMALL; memcpy(buffer, iface->hid_report_descriptor.data, iface->hid_report_descriptor.size); return STATUS_SUCCESS; } static void hid_device_set_output_report(struct unix_device *iface, HID_XFER_PACKET *packet, IO_STATUS_BLOCK *io) { struct hid_physical *physical = &iface->hid_physical; struct hid_haptics *haptics = &iface->hid_haptics; if (packet->reportId == haptics->waveform_report) { struct hid_haptics_waveform *report = (struct hid_haptics_waveform *)(packet->reportBuffer + 1); UINT16 *rumble_intensity = haptics->waveform_intensity + HAPTICS_WAVEFORM_RUMBLE_ORDINAL; UINT16 *buzz_intensity = haptics->waveform_intensity + HAPTICS_WAVEFORM_BUZZ_ORDINAL; ULONG duration_ms; io->Information = sizeof(*report) + 1; assert(packet->reportBufferLen == io->Information); if (report->manual_trigger == 0 || report->manual_trigger > HAPTICS_WAVEFORM_LAST_ORDINAL) io->Status = STATUS_INVALID_PARAMETER; else { if (report->manual_trigger == HAPTICS_WAVEFORM_STOP_ORDINAL) { memset(haptics->waveform_intensity, 0, sizeof(haptics->waveform_intensity)); io->Status = iface->hid_vtbl->haptics_stop(iface); } else { haptics->waveform_intensity[report->manual_trigger] = report->intensity; duration_ms = haptics->features.waveform_cutoff_time_ms; if (!report->repeat_count) io->Status = STATUS_SUCCESS; else io->Status = iface->hid_vtbl->haptics_start(iface, duration_ms, *rumble_intensity, *buzz_intensity); } } } else if (packet->reportId == physical->device_control_report) { struct pid_device_control *report = (struct pid_device_control *)(packet->reportBuffer + 1); USAGE control; io->Information = sizeof(*report) + 1; if (packet->reportBufferLen < io->Information) io->Status = STATUS_BUFFER_TOO_SMALL; else if (report->control_index >= ARRAY_SIZE(pid_device_control_usages)) io->Status = STATUS_INVALID_PARAMETER; else if (!(control = pid_device_control_usages[report->control_index])) io->Status = STATUS_INVALID_PARAMETER; else { io->Status = iface->hid_vtbl->physical_device_control(iface, control); if (control == PID_USAGE_DC_DEVICE_RESET && io->Status == STATUS_SUCCESS) memset(physical->effect_params, 0, sizeof(physical->effect_params)); } } else if (packet->reportId == physical->device_gain_report) { struct pid_device_gain *report = (struct pid_device_gain *)(packet->reportBuffer + 1); io->Information = sizeof(*report) + 1; if (packet->reportBufferLen < io->Information) io->Status = STATUS_BUFFER_TOO_SMALL; else io->Status = iface->hid_vtbl->physical_device_set_gain(iface, report->value); } else if (packet->reportId == physical->effect_control_report) { struct pid_effect_control *report = (struct pid_effect_control *)(packet->reportBuffer + 1); USAGE control; io->Information = sizeof(*report) + 1; if (packet->reportBufferLen < io->Information) io->Status = STATUS_BUFFER_TOO_SMALL; else if (report->control_index >= ARRAY_SIZE(pid_effect_control_usages)) io->Status = STATUS_INVALID_PARAMETER; else if (!(control = pid_effect_control_usages[report->control_index])) io->Status = STATUS_INVALID_PARAMETER; else io->Status = iface->hid_vtbl->physical_effect_control(iface, report->index, control, report->iterations); } else if (packet->reportId == physical->effect_update_report) { struct pid_effect_update *report = (struct pid_effect_update *)(packet->reportBuffer + 1); struct effect_params *params = iface->hid_physical.effect_params + report->index; USAGE effect_type; io->Information = sizeof(*report) + 1; if (packet->reportBufferLen < io->Information) io->Status = STATUS_BUFFER_TOO_SMALL; else if (report->type_index >= ARRAY_SIZE(iface->hid_physical.effect_types)) io->Status = STATUS_INVALID_PARAMETER; else if (!(effect_type = iface->hid_physical.effect_types[report->type_index])) io->Status = STATUS_INVALID_PARAMETER; else { params->effect_type = effect_type; params->duration = report->duration; params->trigger_repeat_interval = report->trigger_repeat_interval; params->sample_period = report->sample_period; params->start_delay = report->start_delay; params->trigger_button = report->trigger_button == 0xff ? 0 : report->trigger_button; params->axis_enabled[0] = (report->enable_bits & 1) != 0; params->axis_enabled[1] = (report->enable_bits & 2) != 0; params->direction_enabled = (report->enable_bits & 4) != 0; params->direction[0] = report->direction[0]; params->direction[1] = report->direction[1]; io->Status = iface->hid_vtbl->physical_effect_update(iface, report->index, params); } } else if (packet->reportId == physical->set_periodic_report) { struct pid_set_periodic *report = (struct pid_set_periodic *)(packet->reportBuffer + 1); struct effect_params *params = iface->hid_physical.effect_params + report->index; io->Information = sizeof(*report) + 1; if (packet->reportBufferLen < io->Information) io->Status = STATUS_BUFFER_TOO_SMALL; else { params->periodic.magnitude = report->magnitude; params->periodic.offset = report->offset; params->periodic.phase = report->phase; params->periodic.period = report->period; io->Status = iface->hid_vtbl->physical_effect_update(iface, report->index, params); } } else if (packet->reportId == physical->set_envelope_report) { struct pid_set_envelope *report = (struct pid_set_envelope *)(packet->reportBuffer + 1); struct effect_params *params = iface->hid_physical.effect_params + report->index; io->Information = sizeof(*report) + 1; if (packet->reportBufferLen < io->Information) io->Status = STATUS_BUFFER_TOO_SMALL; else { params->envelope.attack_level = report->attack_level; params->envelope.fade_level = report->fade_level; params->envelope.attack_time = report->attack_time; params->envelope.fade_time = report->fade_time; io->Status = iface->hid_vtbl->physical_effect_update(iface, report->index, params); } } else if (packet->reportId == physical->set_condition_report) { struct pid_set_condition *report = (struct pid_set_condition *)(packet->reportBuffer + 1); struct effect_params *params = iface->hid_physical.effect_params + report->index; struct effect_condition *condition; UINT index; io->Information = sizeof(*report) + 1; if (packet->reportBufferLen < io->Information) io->Status = STATUS_BUFFER_TOO_SMALL; else if ((index = report->condition_index) >= ARRAY_SIZE(params->condition)) io->Status = STATUS_INVALID_PARAMETER; else { if (params->condition_count <= index) params->condition_count = index + 1; condition = params->condition + index; condition->center_point_offset = report->center_point_offset; condition->positive_coefficient = report->positive_coefficient; condition->negative_coefficient = report->negative_coefficient; condition->positive_saturation = report->positive_saturation; condition->negative_saturation = report->negative_saturation; condition->dead_band = report->dead_band; io->Status = iface->hid_vtbl->physical_effect_update(iface, report->index, params); } } else if (packet->reportId == physical->set_constant_force_report) { struct pid_set_constant_force *report = (struct pid_set_constant_force *)(packet->reportBuffer + 1); struct effect_params *params = iface->hid_physical.effect_params + report->index; io->Information = sizeof(*report) + 1; if (packet->reportBufferLen < io->Information) io->Status = STATUS_BUFFER_TOO_SMALL; else { params->constant_force.magnitude = report->magnitude; io->Status = iface->hid_vtbl->physical_effect_update(iface, report->index, params); } } else if (packet->reportId == physical->set_ramp_force_report) { struct pid_set_ramp_force *report = (struct pid_set_ramp_force *)(packet->reportBuffer + 1); struct effect_params *params = iface->hid_physical.effect_params + report->index; io->Information = sizeof(*report) + 1; if (packet->reportBufferLen < io->Information) io->Status = STATUS_BUFFER_TOO_SMALL; else { params->ramp_force.ramp_start = report->ramp_start; params->ramp_force.ramp_end = report->ramp_end; io->Status = iface->hid_vtbl->physical_effect_update(iface, report->index, params); } } else { io->Information = 0; io->Status = STATUS_NOT_IMPLEMENTED; } } static void hid_device_get_feature_report(struct unix_device *iface, HID_XFER_PACKET *packet, IO_STATUS_BLOCK *io) { struct hid_haptics *haptics = &iface->hid_haptics; if (packet->reportId == haptics->features_report) { struct hid_haptics_features *features = (struct hid_haptics_features *)(packet->reportBuffer + 1); io->Information = sizeof(*features) + 1; assert(packet->reportBufferLen == io->Information); *features = haptics->features; io->Status = STATUS_SUCCESS; } else { io->Information = 0; io->Status = STATUS_NOT_IMPLEMENTED; } } static void hid_device_set_feature_report(struct unix_device *iface, HID_XFER_PACKET *packet, IO_STATUS_BLOCK *io) { struct hid_haptics *haptics = &iface->hid_haptics; if (packet->reportId == haptics->features_report) { struct hid_haptics_features *features = (struct hid_haptics_features *)(packet->reportBuffer + 1); io->Information = sizeof(*features) + 1; assert(packet->reportBufferLen == io->Information); haptics->features.waveform_cutoff_time_ms = features->waveform_cutoff_time_ms; io->Status = STATUS_SUCCESS; } else { io->Information = 0; io->Status = STATUS_NOT_IMPLEMENTED; } } static const struct raw_device_vtbl raw_device_vtbl = { hid_device_destroy, hid_device_start, hid_device_stop, hid_device_get_report_descriptor, hid_device_set_output_report, hid_device_get_feature_report, hid_device_set_feature_report, }; void *hid_device_create(const struct hid_device_vtbl *vtbl, SIZE_T size) { struct unix_device *impl; if (!(impl = raw_device_create(&raw_device_vtbl, size))) return NULL; impl->hid_vtbl = vtbl; return impl; } #ifdef WORDS_BIGENDIAN # define LE_ULONG(x) RtlUlongByteSwap((ULONG)(x)) #else # define LE_ULONG(x) ((ULONG)(x)) #endif BOOL hid_device_set_abs_axis(struct unix_device *iface, ULONG index, LONG value) { struct hid_device_state *state = &iface->hid_device_state; ULONG offset = state->abs_axis_start + index * 4; if (index > state->abs_axis_count) return FALSE; *(ULONG *)(state->report_buf + offset) = LE_ULONG(value); return TRUE; } BOOL hid_device_set_rel_axis(struct unix_device *iface, ULONG index, LONG value) { struct hid_device_state *state = &iface->hid_device_state; ULONG offset = state->rel_axis_start + index * 4; if (index > state->rel_axis_count) return FALSE; *(ULONG *)(state->report_buf + offset) = LE_ULONG(value); return TRUE; } BOOL hid_device_set_button(struct unix_device *iface, ULONG index, BOOL is_set) { struct hid_device_state *state = &iface->hid_device_state; ULONG offset = state->button_start + (index / 8); BYTE mask = (1 << (index % 8)); if (index > state->button_count) return FALSE; if (is_set) state->report_buf[offset] |= mask; else state->report_buf[offset] &= ~mask; return TRUE; } /* hatswitch x / y vs value: * -1 x +1 * +--------> * -1 | 8 1 2 * y | 7 0 3 * +1 | 6 5 4 * v */ static void hatswitch_decompose(BYTE value, LONG *x, LONG *y) { *x = *y = 0; if (value == 8 || value == 1 || value == 2) *y = -1; if (value == 6 || value == 5 || value == 4) *y = +1; if (value == 8 || value == 7 || value == 6) *x = -1; if (value == 2 || value == 3 || value == 4) *x = +1; } static void hatswitch_compose(LONG x, LONG y, BYTE *value) { if (x == 0 && y == 0) *value = 0; else if (x == 0 && y < 0) *value = 1; else if (x > 0 && y < 0) *value = 2; else if (x > 0 && y == 0) *value = 3; else if (x > 0 && y > 0) *value = 4; else if (x == 0 && y > 0) *value = 5; else if (x < 0 && y > 0) *value = 6; else if (x < 0 && y == 0) *value = 7; else if (x < 0 && y < 0) *value = 8; } BOOL hid_device_set_hatswitch_x(struct unix_device *iface, ULONG index, LONG new_x) { struct hid_device_state *state = &iface->hid_device_state; ULONG offset = state->hatswitch_start + index; LONG x, y; if (index > state->hatswitch_count) return FALSE; hatswitch_decompose(state->report_buf[offset], &x, &y); hatswitch_compose(new_x, y, &state->report_buf[offset]); return TRUE; } BOOL hid_device_set_hatswitch_y(struct unix_device *iface, ULONG index, LONG new_y) { struct hid_device_state *state = &iface->hid_device_state; ULONG offset = state->hatswitch_start + index; LONG x, y; if (index > state->hatswitch_count) return FALSE; hatswitch_decompose(state->report_buf[offset], &x, &y); hatswitch_compose(x, new_y, &state->report_buf[offset]); return TRUE; } BOOL hid_device_sync_report(struct unix_device *iface) { BOOL dropped; if (!(dropped = iface->hid_device_state.dropped)) memcpy(iface->hid_device_state.last_report_buf, iface->hid_device_state.report_buf, iface->hid_device_state.report_len); else memcpy(iface->hid_device_state.report_buf, iface->hid_device_state.last_report_buf, iface->hid_device_state.report_len); iface->hid_device_state.dropped = FALSE; return !dropped; } void hid_device_drop_report(struct unix_device *iface) { iface->hid_device_state.dropped = TRUE; } void hid_device_set_effect_state(struct unix_device *iface, BYTE index, BYTE flags) { struct hid_effect_state *state = &iface->hid_physical.effect_state; struct pid_effect_state *report = (struct pid_effect_state *)(state->report_buf + 1); report->index = index; report->flags = flags; }